added OCIO libary

OCIO and Fullscreen stubs
Font loading fixes
2026-06-03 01:16:40 -04:00 · 2026-06-03 01:08:43 -04:00 · 2026-06-03 00:45:31 -04:00 · 2026-06-01 06:52:56 -04:00 · 2026-06-01 06:45:41 -04:00 · 2026-05-30 22:57:59 +10:00
336 changed files with 31648 additions and 12168 deletions
--- a/.gitea/workflows/ci.yml
+++ b/.gitea/workflows/ci.yml
@@ -7,6 +7,9 @@ on:
      - master
      - develop
  pull_request:
  schedule:
    # Nightly build at 14:00 UTC, roughly midnight in Australia/Sydney.
    - cron: "0 14 * * *"
  workflow_dispatch:
 jobs:
@@ -15,8 +18,53 @@ jobs:
    runs-on: windows-2022
    steps:
-      - name: Checkout
+      - name: Manual Checkout With LFS Submodules
-        uses: actions/checkout@v4
+        shell: powershell
        env:
          GITEA_PAT: ${{ secrets.TOKEN }}
        run: |
          function Invoke-Git {
            & git @args
            if ($LASTEXITCODE -ne 0) {
              exit $LASTEXITCODE
            }
          }
          function Add-GiteaTokenToUrl([string]$url) {
            if ([string]::IsNullOrWhiteSpace($env:GITEA_PAT)) {
              return $url
            }
            return $url -replace "^https://", "https://aiden:$($env:GITEA_PAT)@"
          }
          $serverUrl = "${{ gitea.server_url }}".TrimEnd("/")
          $repository = "${{ gitea.repository }}"
          if ([string]::IsNullOrWhiteSpace($serverUrl)) {
            $serverUrl = "https://git.f-40.com"
          }
          if ([string]::IsNullOrWhiteSpace($repository)) {
            $repository = "aiden/video-shader-toys"
          }
          $repoUrl = Add-GiteaTokenToUrl "$serverUrl/$repository.git"
          Invoke-Git init .
          Invoke-Git lfs install --local
          Invoke-Git remote add origin "$repoUrl"
          Invoke-Git fetch --depth=1 origin "${{ gitea.ref }}"
          Invoke-Git checkout FETCH_HEAD
          Invoke-Git lfs pull origin "${{ gitea.ref }}"
          Invoke-Git submodule sync --recursive
          $submoduleUrl = Invoke-Git config --file .gitmodules --get submodule.video-io-3rdParty.url
          $submoduleUrl = Add-GiteaTokenToUrl "$submoduleUrl"
          Invoke-Git config submodule.video-io-3rdParty.url "$submoduleUrl"
          Invoke-Git submodule update --init --recursive --depth=1
          Invoke-Git -C video-io-3rdParty lfs pull
          Write-Host "Parent LFS files:"
          Invoke-Git lfs ls-files
          Write-Host "Submodule LFS files:"
          Invoke-Git -C video-io-3rdParty lfs ls-files
      - name: Verify Visual Studio ATL
        shell: powershell
@@ -31,37 +79,81 @@ jobs:
      - name: Configure Debug
        shell: powershell
        run: |
          $thirdPartyRoot = "${{ vars.THIRD_PARTY_ROOT }}"
          if ([string]::IsNullOrWhiteSpace($thirdPartyRoot)) {
            $thirdPartyRoot = $env:THIRD_PARTY_ROOT
          }
          if ([string]::IsNullOrWhiteSpace($thirdPartyRoot)) {
            $thirdPartyRoot = Join-Path $PWD "video-io-3rdParty"
          }
          if (-not (Test-Path -LiteralPath $thirdPartyRoot)) {
            $thirdPartyRoot = Join-Path $PWD "3rdParty"
          }
          $slangRoot = "${{ vars.SLANG_ROOT }}"
          if ([string]::IsNullOrWhiteSpace($slangRoot)) {
            $slangRoot = $env:SLANG_ROOT
          }
          if ([string]::IsNullOrWhiteSpace($slangRoot)) {
-            $slangRoot = Join-Path $PWD "3rdParty\slang-2026.8-windows-x86_64"
+            $slangRoot = Join-Path $thirdPartyRoot "slang-2026.8-windows-x86_64"
          }
          $msdfAtlasGenRoot = "${{ vars.MSDF_ATLAS_GEN_ROOT }}"
          if ([string]::IsNullOrWhiteSpace($msdfAtlasGenRoot)) {
            $msdfAtlasGenRoot = $env:MSDF_ATLAS_GEN_ROOT
          }
          if ([string]::IsNullOrWhiteSpace($msdfAtlasGenRoot)) {
            $msdfAtlasGenRoot = Join-Path $thirdPartyRoot "msdf-atlas-gen"
          }
          $ndiSdkRoot = "${{ vars.NDI_SDK_ROOT }}"
          if ([string]::IsNullOrWhiteSpace($ndiSdkRoot)) {
            $ndiSdkRoot = $env:NDI_SDK_ROOT
          }
          if ([string]::IsNullOrWhiteSpace($ndiSdkRoot)) {
            $ndiSdkRoot = Join-Path $thirdPartyRoot "NDI 6 SDK"
          }
          $deckLinkSdkRoot = "${{ vars.DECKLINK_SDK_ROOT }}"
          if ([string]::IsNullOrWhiteSpace($deckLinkSdkRoot)) {
            $deckLinkSdkRoot = $env:DECKLINK_SDK_ROOT
          }
          if ([string]::IsNullOrWhiteSpace($deckLinkSdkRoot)) {
            $deckLinkSdkRoot = Join-Path $thirdPartyRoot "Blackmagic DeckLink SDK 16.0"
          }
          $requiredFiles = @(
            (Join-Path $slangRoot "bin\slangc.exe"),
            (Join-Path $slangRoot "bin\slang-compiler.dll"),
            (Join-Path $slangRoot "bin\slang-glslang.dll"),
-            (Join-Path $slangRoot "LICENSE")
+            (Join-Path $slangRoot "LICENSE"),
            (Join-Path $msdfAtlasGenRoot "msdf-atlas-gen.exe"),
            (Join-Path $ndiSdkRoot "Include\Processing.NDI.Lib.h"),
            (Join-Path $ndiSdkRoot "Lib\x64\Processing.NDI.Lib.x64.lib"),
            (Join-Path $ndiSdkRoot "Bin\x64\Processing.NDI.Lib.x64.dll"),
            (Join-Path $deckLinkSdkRoot "Win\include\DeckLinkAPI.idl")
          )
          $missingFiles = @($requiredFiles | Where-Object { -not (Test-Path -LiteralPath $_) })
          if ($missingFiles.Count -gt 0) {
-            Write-Error "Missing native third-party dependencies. Set Gitea repository variable SLANG_ROOT, or pre-populate the repo-local 3rdParty folder on the Windows runner. Missing: $($missingFiles -join ', ')"
+            Write-Error "Missing native third-party dependencies. Initialize the private video-io-3rdParty submodule, set THIRD_PARTY_ROOT, or configure per-SDK repository variables. Missing: $($missingFiles -join ', ')"
            exit 1
          }
          Write-Host "Using THIRD_PARTY_ROOT=$thirdPartyRoot"
          Write-Host "Using SLANG_ROOT=$slangRoot"
-          cmake --preset vs2022-x64-debug -DSLANG_ROOT="$slangRoot"
+          Write-Host "Using MSDF_ATLAS_GEN_ROOT=$msdfAtlasGenRoot"
          Write-Host "Using NDI_SDK_ROOT=$ndiSdkRoot"
          Write-Host "Using DECKLINK_SDK_ROOT=$deckLinkSdkRoot"
          cmake --preset vs2022-x64-debug -DTHIRD_PARTY_ROOT="$thirdPartyRoot" -DSLANG_ROOT="$slangRoot" -DMSDF_ATLAS_GEN_ROOT="$msdfAtlasGenRoot" -DNDI_SDK_ROOT="$ndiSdkRoot" -DDECKLINK_SDK_ROOT="$deckLinkSdkRoot"
      - name: Build Debug
        shell: powershell
-        run: cmake --build --preset build-debug
+        run: cmake --build --preset build-debug --parallel
-      - name: Run Native Tests
+      - name: Run Native Tests And Shader Validation
        shell: powershell
-        run: cmake --build --preset build-debug --target RUN_TESTS
+        run: cmake --build --preset build-debug --target RUN_TESTS --parallel
  ui-ubuntu:
    name: React UI Build
@@ -82,13 +174,59 @@ jobs:
  package-windows:
    name: Windows Release Package
    runs-on: windows-2022
    if: github.event_name == 'schedule' || github.event_name == 'workflow_dispatch'
    needs:
      - native-windows
      - ui-ubuntu
    steps:
-      - name: Checkout
+      - name: Manual Checkout With LFS Submodules
-        uses: actions/checkout@v4
+        shell: powershell
        env:
          GITEA_PAT: ${{ secrets.TOKEN }}
        run: |
          function Invoke-Git {
            & git @args
            if ($LASTEXITCODE -ne 0) {
              exit $LASTEXITCODE
            }
          }
          function Add-GiteaTokenToUrl([string]$url) {
            if ([string]::IsNullOrWhiteSpace($env:GITEA_PAT)) {
              return $url
            }
            return $url -replace "^https://", "https://aiden:$($env:GITEA_PAT)@"
          }
          $serverUrl = "${{ gitea.server_url }}".TrimEnd("/")
          $repository = "${{ gitea.repository }}"
          if ([string]::IsNullOrWhiteSpace($serverUrl)) {
            $serverUrl = "https://git.f-40.com"
          }
          if ([string]::IsNullOrWhiteSpace($repository)) {
            $repository = "aiden/video-shader-toys"
          }
          $repoUrl = Add-GiteaTokenToUrl "$serverUrl/$repository.git"
          Invoke-Git init .
          Invoke-Git lfs install --local
          Invoke-Git remote add origin "$repoUrl"
          Invoke-Git fetch --depth=1 origin "${{ gitea.ref }}"
          Invoke-Git checkout FETCH_HEAD
          Invoke-Git lfs pull origin "${{ gitea.ref }}"
          Invoke-Git submodule sync --recursive
          $submoduleUrl = Invoke-Git config --file .gitmodules --get submodule.video-io-3rdParty.url
          $submoduleUrl = Add-GiteaTokenToUrl "$submoduleUrl"
          Invoke-Git config submodule.video-io-3rdParty.url "$submoduleUrl"
          Invoke-Git submodule update --init --recursive --depth=1
          Invoke-Git -C video-io-3rdParty lfs pull
          Write-Host "Parent LFS files:"
          Invoke-Git lfs ls-files
          Write-Host "Submodule LFS files:"
          Invoke-Git -C video-io-3rdParty lfs ls-files
      - name: Verify Visual Studio ATL
        shell: powershell
@@ -110,33 +248,77 @@ jobs:
      - name: Configure Release
        shell: powershell
        run: |
          $thirdPartyRoot = "${{ vars.THIRD_PARTY_ROOT }}"
          if ([string]::IsNullOrWhiteSpace($thirdPartyRoot)) {
            $thirdPartyRoot = $env:THIRD_PARTY_ROOT
          }
          if ([string]::IsNullOrWhiteSpace($thirdPartyRoot)) {
            $thirdPartyRoot = Join-Path $PWD "video-io-3rdParty"
          }
          if (-not (Test-Path -LiteralPath $thirdPartyRoot)) {
            $thirdPartyRoot = Join-Path $PWD "3rdParty"
          }
          $slangRoot = "${{ vars.SLANG_ROOT }}"
          if ([string]::IsNullOrWhiteSpace($slangRoot)) {
            $slangRoot = $env:SLANG_ROOT
          }
          if ([string]::IsNullOrWhiteSpace($slangRoot)) {
-            $slangRoot = Join-Path $PWD "3rdParty\slang-2026.8-windows-x86_64"
+            $slangRoot = Join-Path $thirdPartyRoot "slang-2026.8-windows-x86_64"
          }
          $msdfAtlasGenRoot = "${{ vars.MSDF_ATLAS_GEN_ROOT }}"
          if ([string]::IsNullOrWhiteSpace($msdfAtlasGenRoot)) {
            $msdfAtlasGenRoot = $env:MSDF_ATLAS_GEN_ROOT
          }
          if ([string]::IsNullOrWhiteSpace($msdfAtlasGenRoot)) {
            $msdfAtlasGenRoot = Join-Path $thirdPartyRoot "msdf-atlas-gen"
          }
          $ndiSdkRoot = "${{ vars.NDI_SDK_ROOT }}"
          if ([string]::IsNullOrWhiteSpace($ndiSdkRoot)) {
            $ndiSdkRoot = $env:NDI_SDK_ROOT
          }
          if ([string]::IsNullOrWhiteSpace($ndiSdkRoot)) {
            $ndiSdkRoot = Join-Path $thirdPartyRoot "NDI 6 SDK"
          }
          $deckLinkSdkRoot = "${{ vars.DECKLINK_SDK_ROOT }}"
          if ([string]::IsNullOrWhiteSpace($deckLinkSdkRoot)) {
            $deckLinkSdkRoot = $env:DECKLINK_SDK_ROOT
          }
          if ([string]::IsNullOrWhiteSpace($deckLinkSdkRoot)) {
            $deckLinkSdkRoot = Join-Path $thirdPartyRoot "Blackmagic DeckLink SDK 16.0"
          }
          $requiredFiles = @(
            (Join-Path $slangRoot "bin\slangc.exe"),
            (Join-Path $slangRoot "bin\slang-compiler.dll"),
            (Join-Path $slangRoot "bin\slang-glslang.dll"),
-            (Join-Path $slangRoot "LICENSE")
+            (Join-Path $slangRoot "LICENSE"),
            (Join-Path $msdfAtlasGenRoot "msdf-atlas-gen.exe"),
            (Join-Path $ndiSdkRoot "Include\Processing.NDI.Lib.h"),
            (Join-Path $ndiSdkRoot "Lib\x64\Processing.NDI.Lib.x64.lib"),
            (Join-Path $ndiSdkRoot "Bin\x64\Processing.NDI.Lib.x64.dll"),
            (Join-Path $deckLinkSdkRoot "Win\include\DeckLinkAPI.idl")
          )
          $missingFiles = @($requiredFiles | Where-Object { -not (Test-Path -LiteralPath $_) })
          if ($missingFiles.Count -gt 0) {
-            Write-Error "Missing native third-party dependencies. Set Gitea repository variable SLANG_ROOT, or pre-populate the repo-local 3rdParty folder on the Windows runner. Missing: $($missingFiles -join ', ')"
+            Write-Error "Missing native third-party dependencies. Initialize the private video-io-3rdParty submodule, set THIRD_PARTY_ROOT, or configure per-SDK repository variables. Missing: $($missingFiles -join ', ')"
            exit 1
          }
          Write-Host "Using THIRD_PARTY_ROOT=$thirdPartyRoot"
          Write-Host "Using SLANG_ROOT=$slangRoot"
-          cmake --preset vs2022-x64-release -DSLANG_ROOT="$slangRoot"
+          Write-Host "Using MSDF_ATLAS_GEN_ROOT=$msdfAtlasGenRoot"
          Write-Host "Using NDI_SDK_ROOT=$ndiSdkRoot"
          Write-Host "Using DECKLINK_SDK_ROOT=$deckLinkSdkRoot"
          cmake --preset vs2022-x64-release -DTHIRD_PARTY_ROOT="$thirdPartyRoot" -DSLANG_ROOT="$slangRoot" -DMSDF_ATLAS_GEN_ROOT="$msdfAtlasGenRoot" -DNDI_SDK_ROOT="$ndiSdkRoot" -DDECKLINK_SDK_ROOT="$deckLinkSdkRoot"
      - name: Build Release
        shell: powershell
-        run: cmake --build --preset build-release
+        run: cmake --build --preset build-release --parallel
      - name: Install Runtime Package
        shell: powershell
--- a/.gitmodules
+++ b/.gitmodules
@@ -0,0 +1,3 @@
 [submodule "video-io-3rdParty"]
 	path = video-io-3rdParty
 	url = https://git.f-40.com/aiden/video-io-3rdParty.git
--- a/.vscode/launch.json
+++ b/.vscode/launch.json
@@ -2,16 +2,21 @@
  "version": "0.2.0",
  "configurations": [
    {
-      "name": "Debug LoopThroughWithOpenGLCompositing",
+      "name": "Debug RenderCadenceCompositor",
      "type": "cppvsdbg",
      "request": "launch",
-      "program": "${workspaceFolder}\\build\\vs2022-x64-debug\\Debug\\LoopThroughWithOpenGLCompositing.exe",
+      "program": "${workspaceFolder}\\build\\vs2022-x64-debug\\Debug\\RenderCadenceCompositor.exe",
      "args": [],
      "stopAtEntry": false,
-      "cwd": "${workspaceFolder}\\build\\vs2022-x64-debug\\Debug",
+      "cwd": "${workspaceFolder}",
      "environment": [],
-      "console": "internalConsole",
+      "console": "externalTerminal",
-      "preLaunchTask": "Build LoopThroughWithOpenGLCompositing Debug x64"
+      "symbolSearchPath": "${workspaceFolder}\\build\\vs2022-x64-debug\\Debug",
      "requireExactSource": true,
      "logging": {
        "moduleLoad": true
      },
      "preLaunchTask": "Build RenderCadenceCompositor Debug x64"
    }
  ]
 }
--- a/.vscode/settings.json
+++ b/.vscode/settings.json
@@ -0,0 +1,11 @@
 {
  "json.schemas": [
    {
      "fileMatch": [
        "/config/runtime-host.json",
        "/config/runtime-host.*.json"
      ],
      "url": "./config/runtime-host.schema.json"
    }
  ]
 }
--- a/.vscode/tasks.json
+++ b/.vscode/tasks.json
@@ -2,42 +2,72 @@
  "version": "2.0.0",
  "tasks": [
    {
-      "label": "Build LoopThroughWithOpenGLCompositing Debug x64",
+      "label": "Configure Debug x64",
      "type": "process",
-      "command": "C:\\Program Files\\Microsoft Visual Studio\\2022\\Community\\Common7\\IDE\\CommonExtensions\\Microsoft\\CMake\\CMake\\bin\\cmake.exe",
+      "command": "cmake",
      "args": [
        "--preset",
        "vs2022-x64-debug"
      ],
      "problemMatcher": "$msCompile"
    },
    {
      "label": "Build RenderCadenceCompositor Debug x64",
      "type": "process",
      "command": "cmake",
      "args": [
        "--build",
        "${workspaceFolder}\\build\\vs2022-x64-debug",
        "--config",
        "Debug",
        "--target",
-        "LoopThroughWithOpenGLCompositing"
+        "RenderCadenceCompositor",
        "--parallel"
      ],
      "group": {
        "kind": "build",
        "isDefault": true
      },
      "dependsOn": "Configure Debug x64",
      "problemMatcher": "$msCompile"
    },
    {
-      "label": "Build LoopThroughWithOpenGLCompositing Release x64",
+      "label": "Build RenderCadenceCompositor Release x64",
      "type": "process",
-      "command": "C:\\Program Files\\Microsoft Visual Studio\\2022\\Community\\Common7\\IDE\\CommonExtensions\\Microsoft\\CMake\\CMake\\bin\\cmake.exe",
+      "command": "cmake",
      "args": [
        "--build",
        "${workspaceFolder}\\build\\vs2022-x64-release",
        "--config",
        "Release",
        "--target",
-        "LoopThroughWithOpenGLCompositing"
+        "RenderCadenceCompositor",
        "--parallel"
      ],
      "group": "build",
      "problemMatcher": "$msCompile"
    },
    {
-      "label": "Clean LoopThroughWithOpenGLCompositing Debug x64",
+      "label": "Run Native Tests Debug x64",
      "type": "process",
-      "command": "C:\\Program Files\\Microsoft Visual Studio\\2022\\Community\\Common7\\IDE\\CommonExtensions\\Microsoft\\CMake\\CMake\\bin\\cmake.exe",
+      "command": "cmake",
      "args": [
        "--build",
        "${workspaceFolder}\\build\\vs2022-x64-debug",
        "--config",
        "Debug",
        "--target",
        "RUN_TESTS",
        "--parallel"
      ],
      "group": "test",
      "dependsOn": "Configure Debug x64",
      "problemMatcher": "$msCompile"
    },
    {
      "label": "Clean Debug x64",
      "type": "process",
      "command": "cmake",
      "args": [
        "--build",
        "${workspaceFolder}\\build\\vs2022-x64-debug",
--- a/CMakeLists.txt
+++ b/CMakeLists.txt
@@ -1,278 +1,316 @@
 cmake_minimum_required(VERSION 3.24)
-project(video_shader LANGUAGES C CXX RC)
+project(video_shader LANGUAGES C CXX)
 include(CTest)
 set(CMAKE_CXX_STANDARD 17)
 set(CMAKE_CXX_STANDARD_REQUIRED ON)
 set(CMAKE_CXX_EXTENSIONS OFF)
-set(APP_DIR "${CMAKE_CURRENT_SOURCE_DIR}/apps/LoopThroughWithOpenGLCompositing")
+set(SRC_DIR "${CMAKE_CURRENT_SOURCE_DIR}/src")
-set(SLANG_ROOT "${CMAKE_CURRENT_SOURCE_DIR}/3rdParty/slang-2026.8-windows-x86_64" CACHE PATH "Path to a Slang binary release containing bin/slangc.exe")
+set(TEST_DIR "${CMAKE_CURRENT_SOURCE_DIR}/tests")
-if(NOT EXISTS "${APP_DIR}/LoopThroughWithOpenGLCompositing.cpp")
+set(LEGACY_THIRD_PARTY_ROOT "${CMAKE_CURRENT_SOURCE_DIR}/3rdParty")
-	message(FATAL_ERROR "Imported app sources were not found under ${APP_DIR}")
+set(DEFAULT_THIRD_PARTY_ROOT "${CMAKE_CURRENT_SOURCE_DIR}/video-io-3rdParty")
 if(NOT EXISTS "${DEFAULT_THIRD_PARTY_ROOT}")
 	set(DEFAULT_THIRD_PARTY_ROOT "${LEGACY_THIRD_PARTY_ROOT}")
 endif()
 set(THIRD_PARTY_ROOT "${DEFAULT_THIRD_PARTY_ROOT}" CACHE PATH "Path to the third-party SDK bundle")
 if(EXISTS "${DEFAULT_THIRD_PARTY_ROOT}" AND THIRD_PARTY_ROOT STREQUAL LEGACY_THIRD_PARTY_ROOT AND NOT EXISTS "${THIRD_PARTY_ROOT}")
 	set(THIRD_PARTY_ROOT "${DEFAULT_THIRD_PARTY_ROOT}" CACHE PATH "Path to the third-party SDK bundle" FORCE)
 endif()
 set(SLANG_ROOT "${THIRD_PARTY_ROOT}/slang-2026.8-windows-x86_64" CACHE PATH "Path to a Slang binary release containing bin/slangc.exe")
 set(MSDF_ATLAS_GEN_ROOT "${THIRD_PARTY_ROOT}/msdf-atlas-gen" CACHE PATH "Path to msdf-atlas-gen binary release")
 set(NDI_SDK_ROOT "${THIRD_PARTY_ROOT}/NDI 6 SDK" CACHE PATH "Path to the NDI SDK")
 set(DECKLINK_SDK_ROOT "${THIRD_PARTY_ROOT}/Blackmagic DeckLink SDK 16.0" CACHE PATH "Path to the Blackmagic DeckLink SDK")
 set(LEGACY_SLANG_ROOT "${LEGACY_THIRD_PARTY_ROOT}/slang-2026.8-windows-x86_64")
 set(LEGACY_MSDF_ATLAS_GEN_ROOT "${LEGACY_THIRD_PARTY_ROOT}/msdf-atlas-gen")
 set(LEGACY_NDI_SDK_ROOT "${LEGACY_THIRD_PARTY_ROOT}/NDI 6 SDK")
 set(LEGACY_DECKLINK_SDK_ROOT "${LEGACY_THIRD_PARTY_ROOT}/Blackmagic DeckLink SDK 16.0")
 if(EXISTS "${DEFAULT_THIRD_PARTY_ROOT}")
 	if(SLANG_ROOT STREQUAL LEGACY_SLANG_ROOT AND NOT EXISTS "${SLANG_ROOT}")
 		set(SLANG_ROOT "${THIRD_PARTY_ROOT}/slang-2026.8-windows-x86_64" CACHE PATH "Path to a Slang binary release containing bin/slangc.exe" FORCE)
 	endif()
 	if(MSDF_ATLAS_GEN_ROOT STREQUAL LEGACY_MSDF_ATLAS_GEN_ROOT AND NOT EXISTS "${MSDF_ATLAS_GEN_ROOT}")
 		set(MSDF_ATLAS_GEN_ROOT "${THIRD_PARTY_ROOT}/msdf-atlas-gen" CACHE PATH "Path to msdf-atlas-gen binary release" FORCE)
 	endif()
 	if(NDI_SDK_ROOT STREQUAL LEGACY_NDI_SDK_ROOT AND NOT EXISTS "${NDI_SDK_ROOT}")
 		set(NDI_SDK_ROOT "${THIRD_PARTY_ROOT}/NDI 6 SDK" CACHE PATH "Path to the NDI SDK" FORCE)
 	endif()
 	if(DECKLINK_SDK_ROOT STREQUAL LEGACY_DECKLINK_SDK_ROOT AND NOT EXISTS "${DECKLINK_SDK_ROOT}")
 		set(DECKLINK_SDK_ROOT "${THIRD_PARTY_ROOT}/Blackmagic DeckLink SDK 16.0" CACHE PATH "Path to the Blackmagic DeckLink SDK" FORCE)
 	endif()
 endif()
 set(VIDEO_SHADER_INCLUDE_DIRS
 	"${SRC_DIR}"
 	"${SRC_DIR}/app"
 	"${SRC_DIR}/control"
 	"${SRC_DIR}/control/http"
 	"${SRC_DIR}/frames"
 	"${SRC_DIR}/json"
 	"${SRC_DIR}/logging"
 	"${SRC_DIR}/platform"
 	"${SRC_DIR}/preview"
 	"${SRC_DIR}/render"
 	"${SRC_DIR}/render/readback"
 	"${SRC_DIR}/render/thread"
 	"${SRC_DIR}/render/runtime"
 	"${SRC_DIR}/runtime"
 	"${SRC_DIR}/runtime/catalog"
 	"${SRC_DIR}/runtime/layers"
 	"${SRC_DIR}/runtime/shader"
 	"${SRC_DIR}/runtime/state"
 	"${SRC_DIR}/runtime/text"
 	"${SRC_DIR}/shader"
 	"${SRC_DIR}/telemetry"
 	"${SRC_DIR}/video"
 	"${SRC_DIR}/video/core"
 	"${SRC_DIR}/video/decklink"
 	"${SRC_DIR}/video/ndi"
 	"${SRC_DIR}/video/playout"
 )
 function(video_shader_target_defaults target)
 	target_include_directories(${target} PRIVATE ${VIDEO_SHADER_INCLUDE_DIRS})
 	target_compile_definitions(${target} PRIVATE _UNICODE UNICODE)
 	if(MSVC)
 		target_compile_options(${target} PRIVATE /W3)
 	endif()
 endfunction()
 function(video_shader_files_exist out_var)
 	set(missing_files)
 	foreach(file IN LISTS ARGN)
 		if(NOT EXISTS "${file}")
 			list(APPEND missing_files "${file}")
 		endif()
 	endforeach()
 	set(${out_var} "${missing_files}" PARENT_SCOPE)
 endfunction()
 function(add_video_shader_test name)
 	add_executable(${name} ${ARGN})
 	video_shader_target_defaults(${name})
 	add_test(NAME ${name} COMMAND ${name})
 endfunction()
 set(RUNTIME_JSON_SOURCES
 	"${SRC_DIR}/runtime/state/RuntimeJson.cpp"
 )
 set(RUNTIME_PARAMETER_SOURCES
 	${RUNTIME_JSON_SOURCES}
 	"${SRC_DIR}/runtime/state/RuntimeParameterUtils.cpp"
 )
 set(RUNTIME_STATE_SOURCES
 	${RUNTIME_JSON_SOURCES}
 	"${SRC_DIR}/runtime/state/RuntimeStatePersistence.cpp"
 )
 set(RUNTIME_LAYER_SOURCES
 	"${SRC_DIR}/runtime/layers/RuntimeLayerModel.cpp"
 	"${SRC_DIR}/runtime/layers/RuntimeLayerReload.cpp"
 	"${SRC_DIR}/runtime/layers/RuntimeLayerSnapshot.cpp"
 	"${SRC_DIR}/runtime/layers/RuntimeLayerStateRestore.cpp"
 )
 set(RUNTIME_TEXT_SOURCES
 	"${SRC_DIR}/runtime/text/FontAtlasBuilder.cpp"
 	"${SRC_DIR}/runtime/text/FontAtlasImageLoader.cpp"
 	"${SRC_DIR}/runtime/text/FontAtlasMetadata.cpp"
 	"${SRC_DIR}/runtime/text/FontAtlasProcess.cpp"
 	"${SRC_DIR}/runtime/text/RuntimeTextTextureComposer.cpp"
 )
 set(RUNTIME_CATALOG_SOURCES
 	"${SRC_DIR}/runtime/catalog/SupportedShaderCatalog.cpp"
 )
 set(SHADER_MANIFEST_SOURCES
 	"${SRC_DIR}/shader/ShaderManifestAssets.cpp"
 	"${SRC_DIR}/shader/ShaderManifestParameters.cpp"
 	"${SRC_DIR}/shader/ShaderManifestParser.cpp"
 	"${SRC_DIR}/shader/ShaderPackageRegistry.cpp"
 	"${SRC_DIR}/shader/ShaderUiPath.cpp"
 )
 set(VIDEO_MODE_SOURCES
 	"${SRC_DIR}/video/core/VideoMode.cpp"
 )
 set(VIDEO_FORMAT_SOURCES
 	"${SRC_DIR}/video/core/VideoIOFormat.cpp"
 )
 set(SLANG_RUNTIME_FILES
 	"${SLANG_ROOT}/bin/slangc.exe"
 	"${SLANG_ROOT}/bin/slang-compiler.dll"
 	"${SLANG_ROOT}/bin/slang-glslang.dll"
 )
 set(SLANG_LICENSE_FILE "${SLANG_ROOT}/LICENSE")
 set(MSDF_ATLAS_GEN_EXE_FILE "${MSDF_ATLAS_GEN_ROOT}/msdf-atlas-gen.exe")
 file(GLOB MSDF_ATLAS_GEN_DLL_FILES CONFIGURE_DEPENDS
 	"${MSDF_ATLAS_GEN_ROOT}/*.dll"
 )
 set(MSDF_ATLAS_GEN_RUNTIME_FILES
 	"${MSDF_ATLAS_GEN_EXE_FILE}"
 	${MSDF_ATLAS_GEN_DLL_FILES}
 )
 set(MSDF_ATLAS_GEN_LICENSE_FILE "${MSDF_ATLAS_GEN_ROOT}/LICENSE.txt")
 set(MSDF_ATLAS_GEN_README_FILE "${MSDF_ATLAS_GEN_ROOT}/README.md")
 set(NDI_INCLUDE_DIR "${NDI_SDK_ROOT}/Include")
 set(NDI_RUNTIME_DLL "${NDI_SDK_ROOT}/Bin/x64/Processing.NDI.Lib.x64.dll")
 set(NDI_IMPORT_LIB "${NDI_SDK_ROOT}/Lib/x64/Processing.NDI.Lib.x64.lib")
 set(NDI_LICENSE_FILE "${NDI_SDK_ROOT}/NDI SDK License Agreement.pdf")
 set(NDI_NOTICES_FILE "${NDI_SDK_ROOT}/Bin/x64/Processing.NDI.Lib.Licenses.txt")
 set(DECKLINK_SDK_IDL_FILE "${DECKLINK_SDK_ROOT}/Win/include/DeckLinkAPI.idl")
 set(DECKLINK_SDK_LICENSE_FILE "${DECKLINK_SDK_ROOT}/End User License Agreement.pdf")
-foreach(SLANG_RUNTIME_FILE IN LISTS SLANG_RUNTIME_FILES)
+set(RENDER_CADENCE_APP_REQUIRED_FILES
-	if(NOT EXISTS "${SLANG_RUNTIME_FILE}")
+	"${SRC_DIR}/RenderCadenceCompositor.cpp"
-		message(FATAL_ERROR "Required Slang runtime file not found: ${SLANG_RUNTIME_FILE}")
+	"${SRC_DIR}/video/decklink/DeckLinkAPI_i.c"
 	"${SRC_DIR}/video/decklink/DeckLinkAPI_h.h"
 )
 video_shader_files_exist(RENDER_CADENCE_APP_MISSING_FILES ${RENDER_CADENCE_APP_REQUIRED_FILES})
 if(EXISTS "${DECKLINK_SDK_IDL_FILE}")
 	message(STATUS "Blackmagic DeckLink SDK found: ${DECKLINK_SDK_ROOT}")
 else()
 	message(STATUS "Blackmagic DeckLink SDK not found at ${DECKLINK_SDK_ROOT}; using checked-in DeckLink API shim files only")
 endif()
 if(RENDER_CADENCE_APP_MISSING_FILES)
 	message(STATUS "RenderCadenceCompositor target skipped; required app entry or external DeckLink SDK shim files are missing:")
 	foreach(missing_file IN LISTS RENDER_CADENCE_APP_MISSING_FILES)
 		message(STATUS "  ${missing_file}")
 	endforeach()
 else()
 	file(GLOB_RECURSE RENDER_CADENCE_APP_SOURCES CONFIGURE_DEPENDS
 		"${SRC_DIR}/*.c"
 		"${SRC_DIR}/*.cpp"
 		"${SRC_DIR}/*.h"
 	)
 	add_executable(RenderCadenceCompositor ${RENDER_CADENCE_APP_SOURCES})
 	video_shader_target_defaults(RenderCadenceCompositor)
 	if(EXISTS "${NDI_INCLUDE_DIR}" AND EXISTS "${NDI_IMPORT_LIB}")
 		target_include_directories(RenderCadenceCompositor PRIVATE "${NDI_INCLUDE_DIR}")
 		target_link_libraries(RenderCadenceCompositor PRIVATE "${NDI_IMPORT_LIB}")
 		if(EXISTS "${NDI_RUNTIME_DLL}")
 			add_custom_command(TARGET RenderCadenceCompositor POST_BUILD
 				COMMAND ${CMAKE_COMMAND} -E copy_if_different
 					"${NDI_RUNTIME_DLL}"
 					"$<TARGET_FILE_DIR:RenderCadenceCompositor>/Processing.NDI.Lib.x64.dll"
 			)
 		endif()
 	else()
 		message(STATUS "NDI SDK headers/import library not found; NDI backends will not build correctly: ${NDI_SDK_ROOT}")
 	endif()
 	target_link_libraries(RenderCadenceCompositor PRIVATE
 		opengl32
 		Ole32
 		Windowscodecs
 		Ws2_32
 	)
 	source_group(TREE "${SRC_DIR}" FILES ${RENDER_CADENCE_APP_SOURCES})
 endif()
 if(BUILD_TESTING)
 	add_subdirectory(tests)
 endif()
 if(TARGET RenderCadenceCompositor)
 	install(TARGETS RenderCadenceCompositor
 		RUNTIME DESTINATION "."
 	)
 endif()
 foreach(slang_runtime_file IN LISTS SLANG_RUNTIME_FILES)
 	if(EXISTS "${slang_runtime_file}")
 		install(FILES "${slang_runtime_file}"
 			DESTINATION "3rdParty/slang/bin"
 		)
 	else()
 		message(STATUS "Slang runtime file not found and will not be installed: ${slang_runtime_file}")
 	endif()
 endforeach()
-set(SLANG_LICENSE_FILE "${SLANG_ROOT}/LICENSE")
+foreach(msdf_runtime_file IN LISTS MSDF_ATLAS_GEN_RUNTIME_FILES)
-if(NOT EXISTS "${SLANG_LICENSE_FILE}")
+	if(EXISTS "${msdf_runtime_file}")
-	message(FATAL_ERROR "Slang license file not found: ${SLANG_LICENSE_FILE}")
+		install(FILES "${msdf_runtime_file}"
 			DESTINATION "3rdParty/msdf-atlas-gen"
 		)
 	else()
 		message(STATUS "msdf-atlas-gen runtime file not found and will not be installed: ${msdf_runtime_file}")
 	endif()
 endforeach()
 if(EXISTS "${MSDF_ATLAS_GEN_LICENSE_FILE}")
 	install(FILES "${MSDF_ATLAS_GEN_LICENSE_FILE}"
 		DESTINATION "third_party_notices"
 		RENAME "MSDF_ATLAS_GEN_LICENSE.txt"
 	)
 else()
 	message(STATUS "msdf-atlas-gen license file not found: ${MSDF_ATLAS_GEN_LICENSE_FILE}")
 endif()
-set(APP_SOURCES
+if(EXISTS "${MSDF_ATLAS_GEN_README_FILE}")
-	"${APP_DIR}/DeckLinkAPI_i.c"
+	install(FILES "${MSDF_ATLAS_GEN_README_FILE}"
-	"${APP_DIR}/control/ControlServer.cpp"
+		DESTINATION "third_party_notices"
-	"${APP_DIR}/control/ControlServer.h"
+		RENAME "MSDF_ATLAS_GEN_README.md"
-	"${APP_DIR}/control/OscServer.cpp"
+	)
-	"${APP_DIR}/control/OscServer.h"
+else()
-	"${APP_DIR}/control/RuntimeControlBridge.cpp"
+	message(STATUS "msdf-atlas-gen readme file not found: ${MSDF_ATLAS_GEN_README_FILE}")
 	"${APP_DIR}/control/RuntimeControlBridge.h"
 	"${APP_DIR}/control/RuntimeServices.cpp"
 	"${APP_DIR}/control/RuntimeServices.h"
 	"${APP_DIR}/decklink/DeckLinkDisplayMode.cpp"
 	"${APP_DIR}/decklink/DeckLinkDisplayMode.h"
 	"${APP_DIR}/decklink/DeckLinkFrameTransfer.cpp"
 	"${APP_DIR}/decklink/DeckLinkFrameTransfer.h"
 	"${APP_DIR}/decklink/DeckLinkSession.cpp"
 	"${APP_DIR}/decklink/DeckLinkSession.h"
 	"${APP_DIR}/decklink/VideoIOFormat.cpp"
 	"${APP_DIR}/decklink/VideoIOFormat.h"
 	"${APP_DIR}/gl/GLExtensions.cpp"
 	"${APP_DIR}/gl/GLExtensions.h"
 	"${APP_DIR}/gl/GlobalParamsBuffer.cpp"
 	"${APP_DIR}/gl/GlobalParamsBuffer.h"
 	"${APP_DIR}/gl/GlRenderConstants.h"
 	"${APP_DIR}/gl/GlScopedObjects.h"
 	"${APP_DIR}/gl/GlShaderSources.cpp"
 	"${APP_DIR}/gl/GlShaderSources.h"
 	"${APP_DIR}/gl/OpenGLComposite.cpp"
 	"${APP_DIR}/gl/OpenGLComposite.h"
 	"${APP_DIR}/gl/OpenGLCompositeRuntimeControls.cpp"
 	"${APP_DIR}/gl/OpenGLDeckLinkBridge.cpp"
 	"${APP_DIR}/gl/OpenGLDeckLinkBridge.h"
 	"${APP_DIR}/gl/OpenGLRenderPass.cpp"
 	"${APP_DIR}/gl/OpenGLRenderPass.h"
 	"${APP_DIR}/gl/OpenGLRenderer.cpp"
 	"${APP_DIR}/gl/OpenGLRenderer.h"
 	"${APP_DIR}/gl/OpenGLShaderPrograms.cpp"
 	"${APP_DIR}/gl/OpenGLShaderPrograms.h"
 	"${APP_DIR}/gl/PngScreenshotWriter.cpp"
 	"${APP_DIR}/gl/PngScreenshotWriter.h"
 	"${APP_DIR}/gl/ShaderProgramCompiler.cpp"
 	"${APP_DIR}/gl/ShaderProgramCompiler.h"
 	"${APP_DIR}/gl/ShaderBuildQueue.cpp"
 	"${APP_DIR}/gl/ShaderBuildQueue.h"
 	"${APP_DIR}/gl/ShaderTextureBindings.cpp"
 	"${APP_DIR}/gl/ShaderTextureBindings.h"
 	"${APP_DIR}/gl/Std140Buffer.h"
 	"${APP_DIR}/gl/TextRasterizer.cpp"
 	"${APP_DIR}/gl/TextRasterizer.h"
 	"${APP_DIR}/gl/TextureAssetLoader.cpp"
 	"${APP_DIR}/gl/TextureAssetLoader.h"
 	"${APP_DIR}/gl/TemporalHistoryBuffers.cpp"
 	"${APP_DIR}/gl/TemporalHistoryBuffers.h"
 	"${APP_DIR}/LoopThroughWithOpenGLCompositing.cpp"
 	"${APP_DIR}/LoopThroughWithOpenGLCompositing.h"
 	"${APP_DIR}/LoopThroughWithOpenGLCompositing.rc"
 	"${APP_DIR}/platform/NativeHandles.h"
 	"${APP_DIR}/platform/NativeSockets.h"
 	"${APP_DIR}/resource.h"
 	"${APP_DIR}/runtime/RuntimeHost.cpp"
 	"${APP_DIR}/runtime/RuntimeHost.h"
 	"${APP_DIR}/runtime/RuntimeClock.cpp"
 	"${APP_DIR}/runtime/RuntimeClock.h"
 	"${APP_DIR}/runtime/RuntimeJson.cpp"
 	"${APP_DIR}/runtime/RuntimeJson.h"
 	"${APP_DIR}/runtime/RuntimeParameterUtils.cpp"
 	"${APP_DIR}/runtime/RuntimeParameterUtils.h"
 	"${APP_DIR}/shader/ShaderCompiler.cpp"
 	"${APP_DIR}/shader/ShaderCompiler.h"
 	"${APP_DIR}/shader/ShaderPackageRegistry.cpp"
 	"${APP_DIR}/shader/ShaderPackageRegistry.h"
 	"${APP_DIR}/shader/ShaderTypes.h"
 	"${APP_DIR}/stdafx.cpp"
 	"${APP_DIR}/stdafx.h"
 	"${APP_DIR}/targetver.h"
 )
 add_executable(LoopThroughWithOpenGLCompositing WIN32 ${APP_SOURCES})
 target_include_directories(LoopThroughWithOpenGLCompositing PRIVATE
 	"${APP_DIR}"
 	"${APP_DIR}/control"
 	"${APP_DIR}/decklink"
 	"${APP_DIR}/gl"
 	"${APP_DIR}/platform"
 	"${APP_DIR}/runtime"
 	"${APP_DIR}/shader"
 )
 target_link_libraries(LoopThroughWithOpenGLCompositing PRIVATE
 	opengl32
 	glu32
 	Ws2_32
 	Crypt32
 	Advapi32
 	Gdiplus
 	Ole32
 	Windowscodecs
 )
 target_compile_definitions(LoopThroughWithOpenGLCompositing PRIVATE
 	_UNICODE
 	UNICODE
 )
 if(MSVC)
 	target_compile_options(LoopThroughWithOpenGLCompositing PRIVATE /W3)
 endif()
-add_executable(RuntimeJsonTests
+if(EXISTS "${SLANG_LICENSE_FILE}")
-	"${APP_DIR}/runtime/RuntimeJson.cpp"
+	install(FILES "${SLANG_LICENSE_FILE}"
-	"${CMAKE_CURRENT_SOURCE_DIR}/tests/RuntimeJsonTests.cpp"
+		DESTINATION "third_party_notices"
-)
+		RENAME "SLANG_LICENSE.txt"
-
+	)
-target_include_directories(RuntimeJsonTests PRIVATE
+else()
-	"${APP_DIR}"
+	message(STATUS "Slang license file not found and will not be installed: ${SLANG_LICENSE_FILE}")
 	"${APP_DIR}/runtime"
 )
 if(MSVC)
 	target_compile_options(RuntimeJsonTests PRIVATE /W3)
 endif()
-enable_testing()
+if(EXISTS "${NDI_RUNTIME_DLL}")
-add_test(NAME RuntimeJsonTests COMMAND RuntimeJsonTests)
+	install(FILES "${NDI_RUNTIME_DLL}"
-
+		DESTINATION "."
-add_executable(RuntimeClockTests
+	)
-	"${APP_DIR}/runtime/RuntimeClock.cpp"
+else()
-	"${CMAKE_CURRENT_SOURCE_DIR}/tests/RuntimeClockTests.cpp"
+	message(STATUS "NDI runtime DLL not found and will not be installed: ${NDI_RUNTIME_DLL}")
 )
 target_include_directories(RuntimeClockTests PRIVATE
 	"${APP_DIR}"
 	"${APP_DIR}/runtime"
 )
 if(MSVC)
 	target_compile_options(RuntimeClockTests PRIVATE /W3)
 endif()
-add_test(NAME RuntimeClockTests COMMAND RuntimeClockTests)
+if(EXISTS "${NDI_LICENSE_FILE}")
-
+	install(FILES "${NDI_LICENSE_FILE}"
-add_executable(RuntimeParameterUtilsTests
+		DESTINATION "third_party_notices"
-	"${APP_DIR}/runtime/RuntimeJson.cpp"
+		RENAME "NDI_SDK_LICENSE_AGREEMENT.pdf"
-	"${APP_DIR}/runtime/RuntimeParameterUtils.cpp"
+	)
-	"${CMAKE_CURRENT_SOURCE_DIR}/tests/RuntimeParameterUtilsTests.cpp"
+else()
-)
+	message(STATUS "NDI license file not found: ${NDI_LICENSE_FILE}")
 target_include_directories(RuntimeParameterUtilsTests PRIVATE
 	"${APP_DIR}"
 	"${APP_DIR}/runtime"
 	"${APP_DIR}/shader"
 )
 if(MSVC)
 	target_compile_options(RuntimeParameterUtilsTests PRIVATE /W3)
 endif()
-add_test(NAME RuntimeParameterUtilsTests COMMAND RuntimeParameterUtilsTests)
+if(EXISTS "${NDI_NOTICES_FILE}")
-
+	install(FILES "${NDI_NOTICES_FILE}"
-add_executable(Std140BufferTests
+		DESTINATION "third_party_notices"
-	"${CMAKE_CURRENT_SOURCE_DIR}/tests/Std140BufferTests.cpp"
+		RENAME "NDI_RUNTIME_LICENSES.txt"
-)
+	)
-
+else()
-target_include_directories(Std140BufferTests PRIVATE
+	message(STATUS "NDI runtime notices file not found: ${NDI_NOTICES_FILE}")
 	"${APP_DIR}"
 	"${APP_DIR}/gl"
 )
 if(MSVC)
 	target_compile_options(Std140BufferTests PRIVATE /W3)
 endif()
-add_test(NAME Std140BufferTests COMMAND Std140BufferTests)
+if(EXISTS "${DECKLINK_SDK_LICENSE_FILE}")
-
+	install(FILES "${DECKLINK_SDK_LICENSE_FILE}"
-add_executable(ShaderPackageRegistryTests
+		DESTINATION "third_party_notices"
-	"${APP_DIR}/runtime/RuntimeJson.cpp"
+		RENAME "BLACKMAGIC_DECKLINK_SDK_EULA.pdf"
-	"${APP_DIR}/shader/ShaderPackageRegistry.cpp"
+	)
-	"${CMAKE_CURRENT_SOURCE_DIR}/tests/ShaderPackageRegistryTests.cpp"
+else()
-)
+	message(STATUS "Blackmagic DeckLink SDK license file not found: ${DECKLINK_SDK_LICENSE_FILE}")
 target_include_directories(ShaderPackageRegistryTests PRIVATE
 	"${APP_DIR}"
 	"${APP_DIR}/runtime"
 	"${APP_DIR}/shader"
 )
 if(MSVC)
 	target_compile_options(ShaderPackageRegistryTests PRIVATE /W3)
 endif()
-add_test(NAME ShaderPackageRegistryTests COMMAND ShaderPackageRegistryTests)
+install(FILES "${CMAKE_CURRENT_SOURCE_DIR}/shaders/SHADER_CONTRACT.md"
 add_executable(OscServerTests
 	"${APP_DIR}/control/OscServer.cpp"
 	"${CMAKE_CURRENT_SOURCE_DIR}/tests/OscServerTests.cpp"
 )
 target_include_directories(OscServerTests PRIVATE
 	"${APP_DIR}"
 	"${APP_DIR}/control"
 	"${APP_DIR}/platform"
 )
 target_link_libraries(OscServerTests PRIVATE
 	Ws2_32
 )
 if(MSVC)
 	target_compile_options(OscServerTests PRIVATE /W3)
 endif()
 add_test(NAME OscServerTests COMMAND OscServerTests)
 add_executable(VideoIOFormatTests
 	"${APP_DIR}/decklink/VideoIOFormat.cpp"
 	"${CMAKE_CURRENT_SOURCE_DIR}/tests/VideoIOFormatTests.cpp"
 )
 target_include_directories(VideoIOFormatTests PRIVATE
 	"${APP_DIR}"
 	"${APP_DIR}/decklink"
 )
 if(MSVC)
 	target_compile_options(VideoIOFormatTests PRIVATE /W3)
 endif()
 add_test(NAME VideoIOFormatTests COMMAND VideoIOFormatTests)
 install(TARGETS LoopThroughWithOpenGLCompositing
 	RUNTIME DESTINATION "."
 )
 install(FILES ${SLANG_RUNTIME_FILES}
 	DESTINATION "3rdParty/slang/bin"
 )
 install(FILES "${SLANG_LICENSE_FILE}"
 	DESTINATION "third_party_notices"
 	RENAME "SLANG_LICENSE.txt"
 )
 install(FILES "${CMAKE_CURRENT_SOURCE_DIR}/SHADER_CONTRACT.md"
 	DESTINATION "."
 )
@@ -301,5 +339,3 @@ install(DIRECTORY "${CMAKE_CURRENT_SOURCE_DIR}/docs/"
 	DESTINATION "docs"
 	OPTIONAL
 )
 source_group(TREE "${APP_DIR}" FILES ${APP_SOURCES})
--- a/OSC/Test.json
+++ b/OSC/Test.json
@@ -36,7 +36,7 @@
    "preArgs": "",
    "typeTags": "",
    "decimals": 2,
-    "target": "127.0.0.1:9000",
+    "target": "192.168.1.46:9000",
    "ignoreDefaults": false,
    "bypass": false,
    "onCreate": "",
@@ -53,8 +53,8 @@
        "visible": true,
        "interaction": true,
        "comments": "XY control for Fisheye Reproject pan and tilt.",
-        "width": 420,
+        "width": 460,
-        "height": 420,
+        "height": 250,
        "expand": false,
        "colorText": "auto",
        "colorWidget": "auto",
@@ -70,14 +70,14 @@
        "css": "",
        "pips": true,
        "snap": false,
-        "spring": false,
+        "spring": true,
        "rangeX": {
-          "min": -60,
+          "min": -1,
-          "max": 60
+          "max": 1
        },
        "rangeY": {
-          "min": 45,
+          "min": 1,
-          "max": -45
+          "max": -1
        },
        "logScaleX": false,
        "logScaleY": false,
@@ -94,13 +94,13 @@
        "address": "/VideoShaderToys/fisheye-reproject/xy",
        "preArgs": "",
        "typeTags": "",
-        "decimals": "2f",
+        "decimals": "3f",
-        "target": "127.0.0.1:9000",
+        "target": "192.168.1.46:9000",
        "ignoreDefaults": false,
        "bypass": true,
-        "onCreate": "",
+        "onCreate": "var state = globalThis.__fisheyePanTiltStick = globalThis.__fisheyePanTiltStick || {};\nstate.target = '192.168.1.46:9000';\nstate.panAddress = '/VideoShaderToys/fisheye-reproject/panDegrees';\nstate.tiltAddress = '/VideoShaderToys/fisheye-reproject/tiltDegrees';\nstate.minPan = -60;\nstate.maxPan = 60;\nstate.minTilt = -45;\nstate.maxTilt = 45;\nstate.pan = 0;\nstate.tilt = 0;\nstate.stickX = 0;\nstate.stickY = 0;\nstate.tickMs = 16;\nstate.stepPan = 0.75;\nstate.stepTilt = 0.75;\nstate.deadzone = 0.14;\nstate.applyCurve = function(input) {\n  var amount = Math.abs(input);\n  if (amount <= state.deadzone) {\n    return 0;\n  }\n  var normalized = (amount - state.deadzone) / (1 - state.deadzone);\n  var softened = normalized * normalized * (3 - (2 * normalized));\n  return (input < 0 ? -1 : 1) * softened;\n};\nif (state.timer) {\n  clearInterval(state.timer);\n  state.timer = null;\n}",
-        "onValue": "var pan = Array.isArray(value) ? Number(value[0]) : 0;\nvar tilt = Array.isArray(value) ? Number(value[1]) : 0;\nsend('127.0.0.1:9000', '/VideoShaderToys/fisheye-reproject/panDegrees', {type: 'f', value: pan});\nsend('127.0.0.1:9000', '/VideoShaderToys/fisheye-reproject/tiltDegrees', {type: 'f', value: tilt});",
+        "onValue": "var state = globalThis.__fisheyePanTiltStick = globalThis.__fisheyePanTiltStick || {};\nvar stickX = Array.isArray(value) ? Number(value[0]) : 0;\nvar stickY = Array.isArray(value) ? Number(value[1]) : 0;\nstate.stickX = isFinite(stickX) ? state.applyCurve(stickX) : 0;\nstate.stickY = isFinite(stickY) ? state.applyCurve(stickY) : 0;",
-        "onTouch": "",
+        "onTouch": "var state = globalThis.__fisheyePanTiltStick = globalThis.__fisheyePanTiltStick || {};\nif (value) {\n  if (!state.timer) {\n    state.timer = setInterval(function() {\n      if (!state.stickX && !state.stickY) {\n        return;\n      }\n      state.pan = Math.max(state.minPan, Math.min(state.maxPan, state.pan + (state.stickX * state.stepPan)));\n      state.tilt = Math.max(state.minTilt, Math.min(state.maxTilt, state.tilt + (state.stickY * state.stepTilt)));\n      send(state.target, state.panAddress, {type: 'f', value: state.pan});\n      send(state.target, state.tiltAddress, {type: 'f', value: state.tilt});\n    }, state.tickMs);\n  }\n} else {\n  state.stickX = 0;\n  state.stickY = 0;\n  if (state.timer) {\n    clearInterval(state.timer);\n    state.timer = null;\n  }\n}",
        "pointSize": 20,
        "ephemeral": false,
        "label": "",
@@ -121,7 +121,7 @@
        "interaction": true,
        "comments": "",
        "width": 90,
-        "height": 420,
+        "height": 250,
        "expand": false,
        "colorText": "auto",
        "colorWidget": "auto",
@@ -144,90 +144,29 @@
        "gradient": [],
        "snap": false,
        "touchZone": "all",
-        "spring": false,
+        "spring": true,
        "doubleTap": false,
        "range": {
-          "min": 100,
+          "min": -1,
-          "max": 10
+          "max": 1
        },
        "logScale": false,
        "sensitivity": 1,
        "steps": "",
        "origin": "auto",
-        "value": "",
+        "value": 0,
-        "default": 90,
+        "default": 0,
        "linkId": "",
        "address": "/VideoShaderToys/fisheye-reproject/virtualFovDegrees",
        "preArgs": "",
        "typeTags": "",
-        "decimals": 2,
+        "decimals": "3f",
-        "target": "127.0.0.1:9000",
+        "target": "192.168.1.46:9000",
        "ignoreDefaults": false,
        "bypass": false,
        "onCreate": "",
        "onValue": "",
        "onTouch": ""
      },
      {
        "type": "xy",
        "top": 700,
        "left": 190,
        "lock": false,
        "id": "Pan Pad",
        "visible": true,
        "interaction": true,
        "comments": "",
        "width": "auto",
        "height": "auto",
        "expand": false,
        "colorText": "auto",
        "colorWidget": "auto",
        "colorStroke": "auto",
        "colorFill": "auto",
        "alphaStroke": "auto",
        "alphaFillOff": "auto",
        "alphaFillOn": "auto",
        "lineWidth": "auto",
        "borderRadius": "auto",
        "padding": "auto",
        "html": "",
        "css": "",
        "pointSize": 20,
        "ephemeral": false,
        "pips": true,
        "label": "",
        "snap": false,
        "spring": false,
        "rangeX": {
          "min": -1,
          "max": 1
        },
        "rangeY": {
          "min": -1,
          "max": 1
        },
        "logScaleX": false,
        "logScaleY": false,
        "stepsX": false,
        "stepsY": false,
        "clipX": "",
        "clipY": "",
        "axisLock": "",
        "doubleTap": false,
        "sensitivity": 1,
        "value": "",
        "default": "",
        "linkId": "",
        "address": "/VideoShaderToys/video-transform/pan",
        "preArgs": "",
        "typeTags": "",
        "decimals": 2,
        "target": "",
        "ignoreDefaults": false,
        "bypass": true,
-        "onCreate": "",
+        "onCreate": "var state = globalThis.__fisheyeFovStick = globalThis.__fisheyeFovStick || {};\nstate.target = '192.168.1.46:9000';\nstate.address = '/VideoShaderToys/fisheye-reproject/virtualFovDegrees';\nstate.minFov = 10;\nstate.maxFov = 100;\nstate.fov = 90;\nstate.stick = 0;\nstate.tickMs = 16;\nstate.stepFov = 0.6;\nstate.deadzone = 0.14;\nstate.applyCurve = function(input) {\n  var amount = Math.abs(input);\n  if (amount <= state.deadzone) {\n    return 0;\n  }\n  var normalized = (amount - state.deadzone) / (1 - state.deadzone);\n  var softened = normalized * normalized * (3 - (2 * normalized));\n  return (input < 0 ? -1 : 1) * softened;\n};\nif (state.timer) {\n  clearInterval(state.timer);\n  state.timer = null;\n}",
-        "onValue": "var x = Array.isArray(value) ? Number(value[0]) : 0;\nvar y = Array.isArray(value) ? Number(value[1]) : 0;\nsend('127.0.0.1:9000', '/VideoShaderToys/video-transform/pan', {type: 'f', value: x}, {type: 'f', value: y});",
+        "onValue": "var state = globalThis.__fisheyeFovStick = globalThis.__fisheyeFovStick || {};\nvar stick = Number(value);\nstate.stick = isFinite(stick) ? state.applyCurve(stick) : 0;",
-        "onTouch": ""
+        "onTouch": "var state = globalThis.__fisheyeFovStick = globalThis.__fisheyeFovStick || {};\nif (value) {\n  if (!state.timer) {\n    state.timer = setInterval(function() {\n      if (!state.stick) {\n        return;\n      }\n      state.fov = Math.max(state.minFov, Math.min(state.maxFov, state.fov - (state.stick * state.stepFov)));\n      send(state.target, state.address, {type: 'f', value: state.fov});\n    }, state.tickMs);\n  }\n} else {\n  state.stick = 0;\n  if (state.timer) {\n    clearInterval(state.timer);\n    state.timer = null;\n  }\n}"
      }
    ],
    "tabs": []
--- a/README.md
+++ b/README.md
@@ -1,47 +1,118 @@
 # Video Shader
-Native video shader host with an OpenGL/DeckLink render path, Slang shader packages, and a local React control UI.
+Native video shader host with an OpenGL render path, pluggable video I/O boundary, DeckLink and NDI backends, Slang shader packages, and a local React control UI.
-The app loads shader packages from `shaders/`, compiles Slang to GLSL at runtime, renders a configurable layer stack, and exposes a browser-based control surface over a local HTTP/WebSocket server.
+The app loads shader packages from `shaders/`, compiles Slang to GLSL at runtime, renders a configurable layer stack, and exposes a browser-based control surface over a local HTTP/WebSocket server. Shader compilation is prepared off the frame path where possible, then committed on the render thread so editing shader files does not block video output for the whole compile.
 ## Repository Layout
- `apps/LoopThroughWithOpenGLCompositing/`: native C++ host app.
+- `src/`: native C++ host app.
 - `shaders/`: shader packages, each with `shader.json` and `shader.slang`.
 - `ui/`: Vite/React control UI.
 - `config/runtime-host.json`: runtime configuration.
 - `runtime/templates/`: tracked shader wrapper templates.
 - `runtime/`: ignored generated runtime cache/state output. See `runtime/README.md`.
 - `tests/`: focused native tests for pure runtime logic.
 - `docs/CURRENT_SYSTEM_ARCHITECTURE.md`: current architecture notes for the cadence/video I/O host.
 - `docs/RENDER_CADENCE_GOLDEN_RULES.md`: guardrails for changes that touch render cadence, runtime work, and video I/O.
 - `.gitea/workflows/ci.yml`: Gitea Actions CI for Windows native tests and Ubuntu UI build.
 Native app internals are grouped by boundary:
 - `app/`: startup/shutdown orchestration, runtime-content controller boundary, config, preview, telemetry, and HTTP hookup.
 - `control/`: HTTP/WebSocket server, command parsing, and runtime-state JSON presentation.
 - `frames/`: system-memory frame exchange and input mailbox handoff.
 - `render/`: render thread, readback, runtime render scene, and shared-context shader program preparation.
 - `runtime/`: shader catalog support, layer model, Slang build bridge, font atlas build, and runtime-state persistence.
 - `shader/`: shader package parsing and Slang compilation helpers.
 - `video/core/`: backend-neutral video IO handoff contracts, mode descriptions, pixel formats, and output scheduling thread.
 - `video/decklink/`: DeckLink input/output backend.
 - `video/ndi/`: NDI input/output backend.
 - `video/playout/`: backend-adjacent playout policy, queues, frame pools, and scheduling helpers.
 - `video/legacy/`: older backend pipeline pieces kept separate while the new edge model settles.
 The runtime shader stack is plugged into the host through `src/app/RuntimeContentController.h`. The checked-in app wires `ShaderRuntimeContentController` into that slot; a fork can provide another runtime-content controller for a larger render engine while keeping the cadence/video I/O shell.
 ## Requirements
 - Windows with Visual Studio 2022 C++ tooling.
 - CMake 3.24 or newer.
 - Node.js and npm for the control UI.
- Blackmagic Desktop Video drivers and a DeckLink device.
+- Blackmagic Desktop Video drivers and a DeckLink device for the current production video I/O backend.
- Slang binary release with `slangc.exe`, `slang-compiler.dll`, `slang-glslang.dll`, and `LICENSE`.
+- Blackmagic DeckLink SDK 16.0 for DeckLink SDK reference files and redistribution notices.
 - NDI 6 SDK for NDI input/output builds. CMake expects `Include/`, `Lib/x64/Processing.NDI.Lib.x64.lib`, `Bin/x64/Processing.NDI.Lib.x64.dll`, and the NDI license/notice files.
 - Slang 2026.8 Windows x86_64 binary release with `bin/slangc.exe`, `bin/slang-compiler.dll`, `bin/slang-glslang.dll`, and `LICENSE`.
 - `msdf-atlas-gen` Windows binary release with `msdf-atlas-gen.exe`, `LICENSE.txt`, `README.md`, and any adjacent runtime DLLs for font atlas generation.
-Default expected Slang path:
+### Third-party SDK bundle
 Org members can initialize the private SDK bundle submodule:
 ```powershell
 git submodule update --init --recursive
 ```
 When present, CMake defaults to this private bundle:
 ```text
 video-io-3rdParty/
  Blackmagic DeckLink SDK 16.0/
  NDI 6 SDK/
  slang-2026.8-windows-x86_64/
  msdf-atlas-gen/
 ```
 The parent repository is public, but this bundle is private. External builders need to obtain the SDKs from their vendors and place them in an ignored local `3rdParty/` folder with the same layout, or pass explicit CMake paths.
 Fallback local Slang path:
 ```text
 3rdParty/slang-2026.8-windows-x86_64
 ```
-Override example:
+Fallback local `msdf-atlas-gen` path:
 ```text
 3rdParty/msdf-atlas-gen
 ```
 Fallback local NDI SDK path:
 ```text
 3rdParty/NDI 6 SDK
 ```
 Fallback local Blackmagic DeckLink SDK path:
 ```text
 3rdParty/Blackmagic DeckLink SDK 16.0
 ```
 Single-root override example:
 ```powershell
-cmake --preset vs2022-x64-debug -DSLANG_ROOT="D:/SDKs/slang-2026.8-windows-x86_64"
+cmake --preset vs2022-x64-debug -DTHIRD_PARTY_ROOT="D:/SDKs/video-io-3rdParty"
 ```
 Individual override example:
 ```powershell
 cmake --preset vs2022-x64-debug `
  -DSLANG_ROOT="D:/SDKs/slang-2026.8-windows-x86_64" `
  -DMSDF_ATLAS_GEN_ROOT="D:/SDKs/msdf-atlas-gen" `
  -DNDI_SDK_ROOT="D:/SDKs/NDI 6 SDK" `
  -DDECKLINK_SDK_ROOT="D:/SDKs/Blackmagic DeckLink SDK 16.0"
 ```
 At runtime, Slang compilation follows the same root order: `SLANG_ROOT`, `THIRD_PARTY_ROOT`, repo `video-io-3rdParty/`, then repo or packaged `3rdParty/`. The packaged layout uses `3rdParty/slang/bin/slangc.exe`; development bundles can use `slang-2026.8-windows-x86_64/bin/slangc.exe`.
 ## Build
 Configure and build the native app:
 ```powershell
 cmake --preset vs2022-x64-debug
-cmake --build --preset build-debug
+cmake --build --preset build-debug --parallel
 ```
 Build the React control UI:
@@ -54,6 +125,15 @@ npm run build
 The native app serves `ui/dist` when it exists, otherwise it falls back to the source UI directory during development.
 The control UI provides:
 - A searchable shader library for adding layers.
 - Compact parameter rows with inline descriptions and intended OSC route copy controls.
 - Shader-declared custom Web Component control panels with default-control fallback.
 - Manual shader reload.
 - Host config editing, save, restart request, and NDI input source discovery.
 - Compact video I/O and render cadence status.
 ## Package
 Build the UI, build the native Release target, then install into a portable runtime folder:
@@ -64,7 +144,7 @@ npm ci
 npm run build
 cd ..
 cmake --preset vs2022-x64-release
-cmake --build --preset build-release
+cmake --build --preset build-release --parallel
 cmake --install build/vs2022-x64-release --config Release --prefix dist/VideoShader
 ```
@@ -72,18 +152,22 @@ The package folder will contain:
 ```text
 dist/VideoShader/
-  LoopThroughWithOpenGLCompositing.exe
+  RenderCadenceCompositor.exe
  Processing.NDI.Lib.x64.dll
  config/
  shaders/
  3rdParty/slang/bin/
  3rdParty/msdf-atlas-gen/
  ui/dist/
  docs/
  SHADER_CONTRACT.md
  runtime/templates/
  third_party_notices/
 ```
-You can run `LoopThroughWithOpenGLCompositing.exe` directly from that folder. In packaged mode, the app resolves `config/`, `shaders/`, `3rdParty/slang/bin/slangc.exe`, `ui/dist/`, and `runtime/templates/` relative to the exe folder. In development mode, it still falls back to repo-root discovery.
+You can run `RenderCadenceCompositor.exe` directly from that folder. In packaged mode, the app resolves `config/`, `shaders/`, `3rdParty/slang/bin/slangc.exe`, `3rdParty/msdf-atlas-gen/msdf-atlas-gen.exe`, `Processing.NDI.Lib.x64.dll`, `ui/dist/`, and `runtime/templates/` relative to the exe folder. In development mode, it still falls back to repo-root discovery.
-The install step copies only the Slang runtime files required by the shader compiler (`slangc.exe`, `slang-compiler.dll`, and `slang-glslang.dll`) plus `third_party_notices/SLANG_LICENSE.txt`. It does not copy the full Slang release folder.
+The install step copies only the Slang runtime files required by the shader compiler (`slangc.exe`, `slang-compiler.dll`, and `slang-glslang.dll`) plus `third_party_notices/SLANG_LICENSE.txt`. It also copies `msdf-atlas-gen.exe`, any adjacent `msdf-atlas-gen` DLLs, `Processing.NDI.Lib.x64.dll`, and the `third_party_notices/MSDF_ATLAS_GEN_LICENSE.txt`, `third_party_notices/MSDF_ATLAS_GEN_README.md`, `third_party_notices/NDI_SDK_LICENSE_AGREEMENT.pdf`, and `third_party_notices/NDI_RUNTIME_LICENSES.txt` notice files. It does not copy full third-party release folders.
 Create a zip for distribution:
@@ -96,7 +180,7 @@ Compress-Archive -Path dist/VideoShader/* -DestinationPath dist/VideoShader.zip
 Run native tests:
 ```powershell
-cmake --build --preset build-debug --target RUN_TESTS
+cmake --build --preset build-debug --target RUN_TESTS --parallel
 ```
 Run the UI production build check:
@@ -111,6 +195,8 @@ Current native test coverage includes:
 - JSON parsing and serialization.
 - Parameter normalization and preset filename safety.
 - Shader manifest parsing, temporal manifest validation, and package registry scanning.
 - Video I/O format helpers, v210/Ay10 row-byte math, v210 pack/unpack math, playout scheduler timing, and fake backend contract coverage.
 - Slang validation for every available shader package.
 ## Runtime Configuration
@@ -120,20 +206,39 @@ Current native test coverage includes:
 {
  "shaderLibrary": "shaders",
  "serverPort": 8080,
  "oscBindAddress": "127.0.0.1",
  "oscPort": 9000,
-  "inputVideoFormat": "1080p",
+  "oscSmoothing": 0.18,
-  "inputFrameRate": "59.94",
+  "runtimeShaderId": "",
-  "outputVideoFormat": "1080p",
+  "input": {
-  "outputFrameRate": "59.94",
+    "backend": "decklink",
    "device": "default",
    "resolution": "1080p",
    "frameRate": "59.94"
  },
  "output": {
    "backend": "decklink",
    "device": "default",
    "resolution": "1080p",
    "frameRate": "59.94",
    "pixelFormat": "auto",
    "keying": {
      "external": false,
      "alphaRequired": false
    }
  },
  "autoReload": true,
  "maxTemporalHistoryFrames": 12,
-  "enableExternalKeying": true
+  "previewEnabled": false,
  "previewFps": 59.94
 }
 ```
-`inputVideoFormat`/`inputFrameRate` select the DeckLink capture mode. `outputVideoFormat`/`outputFrameRate` select the playout mode. The shader stack runs at input resolution and the final rendered frame is scaled once into the configured output mode. Common examples include `720p`/`50`, `720p`/`59.94`, `1080i`/`50`, `1080i`/`59.94`, `1080p`/`25`, `1080p`/`50`, `1080p`/`59.94`, and `2160p`/`59.94`, depending on card support.
+`input.backend` and `output.backend` select the concrete video I/O backend. Today the app supports `decklink`, `ndi`, and `none`; future backends such as Spout or file playback can be added behind the same factory boundary. `device` is a backend-neutral selector placeholder: DeckLink still chooses the first compatible device, NDI input uses it as the source selector, and NDI output uses it as the sender name.
-Legacy `videoFormat` and `frameRate` keys are still accepted and apply to both input and output unless the explicit input/output keys are present.
+`input.resolution`/`input.frameRate` select the video capture mode. `output.resolution`/`output.frameRate` select the playout mode through a backend-neutral mode description; the current DeckLink backend maps that mode to a `BMDDisplayMode` at the DeckLink boundary. Supported modes still depend on the installed card and driver. The shader stack runs at input resolution and the final rendered frame is scaled once into the configured output mode. Common examples include `720p`/`50`, `720p`/`59.94`, `1080i`/`50`, `1080i`/`59.94`, `1080p`/`25`, `1080p`/`50`, `1080p`/`59.94`, and `2160p`/`59.94`.
 The checked-in config uses the nested `input` and `output` objects as the supported shape. When `input.backend` is `ndi`, the host-config editor uses NDI discovery to offer source-name suggestions in the `input.device` field while still allowing manual entry. The control UI presents `output.keying.external` and `output.keying.alphaRequired` as one **Output alpha** control; DeckLink maps that to external keying, while NDI only uses it to request an alpha-carrying system-frame format.
 The control UI is available at:
@@ -141,11 +246,43 @@ The control UI is available at:
 http://127.0.0.1:<serverPort>
 ```
-## Runtime State And Presets
+`/api/state` exposes backend-neutral output telemetry in `videoOutput`. Use `videoOutput.enabled`, `videoOutput.backend`, and `videoOutput.scheduleFailures` for portable status. Backend-specific counters live in `videoOutput.backendMetrics`.
-The current layer stack is autosaved to `runtime/runtime_state.json` whenever layers, shader assignments, bypass state, ordering, or parameter values change. On startup, the host reloads that file before compiling the stack, so the last working stack should come back automatically.
+### Borderless Window / Fullscreen Output Plan
-Manual stack presets are still available from the control UI and are saved under `runtime/stack_presets/*.json`. Presets are useful for named looks, while `runtime_state.json` is the latest working state for the local machine.
+The preview window is a best-effort diagnostic view and is allowed to drop or reuse frames without disturbing cadence. A borderless window or fullscreen display output should be implemented as a real `output.backend`, separate from preview, so it can target full configured resolution and frame rate.
 Rough plan:
 - Add a `window` video output backend behind the existing `IVideoOutput` factory, selectable with `"output": { "backend": "window", ... }`.
 - Give it its own device/display selection, fullscreen/borderless mode, window position, vsync policy, and optional monitor refresh validation in `runtime-host.json`.
 - Consume `SystemFrameExchange` frames like the other output backends, on an output-owned thread, without blocking the render thread.
 - Upload/present frames through a dedicated GL/DX window context or shared-context path, with a bounded mailbox so late window presentation never back-pressures render cadence.
 - Report backend-neutral telemetry through `videoOutput` and put display/window-specific details under `videoOutput.backendMetrics`.
 - Keep the existing preview window as an operator confidence monitor only, not as the full-quality display output path.
 ### OCIO / Linear 16-Bit Float Pipeline Plan
 The render backend should move toward a true linear-light `RGBA16F` pipeline, with OpenColorIO used for explicit color transforms at the video I/O and display edges. Shader packages should be able to assume a stable working space instead of guessing whether input pixels are display-referred, log, Rec.709, HDR, or already linear.
 Rough plan:
 - Add OCIO as an optional third-party dependency and package its required runtime DLLs, config files, and license notices with Release builds.
 - Extend `runtime-host.json` with color settings for input, working, output, and preview/display transforms, including OCIO config path, input color space, working color space, output color space, view, look, exposure, and gamma.
 - Convert captured/input frames into the configured linear working space before shader layers sample them.
 - Allocate runtime render targets, temporal history, feedback buffers, and intermediate layer buffers as `RGBA16F` by default, with explicit fallbacks for unsupported hardware.
 - Keep shader parameter uploads and texture assets explicit about color intent: data textures stay data, image/video textures can opt into OCIO or known transfer conversion.
 - Apply the output transform only at backend edges: DeckLink/NDI/window output, screenshots, and preview each get the correct display/output transform for their target.
 - Prebuild OCIO GPU shader/lut resources off the render thread and commit prepared resources to the render thread only when ready, following the render cadence golden rules.
 - Add test coverage for config parsing, color-pipeline defaults, fallback behavior, and shader/runtime state reporting.
 ## Runtime State
 The current layer stack is autosaved to `runtime/runtime_state.json` whenever durable UI/API layer changes are accepted: add/remove, shader assignment, bypass state, ordering, parameter updates, parameter reset, and reload compatibility refreshes. Saves are debounced and written on a background worker, with a final flush during shutdown.
 On startup, the host tries to reload `runtime/runtime_state.json` before compiling the stack. Valid saved layers are rebuilt in saved order, with shader id, bypass state, and parameter values restored. Missing shader packages are skipped, invalid saved parameter values fall back to shader defaults, and if the file is missing or unusable the app falls back to the optional configured startup shader. The checked-in config leaves `runtimeShaderId` empty, so a fresh host uses the simple fallback renderer until layers are added or a saved stack exists.
 Manual stack preset and screenshot routes are still present in the UI/OpenAPI surface, but they are not implemented by the current native command path yet. `runtime_state.json` is the supported latest-working-state mechanism for now.
 ## Control API
@@ -168,9 +305,15 @@ A Swagger UI page is available at:
 http://127.0.0.1:<serverPort>/docs
 ```
-Use those docs to inspect the `/api/state`, layer control, stack preset, and reload endpoints. Live state updates are also sent over the `/ws` WebSocket.
+Use those docs to inspect the `/api/state`, layer control, and reload endpoints. Live state updates are also sent over the `/ws` WebSocket.
-The control UI also has a Screenshot button. It queues a capture of the final output render target and writes a PNG under:
+The control UI has a **Reload shaders** button. It rescans `shaders/`, re-reads manifests, refreshes shader availability/errors, updates active layer parameter definitions from changed manifests, and queues recompilation for every catalog-valid layer in the active stack. Missing shader packages are marked failed, and the previous working render stack remains active where possible until replacement builds commit successfully.
 Each parameter row still exposes the intended OSC route in the UI. The native host has an OSC service stub that reports the configured bind/port in state, but it does not open a UDP listener or dispatch OSC messages yet.
 The control UI currently still shows preset and screenshot controls from the intended route surface. Those endpoints return an unimplemented action result in the native host until their backend paths are wired.
 The reserved screenshot output directory is:
 ```text
 runtime/screenshots/
@@ -178,13 +321,15 @@ runtime/screenshots/
 ## OSC Control
-The native host also listens for local OSC parameter control on the configured `oscPort`:
+OSC fields are present in `config/runtime-host.json` and `/api/state` for compatibility with the intended control surface, but the current native host does not start an OSC listener yet.
 The intended route shape is:
 ```text
 /VideoShaderToys/{LayerNameOrID}/{ParameterNameOrID}
 ```
-For example, `/VideoShaderToys/VHS/intensity` updates the `intensity` parameter on the first matching `VHS` layer. The listener accepts float, integer, string, and boolean OSC values, and validates them through the same shader parameter path as the REST API. See `docs/OSC_CONTROL.md` for details.
+For now, use the REST layer parameter endpoints or the control UI for live parameter changes. Future OSC-driven parameter changes should stay out of autosave unless an explicit persistence policy is added.
 ## Shader Packages
@@ -194,10 +339,23 @@ Each shader package lives under:
 shaders/<id>/
  shader.json
  shader.slang
  optional-extra-pass.slang
  optional-font-or-texture-assets
 ```
-See `SHADER_CONTRACT.md` for the manifest schema, parameter types, texture assets, font/text assets, temporal history support, and the Slang entry point contract. `shaders/text-overlay/` is the reference live text package and bundles Roboto Regular with its OFL license.
+See `SHADER_CONTRACT.md` for the manifest schema, parameter types, texture assets, font/text assets, temporal history support, optional render-pass declarations, optional custom UI metadata, and the Slang entry point contract. `shaders/text-overlay/` is the reference live text package and bundles Roboto Regular with its OFL license. Broken shader packages are shown as unavailable in the selector with their error text instead of preventing the app from launching.
 Shader packages can optionally declare a custom control panel:
 ```json
 "ui": {
  "type": "webComponent",
  "entry": "ui/controls.js",
  "tag": "my-shader-controls"
 }
 ```
 The host validates that metadata, exposes it in `/api/state`, and serves the module from `/shader-assets/{shaderId}/...`. Custom controls receive the current layer, declared parameters, `setParameter(id, value)`, and `requestReset()`. They still update the same manifest-declared parameters as the default React controls.
 ## Generated Files
@@ -207,7 +365,8 @@ Runtime-generated files are intentionally ignored:
 - `runtime/shader_cache/active_shader.raw.frag`
 - `runtime/shader_cache/active_shader.frag`
 - `runtime/runtime_state.json` autosaved latest stack and parameter state.
- `runtime/stack_presets/*.json`
+- `runtime/stack_presets/*.json` reserved manual preset output; preset routes are not implemented in the native host yet.
 - `runtime/screenshots/*.png` reserved screenshot output; screenshot capture is not implemented in the native host yet.
 Only `runtime/templates/` and `runtime/README.md` are tracked.
@@ -220,7 +379,11 @@ The Gitea workflow expects two act runners:
 The Windows jobs validate native third-party dependencies before configuring CMake. Because `3rdParty/` is ignored, configure this path on the runner or in a Gitea repository variable:
 - `THIRD_PARTY_ROOT`: path to a bundle containing the expected SDK folder layout.
 - `SLANG_ROOT`: path to the Slang binary release folder containing `bin/slangc.exe`.
 - `MSDF_ATLAS_GEN_ROOT`: path to the `msdf-atlas-gen` binary release folder containing `msdf-atlas-gen.exe`.
 - `NDI_SDK_ROOT`: path to the NDI SDK folder containing `Include/`, `Lib/x64/`, and `Bin/x64/`.
 - `DECKLINK_SDK_ROOT`: path to the Blackmagic DeckLink SDK folder containing `Win/include/DeckLinkAPI.idl`.
 The Windows runner also needs the Visual Studio ATL component installed. In Visual Studio Build Tools 2022, add `C++ ATL for latest v143 build tools (x86 & x64)`, component ID `Microsoft.VisualStudio.Component.VC.ATL`.
@@ -228,24 +391,28 @@ Example runner paths:
 ```text
 D:\SDKs\slang-2026.8-windows-x86_64
 D:\SDKs\msdf-atlas-gen
 D:\SDKs\NDI 6 SDK
 D:\SDKs\Blackmagic DeckLink SDK 16.0
 ```
-If `SLANG_ROOT` is not set, the workflow falls back to the repo-local default under `3rdParty/`.
+If these variables are not set, CMake first looks under the private `video-io-3rdParty/` submodule and then falls back to repo-local defaults under ignored `3rdParty/`.
 ## Still Todo
 - Audio.
 - Genlock.
 - Find a better UI library for react.
 - Logs.
 - Continue source cleanup/refactoring. Pass 2 done
 - Support a separate sound shader `.slang` file in shader packages. (https://www.shadertoy.com/view/XsBXWt)
- Add WebView2
+- Add WebView2 for an embedded native control surface.
- move to MSDF, typography rasterisation
+- More shader-library organisation and filtering as the built-in library grows.
- better shader search UI, pass 1
+- Optional linear-light compositing mode.
- More comprehensive greenscreen shader
+- compute shaders or a small 1x1 or nx1 RGBA16f render target for arbitrary data storage
 - linear compositing?
 - compute shaders or a small 1x1 or nx1 RGBA16f render target for abritary data store
 - allow shaders to read other shaders data store based on name? or output over OSC
- Mipmappong for shader declared textures
+- Mipmapping for shader-declared textures
- unwrap a fish eyelens and mirror it and map it to equirectangulr for environmnet map purposes
+- Anotate included shaders
 - allow 3 vector exposed controls
 - add nearest sampling to the extra shader pass
 - Add Aja input and output (Assuming i can get a hold of an aja card)
 - Add bluefish input and output (Assuming again card acess)
 - Endpoint to show OSC paths seperatly instead of a part of the control UI
--- a/apps/LoopThroughWithOpenGLCompositing/LoopThroughWithOpenGLCompositing.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/LoopThroughWithOpenGLCompositing.cpp
@@ -1,589 +0,0 @@
 /* -LICENSE-START-
 ** Copyright (c) 2012 Blackmagic Design
 **  
 ** Permission is hereby granted, free of charge, to any person or organization 
 ** obtaining a copy of the software and accompanying documentation (the 
 ** "Software") to use, reproduce, display, distribute, sub-license, execute, 
 ** and transmit the Software, and to prepare derivative works of the Software, 
 ** and to permit third-parties to whom the Software is furnished to do so, in 
 ** accordance with:
 ** 
 ** (1) if the Software is obtained from Blackmagic Design, the End User License 
 ** Agreement for the Software Development Kit ("EULA") available at 
 ** https://www.blackmagicdesign.com/EULA/DeckLinkSDK; or
 ** 
 ** (2) if the Software is obtained from any third party, such licensing terms 
 ** as notified by that third party,
 ** 
 ** and all subject to the following:
 ** 
 ** (3) the copyright notices in the Software and this entire statement, 
 ** including the above license grant, this restriction and the following 
 ** disclaimer, must be included in all copies of the Software, in whole or in 
 ** part, and all derivative works of the Software, unless such copies or 
 ** derivative works are solely in the form of machine-executable object code 
 ** generated by a source language processor.
 ** 
 ** (4) THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS 
 ** OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, 
 ** FITNESS FOR A PARTICULAR PURPOSE, TITLE AND NON-INFRINGEMENT. IN NO EVENT 
 ** SHALL THE COPYRIGHT HOLDERS OR ANYONE DISTRIBUTING THE SOFTWARE BE LIABLE 
 ** FOR ANY DAMAGES OR OTHER LIABILITY, WHETHER IN CONTRACT, TORT OR OTHERWISE, 
 ** ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER 
 ** DEALINGS IN THE SOFTWARE.
 ** 
 ** A copy of the Software is available free of charge at 
 ** https://www.blackmagicdesign.com/desktopvideo_sdk under the EULA.
 ** 
 ** -LICENSE-END-
 */
 //
 // LoopThroughWithOpenGLCompositing.cpp
 // LoopThroughWithOpenGLCompositing
 //
 #include "stdafx.h"
 #include "resource.h"
 #include "OpenGLComposite.h"
 #include <algorithm>
 #include <shellapi.h>
 #include <string>
 #ifndef WGL_CONTEXT_MAJOR_VERSION_ARB
 #define WGL_CONTEXT_MAJOR_VERSION_ARB 0x2091
 #endif
 #ifndef WGL_CONTEXT_MINOR_VERSION_ARB
 #define WGL_CONTEXT_MINOR_VERSION_ARB 0x2092
 #endif
 #ifndef WGL_CONTEXT_PROFILE_MASK_ARB
 #define WGL_CONTEXT_PROFILE_MASK_ARB 0x9126
 #endif
 #ifndef WGL_CONTEXT_CORE_PROFILE_BIT_ARB
 #define WGL_CONTEXT_CORE_PROFILE_BIT_ARB 0x00000001
 #endif
 #define MAX_LOADSTRING 100
 // Declaration for Window procedure
 LRESULT CALLBACK WndProc(HWND hWnd, UINT message, WPARAM wParam, LPARAM lParam);
 typedef HGLRC (WINAPI* PFNWGLCREATECONTEXTATTRIBSARBPROC)(HDC hdc, HGLRC hShareContext, const int* attribList);
 namespace
 {
 const int kStatusPanelWidth = 680;
 const int kStatusPanelHeight = 92;
 const int kStatusPadding = 8;
 const int kStatusLabelWidth = 58;
 const int kStatusButtonWidth = 86;
 const int kStatusRowHeight = 24;
 const int kStatusGap = 6;
 const UINT kCreateStatusStripMessage = WM_APP + 1;
 enum StatusControlId
 {
 	kControlUrlEditId = 2001,
 	kDocsUrlEditId = 2002,
 	kOscAddressEditId = 2003,
 	kOpenControlButtonId = 2004,
 	kOpenDocsButtonId = 2005
 };
 struct StatusStripControls
 {
 	HWND panel = NULL;
 	HWND controlLabel = NULL;
 	HWND controlUrl = NULL;
 	HWND openControl = NULL;
 	HWND docsLabel = NULL;
 	HWND docsUrl = NULL;
 	HWND openDocs = NULL;
 	HWND oscLabel = NULL;
 	HWND oscAddress = NULL;
 };
 bool StatusStripCreated(const StatusStripControls& controls)
 {
 	return controls.panel != NULL;
 }
 HWND CreateStatusChild(HWND parent, const char* className, const char* text, DWORD style, DWORD exStyle, int controlId)
 {
 	return CreateWindowExA(
 		exStyle,
 		className,
 		text,
 		WS_CHILD | WS_VISIBLE | WS_CLIPSIBLINGS | style,
 		0,
 		0,
 		0,
 		0,
 		parent,
 		reinterpret_cast<HMENU>(static_cast<INT_PTR>(controlId)),
 		reinterpret_cast<HINSTANCE>(GetWindowLongPtr(parent, GWLP_HINSTANCE)),
 		NULL);
 }
 void CreateStatusStrip(HWND hWnd, StatusStripControls& controls)
 {
 	controls.panel = CreateStatusChild(hWnd, "STATIC", "", SS_LEFT, WS_EX_CLIENTEDGE, 0);
 	controls.controlLabel = CreateStatusChild(hWnd, "STATIC", "Control", SS_LEFT, 0, 0);
 	controls.controlUrl = CreateStatusChild(hWnd, "EDIT", "", ES_AUTOHSCROLL | ES_READONLY | WS_TABSTOP, WS_EX_CLIENTEDGE, kControlUrlEditId);
 	controls.openControl = CreateStatusChild(hWnd, "BUTTON", "Open", BS_PUSHBUTTON | WS_TABSTOP, 0, kOpenControlButtonId);
 	controls.docsLabel = CreateStatusChild(hWnd, "STATIC", "Docs", SS_LEFT, 0, 0);
 	controls.docsUrl = CreateStatusChild(hWnd, "EDIT", "", ES_AUTOHSCROLL | ES_READONLY | WS_TABSTOP, WS_EX_CLIENTEDGE, kDocsUrlEditId);
 	controls.openDocs = CreateStatusChild(hWnd, "BUTTON", "Open", BS_PUSHBUTTON | WS_TABSTOP, 0, kOpenDocsButtonId);
 	controls.oscLabel = CreateStatusChild(hWnd, "STATIC", "OSC", SS_LEFT, 0, 0);
 	controls.oscAddress = CreateStatusChild(hWnd, "EDIT", "", ES_AUTOHSCROLL | ES_READONLY | WS_TABSTOP, WS_EX_CLIENTEDGE, kOscAddressEditId);
 	HFONT guiFont = reinterpret_cast<HFONT>(GetStockObject(DEFAULT_GUI_FONT));
 	HWND children[] = {
 		controls.controlLabel,
 		controls.controlUrl,
 		controls.openControl,
 		controls.docsLabel,
 		controls.docsUrl,
 		controls.openDocs,
 		controls.oscLabel,
 		controls.oscAddress
 	};
 	for (HWND child : children)
 	{
 		if (child)
 			SendMessage(child, WM_SETFONT, reinterpret_cast<WPARAM>(guiFont), TRUE);
 	}
 	SetWindowTextA(controls.controlUrl, "Starting control server...");
 	SetWindowTextA(controls.docsUrl, "Starting API docs...");
 	SetWindowTextA(controls.oscAddress, "Starting OSC listener...");
 }
 void RaiseStatusControls(const StatusStripControls& controls)
 {
 	if (!StatusStripCreated(controls))
 		return;
 	SetWindowPos(controls.panel, HWND_BOTTOM, 0, 0, 0, 0, SWP_NOMOVE | SWP_NOSIZE | SWP_NOACTIVATE);
 	HWND interactiveControls[] = {
 		controls.controlLabel,
 		controls.controlUrl,
 		controls.openControl,
 		controls.docsLabel,
 		controls.docsUrl,
 		controls.openDocs,
 		controls.oscLabel,
 		controls.oscAddress
 	};
 	for (HWND control : interactiveControls)
 	{
 		if (control)
 			SetWindowPos(control, HWND_TOP, 0, 0, 0, 0, SWP_NOMOVE | SWP_NOSIZE | SWP_NOACTIVATE);
 	}
 }
 void LayoutStatusStrip(HWND hWnd, const StatusStripControls& controls)
 {
 	RECT clientRect = {};
 	if (!GetClientRect(hWnd, &clientRect) || !controls.panel)
 		return;
 	const int clientWidth = static_cast<int>(clientRect.right - clientRect.left);
 	const int clientHeight = static_cast<int>(clientRect.bottom - clientRect.top);
 	const int panelWidth = std::max(280, std::min(kStatusPanelWidth, clientWidth - (kStatusPadding * 2)));
 	const int panelHeight = kStatusPanelHeight;
 	const int panelLeft = kStatusPadding;
 	const int panelTop = std::max(kStatusPadding, clientHeight - panelHeight - kStatusPadding);
 	MoveWindow(controls.panel, panelLeft, panelTop, panelWidth, panelHeight, TRUE);
 	const int rowX = panelLeft + kStatusPadding;
 	const int editX = rowX + kStatusLabelWidth + kStatusGap;
 	const int buttonX = panelLeft + panelWidth - kStatusPadding - kStatusButtonWidth;
 	const int editWidth = std::max(80, buttonX - editX - kStatusGap);
 	const int oscWidth = std::max(80, panelLeft + panelWidth - editX - kStatusPadding);
 	const int row1 = panelTop + kStatusPadding;
 	const int row2 = row1 + kStatusRowHeight + kStatusGap;
 	const int row3 = row2 + kStatusRowHeight + kStatusGap;
 	MoveWindow(controls.controlLabel, rowX, row1 + 3, kStatusLabelWidth, kStatusRowHeight, TRUE);
 	MoveWindow(controls.controlUrl, editX, row1, editWidth, kStatusRowHeight, TRUE);
 	MoveWindow(controls.openControl, buttonX, row1, kStatusButtonWidth, kStatusRowHeight, TRUE);
 	MoveWindow(controls.docsLabel, rowX, row2 + 3, kStatusLabelWidth, kStatusRowHeight, TRUE);
 	MoveWindow(controls.docsUrl, editX, row2, editWidth, kStatusRowHeight, TRUE);
 	MoveWindow(controls.openDocs, buttonX, row2, kStatusButtonWidth, kStatusRowHeight, TRUE);
 	MoveWindow(controls.oscLabel, rowX, row3 + 3, kStatusLabelWidth, kStatusRowHeight, TRUE);
 	MoveWindow(controls.oscAddress, editX, row3, oscWidth, kStatusRowHeight, TRUE);
 	RaiseStatusControls(controls);
 }
 void UpdateStatusStrip(const StatusStripControls& controls, const OpenGLComposite& composite)
 {
 	if (!StatusStripCreated(controls))
 		return;
 	SetWindowTextA(controls.controlUrl, composite.GetControlUrl().c_str());
 	SetWindowTextA(controls.docsUrl, composite.GetDocsUrl().c_str());
 	SetWindowTextA(controls.oscAddress, composite.GetOscAddress().c_str());
 }
 void OpenUrl(const char* url)
 {
 	ShellExecuteA(NULL, "open", url, NULL, NULL, SW_SHOWNORMAL);
 }
 }
 void ShowUnhandledExceptionMessage(const char* prefix)
 {
 	try
 	{
 		throw;
 	}
 	catch (const std::exception& exception)
 	{
 		std::string message = std::string(prefix) + "\n\n" + exception.what();
 		MessageBoxA(NULL, message.c_str(), "Unhandled exception", MB_OK | MB_ICONERROR);
 	}
 	catch (...)
 	{
 		MessageBoxA(NULL, prefix, "Unhandled exception", MB_OK | MB_ICONERROR);
 	}
 }
 // Select the pixel format for a given device context
 void SetDCPixelFormat(HDC hDC)
 {
 	int nPixelFormat;
 	static PIXELFORMATDESCRIPTOR pfd = {
 		sizeof(PIXELFORMATDESCRIPTOR),	// Size of this structure
 		1,								// Version of this structure
 		PFD_DRAW_TO_WINDOW |			// Draw to Window (not to bitmap)
 		PFD_SUPPORT_OPENGL |			// Support OpenGL calls in window
 		PFD_DOUBLEBUFFER,				// Double buffered mode
 		PFD_TYPE_RGBA,					// RGBA Color mode
 		32,								// Want 32 bit color
 		0,0,0,0,0,0,					// Not used to select mode
 		0,0,							// Not used to select mode
 		0,0,0,0,0,						// Not used to select mode
 		16,								// Size of depth buffer
 		0,								// Not used
 		0,								// Not used
 		0,								// Not used
 		0,								// Not used
 		0,0,0 };						// Not used
 	// Choose a pixel format that best matches that described in pfd
 	nPixelFormat = ChoosePixelFormat(hDC, &pfd);
 	// Set the pixel format for the device context
 	SetPixelFormat(hDC, nPixelFormat, &pfd);
 }
 HGLRC CreateModernOpenGLContext(HDC hDC)
 {
 	PFNWGLCREATECONTEXTATTRIBSARBPROC wglCreateContextAttribsARB =
 		reinterpret_cast<PFNWGLCREATECONTEXTATTRIBSARBPROC>(wglGetProcAddress("wglCreateContextAttribsARB"));
 	if (!wglCreateContextAttribsARB)
 		return NULL;
 	const int versionCandidates[][2] =
 	{
 		{ 4, 5 },
 		{ 4, 3 },
 		{ 3, 3 }
 	};
 	for (const auto& version : versionCandidates)
 	{
 		const int attribs[] =
 		{
 			WGL_CONTEXT_MAJOR_VERSION_ARB, version[0],
 			WGL_CONTEXT_MINOR_VERSION_ARB, version[1],
 			WGL_CONTEXT_PROFILE_MASK_ARB, WGL_CONTEXT_CORE_PROFILE_BIT_ARB,
 			0
 		};
 		HGLRC modernContext = wglCreateContextAttribsARB(hDC, 0, attribs);
 		if (modernContext != NULL)
 			return modernContext;
 	}
 	return NULL;
 }
 int APIENTRY WinMain(HINSTANCE hInstance, HINSTANCE hPrevInstance, LPSTR lpCmdLine, int nCmdShow)
 {
 	MSG			msg;									// Windows message structure
 	WNDCLASS	wc;										// Windows class structure
 	HWND		hWnd;									// Storeage for window handle
 	TCHAR		szTitle[MAX_LOADSTRING];				// The title bar text
 	TCHAR		szWindowClass[MAX_LOADSTRING];			// the main window class name
 	// Initialize global strings
 	LoadString(hInstance, IDS_APP_TITLE, szTitle, MAX_LOADSTRING);
 	LoadString(hInstance, IDC_OPENGLOUTPUT, szWindowClass, MAX_LOADSTRING);
 	// Register Window style
 	wc.style			= CS_HREDRAW | CS_VREDRAW | CS_OWNDC;
 	wc.lpfnWndProc		= (WNDPROC) WndProc;
 	wc.cbClsExtra		= 0;
 	wc.cbWndExtra		= 0;
 	wc.hInstance		= hInstance;
 	wc.hIcon			= NULL;
 	wc.hCursor			= LoadCursor(NULL, IDC_ARROW);
 	// No need for background brush for OpenGL window
 	wc.hbrBackground	= NULL;
 	wc.lpszMenuName		= NULL;
 	wc.lpszClassName	= szWindowClass;
 	// Register the window class
 	if (RegisterClass(&wc) == 0)
 		return FALSE;
 	// Create the main application window
 	hWnd = CreateWindow(szWindowClass, szTitle, WS_OVERLAPPEDWINDOW | WS_CLIPCHILDREN | WS_CLIPSIBLINGS,
 						CW_USEDEFAULT, 0, 250, 250, NULL, NULL, hInstance, NULL);
 	// If window was not created, quit
 	if (hWnd == NULL)
 		return FALSE;
 	// Display the window
 	ShowWindow(hWnd,SW_SHOW);
 	UpdateWindow(hWnd);
 	// Process application messages until the application closes
 	while (GetMessage(&msg, NULL, 0, 0))
 	{
 		TranslateMessage(&msg);
 		DispatchMessage(&msg);
 	}
 	return (int)msg.wParam;
 }
 // Window procedure, handles all messages for this program
 LRESULT CALLBACK WndProc(HWND hWnd, UINT message, WPARAM wParam, LPARAM lParam)
 {
 	static HGLRC				hRC = NULL;					// Permenant Rendering context
 	static HDC					hDC = NULL;					// Private GDI Device context
 	static OpenGLComposite*		pOpenGLComposite = NULL;
 	static bool					sInteractiveResize = false;
 	static StatusStripControls	sStatusStrip;
 	switch (message)
 	{
 		// Window creation, setup for OpenGL context
 		case WM_CREATE:
 		{
 			try
 			{
 			// Store the device context
 			hDC = GetDC(hWnd);
 			// Select the pixel format
 			SetDCPixelFormat(hDC);
 			// Create the rendering context and make it current
 			hRC = wglCreateContext(hDC);
 			wglMakeCurrent(hDC, hRC);
 			HGLRC modernRC = CreateModernOpenGLContext(hDC);
 			if (modernRC == NULL)
 			{
 				MessageBox(NULL, _T("This application requires an OpenGL 3.3+ core profile context."), _T("OpenGL initialization Error."), MB_OK);
 				PostMessage(hWnd, WM_CLOSE, 0, 0);
 				break;
 			}
 			wglMakeCurrent(NULL, NULL);
 			wglDeleteContext(hRC);
 			hRC = modernRC;
 			wglMakeCurrent(hDC, hRC);
 			// Initialize COM
 			HRESULT result;
 			result = CoInitialize(NULL);
 			if (FAILED(result))
 			{
 				MessageBox(NULL, _T("Initialization of COM failed."), _T("Application initialization Error."),MB_OK);
 				PostMessage(hWnd, WM_CLOSE, 0, 0);
 				break;
 			}
 			// Setup OpenGL and DeckLink capture and playout object
 			pOpenGLComposite = new OpenGLComposite(hWnd, hDC, hRC);
 			if (pOpenGLComposite->InitDeckLink())
 			{
 				wglMakeCurrent( NULL, NULL );
 				if (pOpenGLComposite->Start())
 				{
 					PostMessage(hWnd, kCreateStatusStripMessage, 0, 0);
 					break;						// success
 				}
 				MessageBoxA(NULL, "The OpenGL/DeckLink runtime initialized, but playout failed to start. See the previous DeckLink start message for the failing call.", "Startup failed", MB_OK | MB_ICONERROR);
 			}
 			else
 			{
 				MessageBoxA(NULL, "The OpenGL/DeckLink runtime failed to initialize. See the previous initialization message for the failing call.", "Startup failed", MB_OK | MB_ICONERROR);
 			}
 			// Failed to initialize - cleanup
 			delete pOpenGLComposite;
 			pOpenGLComposite = NULL;
 			PostMessage(hWnd, WM_CLOSE, 0, 0);
 			break;
 			}
 			catch (...)
 			{
 				ShowUnhandledExceptionMessage("Startup failed while creating the OpenGL/DeckLink runtime.");
 				PostMessage(hWnd, WM_CLOSE, 0, 0);
 				break;
 			}
 		}
 		case kCreateStatusStripMessage:
 			if (pOpenGLComposite)
 			{
 				if (!StatusStripCreated(sStatusStrip))
 					CreateStatusStrip(hWnd, sStatusStrip);
 				UpdateStatusStrip(sStatusStrip, *pOpenGLComposite);
 				LayoutStatusStrip(hWnd, sStatusStrip);
 				RECT clientRect = {};
 				if (GetClientRect(hWnd, &clientRect))
 				{
 					pOpenGLComposite->resizeGL(
 						static_cast<WORD>(clientRect.right - clientRect.left),
 						static_cast<WORD>(clientRect.bottom - clientRect.top));
 				}
 				InvalidateRect(hWnd, NULL, FALSE);
 			}
 			break;
 		case WM_DESTROY:
 			try
 			{
 				if (pOpenGLComposite)
 				{
 					pOpenGLComposite->Stop();
 					delete pOpenGLComposite;
 				}
 			}
 			catch (...)
 			{
 				ShowUnhandledExceptionMessage("Shutdown failed while tearing down the OpenGL/DeckLink runtime.");
 			}
 			// Deselect the current rendering context and delete it
 			wglMakeCurrent(hDC, NULL);
 			wglDeleteContext(hRC);
 			// Tell the application to terminate after the window is gone
 			PostQuitMessage(0);
 			break;
 		case WM_ENTERSIZEMOVE:
 			sInteractiveResize = true;
 			break;
 		case WM_EXITSIZEMOVE:
 			sInteractiveResize = false;
 			if (pOpenGLComposite)
 			{
 				RECT clientRect = {};
 				if (GetClientRect(hWnd, &clientRect))
 				{
 					pOpenGLComposite->resizeGL(
 						static_cast<WORD>(clientRect.right - clientRect.left),
 						static_cast<WORD>(clientRect.bottom - clientRect.top));
 				}
 			}
 			InvalidateRect(hWnd, NULL, FALSE);
 			break;
 		case WM_SIZE:
 			try
 			{
 				if (StatusStripCreated(sStatusStrip))
 					LayoutStatusStrip(hWnd, sStatusStrip);
 				if (pOpenGLComposite)
 					pOpenGLComposite->resizeGL(LOWORD(lParam), HIWORD(lParam));
 			}
 			catch (...)
 			{
 				ShowUnhandledExceptionMessage("Resize failed inside the OpenGL runtime.");
 			}
 			break;
 		case WM_ERASEBKGND:
 			return 1;
 		case WM_PAINT:
 			try
 			{
 				PAINTSTRUCT paint = {};
 				BeginPaint(hWnd, &paint);
 				EndPaint(hWnd, &paint);
 				if (!sInteractiveResize && pOpenGLComposite)
 				{
 					wglMakeCurrent(hDC, hRC);
 					pOpenGLComposite->paintGL();
 					wglMakeCurrent( NULL, NULL );
 					RaiseStatusControls(sStatusStrip);
 				}
 			}
 			catch (...)
 			{
 				wglMakeCurrent( NULL, NULL );
 				ShowUnhandledExceptionMessage("Paint failed inside the OpenGL runtime.");
 			}
 			break;
 		case WM_KEYDOWN:
 			try
 			{
 				if (pOpenGLComposite && (wParam == 'R' || wParam == 'r'))
 				{
 					pOpenGLComposite->ReloadShader();
 					InvalidateRect(hWnd, NULL, FALSE);
 				}
 			}
 			catch (...)
 			{
 				ShowUnhandledExceptionMessage("Shader reload failed inside the OpenGL runtime.");
 			}
 			break;
 		case WM_COMMAND:
 			switch (LOWORD(wParam))
 			{
 			case kOpenControlButtonId:
 				if (pOpenGLComposite)
 				{
 					std::string url = pOpenGLComposite->GetControlUrl();
 					OpenUrl(url.c_str());
 				}
 				break;
 			case kOpenDocsButtonId:
 				if (pOpenGLComposite)
 				{
 					std::string url = pOpenGLComposite->GetDocsUrl();
 					OpenUrl(url.c_str());
 				}
 				break;
 			default:
 				return DefWindowProc(hWnd, message, wParam, lParam);
 			}
 			break;
 		default:
 			return (DefWindowProc(hWnd, message, wParam, lParam));
 	}
 	return (0L);
 }
--- a/apps/LoopThroughWithOpenGLCompositing/LoopThroughWithOpenGLCompositing.h
+++ b/apps/LoopThroughWithOpenGLCompositing/LoopThroughWithOpenGLCompositing.h
@@ -1,47 +0,0 @@
 /* -LICENSE-START-
 ** Copyright (c) 2012 Blackmagic Design
 **  
 ** Permission is hereby granted, free of charge, to any person or organization 
 ** obtaining a copy of the software and accompanying documentation (the 
 ** "Software") to use, reproduce, display, distribute, sub-license, execute, 
 ** and transmit the Software, and to prepare derivative works of the Software, 
 ** and to permit third-parties to whom the Software is furnished to do so, in 
 ** accordance with:
 ** 
 ** (1) if the Software is obtained from Blackmagic Design, the End User License 
 ** Agreement for the Software Development Kit ("EULA") available at 
 ** https://www.blackmagicdesign.com/EULA/DeckLinkSDK; or
 ** 
 ** (2) if the Software is obtained from any third party, such licensing terms 
 ** as notified by that third party,
 ** 
 ** and all subject to the following:
 ** 
 ** (3) the copyright notices in the Software and this entire statement, 
 ** including the above license grant, this restriction and the following 
 ** disclaimer, must be included in all copies of the Software, in whole or in 
 ** part, and all derivative works of the Software, unless such copies or 
 ** derivative works are solely in the form of machine-executable object code 
 ** generated by a source language processor.
 ** 
 ** (4) THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS 
 ** OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, 
 ** FITNESS FOR A PARTICULAR PURPOSE, TITLE AND NON-INFRINGEMENT. IN NO EVENT 
 ** SHALL THE COPYRIGHT HOLDERS OR ANYONE DISTRIBUTING THE SOFTWARE BE LIABLE 
 ** FOR ANY DAMAGES OR OTHER LIABILITY, WHETHER IN CONTRACT, TORT OR OTHERWISE, 
 ** ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER 
 ** DEALINGS IN THE SOFTWARE.
 ** 
 ** A copy of the Software is available free of charge at 
 ** https://www.blackmagicdesign.com/desktopvideo_sdk under the EULA.
 ** 
 ** -LICENSE-END-
 */
 //
 // LoopThroughWithOpenGLCompositing.h
 // LoopThroughWithOpenGLCompositing
 //
 #pragma once
 #include "resource.h"
--- a/apps/LoopThroughWithOpenGLCompositing/LoopThroughWithOpenGLCompositing.ico
+++ b/apps/LoopThroughWithOpenGLCompositing/LoopThroughWithOpenGLCompositing.ico
--- a/apps/LoopThroughWithOpenGLCompositing/LoopThroughWithOpenGLCompositing.rc
+++ b/apps/LoopThroughWithOpenGLCompositing/LoopThroughWithOpenGLCompositing.rc
@@ -1,95 +0,0 @@
 // Microsoft Visual C++ generated resource script.
 //
 #include "resource.h"
 #define APSTUDIO_READONLY_SYMBOLS
 /////////////////////////////////////////////////////////////////////////////
 //
 // Generated from the TEXTINCLUDE 2 resource.
 //
 #ifndef APSTUDIO_INVOKED
 #include "targetver.h"
 #endif
 #define APSTUDIO_HIDDEN_SYMBOLS
 #include "windows.h"
 #undef APSTUDIO_HIDDEN_SYMBOLS
 /////////////////////////////////////////////////////////////////////////////
 #undef APSTUDIO_READONLY_SYMBOLS
 /////////////////////////////////////////////////////////////////////////////
 // English (U.S.) resources
 #if !defined(AFX_RESOURCE_DLL) || defined(AFX_TARG_ENU)
 #ifdef _WIN32
 LANGUAGE LANG_ENGLISH, SUBLANG_ENGLISH_US
 #pragma code_page(1252)
 #endif //_WIN32
 /////////////////////////////////////////////////////////////////////////////
 //
 // Icon
 //
 // Icon with lowest ID value placed first to ensure application icon
 // remains consistent on all systems.
 IDI_OPENGLOUTPUT        ICON                    "LoopThroughWithOpenGLCompositing.ico"
 IDI_SMALL               ICON                    "small.ico"
 #ifdef APSTUDIO_INVOKED
 /////////////////////////////////////////////////////////////////////////////
 //
 // TEXTINCLUDE
 //
 1 TEXTINCLUDE 
 BEGIN
    "resource.h\0"
 END
 2 TEXTINCLUDE 
 BEGIN
    "#ifndef APSTUDIO_INVOKED\r\n"
    "#include ""targetver.h""\r\n"
    "#endif\r\n"
    "#define APSTUDIO_HIDDEN_SYMBOLS\r\n"
    "#include ""windows.h""\r\n"
    "#undef APSTUDIO_HIDDEN_SYMBOLS\r\n"
    "\0"
 END
 3 TEXTINCLUDE 
 BEGIN
    "\r\n"
    "\0"
 END
 #endif    // APSTUDIO_INVOKED
 /////////////////////////////////////////////////////////////////////////////
 //
 // String Table
 //
 STRINGTABLE 
 BEGIN
    IDS_APP_TITLE           "Video Shader Toys"
    IDC_OPENGLOUTPUT        "OPENGLOUTPUT"
 END
 #endif    // English (U.S.) resources
 /////////////////////////////////////////////////////////////////////////////
 #ifndef APSTUDIO_INVOKED
 /////////////////////////////////////////////////////////////////////////////
 //
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--- a/apps/LoopThroughWithOpenGLCompositing/LoopThroughWithOpenGLCompositing.sln
+++ b/apps/LoopThroughWithOpenGLCompositing/LoopThroughWithOpenGLCompositing.sln
@@ -1,28 +0,0 @@
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 EndProject
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--- a/apps/LoopThroughWithOpenGLCompositing/control/ControlServer.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/control/ControlServer.cpp
@@ -1,632 +0,0 @@
 #include "stdafx.h"
 #include "ControlServer.h"
 #include "RuntimeJson.h"
 #include <Wincrypt.h>
 #include <ws2tcpip.h>
 #include <algorithm>
 #include <fstream>
 #include <sstream>
 #pragma comment(lib, "Ws2_32.lib")
 #pragma comment(lib, "Crypt32.lib")
 #pragma comment(lib, "Advapi32.lib")
 namespace
 {
 constexpr DWORD kStateBroadcastIntervalMs = 250;
 bool InitializeWinsock(std::string& error)
 {
 	WSADATA wsaData = {};
 	int result = WSAStartup(MAKEWORD(2, 2), &wsaData);
 	if (result != 0)
 	{
 		error = "WSAStartup failed.";
 		return false;
 	}
 	return true;
 }
 std::string ToLower(std::string text)
 {
 	std::transform(text.begin(), text.end(), text.begin(),
 		[](unsigned char ch) { return static_cast<char>(std::tolower(ch)); });
 	return text;
 }
 bool IsSafeUiPath(const std::filesystem::path& relativePath)
 {
 	for (const std::filesystem::path& part : relativePath)
 	{
 		if (part == "..")
 			return false;
 	}
 	return !relativePath.empty();
 }
 std::string GuessContentType(const std::filesystem::path& assetPath)
 {
 	const std::string extension = ToLower(assetPath.extension().string());
 	if (extension == ".js" || extension == ".mjs")
 		return "text/javascript";
 	if (extension == ".css")
 		return "text/css";
 	if (extension == ".json")
 		return "application/json";
 	if (extension == ".yaml" || extension == ".yml")
 		return "application/yaml";
 	if (extension == ".svg")
 		return "image/svg+xml";
 	if (extension == ".png")
 		return "image/png";
 	if (extension == ".jpg" || extension == ".jpeg")
 		return "image/jpeg";
 	if (extension == ".ico")
 		return "image/x-icon";
 	if (extension == ".map")
 		return "application/json";
 	if (extension == ".md")
 		return "text/markdown";
 	return "text/html";
 }
 }
 ControlServer::ControlServer()
 	: mPort(0), mRunning(false)
 {
 }
 ControlServer::~ControlServer()
 {
 	Stop();
 }
 bool ControlServer::Start(const std::filesystem::path& uiRoot, const std::filesystem::path& docsRoot, unsigned short preferredPort, const Callbacks& callbacks, std::string& error)
 {
 	mUiRoot = uiRoot;
 	mDocsRoot = docsRoot;
 	mCallbacks = callbacks;
 	if (!InitializeWinsock(error))
 		return false;
 	mListenSocket.reset(socket(AF_INET, SOCK_STREAM, IPPROTO_TCP));
 	if (!mListenSocket.valid())
 	{
 		error = "Could not create listening socket.";
 		return false;
 	}
 	u_long nonBlocking = 1;
 	ioctlsocket(mListenSocket.get(), FIONBIO, &nonBlocking);
 	sockaddr_in address = {};
 	address.sin_family = AF_INET;
 	address.sin_addr.s_addr = htonl(INADDR_LOOPBACK);
 	bool bound = false;
 	for (unsigned short offset = 0; offset < 20; ++offset)
 	{
 		address.sin_port = htons(static_cast<u_short>(preferredPort + offset));
 		if (bind(mListenSocket.get(), reinterpret_cast<sockaddr*>(&address), sizeof(address)) == 0)
 		{
 			mPort = preferredPort + offset;
 			bound = true;
 			break;
 		}
 	}
 	if (!bound)
 	{
 		error = "Could not bind the local control server to any port in the preferred range.";
 		mListenSocket.reset();
 		return false;
 	}
 	if (listen(mListenSocket.get(), SOMAXCONN) != 0)
 	{
 		error = "Could not start listening on the local control server socket.";
 		mListenSocket.reset();
 		return false;
 	}
 	mRunning = true;
 	mThread = std::thread(&ControlServer::ServerLoop, this);
 	return true;
 }
 void ControlServer::Stop()
 {
 	const bool wasActive = mRunning || mListenSocket.valid() || mThread.joinable();
 	mRunning = false;
 	{
 		std::lock_guard<std::mutex> lock(mMutex);
 		for (ClientConnection& client : mClients)
 			client.socket.reset();
 		mClients.clear();
 	}
 	mListenSocket.reset();
 	if (mThread.joinable())
 		mThread.join();
 	if (wasActive)
 		WSACleanup();
 }
 void ControlServer::BroadcastState()
 {
 	std::lock_guard<std::mutex> lock(mMutex);
 	BroadcastStateLocked();
 }
 void ControlServer::ServerLoop()
 {
 	DWORD lastStateBroadcastMs = GetTickCount();
 	while (mRunning)
 	{
 		TryAcceptClient();
 		const DWORD nowMs = GetTickCount();
 		if (nowMs - lastStateBroadcastMs >= kStateBroadcastIntervalMs)
 		{
 			BroadcastState();
 			lastStateBroadcastMs = nowMs;
 		}
 		Sleep(25);
 	}
 }
 bool ControlServer::HandleHttpClient(UniqueSocket clientSocket)
 {
 	std::string request;
 	char buffer[8192];
 	int received = recv(clientSocket.get(), buffer, sizeof(buffer), 0);
 	if (received <= 0)
 		return false;
 	request.assign(buffer, buffer + received);
 	return HandleHttpRequest(std::move(clientSocket), request);
 }
 bool ControlServer::TryAcceptClient()
 {
 	sockaddr_in clientAddress = {};
 	int addressSize = sizeof(clientAddress);
 	UniqueSocket clientSocket(accept(mListenSocket.get(), reinterpret_cast<sockaddr*>(&clientAddress), &addressSize));
 	if (!clientSocket.valid())
 		return false;
 	return HandleHttpClient(std::move(clientSocket));
 }
 bool ControlServer::SendHttpResponse(SOCKET clientSocket, const std::string& status, const std::string& contentType, const std::string& body)
 {
 	std::ostringstream response;
 	response << "HTTP/1.1 " << status << "\r\n";
 	response << "Content-Type: " << contentType << "\r\n";
 	response << "Content-Length: " << body.size() << "\r\n";
 	response << "Connection: close\r\n\r\n";
 	response << body;
 	const std::string payload = response.str();
 	return send(clientSocket, payload.c_str(), static_cast<int>(payload.size()), 0) == static_cast<int>(payload.size());
 }
 bool ControlServer::SendHttpResponse(SOCKET clientSocket, const HttpResponse& response)
 {
 	return SendHttpResponse(clientSocket, response.status, response.contentType, response.body);
 }
 bool ControlServer::HandleHttpRequest(UniqueSocket clientSocket, const std::string& request)
 {
 	HttpRequest httpRequest;
 	if (!ParseHttpRequest(request, httpRequest))
 	{
 		SendHttpResponse(clientSocket.get(), "400 Bad Request", "text/plain", "Bad Request");
 		return true;
 	}
 	if (ToLower(GetHeaderValue(httpRequest, "Upgrade")) == "websocket")
 		return HandleWebSocketUpgrade(std::move(clientSocket), httpRequest);
 	const HttpResponse response = RouteHttpRequest(httpRequest);
 	SendHttpResponse(clientSocket.get(), response);
 	if (response.broadcastState)
 		BroadcastState();
 	return true;
 }
 ControlServer::HttpResponse ControlServer::RouteHttpRequest(const HttpRequest& request)
 {
 	if (request.method == "GET")
 		return ServeGetRequest(request);
 	if (request.method == "POST")
 		return HandleApiPost(request);
 	return { "404 Not Found", "text/plain", "Not Found" };
 }
 ControlServer::HttpResponse ControlServer::ServeGetRequest(const HttpRequest& request) const
 {
 	if (request.path == "/" || request.path == "/index.html")
 		return ServeUiAsset("index.html");
 	if (request.path == "/api/state")
 		return { "200 OK", "application/json", mCallbacks.getStateJson ? mCallbacks.getStateJson() : "{}" };
 	if (request.path == "/openapi.yaml" || request.path == "/docs/openapi.yaml")
 		return ServeOpenApiSpec();
 	if (request.path == "/docs" || request.path == "/docs/")
 		return ServeSwaggerDocs();
 	const std::string docsPrefix = "/docs/";
 	if (request.path.rfind(docsPrefix, 0) == 0)
 		return ServeDocsAsset(request.path.substr(docsPrefix.size()));
 	if (request.path.size() > 1)
 	{
 		const HttpResponse assetResponse = ServeUiAsset(request.path.substr(1));
 		if (!assetResponse.body.empty())
 			return assetResponse;
 	}
 	return { "404 Not Found", "text/plain", "Not Found" };
 }
 ControlServer::HttpResponse ControlServer::ServeUiAsset(const std::string& relativePath) const
 {
 	std::string contentType;
 	const std::string body = LoadUiAsset(relativePath, contentType);
 	return body.empty()
 		? HttpResponse{ "404 Not Found", "text/plain", "Not Found" }
 		: HttpResponse{ "200 OK", contentType, body };
 }
 ControlServer::HttpResponse ControlServer::ServeDocsAsset(const std::string& relativePath) const
 {
 	const std::filesystem::path sanitizedPath = std::filesystem::path(relativePath).lexically_normal();
 	if (!IsSafeUiPath(sanitizedPath))
 		return { "404 Not Found", "text/plain", "Not Found" };
 	const std::filesystem::path docsPath = mDocsRoot / sanitizedPath;
 	const std::string body = LoadTextFile(docsPath);
 	return body.empty()
 		? HttpResponse{ "404 Not Found", "text/plain", "Not Found" }
 		: HttpResponse{ "200 OK", GuessContentType(docsPath), body };
 }
 ControlServer::HttpResponse ControlServer::ServeOpenApiSpec() const
 {
 	const std::filesystem::path specPath = mDocsRoot / "openapi.yaml";
 	const std::string body = LoadTextFile(specPath);
 	return body.empty()
 		? HttpResponse{ "404 Not Found", "text/plain", "OpenAPI spec not found" }
 		: HttpResponse{ "200 OK", GuessContentType(specPath), body };
 }
 ControlServer::HttpResponse ControlServer::ServeSwaggerDocs() const
 {
 	std::ostringstream html;
 	html << "<!doctype html>\n"
 		<< "<html lang=\"en\">\n"
 		<< "<head>\n"
 		<< "  <meta charset=\"utf-8\">\n"
 		<< "  <meta name=\"viewport\" content=\"width=device-width, initial-scale=1\">\n"
 		<< "  <title>Video Shader Toys API Docs</title>\n"
 		<< "  <link rel=\"stylesheet\" href=\"https://unpkg.com/swagger-ui-dist@5/swagger-ui.css\">\n"
 		<< "</head>\n"
 		<< "<body>\n"
 		<< "  <div id=\"swagger-ui\"></div>\n"
 		<< "  <script src=\"https://unpkg.com/swagger-ui-dist@5/swagger-ui-bundle.js\"></script>\n"
 		<< "  <script>SwaggerUIBundle({url:'/docs/openapi.yaml',dom_id:'#swagger-ui'});</script>\n"
 		<< "</body>\n"
 		<< "</html>\n";
 	return { "200 OK", "text/html", html.str() };
 }
 ControlServer::HttpResponse ControlServer::HandleApiPost(const HttpRequest& request)
 {
 	JsonValue root;
 	std::string parseError;
 	if (!ParseJson(request.body, root, parseError))
 		return { "400 Bad Request", "application/json", BuildJsonResponse(false, parseError) };
 	std::string actionError;
 	const bool success = InvokePostRoute(request.path, root, actionError);
 	return {
 		success ? "200 OK" : "400 Bad Request",
 		"application/json",
 		BuildJsonResponse(success, actionError),
 		success
 	};
 }
 bool ControlServer::InvokePostRoute(const std::string& path, const JsonValue& root, std::string& actionError)
 {
 	using PostHandler = std::function<bool(const JsonValue&, std::string&)>;
 	const std::map<std::string, PostHandler> postRoutes =
 	{
 		{ "/api/layers/add", [this](const JsonValue& json, std::string& error)
 			{
 				const JsonValue* shaderId = json.find("shaderId");
 				return shaderId && mCallbacks.addLayer && mCallbacks.addLayer(shaderId->asString(), error);
 			}
 		},
 		{ "/api/layers/remove", [this](const JsonValue& json, std::string& error)
 			{
 				const JsonValue* layerId = json.find("layerId");
 				return layerId && mCallbacks.removeLayer && mCallbacks.removeLayer(layerId->asString(), error);
 			}
 		},
 		{ "/api/layers/move", [this](const JsonValue& json, std::string& error)
 			{
 				const JsonValue* layerId = json.find("layerId");
 				const JsonValue* direction = json.find("direction");
 				return layerId && direction && mCallbacks.moveLayer &&
 					mCallbacks.moveLayer(layerId->asString(), static_cast<int>(direction->asNumber()), error);
 			}
 		},
 		{ "/api/layers/reorder", [this](const JsonValue& json, std::string& error)
 			{
 				const JsonValue* layerId = json.find("layerId");
 				const JsonValue* targetIndex = json.find("targetIndex");
 				return layerId && targetIndex && mCallbacks.moveLayerToIndex &&
 					mCallbacks.moveLayerToIndex(layerId->asString(), static_cast<std::size_t>(targetIndex->asNumber()), error);
 			}
 		},
 		{ "/api/layers/set-bypass", [this](const JsonValue& json, std::string& error)
 			{
 				const JsonValue* layerId = json.find("layerId");
 				const JsonValue* bypass = json.find("bypass");
 				return layerId && bypass && mCallbacks.setLayerBypass &&
 					mCallbacks.setLayerBypass(layerId->asString(), bypass->asBoolean(), error);
 			}
 		},
 		{ "/api/layers/set-shader", [this](const JsonValue& json, std::string& error)
 			{
 				const JsonValue* layerId = json.find("layerId");
 				const JsonValue* shaderId = json.find("shaderId");
 				return layerId && shaderId && mCallbacks.setLayerShader &&
 					mCallbacks.setLayerShader(layerId->asString(), shaderId->asString(), error);
 			}
 		},
 		{ "/api/layers/update-parameter", [this](const JsonValue& json, std::string& error)
 			{
 				const JsonValue* layerId = json.find("layerId");
 				const JsonValue* parameterId = json.find("parameterId");
 				const JsonValue* value = json.find("value");
 				return layerId && parameterId && value && mCallbacks.updateLayerParameter &&
 					mCallbacks.updateLayerParameter(layerId->asString(), parameterId->asString(), SerializeJson(*value, false), error);
 			}
 		},
 		{ "/api/layers/reset-parameters", [this](const JsonValue& json, std::string& error)
 			{
 				const JsonValue* layerId = json.find("layerId");
 				return layerId && mCallbacks.resetLayerParameters &&
 					mCallbacks.resetLayerParameters(layerId->asString(), error);
 			}
 		},
 		{ "/api/stack-presets/save", [this](const JsonValue& json, std::string& error)
 			{
 				const JsonValue* presetName = json.find("presetName");
 				return presetName && mCallbacks.saveStackPreset &&
 					mCallbacks.saveStackPreset(presetName->asString(), error);
 			}
 		},
 		{ "/api/stack-presets/load", [this](const JsonValue& json, std::string& error)
 			{
 				const JsonValue* presetName = json.find("presetName");
 				return presetName && mCallbacks.loadStackPreset &&
 					mCallbacks.loadStackPreset(presetName->asString(), error);
 			}
 		},
 		{ "/api/reload", [this](const JsonValue&, std::string& error)
 			{
 				return mCallbacks.reloadShader && mCallbacks.reloadShader(error);
 			}
 		},
 		{ "/api/screenshot", [this](const JsonValue&, std::string& error)
 			{
 				return mCallbacks.requestScreenshot && mCallbacks.requestScreenshot(error);
 			}
 		}
 	};
 	const auto route = postRoutes.find(path);
 	return route != postRoutes.end() && route->second(root, actionError);
 }
 bool ControlServer::HandleWebSocketUpgrade(UniqueSocket clientSocket, const HttpRequest& request)
 {
 	const std::string clientKey = GetHeaderValue(request, "Sec-WebSocket-Key");
 	if (clientKey.empty())
 	{
 		SendHttpResponse(clientSocket.get(), "400 Bad Request", "text/plain", "Missing Sec-WebSocket-Key");
 		return true;
 	}
 	std::ostringstream response;
 	response << "HTTP/1.1 101 Switching Protocols\r\n";
 	response << "Upgrade: websocket\r\n";
 	response << "Connection: Upgrade\r\n";
 	response << "Sec-WebSocket-Accept: " << ComputeWebSocketAcceptKey(clientKey) << "\r\n\r\n";
 	const std::string payload = response.str();
 	send(clientSocket.get(), payload.c_str(), static_cast<int>(payload.size()), 0);
 	{
 		std::lock_guard<std::mutex> lock(mMutex);
 		ClientConnection client;
 		client.socket.reset(clientSocket.release());
 		client.websocket = true;
 		mClients.push_back(std::move(client));
 		BroadcastStateLocked();
 	}
 	return true;
 }
 bool ControlServer::SendWebSocketText(SOCKET clientSocket, const std::string& payload)
 {
 	std::string frame;
 	frame.push_back(static_cast<char>(0x81));
 	if (payload.size() <= 125)
 	{
 		frame.push_back(static_cast<char>(payload.size()));
 	}
 	else if (payload.size() <= 65535)
 	{
 		frame.push_back(126);
 		frame.push_back(static_cast<char>((payload.size() >> 8) & 0xFF));
 		frame.push_back(static_cast<char>(payload.size() & 0xFF));
 	}
 	else
 	{
 		frame.push_back(127);
 		for (int shift = 56; shift >= 0; shift -= 8)
 			frame.push_back(static_cast<char>((payload.size() >> shift) & 0xFF));
 	}
 	frame.append(payload);
 	return send(clientSocket, frame.data(), static_cast<int>(frame.size()), 0) == static_cast<int>(frame.size());
 }
 void ControlServer::BroadcastStateLocked()
 {
 	const std::string stateMessage = mCallbacks.getStateJson ? mCallbacks.getStateJson() : "{}";
 	for (auto it = mClients.begin(); it != mClients.end();)
 	{
 		if (!SendWebSocketText(it->socket.get(), stateMessage))
 		{
 			it = mClients.erase(it);
 		}
 		else
 		{
 			++it;
 		}
 	}
 }
 std::string ControlServer::LoadUiAsset(const std::string& relativePath, std::string& contentType) const
 {
 	const std::filesystem::path sanitizedPath = std::filesystem::path(relativePath).lexically_normal();
 	if (!IsSafeUiPath(sanitizedPath))
 		return std::string();
 	const std::filesystem::path assetPath = mUiRoot / sanitizedPath;
 	contentType = GuessContentType(assetPath);
 	return LoadTextFile(assetPath);
 }
 std::string ControlServer::LoadTextFile(const std::filesystem::path& path) const
 {
 	std::ifstream input(path, std::ios::binary);
 	if (!input)
 		return std::string();
 	std::ostringstream buffer;
 	buffer << input.rdbuf();
 	return buffer.str();
 }
 std::string ControlServer::BuildJsonResponse(bool success, const std::string& error) const
 {
 	JsonValue response = JsonValue::MakeObject();
 	response.set("ok", JsonValue(success));
 	if (!error.empty())
 		response.set("error", JsonValue(error));
 	return SerializeJson(response, false);
 }
 std::string ControlServer::Base64Encode(const unsigned char* data, DWORD dataLength)
 {
 	DWORD outputLength = 0;
 	CryptBinaryToStringA(data, dataLength, CRYPT_STRING_BASE64 | CRYPT_STRING_NOCRLF, NULL, &outputLength);
 	std::string encoded(outputLength, '\0');
 	CryptBinaryToStringA(data, dataLength, CRYPT_STRING_BASE64 | CRYPT_STRING_NOCRLF, &encoded[0], &outputLength);
 	if (!encoded.empty() && encoded.back() == '\0')
 		encoded.pop_back();
 	return encoded;
 }
 std::string ControlServer::ComputeWebSocketAcceptKey(const std::string& clientKey)
 {
 	const std::string combined = clientKey + "258EAFA5-E914-47DA-95CA-C5AB0DC85B11";
 	HCRYPTPROV provider = 0;
 	HCRYPTHASH hash = 0;
 	BYTE digest[20] = {};
 	DWORD digestLength = sizeof(digest);
 	CryptAcquireContext(&provider, NULL, NULL, PROV_RSA_FULL, CRYPT_VERIFYCONTEXT);
 	CryptCreateHash(provider, CALG_SHA1, 0, 0, &hash);
 	CryptHashData(hash, reinterpret_cast<const BYTE*>(combined.data()), static_cast<DWORD>(combined.size()), 0);
 	CryptGetHashParam(hash, HP_HASHVAL, digest, &digestLength, 0);
 	if (hash)
 		CryptDestroyHash(hash);
 	if (provider)
 		CryptReleaseContext(provider, 0);
 	return Base64Encode(digest, digestLength);
 }
 std::string ControlServer::GetHeaderValue(const HttpRequest& request, const std::string& headerName)
 {
 	const auto header = request.headers.find(ToLower(headerName));
 	return header == request.headers.end() ? std::string() : header->second;
 }
 bool ControlServer::ParseHttpRequest(const std::string& rawRequest, HttpRequest& request)
 {
 	const std::size_t requestLineEnd = rawRequest.find("\r\n");
 	if (requestLineEnd == std::string::npos)
 		return false;
 	const std::string requestLine = rawRequest.substr(0, requestLineEnd);
 	const std::size_t methodEnd = requestLine.find(' ');
 	if (methodEnd == std::string::npos)
 		return false;
 	const std::size_t pathEnd = requestLine.find(' ', methodEnd + 1);
 	if (pathEnd == std::string::npos)
 		return false;
 	request.method = requestLine.substr(0, methodEnd);
 	request.path = requestLine.substr(methodEnd + 1, pathEnd - methodEnd - 1);
 	request.headers.clear();
 	const std::size_t headersStart = requestLineEnd + 2;
 	const std::size_t bodySeparator = rawRequest.find("\r\n\r\n", headersStart);
 	const std::size_t headersEnd = bodySeparator == std::string::npos ? rawRequest.size() : bodySeparator;
 	for (std::size_t lineStart = headersStart; lineStart < headersEnd;)
 	{
 		const std::size_t lineEnd = rawRequest.find("\r\n", lineStart);
 		const std::size_t currentLineEnd = lineEnd == std::string::npos ? headersEnd : std::min(lineEnd, headersEnd);
 		const std::string line = rawRequest.substr(lineStart, currentLineEnd - lineStart);
 		const std::size_t separator = line.find(':');
 		if (separator != std::string::npos)
 		{
 			const std::string key = ToLower(line.substr(0, separator));
 			std::string value = line.substr(separator + 1);
 			const std::size_t first = value.find_first_not_of(" \t");
 			const std::size_t last = value.find_last_not_of(" \t");
 			request.headers[key] = first == std::string::npos ? std::string() : value.substr(first, last - first + 1);
 		}
 		if (lineEnd == std::string::npos || lineEnd >= headersEnd)
 			break;
 		lineStart = lineEnd + 2;
 	}
 	request.body = bodySeparator == std::string::npos ? std::string() : rawRequest.substr(bodySeparator + 4);
 	return !request.method.empty() && !request.path.empty();
 }
--- a/apps/LoopThroughWithOpenGLCompositing/control/ControlServer.h
+++ b/apps/LoopThroughWithOpenGLCompositing/control/ControlServer.h
@@ -1,105 +0,0 @@
 #pragma once
 #include "NativeSockets.h"
 #include <winsock2.h>
 #include <atomic>
 #include <filesystem>
 #include <functional>
 #include <map>
 #include <mutex>
 #include <string>
 #include <thread>
 #include <vector>
 class JsonValue;
 class ControlServer
 {
 public:
 	struct Callbacks
 	{
 		std::function<std::string()> getStateJson;
 		std::function<bool(const std::string&, std::string&)> addLayer;
 		std::function<bool(const std::string&, std::string&)> removeLayer;
 		std::function<bool(const std::string&, int, std::string&)> moveLayer;
 		std::function<bool(const std::string&, std::size_t, std::string&)> moveLayerToIndex;
 		std::function<bool(const std::string&, bool, std::string&)> setLayerBypass;
 		std::function<bool(const std::string&, const std::string&, std::string&)> setLayerShader;
 		std::function<bool(const std::string&, const std::string&, const std::string&, std::string&)> updateLayerParameter;
 		std::function<bool(const std::string&, std::string&)> resetLayerParameters;
 		std::function<bool(const std::string&, std::string&)> saveStackPreset;
 		std::function<bool(const std::string&, std::string&)> loadStackPreset;
 		std::function<bool(std::string&)> reloadShader;
 		std::function<bool(std::string&)> requestScreenshot;
 	};
 	ControlServer();
 	~ControlServer();
 	bool Start(const std::filesystem::path& uiRoot, const std::filesystem::path& docsRoot, unsigned short preferredPort, const Callbacks& callbacks, std::string& error);
 	void Stop();
 	void BroadcastState();
 	unsigned short GetPort() const { return mPort; }
 private:
 	struct ClientConnection
 	{
 		UniqueSocket socket;
 		bool websocket = false;
 	};
 	struct HttpRequest
 	{
 		std::string method;
 		std::string path;
 		std::map<std::string, std::string> headers;
 		std::string body;
 	};
 	struct HttpResponse
 	{
 		std::string status;
 		std::string contentType;
 		std::string body;
 		bool broadcastState = false;
 	};
 	void ServerLoop();
 	bool HandleHttpClient(UniqueSocket clientSocket);
 	bool TryAcceptClient();
 	bool SendHttpResponse(SOCKET clientSocket, const HttpResponse& response);
 	bool SendHttpResponse(SOCKET clientSocket, const std::string& status, const std::string& contentType, const std::string& body);
 	bool HandleHttpRequest(UniqueSocket clientSocket, const std::string& request);
 	bool HandleWebSocketUpgrade(UniqueSocket clientSocket, const HttpRequest& request);
 	HttpResponse RouteHttpRequest(const HttpRequest& request);
 	HttpResponse ServeGetRequest(const HttpRequest& request) const;
 	HttpResponse ServeUiAsset(const std::string& relativePath) const;
 	HttpResponse ServeDocsAsset(const std::string& relativePath) const;
 	HttpResponse ServeOpenApiSpec() const;
 	HttpResponse ServeSwaggerDocs() const;
 	HttpResponse HandleApiPost(const HttpRequest& request);
 	bool InvokePostRoute(const std::string& path, const JsonValue& root, std::string& actionError);
 	bool SendWebSocketText(SOCKET clientSocket, const std::string& payload);
 	void BroadcastStateLocked();
 	std::string LoadUiAsset(const std::string& relativePath, std::string& contentType) const;
 	std::string LoadTextFile(const std::filesystem::path& path) const;
 	std::string BuildJsonResponse(bool success, const std::string& error = std::string()) const;
 	static std::string Base64Encode(const unsigned char* data, DWORD dataLength);
 	static std::string ComputeWebSocketAcceptKey(const std::string& clientKey);
 	static std::string GetHeaderValue(const HttpRequest& request, const std::string& headerName);
 	static bool ParseHttpRequest(const std::string& rawRequest, HttpRequest& request);
 private:
 	std::filesystem::path mUiRoot;
 	std::filesystem::path mDocsRoot;
 	Callbacks mCallbacks;
 	UniqueSocket mListenSocket;
 	unsigned short mPort;
 	std::thread mThread;
 	std::atomic<bool> mRunning;
 	mutable std::mutex mMutex;
 	std::vector<ClientConnection> mClients;
 };
--- a/apps/LoopThroughWithOpenGLCompositing/control/OscServer.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/control/OscServer.cpp
@@ -1,314 +0,0 @@
 #include "stdafx.h"
 #include "OscServer.h"
 #include <ws2tcpip.h>
 #include <array>
 #include <cstring>
 #include <iomanip>
 #include <sstream>
 #include <vector>
 #pragma comment(lib, "Ws2_32.lib")
 namespace
 {
 bool InitializeWinsock(std::string& error)
 {
 	WSADATA wsaData = {};
 	const int result = WSAStartup(MAKEWORD(2, 2), &wsaData);
 	if (result != 0)
 	{
 		error = "WSAStartup failed.";
 		return false;
 	}
 	return true;
 }
 std::vector<std::string> SplitAddress(const std::string& address)
 {
 	std::vector<std::string> parts;
 	std::size_t start = !address.empty() && address[0] == '/' ? 1 : 0;
 	while (start <= address.size())
 	{
 		const std::size_t slash = address.find('/', start);
 		const std::size_t end = slash == std::string::npos ? address.size() : slash;
 		if (end > start)
 			parts.push_back(address.substr(start, end - start));
 		if (slash == std::string::npos)
 			break;
 		start = slash + 1;
 	}
 	return parts;
 }
 }
 OscServer::OscServer()
 	: mPort(0), mRunning(false)
 {
 }
 OscServer::~OscServer()
 {
 	Stop();
 }
 bool OscServer::Start(unsigned short port, const Callbacks& callbacks, std::string& error)
 {
 	if (port == 0)
 		return true;
 	mCallbacks = callbacks;
 	mPort = port;
 	if (!InitializeWinsock(error))
 		return false;
 	mSocket.reset(socket(AF_INET, SOCK_DGRAM, IPPROTO_UDP));
 	if (!mSocket.valid())
 	{
 		error = "Could not create OSC UDP socket.";
 		return false;
 	}
 	DWORD timeoutMilliseconds = 100;
 	setsockopt(mSocket.get(), SOL_SOCKET, SO_RCVTIMEO, reinterpret_cast<const char*>(&timeoutMilliseconds), sizeof(timeoutMilliseconds));
 	sockaddr_in address = {};
 	address.sin_family = AF_INET;
 	address.sin_addr.s_addr = htonl(INADDR_LOOPBACK);
 	address.sin_port = htons(static_cast<u_short>(port));
 	if (bind(mSocket.get(), reinterpret_cast<sockaddr*>(&address), sizeof(address)) != 0)
 	{
 		error = "Could not bind OSC listener to UDP port " + std::to_string(port) + ".";
 		mSocket.reset();
 		return false;
 	}
 	mRunning = true;
 	mThread = std::thread(&OscServer::ServerLoop, this);
 	return true;
 }
 void OscServer::Stop()
 {
 	mRunning = false;
 	mSocket.reset();
 	if (mThread.joinable())
 		mThread.join();
 }
 void OscServer::ServerLoop()
 {
 	std::array<char, 4096> buffer = {};
 	while (mRunning)
 	{
 		sockaddr_in sender = {};
 		int senderLength = sizeof(sender);
 		const int byteCount = recvfrom(mSocket.get(), buffer.data(), static_cast<int>(buffer.size()), 0,
 			reinterpret_cast<sockaddr*>(&sender), &senderLength);
 		if (byteCount <= 0)
 			continue;
 		OscMessage message;
 		std::string error;
 		if (DecodeMessage(buffer.data(), byteCount, message, error))
 		{
 			if (!DispatchMessage(message, error) && !error.empty())
 				OutputDebugStringA(("OSC dispatch failed: " + error + "\n").c_str());
 		}
 		else if (!error.empty())
 		{
 			OutputDebugStringA(("OSC decode failed: " + error + "\n").c_str());
 		}
 	}
 }
 bool OscServer::DecodeMessage(const char* data, int byteCount, OscMessage& message, std::string& error) const
 {
 	int offset = 0;
 	if (!ReadPaddedString(data, byteCount, offset, message.address) || message.address.empty() || message.address[0] != '/')
 	{
 		error = "Invalid OSC address.";
 		return false;
 	}
 	std::string typeTags;
 	if (!ReadPaddedString(data, byteCount, offset, typeTags) || typeTags.empty() || typeTags[0] != ',')
 	{
 		error = "Invalid OSC type tag string.";
 		return false;
 	}
 	if (typeTags.size() < 2)
 	{
 		error = "OSC message has no parameter value.";
 		return false;
 	}
 	std::vector<std::string> values;
 	for (std::size_t index = 1; index < typeTags.size(); ++index)
 	{
 		std::string valueJson;
 		if (!DecodeArgument(data, byteCount, offset, typeTags[index], valueJson))
 		{
 			error = "Unsupported or malformed OSC value type.";
 			return false;
 		}
 		values.push_back(valueJson);
 	}
 	if (values.size() == 1)
 	{
 		message.valueJson = values.front();
 		return true;
 	}
 	std::ostringstream arrayJson;
 	arrayJson << "[";
 	for (std::size_t index = 0; index < values.size(); ++index)
 	{
 		if (index > 0)
 			arrayJson << ",";
 		arrayJson << values[index];
 	}
 	arrayJson << "]";
 	message.valueJson = arrayJson.str();
 	return true;
 }
 bool OscServer::DispatchMessage(const OscMessage& message, std::string& error) const
 {
 	const std::vector<std::string> parts = SplitAddress(message.address);
 	if (parts.size() != 3 || parts[0] != "VideoShaderToys")
 	{
 		error = "Unsupported OSC address: " + message.address;
 		return false;
 	}
 	return mCallbacks.updateParameter &&
 		mCallbacks.updateParameter(parts[1], parts[2], message.valueJson, error);
 }
 bool OscServer::DecodeArgument(const char* data, int byteCount, int& offset, char valueType, std::string& valueJson)
 {
 	if (valueType == 'f')
 	{
 		double value = 0.0;
 		if (!ReadFloat32(data, byteCount, offset, value))
 			return false;
 		std::ostringstream stream;
 		stream << std::setprecision(9) << value;
 		valueJson = stream.str();
 		return true;
 	}
 	if (valueType == 'd')
 	{
 		double value = 0.0;
 		if (!ReadFloat64(data, byteCount, offset, value))
 			return false;
 		std::ostringstream stream;
 		stream << std::setprecision(17) << value;
 		valueJson = stream.str();
 		return true;
 	}
 	if (valueType == 'i')
 	{
 		int value = 0;
 		if (!ReadInt32(data, byteCount, offset, value))
 			return false;
 		valueJson = std::to_string(value);
 		return true;
 	}
 	if (valueType == 's')
 	{
 		std::string value;
 		if (!ReadPaddedString(data, byteCount, offset, value))
 			return false;
 		valueJson = BuildJsonString(value);
 		return true;
 	}
 	if (valueType == 'T' || valueType == 'F')
 	{
 		valueJson = valueType == 'T' ? "true" : "false";
 		return true;
 	}
 	return false;
 }
 bool OscServer::ReadPaddedString(const char* data, int byteCount, int& offset, std::string& value)
 {
 	if (offset < 0 || offset >= byteCount)
 		return false;
 	const int start = offset;
 	while (offset < byteCount && data[offset] != '\0')
 		++offset;
 	if (offset >= byteCount)
 		return false;
 	value.assign(data + start, data + offset);
 	++offset;
 	while (offset % 4 != 0)
 		++offset;
 	return offset <= byteCount;
 }
 bool OscServer::ReadInt32(const char* data, int byteCount, int& offset, int& value)
 {
 	if (offset + 4 > byteCount)
 		return false;
 	const unsigned char* bytes = reinterpret_cast<const unsigned char*>(data + offset);
 	value = static_cast<int>((bytes[0] << 24) | (bytes[1] << 16) | (bytes[2] << 8) | bytes[3]);
 	offset += 4;
 	return true;
 }
 bool OscServer::ReadFloat32(const char* data, int byteCount, int& offset, double& value)
 {
 	int bits = 0;
 	if (!ReadInt32(data, byteCount, offset, bits))
 		return false;
 	float floatValue = 0.0f;
 	const unsigned int unsignedBits = static_cast<unsigned int>(bits);
 	std::memcpy(&floatValue, &unsignedBits, sizeof(floatValue));
 	value = static_cast<double>(floatValue);
 	return true;
 }
 bool OscServer::ReadFloat64(const char* data, int byteCount, int& offset, double& value)
 {
 	if (offset + 8 > byteCount)
 		return false;
 	const unsigned char* bytes = reinterpret_cast<const unsigned char*>(data + offset);
 	uint64_t bits = 0;
 	for (int index = 0; index < 8; ++index)
 		bits = (bits << 8) | static_cast<uint64_t>(bytes[index]);
 	std::memcpy(&value, &bits, sizeof(value));
 	offset += 8;
 	return true;
 }
 std::string OscServer::BuildJsonString(const std::string& value)
 {
 	std::ostringstream stream;
 	stream << '"';
 	for (char ch : value)
 	{
 		if (ch == '"' || ch == '\\')
 			stream << '\\';
 		stream << ch;
 	}
 	stream << '"';
 	return stream.str();
 }
--- a/apps/LoopThroughWithOpenGLCompositing/control/OscServer.h
+++ b/apps/LoopThroughWithOpenGLCompositing/control/OscServer.h
@@ -1,52 +0,0 @@
 #pragma once
 #include "NativeSockets.h"
 #include <winsock2.h>
 #include <atomic>
 #include <functional>
 #include <string>
 #include <thread>
 class OscServer
 {
 public:
 	struct Callbacks
 	{
 		std::function<bool(const std::string&, const std::string&, const std::string&, std::string&)> updateParameter;
 	};
 	OscServer();
 	~OscServer();
 	bool Start(unsigned short port, const Callbacks& callbacks, std::string& error);
 	void Stop();
 	unsigned short GetPort() const { return mPort; }
 private:
 	friend struct OscServerTestAccess;
 	struct OscMessage
 	{
 		std::string address;
 		std::string valueJson;
 	};
 	void ServerLoop();
 	bool DecodeMessage(const char* data, int byteCount, OscMessage& message, std::string& error) const;
 	bool DispatchMessage(const OscMessage& message, std::string& error) const;
 	static bool DecodeArgument(const char* data, int byteCount, int& offset, char valueType, std::string& valueJson);
 	static bool ReadPaddedString(const char* data, int byteCount, int& offset, std::string& value);
 	static bool ReadInt32(const char* data, int byteCount, int& offset, int& value);
 	static bool ReadFloat32(const char* data, int byteCount, int& offset, double& value);
 	static bool ReadFloat64(const char* data, int byteCount, int& offset, double& value);
 	static std::string BuildJsonString(const std::string& value);
 	Callbacks mCallbacks;
 	UniqueSocket mSocket;
 	unsigned short mPort;
 	std::thread mThread;
 	std::atomic<bool> mRunning;
 };
--- a/apps/LoopThroughWithOpenGLCompositing/control/RuntimeControlBridge.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/control/RuntimeControlBridge.cpp
@@ -1,51 +0,0 @@
 #include "RuntimeControlBridge.h"
 #include "ControlServer.h"
 #include "OpenGLComposite.h"
 #include "OscServer.h"
 #include "RuntimeHost.h"
 bool StartRuntimeControlServices(
 	OpenGLComposite& composite,
 	RuntimeHost& runtimeHost,
 	ControlServer& controlServer,
 	OscServer& oscServer,
 	std::string& error)
 {
 	ControlServer::Callbacks callbacks;
 	callbacks.getStateJson = [&composite]() { return composite.GetRuntimeStateJson(); };
 	callbacks.addLayer = [&composite](const std::string& shaderId, std::string& actionError) { return composite.AddLayer(shaderId, actionError); };
 	callbacks.removeLayer = [&composite](const std::string& layerId, std::string& actionError) { return composite.RemoveLayer(layerId, actionError); };
 	callbacks.moveLayer = [&composite](const std::string& layerId, int direction, std::string& actionError) { return composite.MoveLayer(layerId, direction, actionError); };
 	callbacks.moveLayerToIndex = [&composite](const std::string& layerId, std::size_t targetIndex, std::string& actionError) { return composite.MoveLayerToIndex(layerId, targetIndex, actionError); };
 	callbacks.setLayerBypass = [&composite](const std::string& layerId, bool bypassed, std::string& actionError) { return composite.SetLayerBypass(layerId, bypassed, actionError); };
 	callbacks.setLayerShader = [&composite](const std::string& layerId, const std::string& shaderId, std::string& actionError) { return composite.SetLayerShader(layerId, shaderId, actionError); };
 	callbacks.updateLayerParameter = [&composite](const std::string& layerId, const std::string& parameterId, const std::string& valueJson, std::string& actionError) {
 		return composite.UpdateLayerParameterJson(layerId, parameterId, valueJson, actionError);
 	};
 	callbacks.resetLayerParameters = [&composite](const std::string& layerId, std::string& actionError) { return composite.ResetLayerParameters(layerId, actionError); };
 	callbacks.saveStackPreset = [&composite](const std::string& presetName, std::string& actionError) { return composite.SaveStackPreset(presetName, actionError); };
 	callbacks.loadStackPreset = [&composite](const std::string& presetName, std::string& actionError) { return composite.LoadStackPreset(presetName, actionError); };
 	callbacks.requestScreenshot = [&composite](std::string& actionError) { return composite.RequestScreenshot(actionError); };
 	callbacks.reloadShader = [&composite](std::string& actionError) {
 		if (!composite.ReloadShader())
 		{
 			actionError = "Shader reload failed. See native app status for details.";
 			return false;
 		}
 		return true;
 	};
 	if (!controlServer.Start(runtimeHost.GetUiRoot(), runtimeHost.GetDocsRoot(), runtimeHost.GetServerPort(), callbacks, error))
 		return false;
 	runtimeHost.SetServerPort(controlServer.GetPort());
 	OscServer::Callbacks oscCallbacks;
 	oscCallbacks.updateParameter = [&composite](const std::string& layerKey, const std::string& parameterKey, const std::string& valueJson, std::string& actionError) {
 		return composite.UpdateLayerParameterByControlKeyJson(layerKey, parameterKey, valueJson, actionError);
 	};
 	if (runtimeHost.GetOscPort() > 0 && !oscServer.Start(runtimeHost.GetOscPort(), oscCallbacks, error))
 		return false;
 	return true;
 }
--- a/apps/LoopThroughWithOpenGLCompositing/control/RuntimeControlBridge.h
+++ b/apps/LoopThroughWithOpenGLCompositing/control/RuntimeControlBridge.h
@@ -1,15 +0,0 @@
 #pragma once
 #include <string>
 class ControlServer;
 class OpenGLComposite;
 class OscServer;
 class RuntimeHost;
 bool StartRuntimeControlServices(
 	OpenGLComposite& composite,
 	RuntimeHost& runtimeHost,
 	ControlServer& controlServer,
 	OscServer& oscServer,
 	std::string& error);
--- a/apps/LoopThroughWithOpenGLCompositing/control/RuntimeServices.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/control/RuntimeServices.cpp
@@ -1,119 +0,0 @@
 #include "RuntimeServices.h"
 #include "ControlServer.h"
 #include "OscServer.h"
 #include "RuntimeControlBridge.h"
 #include "RuntimeHost.h"
 #include <windows.h>
 RuntimeServices::RuntimeServices() :
 	mControlServer(std::make_unique<ControlServer>()),
 	mOscServer(std::make_unique<OscServer>()),
 	mPollRunning(false),
 	mRegistryChanged(false),
 	mReloadRequested(false),
 	mPollFailed(false)
 {
 }
 RuntimeServices::~RuntimeServices()
 {
 	Stop();
 }
 bool RuntimeServices::Start(OpenGLComposite& composite, RuntimeHost& runtimeHost, std::string& error)
 {
 	Stop();
 	if (!StartRuntimeControlServices(composite, runtimeHost, *mControlServer, *mOscServer, error))
 	{
 		Stop();
 		return false;
 	}
 	return true;
 }
 void RuntimeServices::BeginPolling(RuntimeHost& runtimeHost)
 {
 	StartPolling(runtimeHost);
 }
 void RuntimeServices::Stop()
 {
 	StopPolling();
 	if (mOscServer)
 		mOscServer->Stop();
 	if (mControlServer)
 		mControlServer->Stop();
 }
 void RuntimeServices::BroadcastState()
 {
 	if (mControlServer)
 		mControlServer->BroadcastState();
 }
 RuntimePollEvents RuntimeServices::ConsumePollEvents()
 {
 	RuntimePollEvents events;
 	events.registryChanged = mRegistryChanged.exchange(false);
 	events.reloadRequested = mReloadRequested.exchange(false);
 	events.failed = mPollFailed.exchange(false);
 	if (events.failed)
 	{
 		std::lock_guard<std::mutex> lock(mPollErrorMutex);
 		events.error = mPollError;
 	}
 	return events;
 }
 void RuntimeServices::StartPolling(RuntimeHost& runtimeHost)
 {
 	if (mPollRunning.exchange(true))
 		return;
 	mPollThread = std::thread([this, &runtimeHost]() { PollLoop(runtimeHost); });
 }
 void RuntimeServices::StopPolling()
 {
 	if (!mPollRunning.exchange(false))
 		return;
 	if (mPollThread.joinable())
 		mPollThread.join();
 }
 void RuntimeServices::PollLoop(RuntimeHost& runtimeHost)
 {
 	while (mPollRunning)
 	{
 		bool registryChanged = false;
 		bool reloadRequested = false;
 		std::string runtimeError;
 		if (!runtimeHost.PollFileChanges(registryChanged, reloadRequested, runtimeError))
 		{
 			{
 				std::lock_guard<std::mutex> lock(mPollErrorMutex);
 				mPollError = runtimeError;
 			}
 			mPollFailed = true;
 		}
 		else
 		{
 			if (registryChanged)
 				mRegistryChanged = true;
 			if (reloadRequested)
 				mReloadRequested = true;
 		}
 		for (int i = 0; i < 25 && mPollRunning; ++i)
 			Sleep(10);
 	}
 }
--- a/apps/LoopThroughWithOpenGLCompositing/control/RuntimeServices.h
+++ b/apps/LoopThroughWithOpenGLCompositing/control/RuntimeServices.h
@@ -1,48 +0,0 @@
 #pragma once
 #include <atomic>
 #include <memory>
 #include <mutex>
 #include <string>
 #include <thread>
 class ControlServer;
 class OpenGLComposite;
 class OscServer;
 class RuntimeHost;
 struct RuntimePollEvents
 {
 	bool registryChanged = false;
 	bool reloadRequested = false;
 	bool failed = false;
 	std::string error;
 };
 class RuntimeServices
 {
 public:
 	RuntimeServices();
 	~RuntimeServices();
 	bool Start(OpenGLComposite& composite, RuntimeHost& runtimeHost, std::string& error);
 	void BeginPolling(RuntimeHost& runtimeHost);
 	void Stop();
 	void BroadcastState();
 	RuntimePollEvents ConsumePollEvents();
 private:
 	void StartPolling(RuntimeHost& runtimeHost);
 	void StopPolling();
 	void PollLoop(RuntimeHost& runtimeHost);
 	std::unique_ptr<ControlServer> mControlServer;
 	std::unique_ptr<OscServer> mOscServer;
 	std::thread mPollThread;
 	std::atomic<bool> mPollRunning;
 	std::atomic<bool> mRegistryChanged;
 	std::atomic<bool> mReloadRequested;
 	std::atomic<bool> mPollFailed;
 	std::mutex mPollErrorMutex;
 	std::string mPollError;
 };
--- a/apps/LoopThroughWithOpenGLCompositing/decklink/DeckLinkDisplayMode.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/decklink/DeckLinkDisplayMode.cpp
@@ -1,146 +0,0 @@
 #include "DeckLinkDisplayMode.h"
 #include <cctype>
 std::string NormalizeModeToken(const std::string& value)
 {
 	std::string normalized;
 	for (unsigned char ch : value)
 	{
 		if (std::isalnum(ch))
 			normalized.push_back(static_cast<char>(std::tolower(ch)));
 	}
 	return normalized;
 }
 bool ResolveConfiguredDisplayMode(const std::string& videoFormat, const std::string& frameRate, BMDDisplayMode& displayMode, std::string& displayModeName)
 {
 	VideoFormat videoMode;
 	if (!ResolveConfiguredVideoFormat(videoFormat, frameRate, videoMode))
 		return false;
 	displayMode = videoMode.displayMode;
 	displayModeName = videoMode.displayName;
 	return true;
 }
 bool ResolveConfiguredVideoFormat(const std::string& videoFormat, const std::string& frameRate, VideoFormat& videoMode)
 {
 	const std::string formatToken = NormalizeModeToken(videoFormat);
 	const std::string frameToken = NormalizeModeToken(frameRate);
 	const std::string combinedToken = formatToken + frameToken;
 	struct ModeOption
 	{
 		const char* token;
 		BMDDisplayMode mode;
 		const char* displayName;
 	};
 	static const ModeOption options[] =
 	{
 		{ "720p50", bmdModeHD720p50, "720p50" },
 		{ "hd720p50", bmdModeHD720p50, "720p50" },
 		{ "720p5994", bmdModeHD720p5994, "720p59.94" },
 		{ "hd720p5994", bmdModeHD720p5994, "720p59.94" },
 		{ "720p60", bmdModeHD720p60, "720p60" },
 		{ "hd720p60", bmdModeHD720p60, "720p60" },
 		{ "1080i50", bmdModeHD1080i50, "1080i50" },
 		{ "hd1080i50", bmdModeHD1080i50, "1080i50" },
 		{ "1080i5994", bmdModeHD1080i5994, "1080i59.94" },
 		{ "hd1080i5994", bmdModeHD1080i5994, "1080i59.94" },
 		{ "1080i60", bmdModeHD1080i6000, "1080i60" },
 		{ "hd1080i60", bmdModeHD1080i6000, "1080i60" },
 		{ "1080p2398", bmdModeHD1080p2398, "1080p23.98" },
 		{ "hd1080p2398", bmdModeHD1080p2398, "1080p23.98" },
 		{ "1080p24", bmdModeHD1080p24, "1080p24" },
 		{ "hd1080p24", bmdModeHD1080p24, "1080p24" },
 		{ "1080p25", bmdModeHD1080p25, "1080p25" },
 		{ "hd1080p25", bmdModeHD1080p25, "1080p25" },
 		{ "1080p2997", bmdModeHD1080p2997, "1080p29.97" },
 		{ "hd1080p2997", bmdModeHD1080p2997, "1080p29.97" },
 		{ "1080p30", bmdModeHD1080p30, "1080p30" },
 		{ "hd1080p30", bmdModeHD1080p30, "1080p30" },
 		{ "1080p50", bmdModeHD1080p50, "1080p50" },
 		{ "hd1080p50", bmdModeHD1080p50, "1080p50" },
 		{ "1080p5994", bmdModeHD1080p5994, "1080p59.94" },
 		{ "hd1080p5994", bmdModeHD1080p5994, "1080p59.94" },
 		{ "1080p60", bmdModeHD1080p6000, "1080p60" },
 		{ "hd1080p60", bmdModeHD1080p6000, "1080p60" },
 		{ "2160p2398", bmdMode4K2160p2398, "2160p23.98" },
 		{ "4k2160p2398", bmdMode4K2160p2398, "2160p23.98" },
 		{ "2160p24", bmdMode4K2160p24, "2160p24" },
 		{ "4k2160p24", bmdMode4K2160p24, "2160p24" },
 		{ "2160p25", bmdMode4K2160p25, "2160p25" },
 		{ "4k2160p25", bmdMode4K2160p25, "2160p25" },
 		{ "2160p2997", bmdMode4K2160p2997, "2160p29.97" },
 		{ "4k2160p2997", bmdMode4K2160p2997, "2160p29.97" },
 		{ "2160p30", bmdMode4K2160p30, "2160p30" },
 		{ "4k2160p30", bmdMode4K2160p30, "2160p30" },
 		{ "2160p50", bmdMode4K2160p50, "2160p50" },
 		{ "4k2160p50", bmdMode4K2160p50, "2160p50" },
 		{ "2160p5994", bmdMode4K2160p5994, "2160p59.94" },
 		{ "4k2160p5994", bmdMode4K2160p5994, "2160p59.94" },
 		{ "2160p60", bmdMode4K2160p60, "2160p60" },
 		{ "4k2160p60", bmdMode4K2160p60, "2160p60" }
 	};
 	for (const ModeOption& option : options)
 	{
 		if (combinedToken == option.token || (frameToken.empty() && formatToken == option.token))
 		{
 			videoMode.displayMode = option.mode;
 			videoMode.displayName = option.displayName;
 			return true;
 		}
 	}
 	return false;
 }
 bool ResolveConfiguredVideoFormats(
 	const std::string& inputVideoFormat,
 	const std::string& inputFrameRate,
 	const std::string& outputVideoFormat,
 	const std::string& outputFrameRate,
 	VideoFormatSelection& videoModes,
 	std::string& error)
 {
 	if (!ResolveConfiguredVideoFormat(inputVideoFormat, inputFrameRate, videoModes.input))
 	{
 		error = "Unsupported DeckLink inputVideoFormat/inputFrameRate in config/runtime-host.json: " +
 			inputVideoFormat + " / " + inputFrameRate;
 		return false;
 	}
 	if (!ResolveConfiguredVideoFormat(outputVideoFormat, outputFrameRate, videoModes.output))
 	{
 		error = "Unsupported DeckLink outputVideoFormat/outputFrameRate in config/runtime-host.json: " +
 			outputVideoFormat + " / " + outputFrameRate;
 		return false;
 	}
 	return true;
 }
 bool FindDeckLinkDisplayMode(IDeckLinkDisplayModeIterator* iterator, BMDDisplayMode targetMode, IDeckLinkDisplayMode** foundMode)
 {
 	if (!iterator || !foundMode)
 		return false;
 	*foundMode = NULL;
 	IDeckLinkDisplayMode* candidate = NULL;
 	while (iterator->Next(&candidate) == S_OK)
 	{
 		if (candidate->GetDisplayMode() == targetMode)
 		{
 			*foundMode = candidate;
 			return true;
 		}
 		candidate->Release();
 		candidate = NULL;
 	}
 	return false;
 }
--- a/apps/LoopThroughWithOpenGLCompositing/decklink/DeckLinkFrameTransfer.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/decklink/DeckLinkFrameTransfer.cpp
@@ -1,104 +0,0 @@
 #include "DeckLinkFrameTransfer.h"
 #include "OpenGLComposite.h"
 ////////////////////////////////////////////
 // DeckLink Capture Delegate Class
 ////////////////////////////////////////////
 CaptureDelegate::CaptureDelegate(OpenGLComposite* pOwner) :
 	m_pOwner(pOwner),
 	mRefCount(1)
 {
 }
 HRESULT CaptureDelegate::QueryInterface(REFIID, LPVOID* ppv)
 {
 	*ppv = NULL;
 	return E_NOINTERFACE;
 }
 ULONG CaptureDelegate::AddRef()
 {
 	return InterlockedIncrement(&mRefCount);
 }
 ULONG CaptureDelegate::Release()
 {
 	int newCount = InterlockedDecrement(&mRefCount);
 	if (newCount == 0)
 		delete this;
 	return newCount;
 }
 HRESULT CaptureDelegate::VideoInputFrameArrived(IDeckLinkVideoInputFrame* inputFrame, IDeckLinkAudioInputPacket*)
 {
 	if (!inputFrame)
 	{
 		// It's possible to receive a NULL inputFrame, but a valid audioPacket. Ignore audio-only frame.
 		return S_OK;
 	}
 	bool hasNoInputSource = (inputFrame->GetFlags() & bmdFrameHasNoInputSource) == bmdFrameHasNoInputSource;
 	m_pOwner->VideoFrameArrived(inputFrame, hasNoInputSource);
 	return S_OK;
 }
 HRESULT CaptureDelegate::VideoInputFormatChanged(BMDVideoInputFormatChangedEvents, IDeckLinkDisplayMode*, BMDDetectedVideoInputFormatFlags)
 {
 	return S_OK;
 }
 ////////////////////////////////////////////
 // DeckLink Playout Delegate Class
 ////////////////////////////////////////////
 PlayoutDelegate::PlayoutDelegate(OpenGLComposite* pOwner) :
 	m_pOwner(pOwner),
 	mRefCount(1)
 {
 }
 HRESULT PlayoutDelegate::QueryInterface(REFIID, LPVOID* ppv)
 {
 	*ppv = NULL;
 	return E_NOINTERFACE;
 }
 ULONG PlayoutDelegate::AddRef()
 {
 	return InterlockedIncrement(&mRefCount);
 }
 ULONG PlayoutDelegate::Release()
 {
 	int newCount = InterlockedDecrement(&mRefCount);
 	if (newCount == 0)
 		delete this;
 	return newCount;
 }
 HRESULT PlayoutDelegate::ScheduledFrameCompleted(IDeckLinkVideoFrame* completedFrame, BMDOutputFrameCompletionResult result)
 {
 	switch (result)
 	{
 	case bmdOutputFrameDisplayedLate:
 		OutputDebugStringA("ScheduledFrameCompleted() frame did not complete: Frame Displayed Late\n");
 		break;
 	case bmdOutputFrameDropped:
 		OutputDebugStringA("ScheduledFrameCompleted() frame did not complete: Frame Dropped\n");
 		break;
 	case bmdOutputFrameCompleted:
 	case bmdOutputFrameFlushed:
 		// Don't log bmdOutputFrameFlushed result since it is expected when Stop() is called
 		break;
 	default:
 		OutputDebugStringA("ScheduledFrameCompleted() frame did not complete: Unknown error\n");
 	}
 	m_pOwner->PlayoutFrameCompleted(completedFrame, result);
 	return S_OK;
 }
 HRESULT PlayoutDelegate::ScheduledPlaybackHasStopped()
 {
 	return S_OK;
 }
--- a/apps/LoopThroughWithOpenGLCompositing/decklink/DeckLinkFrameTransfer.h
+++ b/apps/LoopThroughWithOpenGLCompositing/decklink/DeckLinkFrameTransfer.h
@@ -1,49 +0,0 @@
 #pragma once
 #include <windows.h>
 #include <atomic>
 #include "DeckLinkAPI_h.h"
 class OpenGLComposite;
 ////////////////////////////////////////////
 // Capture Delegate Class
 ////////////////////////////////////////////
 class CaptureDelegate : public IDeckLinkInputCallback
 {
 	OpenGLComposite* m_pOwner;
 	LONG mRefCount;
 public:
 	CaptureDelegate(OpenGLComposite* pOwner);
 	// IUnknown needs only a dummy implementation
 	virtual HRESULT STDMETHODCALLTYPE QueryInterface(REFIID iid, LPVOID* ppv);
 	virtual ULONG STDMETHODCALLTYPE AddRef();
 	virtual ULONG STDMETHODCALLTYPE Release();
 	virtual HRESULT STDMETHODCALLTYPE VideoInputFrameArrived(IDeckLinkVideoInputFrame* videoFrame, IDeckLinkAudioInputPacket* audioPacket);
 	virtual HRESULT STDMETHODCALLTYPE VideoInputFormatChanged(BMDVideoInputFormatChangedEvents notificationEvents, IDeckLinkDisplayMode* newDisplayMode, BMDDetectedVideoInputFormatFlags detectedSignalFlags);
 };
 ////////////////////////////////////////////
 // Render Delegate Class
 ////////////////////////////////////////////
 class PlayoutDelegate : public IDeckLinkVideoOutputCallback
 {
 	OpenGLComposite* m_pOwner;
 	LONG mRefCount;
 public:
 	PlayoutDelegate(OpenGLComposite* pOwner);
 	// IUnknown needs only a dummy implementation
 	virtual HRESULT STDMETHODCALLTYPE QueryInterface(REFIID iid, LPVOID* ppv);
 	virtual ULONG STDMETHODCALLTYPE AddRef();
 	virtual ULONG STDMETHODCALLTYPE Release();
 	virtual HRESULT STDMETHODCALLTYPE ScheduledFrameCompleted(IDeckLinkVideoFrame* completedFrame, BMDOutputFrameCompletionResult result);
 	virtual HRESULT STDMETHODCALLTYPE ScheduledPlaybackHasStopped();
 };
--- a/apps/LoopThroughWithOpenGLCompositing/decklink/DeckLinkSession.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/decklink/DeckLinkSession.cpp
@@ -1,518 +0,0 @@
 #include "DeckLinkSession.h"
 #include "GlRenderConstants.h"
 #include <atlbase.h>
 #include <cstdio>
 #include <cstring>
 #include <new>
 #include <sstream>
 #include <vector>
 namespace
 {
 std::string BstrToUtf8(BSTR value)
 {
 	if (value == nullptr)
 		return std::string();
 	const int requiredBytes = WideCharToMultiByte(CP_UTF8, 0, value, -1, NULL, 0, NULL, NULL);
 	if (requiredBytes <= 1)
 		return std::string();
 	std::vector<char> utf8Name(static_cast<std::size_t>(requiredBytes), '\0');
 	if (WideCharToMultiByte(CP_UTF8, 0, value, -1, utf8Name.data(), requiredBytes, NULL, NULL) <= 0)
 		return std::string();
 	return std::string(utf8Name.data());
 }
 bool InputSupportsFormat(IDeckLinkInput* input, BMDDisplayMode displayMode, BMDPixelFormat pixelFormat)
 {
 	if (input == nullptr)
 		return false;
 	BOOL supported = FALSE;
 	BMDDisplayMode actualMode = bmdModeUnknown;
 	const HRESULT result = input->DoesSupportVideoMode(
 		bmdVideoConnectionUnspecified,
 		displayMode,
 		pixelFormat,
 		bmdNoVideoInputConversion,
 		bmdSupportedVideoModeDefault,
 		&actualMode,
 		&supported);
 	return result == S_OK && supported != FALSE;
 }
 bool OutputSupportsFormat(IDeckLinkOutput* output, BMDDisplayMode displayMode, BMDPixelFormat pixelFormat)
 {
 	if (output == nullptr)
 		return false;
 	BOOL supported = FALSE;
 	BMDDisplayMode actualMode = bmdModeUnknown;
 	const HRESULT result = output->DoesSupportVideoMode(
 		bmdVideoConnectionUnspecified,
 		displayMode,
 		pixelFormat,
 		bmdNoVideoOutputConversion,
 		bmdSupportedVideoModeDefault,
 		&actualMode,
 		&supported);
 	return result == S_OK && supported != FALSE;
 }
 }
 DeckLinkSession::~DeckLinkSession()
 {
 	ReleaseResources();
 }
 void DeckLinkSession::ReleaseResources()
 {
 	if (input != nullptr)
 		input->SetCallback(nullptr);
 	captureDelegate.Release();
 	input.Release();
 	if (output != nullptr)
 		output->SetScheduledFrameCompletionCallback(nullptr);
 	if (keyer != nullptr)
 	{
 		keyer->Disable();
 		externalKeyingActive = false;
 	}
 	keyer.Release();
 	playoutDelegate.Release();
 	outputVideoFrameQueue.clear();
 	output.Release();
 }
 bool DeckLinkSession::DiscoverDevicesAndModes(const VideoFormatSelection& videoModes, std::string& error)
 {
 	CComPtr<IDeckLinkIterator> deckLinkIterator;
 	CComPtr<IDeckLinkDisplayMode> inputMode;
 	CComPtr<IDeckLinkDisplayMode> outputMode;
 	inputDisplayModeName = videoModes.input.displayName;
 	outputDisplayModeName = videoModes.output.displayName;
 	HRESULT result = CoCreateInstance(CLSID_CDeckLinkIterator, nullptr, CLSCTX_ALL, IID_IDeckLinkIterator, reinterpret_cast<void**>(&deckLinkIterator));
 	if (FAILED(result))
 	{
 		error = "Please install the Blackmagic DeckLink drivers to use the features of this application.";
 		return false;
 	}
 	CComPtr<IDeckLink> deckLink;
 	while (deckLinkIterator->Next(&deckLink) == S_OK)
 	{
 		int64_t duplexMode;
 		bool deviceSupportsInternalKeying = false;
 		bool deviceSupportsExternalKeying = false;
 		std::string modelName;
 		CComPtr<IDeckLinkProfileAttributes> deckLinkAttributes;
 		if (deckLink->QueryInterface(IID_IDeckLinkProfileAttributes, (void**)&deckLinkAttributes) != S_OK)
 		{
 			printf("Could not obtain the IDeckLinkProfileAttributes interface\n");
 			deckLink.Release();
 			continue;
 		}
 		result = deckLinkAttributes->GetInt(BMDDeckLinkDuplex, &duplexMode);
 		BOOL attributeFlag = FALSE;
 		if (deckLinkAttributes->GetFlag(BMDDeckLinkSupportsInternalKeying, &attributeFlag) == S_OK)
 			deviceSupportsInternalKeying = (attributeFlag != FALSE);
 		attributeFlag = FALSE;
 		if (deckLinkAttributes->GetFlag(BMDDeckLinkSupportsExternalKeying, &attributeFlag) == S_OK)
 			deviceSupportsExternalKeying = (attributeFlag != FALSE);
 		CComBSTR modelNameBstr;
 		if (deckLinkAttributes->GetString(BMDDeckLinkModelName, &modelNameBstr) == S_OK)
 			modelName = BstrToUtf8(modelNameBstr);
 		if (result != S_OK || duplexMode == bmdDuplexInactive)
 		{
 			deckLink.Release();
 			continue;
 		}
 		bool inputUsed = false;
 		if (!input && deckLink->QueryInterface(IID_IDeckLinkInput, (void**)&input) == S_OK)
 			inputUsed = true;
 		if (!output && (!inputUsed || (duplexMode == bmdDuplexFull)))
 		{
 			if (deckLink->QueryInterface(IID_IDeckLinkOutput, (void**)&output) != S_OK)
 				output.Release();
 			else
 			{
 				outputModelName = modelName;
 				supportsInternalKeying = deviceSupportsInternalKeying;
 				supportsExternalKeying = deviceSupportsExternalKeying;
 			}
 		}
 		deckLink.Release();
 		if (output && input)
 			break;
 	}
 	if (!output)
 	{
 		error = "Expected an Output DeckLink device";
 		ReleaseResources();
 		return false;
 	}
 	CComPtr<IDeckLinkDisplayModeIterator> inputDisplayModeIterator;
 	if (input && input->GetDisplayModeIterator(&inputDisplayModeIterator) != S_OK)
 	{
 		error = "Cannot get input Display Mode Iterator.";
 		ReleaseResources();
 		return false;
 	}
 	if (input && !FindDeckLinkDisplayMode(inputDisplayModeIterator, videoModes.input.displayMode, &inputMode))
 	{
 		error = "Cannot get specified input BMDDisplayMode for configured mode: " + videoModes.input.displayName;
 		ReleaseResources();
 		return false;
 	}
 	inputDisplayModeIterator.Release();
 	CComPtr<IDeckLinkDisplayModeIterator> outputDisplayModeIterator;
 	if (output->GetDisplayModeIterator(&outputDisplayModeIterator) != S_OK)
 	{
 		error = "Cannot get output Display Mode Iterator.";
 		ReleaseResources();
 		return false;
 	}
 	if (!FindDeckLinkDisplayMode(outputDisplayModeIterator, videoModes.output.displayMode, &outputMode))
 	{
 		error = "Cannot get specified output BMDDisplayMode for configured mode: " + videoModes.output.displayName;
 		ReleaseResources();
 		return false;
 	}
 	outputFrameSize = { static_cast<unsigned>(outputMode->GetWidth()), static_cast<unsigned>(outputMode->GetHeight()) };
 	inputFrameSize = inputMode
 		? FrameSize{ static_cast<unsigned>(inputMode->GetWidth()), static_cast<unsigned>(inputMode->GetHeight()) }
 		: outputFrameSize;
 	if (!input)
 		inputDisplayModeName = "No input - black frame";
 	outputMode->GetFrameRate(&frameDuration, &frameTimescale);
 	inputFrameRowBytes = inputFrameSize.width * 2u;
 	outputFrameRowBytes = outputFrameSize.width * 4u;
 	captureTextureWidth = inputFrameSize.width / 2u;
 	outputPackTextureWidth = outputFrameSize.width;
 	return true;
 }
 bool DeckLinkSession::SelectPreferredFormats(const VideoFormatSelection& videoModes, std::string& error)
 {
 	if (!output)
 	{
 		error = "Expected an Output DeckLink device";
 		return false;
 	}
 	formatStatusMessage.clear();
 	const bool inputTenBitSupported = input != nullptr && InputSupportsFormat(input, videoModes.input.displayMode, bmdFormat10BitYUV);
 	inputPixelFormat = input != nullptr ? ChoosePreferredVideoIOFormat(inputTenBitSupported) : VideoIOPixelFormat::Uyvy8;
 	if (input != nullptr && !inputTenBitSupported)
 		formatStatusMessage += "DeckLink input does not report 10-bit YUV support for the configured mode; using 8-bit capture. ";
 	const bool outputTenBitSupported = OutputSupportsFormat(output, videoModes.output.displayMode, bmdFormat10BitYUV);
 	outputPixelFormat = ChoosePreferredVideoIOFormat(outputTenBitSupported);
 	if (!outputTenBitSupported)
 		formatStatusMessage += "DeckLink output does not report 10-bit YUV support for the configured mode; using 8-bit BGRA output. ";
 	int deckLinkOutputRowBytes = 0;
 	if (output->RowBytesForPixelFormat(OutputIsTenBit() ? bmdFormat10BitYUV : bmdFormat8BitBGRA, outputFrameSize.width, &deckLinkOutputRowBytes) != S_OK)
 	{
 		error = "DeckLink output setup failed while calculating output row bytes.";
 		return false;
 	}
 	outputFrameRowBytes = static_cast<unsigned>(deckLinkOutputRowBytes);
 	outputPackTextureWidth = OutputIsTenBit()
 		? PackedTextureWidthFromRowBytes(outputFrameRowBytes)
 		: outputFrameSize.width;
 	if (InputIsTenBit())
 	{
 		int deckLinkInputRowBytes = 0;
 		if (output->RowBytesForPixelFormat(bmdFormat10BitYUV, inputFrameSize.width, &deckLinkInputRowBytes) == S_OK)
 			inputFrameRowBytes = static_cast<unsigned>(deckLinkInputRowBytes);
 		else
 			inputFrameRowBytes = MinimumV210RowBytes(inputFrameSize.width);
 	}
 	else
 	{
 		inputFrameRowBytes = inputFrameSize.width * 2u;
 	}
 	captureTextureWidth = InputIsTenBit()
 		? PackedTextureWidthFromRowBytes(inputFrameRowBytes)
 		: inputFrameSize.width / 2u;
 	std::ostringstream status;
 	status << "DeckLink formats: capture " << (input ? VideoIOPixelFormatName(inputPixelFormat) : "none")
 		<< ", output " << (OutputIsTenBit() ? "10-bit YUV v210" : "8-bit BGRA") << ".";
 	if (!formatStatusMessage.empty())
 		status << " " << formatStatusMessage;
 	formatStatusMessage = status.str();
 	return true;
 }
 bool DeckLinkSession::ConfigureInput(OpenGLComposite* owner, HDC hdc, HGLRC hglrc, const VideoFormat& inputVideoMode, std::string& error)
 {
 	(void)hdc;
 	(void)hglrc;
 	if (!input)
 	{
 		hasNoInputSource = true;
 		inputDisplayModeName = "No input - black frame";
 		return true;
 	}
 	const BMDPixelFormat deckLinkInputPixelFormat = DeckLinkPixelFormatForVideoIO(inputPixelFormat);
 	if (input->EnableVideoInput(inputVideoMode.displayMode, deckLinkInputPixelFormat, bmdVideoInputFlagDefault) != S_OK)
 	{
 		if (inputPixelFormat == VideoIOPixelFormat::V210)
 		{
 			OutputDebugStringA("DeckLink 10-bit input could not be enabled; falling back to 8-bit capture.\n");
 			inputPixelFormat = VideoIOPixelFormat::Uyvy8;
 			inputFrameRowBytes = inputFrameSize.width * 2u;
 			captureTextureWidth = inputFrameSize.width / 2u;
 			if (input->EnableVideoInput(inputVideoMode.displayMode, bmdFormat8BitYUV, bmdVideoInputFlagDefault) == S_OK)
 			{
 				std::ostringstream status;
 				status << "DeckLink formats: capture " << VideoIOPixelFormatName(inputPixelFormat)
 					<< ", output " << (OutputIsTenBit() ? "10-bit YUV v210" : "8-bit BGRA")
 					<< ". DeckLink 10-bit input enable failed; using 8-bit capture.";
 				formatStatusMessage = status.str();
 				goto input_enabled;
 			}
 		}
 		OutputDebugStringA("DeckLink input could not be enabled; continuing in output-only black-frame mode.\n");
 		input.Release();
 		hasNoInputSource = true;
 		inputDisplayModeName = "No input - black frame";
 		return true;
 	}
 input_enabled:
 	captureDelegate.Attach(new (std::nothrow) CaptureDelegate(owner));
 	if (captureDelegate == nullptr)
 	{
 		error = "DeckLink input setup failed while creating the capture callback.";
 		return false;
 	}
 	if (input->SetCallback(captureDelegate) != S_OK)
 	{
 		error = "DeckLink input setup failed while installing the capture callback.";
 		return false;
 	}
 	return true;
 }
 bool DeckLinkSession::ConfigureOutput(OpenGLComposite* owner, HDC hdc, HGLRC hglrc, const VideoFormat& outputVideoMode, bool externalKeyingEnabled, std::string& error)
 {
 	(void)hdc;
 	(void)hglrc;
 	if (output->EnableVideoOutput(outputVideoMode.displayMode, bmdVideoOutputFlagDefault) != S_OK)
 	{
 		error = "DeckLink output setup failed while enabling video output.";
 		return false;
 	}
 	if (output->QueryInterface(IID_IDeckLinkKeyer, (void**)&keyer) == S_OK && keyer != NULL)
 		keyerInterfaceAvailable = true;
 	if (externalKeyingEnabled)
 	{
 		if (!supportsExternalKeying)
 		{
 			statusMessage = "External keying was requested, but the selected DeckLink output does not report external keying support.";
 		}
 		else if (!keyerInterfaceAvailable)
 		{
 			statusMessage = "External keying was requested, but the selected DeckLink output does not expose the IDeckLinkKeyer interface.";
 		}
 		else if (keyer->Enable(TRUE) != S_OK || keyer->SetLevel(255) != S_OK)
 		{
 			statusMessage = "External keying was requested, but enabling the DeckLink keyer failed.";
 		}
 		else
 		{
 			externalKeyingActive = true;
 			statusMessage = "External keying is active on the selected DeckLink output.";
 		}
 	}
 	else if (supportsExternalKeying)
 	{
 		statusMessage = "Selected DeckLink output supports external keying. Set enableExternalKeying to true in runtime-host.json to request it.";
 	}
 	for (int i = 0; i < 10; i++)
 	{
 		CComPtr<IDeckLinkMutableVideoFrame> outputFrame;
 		const BMDPixelFormat deckLinkOutputPixelFormat = OutputIsTenBit() ? bmdFormat10BitYUV : bmdFormat8BitBGRA;
 		if (output->CreateVideoFrame(outputFrameSize.width, outputFrameSize.height, outputFrameRowBytes, deckLinkOutputPixelFormat, bmdFrameFlagFlipVertical, &outputFrame) != S_OK)
 		{
 			error = "DeckLink output setup failed while creating an output video frame.";
 			return false;
 		}
 		outputVideoFrameQueue.push_back(outputFrame);
 	}
 	playoutDelegate.Attach(new (std::nothrow) PlayoutDelegate(owner));
 	if (playoutDelegate == nullptr)
 	{
 		error = "DeckLink output setup failed while creating the playout callback.";
 		return false;
 	}
 	if (output->SetScheduledFrameCompletionCallback(playoutDelegate) != S_OK)
 	{
 		error = "DeckLink output setup failed while installing the scheduled-frame callback.";
 		return false;
 	}
 	if (!formatStatusMessage.empty())
 		statusMessage = statusMessage.empty() ? formatStatusMessage : formatStatusMessage + " " + statusMessage;
 	return true;
 }
 double DeckLinkSession::FrameBudgetMilliseconds() const
 {
 	return frameTimescale != 0
 		? (static_cast<double>(frameDuration) * 1000.0) / static_cast<double>(frameTimescale)
 		: 0.0;
 }
 IDeckLinkMutableVideoFrame* DeckLinkSession::RotateOutputFrame()
 {
 	CComPtr<IDeckLinkMutableVideoFrame> outputVideoFrame = outputVideoFrameQueue.front();
 	outputVideoFrameQueue.push_back(outputVideoFrame);
 	outputVideoFrameQueue.pop_front();
 	return outputVideoFrame.p;
 }
 void DeckLinkSession::AccountForCompletionResult(BMDOutputFrameCompletionResult completionResult)
 {
 	if (completionResult == bmdOutputFrameDisplayedLate || completionResult == bmdOutputFrameDropped)
 		totalPlayoutFrames += 2;
 }
 bool DeckLinkSession::ScheduleOutputFrame(IDeckLinkMutableVideoFrame* outputVideoFrame)
 {
 	if (output->ScheduleVideoFrame(outputVideoFrame, (totalPlayoutFrames * frameDuration), frameDuration, frameTimescale) != S_OK)
 		return false;
 	totalPlayoutFrames++;
 	return true;
 }
 bool DeckLinkSession::Start()
 {
 	totalPlayoutFrames = 0;
 	if (!output)
 	{
 		MessageBoxA(NULL, "Cannot start playout because no DeckLink output device is available.", "DeckLink start failed", MB_OK | MB_ICONERROR);
 		return false;
 	}
 	if (outputVideoFrameQueue.empty())
 	{
 		MessageBoxA(NULL, "Cannot start playout because the output frame queue is empty.", "DeckLink start failed", MB_OK | MB_ICONERROR);
 		return false;
 	}
 	for (unsigned i = 0; i < kPrerollFrameCount; i++)
 	{
 		CComPtr<IDeckLinkMutableVideoFrame> outputVideoFrame = outputVideoFrameQueue.front();
 		outputVideoFrameQueue.push_back(outputVideoFrame);
 		outputVideoFrameQueue.pop_front();
 		CComPtr<IDeckLinkVideoBuffer> outputVideoFrameBuffer;
 		if (outputVideoFrame->QueryInterface(IID_IDeckLinkVideoBuffer, (void**)&outputVideoFrameBuffer) != S_OK)
 		{
 			MessageBoxA(NULL, "Could not query the preroll output frame buffer.", "DeckLink start failed", MB_OK | MB_ICONERROR);
 			return false;
 		}
 		if (outputVideoFrameBuffer->StartAccess(bmdBufferAccessWrite) != S_OK)
 		{
 			MessageBoxA(NULL, "Could not write to the preroll output frame buffer.", "DeckLink start failed", MB_OK | MB_ICONERROR);
 			return false;
 		}
 		void* pFrame;
 		outputVideoFrameBuffer->GetBytes((void**)&pFrame);
 		memset(pFrame, 0, outputVideoFrame->GetRowBytes() * outputFrameSize.height);
 		outputVideoFrameBuffer->EndAccess(bmdBufferAccessWrite);
 		if (output->ScheduleVideoFrame(outputVideoFrame, (totalPlayoutFrames * frameDuration), frameDuration, frameTimescale) != S_OK)
 		{
 			MessageBoxA(NULL, "Could not schedule a preroll output frame.", "DeckLink start failed", MB_OK | MB_ICONERROR);
 			return false;
 		}
 		totalPlayoutFrames++;
 	}
 	if (input)
 	{
 		if (input->StartStreams() != S_OK)
 		{
 			MessageBoxA(NULL, "Could not start the DeckLink input stream.", "DeckLink start failed", MB_OK | MB_ICONERROR);
 			return false;
 		}
 	}
 	if (output->StartScheduledPlayback(0, frameTimescale, 1.0) != S_OK)
 	{
 		MessageBoxA(NULL, "Could not start DeckLink scheduled playback.", "DeckLink start failed", MB_OK | MB_ICONERROR);
 		return false;
 	}
 	return true;
 }
 bool DeckLinkSession::Stop()
 {
 	if (keyer != nullptr)
 	{
 		keyer->Disable();
 		externalKeyingActive = false;
 	}
 	if (input)
 	{
 		input->StopStreams();
 		input->DisableVideoInput();
 	}
 	if (output)
 	{
 		output->StopScheduledPlayback(0, NULL, 0);
 		output->DisableVideoOutput();
 	}
 	return true;
 }
--- a/apps/LoopThroughWithOpenGLCompositing/decklink/DeckLinkSession.h
+++ b/apps/LoopThroughWithOpenGLCompositing/decklink/DeckLinkSession.h
@@ -1,88 +0,0 @@
 #pragma once
 #include "DeckLinkAPI_h.h"
 #include "DeckLinkDisplayMode.h"
 #include "DeckLinkFrameTransfer.h"
 #include "VideoIOFormat.h"
 #include <atlbase.h>
 #include <deque>
 #include <string>
 class OpenGLComposite;
 class DeckLinkSession
 {
 public:
 	DeckLinkSession() = default;
 	~DeckLinkSession();
 	void ReleaseResources();
 	bool DiscoverDevicesAndModes(const VideoFormatSelection& videoModes, std::string& error);
 	bool SelectPreferredFormats(const VideoFormatSelection& videoModes, std::string& error);
 	bool ConfigureInput(OpenGLComposite* owner, HDC hdc, HGLRC hglrc, const VideoFormat& inputVideoMode, std::string& error);
 	bool ConfigureOutput(OpenGLComposite* owner, HDC hdc, HGLRC hglrc, const VideoFormat& outputVideoMode, bool externalKeyingEnabled, std::string& error);
 	bool Start();
 	bool Stop();
 	bool HasInputDevice() const { return input != nullptr; }
 	bool HasInputSource() const { return !hasNoInputSource; }
 	void SetInputSourceMissing(bool missing) { hasNoInputSource = missing; }
 	bool InputOutputDimensionsDiffer() const { return inputFrameSize != outputFrameSize; }
 	const FrameSize& InputFrameSize() const { return inputFrameSize; }
 	const FrameSize& OutputFrameSize() const { return outputFrameSize; }
 	unsigned InputFrameWidth() const { return inputFrameSize.width; }
 	unsigned InputFrameHeight() const { return inputFrameSize.height; }
 	unsigned OutputFrameWidth() const { return outputFrameSize.width; }
 	unsigned OutputFrameHeight() const { return outputFrameSize.height; }
 	VideoIOPixelFormat InputPixelFormat() const { return inputPixelFormat; }
 	VideoIOPixelFormat OutputPixelFormat() const { return outputPixelFormat; }
 	bool InputIsTenBit() const { return VideoIOPixelFormatIsTenBit(inputPixelFormat); }
 	bool OutputIsTenBit() const { return VideoIOPixelFormatIsTenBit(outputPixelFormat); }
 	unsigned InputFrameRowBytes() const { return inputFrameRowBytes; }
 	unsigned OutputFrameRowBytes() const { return outputFrameRowBytes; }
 	unsigned CaptureTextureWidth() const { return captureTextureWidth; }
 	unsigned OutputPackTextureWidth() const { return outputPackTextureWidth; }
 	const std::string& FormatStatusMessage() const { return formatStatusMessage; }
 	const std::string& InputDisplayModeName() const { return inputDisplayModeName; }
 	const std::string& OutputModelName() const { return outputModelName; }
 	bool SupportsInternalKeying() const { return supportsInternalKeying; }
 	bool SupportsExternalKeying() const { return supportsExternalKeying; }
 	bool KeyerInterfaceAvailable() const { return keyerInterfaceAvailable; }
 	bool ExternalKeyingActive() const { return externalKeyingActive; }
 	const std::string& StatusMessage() const { return statusMessage; }
 	void SetStatusMessage(const std::string& message) { statusMessage = message; }
 	double FrameBudgetMilliseconds() const;
 	IDeckLinkMutableVideoFrame* RotateOutputFrame();
 	void AccountForCompletionResult(BMDOutputFrameCompletionResult completionResult);
 	bool ScheduleOutputFrame(IDeckLinkMutableVideoFrame* outputVideoFrame);
 private:
 	CComPtr<CaptureDelegate>				captureDelegate;
 	CComPtr<PlayoutDelegate>				playoutDelegate;
 	CComPtr<IDeckLinkInput>					input;
 	CComPtr<IDeckLinkOutput>				output;
 	CComPtr<IDeckLinkKeyer>					keyer;
 	std::deque<CComPtr<IDeckLinkMutableVideoFrame>> outputVideoFrameQueue;
 	BMDTimeValue							frameDuration = 0;
 	BMDTimeScale							frameTimescale = 0;
 	unsigned								totalPlayoutFrames = 0;
 	FrameSize								inputFrameSize;
 	FrameSize								outputFrameSize;
 	VideoIOPixelFormat						inputPixelFormat = VideoIOPixelFormat::Uyvy8;
 	VideoIOPixelFormat						outputPixelFormat = VideoIOPixelFormat::Uyvy8;
 	unsigned								inputFrameRowBytes = 0;
 	unsigned								outputFrameRowBytes = 0;
 	unsigned								captureTextureWidth = 0;
 	unsigned								outputPackTextureWidth = 0;
 	std::string								inputDisplayModeName = "1080p59.94";
 	std::string								outputDisplayModeName = "1080p59.94";
 	bool									hasNoInputSource = true;
 	std::string								outputModelName;
 	bool									supportsInternalKeying = false;
 	bool									supportsExternalKeying = false;
 	bool									keyerInterfaceAvailable = false;
 	bool									externalKeyingActive = false;
 	std::string								statusMessage;
 	std::string								formatStatusMessage;
 };
--- a/apps/LoopThroughWithOpenGLCompositing/gl/GlRenderConstants.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/GlRenderConstants.h
@@ -1,9 +0,0 @@
 #pragma once
 #include <gl/gl.h>
 constexpr GLuint kDecodedVideoTextureUnit = 1;
 constexpr GLuint kSourceHistoryTextureUnitBase = 2;
 constexpr GLuint kPackedVideoTextureUnit = 2;
 constexpr GLuint kGlobalParamsBindingPoint = 0;
 constexpr unsigned kPrerollFrameCount = 8;
--- a/apps/LoopThroughWithOpenGLCompositing/gl/GlScopedObjects.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/GlScopedObjects.h
@@ -1,57 +0,0 @@
 #pragma once
 #include <gl/gl.h>
 class ScopedGlShader
 {
 public:
 	explicit ScopedGlShader(GLuint shader = 0) : mShader(shader) {}
 	~ScopedGlShader() { reset(); }
 	ScopedGlShader(const ScopedGlShader&) = delete;
 	ScopedGlShader& operator=(const ScopedGlShader&) = delete;
 	GLuint get() const { return mShader; }
 	GLuint release()
 	{
 		GLuint shader = mShader;
 		mShader = 0;
 		return shader;
 	}
 	void reset(GLuint shader = 0)
 	{
 		if (mShader != 0)
 			glDeleteShader(mShader);
 		mShader = shader;
 	}
 private:
 	GLuint mShader;
 };
 class ScopedGlProgram
 {
 public:
 	explicit ScopedGlProgram(GLuint program = 0) : mProgram(program) {}
 	~ScopedGlProgram() { reset(); }
 	ScopedGlProgram(const ScopedGlProgram&) = delete;
 	ScopedGlProgram& operator=(const ScopedGlProgram&) = delete;
 	GLuint get() const { return mProgram; }
 	GLuint release()
 	{
 		GLuint program = mProgram;
 		mProgram = 0;
 		return program;
 	}
 	void reset(GLuint program = 0)
 	{
 		if (mProgram != 0)
 			glDeleteProgram(mProgram);
 		mProgram = program;
 	}
 private:
 	GLuint mProgram;
 };
--- a/apps/LoopThroughWithOpenGLCompositing/gl/GlShaderSources.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/GlShaderSources.cpp
@@ -1,141 +0,0 @@
 #include "GlShaderSources.h"
 const char* kFullscreenTriangleVertexShaderSource =
 	"#version 430 core\n"
 	"out vec2 vTexCoord;\n"
 	"void main()\n"
 	"{\n"
 	"	vec2 positions[3] = vec2[3](vec2(-1.0, -1.0), vec2(3.0, -1.0), vec2(-1.0, 3.0));\n"
 	"	vec2 texCoords[3] = vec2[3](vec2(0.0, 0.0), vec2(2.0, 0.0), vec2(0.0, 2.0));\n"
 	"	gl_Position = vec4(positions[gl_VertexID], 0.0, 1.0);\n"
 	"	vTexCoord = texCoords[gl_VertexID];\n"
 	"}\n";
 const char* kDecodeFragmentShaderSource =
 	"#version 430 core\n"
 	"layout(binding = 2) uniform sampler2D uPackedVideoInput;\n"
 	"uniform vec2 uPackedVideoResolution;\n"
 	"uniform vec2 uDecodedVideoResolution;\n"
 	"uniform int uInputPixelFormat;\n"
 	"in vec2 vTexCoord;\n"
 	"layout(location = 0) out vec4 fragColor;\n"
 	"vec4 rec709YCbCr2rgba(float Y, float Cb, float Cr, float a)\n"
 	"{\n"
 	"	Y = (Y * 256.0 - 16.0) / 219.0;\n"
 	"	Cb = (Cb * 256.0 - 16.0) / 224.0 - 0.5;\n"
 	"	Cr = (Cr * 256.0 - 16.0) / 224.0 - 0.5;\n"
 	"	return vec4(Y + 1.5748 * Cr, Y - 0.1873 * Cb - 0.4681 * Cr, Y + 1.8556 * Cb, a);\n"
 	"}\n"
 	"vec4 rec709YCbCr10_2rgba(float Y, float Cb, float Cr, float a)\n"
 	"{\n"
 	"	Y = (Y - 64.0) / 876.0;\n"
 	"	Cb = (Cb - 64.0) / 896.0 - 0.5;\n"
 	"	Cr = (Cr - 64.0) / 896.0 - 0.5;\n"
 	"	return vec4(Y + 1.5748 * Cr, Y - 0.1873 * Cb - 0.4681 * Cr, Y + 1.8556 * Cb, a);\n"
 	"}\n"
 	"uint loadV210Word(ivec2 coord)\n"
 	"{\n"
 	"	vec4 b = round(texelFetch(uPackedVideoInput, coord, 0) * 255.0);\n"
 	"	return uint(b.r) | (uint(b.g) << 8) | (uint(b.b) << 16) | (uint(b.a) << 24);\n"
 	"}\n"
 	"float v210Component(uint word, int index)\n"
 	"{\n"
 	"	return float((word >> uint(index * 10)) & 1023u);\n"
 	"}\n"
 	"vec4 decodeUyvy8(ivec2 outputCoord, ivec2 packedSize)\n"
 	"{\n"
 	"	ivec2 packedCoord = ivec2(clamp(outputCoord.x / 2, 0, packedSize.x - 1), clamp(outputCoord.y, 0, packedSize.y - 1));\n"
 	"	vec4 macroPixel = texelFetch(uPackedVideoInput, packedCoord, 0);\n"
 	"	float ySample = (outputCoord.x & 1) != 0 ? macroPixel.a : macroPixel.g;\n"
 	"	return rec709YCbCr2rgba(ySample, macroPixel.b, macroPixel.r, 1.0);\n"
 	"}\n"
 	"vec4 decodeV210(ivec2 outputCoord, ivec2 packedSize)\n"
 	"{\n"
 	"	int group = outputCoord.x / 6;\n"
 	"	int pixel = outputCoord.x - group * 6;\n"
 	"	int wordBase = group * 4;\n"
 	"	ivec2 rowBase = ivec2(wordBase, clamp(outputCoord.y, 0, packedSize.y - 1));\n"
 	"	uint w0 = loadV210Word(ivec2(min(rowBase.x + 0, packedSize.x - 1), rowBase.y));\n"
 	"	uint w1 = loadV210Word(ivec2(min(rowBase.x + 1, packedSize.x - 1), rowBase.y));\n"
 	"	uint w2 = loadV210Word(ivec2(min(rowBase.x + 2, packedSize.x - 1), rowBase.y));\n"
 	"	uint w3 = loadV210Word(ivec2(min(rowBase.x + 3, packedSize.x - 1), rowBase.y));\n"
 	"	float y0 = v210Component(w0, 1);\n"
 	"	float y1 = v210Component(w1, 0);\n"
 	"	float y2 = v210Component(w1, 2);\n"
 	"	float y3 = v210Component(w2, 1);\n"
 	"	float y4 = v210Component(w3, 0);\n"
 	"	float y5 = v210Component(w3, 2);\n"
 	"	float cb0 = v210Component(w0, 0);\n"
 	"	float cr0 = v210Component(w0, 2);\n"
 	"	float cb2 = v210Component(w1, 1);\n"
 	"	float cr2 = v210Component(w2, 0);\n"
 	"	float cb4 = v210Component(w2, 2);\n"
 	"	float cr4 = v210Component(w3, 1);\n"
 	"	float ySample = pixel == 0 ? y0 : pixel == 1 ? y1 : pixel == 2 ? y2 : pixel == 3 ? y3 : pixel == 4 ? y4 : y5;\n"
 	"	float cbSample = pixel < 2 ? cb0 : pixel < 4 ? cb2 : cb4;\n"
 	"	float crSample = pixel < 2 ? cr0 : pixel < 4 ? cr2 : cr4;\n"
 	"	return rec709YCbCr10_2rgba(ySample, cbSample, crSample, 1.0);\n"
 	"}\n"
 	"void main()\n"
 	"{\n"
 	"	vec2 correctedUv = vec2(vTexCoord.x, 1.0 - vTexCoord.y);\n"
 	"	ivec2 decodedSize = ivec2(max(uDecodedVideoResolution, vec2(1.0, 1.0)));\n"
 	"	ivec2 outputCoord = clamp(ivec2(correctedUv * vec2(decodedSize)), ivec2(0, 0), decodedSize - ivec2(1, 1));\n"
 	"	ivec2 packedSize = ivec2(max(uPackedVideoResolution, vec2(1.0, 1.0)));\n"
 	"	fragColor = uInputPixelFormat == 1 ? decodeV210(outputCoord, packedSize) : decodeUyvy8(outputCoord, packedSize);\n"
 	"}\n";
 const char* kOutputPackFragmentShaderSource =
 	"#version 430 core\n"
 	"layout(binding = 0) uniform sampler2D uOutputRgb;\n"
 	"uniform vec2 uOutputVideoResolution;\n"
 	"uniform float uActiveV210Words;\n"
 	"in vec2 vTexCoord;\n"
 	"layout(location = 0) out vec4 fragColor;\n"
 	"vec3 rgbAt(int x, int y)\n"
 	"{\n"
 	"	ivec2 size = ivec2(max(uOutputVideoResolution, vec2(1.0, 1.0)));\n"
 	"	return clamp(texelFetch(uOutputRgb, ivec2(clamp(x, 0, size.x - 1), clamp(y, 0, size.y - 1)), 0).rgb, vec3(0.0), vec3(1.0));\n"
 	"}\n"
 	"vec3 rgbToLegalYcbcr10(vec3 rgb)\n"
 	"{\n"
 	"	float y = dot(rgb, vec3(0.2126, 0.7152, 0.0722));\n"
 	"	float cb = (rgb.b - y) / 1.8556 + 0.5;\n"
 	"	float cr = (rgb.r - y) / 1.5748 + 0.5;\n"
 	"	return vec3(clamp(round(64.0 + y * 876.0), 64.0, 940.0), clamp(round(64.0 + cb * 896.0), 64.0, 960.0), clamp(round(64.0 + cr * 896.0), 64.0, 960.0));\n"
 	"}\n"
 	"uint makeWord(float a, float b, float c)\n"
 	"{\n"
 	"	return (uint(a) & 1023u) | ((uint(b) & 1023u) << 10) | ((uint(c) & 1023u) << 20);\n"
 	"}\n"
 	"vec4 wordToBytes(uint word)\n"
 	"{\n"
 	"	return vec4(float(word & 255u), float((word >> 8) & 255u), float((word >> 16) & 255u), float((word >> 24) & 255u)) / 255.0;\n"
 	"}\n"
 	"void main()\n"
 	"{\n"
 	"	ivec2 outCoord = ivec2(gl_FragCoord.xy);\n"
 	"	if (float(outCoord.x) >= uActiveV210Words)\n"
 	"	{\n"
 	"		fragColor = vec4(0.0);\n"
 	"		return;\n"
 	"	}\n"
 	"	int group = outCoord.x / 4;\n"
 	"	int wordIndex = outCoord.x - group * 4;\n"
 	"	int pixelBase = group * 6;\n"
 	"	int y = outCoord.y;\n"
 	"	vec3 c0 = rgbToLegalYcbcr10(rgbAt(pixelBase + 0, y));\n"
 	"	vec3 c1 = rgbToLegalYcbcr10(rgbAt(pixelBase + 1, y));\n"
 	"	vec3 c2 = rgbToLegalYcbcr10(rgbAt(pixelBase + 2, y));\n"
 	"	vec3 c3 = rgbToLegalYcbcr10(rgbAt(pixelBase + 3, y));\n"
 	"	vec3 c4 = rgbToLegalYcbcr10(rgbAt(pixelBase + 4, y));\n"
 	"	vec3 c5 = rgbToLegalYcbcr10(rgbAt(pixelBase + 5, y));\n"
 	"	float cb0 = round((c0.y + c1.y) * 0.5);\n"
 	"	float cr0 = round((c0.z + c1.z) * 0.5);\n"
 	"	float cb2 = round((c2.y + c3.y) * 0.5);\n"
 	"	float cr2 = round((c2.z + c3.z) * 0.5);\n"
 	"	float cb4 = round((c4.y + c5.y) * 0.5);\n"
 	"	float cr4 = round((c4.z + c5.z) * 0.5);\n"
 	"	uint word = wordIndex == 0 ? makeWord(cb0, c0.x, cr0) : wordIndex == 1 ? makeWord(c1.x, cb2, c2.x) : wordIndex == 2 ? makeWord(cr2, c3.x, cb4) : makeWord(c4.x, cr4, c5.x);\n"
 	"	fragColor = wordToBytes(word);\n"
 	"}\n";
--- a/apps/LoopThroughWithOpenGLCompositing/gl/GlShaderSources.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/GlShaderSources.h
@@ -1,5 +0,0 @@
 #pragma once
 extern const char* kFullscreenTriangleVertexShaderSource;
 extern const char* kDecodeFragmentShaderSource;
 extern const char* kOutputPackFragmentShaderSource;
--- a/apps/LoopThroughWithOpenGLCompositing/gl/GlobalParamsBuffer.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/GlobalParamsBuffer.cpp
@@ -1,102 +0,0 @@
 #include "GlobalParamsBuffer.h"
 #include "GlRenderConstants.h"
 #include "Std140Buffer.h"
 #include <vector>
 GlobalParamsBuffer::GlobalParamsBuffer(OpenGLRenderer& renderer) :
 	mRenderer(renderer)
 {
 }
 bool GlobalParamsBuffer::Update(const RuntimeRenderState& state, unsigned availableSourceHistoryLength, unsigned availableTemporalHistoryLength)
 {
 	std::vector<unsigned char> buffer;
 	buffer.reserve(512);
 	AppendStd140Float(buffer, static_cast<float>(state.timeSeconds));
 	AppendStd140Vec2(buffer, static_cast<float>(state.inputWidth), static_cast<float>(state.inputHeight));
 	AppendStd140Vec2(buffer, static_cast<float>(state.outputWidth), static_cast<float>(state.outputHeight));
 	AppendStd140Float(buffer, static_cast<float>(state.utcTimeSeconds));
 	AppendStd140Float(buffer, static_cast<float>(state.utcOffsetSeconds));
 	AppendStd140Float(buffer, static_cast<float>(state.startupRandom));
 	AppendStd140Float(buffer, static_cast<float>(state.frameCount));
 	AppendStd140Float(buffer, static_cast<float>(state.mixAmount));
 	AppendStd140Float(buffer, static_cast<float>(state.bypass));
 	const unsigned effectiveSourceHistoryLength = availableSourceHistoryLength < state.effectiveTemporalHistoryLength
 		? availableSourceHistoryLength
 		: state.effectiveTemporalHistoryLength;
 	const unsigned effectiveTemporalHistoryLength = (state.temporalHistorySource == TemporalHistorySource::PreLayerInput)
 		? (availableTemporalHistoryLength < state.effectiveTemporalHistoryLength ? availableTemporalHistoryLength : state.effectiveTemporalHistoryLength)
 		: 0u;
 	AppendStd140Int(buffer, static_cast<int>(effectiveSourceHistoryLength));
 	AppendStd140Int(buffer, static_cast<int>(effectiveTemporalHistoryLength));
 	for (const ShaderParameterDefinition& definition : state.parameterDefinitions)
 	{
 		auto valueIt = state.parameterValues.find(definition.id);
 		const ShaderParameterValue value = valueIt != state.parameterValues.end()
 			? valueIt->second
 			: ShaderParameterValue();
 		switch (definition.type)
 		{
 		case ShaderParameterType::Float:
 			AppendStd140Float(buffer, value.numberValues.empty() ? 0.0f : static_cast<float>(value.numberValues[0]));
 			break;
 		case ShaderParameterType::Vec2:
 			AppendStd140Vec2(buffer,
 				value.numberValues.size() > 0 ? static_cast<float>(value.numberValues[0]) : 0.0f,
 				value.numberValues.size() > 1 ? static_cast<float>(value.numberValues[1]) : 0.0f);
 			break;
 		case ShaderParameterType::Color:
 			AppendStd140Vec4(buffer,
 				value.numberValues.size() > 0 ? static_cast<float>(value.numberValues[0]) : 1.0f,
 				value.numberValues.size() > 1 ? static_cast<float>(value.numberValues[1]) : 1.0f,
 				value.numberValues.size() > 2 ? static_cast<float>(value.numberValues[2]) : 1.0f,
 				value.numberValues.size() > 3 ? static_cast<float>(value.numberValues[3]) : 1.0f);
 			break;
 		case ShaderParameterType::Boolean:
 			AppendStd140Int(buffer, value.booleanValue ? 1 : 0);
 			break;
 		case ShaderParameterType::Enum:
 		{
 			int selectedIndex = 0;
 			for (std::size_t optionIndex = 0; optionIndex < definition.enumOptions.size(); ++optionIndex)
 			{
 				if (definition.enumOptions[optionIndex].value == value.enumValue)
 				{
 					selectedIndex = static_cast<int>(optionIndex);
 					break;
 				}
 			}
 			AppendStd140Int(buffer, selectedIndex);
 			break;
 		}
 		case ShaderParameterType::Text:
 			break;
 		case ShaderParameterType::Trigger:
 			AppendStd140Int(buffer, value.numberValues.empty() ? 0 : static_cast<int>(value.numberValues[0]));
 			AppendStd140Float(buffer, value.numberValues.size() > 1 ? static_cast<float>(value.numberValues[1]) : -1000000.0f);
 			break;
 		}
 	}
 	buffer.resize(AlignStd140(buffer.size(), 16), 0);
 	glBindBuffer(GL_UNIFORM_BUFFER, mRenderer.GlobalParamsUBO());
 	if (mRenderer.GlobalParamsUBOSize() != static_cast<GLsizeiptr>(buffer.size()))
 	{
 		glBufferData(GL_UNIFORM_BUFFER, static_cast<GLsizeiptr>(buffer.size()), buffer.data(), GL_DYNAMIC_DRAW);
 		mRenderer.SetGlobalParamsUBOSize(static_cast<GLsizeiptr>(buffer.size()));
 	}
 	else
 	{
 		glBufferSubData(GL_UNIFORM_BUFFER, 0, static_cast<GLsizeiptr>(buffer.size()), buffer.data());
 	}
 	glBindBufferBase(GL_UNIFORM_BUFFER, kGlobalParamsBindingPoint, mRenderer.GlobalParamsUBO());
 	glBindBuffer(GL_UNIFORM_BUFFER, 0);
 	return true;
 }
--- a/apps/LoopThroughWithOpenGLCompositing/gl/GlobalParamsBuffer.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/GlobalParamsBuffer.h
@@ -1,15 +0,0 @@
 #pragma once
 #include "OpenGLRenderer.h"
 #include "ShaderTypes.h"
 class GlobalParamsBuffer
 {
 public:
 	explicit GlobalParamsBuffer(OpenGLRenderer& renderer);
 	bool Update(const RuntimeRenderState& state, unsigned availableSourceHistoryLength, unsigned availableTemporalHistoryLength);
 private:
 	OpenGLRenderer& mRenderer;
 };
--- a/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLComposite.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLComposite.cpp
@@ -1,479 +0,0 @@
 #include "DeckLinkDisplayMode.h"
 #include "DeckLinkSession.h"
 #include "OpenGLComposite.h"
 #include "GLExtensions.h"
 #include "GlRenderConstants.h"
 #include "OpenGLDeckLinkBridge.h"
 #include "OpenGLRenderPass.h"
 #include "OpenGLShaderPrograms.h"
 #include "PngScreenshotWriter.h"
 #include "RuntimeServices.h"
 #include "ShaderBuildQueue.h"
 #include <algorithm>
 #include <chrono>
 #include <ctime>
 #include <filesystem>
 #include <iomanip>
 #include <memory>
 #include <sstream>
 #include <string>
 #include <vector>
 OpenGLComposite::OpenGLComposite(HWND hWnd, HDC hDC, HGLRC hRC) :
 	hGLWnd(hWnd), hGLDC(hDC), hGLRC(hRC),
 	mDeckLink(std::make_unique<DeckLinkSession>()),
 	mRenderer(std::make_unique<OpenGLRenderer>()),
 	mUseCommittedLayerStates(false),
 	mScreenshotRequested(false)
 {
 	InitializeCriticalSection(&pMutex);
 	mRuntimeHost = std::make_unique<RuntimeHost>();
 	mDeckLinkBridge = std::make_unique<OpenGLDeckLinkBridge>(
 		*mDeckLink,
 		*mRenderer,
 		*mRuntimeHost,
 		pMutex,
 		hGLDC,
 		hGLRC,
 		[this]() { renderEffect(); },
 		[this]() { ProcessScreenshotRequest(); },
 		[this]() { paintGL(); });
 	mRenderPass = std::make_unique<OpenGLRenderPass>(*mRenderer);
 	mShaderPrograms = std::make_unique<OpenGLShaderPrograms>(*mRenderer, *mRuntimeHost);
 	mShaderBuildQueue = std::make_unique<ShaderBuildQueue>(*mRuntimeHost);
 	mRuntimeServices = std::make_unique<RuntimeServices>();
 }
 OpenGLComposite::~OpenGLComposite()
 {
 	if (mRuntimeServices)
 		mRuntimeServices->Stop();
 	if (mShaderBuildQueue)
 		mShaderBuildQueue->Stop();
 	mDeckLink->ReleaseResources();
 	mRenderer->DestroyResources();
 	DeleteCriticalSection(&pMutex);
 }
 bool OpenGLComposite::InitDeckLink()
 {
 	VideoFormatSelection		videoModes;
 	std::string						initFailureReason;
 	if (mRuntimeHost && mRuntimeHost->GetRepoRoot().empty())
 	{
 		std::string runtimeError;
 		if (!mRuntimeHost->Initialize(runtimeError))
 		{
 			MessageBoxA(NULL, runtimeError.c_str(), "Runtime host failed to initialize", MB_OK);
 			return false;
 		}
 	}
 	if (mRuntimeHost)
 	{
 		if (!ResolveConfiguredVideoFormats(
 			mRuntimeHost->GetInputVideoFormat(),
 			mRuntimeHost->GetInputFrameRate(),
 			mRuntimeHost->GetOutputVideoFormat(),
 			mRuntimeHost->GetOutputFrameRate(),
 			videoModes,
 			initFailureReason))
 		{
 			MessageBoxA(NULL, initFailureReason.c_str(), "DeckLink mode configuration error", MB_OK);
 			return false;
 		}
 	}
 	if (!mDeckLink->DiscoverDevicesAndModes(videoModes, initFailureReason))
 	{
 		const char* title = initFailureReason == "Please install the Blackmagic DeckLink drivers to use the features of this application."
 			? "This application requires the DeckLink drivers installed."
 			: "DeckLink initialization failed";
 		MessageBoxA(NULL, initFailureReason.c_str(), title, MB_OK | MB_ICONERROR);
 		return false;
 	}
 	if (!mDeckLink->SelectPreferredFormats(videoModes, initFailureReason))
 		goto error;
 	if (! CheckOpenGLExtensions())
 	{
 		initFailureReason = "OpenGL extension checks failed.";
 		goto error;
 	}
 	if (! InitOpenGLState())
 	{
 		initFailureReason = "OpenGL state initialization failed.";
 		goto error;
 	}
 	PublishDeckLinkOutputStatus(mDeckLink->OutputModelName().empty()
 		? "DeckLink output device selected."
 		: ("Selected output device: " + mDeckLink->OutputModelName()));
 	// Resize window to match output video frame, but scale large formats down by half for viewing.
 	if (mDeckLink->OutputFrameWidth() < 1920)
 		resizeWindow(mDeckLink->OutputFrameWidth(), mDeckLink->OutputFrameHeight());
 	else
 		resizeWindow(mDeckLink->OutputFrameWidth() / 2, mDeckLink->OutputFrameHeight() / 2);
 	if (!mDeckLink->ConfigureInput(this, hGLDC, hGLRC, videoModes.input, initFailureReason))
 	{
 		goto error;
 	}
 	if (!mDeckLink->HasInputDevice() && mRuntimeHost)
 	{
 		mRuntimeHost->SetSignalStatus(false, mDeckLink->InputFrameWidth(), mDeckLink->InputFrameHeight(), mDeckLink->InputDisplayModeName());
 	}
 	if (!mDeckLink->ConfigureOutput(this, hGLDC, hGLRC, videoModes.output, mRuntimeHost && mRuntimeHost->ExternalKeyingEnabled(), initFailureReason))
 	{
 		goto error;
 	}
 	PublishDeckLinkOutputStatus(mDeckLink->StatusMessage());
 	return true;
 error:
 	if (!initFailureReason.empty())
 		MessageBoxA(NULL, initFailureReason.c_str(), "DeckLink initialization failed", MB_OK | MB_ICONERROR);
 	mDeckLink->ReleaseResources();
 	return false;
 }
 void OpenGLComposite::paintGL()
 {
 	if (!TryEnterCriticalSection(&pMutex))
 	{
 		ValidateRect(hGLWnd, NULL);
 		return;
 	}
 	mRenderer->PresentToWindow(hGLDC, mDeckLink->OutputFrameWidth(), mDeckLink->OutputFrameHeight());
 	ValidateRect(hGLWnd, NULL);
 	LeaveCriticalSection(&pMutex);
 }
 void OpenGLComposite::resizeGL(WORD width, WORD height)
 {
 	// We don't set the project or model matrices here since the window data is copied directly from
 	// an off-screen FBO in paintGL().  Just save the width and height for use in paintGL().
 	mRenderer->ResizeView(width, height);
 }
 void OpenGLComposite::resizeWindow(int width, int height)
 {
 	RECT r;
 	if (GetWindowRect(hGLWnd, &r))
 	{
 		SetWindowPos(hGLWnd, HWND_TOP, r.left, r.top, r.left + width, r.top + height, 0);
 	}
 }
 void OpenGLComposite::PublishDeckLinkOutputStatus(const std::string& statusMessage)
 {
 	if (!mRuntimeHost)
 		return;
 	if (!statusMessage.empty())
 		mDeckLink->SetStatusMessage(statusMessage);
 	mRuntimeHost->SetDeckLinkOutputStatus(
 		mDeckLink->OutputModelName(),
 		mDeckLink->SupportsInternalKeying(),
 		mDeckLink->SupportsExternalKeying(),
 		mDeckLink->KeyerInterfaceAvailable(),
 		mRuntimeHost->ExternalKeyingEnabled(),
 		mDeckLink->ExternalKeyingActive(),
 		mDeckLink->StatusMessage());
 }
 bool OpenGLComposite::InitOpenGLState()
 {
 	if (! ResolveGLExtensions())
 		return false;
 	std::string runtimeError;
 	if (mRuntimeHost->GetRepoRoot().empty() && !mRuntimeHost->Initialize(runtimeError))
 	{
 		MessageBoxA(NULL, runtimeError.c_str(), "Runtime host failed to initialize", MB_OK);
 		return false;
 	}
 	if (!mRuntimeServices->Start(*this, *mRuntimeHost, runtimeError))
 	{
 		MessageBoxA(NULL, runtimeError.c_str(), "Runtime control services failed to start", MB_OK);
 		return false;
 	}
 	// Prepare the runtime shader program generated from the active shader package.
 	char compilerErrorMessage[1024];
 	if (!mShaderPrograms->CompileDecodeShader(sizeof(compilerErrorMessage), compilerErrorMessage))
 	{
 		MessageBoxA(NULL, compilerErrorMessage, "OpenGL decode shader failed to load or compile", MB_OK);
 		return false;
 	}
 	if (!mShaderPrograms->CompileOutputPackShader(sizeof(compilerErrorMessage), compilerErrorMessage))
 	{
 		MessageBoxA(NULL, compilerErrorMessage, "OpenGL output pack shader failed to load or compile", MB_OK);
 		return false;
 	}
 	if (!mShaderPrograms->CompileLayerPrograms(mDeckLink->InputFrameWidth(), mDeckLink->InputFrameHeight(), sizeof(compilerErrorMessage), compilerErrorMessage))
 	{
 		MessageBoxA(NULL, compilerErrorMessage, "OpenGL shader failed to load or compile", MB_OK);
 		return false;
 	}
 	mCachedLayerRenderStates = mShaderPrograms->CommittedLayerStates();
 	mUseCommittedLayerStates = false;
 	mShaderPrograms->ResetTemporalHistoryState();
 	std::string rendererError;
 	if (!mRenderer->InitializeResources(
 		mDeckLink->InputFrameWidth(),
 		mDeckLink->InputFrameHeight(),
 		mDeckLink->CaptureTextureWidth(),
 		mDeckLink->OutputFrameWidth(),
 		mDeckLink->OutputFrameHeight(),
 		mDeckLink->OutputPackTextureWidth(),
 		rendererError))
 	{
 		MessageBoxA(NULL, rendererError.c_str(), "OpenGL initialization error.", MB_OK);
 		return false;
 	}
 	broadcastRuntimeState();
 	mRuntimeServices->BeginPolling(*mRuntimeHost);
 	return true;
 }
 // DeckLink delegates still target OpenGLComposite; the bridge owns the per-frame work.
 void OpenGLComposite::VideoFrameArrived(IDeckLinkVideoInputFrame* inputFrame, bool hasNoInputSource)
 {
 	mDeckLinkBridge->VideoFrameArrived(inputFrame, hasNoInputSource);
 }
 void OpenGLComposite::PlayoutFrameCompleted(IDeckLinkVideoFrame* completedFrame, BMDOutputFrameCompletionResult completionResult)
 {
 	mDeckLinkBridge->PlayoutFrameCompleted(completedFrame, completionResult);
 }
 bool OpenGLComposite::Start()
 {
 	return mDeckLink->Start();
 }
 bool OpenGLComposite::Stop()
 {
 	if (mRuntimeServices)
 		mRuntimeServices->Stop();
 	const bool wasExternalKeyingActive = mDeckLink->ExternalKeyingActive();
 	mDeckLink->Stop();
 	if (wasExternalKeyingActive)
 		PublishDeckLinkOutputStatus("External keying has been disabled.");
 	return true;
 }
 bool OpenGLComposite::ReloadShader()
 {
 	if (mRuntimeHost)
 	{
 		mRuntimeHost->SetCompileStatus(true, "Shader rebuild queued.");
 		mRuntimeHost->ClearReloadRequest();
 	}
 	RequestShaderBuild();
 	broadcastRuntimeState();
 	return true;
 }
 bool OpenGLComposite::RequestScreenshot(std::string& error)
 {
 	(void)error;
 	mScreenshotRequested.store(true);
 	return true;
 }
 void OpenGLComposite::renderEffect()
 {
 	ProcessRuntimePollResults();
 	const bool hasInputSource = mDeckLink->HasInputSource();
 	std::vector<RuntimeRenderState> layerStates;
 	if (mUseCommittedLayerStates)
 	{
 		layerStates = mShaderPrograms->CommittedLayerStates();
 		if (mRuntimeHost)
 			mRuntimeHost->RefreshDynamicRenderStateFields(layerStates);
 	}
 	else if (mRuntimeHost)
 	{
 		if (mRuntimeHost->TryGetLayerRenderStates(mDeckLink->InputFrameWidth(), mDeckLink->InputFrameHeight(), layerStates))
 		{
 			mCachedLayerRenderStates = layerStates;
 		}
 		else
 		{
 			layerStates = mCachedLayerRenderStates;
 			mRuntimeHost->RefreshDynamicRenderStateFields(layerStates);
 		}
 	}
 	const unsigned historyCap = mRuntimeHost ? mRuntimeHost->GetMaxTemporalHistoryFrames() : 0;
 	mRenderPass->Render(
 		hasInputSource,
 		layerStates,
 		mDeckLink->InputFrameWidth(),
 		mDeckLink->InputFrameHeight(),
 		mDeckLink->CaptureTextureWidth(),
 		mDeckLink->InputPixelFormat(),
 		historyCap,
 		[this](const RuntimeRenderState& state, LayerProgram::TextBinding& textBinding, std::string& error) {
 			return mShaderPrograms->UpdateTextBindingTexture(state, textBinding, error);
 		},
 		[this](const RuntimeRenderState& state, unsigned availableSourceHistoryLength, unsigned availableTemporalHistoryLength) {
 			return mShaderPrograms->UpdateGlobalParamsBuffer(state, availableSourceHistoryLength, availableTemporalHistoryLength);
 		});
 }
 void OpenGLComposite::ProcessScreenshotRequest()
 {
 	if (!mScreenshotRequested.exchange(false))
 		return;
 	const unsigned width = mDeckLink ? mDeckLink->OutputFrameWidth() : 0;
 	const unsigned height = mDeckLink ? mDeckLink->OutputFrameHeight() : 0;
 	if (width == 0 || height == 0)
 		return;
 	std::vector<unsigned char> bottomUpPixels(static_cast<std::size_t>(width) * height * 4);
 	std::vector<unsigned char> topDownPixels(bottomUpPixels.size());
 	glBindFramebuffer(GL_READ_FRAMEBUFFER, mRenderer->OutputFramebuffer());
 	glReadBuffer(GL_COLOR_ATTACHMENT0);
 	glPixelStorei(GL_PACK_ALIGNMENT, 1);
 	glPixelStorei(GL_PACK_ROW_LENGTH, 0);
 	glReadPixels(0, 0, width, height, GL_RGBA, GL_UNSIGNED_BYTE, bottomUpPixels.data());
 	glPixelStorei(GL_PACK_ALIGNMENT, 4);
 	const std::size_t rowBytes = static_cast<std::size_t>(width) * 4;
 	for (unsigned y = 0; y < height; ++y)
 	{
 		const unsigned sourceY = height - 1 - y;
 		std::copy(
 			bottomUpPixels.begin() + static_cast<std::ptrdiff_t>(sourceY * rowBytes),
 			bottomUpPixels.begin() + static_cast<std::ptrdiff_t>((sourceY + 1) * rowBytes),
 			topDownPixels.begin() + static_cast<std::ptrdiff_t>(y * rowBytes));
 	}
 	try
 	{
 		const std::filesystem::path outputPath = BuildScreenshotPath();
 		std::filesystem::create_directories(outputPath.parent_path());
 		WritePngFileAsync(outputPath, width, height, std::move(topDownPixels));
 	}
 	catch (const std::exception& exception)
 	{
 		OutputDebugStringA((std::string("Screenshot request failed: ") + exception.what() + "\n").c_str());
 	}
 }
 std::filesystem::path OpenGLComposite::BuildScreenshotPath() const
 {
 	const std::filesystem::path root = mRuntimeHost && !mRuntimeHost->GetRuntimeRoot().empty()
 		? mRuntimeHost->GetRuntimeRoot()
 		: std::filesystem::current_path();
 	const auto now = std::chrono::system_clock::now();
 	const auto milliseconds = std::chrono::duration_cast<std::chrono::milliseconds>(now.time_since_epoch()) % 1000;
 	const std::time_t nowTime = std::chrono::system_clock::to_time_t(now);
 	std::tm localTime = {};
 	localtime_s(&localTime, &nowTime);
 	std::ostringstream filename;
 	filename << "video-shader-toys-"
 		<< std::put_time(&localTime, "%Y%m%d-%H%M%S")
 		<< "-" << std::setw(3) << std::setfill('0') << milliseconds.count()
 		<< ".png";
 	return root / "screenshots" / filename.str();
 }
 bool OpenGLComposite::ProcessRuntimePollResults()
 {
 	if (!mRuntimeHost || !mRuntimeServices)
 		return true;
 	const RuntimePollEvents events = mRuntimeServices->ConsumePollEvents();
 	if (events.failed)
 	{
 		mRuntimeHost->SetCompileStatus(false, events.error);
 		broadcastRuntimeState();
 		return false;
 	}
 	if (events.registryChanged)
 		broadcastRuntimeState();
 	if (!events.reloadRequested)
 	{
 		PreparedShaderBuild readyBuild;
 		if (!mShaderBuildQueue || !mShaderBuildQueue->TryConsumeReadyBuild(readyBuild))
 			return true;
 		char compilerErrorMessage[1024] = {};
 		if (!mShaderPrograms->CommitPreparedLayerPrograms(readyBuild, mDeckLink->InputFrameWidth(), mDeckLink->InputFrameHeight(), sizeof(compilerErrorMessage), compilerErrorMessage))
 		{
 			mRuntimeHost->SetCompileStatus(false, compilerErrorMessage);
 			mUseCommittedLayerStates = true;
 			broadcastRuntimeState();
 			return false;
 		}
 		mUseCommittedLayerStates = false;
 		mCachedLayerRenderStates = mShaderPrograms->CommittedLayerStates();
 		mShaderPrograms->ResetTemporalHistoryState();
 		broadcastRuntimeState();
 		return true;
 	}
 	mRuntimeHost->SetCompileStatus(true, "Shader rebuild queued.");
 	RequestShaderBuild();
 	broadcastRuntimeState();
 	return true;
 }
 void OpenGLComposite::RequestShaderBuild()
 {
 	if (!mShaderBuildQueue || !mDeckLink)
 		return;
 	mUseCommittedLayerStates = true;
 	if (mRuntimeHost)
 		mRuntimeHost->ClearReloadRequest();
 	mShaderBuildQueue->RequestBuild(mDeckLink->InputFrameWidth(), mDeckLink->InputFrameHeight());
 }
 void OpenGLComposite::broadcastRuntimeState()
 {
 	if (mRuntimeServices)
 		mRuntimeServices->BroadcastState();
 }
 void OpenGLComposite::resetTemporalHistoryState()
 {
 	mShaderPrograms->ResetTemporalHistoryState();
 }
 bool OpenGLComposite::CheckOpenGLExtensions()
 {
 	return true;
 }
 ////////////////////////////////////////////
--- a/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLComposite.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLComposite.h
@@ -1,104 +0,0 @@
 #ifndef __OPENGL_COMPOSITE_H__
 #define __OPENGL_COMPOSITE_H__
 #include <windows.h>
 #include <process.h>
 #include <tchar.h>
 #include <gl/gl.h>
 #include <gl/glu.h>
 #include <objbase.h>
 #include <atlbase.h>
 #include <comutil.h>
 #include "DeckLinkAPI_h.h"
 #include "GLExtensions.h"
 #include "OpenGLRenderer.h"
 #include "RuntimeHost.h"
 #include <functional>
 #include <atomic>
 #include <filesystem>
 #include <map>
 #include <memory>
 #include <string>
 #include <vector>
 #include <deque>
 class DeckLinkSession;
 class OpenGLDeckLinkBridge;
 class OpenGLRenderPass;
 class OpenGLShaderPrograms;
 class RuntimeServices;
 class ShaderBuildQueue;
 class OpenGLComposite
 {
 public:
 	OpenGLComposite(HWND hWnd, HDC hDC, HGLRC hRC);
 	~OpenGLComposite();
 	bool InitDeckLink();
 	bool Start();
 	bool Stop();
 	bool ReloadShader();
 	std::string GetRuntimeStateJson() const;
 	bool AddLayer(const std::string& shaderId, std::string& error);
 	bool RemoveLayer(const std::string& layerId, std::string& error);
 	bool MoveLayer(const std::string& layerId, int direction, std::string& error);
 	bool MoveLayerToIndex(const std::string& layerId, std::size_t targetIndex, std::string& error);
 	bool SetLayerBypass(const std::string& layerId, bool bypassed, std::string& error);
 	bool SetLayerShader(const std::string& layerId, const std::string& shaderId, std::string& error);
 	bool UpdateLayerParameterJson(const std::string& layerId, const std::string& parameterId, const std::string& valueJson, std::string& error);
 	bool UpdateLayerParameterByControlKeyJson(const std::string& layerKey, const std::string& parameterKey, const std::string& valueJson, std::string& error);
 	bool ResetLayerParameters(const std::string& layerId, std::string& error);
 	bool SaveStackPreset(const std::string& presetName, std::string& error);
 	bool LoadStackPreset(const std::string& presetName, std::string& error);
 	bool RequestScreenshot(std::string& error);
 	unsigned short GetControlServerPort() const;
 	unsigned short GetOscPort() const;
 	std::string GetControlUrl() const;
 	std::string GetDocsUrl() const;
 	std::string GetOscAddress() const;
 	void resizeGL(WORD width, WORD height);
 	void paintGL();
 	void VideoFrameArrived(IDeckLinkVideoInputFrame* inputFrame, bool hasNoInputSource);
 	void PlayoutFrameCompleted(IDeckLinkVideoFrame* completedFrame, BMDOutputFrameCompletionResult result);
 private:
 	void resizeWindow(int width, int height);
 	bool CheckOpenGLExtensions();
 	void PublishDeckLinkOutputStatus(const std::string& statusMessage);
 	using LayerProgram = OpenGLRenderer::LayerProgram;
 	HWND									hGLWnd;
 	HDC										hGLDC;
 	HGLRC									hGLRC;
 	CRITICAL_SECTION						pMutex;
 	std::unique_ptr<DeckLinkSession>			mDeckLink;
 	std::unique_ptr<OpenGLRenderer>			mRenderer;
 	std::unique_ptr<RuntimeHost>				mRuntimeHost;
 	std::unique_ptr<OpenGLDeckLinkBridge>	mDeckLinkBridge;
 	std::unique_ptr<OpenGLRenderPass>		mRenderPass;
 	std::unique_ptr<OpenGLShaderPrograms>	mShaderPrograms;
 	std::unique_ptr<ShaderBuildQueue>		mShaderBuildQueue;
 	std::unique_ptr<RuntimeServices>		mRuntimeServices;
 	std::vector<RuntimeRenderState>			mCachedLayerRenderStates;
 	std::atomic<bool>						mUseCommittedLayerStates;
 	std::atomic<bool>						mScreenshotRequested;
 	bool InitOpenGLState();
 	void renderEffect();
 	bool ProcessRuntimePollResults();
 	void RequestShaderBuild();
 	void ProcessScreenshotRequest();
 	std::filesystem::path BuildScreenshotPath() const;
 	void broadcastRuntimeState();
 	void resetTemporalHistoryState();
 };
 #endif		// __OPENGL_COMPOSITE_H__
--- a/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLCompositeRuntimeControls.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLCompositeRuntimeControls.cpp
@@ -1,145 +0,0 @@
 #include "OpenGLComposite.h"
 std::string OpenGLComposite::GetRuntimeStateJson() const
 {
 	return mRuntimeHost ? mRuntimeHost->BuildStateJson() : "{}";
 }
 unsigned short OpenGLComposite::GetControlServerPort() const
 {
 	return mRuntimeHost ? mRuntimeHost->GetServerPort() : 0;
 }
 unsigned short OpenGLComposite::GetOscPort() const
 {
 	return mRuntimeHost ? mRuntimeHost->GetOscPort() : 0;
 }
 std::string OpenGLComposite::GetControlUrl() const
 {
 	return "http://127.0.0.1:" + std::to_string(GetControlServerPort()) + "/";
 }
 std::string OpenGLComposite::GetDocsUrl() const
 {
 	return "http://127.0.0.1:" + std::to_string(GetControlServerPort()) + "/docs";
 }
 std::string OpenGLComposite::GetOscAddress() const
 {
 	return "udp://127.0.0.1:" + std::to_string(GetOscPort()) + " /VideoShaderToys/{Layer}/{Parameter}";
 }
 bool OpenGLComposite::AddLayer(const std::string& shaderId, std::string& error)
 {
 	if (!mRuntimeHost->AddLayer(shaderId, error))
 		return false;
 	ReloadShader();
 	broadcastRuntimeState();
 	return true;
 }
 bool OpenGLComposite::RemoveLayer(const std::string& layerId, std::string& error)
 {
 	if (!mRuntimeHost->RemoveLayer(layerId, error))
 		return false;
 	ReloadShader();
 	broadcastRuntimeState();
 	return true;
 }
 bool OpenGLComposite::MoveLayer(const std::string& layerId, int direction, std::string& error)
 {
 	if (!mRuntimeHost->MoveLayer(layerId, direction, error))
 		return false;
 	ReloadShader();
 	broadcastRuntimeState();
 	return true;
 }
 bool OpenGLComposite::MoveLayerToIndex(const std::string& layerId, std::size_t targetIndex, std::string& error)
 {
 	if (!mRuntimeHost->MoveLayerToIndex(layerId, targetIndex, error))
 		return false;
 	ReloadShader();
 	broadcastRuntimeState();
 	return true;
 }
 bool OpenGLComposite::SetLayerBypass(const std::string& layerId, bool bypassed, std::string& error)
 {
 	if (!mRuntimeHost->SetLayerBypass(layerId, bypassed, error))
 		return false;
 	ReloadShader();
 	broadcastRuntimeState();
 	return true;
 }
 bool OpenGLComposite::SetLayerShader(const std::string& layerId, const std::string& shaderId, std::string& error)
 {
 	if (!mRuntimeHost->SetLayerShader(layerId, shaderId, error))
 		return false;
 	ReloadShader();
 	broadcastRuntimeState();
 	return true;
 }
 bool OpenGLComposite::UpdateLayerParameterJson(const std::string& layerId, const std::string& parameterId, const std::string& valueJson, std::string& error)
 {
 	JsonValue parsedValue;
 	if (!ParseJson(valueJson, parsedValue, error))
 		return false;
 	if (!mRuntimeHost->UpdateLayerParameter(layerId, parameterId, parsedValue, error))
 		return false;
 	broadcastRuntimeState();
 	return true;
 }
 bool OpenGLComposite::UpdateLayerParameterByControlKeyJson(const std::string& layerKey, const std::string& parameterKey, const std::string& valueJson, std::string& error)
 {
 	JsonValue parsedValue;
 	if (!ParseJson(valueJson, parsedValue, error))
 		return false;
 	if (!mRuntimeHost->UpdateLayerParameterByControlKey(layerKey, parameterKey, parsedValue, error))
 		return false;
 	broadcastRuntimeState();
 	return true;
 }
 bool OpenGLComposite::ResetLayerParameters(const std::string& layerId, std::string& error)
 {
 	if (!mRuntimeHost->ResetLayerParameters(layerId, error))
 		return false;
 	broadcastRuntimeState();
 	return true;
 }
 bool OpenGLComposite::SaveStackPreset(const std::string& presetName, std::string& error)
 {
 	if (!mRuntimeHost->SaveStackPreset(presetName, error))
 		return false;
 	broadcastRuntimeState();
 	return true;
 }
 bool OpenGLComposite::LoadStackPreset(const std::string& presetName, std::string& error)
 {
 	if (!mRuntimeHost->LoadStackPreset(presetName, error))
 		return false;
 	ReloadShader();
 	broadcastRuntimeState();
 	return true;
 }
--- a/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLDeckLinkBridge.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLDeckLinkBridge.cpp
@@ -1,209 +0,0 @@
 #include "OpenGLDeckLinkBridge.h"
 #include "DeckLinkSession.h"
 #include "OpenGLRenderer.h"
 #include "RuntimeHost.h"
 #include <chrono>
 #include <gl/gl.h>
 OpenGLDeckLinkBridge::OpenGLDeckLinkBridge(
 	DeckLinkSession& deckLink,
 	OpenGLRenderer& renderer,
 	RuntimeHost& runtimeHost,
 	CRITICAL_SECTION& mutex,
 	HDC hdc,
 	HGLRC hglrc,
 	RenderEffectCallback renderEffect,
 	OutputReadyCallback outputReady,
 	PaintCallback paint) :
 	mDeckLink(deckLink),
 	mRenderer(renderer),
 	mRuntimeHost(runtimeHost),
 	mMutex(mutex),
 	mHdc(hdc),
 	mHglrc(hglrc),
 	mRenderEffect(renderEffect),
 	mOutputReady(outputReady),
 	mPaint(paint)
 {
 }
 void OpenGLDeckLinkBridge::RecordFramePacing(BMDOutputFrameCompletionResult completionResult)
 {
 	const auto now = std::chrono::steady_clock::now();
 	if (mLastPlayoutCompletionTime != std::chrono::steady_clock::time_point())
 	{
 		mCompletionIntervalMilliseconds = std::chrono::duration_cast<std::chrono::duration<double, std::milli>>(now - mLastPlayoutCompletionTime).count();
 		if (mSmoothedCompletionIntervalMilliseconds <= 0.0)
 			mSmoothedCompletionIntervalMilliseconds = mCompletionIntervalMilliseconds;
 		else
 			mSmoothedCompletionIntervalMilliseconds = mSmoothedCompletionIntervalMilliseconds * 0.9 + mCompletionIntervalMilliseconds * 0.1;
 		if (mCompletionIntervalMilliseconds > mMaxCompletionIntervalMilliseconds)
 			mMaxCompletionIntervalMilliseconds = mCompletionIntervalMilliseconds;
 	}
 	mLastPlayoutCompletionTime = now;
 	if (completionResult == bmdOutputFrameDisplayedLate)
 		++mLateFrameCount;
 	else if (completionResult == bmdOutputFrameDropped)
 		++mDroppedFrameCount;
 	else if (completionResult == bmdOutputFrameFlushed)
 		++mFlushedFrameCount;
 	mRuntimeHost.TrySetFramePacingStats(
 		mCompletionIntervalMilliseconds,
 		mSmoothedCompletionIntervalMilliseconds,
 		mMaxCompletionIntervalMilliseconds,
 		mLateFrameCount,
 		mDroppedFrameCount,
 		mFlushedFrameCount);
 }
 void OpenGLDeckLinkBridge::VideoFrameArrived(IDeckLinkVideoInputFrame* inputFrame, bool hasNoInputSource)
 {
 	mDeckLink.SetInputSourceMissing(hasNoInputSource);
 	mRuntimeHost.TrySetSignalStatus(!hasNoInputSource, mDeckLink.InputFrameWidth(), mDeckLink.InputFrameHeight(), mDeckLink.InputDisplayModeName());
 	if (!mDeckLink.HasInputSource())
 		return;							// don't transfer texture when there's no input
 	long textureSize = inputFrame->GetRowBytes() * inputFrame->GetHeight();
 	IDeckLinkVideoBuffer* inputFrameBuffer = NULL;
 	void* videoPixels;
 	if (inputFrame->QueryInterface(IID_IDeckLinkVideoBuffer, (void**)&inputFrameBuffer) != S_OK)
 		return;
 	if (inputFrameBuffer->StartAccess(bmdBufferAccessRead) != S_OK)
 	{
 		inputFrameBuffer->Release();
 		return;
 	}
 	inputFrameBuffer->GetBytes(&videoPixels);
 	EnterCriticalSection(&mMutex);
 	wglMakeCurrent(mHdc, mHglrc);		// make OpenGL context current in this thread
 	glPixelStorei(GL_UNPACK_ALIGNMENT, 4);
 	glPixelStorei(GL_UNPACK_ROW_LENGTH, 0);
 	glBindBuffer(GL_PIXEL_UNPACK_BUFFER, mRenderer.TextureUploadBuffer());
 	glBufferData(GL_PIXEL_UNPACK_BUFFER, textureSize, videoPixels, GL_DYNAMIC_DRAW);
 	glBindTexture(GL_TEXTURE_2D, mRenderer.CaptureTexture());
 	// NULL for last arg indicates use current GL_PIXEL_UNPACK_BUFFER target as texture data.
 	if (mDeckLink.InputPixelFormat() == VideoIOPixelFormat::V210)
 		glTexSubImage2D(GL_TEXTURE_2D, 0, 0, 0, mDeckLink.CaptureTextureWidth(), mDeckLink.InputFrameHeight(), GL_RGBA, GL_UNSIGNED_BYTE, NULL);
 	else
 		glTexSubImage2D(GL_TEXTURE_2D, 0, 0, 0, mDeckLink.CaptureTextureWidth(), mDeckLink.InputFrameHeight(), GL_BGRA, GL_UNSIGNED_INT_8_8_8_8_REV, NULL);
 	glBindTexture(GL_TEXTURE_2D, 0);
 	glBindBuffer(GL_PIXEL_UNPACK_BUFFER, 0);
 	wglMakeCurrent(NULL, NULL);
 	LeaveCriticalSection(&mMutex);
 	inputFrameBuffer->EndAccess(bmdBufferAccessRead);
 	inputFrameBuffer->Release();
 }
 void OpenGLDeckLinkBridge::PlayoutFrameCompleted(IDeckLinkVideoFrame* completedFrame, BMDOutputFrameCompletionResult completionResult)
 {
 	(void)completedFrame;
 	RecordFramePacing(completionResult);
 	EnterCriticalSection(&mMutex);
 	// Get the first frame from the queue
 	IDeckLinkMutableVideoFrame* outputVideoFrame = mDeckLink.RotateOutputFrame();
 	// make GL context current in this thread
 	wglMakeCurrent(mHdc, mHglrc);
 	// Draw the effect output to the off-screen framebuffer.
 	const auto renderStartTime = std::chrono::steady_clock::now();
 	glBindFramebuffer(GL_FRAMEBUFFER, mRenderer.CompositeFramebuffer());
 	mRenderEffect();
 	glBindFramebuffer(GL_READ_FRAMEBUFFER, mRenderer.CompositeFramebuffer());
 	glBindFramebuffer(GL_DRAW_FRAMEBUFFER, mRenderer.OutputFramebuffer());
 	glBlitFramebuffer(0, 0, mDeckLink.InputFrameWidth(), mDeckLink.InputFrameHeight(), 0, 0, mDeckLink.OutputFrameWidth(), mDeckLink.OutputFrameHeight(), GL_COLOR_BUFFER_BIT, GL_LINEAR);
 	glBindFramebuffer(GL_FRAMEBUFFER, mRenderer.OutputFramebuffer());
 	if (mOutputReady)
 		mOutputReady();
 	if (mDeckLink.OutputIsTenBit())
 	{
 		glBindFramebuffer(GL_FRAMEBUFFER, mRenderer.OutputPackFramebuffer());
 		glViewport(0, 0, mDeckLink.OutputPackTextureWidth(), mDeckLink.OutputFrameHeight());
 		glDisable(GL_SCISSOR_TEST);
 		glDisable(GL_BLEND);
 		glDisable(GL_DEPTH_TEST);
 		glActiveTexture(GL_TEXTURE0);
 		glBindTexture(GL_TEXTURE_2D, mRenderer.OutputTexture());
 		glBindVertexArray(mRenderer.FullscreenVertexArray());
 		glUseProgram(mRenderer.OutputPackProgram());
 		const GLint outputResolutionLocation = glGetUniformLocation(mRenderer.OutputPackProgram(), "uOutputVideoResolution");
 		const GLint activeWordsLocation = glGetUniformLocation(mRenderer.OutputPackProgram(), "uActiveV210Words");
 		if (outputResolutionLocation >= 0)
 			glUniform2f(outputResolutionLocation, static_cast<float>(mDeckLink.OutputFrameWidth()), static_cast<float>(mDeckLink.OutputFrameHeight()));
 		if (activeWordsLocation >= 0)
 			glUniform1f(activeWordsLocation, static_cast<float>(ActiveV210WordsForWidth(mDeckLink.OutputFrameWidth())));
 		glDrawArrays(GL_TRIANGLES, 0, 3);
 		glUseProgram(0);
 		glBindVertexArray(0);
 		glBindTexture(GL_TEXTURE_2D, 0);
 	}
 	glFlush();
 	const auto renderEndTime = std::chrono::steady_clock::now();
 	const double frameBudgetMilliseconds = mDeckLink.FrameBudgetMilliseconds();
 	const double renderMilliseconds = std::chrono::duration_cast<std::chrono::duration<double, std::milli>>(renderEndTime - renderStartTime).count();
 	mRuntimeHost.TrySetPerformanceStats(frameBudgetMilliseconds, renderMilliseconds);
 	mRuntimeHost.TryAdvanceFrame();
 	IDeckLinkVideoBuffer* outputVideoFrameBuffer;
 	if (outputVideoFrame->QueryInterface(IID_IDeckLinkVideoBuffer, (void**)&outputVideoFrameBuffer) != S_OK)
 	{
 		wglMakeCurrent(NULL, NULL);
 		LeaveCriticalSection(&mMutex);
 		return;
 	}
 	if (outputVideoFrameBuffer->StartAccess(bmdBufferAccessWrite) != S_OK)
 	{
 		outputVideoFrameBuffer->Release();
 		wglMakeCurrent(NULL, NULL);
 		LeaveCriticalSection(&mMutex);
 		return;
 	}
 	void*	pFrame;
 	outputVideoFrameBuffer->GetBytes(&pFrame);
 	glPixelStorei(GL_PACK_ALIGNMENT, 4);
 	glPixelStorei(GL_PACK_ROW_LENGTH, 0);
 	if (mDeckLink.OutputIsTenBit())
 	{
 		glBindFramebuffer(GL_READ_FRAMEBUFFER, mRenderer.OutputPackFramebuffer());
 		glReadPixels(0, 0, mDeckLink.OutputPackTextureWidth(), mDeckLink.OutputFrameHeight(), GL_RGBA, GL_UNSIGNED_BYTE, pFrame);
 	}
 	else
 	{
 		glBindFramebuffer(GL_READ_FRAMEBUFFER, mRenderer.OutputFramebuffer());
 		glReadPixels(0, 0, mDeckLink.OutputFrameWidth(), mDeckLink.OutputFrameHeight(), GL_BGRA, GL_UNSIGNED_INT_8_8_8_8_REV, pFrame);
 	}
 	mPaint();
 	outputVideoFrameBuffer->EndAccess(bmdBufferAccessWrite);
 	outputVideoFrameBuffer->Release();
 	mDeckLink.AccountForCompletionResult(completionResult);
 	// Schedule the next frame for playout
 	mDeckLink.ScheduleOutputFrame(outputVideoFrame);
 	wglMakeCurrent(NULL, NULL);
 	LeaveCriticalSection(&mMutex);
 }
--- a/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLDeckLinkBridge.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLDeckLinkBridge.h
@@ -1,55 +0,0 @@
 #pragma once
 #include "DeckLinkAPI_h.h"
 #include <windows.h>
 #include <chrono>
 #include <functional>
 #include <cstdint>
 class DeckLinkSession;
 class OpenGLRenderer;
 class RuntimeHost;
 class OpenGLDeckLinkBridge
 {
 public:
 	using RenderEffectCallback = std::function<void()>;
 	using OutputReadyCallback = std::function<void()>;
 	using PaintCallback = std::function<void()>;
 	OpenGLDeckLinkBridge(
 		DeckLinkSession& deckLink,
 		OpenGLRenderer& renderer,
 		RuntimeHost& runtimeHost,
 		CRITICAL_SECTION& mutex,
 		HDC hdc,
 		HGLRC hglrc,
 		RenderEffectCallback renderEffect,
 		OutputReadyCallback outputReady,
 		PaintCallback paint);
 	void VideoFrameArrived(IDeckLinkVideoInputFrame* inputFrame, bool hasNoInputSource);
 	void PlayoutFrameCompleted(IDeckLinkVideoFrame* completedFrame, BMDOutputFrameCompletionResult completionResult);
 private:
 	void RecordFramePacing(BMDOutputFrameCompletionResult completionResult);
 	DeckLinkSession& mDeckLink;
 	OpenGLRenderer& mRenderer;
 	RuntimeHost& mRuntimeHost;
 	CRITICAL_SECTION& mMutex;
 	HDC mHdc;
 	HGLRC mHglrc;
 	RenderEffectCallback mRenderEffect;
 	OutputReadyCallback mOutputReady;
 	PaintCallback mPaint;
 	std::chrono::steady_clock::time_point mLastPlayoutCompletionTime;
 	double mCompletionIntervalMilliseconds = 0.0;
 	double mSmoothedCompletionIntervalMilliseconds = 0.0;
 	double mMaxCompletionIntervalMilliseconds = 0.0;
 	uint64_t mLateFrameCount = 0;
 	uint64_t mDroppedFrameCount = 0;
 	uint64_t mFlushedFrameCount = 0;
 };
--- a/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLRenderPass.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLRenderPass.cpp
@@ -1,169 +0,0 @@
 #include "OpenGLRenderPass.h"
 #include "GlRenderConstants.h"
 OpenGLRenderPass::OpenGLRenderPass(OpenGLRenderer& renderer) :
 	mRenderer(renderer)
 {
 }
 void OpenGLRenderPass::Render(
 	bool hasInputSource,
 	const std::vector<RuntimeRenderState>& layerStates,
 	unsigned inputFrameWidth,
 	unsigned inputFrameHeight,
 	unsigned captureTextureWidth,
 	VideoIOPixelFormat inputPixelFormat,
 	unsigned historyCap,
 	const TextBindingUpdater& updateTextBinding,
 	const GlobalParamsUpdater& updateGlobalParams)
 {
 	glDisable(GL_SCISSOR_TEST);
 	glDisable(GL_BLEND);
 	glDisable(GL_DEPTH_TEST);
 	if (hasInputSource)
 	{
 		RenderDecodePass(inputFrameWidth, inputFrameHeight, captureTextureWidth, inputPixelFormat);
 	}
 	else
 	{
 		glBindFramebuffer(GL_FRAMEBUFFER, mRenderer.DecodeFramebuffer());
 		glViewport(0, 0, inputFrameWidth, inputFrameHeight);
 		glClearColor(0.0f, 0.0f, 0.0f, 1.0f);
 		glClear(GL_COLOR_BUFFER_BIT);
 	}
 	std::vector<LayerProgram>& layerPrograms = mRenderer.LayerPrograms();
 	if (layerStates.empty() || layerPrograms.empty())
 	{
 		glBindFramebuffer(GL_READ_FRAMEBUFFER, mRenderer.DecodeFramebuffer());
 		glBindFramebuffer(GL_DRAW_FRAMEBUFFER, mRenderer.CompositeFramebuffer());
 		glBlitFramebuffer(0, 0, inputFrameWidth, inputFrameHeight, 0, 0, inputFrameWidth, inputFrameHeight, GL_COLOR_BUFFER_BIT, GL_LINEAR);
 		glBindFramebuffer(GL_FRAMEBUFFER, mRenderer.CompositeFramebuffer());
 	}
 	else
 	{
 		GLuint sourceTexture = mRenderer.DecodedTexture();
 		GLuint sourceFrameBuffer = mRenderer.DecodeFramebuffer();
 		for (std::size_t index = 0; index < layerStates.size() && index < layerPrograms.size(); ++index)
 		{
 			const std::size_t remaining = layerStates.size() - index;
 			const bool writeToMain = (remaining % 2) == 1;
 			RenderShaderProgram(
 				sourceTexture,
 				writeToMain ? mRenderer.CompositeFramebuffer() : mRenderer.LayerTempFramebuffer(),
 				layerPrograms[index],
 				layerStates[index],
 				inputFrameWidth,
 				inputFrameHeight,
 				historyCap,
 				updateTextBinding,
 				updateGlobalParams);
 			if (layerStates[index].temporalHistorySource == TemporalHistorySource::PreLayerInput)
 				mRenderer.TemporalHistory().PushPreLayerFramebuffer(layerStates[index].layerId, sourceFrameBuffer, inputFrameWidth, inputFrameHeight);
 			sourceTexture = writeToMain ? mRenderer.CompositeTexture() : mRenderer.LayerTempTexture();
 			sourceFrameBuffer = writeToMain ? mRenderer.CompositeFramebuffer() : mRenderer.LayerTempFramebuffer();
 		}
 	}
 	mRenderer.TemporalHistory().PushSourceFramebuffer(mRenderer.DecodeFramebuffer(), inputFrameWidth, inputFrameHeight);
 }
 void OpenGLRenderPass::RenderDecodePass(unsigned inputFrameWidth, unsigned inputFrameHeight, unsigned captureTextureWidth, VideoIOPixelFormat inputPixelFormat)
 {
 	glBindFramebuffer(GL_FRAMEBUFFER, mRenderer.DecodeFramebuffer());
 	glViewport(0, 0, inputFrameWidth, inputFrameHeight);
 	glClear(GL_COLOR_BUFFER_BIT);
 	glActiveTexture(GL_TEXTURE0 + kPackedVideoTextureUnit);
 	glBindTexture(GL_TEXTURE_2D, mRenderer.CaptureTexture());
 	glBindVertexArray(mRenderer.FullscreenVertexArray());
 	glUseProgram(mRenderer.DecodeProgram());
 	const GLint packedResolutionLocation = glGetUniformLocation(mRenderer.DecodeProgram(), "uPackedVideoResolution");
 	const GLint decodedResolutionLocation = glGetUniformLocation(mRenderer.DecodeProgram(), "uDecodedVideoResolution");
 	const GLint inputPixelFormatLocation = glGetUniformLocation(mRenderer.DecodeProgram(), "uInputPixelFormat");
 	if (packedResolutionLocation >= 0)
 		glUniform2f(packedResolutionLocation, static_cast<float>(captureTextureWidth), static_cast<float>(inputFrameHeight));
 	if (decodedResolutionLocation >= 0)
 		glUniform2f(decodedResolutionLocation, static_cast<float>(inputFrameWidth), static_cast<float>(inputFrameHeight));
 	if (inputPixelFormatLocation >= 0)
 		glUniform1i(inputPixelFormatLocation, inputPixelFormat == VideoIOPixelFormat::V210 ? 1 : 0);
 	glDrawArrays(GL_TRIANGLES, 0, 3);
 	glUseProgram(0);
 	glBindVertexArray(0);
 	glBindTexture(GL_TEXTURE_2D, 0);
 	glActiveTexture(GL_TEXTURE0);
 }
 void OpenGLRenderPass::RenderShaderProgram(
 	GLuint sourceTexture,
 	GLuint destinationFrameBuffer,
 	LayerProgram& layerProgram,
 	const RuntimeRenderState& state,
 	unsigned inputFrameWidth,
 	unsigned inputFrameHeight,
 	unsigned historyCap,
 	const TextBindingUpdater& updateTextBinding,
 	const GlobalParamsUpdater& updateGlobalParams)
 {
 	for (LayerProgram::TextBinding& textBinding : layerProgram.textBindings)
 	{
 		std::string textError;
 		if (!updateTextBinding(state, textBinding, textError))
 			OutputDebugStringA((textError + "\n").c_str());
 	}
 	glBindFramebuffer(GL_FRAMEBUFFER, destinationFrameBuffer);
 	glViewport(0, 0, inputFrameWidth, inputFrameHeight);
 	glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT);
 	glActiveTexture(GL_TEXTURE0 + kDecodedVideoTextureUnit);
 	glBindTexture(GL_TEXTURE_2D, sourceTexture);
 	mRenderer.TemporalHistory().BindSamplers(state, sourceTexture, historyCap);
 	BindLayerTextureAssets(layerProgram);
 	glBindVertexArray(mRenderer.FullscreenVertexArray());
 	glUseProgram(layerProgram.program);
 	updateGlobalParams(state, mRenderer.TemporalHistory().SourceAvailableCount(), mRenderer.TemporalHistory().AvailableCountForLayer(state.layerId));
 	glDrawArrays(GL_TRIANGLES, 0, 3);
 	glUseProgram(0);
 	glBindVertexArray(0);
 	UnbindLayerTextureAssets(layerProgram, historyCap);
 }
 void OpenGLRenderPass::BindLayerTextureAssets(const LayerProgram& layerProgram)
 {
 	const GLuint shaderTextureBase = layerProgram.shaderTextureBase != 0 ? layerProgram.shaderTextureBase : kSourceHistoryTextureUnitBase;
 	for (std::size_t index = 0; index < layerProgram.textureBindings.size(); ++index)
 	{
 		glActiveTexture(GL_TEXTURE0 + shaderTextureBase + static_cast<GLuint>(index));
 		glBindTexture(GL_TEXTURE_2D, layerProgram.textureBindings[index].texture);
 	}
 	const GLuint textTextureBase = shaderTextureBase + static_cast<GLuint>(layerProgram.textureBindings.size());
 	for (std::size_t index = 0; index < layerProgram.textBindings.size(); ++index)
 	{
 		glActiveTexture(GL_TEXTURE0 + textTextureBase + static_cast<GLuint>(index));
 		glBindTexture(GL_TEXTURE_2D, layerProgram.textBindings[index].texture);
 	}
 	glActiveTexture(GL_TEXTURE0);
 }
 void OpenGLRenderPass::UnbindLayerTextureAssets(const LayerProgram& layerProgram, unsigned historyCap)
 {
 	for (unsigned index = 0; index < historyCap; ++index)
 	{
 		glActiveTexture(GL_TEXTURE0 + kSourceHistoryTextureUnitBase + index);
 		glBindTexture(GL_TEXTURE_2D, 0);
 		glActiveTexture(GL_TEXTURE0 + kSourceHistoryTextureUnitBase + historyCap + index);
 		glBindTexture(GL_TEXTURE_2D, 0);
 	}
 	const GLuint shaderTextureBase = layerProgram.shaderTextureBase != 0 ? layerProgram.shaderTextureBase : kSourceHistoryTextureUnitBase;
 	for (std::size_t index = 0; index < layerProgram.textureBindings.size() + layerProgram.textBindings.size(); ++index)
 	{
 		glActiveTexture(GL_TEXTURE0 + shaderTextureBase + static_cast<GLuint>(index));
 		glBindTexture(GL_TEXTURE_2D, 0);
 	}
 	glActiveTexture(GL_TEXTURE0 + kDecodedVideoTextureUnit);
 	glBindTexture(GL_TEXTURE_2D, 0);
 	glActiveTexture(GL_TEXTURE0);
 }
--- a/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLRenderPass.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLRenderPass.h
@@ -1,47 +0,0 @@
 #pragma once
 #include "OpenGLRenderer.h"
 #include "ShaderTypes.h"
 #include "VideoIOFormat.h"
 #include <functional>
 #include <string>
 #include <vector>
 class OpenGLRenderPass
 {
 public:
 	using LayerProgram = OpenGLRenderer::LayerProgram;
 	using TextBindingUpdater = std::function<bool(const RuntimeRenderState&, LayerProgram::TextBinding&, std::string&)>;
 	using GlobalParamsUpdater = std::function<bool(const RuntimeRenderState&, unsigned, unsigned)>;
 	explicit OpenGLRenderPass(OpenGLRenderer& renderer);
 	void Render(
 		bool hasInputSource,
 		const std::vector<RuntimeRenderState>& layerStates,
 		unsigned inputFrameWidth,
 		unsigned inputFrameHeight,
 		unsigned captureTextureWidth,
 		VideoIOPixelFormat inputPixelFormat,
 		unsigned historyCap,
 		const TextBindingUpdater& updateTextBinding,
 		const GlobalParamsUpdater& updateGlobalParams);
 private:
 	void RenderDecodePass(unsigned inputFrameWidth, unsigned inputFrameHeight, unsigned captureTextureWidth, VideoIOPixelFormat inputPixelFormat);
 	void RenderShaderProgram(
 		GLuint sourceTexture,
 		GLuint destinationFrameBuffer,
 		LayerProgram& layerProgram,
 		const RuntimeRenderState& state,
 		unsigned inputFrameWidth,
 		unsigned inputFrameHeight,
 		unsigned historyCap,
 		const TextBindingUpdater& updateTextBinding,
 		const GlobalParamsUpdater& updateGlobalParams);
 	void BindLayerTextureAssets(const LayerProgram& layerProgram);
 	void UnbindLayerTextureAssets(const LayerProgram& layerProgram, unsigned historyCap);
 	OpenGLRenderer& mRenderer;
 };
--- a/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLRenderer.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLRenderer.cpp
@@ -1,330 +0,0 @@
 #include "OpenGLRenderer.h"
 #include "GlRenderConstants.h"
 namespace
 {
 	void ConfigureByteFrameTexture(unsigned width, unsigned height)
 	{
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
 		glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA8, width, height, 0, GL_RGBA, GL_UNSIGNED_BYTE, NULL);
 	}
 	void ConfigureDisplayFrameTexture(unsigned width, unsigned height)
 	{
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
 		glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA16F, width, height, 0, GL_RGBA, GL_FLOAT, NULL);
 	}
 }
 bool OpenGLRenderer::InitializeResources(unsigned inputFrameWidth, unsigned inputFrameHeight, unsigned captureTextureWidth, unsigned outputFrameWidth, unsigned outputFrameHeight, unsigned outputPackTextureWidth, std::string& error)
 {
 	glClearColor(0.0f, 0.0f, 0.0f, 0.5f);
 	glDisable(GL_DEPTH_TEST);
 	glGenBuffers(1, &mTextureUploadBuffer);
 	glGenTextures(1, &mCaptureTexture);
 	glBindTexture(GL_TEXTURE_2D, mCaptureTexture);
 	ConfigureByteFrameTexture(captureTextureWidth, inputFrameHeight);
 	glBindTexture(GL_TEXTURE_2D, 0);
 	glGenTextures(1, &mDecodedTexture);
 	glBindTexture(GL_TEXTURE_2D, mDecodedTexture);
 	ConfigureDisplayFrameTexture(inputFrameWidth, inputFrameHeight);
 	glBindTexture(GL_TEXTURE_2D, 0);
 	glGenTextures(1, &mLayerTempTexture);
 	glBindTexture(GL_TEXTURE_2D, mLayerTempTexture);
 	ConfigureDisplayFrameTexture(inputFrameWidth, inputFrameHeight);
 	glBindTexture(GL_TEXTURE_2D, 0);
 	glGenFramebuffers(1, &mDecodeFrameBuf);
 	glGenFramebuffers(1, &mLayerTempFrameBuf);
 	glGenFramebuffers(1, &mIdFrameBuf);
 	glGenFramebuffers(1, &mOutputFrameBuf);
 	glGenFramebuffers(1, &mOutputPackFrameBuf);
 	glGenRenderbuffers(1, &mIdColorBuf);
 	glGenRenderbuffers(1, &mIdDepthBuf);
 	glGenVertexArrays(1, &mFullscreenVAO);
 	glGenBuffers(1, &mGlobalParamsUBO);
 	glBindFramebuffer(GL_FRAMEBUFFER, mDecodeFrameBuf);
 	glFramebufferTexture2D(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, GL_TEXTURE_2D, mDecodedTexture, 0);
 	if (glCheckFramebufferStatus(GL_FRAMEBUFFER) != GL_FRAMEBUFFER_COMPLETE)
 	{
 		error = "Cannot initialize decode framebuffer.";
 		return false;
 	}
 	glBindFramebuffer(GL_FRAMEBUFFER, mLayerTempFrameBuf);
 	glFramebufferTexture2D(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, GL_TEXTURE_2D, mLayerTempTexture, 0);
 	if (glCheckFramebufferStatus(GL_FRAMEBUFFER) != GL_FRAMEBUFFER_COMPLETE)
 	{
 		error = "Cannot initialize layer framebuffer.";
 		return false;
 	}
 	glBindFramebuffer(GL_FRAMEBUFFER, mIdFrameBuf);
 	glGenTextures(1, &mFBOTexture);
 	glBindTexture(GL_TEXTURE_2D, mFBOTexture);
 	ConfigureDisplayFrameTexture(inputFrameWidth, inputFrameHeight);
 	glBindRenderbuffer(GL_RENDERBUFFER, mIdDepthBuf);
 	glRenderbufferStorage(GL_RENDERBUFFER, GL_DEPTH_COMPONENT24, inputFrameWidth, inputFrameHeight);
 	glFramebufferRenderbuffer(GL_FRAMEBUFFER, GL_DEPTH_ATTACHMENT_EXT, GL_RENDERBUFFER, mIdDepthBuf);
 	glFramebufferTexture2D(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, GL_TEXTURE_2D, mFBOTexture, 0);
 	if (glCheckFramebufferStatus(GL_FRAMEBUFFER) != GL_FRAMEBUFFER_COMPLETE)
 	{
 		error = "Cannot initialize framebuffer.";
 		return false;
 	}
 	glGenTextures(1, &mOutputTexture);
 	glBindTexture(GL_TEXTURE_2D, mOutputTexture);
 	ConfigureDisplayFrameTexture(outputFrameWidth, outputFrameHeight);
 	glBindFramebuffer(GL_FRAMEBUFFER, mOutputFrameBuf);
 	glFramebufferTexture2D(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, GL_TEXTURE_2D, mOutputTexture, 0);
 	if (glCheckFramebufferStatus(GL_FRAMEBUFFER) != GL_FRAMEBUFFER_COMPLETE)
 	{
 		error = "Cannot initialize output framebuffer.";
 		return false;
 	}
 	glGenTextures(1, &mOutputPackTexture);
 	glBindTexture(GL_TEXTURE_2D, mOutputPackTexture);
 	ConfigureByteFrameTexture(outputPackTextureWidth, outputFrameHeight);
 	glBindFramebuffer(GL_FRAMEBUFFER, mOutputPackFrameBuf);
 	glFramebufferTexture2D(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, GL_TEXTURE_2D, mOutputPackTexture, 0);
 	if (glCheckFramebufferStatus(GL_FRAMEBUFFER) != GL_FRAMEBUFFER_COMPLETE)
 	{
 		error = "Cannot initialize output pack framebuffer.";
 		return false;
 	}
 	glBindTexture(GL_TEXTURE_2D, 0);
 	glBindRenderbuffer(GL_RENDERBUFFER, 0);
 	glBindFramebuffer(GL_FRAMEBUFFER, 0);
 	glBindVertexArray(mFullscreenVAO);
 	glBindVertexArray(0);
 	glBindBuffer(GL_UNIFORM_BUFFER, mGlobalParamsUBO);
 	glBufferData(GL_UNIFORM_BUFFER, 1024, NULL, GL_DYNAMIC_DRAW);
 	glBindBufferBase(GL_UNIFORM_BUFFER, kGlobalParamsBindingPoint, mGlobalParamsUBO);
 	glBindBuffer(GL_UNIFORM_BUFFER, 0);
 	return true;
 }
 void OpenGLRenderer::SetDecodeShaderProgram(GLuint program, GLuint vertexShader, GLuint fragmentShader)
 {
 	mDecodeProgram = program;
 	mDecodeVertexShader = vertexShader;
 	mDecodeFragmentShader = fragmentShader;
 }
 void OpenGLRenderer::SetOutputPackShaderProgram(GLuint program, GLuint vertexShader, GLuint fragmentShader)
 {
 	mOutputPackProgram = program;
 	mOutputPackVertexShader = vertexShader;
 	mOutputPackFragmentShader = fragmentShader;
 }
 void OpenGLRenderer::ResizeView(int width, int height)
 {
 	mViewWidth = width;
 	mViewHeight = height;
 }
 void OpenGLRenderer::PresentToWindow(HDC hdc, unsigned outputFrameWidth, unsigned outputFrameHeight)
 {
 	int destWidth = mViewWidth;
 	int destHeight = mViewHeight;
 	int destX = 0;
 	int destY = 0;
 	if (outputFrameWidth > 0 && outputFrameHeight > 0 && mViewWidth > 0 && mViewHeight > 0)
 	{
 		const double frameAspect = static_cast<double>(outputFrameWidth) / static_cast<double>(outputFrameHeight);
 		const double viewAspect = static_cast<double>(mViewWidth) / static_cast<double>(mViewHeight);
 		if (viewAspect > frameAspect)
 		{
 			destHeight = mViewHeight;
 			destWidth = static_cast<int>(destHeight * frameAspect + 0.5);
 			destX = (mViewWidth - destWidth) / 2;
 		}
 		else
 		{
 			destWidth = mViewWidth;
 			destHeight = static_cast<int>(destWidth / frameAspect + 0.5);
 			destY = (mViewHeight - destHeight) / 2;
 		}
 	}
 	glBindFramebuffer(GL_READ_FRAMEBUFFER, mOutputFrameBuf);
 	glBindFramebuffer(GL_DRAW_FRAMEBUFFER, 0);
 	glDisable(GL_SCISSOR_TEST);
 	glViewport(0, 0, mViewWidth, mViewHeight);
 	glClearColor(0.0f, 0.0f, 0.0f, 1.0f);
 	glClear(GL_COLOR_BUFFER_BIT);
 	glBlitFramebuffer(0, 0, outputFrameWidth, outputFrameHeight, destX, destY, destX + destWidth, destY + destHeight, GL_COLOR_BUFFER_BIT, GL_LINEAR);
 	SwapBuffers(hdc);
 }
 void OpenGLRenderer::DestroyResources()
 {
 	if (mFullscreenVAO != 0)
 		glDeleteVertexArrays(1, &mFullscreenVAO);
 	if (mGlobalParamsUBO != 0)
 		glDeleteBuffers(1, &mGlobalParamsUBO);
 	if (mDecodeFrameBuf != 0)
 		glDeleteFramebuffers(1, &mDecodeFrameBuf);
 	if (mLayerTempFrameBuf != 0)
 		glDeleteFramebuffers(1, &mLayerTempFrameBuf);
 	if (mIdFrameBuf != 0)
 		glDeleteFramebuffers(1, &mIdFrameBuf);
 	if (mOutputFrameBuf != 0)
 		glDeleteFramebuffers(1, &mOutputFrameBuf);
 	if (mOutputPackFrameBuf != 0)
 		glDeleteFramebuffers(1, &mOutputPackFrameBuf);
 	if (mIdColorBuf != 0)
 		glDeleteRenderbuffers(1, &mIdColorBuf);
 	if (mIdDepthBuf != 0)
 		glDeleteRenderbuffers(1, &mIdDepthBuf);
 	if (mCaptureTexture != 0)
 		glDeleteTextures(1, &mCaptureTexture);
 	if (mDecodedTexture != 0)
 		glDeleteTextures(1, &mDecodedTexture);
 	if (mLayerTempTexture != 0)
 		glDeleteTextures(1, &mLayerTempTexture);
 	if (mFBOTexture != 0)
 		glDeleteTextures(1, &mFBOTexture);
 	if (mOutputTexture != 0)
 		glDeleteTextures(1, &mOutputTexture);
 	if (mOutputPackTexture != 0)
 		glDeleteTextures(1, &mOutputPackTexture);
 	if (mTextureUploadBuffer != 0)
 		glDeleteBuffers(1, &mTextureUploadBuffer);
 	mFullscreenVAO = 0;
 	mGlobalParamsUBO = 0;
 	mDecodeFrameBuf = 0;
 	mLayerTempFrameBuf = 0;
 	mIdFrameBuf = 0;
 	mOutputFrameBuf = 0;
 	mOutputPackFrameBuf = 0;
 	mIdColorBuf = 0;
 	mIdDepthBuf = 0;
 	mCaptureTexture = 0;
 	mDecodedTexture = 0;
 	mLayerTempTexture = 0;
 	mFBOTexture = 0;
 	mOutputTexture = 0;
 	mOutputPackTexture = 0;
 	mTextureUploadBuffer = 0;
 	mGlobalParamsUBOSize = 0;
 	mTemporalHistory.DestroyResources();
 	DestroyLayerPrograms();
 	DestroyDecodeShaderProgram();
 	DestroyOutputPackShaderProgram();
 }
 void OpenGLRenderer::DestroySingleLayerProgram(LayerProgram& layerProgram)
 {
 	for (LayerProgram::TextureBinding& binding : layerProgram.textureBindings)
 	{
 		if (binding.texture != 0)
 		{
 			glDeleteTextures(1, &binding.texture);
 			binding.texture = 0;
 		}
 	}
 	layerProgram.textureBindings.clear();
 	for (LayerProgram::TextBinding& binding : layerProgram.textBindings)
 	{
 		if (binding.texture != 0)
 		{
 			glDeleteTextures(1, &binding.texture);
 			binding.texture = 0;
 		}
 	}
 	layerProgram.textBindings.clear();
 	if (layerProgram.program != 0)
 	{
 		glDeleteProgram(layerProgram.program);
 		layerProgram.program = 0;
 	}
 	if (layerProgram.fragmentShader != 0)
 	{
 		glDeleteShader(layerProgram.fragmentShader);
 		layerProgram.fragmentShader = 0;
 	}
 	if (layerProgram.vertexShader != 0)
 	{
 		glDeleteShader(layerProgram.vertexShader);
 		layerProgram.vertexShader = 0;
 	}
 }
 void OpenGLRenderer::DestroyLayerPrograms()
 {
 	for (LayerProgram& layerProgram : mLayerPrograms)
 		DestroySingleLayerProgram(layerProgram);
 	mLayerPrograms.clear();
 }
 void OpenGLRenderer::DestroyDecodeShaderProgram()
 {
 	if (mDecodeProgram != 0)
 	{
 		glDeleteProgram(mDecodeProgram);
 		mDecodeProgram = 0;
 	}
 	if (mDecodeFragmentShader != 0)
 	{
 		glDeleteShader(mDecodeFragmentShader);
 		mDecodeFragmentShader = 0;
 	}
 	if (mDecodeVertexShader != 0)
 	{
 		glDeleteShader(mDecodeVertexShader);
 		mDecodeVertexShader = 0;
 	}
 }
 void OpenGLRenderer::DestroyOutputPackShaderProgram()
 {
 	if (mOutputPackProgram != 0)
 	{
 		glDeleteProgram(mOutputPackProgram);
 		mOutputPackProgram = 0;
 	}
 	if (mOutputPackFragmentShader != 0)
 	{
 		glDeleteShader(mOutputPackFragmentShader);
 		mOutputPackFragmentShader = 0;
 	}
 	if (mOutputPackVertexShader != 0)
 	{
 		glDeleteShader(mOutputPackVertexShader);
 		mOutputPackVertexShader = 0;
 	}
 }
--- a/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLRenderer.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLRenderer.h
@@ -1,109 +0,0 @@
 #pragma once
 #include "GLExtensions.h"
 #include "ShaderTypes.h"
 #include "TemporalHistoryBuffers.h"
 #include <windows.h>
 #include <filesystem>
 #include <gl/gl.h>
 #include <string>
 #include <vector>
 class OpenGLRenderer
 {
 public:
 	struct LayerProgram
 	{
 		struct TextureBinding
 		{
 			std::string samplerName;
 			std::filesystem::path sourcePath;
 			GLuint texture = 0;
 		};
 		struct TextBinding
 		{
 			std::string parameterId;
 			std::string samplerName;
 			std::string fontId;
 			GLuint texture = 0;
 			std::string renderedText;
 			unsigned renderedWidth = 0;
 			unsigned renderedHeight = 0;
 		};
 		std::string layerId;
 		std::string shaderId;
 		GLuint shaderTextureBase = 0;
 		GLuint program = 0;
 		GLuint vertexShader = 0;
 		GLuint fragmentShader = 0;
 		std::vector<TextureBinding> textureBindings;
 		std::vector<TextBinding> textBindings;
 	};
 	GLuint CaptureTexture() const { return mCaptureTexture; }
 	GLuint DecodedTexture() const { return mDecodedTexture; }
 	GLuint LayerTempTexture() const { return mLayerTempTexture; }
 	GLuint CompositeTexture() const { return mFBOTexture; }
 	GLuint OutputTexture() const { return mOutputTexture; }
 	GLuint OutputPackTexture() const { return mOutputPackTexture; }
 	GLuint TextureUploadBuffer() const { return mTextureUploadBuffer; }
 	GLuint DecodeFramebuffer() const { return mDecodeFrameBuf; }
 	GLuint LayerTempFramebuffer() const { return mLayerTempFrameBuf; }
 	GLuint CompositeFramebuffer() const { return mIdFrameBuf; }
 	GLuint OutputFramebuffer() const { return mOutputFrameBuf; }
 	GLuint OutputPackFramebuffer() const { return mOutputPackFrameBuf; }
 	GLuint FullscreenVertexArray() const { return mFullscreenVAO; }
 	GLuint GlobalParamsUBO() const { return mGlobalParamsUBO; }
 	GLuint DecodeProgram() const { return mDecodeProgram; }
 	GLuint OutputPackProgram() const { return mOutputPackProgram; }
 	GLsizeiptr GlobalParamsUBOSize() const { return mGlobalParamsUBOSize; }
 	void SetGlobalParamsUBOSize(GLsizeiptr size) { mGlobalParamsUBOSize = size; }
 	void ReplaceLayerPrograms(std::vector<LayerProgram>& newPrograms) { mLayerPrograms.swap(newPrograms); }
 	std::vector<LayerProgram>& LayerPrograms() { return mLayerPrograms; }
 	const std::vector<LayerProgram>& LayerPrograms() const { return mLayerPrograms; }
 	TemporalHistoryBuffers& TemporalHistory() { return mTemporalHistory; }
 	const TemporalHistoryBuffers& TemporalHistory() const { return mTemporalHistory; }
 	void SetDecodeShaderProgram(GLuint program, GLuint vertexShader, GLuint fragmentShader);
 	void SetOutputPackShaderProgram(GLuint program, GLuint vertexShader, GLuint fragmentShader);
 	bool InitializeResources(unsigned inputFrameWidth, unsigned inputFrameHeight, unsigned captureTextureWidth, unsigned outputFrameWidth, unsigned outputFrameHeight, unsigned outputPackTextureWidth, std::string& error);
 	void ResizeView(int width, int height);
 	void PresentToWindow(HDC hdc, unsigned outputFrameWidth, unsigned outputFrameHeight);
 	void DestroyResources();
 	void DestroySingleLayerProgram(LayerProgram& layerProgram);
 	void DestroyLayerPrograms();
 	void DestroyDecodeShaderProgram();
 	void DestroyOutputPackShaderProgram();
 private:
 	GLuint mCaptureTexture = 0;
 	GLuint mDecodedTexture = 0;
 	GLuint mLayerTempTexture = 0;
 	GLuint mFBOTexture = 0;
 	GLuint mOutputTexture = 0;
 	GLuint mOutputPackTexture = 0;
 	GLuint mTextureUploadBuffer = 0;
 	GLuint mDecodeFrameBuf = 0;
 	GLuint mLayerTempFrameBuf = 0;
 	GLuint mIdFrameBuf = 0;
 	GLuint mOutputFrameBuf = 0;
 	GLuint mOutputPackFrameBuf = 0;
 	GLuint mIdColorBuf = 0;
 	GLuint mIdDepthBuf = 0;
 	GLuint mFullscreenVAO = 0;
 	GLuint mGlobalParamsUBO = 0;
 	GLuint mDecodeProgram = 0;
 	GLuint mDecodeVertexShader = 0;
 	GLuint mDecodeFragmentShader = 0;
 	GLuint mOutputPackProgram = 0;
 	GLuint mOutputPackVertexShader = 0;
 	GLuint mOutputPackFragmentShader = 0;
 	GLsizeiptr mGlobalParamsUBOSize = 0;
 	int mViewWidth = 0;
 	int mViewHeight = 0;
 	std::vector<LayerProgram> mLayerPrograms;
 	TemporalHistoryBuffers mTemporalHistory;
 };
--- a/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLShaderPrograms.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLShaderPrograms.cpp
@@ -1,151 +0,0 @@
 #include "OpenGLShaderPrograms.h"
 #include <cstring>
 #include <string>
 #include <vector>
 namespace
 {
 void CopyErrorMessage(const std::string& message, int errorMessageSize, char* errorMessage)
 {
 	if (!errorMessage || errorMessageSize <= 0)
 		return;
 	strncpy_s(errorMessage, errorMessageSize, message.c_str(), _TRUNCATE);
 }
 }
 OpenGLShaderPrograms::OpenGLShaderPrograms(OpenGLRenderer& renderer, RuntimeHost& runtimeHost) :
 	mRenderer(renderer),
 	mRuntimeHost(runtimeHost),
 	mGlobalParamsBuffer(renderer),
 	mCompiler(renderer, runtimeHost, mTextureBindings)
 {
 }
 bool OpenGLShaderPrograms::CompileLayerPrograms(unsigned inputFrameWidth, unsigned inputFrameHeight, int errorMessageSize, char* errorMessage)
 {
 	const std::vector<RuntimeRenderState> layerStates = mRuntimeHost.GetLayerRenderStates(inputFrameWidth, inputFrameHeight);
 	std::string temporalError;
 	const unsigned historyCap = mRuntimeHost.GetMaxTemporalHistoryFrames();
 	if (!mRenderer.TemporalHistory().ValidateTextureUnitBudget(layerStates, historyCap, temporalError))
 	{
 		CopyErrorMessage(temporalError, errorMessageSize, errorMessage);
 		return false;
 	}
 	if (!mRenderer.TemporalHistory().EnsureResources(layerStates, historyCap, inputFrameWidth, inputFrameHeight, temporalError))
 	{
 		CopyErrorMessage(temporalError, errorMessageSize, errorMessage);
 		return false;
 	}
 	std::vector<LayerProgram> newPrograms;
 	newPrograms.reserve(layerStates.size());
 	for (const RuntimeRenderState& state : layerStates)
 	{
 		LayerProgram layerProgram;
 		if (!mCompiler.CompileLayerProgram(state, layerProgram, errorMessageSize, errorMessage))
 		{
 			for (LayerProgram& program : newPrograms)
 				DestroySingleLayerProgram(program);
 			return false;
 		}
 		newPrograms.push_back(layerProgram);
 	}
 	DestroyLayerPrograms();
 	mRenderer.ReplaceLayerPrograms(newPrograms);
 	mCommittedLayerStates = layerStates;
 	mRuntimeHost.SetCompileStatus(true, "Shader layers compiled successfully.");
 	mRuntimeHost.ClearReloadRequest();
 	return true;
 }
 bool OpenGLShaderPrograms::CommitPreparedLayerPrograms(const PreparedShaderBuild& preparedBuild, unsigned inputFrameWidth, unsigned inputFrameHeight, int errorMessageSize, char* errorMessage)
 {
 	if (!preparedBuild.succeeded)
 	{
 		CopyErrorMessage(preparedBuild.message, errorMessageSize, errorMessage);
 		return false;
 	}
 	std::string temporalError;
 	const unsigned historyCap = mRuntimeHost.GetMaxTemporalHistoryFrames();
 	if (!mRenderer.TemporalHistory().ValidateTextureUnitBudget(preparedBuild.layerStates, historyCap, temporalError))
 	{
 		CopyErrorMessage(temporalError, errorMessageSize, errorMessage);
 		return false;
 	}
 	if (!mRenderer.TemporalHistory().EnsureResources(preparedBuild.layerStates, historyCap, inputFrameWidth, inputFrameHeight, temporalError))
 	{
 		CopyErrorMessage(temporalError, errorMessageSize, errorMessage);
 		return false;
 	}
 	std::vector<LayerProgram> newPrograms;
 	newPrograms.reserve(preparedBuild.layers.size());
 	for (const PreparedLayerShader& preparedLayer : preparedBuild.layers)
 	{
 		LayerProgram layerProgram;
 		if (!mCompiler.CompilePreparedLayerProgram(preparedLayer.state, preparedLayer.fragmentShaderSource, layerProgram, errorMessageSize, errorMessage))
 		{
 			for (LayerProgram& program : newPrograms)
 				DestroySingleLayerProgram(program);
 			return false;
 		}
 		newPrograms.push_back(layerProgram);
 	}
 	DestroyLayerPrograms();
 	mRenderer.ReplaceLayerPrograms(newPrograms);
 	mCommittedLayerStates = preparedBuild.layerStates;
 	mRuntimeHost.SetCompileStatus(true, "Shader layers compiled successfully.");
 	mRuntimeHost.ClearReloadRequest();
 	return true;
 }
 bool OpenGLShaderPrograms::CompileDecodeShader(int errorMessageSize, char* errorMessage)
 {
 	return mCompiler.CompileDecodeShader(errorMessageSize, errorMessage);
 }
 bool OpenGLShaderPrograms::CompileOutputPackShader(int errorMessageSize, char* errorMessage)
 {
 	return mCompiler.CompileOutputPackShader(errorMessageSize, errorMessage);
 }
 void OpenGLShaderPrograms::DestroySingleLayerProgram(LayerProgram& layerProgram)
 {
 	mRenderer.DestroySingleLayerProgram(layerProgram);
 }
 void OpenGLShaderPrograms::DestroyLayerPrograms()
 {
 	mRenderer.DestroyLayerPrograms();
 }
 void OpenGLShaderPrograms::DestroyDecodeShaderProgram()
 {
 	mRenderer.DestroyDecodeShaderProgram();
 }
 void OpenGLShaderPrograms::ResetTemporalHistoryState()
 {
 	mRenderer.TemporalHistory().ResetState();
 }
 bool OpenGLShaderPrograms::UpdateTextBindingTexture(const RuntimeRenderState& state, LayerProgram::TextBinding& textBinding, std::string& error)
 {
 	return mTextureBindings.UpdateTextBindingTexture(state, textBinding, error);
 }
 bool OpenGLShaderPrograms::UpdateGlobalParamsBuffer(const RuntimeRenderState& state, unsigned availableSourceHistoryLength, unsigned availableTemporalHistoryLength)
 {
 	return mGlobalParamsBuffer.Update(state, availableSourceHistoryLength, availableTemporalHistoryLength);
 }
--- a/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLShaderPrograms.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/OpenGLShaderPrograms.h
@@ -1,39 +0,0 @@
 #pragma once
 #include "GlobalParamsBuffer.h"
 #include "OpenGLRenderer.h"
 #include "RuntimeHost.h"
 #include "ShaderBuildQueue.h"
 #include "ShaderTypes.h"
 #include "ShaderProgramCompiler.h"
 #include "ShaderTextureBindings.h"
 #include <string>
 class OpenGLShaderPrograms
 {
 public:
 	using LayerProgram = OpenGLRenderer::LayerProgram;
 	OpenGLShaderPrograms(OpenGLRenderer& renderer, RuntimeHost& runtimeHost);
 	bool CompileLayerPrograms(unsigned inputFrameWidth, unsigned inputFrameHeight, int errorMessageSize, char* errorMessage);
 	bool CommitPreparedLayerPrograms(const PreparedShaderBuild& preparedBuild, unsigned inputFrameWidth, unsigned inputFrameHeight, int errorMessageSize, char* errorMessage);
 	bool CompileDecodeShader(int errorMessageSize, char* errorMessage);
 	bool CompileOutputPackShader(int errorMessageSize, char* errorMessage);
 	void DestroyLayerPrograms();
 	void DestroySingleLayerProgram(LayerProgram& layerProgram);
 	void DestroyDecodeShaderProgram();
 	void ResetTemporalHistoryState();
 	const std::vector<RuntimeRenderState>& CommittedLayerStates() const { return mCommittedLayerStates; }
 	bool UpdateTextBindingTexture(const RuntimeRenderState& state, LayerProgram::TextBinding& textBinding, std::string& error);
 	bool UpdateGlobalParamsBuffer(const RuntimeRenderState& state, unsigned availableSourceHistoryLength, unsigned availableTemporalHistoryLength);
 private:
 	OpenGLRenderer& mRenderer;
 	RuntimeHost& mRuntimeHost;
 	ShaderTextureBindings mTextureBindings;
 	GlobalParamsBuffer mGlobalParamsBuffer;
 	ShaderProgramCompiler mCompiler;
 	std::vector<RuntimeRenderState> mCommittedLayerStates;
 };
--- a/apps/LoopThroughWithOpenGLCompositing/gl/PngScreenshotWriter.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/PngScreenshotWriter.cpp
@@ -1,137 +0,0 @@
 #include "PngScreenshotWriter.h"
 #include <windows.h>
 #include <wincodec.h>
 #include <atlbase.h>
 #include <sstream>
 #include <thread>
 namespace
 {
 std::string HResultToString(HRESULT hr)
 {
 	std::ostringstream stream;
 	stream << "HRESULT 0x" << std::hex << static_cast<unsigned long>(hr);
 	return stream.str();
 }
 bool WritePngFile(
 	const std::filesystem::path& outputPath,
 	unsigned width,
 	unsigned height,
 	const std::vector<unsigned char>& bgraPixels,
 	std::string& error)
 {
 	if (width == 0 || height == 0 || bgraPixels.size() < static_cast<std::size_t>(width) * height * 4)
 	{
 		error = "Invalid screenshot dimensions or pixel buffer.";
 		return false;
 	}
 	HRESULT initializeResult = CoInitializeEx(nullptr, COINIT_MULTITHREADED);
 	const bool shouldUninitialize = SUCCEEDED(initializeResult);
 	if (FAILED(initializeResult) && initializeResult != RPC_E_CHANGED_MODE)
 	{
 		error = "CoInitializeEx failed: " + HResultToString(initializeResult);
 		return false;
 	}
 	CComPtr<IWICImagingFactory> factory;
 	HRESULT result = CoCreateInstance(
 		CLSID_WICImagingFactory,
 		nullptr,
 		CLSCTX_INPROC_SERVER,
 		IID_PPV_ARGS(&factory));
 	if (FAILED(result))
 	{
 		error = "Could not create WIC imaging factory: " + HResultToString(result);
 		if (shouldUninitialize)
 			CoUninitialize();
 		return false;
 	}
 	CComPtr<IWICStream> stream;
 	result = factory->CreateStream(&stream);
 	if (SUCCEEDED(result))
 		result = stream->InitializeFromFilename(outputPath.wstring().c_str(), GENERIC_WRITE);
 	if (FAILED(result))
 	{
 		error = "Could not open screenshot output file: " + HResultToString(result);
 		if (shouldUninitialize)
 			CoUninitialize();
 		return false;
 	}
 	CComPtr<IWICBitmapEncoder> encoder;
 	result = factory->CreateEncoder(GUID_ContainerFormatPng, nullptr, &encoder);
 	if (SUCCEEDED(result))
 		result = encoder->Initialize(stream, WICBitmapEncoderNoCache);
 	if (FAILED(result))
 	{
 		error = "Could not initialize PNG encoder: " + HResultToString(result);
 		if (shouldUninitialize)
 			CoUninitialize();
 		return false;
 	}
 	CComPtr<IWICBitmapFrameEncode> frame;
 	CComPtr<IPropertyBag2> propertyBag;
 	result = encoder->CreateNewFrame(&frame, &propertyBag);
 	if (SUCCEEDED(result))
 		result = frame->Initialize(propertyBag);
 	if (SUCCEEDED(result))
 		result = frame->SetSize(width, height);
 	WICPixelFormatGUID pixelFormat = GUID_WICPixelFormat32bppBGRA;
 	if (SUCCEEDED(result))
 		result = frame->SetPixelFormat(&pixelFormat);
 	if (SUCCEEDED(result) && pixelFormat != GUID_WICPixelFormat32bppBGRA)
 	{
 		error = "PNG encoder did not accept BGRA pixel format.";
 		result = E_FAIL;
 	}
 	const UINT stride = width * 4;
 	const UINT imageSize = stride * height;
 	if (SUCCEEDED(result))
 		result = frame->WritePixels(height, stride, imageSize, const_cast<BYTE*>(bgraPixels.data()));
 	if (SUCCEEDED(result))
 		result = frame->Commit();
 	if (SUCCEEDED(result))
 		result = encoder->Commit();
 	if (shouldUninitialize)
 		CoUninitialize();
 	if (FAILED(result))
 	{
 		error = "Could not write screenshot PNG: " + HResultToString(result);
 		std::error_code ignored;
 		std::filesystem::remove(outputPath, ignored);
 		return false;
 	}
 	return true;
 }
 }
 void WritePngFileAsync(
 	const std::filesystem::path& outputPath,
 	unsigned width,
 	unsigned height,
 	std::vector<unsigned char> rgbaPixels)
 {
 	std::thread(
 		[outputPath, width, height, pixels = std::move(rgbaPixels)]() mutable
 		{
 			for (std::size_t index = 0; index + 3 < pixels.size(); index += 4)
 				std::swap(pixels[index], pixels[index + 2]);
 			std::string error;
 			if (!WritePngFile(outputPath, width, height, pixels, error))
 				OutputDebugStringA(("Screenshot write failed: " + error + "\n").c_str());
 			else
 				OutputDebugStringA(("Screenshot written: " + outputPath.string() + "\n").c_str());
 		}).detach();
 }
--- a/apps/LoopThroughWithOpenGLCompositing/gl/PngScreenshotWriter.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/PngScreenshotWriter.h
@@ -1,12 +0,0 @@
 #pragma once
 #include <filesystem>
 #include <string>
 #include <vector>
 void WritePngFileAsync(
 	const std::filesystem::path& outputPath,
 	unsigned width,
 	unsigned height,
 	std::vector<unsigned char> rgbaPixels);
--- a/apps/LoopThroughWithOpenGLCompositing/gl/ShaderBuildQueue.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/ShaderBuildQueue.cpp
@@ -1,134 +0,0 @@
 #include "ShaderBuildQueue.h"
 #include "RuntimeHost.h"
 #include <chrono>
 #include <utility>
 namespace
 {
 constexpr auto kShaderBuildDebounce = std::chrono::milliseconds(400);
 }
 ShaderBuildQueue::ShaderBuildQueue(RuntimeHost& runtimeHost) :
 	mRuntimeHost(runtimeHost),
 	mWorkerThread([this]() { WorkerLoop(); })
 {
 }
 ShaderBuildQueue::~ShaderBuildQueue()
 {
 	Stop();
 }
 void ShaderBuildQueue::RequestBuild(unsigned outputWidth, unsigned outputHeight)
 {
 	{
 		std::lock_guard<std::mutex> lock(mMutex);
 		mHasRequest = true;
 		++mRequestedGeneration;
 		mRequestedOutputWidth = outputWidth;
 		mRequestedOutputHeight = outputHeight;
 		mHasReadyBuild = false;
 	}
 	mCondition.notify_one();
 }
 bool ShaderBuildQueue::TryConsumeReadyBuild(PreparedShaderBuild& build)
 {
 	std::lock_guard<std::mutex> lock(mMutex);
 	if (!mHasReadyBuild)
 		return false;
 	build = std::move(mReadyBuild);
 	mReadyBuild = PreparedShaderBuild();
 	mHasReadyBuild = false;
 	return true;
 }
 void ShaderBuildQueue::Stop()
 {
 	{
 		std::lock_guard<std::mutex> lock(mMutex);
 		if (mStopping)
 			return;
 		mStopping = true;
 	}
 	mCondition.notify_one();
 	if (mWorkerThread.joinable())
 		mWorkerThread.join();
 }
 void ShaderBuildQueue::WorkerLoop()
 {
 	for (;;)
 	{
 		uint64_t generation = 0;
 		unsigned outputWidth = 0;
 		unsigned outputHeight = 0;
 		{
 			std::unique_lock<std::mutex> lock(mMutex);
 			mCondition.wait(lock, [this]() { return mStopping || mHasRequest; });
 			if (mStopping)
 				return;
 			generation = mRequestedGeneration;
 			outputWidth = mRequestedOutputWidth;
 			outputHeight = mRequestedOutputHeight;
 			mHasRequest = false;
 		}
 		for (;;)
 		{
 			std::unique_lock<std::mutex> lock(mMutex);
 			if (mCondition.wait_for(lock, kShaderBuildDebounce, [this, generation]() {
 				return mStopping || (mHasRequest && mRequestedGeneration != generation);
 			}))
 			{
 				if (mStopping)
 					return;
 				generation = mRequestedGeneration;
 				outputWidth = mRequestedOutputWidth;
 				outputHeight = mRequestedOutputHeight;
 				mHasRequest = false;
 				continue;
 			}
 			break;
 		}
 		PreparedShaderBuild build = Build(generation, outputWidth, outputHeight);
 		std::lock_guard<std::mutex> lock(mMutex);
 		if (mStopping)
 			return;
 		if (generation != mRequestedGeneration)
 			continue;
 		mReadyBuild = std::move(build);
 		mHasReadyBuild = true;
 	}
 }
 PreparedShaderBuild ShaderBuildQueue::Build(uint64_t generation, unsigned outputWidth, unsigned outputHeight)
 {
 	PreparedShaderBuild build;
 	build.generation = generation;
 	build.layerStates = mRuntimeHost.GetLayerRenderStates(outputWidth, outputHeight);
 	build.layers.reserve(build.layerStates.size());
 	for (const RuntimeRenderState& state : build.layerStates)
 	{
 		PreparedLayerShader layer;
 		layer.state = state;
 		if (!mRuntimeHost.BuildLayerFragmentShaderSource(state.layerId, layer.fragmentShaderSource, build.message))
 		{
 			build.succeeded = false;
 			return build;
 		}
 		build.layers.push_back(std::move(layer));
 	}
 	build.succeeded = true;
 	build.message = "Shader layers prepared successfully.";
 	return build;
 }
--- a/apps/LoopThroughWithOpenGLCompositing/gl/ShaderBuildQueue.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/ShaderBuildQueue.h
@@ -1,57 +0,0 @@
 #pragma once
 #include "ShaderTypes.h"
 #include <condition_variable>
 #include <cstdint>
 #include <mutex>
 #include <string>
 #include <thread>
 #include <vector>
 class RuntimeHost;
 struct PreparedLayerShader
 {
 	RuntimeRenderState state;
 	std::string fragmentShaderSource;
 };
 struct PreparedShaderBuild
 {
 	uint64_t generation = 0;
 	bool succeeded = false;
 	std::string message;
 	std::vector<RuntimeRenderState> layerStates;
 	std::vector<PreparedLayerShader> layers;
 };
 class ShaderBuildQueue
 {
 public:
 	explicit ShaderBuildQueue(RuntimeHost& runtimeHost);
 	~ShaderBuildQueue();
 	ShaderBuildQueue(const ShaderBuildQueue&) = delete;
 	ShaderBuildQueue& operator=(const ShaderBuildQueue&) = delete;
 	void RequestBuild(unsigned outputWidth, unsigned outputHeight);
 	bool TryConsumeReadyBuild(PreparedShaderBuild& build);
 	void Stop();
 private:
 	void WorkerLoop();
 	PreparedShaderBuild Build(uint64_t generation, unsigned outputWidth, unsigned outputHeight);
 	RuntimeHost& mRuntimeHost;
 	std::thread mWorkerThread;
 	std::mutex mMutex;
 	std::condition_variable mCondition;
 	bool mStopping = false;
 	bool mHasRequest = false;
 	uint64_t mRequestedGeneration = 0;
 	unsigned mRequestedOutputWidth = 0;
 	unsigned mRequestedOutputHeight = 0;
 	bool mHasReadyBuild = false;
 	PreparedShaderBuild mReadyBuild;
 };
--- a/apps/LoopThroughWithOpenGLCompositing/gl/ShaderProgramCompiler.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/ShaderProgramCompiler.cpp
@@ -1,244 +0,0 @@
 #include "ShaderProgramCompiler.h"
 #include "GlRenderConstants.h"
 #include "GlScopedObjects.h"
 #include "GlShaderSources.h"
 #include <cstring>
 #include <vector>
 namespace
 {
 void CopyErrorMessage(const std::string& message, int errorMessageSize, char* errorMessage)
 {
 	if (!errorMessage || errorMessageSize <= 0)
 		return;
 	strncpy_s(errorMessage, errorMessageSize, message.c_str(), _TRUNCATE);
 }
 }
 ShaderProgramCompiler::ShaderProgramCompiler(OpenGLRenderer& renderer, RuntimeHost& runtimeHost, ShaderTextureBindings& textureBindings) :
 	mRenderer(renderer),
 	mRuntimeHost(runtimeHost),
 	mTextureBindings(textureBindings)
 {
 }
 bool ShaderProgramCompiler::CompileLayerProgram(const RuntimeRenderState& state, LayerProgram& layerProgram, int errorMessageSize, char* errorMessage)
 {
 	std::string fragmentShaderSource;
 	std::string loadError;
 	if (!mRuntimeHost.BuildLayerFragmentShaderSource(state.layerId, fragmentShaderSource, loadError))
 	{
 		CopyErrorMessage(loadError, errorMessageSize, errorMessage);
 		return false;
 	}
 	return CompilePreparedLayerProgram(state, fragmentShaderSource, layerProgram, errorMessageSize, errorMessage);
 }
 bool ShaderProgramCompiler::CompilePreparedLayerProgram(const RuntimeRenderState& state, const std::string& fragmentShaderSource, LayerProgram& layerProgram, int errorMessageSize, char* errorMessage)
 {
 	GLsizei errorBufferSize = 0;
 	GLint compileResult = GL_FALSE;
 	GLint linkResult = GL_FALSE;
 	std::string loadError;
 	std::vector<LayerProgram::TextureBinding> textureBindings;
 	const char* vertexSource = kFullscreenTriangleVertexShaderSource;
 	const char* fragmentSource = fragmentShaderSource.c_str();
 	ScopedGlShader newVertexShader(glCreateShader(GL_VERTEX_SHADER));
 	glShaderSource(newVertexShader.get(), 1, (const GLchar**)&vertexSource, NULL);
 	glCompileShader(newVertexShader.get());
 	glGetShaderiv(newVertexShader.get(), GL_COMPILE_STATUS, &compileResult);
 	if (compileResult == GL_FALSE)
 	{
 		glGetShaderInfoLog(newVertexShader.get(), errorMessageSize, &errorBufferSize, errorMessage);
 		return false;
 	}
 	ScopedGlShader newFragmentShader(glCreateShader(GL_FRAGMENT_SHADER));
 	glShaderSource(newFragmentShader.get(), 1, (const GLchar**)&fragmentSource, NULL);
 	glCompileShader(newFragmentShader.get());
 	glGetShaderiv(newFragmentShader.get(), GL_COMPILE_STATUS, &compileResult);
 	if (compileResult == GL_FALSE)
 	{
 		glGetShaderInfoLog(newFragmentShader.get(), errorMessageSize, &errorBufferSize, errorMessage);
 		return false;
 	}
 	ScopedGlProgram newProgram(glCreateProgram());
 	glAttachShader(newProgram.get(), newVertexShader.get());
 	glAttachShader(newProgram.get(), newFragmentShader.get());
 	glLinkProgram(newProgram.get());
 	glGetProgramiv(newProgram.get(), GL_LINK_STATUS, &linkResult);
 	if (linkResult == GL_FALSE)
 	{
 		glGetProgramInfoLog(newProgram.get(), errorMessageSize, &errorBufferSize, errorMessage);
 		return false;
 	}
 	for (const ShaderTextureAsset& textureAsset : state.textureAssets)
 	{
 		LayerProgram::TextureBinding textureBinding;
 		textureBinding.samplerName = textureAsset.id;
 		textureBinding.sourcePath = textureAsset.path;
 		if (!mTextureBindings.LoadTextureAsset(textureAsset, textureBinding.texture, loadError))
 		{
 			for (LayerProgram::TextureBinding& loadedTexture : textureBindings)
 			{
 				if (loadedTexture.texture != 0)
 					glDeleteTextures(1, &loadedTexture.texture);
 			}
 			CopyErrorMessage(loadError, errorMessageSize, errorMessage);
 			return false;
 		}
 		textureBindings.push_back(textureBinding);
 	}
 	std::vector<LayerProgram::TextBinding> textBindings;
 	mTextureBindings.CreateTextBindings(state, textBindings);
 	const GLuint globalParamsIndex = glGetUniformBlockIndex(newProgram.get(), "GlobalParams");
 	if (globalParamsIndex != GL_INVALID_INDEX)
 		glUniformBlockBinding(newProgram.get(), globalParamsIndex, kGlobalParamsBindingPoint);
 	const unsigned historyCap = mRuntimeHost.GetMaxTemporalHistoryFrames();
 	const GLuint shaderTextureBase = state.isTemporal ? kSourceHistoryTextureUnitBase + historyCap + historyCap : kSourceHistoryTextureUnitBase;
 	glUseProgram(newProgram.get());
 	const GLint videoInputLocation = glGetUniformLocation(newProgram.get(), "gVideoInput");
 	if (videoInputLocation >= 0)
 		glUniform1i(videoInputLocation, static_cast<GLint>(kDecodedVideoTextureUnit));
 	for (unsigned index = 0; index < historyCap; ++index)
 	{
 		const std::string sourceSamplerName = "gSourceHistory" + std::to_string(index);
 		const GLint sourceSamplerLocation = glGetUniformLocation(newProgram.get(), sourceSamplerName.c_str());
 		if (sourceSamplerLocation >= 0)
 			glUniform1i(sourceSamplerLocation, static_cast<GLint>(kSourceHistoryTextureUnitBase + index));
 		const std::string temporalSamplerName = "gTemporalHistory" + std::to_string(index);
 		const GLint temporalSamplerLocation = glGetUniformLocation(newProgram.get(), temporalSamplerName.c_str());
 		if (temporalSamplerLocation >= 0)
 			glUniform1i(temporalSamplerLocation, static_cast<GLint>(kSourceHistoryTextureUnitBase + historyCap + index));
 	}
 	for (std::size_t index = 0; index < textureBindings.size(); ++index)
 	{
 		const GLint textureSamplerLocation = mTextureBindings.FindSamplerUniformLocation(newProgram.get(), textureBindings[index].samplerName);
 		if (textureSamplerLocation >= 0)
 			glUniform1i(textureSamplerLocation, static_cast<GLint>(shaderTextureBase + static_cast<GLuint>(index)));
 	}
 	const GLuint textTextureBase = shaderTextureBase + static_cast<GLuint>(textureBindings.size());
 	for (std::size_t index = 0; index < textBindings.size(); ++index)
 	{
 		const GLint textSamplerLocation = mTextureBindings.FindSamplerUniformLocation(newProgram.get(), textBindings[index].samplerName);
 		if (textSamplerLocation >= 0)
 			glUniform1i(textSamplerLocation, static_cast<GLint>(textTextureBase + static_cast<GLuint>(index)));
 	}
 	glUseProgram(0);
 	layerProgram.layerId = state.layerId;
 	layerProgram.shaderId = state.shaderId;
 	layerProgram.shaderTextureBase = shaderTextureBase;
 	layerProgram.program = newProgram.release();
 	layerProgram.vertexShader = newVertexShader.release();
 	layerProgram.fragmentShader = newFragmentShader.release();
 	layerProgram.textureBindings.swap(textureBindings);
 	layerProgram.textBindings.swap(textBindings);
 	return true;
 }
 bool ShaderProgramCompiler::CompileDecodeShader(int errorMessageSize, char* errorMessage)
 {
 	GLsizei errorBufferSize = 0;
 	GLint compileResult = GL_FALSE;
 	GLint linkResult = GL_FALSE;
 	const char* vertexSource = kFullscreenTriangleVertexShaderSource;
 	const char* fragmentSource = kDecodeFragmentShaderSource;
 	ScopedGlShader newVertexShader(glCreateShader(GL_VERTEX_SHADER));
 	glShaderSource(newVertexShader.get(), 1, (const GLchar**)&vertexSource, NULL);
 	glCompileShader(newVertexShader.get());
 	glGetShaderiv(newVertexShader.get(), GL_COMPILE_STATUS, &compileResult);
 	if (compileResult == GL_FALSE)
 	{
 		glGetShaderInfoLog(newVertexShader.get(), errorMessageSize, &errorBufferSize, errorMessage);
 		return false;
 	}
 	ScopedGlShader newFragmentShader(glCreateShader(GL_FRAGMENT_SHADER));
 	glShaderSource(newFragmentShader.get(), 1, (const GLchar**)&fragmentSource, NULL);
 	glCompileShader(newFragmentShader.get());
 	glGetShaderiv(newFragmentShader.get(), GL_COMPILE_STATUS, &compileResult);
 	if (compileResult == GL_FALSE)
 	{
 		glGetShaderInfoLog(newFragmentShader.get(), errorMessageSize, &errorBufferSize, errorMessage);
 		return false;
 	}
 	ScopedGlProgram newProgram(glCreateProgram());
 	glAttachShader(newProgram.get(), newVertexShader.get());
 	glAttachShader(newProgram.get(), newFragmentShader.get());
 	glLinkProgram(newProgram.get());
 	glGetProgramiv(newProgram.get(), GL_LINK_STATUS, &linkResult);
 	if (linkResult == GL_FALSE)
 	{
 		glGetProgramInfoLog(newProgram.get(), errorMessageSize, &errorBufferSize, errorMessage);
 		return false;
 	}
 	mRenderer.DestroyDecodeShaderProgram();
 	mRenderer.SetDecodeShaderProgram(newProgram.release(), newVertexShader.release(), newFragmentShader.release());
 	return true;
 }
 bool ShaderProgramCompiler::CompileOutputPackShader(int errorMessageSize, char* errorMessage)
 {
 	GLsizei errorBufferSize = 0;
 	GLint compileResult = GL_FALSE;
 	GLint linkResult = GL_FALSE;
 	const char* vertexSource = kFullscreenTriangleVertexShaderSource;
 	const char* fragmentSource = kOutputPackFragmentShaderSource;
 	ScopedGlShader newVertexShader(glCreateShader(GL_VERTEX_SHADER));
 	glShaderSource(newVertexShader.get(), 1, (const GLchar**)&vertexSource, NULL);
 	glCompileShader(newVertexShader.get());
 	glGetShaderiv(newVertexShader.get(), GL_COMPILE_STATUS, &compileResult);
 	if (compileResult == GL_FALSE)
 	{
 		glGetShaderInfoLog(newVertexShader.get(), errorMessageSize, &errorBufferSize, errorMessage);
 		return false;
 	}
 	ScopedGlShader newFragmentShader(glCreateShader(GL_FRAGMENT_SHADER));
 	glShaderSource(newFragmentShader.get(), 1, (const GLchar**)&fragmentSource, NULL);
 	glCompileShader(newFragmentShader.get());
 	glGetShaderiv(newFragmentShader.get(), GL_COMPILE_STATUS, &compileResult);
 	if (compileResult == GL_FALSE)
 	{
 		glGetShaderInfoLog(newFragmentShader.get(), errorMessageSize, &errorBufferSize, errorMessage);
 		return false;
 	}
 	ScopedGlProgram newProgram(glCreateProgram());
 	glAttachShader(newProgram.get(), newVertexShader.get());
 	glAttachShader(newProgram.get(), newFragmentShader.get());
 	glLinkProgram(newProgram.get());
 	glGetProgramiv(newProgram.get(), GL_LINK_STATUS, &linkResult);
 	if (linkResult == GL_FALSE)
 	{
 		glGetProgramInfoLog(newProgram.get(), errorMessageSize, &errorBufferSize, errorMessage);
 		return false;
 	}
 	glUseProgram(newProgram.get());
 	const GLint outputSamplerLocation = glGetUniformLocation(newProgram.get(), "uOutputRgb");
 	if (outputSamplerLocation >= 0)
 		glUniform1i(outputSamplerLocation, 0);
 	glUseProgram(0);
 	mRenderer.DestroyOutputPackShaderProgram();
 	mRenderer.SetOutputPackShaderProgram(newProgram.release(), newVertexShader.release(), newFragmentShader.release());
 	return true;
 }
--- a/apps/LoopThroughWithOpenGLCompositing/gl/ShaderProgramCompiler.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/ShaderProgramCompiler.h
@@ -1,25 +0,0 @@
 #pragma once
 #include "OpenGLRenderer.h"
 #include "RuntimeHost.h"
 #include "ShaderTextureBindings.h"
 #include <string>
 class ShaderProgramCompiler
 {
 public:
 	using LayerProgram = OpenGLRenderer::LayerProgram;
 	ShaderProgramCompiler(OpenGLRenderer& renderer, RuntimeHost& runtimeHost, ShaderTextureBindings& textureBindings);
 	bool CompileLayerProgram(const RuntimeRenderState& state, LayerProgram& layerProgram, int errorMessageSize, char* errorMessage);
 	bool CompilePreparedLayerProgram(const RuntimeRenderState& state, const std::string& fragmentShaderSource, LayerProgram& layerProgram, int errorMessageSize, char* errorMessage);
 	bool CompileDecodeShader(int errorMessageSize, char* errorMessage);
 	bool CompileOutputPackShader(int errorMessageSize, char* errorMessage);
 private:
 	OpenGLRenderer& mRenderer;
 	RuntimeHost& mRuntimeHost;
 	ShaderTextureBindings& mTextureBindings;
 };
--- a/apps/LoopThroughWithOpenGLCompositing/gl/ShaderTextureBindings.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/ShaderTextureBindings.cpp
@@ -1,104 +0,0 @@
 #include "ShaderTextureBindings.h"
 #include "GlRenderConstants.h"
 #include "TextRasterizer.h"
 #include "TextureAssetLoader.h"
 #include <algorithm>
 #include <filesystem>
 namespace
 {
 std::string TextValueForBinding(const RuntimeRenderState& state, const std::string& parameterId)
 {
 	auto valueIt = state.parameterValues.find(parameterId);
 	return valueIt == state.parameterValues.end() ? std::string() : valueIt->second.textValue;
 }
 const ShaderFontAsset* FindFontAssetForParameter(const RuntimeRenderState& state, const ShaderParameterDefinition& definition)
 {
 	if (!definition.fontId.empty())
 	{
 		for (const ShaderFontAsset& fontAsset : state.fontAssets)
 		{
 			if (fontAsset.id == definition.fontId)
 				return &fontAsset;
 		}
 	}
 	return state.fontAssets.empty() ? nullptr : &state.fontAssets.front();
 }
 }
 bool ShaderTextureBindings::LoadTextureAsset(const ShaderTextureAsset& textureAsset, GLuint& textureId, std::string& error)
 {
 	return ::LoadTextureAsset(textureAsset, textureId, error);
 }
 void ShaderTextureBindings::CreateTextBindings(const RuntimeRenderState& state, std::vector<LayerProgram::TextBinding>& textBindings)
 {
 	for (const ShaderParameterDefinition& definition : state.parameterDefinitions)
 	{
 		if (definition.type != ShaderParameterType::Text)
 			continue;
 		LayerProgram::TextBinding textBinding;
 		textBinding.parameterId = definition.id;
 		textBinding.samplerName = definition.id + "Texture";
 		textBinding.fontId = definition.fontId;
 		glGenTextures(1, &textBinding.texture);
 		glBindTexture(GL_TEXTURE_2D, textBinding.texture);
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
 		std::vector<unsigned char> empty(static_cast<std::size_t>(kTextTextureWidth) * kTextTextureHeight * 4, 0);
 		glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA8, kTextTextureWidth, kTextTextureHeight, 0, GL_BGRA, GL_UNSIGNED_INT_8_8_8_8_REV, empty.data());
 		glBindTexture(GL_TEXTURE_2D, 0);
 		textBindings.push_back(textBinding);
 	}
 }
 bool ShaderTextureBindings::UpdateTextBindingTexture(const RuntimeRenderState& state, LayerProgram::TextBinding& textBinding, std::string& error)
 {
 	const std::string text = TextValueForBinding(state, textBinding.parameterId);
 	if (text == textBinding.renderedText && textBinding.renderedWidth == kTextTextureWidth && textBinding.renderedHeight == kTextTextureHeight)
 		return true;
 	auto definitionIt = std::find_if(state.parameterDefinitions.begin(), state.parameterDefinitions.end(),
 		[&textBinding](const ShaderParameterDefinition& definition) { return definition.id == textBinding.parameterId; });
 	if (definitionIt == state.parameterDefinitions.end())
 		return true;
 	const ShaderFontAsset* fontAsset = FindFontAssetForParameter(state, *definitionIt);
 	std::filesystem::path fontPath;
 	if (fontAsset)
 		fontPath = fontAsset->path;
 	std::vector<unsigned char> sdf;
 	if (!RasterizeTextSdf(text, fontPath, sdf, error))
 		return false;
 	GLint previousActiveTexture = 0;
 	GLint previousUnpackBuffer = 0;
 	glGetIntegerv(GL_ACTIVE_TEXTURE, &previousActiveTexture);
 	glGetIntegerv(GL_PIXEL_UNPACK_BUFFER_BINDING, &previousUnpackBuffer);
 	glActiveTexture(GL_TEXTURE0);
 	glBindBuffer(GL_PIXEL_UNPACK_BUFFER, 0);
 	glBindTexture(GL_TEXTURE_2D, textBinding.texture);
 	glTexSubImage2D(GL_TEXTURE_2D, 0, 0, 0, kTextTextureWidth, kTextTextureHeight, GL_BGRA, GL_UNSIGNED_INT_8_8_8_8_REV, sdf.data());
 	glBindTexture(GL_TEXTURE_2D, 0);
 	glBindBuffer(GL_PIXEL_UNPACK_BUFFER, static_cast<GLuint>(previousUnpackBuffer));
 	glActiveTexture(static_cast<GLenum>(previousActiveTexture));
 	textBinding.renderedText = text;
 	textBinding.renderedWidth = kTextTextureWidth;
 	textBinding.renderedHeight = kTextTextureHeight;
 	return true;
 }
 GLint ShaderTextureBindings::FindSamplerUniformLocation(GLuint program, const std::string& samplerName) const
 {
 	GLint location = glGetUniformLocation(program, samplerName.c_str());
 	if (location >= 0)
 		return location;
 	return glGetUniformLocation(program, (samplerName + "_0").c_str());
 }
--- a/apps/LoopThroughWithOpenGLCompositing/gl/ShaderTextureBindings.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/ShaderTextureBindings.h
@@ -1,18 +0,0 @@
 #pragma once
 #include "OpenGLRenderer.h"
 #include "ShaderTypes.h"
 #include <string>
 #include <vector>
 class ShaderTextureBindings
 {
 public:
 	using LayerProgram = OpenGLRenderer::LayerProgram;
 	bool LoadTextureAsset(const ShaderTextureAsset& textureAsset, GLuint& textureId, std::string& error);
 	void CreateTextBindings(const RuntimeRenderState& state, std::vector<LayerProgram::TextBinding>& textBindings);
 	bool UpdateTextBindingTexture(const RuntimeRenderState& state, LayerProgram::TextBinding& textBinding, std::string& error);
 	GLint FindSamplerUniformLocation(GLuint program, const std::string& samplerName) const;
 };
--- a/apps/LoopThroughWithOpenGLCompositing/gl/TemporalHistoryBuffers.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/TemporalHistoryBuffers.cpp
@@ -1,237 +0,0 @@
 #include "TemporalHistoryBuffers.h"
 #include "GlRenderConstants.h"
 #include "ShaderTypes.h"
 #include <algorithm>
 #include <sstream>
 #include <set>
 bool TemporalHistoryBuffers::ValidateTextureUnitBudget(const std::vector<RuntimeRenderState>& layerStates, unsigned historyCap, std::string& error) const
 {
 	unsigned requiredUnits = kSourceHistoryTextureUnitBase;
 	for (const RuntimeRenderState& state : layerStates)
 	{
 		unsigned textTextureCount = 0;
 		for (const ShaderParameterDefinition& definition : state.parameterDefinitions)
 		{
 			if (definition.type == ShaderParameterType::Text)
 				++textTextureCount;
 		}
 		const unsigned totalShaderTextures = static_cast<unsigned>(state.textureAssets.size()) + textTextureCount;
 		const unsigned layerRequiredUnits = kSourceHistoryTextureUnitBase + (state.isTemporal ? historyCap + historyCap : 0u) + totalShaderTextures;
 		if (layerRequiredUnits > requiredUnits)
 			requiredUnits = layerRequiredUnits;
 	}
 	GLint maxTextureUnits = 0;
 	glGetIntegerv(GL_MAX_TEXTURE_IMAGE_UNITS, &maxTextureUnits);
 	const unsigned availableUnits = maxTextureUnits > 0 ? static_cast<unsigned>(maxTextureUnits) : 0u;
 	if (requiredUnits > availableUnits)
 	{
 		std::ostringstream message;
 		message << "The current history and shader texture asset configuration requires " << requiredUnits
 			<< " fragment texture units, but only " << maxTextureUnits << " are available.";
 		error = message.str();
 		return false;
 	}
 	return true;
 }
 bool TemporalHistoryBuffers::EnsureResources(const std::vector<RuntimeRenderState>& layerStates, unsigned historyCap, unsigned frameWidth, unsigned frameHeight, std::string& error)
 {
 	const bool sourceHistoryNeeded = std::any_of(layerStates.begin(), layerStates.end(),
 		[](const RuntimeRenderState& state) { return state.isTemporal && state.effectiveTemporalHistoryLength > 0; });
 	const unsigned sourceHistoryLength = sourceHistoryNeeded ? historyCap : 0;
 	if (sourceHistoryRing.effectiveLength != sourceHistoryLength)
 	{
 		if (!CreateRing(sourceHistoryRing, sourceHistoryLength, TemporalHistorySource::Source, frameWidth, frameHeight, error))
 			return false;
 		mNeedsReset = true;
 	}
 	std::set<std::string> requiredPreLayerIds;
 	for (const RuntimeRenderState& state : layerStates)
 	{
 		if (!state.isTemporal || state.temporalHistorySource != TemporalHistorySource::PreLayerInput)
 			continue;
 		requiredPreLayerIds.insert(state.layerId);
 		auto historyIt = preLayerHistoryByLayerId.find(state.layerId);
 		if (historyIt == preLayerHistoryByLayerId.end() || historyIt->second.effectiveLength != state.effectiveTemporalHistoryLength)
 		{
 			Ring replacement;
 			if (!CreateRing(replacement, state.effectiveTemporalHistoryLength, TemporalHistorySource::PreLayerInput, frameWidth, frameHeight, error))
 				return false;
 			preLayerHistoryByLayerId[state.layerId] = std::move(replacement);
 			mNeedsReset = true;
 		}
 	}
 	for (auto it = preLayerHistoryByLayerId.begin(); it != preLayerHistoryByLayerId.end();)
 	{
 		if (requiredPreLayerIds.find(it->first) == requiredPreLayerIds.end())
 		{
 			DestroyRing(it->second);
 			it = preLayerHistoryByLayerId.erase(it);
 			mNeedsReset = true;
 		}
 		else
 		{
 			++it;
 		}
 	}
 	if (mNeedsReset)
 		ResetState();
 	return true;
 }
 bool TemporalHistoryBuffers::CreateRing(Ring& ring, unsigned effectiveLength, TemporalHistorySource historySource, unsigned frameWidth, unsigned frameHeight, std::string& error)
 {
 	DestroyRing(ring);
 	ring.effectiveLength = effectiveLength;
 	ring.historySource = historySource;
 	if (effectiveLength == 0)
 		return true;
 	ring.slots.resize(effectiveLength);
 	for (Slot& slot : ring.slots)
 	{
 		glGenTextures(1, &slot.texture);
 		glBindTexture(GL_TEXTURE_2D, slot.texture);
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
 		glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
 		glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA16F, frameWidth, frameHeight, 0, GL_RGBA, GL_FLOAT, NULL);
 		glGenFramebuffers(1, &slot.framebuffer);
 		glBindFramebuffer(GL_FRAMEBUFFER, slot.framebuffer);
 		glFramebufferTexture2D(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, GL_TEXTURE_2D, slot.texture, 0);
 		const GLenum framebufferStatus = glCheckFramebufferStatus(GL_FRAMEBUFFER);
 		if (framebufferStatus != GL_FRAMEBUFFER_COMPLETE)
 		{
 			error = "Failed to initialize a temporal history framebuffer.";
 			glBindFramebuffer(GL_FRAMEBUFFER, 0);
 			glBindTexture(GL_TEXTURE_2D, 0);
 			DestroyRing(ring);
 			return false;
 		}
 	}
 	glBindFramebuffer(GL_FRAMEBUFFER, 0);
 	glBindTexture(GL_TEXTURE_2D, 0);
 	return true;
 }
 void TemporalHistoryBuffers::DestroyRing(Ring& ring)
 {
 	for (Slot& slot : ring.slots)
 	{
 		if (slot.framebuffer != 0)
 			glDeleteFramebuffers(1, &slot.framebuffer);
 		if (slot.texture != 0)
 			glDeleteTextures(1, &slot.texture);
 		slot.framebuffer = 0;
 		slot.texture = 0;
 	}
 	ring.slots.clear();
 	ring.nextWriteIndex = 0;
 	ring.filledCount = 0;
 	ring.effectiveLength = 0;
 	ring.historySource = TemporalHistorySource::None;
 }
 void TemporalHistoryBuffers::DestroyResources()
 {
 	DestroyRing(sourceHistoryRing);
 	for (auto& historyEntry : preLayerHistoryByLayerId)
 		DestroyRing(historyEntry.second);
 	preLayerHistoryByLayerId.clear();
 	mNeedsReset = true;
 }
 void TemporalHistoryBuffers::ResetState()
 {
 	sourceHistoryRing.nextWriteIndex = 0;
 	sourceHistoryRing.filledCount = 0;
 	for (auto& historyEntry : preLayerHistoryByLayerId)
 	{
 		historyEntry.second.nextWriteIndex = 0;
 		historyEntry.second.filledCount = 0;
 	}
 	mNeedsReset = false;
 }
 void TemporalHistoryBuffers::PushFramebuffer(GLuint sourceFramebuffer, Ring& ring, unsigned frameWidth, unsigned frameHeight)
 {
 	if (ring.effectiveLength == 0 || ring.slots.empty())
 		return;
 	Slot& targetSlot = ring.slots[ring.nextWriteIndex];
 	glBindFramebuffer(GL_READ_FRAMEBUFFER, sourceFramebuffer);
 	glBindFramebuffer(GL_DRAW_FRAMEBUFFER, targetSlot.framebuffer);
 	glBlitFramebuffer(0, 0, frameWidth, frameHeight, 0, 0, frameWidth, frameHeight, GL_COLOR_BUFFER_BIT, GL_LINEAR);
 	ring.nextWriteIndex = (ring.nextWriteIndex + 1) % ring.slots.size();
 	ring.filledCount = std::min<std::size_t>(ring.filledCount + 1, ring.slots.size());
 }
 void TemporalHistoryBuffers::PushSourceFramebuffer(GLuint sourceFramebuffer, unsigned frameWidth, unsigned frameHeight)
 {
 	PushFramebuffer(sourceFramebuffer, sourceHistoryRing, frameWidth, frameHeight);
 }
 void TemporalHistoryBuffers::PushPreLayerFramebuffer(const std::string& layerId, GLuint sourceFramebuffer, unsigned frameWidth, unsigned frameHeight)
 {
 	auto historyIt = preLayerHistoryByLayerId.find(layerId);
 	if (historyIt != preLayerHistoryByLayerId.end())
 		PushFramebuffer(sourceFramebuffer, historyIt->second, frameWidth, frameHeight);
 }
 void TemporalHistoryBuffers::BindSamplers(const RuntimeRenderState& state, GLuint currentSourceTexture, unsigned historyCap)
 {
 	for (unsigned index = 0; index < historyCap; ++index)
 	{
 		glActiveTexture(GL_TEXTURE0 + kSourceHistoryTextureUnitBase + index);
 		glBindTexture(GL_TEXTURE_2D, ResolveTexture(sourceHistoryRing, currentSourceTexture, index));
 	}
 	const GLuint temporalBase = kSourceHistoryTextureUnitBase + historyCap;
 	const Ring* temporalRing = nullptr;
 	auto it = preLayerHistoryByLayerId.find(state.layerId);
 	if (it != preLayerHistoryByLayerId.end())
 		temporalRing = &it->second;
 	for (unsigned index = 0; index < historyCap; ++index)
 	{
 		glActiveTexture(GL_TEXTURE0 + temporalBase + index);
 		glBindTexture(GL_TEXTURE_2D, temporalRing ? ResolveTexture(*temporalRing, currentSourceTexture, index) : currentSourceTexture);
 	}
 	glActiveTexture(GL_TEXTURE0);
 }
 GLuint TemporalHistoryBuffers::ResolveTexture(const Ring& ring, GLuint fallbackTexture, std::size_t framesAgo) const
 {
 	if (ring.filledCount == 0 || ring.slots.empty())
 		return fallbackTexture;
 	const std::size_t clampedOffset = std::min<std::size_t>(framesAgo, ring.filledCount - 1);
 	const std::size_t newestIndex = (ring.nextWriteIndex + ring.slots.size() - 1) % ring.slots.size();
 	const std::size_t slotIndex = (newestIndex + ring.slots.size() - clampedOffset) % ring.slots.size();
 	return ring.slots[slotIndex].texture != 0 ? ring.slots[slotIndex].texture : fallbackTexture;
 }
 unsigned TemporalHistoryBuffers::SourceAvailableCount() const
 {
 	return static_cast<unsigned>(sourceHistoryRing.filledCount);
 }
 unsigned TemporalHistoryBuffers::AvailableCountForLayer(const std::string& layerId) const
 {
 	auto it = preLayerHistoryByLayerId.find(layerId);
 	if (it == preLayerHistoryByLayerId.end())
 		return 0;
 	return static_cast<unsigned>(it->second.filledCount);
 }
--- a/apps/LoopThroughWithOpenGLCompositing/gl/TemporalHistoryBuffers.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/TemporalHistoryBuffers.h
@@ -1,51 +0,0 @@
 #pragma once
 #include "GLExtensions.h"
 #include "ShaderTypes.h"
 #include <windows.h>
 #include <gl/gl.h>
 #include <map>
 #include <string>
 #include <vector>
 struct RuntimeRenderState;
 class TemporalHistoryBuffers
 {
 public:
 	struct Slot
 	{
 		GLuint texture = 0;
 		GLuint framebuffer = 0;
 	};
 	struct Ring
 	{
 		std::vector<Slot> slots;
 		std::size_t nextWriteIndex = 0;
 		std::size_t filledCount = 0;
 		unsigned effectiveLength = 0;
 		TemporalHistorySource historySource = TemporalHistorySource::None;
 	};
 	bool ValidateTextureUnitBudget(const std::vector<RuntimeRenderState>& layerStates, unsigned historyCap, std::string& error) const;
 	bool EnsureResources(const std::vector<RuntimeRenderState>& layerStates, unsigned historyCap, unsigned frameWidth, unsigned frameHeight, std::string& error);
 	bool CreateRing(Ring& ring, unsigned effectiveLength, TemporalHistorySource historySource, unsigned frameWidth, unsigned frameHeight, std::string& error);
 	void DestroyRing(Ring& ring);
 	void DestroyResources();
 	void ResetState();
 	void PushFramebuffer(GLuint sourceFramebuffer, Ring& ring, unsigned frameWidth, unsigned frameHeight);
 	void PushSourceFramebuffer(GLuint sourceFramebuffer, unsigned frameWidth, unsigned frameHeight);
 	void PushPreLayerFramebuffer(const std::string& layerId, GLuint sourceFramebuffer, unsigned frameWidth, unsigned frameHeight);
 	void BindSamplers(const RuntimeRenderState& state, GLuint currentSourceTexture, unsigned historyCap);
 	GLuint ResolveTexture(const Ring& ring, GLuint fallbackTexture, std::size_t framesAgo) const;
 	unsigned SourceAvailableCount() const;
 	unsigned AvailableCountForLayer(const std::string& layerId) const;
 private:
 	Ring sourceHistoryRing;
 	std::map<std::string, Ring> preLayerHistoryByLayerId;
 	bool mNeedsReset = true;
 };
--- a/apps/LoopThroughWithOpenGLCompositing/gl/TextRasterizer.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/TextRasterizer.cpp
@@ -1,243 +0,0 @@
 #include "TextRasterizer.h"
 #include <windows.h>
 #include <algorithm>
 #include <cmath>
 #include <cstring>
 #include <gdiplus.h>
 #include <memory>
 namespace
 {
 constexpr int kTextSdfSpread = 20;
 constexpr float kTextFontPixelSize = 144.0f;
 constexpr float kTextLayoutPadding = 48.0f;
 constexpr float kSdfInfinity = 1.0e20f;
 class GdiplusSession
 {
 public:
 	GdiplusSession()
 	{
 		Gdiplus::GdiplusStartupInput startupInput;
 		mStarted = Gdiplus::GdiplusStartup(&mToken, &startupInput, NULL) == Gdiplus::Ok;
 	}
 	~GdiplusSession()
 	{
 		if (mStarted)
 			Gdiplus::GdiplusShutdown(mToken);
 	}
 	GdiplusSession(const GdiplusSession&) = delete;
 	GdiplusSession& operator=(const GdiplusSession&) = delete;
 	bool started() const { return mStarted; }
 private:
 	ULONG_PTR mToken = 0;
 	bool mStarted = false;
 };
 std::wstring Utf8ToWide(const std::string& text)
 {
 	if (text.empty())
 		return std::wstring();
 	const int required = MultiByteToWideChar(CP_UTF8, 0, text.c_str(), -1, NULL, 0);
 	if (required <= 1)
 		return std::wstring();
 	std::wstring wide(static_cast<std::size_t>(required - 1), L'\0');
 	MultiByteToWideChar(CP_UTF8, 0, text.c_str(), -1, wide.data(), required);
 	return wide;
 }
 void DistanceTransform1D(const std::vector<float>& input, std::vector<float>& output, unsigned count)
 {
 	std::vector<unsigned> locations(count, 0);
 	std::vector<float> boundaries(static_cast<std::size_t>(count) + 1, 0.0f);
 	unsigned segment = 0;
 	locations[0] = 0;
 	boundaries[0] = -kSdfInfinity;
 	boundaries[1] = kSdfInfinity;
 	for (unsigned q = 1; q < count; ++q)
 	{
 		float intersection = 0.0f;
 		for (;;)
 		{
 			const unsigned location = locations[segment];
 			intersection =
 				((input[q] + static_cast<float>(q * q)) - (input[location] + static_cast<float>(location * location))) /
 				(2.0f * static_cast<float>(q) - 2.0f * static_cast<float>(location));
 			if (intersection > boundaries[segment] || segment == 0)
 				break;
 			--segment;
 		}
 		++segment;
 		locations[segment] = q;
 		boundaries[segment] = intersection;
 		boundaries[segment + 1] = kSdfInfinity;
 	}
 	segment = 0;
 	for (unsigned q = 0; q < count; ++q)
 	{
 		while (boundaries[segment + 1] < static_cast<float>(q))
 			++segment;
 		const unsigned location = locations[segment];
 		const float delta = static_cast<float>(q) - static_cast<float>(location);
 		output[q] = delta * delta + input[location];
 	}
 }
 std::vector<float> DistanceTransform2D(const std::vector<unsigned char>& targetMask, unsigned width, unsigned height)
 {
 	std::vector<float> rowInput(width, 0.0f);
 	std::vector<float> rowOutput(width, 0.0f);
 	std::vector<float> columnInput(height, 0.0f);
 	std::vector<float> columnOutput(height, 0.0f);
 	std::vector<float> rowDistance(static_cast<std::size_t>(width) * height, 0.0f);
 	std::vector<float> distance(static_cast<std::size_t>(width) * height, 0.0f);
 	for (unsigned y = 0; y < height; ++y)
 	{
 		for (unsigned x = 0; x < width; ++x)
 			rowInput[x] = targetMask[static_cast<std::size_t>(y) * width + x] ? 0.0f : kSdfInfinity;
 		DistanceTransform1D(rowInput, rowOutput, width);
 		for (unsigned x = 0; x < width; ++x)
 			rowDistance[static_cast<std::size_t>(y) * width + x] = rowOutput[x];
 	}
 	for (unsigned x = 0; x < width; ++x)
 	{
 		for (unsigned y = 0; y < height; ++y)
 			columnInput[y] = rowDistance[static_cast<std::size_t>(y) * width + x];
 		DistanceTransform1D(columnInput, columnOutput, height);
 		for (unsigned y = 0; y < height; ++y)
 			distance[static_cast<std::size_t>(y) * width + x] = columnOutput[y];
 	}
 	return distance;
 }
 std::vector<unsigned char> BuildTextSdfTexture(const std::vector<unsigned char>& alpha, unsigned width, unsigned height)
 {
 	std::vector<unsigned char> insideMask(static_cast<std::size_t>(width) * height, 0);
 	std::vector<unsigned char> outsideMask(static_cast<std::size_t>(width) * height, 0);
 	for (std::size_t index = 0; index < alpha.size(); ++index)
 	{
 		const bool inside = alpha[index] > 127;
 		insideMask[index] = inside ? 1 : 0;
 		outsideMask[index] = inside ? 0 : 1;
 	}
 	const std::vector<float> distanceToInside = DistanceTransform2D(insideMask, width, height);
 	const std::vector<float> distanceToOutside = DistanceTransform2D(outsideMask, width, height);
 	std::vector<unsigned char> sdf(static_cast<std::size_t>(width) * height * 4, 0);
 	for (unsigned y = 0; y < height; ++y)
 	{
 		const unsigned flippedY = height - 1 - y;
 		for (unsigned x = 0; x < width; ++x)
 		{
 			const std::size_t source = static_cast<std::size_t>(y) * width + x;
 			const float signedDistance = std::sqrt(distanceToOutside[source]) - std::sqrt(distanceToInside[source]);
 			const float normalized = std::clamp(
 				0.5f + signedDistance / static_cast<float>(kTextSdfSpread * 2),
 				0.0f,
 				1.0f);
 			const unsigned char value = static_cast<unsigned char>(normalized * 255.0f + 0.5f);
 			const std::size_t out = (static_cast<std::size_t>(flippedY) * width + x) * 4;
 			sdf[out + 0] = value;
 			sdf[out + 1] = value;
 			sdf[out + 2] = value;
 			sdf[out + 3] = value;
 		}
 	}
 	return sdf;
 }
 }
 bool RasterizeTextSdf(const std::string& text, const std::filesystem::path& fontPath, std::vector<unsigned char>& sdf, std::string& error)
 {
 	GdiplusSession gdiplus;
 	if (!gdiplus.started())
 	{
 		error = "Could not start GDI+ for text rendering.";
 		return false;
 	}
 	Gdiplus::PrivateFontCollection fontCollection;
 	Gdiplus::FontFamily fallbackFamily(L"Arial");
 	Gdiplus::FontFamily* fontFamily = &fallbackFamily;
 	std::unique_ptr<Gdiplus::FontFamily[]> families;
 	const std::wstring wideFontPath = fontPath.empty() ? std::wstring() : fontPath.wstring();
 	if (!wideFontPath.empty())
 	{
 		if (fontCollection.AddFontFile(wideFontPath.c_str()) != Gdiplus::Ok)
 		{
 			error = "Could not load packaged font file for text rendering: " + fontPath.string();
 			return false;
 		}
 		const INT familyCount = fontCollection.GetFamilyCount();
 		if (familyCount <= 0)
 		{
 			error = "Packaged font did not contain a usable font family: " + fontPath.string();
 			return false;
 		}
 		families.reset(new Gdiplus::FontFamily[familyCount]);
 		INT found = 0;
 		if (fontCollection.GetFamilies(familyCount, families.get(), &found) != Gdiplus::Ok || found <= 0)
 		{
 			error = "Could not read the packaged font family: " + fontPath.string();
 			return false;
 		}
 		fontFamily = &families[0];
 	}
 	Gdiplus::Bitmap bitmap(kTextTextureWidth, kTextTextureHeight, PixelFormat32bppARGB);
 	Gdiplus::Graphics graphics(&bitmap);
 	graphics.SetCompositingMode(Gdiplus::CompositingModeSourceCopy);
 	graphics.Clear(Gdiplus::Color(255, 0, 0, 0));
 	graphics.SetCompositingMode(Gdiplus::CompositingModeSourceOver);
 	graphics.SetTextRenderingHint(Gdiplus::TextRenderingHintAntiAlias);
 	graphics.SetSmoothingMode(Gdiplus::SmoothingModeHighQuality);
 	Gdiplus::Font font(fontFamily, kTextFontPixelSize, Gdiplus::FontStyleRegular, Gdiplus::UnitPixel);
 	Gdiplus::SolidBrush brush(Gdiplus::Color(255, 255, 255, 255));
 	Gdiplus::StringFormat format;
 	format.SetAlignment(Gdiplus::StringAlignmentNear);
 	format.SetLineAlignment(Gdiplus::StringAlignmentCenter);
 	format.SetFormatFlags(Gdiplus::StringFormatFlagsNoWrap | Gdiplus::StringFormatFlagsMeasureTrailingSpaces);
 	const Gdiplus::RectF layout(
 		kTextLayoutPadding,
 		0.0f,
 		static_cast<Gdiplus::REAL>(kTextTextureWidth) - (kTextLayoutPadding * 2.0f),
 		static_cast<Gdiplus::REAL>(kTextTextureHeight));
 	const std::wstring wideText = Utf8ToWide(text);
 	graphics.DrawString(wideText.c_str(), -1, &font, layout, &format, &brush);
 	std::vector<unsigned char> alpha(static_cast<std::size_t>(kTextTextureWidth) * kTextTextureHeight, 0);
 	for (unsigned y = 0; y < kTextTextureHeight; ++y)
 	{
 		for (unsigned x = 0; x < kTextTextureWidth; ++x)
 		{
 			Gdiplus::Color pixel;
 			bitmap.GetPixel(x, y, &pixel);
 			BYTE luminance = pixel.GetRed();
 			if (pixel.GetGreen() > luminance)
 				luminance = pixel.GetGreen();
 			if (pixel.GetBlue() > luminance)
 				luminance = pixel.GetBlue();
 			alpha[static_cast<std::size_t>(y) * kTextTextureWidth + x] = static_cast<unsigned char>(luminance);
 		}
 	}
 	sdf = BuildTextSdfTexture(alpha, kTextTextureWidth, kTextTextureHeight);
 	return true;
 }
--- a/apps/LoopThroughWithOpenGLCompositing/gl/TextRasterizer.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/TextRasterizer.h
@@ -1,10 +0,0 @@
 #pragma once
 #include <filesystem>
 #include <string>
 #include <vector>
 constexpr unsigned kTextTextureWidth = 4096;
 constexpr unsigned kTextTextureHeight = 512;
 bool RasterizeTextSdf(const std::string& text, const std::filesystem::path& fontPath, std::vector<unsigned char>& sdf, std::string& error);
--- a/apps/LoopThroughWithOpenGLCompositing/gl/TextureAssetLoader.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/TextureAssetLoader.cpp
@@ -1,222 +0,0 @@
 #include "TextureAssetLoader.h"
 #include <windows.h>
 #include <wincodec.h>
 #include <atlbase.h>
 #include <algorithm>
 #include <cctype>
 #include <cstring>
 #include <fstream>
 #include <sstream>
 #include <string>
 #include <vector>
 #ifndef GL_RGBA32F
 #define GL_RGBA32F 0x8814
 #endif
 namespace
 {
 std::string LowercaseExtension(const std::filesystem::path& path)
 {
 	std::string extension = path.extension().string();
 	std::transform(extension.begin(), extension.end(), extension.begin(),
 		[](unsigned char value) { return static_cast<char>(std::tolower(value)); });
 	return extension;
 }
 bool LoadCubeTextureAsset(const ShaderTextureAsset& textureAsset, GLuint& textureId, std::string& error)
 {
 	std::ifstream file(textureAsset.path);
 	if (!file)
 	{
 		error = "Could not open shader LUT asset: " + textureAsset.path.string();
 		return false;
 	}
 	unsigned lutSize = 0;
 	std::vector<float> values;
 	std::string line;
 	while (std::getline(file, line))
 	{
 		const std::size_t commentStart = line.find('#');
 		if (commentStart != std::string::npos)
 			line.resize(commentStart);
 		std::istringstream stream(line);
 		std::string firstToken;
 		if (!(stream >> firstToken))
 			continue;
 		if (firstToken == "TITLE" || firstToken == "DOMAIN_MIN" || firstToken == "DOMAIN_MAX")
 			continue;
 		if (firstToken == "LUT_3D_SIZE")
 		{
 			stream >> lutSize;
 			continue;
 		}
 		if (firstToken == "LUT_1D_SIZE")
 		{
 			error = "Only 3D .cube LUT assets are supported: " + textureAsset.path.string();
 			return false;
 		}
 		float red = 0.0f;
 		float green = 0.0f;
 		float blue = 0.0f;
 		try
 		{
 			red = std::stof(firstToken);
 		}
 		catch (...)
 		{
 			error = "Unsupported .cube directive in shader LUT asset: " + firstToken;
 			return false;
 		}
 		if (!(stream >> green >> blue))
 		{
 			error = "Malformed RGB entry in shader LUT asset: " + textureAsset.path.string();
 			return false;
 		}
 		values.push_back(red);
 		values.push_back(green);
 		values.push_back(blue);
 		values.push_back(1.0f);
 	}
 	if (lutSize == 0)
 	{
 		error = "Shader LUT asset is missing LUT_3D_SIZE: " + textureAsset.path.string();
 		return false;
 	}
 	const std::size_t expectedFloats = static_cast<std::size_t>(lutSize) * lutSize * lutSize * 4;
 	if (values.size() != expectedFloats)
 	{
 		error = "Shader LUT asset entry count does not match LUT_3D_SIZE: " + textureAsset.path.string();
 		return false;
 	}
 	const GLsizei atlasWidth = static_cast<GLsizei>(lutSize * lutSize);
 	const GLsizei atlasHeight = static_cast<GLsizei>(lutSize);
 	glGenTextures(1, &textureId);
 	glBindTexture(GL_TEXTURE_2D, textureId);
 	glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST);
 	glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST);
 	glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
 	glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
 	glPixelStorei(GL_UNPACK_ALIGNMENT, 4);
 	glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA32F, atlasWidth, atlasHeight, 0, GL_RGBA, GL_FLOAT, values.data());
 	glBindTexture(GL_TEXTURE_2D, 0);
 	return true;
 }
 }
 bool LoadTextureAsset(const ShaderTextureAsset& textureAsset, GLuint& textureId, std::string& error)
 {
 	textureId = 0;
 	if (LowercaseExtension(textureAsset.path) == ".cube")
 		return LoadCubeTextureAsset(textureAsset, textureId, error);
 	HRESULT comInitResult = CoInitializeEx(NULL, COINIT_MULTITHREADED);
 	const bool shouldUninitializeCom = (comInitResult == S_OK || comInitResult == S_FALSE);
 	if (FAILED(comInitResult) && comInitResult != RPC_E_CHANGED_MODE)
 	{
 		error = "Could not initialize COM to load shader texture assets.";
 		return false;
 	}
 	CComPtr<IWICImagingFactory> imagingFactory;
 	HRESULT result = CoCreateInstance(CLSID_WICImagingFactory, NULL, CLSCTX_INPROC_SERVER, IID_PPV_ARGS(&imagingFactory));
 	if (FAILED(result) || !imagingFactory)
 	{
 		if (shouldUninitializeCom)
 			CoUninitialize();
 		error = "Could not create a WIC imaging factory to load shader texture assets.";
 		return false;
 	}
 	CComPtr<IWICBitmapDecoder> bitmapDecoder;
 	result = imagingFactory->CreateDecoderFromFilename(textureAsset.path.wstring().c_str(), NULL, GENERIC_READ, WICDecodeMetadataCacheOnLoad, &bitmapDecoder);
 	if (FAILED(result) || !bitmapDecoder)
 	{
 		if (shouldUninitializeCom)
 			CoUninitialize();
 		error = "Could not open shader texture asset: " + textureAsset.path.string();
 		return false;
 	}
 	CComPtr<IWICBitmapFrameDecode> bitmapFrame;
 	result = bitmapDecoder->GetFrame(0, &bitmapFrame);
 	if (FAILED(result) || !bitmapFrame)
 	{
 		if (shouldUninitializeCom)
 			CoUninitialize();
 		error = "Could not decode the first frame of shader texture asset: " + textureAsset.path.string();
 		return false;
 	}
 	CComPtr<IWICFormatConverter> formatConverter;
 	result = imagingFactory->CreateFormatConverter(&formatConverter);
 	if (FAILED(result) || !formatConverter)
 	{
 		if (shouldUninitializeCom)
 			CoUninitialize();
 		error = "Could not create a WIC format converter for shader texture asset: " + textureAsset.path.string();
 		return false;
 	}
 	result = formatConverter->Initialize(bitmapFrame, GUID_WICPixelFormat32bppBGRA, WICBitmapDitherTypeNone, NULL, 0.0, WICBitmapPaletteTypeCustom);
 	if (FAILED(result))
 	{
 		if (shouldUninitializeCom)
 			CoUninitialize();
 		error = "Could not convert shader texture asset to BGRA: " + textureAsset.path.string();
 		return false;
 	}
 	UINT width = 0;
 	UINT height = 0;
 	result = formatConverter->GetSize(&width, &height);
 	if (FAILED(result) || width == 0 || height == 0)
 	{
 		if (shouldUninitializeCom)
 			CoUninitialize();
 		error = "Shader texture asset has an invalid size: " + textureAsset.path.string();
 		return false;
 	}
 	const UINT stride = width * 4;
 	std::vector<unsigned char> pixels(static_cast<std::size_t>(stride) * static_cast<std::size_t>(height));
 	result = formatConverter->CopyPixels(NULL, stride, static_cast<UINT>(pixels.size()), pixels.data());
 	if (FAILED(result))
 	{
 		if (shouldUninitializeCom)
 			CoUninitialize();
 		error = "Could not read shader texture pixels: " + textureAsset.path.string();
 		return false;
 	}
 	std::vector<unsigned char> flippedPixels(pixels.size());
 	for (UINT row = 0; row < height; ++row)
 	{
 		const std::size_t srcOffset = static_cast<std::size_t>(row) * stride;
 		const std::size_t dstOffset = static_cast<std::size_t>(height - 1 - row) * stride;
 		std::memcpy(flippedPixels.data() + dstOffset, pixels.data() + srcOffset, stride);
 	}
 	glGenTextures(1, &textureId);
 	glBindTexture(GL_TEXTURE_2D, textureId);
 	glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
 	glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
 	glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
 	glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
 	glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA8, static_cast<GLsizei>(width), static_cast<GLsizei>(height), 0, GL_BGRA, GL_UNSIGNED_BYTE, flippedPixels.data());
 	glBindTexture(GL_TEXTURE_2D, 0);
 	if (shouldUninitializeCom)
 		CoUninitialize();
 	return true;
 }
--- a/apps/LoopThroughWithOpenGLCompositing/gl/TextureAssetLoader.h
+++ b/apps/LoopThroughWithOpenGLCompositing/gl/TextureAssetLoader.h
@@ -1,11 +0,0 @@
 #pragma once
 #include "GLExtensions.h"
 #include "ShaderTypes.h"
 #include <windows.h>
 #include <gl/gl.h>
 #include <string>
 bool LoadTextureAsset(const ShaderTextureAsset& textureAsset, GLuint& textureId, std::string& error);
--- a/apps/LoopThroughWithOpenGLCompositing/resource.h
+++ b/apps/LoopThroughWithOpenGLCompositing/resource.h
@@ -1,24 +0,0 @@
 //{{NO_DEPENDENCIES}}
 // Microsoft Visual C++ generated include file.
 // Used by LoopThroughWithOpenGLCompositing.rc
 //
 #define IDC_MYICON                      2
 #define IDD_OPENGLOUTPUT_DIALOG         102
 #define IDS_APP_TITLE                   103
 #define IDI_OPENGLOUTPUT                107
 #define IDI_SMALL                       108
 #define IDC_OPENGLOUTPUT                109
 #define IDR_MAINFRAME                   128
 #define IDC_STATIC                      -1
 // Next default values for new objects
 //
 #ifdef APSTUDIO_INVOKED
 #ifndef APSTUDIO_READONLY_SYMBOLS
 #define _APS_NO_MFC                     1
 #define _APS_NEXT_RESOURCE_VALUE        129
 #define _APS_NEXT_COMMAND_VALUE         32771
 #define _APS_NEXT_CONTROL_VALUE         1000
 #define _APS_NEXT_SYMED_VALUE           110
 #endif
 #endif
--- a/apps/LoopThroughWithOpenGLCompositing/runtime/RuntimeClock.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/runtime/RuntimeClock.cpp
@@ -1,45 +0,0 @@
 #include "RuntimeClock.h"
 #include <chrono>
 namespace
 {
 bool ToUtcTime(std::time_t time, std::tm& utcTime)
 {
 	return gmtime_s(&utcTime, &time) == 0;
 }
 bool ToLocalTime(std::time_t time, std::tm& localTime)
 {
 	return localtime_s(&localTime, &time) == 0;
 }
 }
 RuntimeClockSnapshot GetRuntimeClockSnapshot()
 {
 	return MakeRuntimeClockSnapshot(std::chrono::system_clock::to_time_t(std::chrono::system_clock::now()));
 }
 RuntimeClockSnapshot MakeRuntimeClockSnapshot(std::time_t now)
 {
 	RuntimeClockSnapshot snapshot;
 	std::tm utcTime = {};
 	if (!ToUtcTime(now, utcTime))
 		return snapshot;
 	snapshot.utcTimeSeconds =
 		static_cast<double>(utcTime.tm_hour * 3600 + utcTime.tm_min * 60 + utcTime.tm_sec);
 	std::tm localTime = {};
 	if (!ToLocalTime(now, localTime))
 		return snapshot;
 	utcTime.tm_isdst = localTime.tm_isdst;
 	const std::time_t localAsTime = std::mktime(&localTime);
 	const std::time_t utcAsLocalTime = std::mktime(&utcTime);
 	if (localAsTime != static_cast<std::time_t>(-1) && utcAsLocalTime != static_cast<std::time_t>(-1))
 		snapshot.utcOffsetSeconds = std::difftime(localAsTime, utcAsLocalTime);
 	return snapshot;
 }
--- a/apps/LoopThroughWithOpenGLCompositing/runtime/RuntimeClock.h
+++ b/apps/LoopThroughWithOpenGLCompositing/runtime/RuntimeClock.h
@@ -1,12 +0,0 @@
 #pragma once
 #include <ctime>
 struct RuntimeClockSnapshot
 {
 	double utcTimeSeconds = 0.0;
 	double utcOffsetSeconds = 0.0;
 };
 RuntimeClockSnapshot GetRuntimeClockSnapshot();
 RuntimeClockSnapshot MakeRuntimeClockSnapshot(std::time_t now);
--- a/apps/LoopThroughWithOpenGLCompositing/runtime/RuntimeHost.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/runtime/RuntimeHost.cpp
--- a/apps/LoopThroughWithOpenGLCompositing/runtime/RuntimeHost.h
+++ b/apps/LoopThroughWithOpenGLCompositing/runtime/RuntimeHost.h
@@ -1,181 +0,0 @@
 #pragma once
 #include "RuntimeJson.h"
 #include "ShaderTypes.h"
 #include <atomic>
 #include <chrono>
 #include <filesystem>
 #include <map>
 #include <mutex>
 #include <string>
 #include <vector>
 class RuntimeHost
 {
 public:
 	RuntimeHost();
 	bool Initialize(std::string& error);
 	bool PollFileChanges(bool& registryChanged, bool& reloadRequested, std::string& error);
 	bool ManualReloadRequested();
 	void ClearReloadRequest();
 	bool AddLayer(const std::string& shaderId, std::string& error);
 	bool RemoveLayer(const std::string& layerId, std::string& error);
 	bool MoveLayer(const std::string& layerId, int direction, std::string& error);
 	bool MoveLayerToIndex(const std::string& layerId, std::size_t targetIndex, std::string& error);
 	bool SetLayerBypass(const std::string& layerId, bool bypassed, std::string& error);
 	bool SetLayerShader(const std::string& layerId, const std::string& shaderId, std::string& error);
 	bool UpdateLayerParameter(const std::string& layerId, const std::string& parameterId, const JsonValue& newValue, std::string& error);
 	bool UpdateLayerParameterByControlKey(const std::string& layerKey, const std::string& parameterKey, const JsonValue& newValue, std::string& error);
 	bool ResetLayerParameters(const std::string& layerId, std::string& error);
 	bool SaveStackPreset(const std::string& presetName, std::string& error) const;
 	bool LoadStackPreset(const std::string& presetName, std::string& error);
 	void SetCompileStatus(bool succeeded, const std::string& message);
 	void SetSignalStatus(bool hasSignal, unsigned width, unsigned height, const std::string& modeName);
 	bool TrySetSignalStatus(bool hasSignal, unsigned width, unsigned height, const std::string& modeName);
 	void SetDeckLinkOutputStatus(const std::string& modelName, bool supportsInternalKeying, bool supportsExternalKeying,
 		bool keyerInterfaceAvailable, bool externalKeyingRequested, bool externalKeyingActive, const std::string& statusMessage);
 	void SetPerformanceStats(double frameBudgetMilliseconds, double renderMilliseconds);
 	bool TrySetPerformanceStats(double frameBudgetMilliseconds, double renderMilliseconds);
 	void SetFramePacingStats(double completionIntervalMilliseconds, double smoothedCompletionIntervalMilliseconds,
 		double maxCompletionIntervalMilliseconds, uint64_t lateFrameCount, uint64_t droppedFrameCount, uint64_t flushedFrameCount);
 	bool TrySetFramePacingStats(double completionIntervalMilliseconds, double smoothedCompletionIntervalMilliseconds,
 		double maxCompletionIntervalMilliseconds, uint64_t lateFrameCount, uint64_t droppedFrameCount, uint64_t flushedFrameCount);
 	void AdvanceFrame();
 	bool TryAdvanceFrame();
 	bool BuildLayerFragmentShaderSource(const std::string& layerId, std::string& fragmentShaderSource, std::string& error);
 	std::vector<RuntimeRenderState> GetLayerRenderStates(unsigned outputWidth, unsigned outputHeight) const;
 	bool TryGetLayerRenderStates(unsigned outputWidth, unsigned outputHeight, std::vector<RuntimeRenderState>& states) const;
 	void RefreshDynamicRenderStateFields(std::vector<RuntimeRenderState>& states) const;
 	std::string BuildStateJson() const;
 	const std::filesystem::path& GetRepoRoot() const { return mRepoRoot; }
 	const std::filesystem::path& GetUiRoot() const { return mUiRoot; }
 	const std::filesystem::path& GetDocsRoot() const { return mDocsRoot; }
 	const std::filesystem::path& GetRuntimeRoot() const { return mRuntimeRoot; }
 	unsigned short GetServerPort() const { return mServerPort; }
 	unsigned short GetOscPort() const { return mConfig.oscPort; }
 	unsigned GetMaxTemporalHistoryFrames() const { return mConfig.maxTemporalHistoryFrames; }
 	bool ExternalKeyingEnabled() const { return mConfig.enableExternalKeying; }
 	const std::string& GetInputVideoFormat() const { return mConfig.inputVideoFormat; }
 	const std::string& GetInputFrameRate() const { return mConfig.inputFrameRate; }
 	const std::string& GetOutputVideoFormat() const { return mConfig.outputVideoFormat; }
 	const std::string& GetOutputFrameRate() const { return mConfig.outputFrameRate; }
 	void SetServerPort(unsigned short port);
 	bool AutoReloadEnabled() const { return mAutoReloadEnabled; }
 private:
 	struct AppConfig
 	{
 		std::string shaderLibrary = "shaders";
 		unsigned short serverPort = 8080;
 		unsigned short oscPort = 9000;
 		bool autoReload = true;
 		unsigned maxTemporalHistoryFrames = 4;
 		bool enableExternalKeying = false;
 		std::string inputVideoFormat = "1080p";
 		std::string inputFrameRate = "59.94";
 		std::string outputVideoFormat = "1080p";
 		std::string outputFrameRate = "59.94";
 	};
 	struct DeckLinkOutputStatus
 	{
 		std::string modelName;
 		bool supportsInternalKeying = false;
 		bool supportsExternalKeying = false;
 		bool keyerInterfaceAvailable = false;
 		bool externalKeyingRequested = false;
 		bool externalKeyingActive = false;
 		std::string statusMessage;
 	};
 	struct LayerPersistentState
 	{
 		std::string id;
 		std::string shaderId;
 		bool bypass = false;
 		std::map<std::string, ShaderParameterValue> parameterValues;
 	};
 	struct PersistentState
 	{
 		std::vector<LayerPersistentState> layers;
 	};
 	bool LoadConfig(std::string& error);
 	bool LoadPersistentState(std::string& error);
 	bool SavePersistentState(std::string& error) const;
 	bool ScanShaderPackages(std::string& error);
 	bool ParseShaderManifest(const std::filesystem::path& manifestPath, ShaderPackage& shaderPackage, std::string& error) const;
 	bool NormalizeAndValidateValue(const ShaderParameterDefinition& definition, const JsonValue& value, ShaderParameterValue& normalizedValue, std::string& error) const;
 	ShaderParameterValue DefaultValueForDefinition(const ShaderParameterDefinition& definition) const;
 	void EnsureLayerDefaultsLocked(LayerPersistentState& layerState, const ShaderPackage& shaderPackage) const;
 	std::string ReadTextFile(const std::filesystem::path& path, std::string& error) const;
 	bool WriteTextFile(const std::filesystem::path& path, const std::string& contents, std::string& error) const;
 	bool ResolvePaths(std::string& error);
 	void BuildLayerRenderStatesLocked(unsigned outputWidth, unsigned outputHeight, std::vector<RuntimeRenderState>& states) const;
 	JsonValue BuildStateValue() const;
 	JsonValue SerializeLayerStackLocked() const;
 	bool DeserializeLayerStackLocked(const JsonValue& layersValue, std::vector<LayerPersistentState>& layers, std::string& error);
 	void NormalizePersistentLayerIdsLocked();
 	std::vector<std::string> GetStackPresetNamesLocked() const;
 	std::string MakeSafePresetFileStem(const std::string& presetName) const;
 	JsonValue SerializeParameterValue(const ShaderParameterDefinition& definition, const ShaderParameterValue& value) const;
 	std::string TemporalHistorySourceToString(TemporalHistorySource source) const;
 	LayerPersistentState* FindLayerById(const std::string& layerId);
 	const LayerPersistentState* FindLayerById(const std::string& layerId) const;
 	std::string GenerateLayerId();
 	void SetSignalStatusLocked(bool hasSignal, unsigned width, unsigned height, const std::string& modeName);
 	void SetPerformanceStatsLocked(double frameBudgetMilliseconds, double renderMilliseconds);
 	void SetFramePacingStatsLocked(double completionIntervalMilliseconds, double smoothedCompletionIntervalMilliseconds,
 		double maxCompletionIntervalMilliseconds, uint64_t lateFrameCount, uint64_t droppedFrameCount, uint64_t flushedFrameCount);
 private:
 	mutable std::mutex mMutex;
 	AppConfig mConfig;
 	PersistentState mPersistentState;
 	std::filesystem::path mRepoRoot;
 	std::filesystem::path mUiRoot;
 	std::filesystem::path mDocsRoot;
 	std::filesystem::path mShaderRoot;
 	std::filesystem::path mRuntimeRoot;
 	std::filesystem::path mPresetRoot;
 	std::filesystem::path mRuntimeStatePath;
 	std::filesystem::path mConfigPath;
 	std::filesystem::path mWrapperPath;
 	std::filesystem::path mGeneratedGlslPath;
 	std::filesystem::path mPatchedGlslPath;
 	std::map<std::string, ShaderPackage> mPackagesById;
 	std::vector<std::string> mPackageOrder;
 	std::vector<ShaderPackageStatus> mPackageStatuses;
 	bool mReloadRequested;
 	bool mCompileSucceeded;
 	std::string mCompileMessage;
 	bool mHasSignal;
 	unsigned mSignalWidth;
 	unsigned mSignalHeight;
 	std::string mSignalModeName;
 	double mFrameBudgetMilliseconds;
 	double mRenderMilliseconds;
 	double mSmoothedRenderMilliseconds;
 	double mCompletionIntervalMilliseconds;
 	double mSmoothedCompletionIntervalMilliseconds;
 	double mMaxCompletionIntervalMilliseconds;
 	double mStartupRandom;
 	uint64_t mLateFrameCount;
 	uint64_t mDroppedFrameCount;
 	uint64_t mFlushedFrameCount;
 	DeckLinkOutputStatus mDeckLinkOutputStatus;
 	unsigned short mServerPort;
 	bool mAutoReloadEnabled;
 	std::chrono::steady_clock::time_point mStartTime;
 	std::chrono::steady_clock::time_point mLastScanTime;
 	std::atomic<uint64_t> mFrameCounter;
 	uint64_t mNextLayerId;
 };
--- a/apps/LoopThroughWithOpenGLCompositing/shader/ShaderPackageRegistry.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/shader/ShaderPackageRegistry.cpp
@@ -1,682 +0,0 @@
 #include "stdafx.h"
 #include "ShaderPackageRegistry.h"
 #include "RuntimeJson.h"
 #include <algorithm>
 #include <cmath>
 #include <cctype>
 #include <fstream>
 #include <sstream>
 namespace
 {
 std::string Trim(const std::string& text)
 {
 	std::size_t start = 0;
 	while (start < text.size() && std::isspace(static_cast<unsigned char>(text[start])))
 		++start;
 	std::size_t end = text.size();
 	while (end > start && std::isspace(static_cast<unsigned char>(text[end - 1])))
 		--end;
 	return text.substr(start, end - start);
 }
 bool IsFiniteNumber(double value)
 {
 	return std::isfinite(value) != 0;
 }
 std::vector<double> JsonArrayToNumbers(const JsonValue& value)
 {
 	std::vector<double> numbers;
 	for (const JsonValue& item : value.asArray())
 	{
 		if (item.isNumber())
 			numbers.push_back(item.asNumber());
 	}
 	return numbers;
 }
 bool ParseShaderParameterType(const std::string& typeName, ShaderParameterType& type)
 {
 	if (typeName == "float")
 	{
 		type = ShaderParameterType::Float;
 		return true;
 	}
 	if (typeName == "vec2")
 	{
 		type = ShaderParameterType::Vec2;
 		return true;
 	}
 	if (typeName == "color")
 	{
 		type = ShaderParameterType::Color;
 		return true;
 	}
 	if (typeName == "bool")
 	{
 		type = ShaderParameterType::Boolean;
 		return true;
 	}
 	if (typeName == "enum")
 	{
 		type = ShaderParameterType::Enum;
 		return true;
 	}
 	if (typeName == "text")
 	{
 		type = ShaderParameterType::Text;
 		return true;
 	}
 	if (typeName == "trigger")
 	{
 		type = ShaderParameterType::Trigger;
 		return true;
 	}
 	return false;
 }
 bool ParseTemporalHistorySource(const std::string& sourceName, TemporalHistorySource& source)
 {
 	if (sourceName == "source")
 	{
 		source = TemporalHistorySource::Source;
 		return true;
 	}
 	if (sourceName == "preLayerInput")
 	{
 		source = TemporalHistorySource::PreLayerInput;
 		return true;
 	}
 	if (sourceName == "none")
 	{
 		source = TemporalHistorySource::None;
 		return true;
 	}
 	return false;
 }
 std::string ReadTextFile(const std::filesystem::path& path, std::string& error)
 {
 	std::ifstream input(path, std::ios::binary);
 	if (!input)
 	{
 		error = "Could not open file: " + path.string();
 		return std::string();
 	}
 	std::ostringstream buffer;
 	buffer << input.rdbuf();
 	return buffer.str();
 }
 std::string ManifestPathMessage(const std::filesystem::path& manifestPath)
 {
 	return manifestPath.string();
 }
 bool RequireStringField(const JsonValue& object, const char* fieldName, std::string& value, const std::filesystem::path& manifestPath, std::string& error)
 {
 	const JsonValue* fieldValue = object.find(fieldName);
 	if (!fieldValue || !fieldValue->isString())
 	{
 		error = "Shader manifest is missing required string '" + std::string(fieldName) + "' field: " + ManifestPathMessage(manifestPath);
 		return false;
 	}
 	value = fieldValue->asString();
 	return true;
 }
 bool RequireNonEmptyStringField(const JsonValue& object, const char* fieldName, std::string& value, const std::filesystem::path& manifestPath, std::string& error)
 {
 	if (!RequireStringField(object, fieldName, value, manifestPath, error))
 		return false;
 	if (Trim(value).empty())
 	{
 		error = "Shader manifest string '" + std::string(fieldName) + "' must not be empty: " + ManifestPathMessage(manifestPath);
 		return false;
 	}
 	return true;
 }
 bool OptionalStringField(const JsonValue& object, const char* fieldName, std::string& value, const std::string& fallback, const std::filesystem::path& manifestPath, std::string& error)
 {
 	const JsonValue* fieldValue = object.find(fieldName);
 	if (!fieldValue)
 	{
 		value = fallback;
 		return true;
 	}
 	if (!fieldValue->isString())
 	{
 		error = "Shader manifest field '" + std::string(fieldName) + "' must be a string in: " + ManifestPathMessage(manifestPath);
 		return false;
 	}
 	value = fieldValue->asString();
 	return true;
 }
 bool OptionalArrayField(const JsonValue& object, const char* fieldName, const JsonValue*& value, const std::filesystem::path& manifestPath, std::string& error)
 {
 	value = object.find(fieldName);
 	if (!value)
 		return true;
 	if (!value->isArray())
 	{
 		error = "Shader manifest '" + std::string(fieldName) + "' field must be an array in: " + ManifestPathMessage(manifestPath);
 		return false;
 	}
 	return true;
 }
 bool OptionalObjectField(const JsonValue& object, const char* fieldName, const JsonValue*& value, const std::filesystem::path& manifestPath, std::string& error)
 {
 	value = object.find(fieldName);
 	if (!value)
 		return true;
 	if (!value->isObject())
 	{
 		error = "Shader manifest '" + std::string(fieldName) + "' field must be an object in: " + ManifestPathMessage(manifestPath);
 		return false;
 	}
 	return true;
 }
 bool NumberListFromJsonValue(const JsonValue& value, std::vector<double>& numbers, const std::string& fieldName, const std::filesystem::path& manifestPath, std::string& error)
 {
 	if (value.isNumber())
 	{
 		numbers.push_back(value.asNumber());
 		return true;
 	}
 	if (value.isArray())
 	{
 		numbers = JsonArrayToNumbers(value);
 		if (numbers.size() != value.asArray().size())
 		{
 			error = "Shader parameter field '" + fieldName + "' must contain only numbers in: " + ManifestPathMessage(manifestPath);
 			return false;
 		}
 		return true;
 	}
 	error = "Shader parameter field '" + fieldName + "' must be a number or array of numbers in: " + ManifestPathMessage(manifestPath);
 	return false;
 }
 bool ValidateShaderIdentifier(const std::string& identifier, const std::string& fieldName, const std::filesystem::path& manifestPath, std::string& error)
 {
 	if (identifier.empty() || !(std::isalpha(static_cast<unsigned char>(identifier.front())) || identifier.front() == '_'))
 	{
 		error = "Shader manifest field '" + fieldName + "' must be a valid shader identifier in: " + ManifestPathMessage(manifestPath);
 		return false;
 	}
 	for (char ch : identifier)
 	{
 		const unsigned char unsignedCh = static_cast<unsigned char>(ch);
 		if (!(std::isalnum(unsignedCh) || ch == '_'))
 		{
 			error = "Shader manifest field '" + fieldName + "' must be a valid shader identifier in: " + ManifestPathMessage(manifestPath);
 			return false;
 		}
 	}
 	return true;
 }
 bool ParseShaderMetadata(const JsonValue& manifestJson, ShaderPackage& shaderPackage, const std::filesystem::path& manifestPath, std::string& error)
 {
 	if (!RequireStringField(manifestJson, "id", shaderPackage.id, manifestPath, error) ||
 		!RequireStringField(manifestJson, "name", shaderPackage.displayName, manifestPath, error) ||
 		!OptionalStringField(manifestJson, "description", shaderPackage.description, "", manifestPath, error) ||
 		!OptionalStringField(manifestJson, "category", shaderPackage.category, "", manifestPath, error) ||
 		!OptionalStringField(manifestJson, "entryPoint", shaderPackage.entryPoint, "shadeVideo", manifestPath, error))
 	{
 		return false;
 	}
 	if (!ValidateShaderIdentifier(shaderPackage.entryPoint, "entryPoint", manifestPath, error))
 		return false;
 	shaderPackage.directoryPath = manifestPath.parent_path();
 	shaderPackage.shaderPath = shaderPackage.directoryPath / "shader.slang";
 	shaderPackage.manifestPath = manifestPath;
 	return true;
 }
 bool ParseTextureAssets(const JsonValue& manifestJson, ShaderPackage& shaderPackage, const std::filesystem::path& manifestPath, std::string& error)
 {
 	const JsonValue* texturesValue = nullptr;
 	if (!OptionalArrayField(manifestJson, "textures", texturesValue, manifestPath, error))
 		return false;
 	if (!texturesValue)
 		return true;
 	for (const JsonValue& textureJson : texturesValue->asArray())
 	{
 		if (!textureJson.isObject())
 		{
 			error = "Shader texture entry must be an object in: " + ManifestPathMessage(manifestPath);
 			return false;
 		}
 		std::string textureId;
 		std::string texturePath;
 		if (!RequireNonEmptyStringField(textureJson, "id", textureId, manifestPath, error) ||
 			!RequireNonEmptyStringField(textureJson, "path", texturePath, manifestPath, error))
 		{
 			error = "Shader texture is missing required 'id' or 'path' in: " + ManifestPathMessage(manifestPath);
 			return false;
 		}
 		if (!ValidateShaderIdentifier(textureId, "textures[].id", manifestPath, error))
 			return false;
 		ShaderTextureAsset textureAsset;
 		textureAsset.id = textureId;
 		textureAsset.path = shaderPackage.directoryPath / texturePath;
 		if (!std::filesystem::exists(textureAsset.path))
 		{
 			error = "Shader texture asset not found for package " + shaderPackage.id + ": " + textureAsset.path.string();
 			return false;
 		}
 		textureAsset.writeTime = std::filesystem::last_write_time(textureAsset.path);
 		shaderPackage.textureAssets.push_back(textureAsset);
 	}
 	return true;
 }
 bool ParseFontAssets(const JsonValue& manifestJson, ShaderPackage& shaderPackage, const std::filesystem::path& manifestPath, std::string& error)
 {
 	const JsonValue* fontsValue = nullptr;
 	if (!OptionalArrayField(manifestJson, "fonts", fontsValue, manifestPath, error))
 		return false;
 	if (!fontsValue)
 		return true;
 	for (const JsonValue& fontJson : fontsValue->asArray())
 	{
 		if (!fontJson.isObject())
 		{
 			error = "Shader font entry must be an object in: " + ManifestPathMessage(manifestPath);
 			return false;
 		}
 		std::string fontId;
 		std::string fontPath;
 		if (!RequireNonEmptyStringField(fontJson, "id", fontId, manifestPath, error) ||
 			!RequireNonEmptyStringField(fontJson, "path", fontPath, manifestPath, error))
 		{
 			error = "Shader font is missing required 'id' or 'path' in: " + ManifestPathMessage(manifestPath);
 			return false;
 		}
 		if (!ValidateShaderIdentifier(fontId, "fonts[].id", manifestPath, error))
 			return false;
 		ShaderFontAsset fontAsset;
 		fontAsset.id = fontId;
 		fontAsset.path = shaderPackage.directoryPath / fontPath;
 		if (!std::filesystem::exists(fontAsset.path))
 		{
 			error = "Shader font asset not found for package " + shaderPackage.id + ": " + fontAsset.path.string();
 			return false;
 		}
 		fontAsset.writeTime = std::filesystem::last_write_time(fontAsset.path);
 		shaderPackage.fontAssets.push_back(fontAsset);
 	}
 	return true;
 }
 bool ParseTemporalSettings(const JsonValue& manifestJson, ShaderPackage& shaderPackage, unsigned maxTemporalHistoryFrames, const std::filesystem::path& manifestPath, std::string& error)
 {
 	const JsonValue* temporalValue = nullptr;
 	if (!OptionalObjectField(manifestJson, "temporal", temporalValue, manifestPath, error))
 		return false;
 	if (!temporalValue)
 		return true;
 	const JsonValue* enabledValue = temporalValue->find("enabled");
 	if (!enabledValue || !enabledValue->asBoolean(false))
 		return true;
 	std::string historySourceName;
 	if (!RequireNonEmptyStringField(*temporalValue, "historySource", historySourceName, manifestPath, error))
 	{
 		error = "Temporal shader is missing required 'historySource' in: " + ManifestPathMessage(manifestPath);
 		return false;
 	}
 	const JsonValue* historyLengthValue = temporalValue->find("historyLength");
 	if (!historyLengthValue || !historyLengthValue->isNumber())
 	{
 		error = "Temporal shader is missing required numeric 'historyLength' in: " + ManifestPathMessage(manifestPath);
 		return false;
 	}
 	TemporalHistorySource historySource = TemporalHistorySource::None;
 	if (!ParseTemporalHistorySource(historySourceName, historySource))
 	{
 		error = "Unsupported temporal historySource '" + historySourceName + "' in: " + ManifestPathMessage(manifestPath);
 		return false;
 	}
 	const double requestedHistoryLength = historyLengthValue->asNumber();
 	if (!IsFiniteNumber(requestedHistoryLength) || requestedHistoryLength <= 0.0 || std::floor(requestedHistoryLength) != requestedHistoryLength)
 	{
 		error = "Temporal shader 'historyLength' must be a positive integer in: " + ManifestPathMessage(manifestPath);
 		return false;
 	}
 	shaderPackage.temporal.enabled = true;
 	shaderPackage.temporal.historySource = historySource;
 	shaderPackage.temporal.requestedHistoryLength = static_cast<unsigned>(requestedHistoryLength);
 	shaderPackage.temporal.effectiveHistoryLength = std::min(shaderPackage.temporal.requestedHistoryLength, maxTemporalHistoryFrames);
 	return true;
 }
 bool ParseParameterNumberField(const JsonValue& parameterJson, const char* fieldName, std::vector<double>& values, const std::filesystem::path& manifestPath, std::string& error)
 {
 	if (const JsonValue* fieldValue = parameterJson.find(fieldName))
 		return NumberListFromJsonValue(*fieldValue, values, fieldName, manifestPath, error);
 	return true;
 }
 bool ParseParameterDefault(const JsonValue& parameterJson, ShaderParameterDefinition& definition, const std::filesystem::path& manifestPath, std::string& error)
 {
 	const JsonValue* defaultValue = parameterJson.find("default");
 	if (!defaultValue)
 		return true;
 	if (definition.type == ShaderParameterType::Boolean)
 	{
 		if (!defaultValue->isBoolean())
 		{
 			error = "Boolean parameter default must be a boolean for: " + definition.id;
 			return false;
 		}
 		definition.defaultBoolean = defaultValue->asBoolean(false);
 		return true;
 	}
 	if (definition.type == ShaderParameterType::Enum)
 	{
 		if (!defaultValue->isString())
 		{
 			error = "Enum parameter default must be a string for: " + definition.id;
 			return false;
 		}
 		definition.defaultEnumValue = defaultValue->asString();
 		return true;
 	}
 	if (definition.type == ShaderParameterType::Text)
 	{
 		if (!defaultValue->isString())
 		{
 			error = "Text parameter default must be a string for: " + definition.id;
 			return false;
 		}
 		definition.defaultTextValue = defaultValue->asString();
 		return true;
 	}
 	return NumberListFromJsonValue(*defaultValue, definition.defaultNumbers, "default", manifestPath, error);
 }
 bool ParseParameterOptions(const JsonValue& parameterJson, ShaderParameterDefinition& definition, const std::filesystem::path& manifestPath, std::string& error)
 {
 	const JsonValue* optionsValue = nullptr;
 	if (!OptionalArrayField(parameterJson, "options", optionsValue, manifestPath, error) || !optionsValue)
 	{
 		error = "Enum parameter is missing 'options' in: " + ManifestPathMessage(manifestPath);
 		return false;
 	}
 	for (const JsonValue& optionJson : optionsValue->asArray())
 	{
 		if (!optionJson.isObject())
 		{
 			error = "Enum parameter option must be an object in: " + ManifestPathMessage(manifestPath);
 			return false;
 		}
 		ShaderParameterOption option;
 		if (!RequireStringField(optionJson, "value", option.value, manifestPath, error) ||
 			!RequireStringField(optionJson, "label", option.label, manifestPath, error))
 		{
 			error = "Enum parameter option is missing 'value' or 'label' in: " + ManifestPathMessage(manifestPath);
 			return false;
 		}
 		definition.enumOptions.push_back(option);
 	}
 	bool defaultFound = definition.defaultEnumValue.empty();
 	for (const ShaderParameterOption& option : definition.enumOptions)
 	{
 		if (option.value == definition.defaultEnumValue)
 		{
 			defaultFound = true;
 			break;
 		}
 	}
 	if (!defaultFound)
 	{
 		error = "Enum parameter default is not present in its option list for: " + definition.id;
 		return false;
 	}
 	return true;
 }
 bool ParseParameterDefinition(const JsonValue& parameterJson, ShaderParameterDefinition& definition, const std::filesystem::path& manifestPath, std::string& error)
 {
 	if (!parameterJson.isObject())
 	{
 		error = "Shader parameter entry must be an object in: " + ManifestPathMessage(manifestPath);
 		return false;
 	}
 	std::string typeName;
 	if (!RequireStringField(parameterJson, "id", definition.id, manifestPath, error) ||
 		!RequireStringField(parameterJson, "label", definition.label, manifestPath, error) ||
 		!RequireStringField(parameterJson, "type", typeName, manifestPath, error))
 	{
 		error = "Shader parameter is missing required fields in: " + ManifestPathMessage(manifestPath);
 		return false;
 	}
 	if (!ParseShaderParameterType(typeName, definition.type))
 	{
 		error = "Unsupported parameter type '" + typeName + "' in: " + ManifestPathMessage(manifestPath);
 		return false;
 	}
 	if (!ValidateShaderIdentifier(definition.id, "parameters[].id", manifestPath, error))
 		return false;
 	if (!ParseParameterDefault(parameterJson, definition, manifestPath, error) ||
 		!ParseParameterNumberField(parameterJson, "min", definition.minNumbers, manifestPath, error) ||
 		!ParseParameterNumberField(parameterJson, "max", definition.maxNumbers, manifestPath, error) ||
 		!ParseParameterNumberField(parameterJson, "step", definition.stepNumbers, manifestPath, error))
 	{
 		return false;
 	}
 	if (definition.type == ShaderParameterType::Text)
 	{
 		if (const JsonValue* fontValue = parameterJson.find("font"))
 		{
 			if (!fontValue->isString())
 			{
 				error = "Text parameter 'font' must be a string for: " + definition.id;
 				return false;
 			}
 			definition.fontId = fontValue->asString();
 			if (!definition.fontId.empty() && !ValidateShaderIdentifier(definition.fontId, "parameters[].font", manifestPath, error))
 				return false;
 		}
 		if (const JsonValue* maxLengthValue = parameterJson.find("maxLength"))
 		{
 			if (!maxLengthValue->isNumber() || maxLengthValue->asNumber() < 1.0 || maxLengthValue->asNumber() > 256.0)
 			{
 				error = "Text parameter 'maxLength' must be a number from 1 to 256 for: " + definition.id;
 				return false;
 			}
 			definition.maxLength = static_cast<unsigned>(maxLengthValue->asNumber());
 		}
 	}
 	if (definition.type == ShaderParameterType::Enum)
 		return ParseParameterOptions(parameterJson, definition, manifestPath, error);
 	return true;
 }
 bool ParseParameterDefinitions(const JsonValue& manifestJson, ShaderPackage& shaderPackage, const std::filesystem::path& manifestPath, std::string& error)
 {
 	const JsonValue* parametersValue = nullptr;
 	if (!OptionalArrayField(manifestJson, "parameters", parametersValue, manifestPath, error))
 		return false;
 	if (!parametersValue)
 		return true;
 	for (const JsonValue& parameterJson : parametersValue->asArray())
 	{
 		ShaderParameterDefinition definition;
 		if (!ParseParameterDefinition(parameterJson, definition, manifestPath, error))
 			return false;
 		shaderPackage.parameters.push_back(definition);
 	}
 	return true;
 }
 std::string UniqueUnavailableShaderId(const std::filesystem::path& manifestPath, const std::string& parsedId)
 {
 	const std::string fallbackId = manifestPath.parent_path().filename().string();
 	const std::string baseId = parsedId.empty() ? fallbackId : parsedId;
 	return baseId + "@invalid:" + fallbackId;
 }
 ShaderPackageStatus BuildUnavailableStatus(const std::filesystem::path& manifestPath, const ShaderPackage& partialPackage, const std::string& packageError)
 {
 	ShaderPackageStatus status;
 	status.id = UniqueUnavailableShaderId(manifestPath, partialPackage.id);
 	status.displayName = !partialPackage.displayName.empty() ? partialPackage.displayName : manifestPath.parent_path().filename().string();
 	status.description = partialPackage.description;
 	status.category = !partialPackage.category.empty() ? partialPackage.category : "Unavailable";
 	status.available = false;
 	status.error = packageError;
 	return status;
 }
 ShaderPackageStatus BuildAvailableStatus(const ShaderPackage& shaderPackage)
 {
 	ShaderPackageStatus status;
 	status.id = shaderPackage.id;
 	status.displayName = shaderPackage.displayName;
 	status.description = shaderPackage.description;
 	status.category = shaderPackage.category;
 	status.available = true;
 	return status;
 }
 }
 ShaderPackageRegistry::ShaderPackageRegistry(unsigned maxTemporalHistoryFrames)
 	: mMaxTemporalHistoryFrames(maxTemporalHistoryFrames)
 {
 }
 bool ShaderPackageRegistry::Scan(
 	const std::filesystem::path& shaderRoot,
 	std::map<std::string, ShaderPackage>& packagesById,
 	std::vector<std::string>& packageOrder,
 	std::vector<ShaderPackageStatus>& packageStatuses,
 	std::string& error) const
 {
 	packagesById.clear();
 	packageOrder.clear();
 	packageStatuses.clear();
 	if (!std::filesystem::exists(shaderRoot))
 	{
 		error = "Shader library directory does not exist: " + shaderRoot.string();
 		return false;
 	}
 	for (const auto& entry : std::filesystem::directory_iterator(shaderRoot))
 	{
 		if (!entry.is_directory())
 			continue;
 		std::filesystem::path manifestPath = entry.path() / "shader.json";
 		if (!std::filesystem::exists(manifestPath))
 			continue;
 		ShaderPackage shaderPackage;
 		if (!ParseManifest(manifestPath, shaderPackage, error))
 		{
 			packageStatuses.push_back(BuildUnavailableStatus(manifestPath, shaderPackage, error));
 			error.clear();
 			continue;
 		}
 		if (packagesById.find(shaderPackage.id) != packagesById.end())
 		{
 			packageStatuses.push_back(BuildUnavailableStatus(manifestPath, shaderPackage, "Duplicate shader id found: " + shaderPackage.id));
 			continue;
 		}
 		packageOrder.push_back(shaderPackage.id);
 		packageStatuses.push_back(BuildAvailableStatus(shaderPackage));
 		packagesById[shaderPackage.id] = shaderPackage;
 	}
 	std::sort(packageOrder.begin(), packageOrder.end());
 	std::sort(packageStatuses.begin(), packageStatuses.end(), [](const ShaderPackageStatus& left, const ShaderPackageStatus& right) {
 		return left.displayName < right.displayName;
 	});
 	return true;
 }
 bool ShaderPackageRegistry::ParseManifest(const std::filesystem::path& manifestPath, ShaderPackage& shaderPackage, std::string& error) const
 {
 	const std::string manifestText = ReadTextFile(manifestPath, error);
 	if (manifestText.empty())
 		return false;
 	JsonValue manifestJson;
 	if (!ParseJson(manifestText, manifestJson, error))
 		return false;
 	if (!manifestJson.isObject())
 	{
 		error = "Shader manifest root must be an object: " + manifestPath.string();
 		return false;
 	}
 	if (!ParseShaderMetadata(manifestJson, shaderPackage, manifestPath, error))
 		return false;
 	if (!std::filesystem::exists(shaderPackage.shaderPath))
 	{
 		error = "Shader source not found for package " + shaderPackage.id + ": " + shaderPackage.shaderPath.string();
 		return false;
 	}
 	shaderPackage.shaderWriteTime = std::filesystem::last_write_time(shaderPackage.shaderPath);
 	shaderPackage.manifestWriteTime = std::filesystem::last_write_time(shaderPackage.manifestPath);
 	return ParseTextureAssets(manifestJson, shaderPackage, manifestPath, error) &&
 		ParseFontAssets(manifestJson, shaderPackage, manifestPath, error) &&
 		ParseTemporalSettings(manifestJson, shaderPackage, mMaxTemporalHistoryFrames, manifestPath, error) &&
 		ParseParameterDefinitions(manifestJson, shaderPackage, manifestPath, error);
 }
--- a/apps/LoopThroughWithOpenGLCompositing/small.ico
+++ b/apps/LoopThroughWithOpenGLCompositing/small.ico
--- a/apps/LoopThroughWithOpenGLCompositing/stdafx.cpp
+++ b/apps/LoopThroughWithOpenGLCompositing/stdafx.cpp
@@ -1,46 +0,0 @@
 /* -LICENSE-START-
 ** Copyright (c) 2012 Blackmagic Design
 **  
 ** Permission is hereby granted, free of charge, to any person or organization 
 ** obtaining a copy of the software and accompanying documentation (the 
 ** "Software") to use, reproduce, display, distribute, sub-license, execute, 
 ** and transmit the Software, and to prepare derivative works of the Software, 
 ** and to permit third-parties to whom the Software is furnished to do so, in 
 ** accordance with:
 ** 
 ** (1) if the Software is obtained from Blackmagic Design, the End User License 
 ** Agreement for the Software Development Kit ("EULA") available at 
 ** https://www.blackmagicdesign.com/EULA/DeckLinkSDK; or
 ** 
 ** (2) if the Software is obtained from any third party, such licensing terms 
 ** as notified by that third party,
 ** 
 ** and all subject to the following:
 ** 
 ** (3) the copyright notices in the Software and this entire statement, 
 ** including the above license grant, this restriction and the following 
 ** disclaimer, must be included in all copies of the Software, in whole or in 
 ** part, and all derivative works of the Software, unless such copies or 
 ** derivative works are solely in the form of machine-executable object code 
 ** generated by a source language processor.
 ** 
 ** (4) THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS 
 ** OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, 
 ** FITNESS FOR A PARTICULAR PURPOSE, TITLE AND NON-INFRINGEMENT. IN NO EVENT 
 ** SHALL THE COPYRIGHT HOLDERS OR ANYONE DISTRIBUTING THE SOFTWARE BE LIABLE 
 ** FOR ANY DAMAGES OR OTHER LIABILITY, WHETHER IN CONTRACT, TORT OR OTHERWISE, 
 ** ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER 
 ** DEALINGS IN THE SOFTWARE.
 ** 
 ** A copy of the Software is available free of charge at 
 ** https://www.blackmagicdesign.com/desktopvideo_sdk under the EULA.
 ** 
 ** -LICENSE-END-
 */
 //
 // stdafx.cpp : source file that includes just the standard includes
 // LoopThroughWithOpenGLCompositing.pch will be the pre-compiled header
 // stdafx.obj will contain the pre-compiled type information
 #include "stdafx.h"
--- a/apps/LoopThroughWithOpenGLCompositing/stdafx.h
+++ b/apps/LoopThroughWithOpenGLCompositing/stdafx.h
@@ -1,65 +0,0 @@
 /* -LICENSE-START-
 ** Copyright (c) 2012 Blackmagic Design
 **  
 ** Permission is hereby granted, free of charge, to any person or organization 
 ** obtaining a copy of the software and accompanying documentation (the 
 ** "Software") to use, reproduce, display, distribute, sub-license, execute, 
 ** and transmit the Software, and to prepare derivative works of the Software, 
 ** and to permit third-parties to whom the Software is furnished to do so, in 
 ** accordance with:
 ** 
 ** (1) if the Software is obtained from Blackmagic Design, the End User License 
 ** Agreement for the Software Development Kit ("EULA") available at 
 ** https://www.blackmagicdesign.com/EULA/DeckLinkSDK; or
 ** 
 ** (2) if the Software is obtained from any third party, such licensing terms 
 ** as notified by that third party,
 ** 
 ** and all subject to the following:
 ** 
 ** (3) the copyright notices in the Software and this entire statement, 
 ** including the above license grant, this restriction and the following 
 ** disclaimer, must be included in all copies of the Software, in whole or in 
 ** part, and all derivative works of the Software, unless such copies or 
 ** derivative works are solely in the form of machine-executable object code 
 ** generated by a source language processor.
 ** 
 ** (4) THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS 
 ** OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, 
 ** FITNESS FOR A PARTICULAR PURPOSE, TITLE AND NON-INFRINGEMENT. IN NO EVENT 
 ** SHALL THE COPYRIGHT HOLDERS OR ANYONE DISTRIBUTING THE SOFTWARE BE LIABLE 
 ** FOR ANY DAMAGES OR OTHER LIABILITY, WHETHER IN CONTRACT, TORT OR OTHERWISE, 
 ** ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER 
 ** DEALINGS IN THE SOFTWARE.
 ** 
 ** A copy of the Software is available free of charge at 
 ** https://www.blackmagicdesign.com/desktopvideo_sdk under the EULA.
 ** 
 ** -LICENSE-END-
 */
 //
 // stdafx.h : include file for standard system include files,
 // or project specific include files that are used frequently, but
 // are changed infrequently
 //
 #pragma once
 #include "targetver.h"
 #ifndef NOMINMAX
 #define NOMINMAX
 #endif
 #define WIN32_LEAN_AND_MEAN             // Exclude rarely-used stuff from Windows headers
 // Windows Header Files:
 #include <winsock2.h>
 #include <ws2tcpip.h>
 #include <windows.h>
 // C RunTime Header Files
 #include <stdlib.h>
 #include <malloc.h>
 #include <memory.h>
 #include <tchar.h>
--- a/apps/LoopThroughWithOpenGLCompositing/targetver.h
+++ b/apps/LoopThroughWithOpenGLCompositing/targetver.h
@@ -1,64 +0,0 @@
 /* -LICENSE-START-
 ** Copyright (c) 2012 Blackmagic Design
 **  
 ** Permission is hereby granted, free of charge, to any person or organization 
 ** obtaining a copy of the software and accompanying documentation (the 
 ** "Software") to use, reproduce, display, distribute, sub-license, execute, 
 ** and transmit the Software, and to prepare derivative works of the Software, 
 ** and to permit third-parties to whom the Software is furnished to do so, in 
 ** accordance with:
 ** 
 ** (1) if the Software is obtained from Blackmagic Design, the End User License 
 ** Agreement for the Software Development Kit ("EULA") available at 
 ** https://www.blackmagicdesign.com/EULA/DeckLinkSDK; or
 ** 
 ** (2) if the Software is obtained from any third party, such licensing terms 
 ** as notified by that third party,
 ** 
 ** and all subject to the following:
 ** 
 ** (3) the copyright notices in the Software and this entire statement, 
 ** including the above license grant, this restriction and the following 
 ** disclaimer, must be included in all copies of the Software, in whole or in 
 ** part, and all derivative works of the Software, unless such copies or 
 ** derivative works are solely in the form of machine-executable object code 
 ** generated by a source language processor.
 ** 
 ** (4) THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS 
 ** OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, 
 ** FITNESS FOR A PARTICULAR PURPOSE, TITLE AND NON-INFRINGEMENT. IN NO EVENT 
 ** SHALL THE COPYRIGHT HOLDERS OR ANYONE DISTRIBUTING THE SOFTWARE BE LIABLE 
 ** FOR ANY DAMAGES OR OTHER LIABILITY, WHETHER IN CONTRACT, TORT OR OTHERWISE, 
 ** ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER 
 ** DEALINGS IN THE SOFTWARE.
 ** 
 ** A copy of the Software is available free of charge at 
 ** https://www.blackmagicdesign.com/desktopvideo_sdk under the EULA.
 ** 
 ** -LICENSE-END-
 */
 //
 #pragma once
 // The following macros define the minimum required platform.  The minimum required platform
 // is the earliest version of Windows, Internet Explorer etc. that has the necessary features to run
 // your application.  The macros work by enabling all features available on platform versions up to and
 // including the version specified.
 // Modify the following defines if you have to target a platform prior to the ones specified below.
 // Refer to MSDN for the latest info on corresponding values for different platforms.
 #ifndef WINVER                          // Specifies that the minimum required platform is Windows Vista.
 #define WINVER 0x0600           // Change this to the appropriate value to target other versions of Windows.
 #endif
 #ifndef _WIN32_WINNT            // Specifies that the minimum required platform is Windows Vista.
 #define _WIN32_WINNT 0x0600     // Change this to the appropriate value to target other versions of Windows.
 #endif
 #ifndef _WIN32_WINDOWS          // Specifies that the minimum required platform is Windows 98.
 #define _WIN32_WINDOWS 0x0410 // Change this to the appropriate value to target Windows Me or later.
 #endif
 #ifndef _WIN32_IE                       // Specifies that the minimum required platform is Internet Explorer 7.0.
 #define _WIN32_IE 0x0700        // Change this to the appropriate value to target other versions of IE.
 #endif
--- a/config/runtime-host.json
+++ b/config/runtime-host.json
@@ -1,12 +1,55 @@
 {
-  "shaderLibrary": "shaders",
+  "$schema": "./runtime-host.schema.json",
  "serverPort": 8080,
  "oscPort": 9000,
  "inputVideoFormat": "1080p",
  "inputFrameRate": "59.94",
  "outputVideoFormat": "1080p",
  "outputFrameRate": "59.94",
  "autoReload": true,
  "input": {
    "backend": "ndi",
    "device": "AIDENLAPTOP (Test Pattern)",
    "frameRate": "59.94",
    "resolution": "1080p"
  },
  "maxTemporalHistoryFrames": 12,
-  "enableExternalKeying": true
+  "oscBindAddress": "0.0.0.0",
  "oscPort": 9000,
  "oscSmoothing": 0.18,
  "output": {
    "backend": "ndi",
    "device": "Shader",
    "frameRate": "59.94",
    "keying": {
      "alphaRequired": false,
      "external": false
    },
    "pixelFormat": "auto",
    "resolution": "1080p"
  },
  "windowOutput": {
    "fullscreen": true,
    "borderless": true,
    "display": "default",
    "x": 0,
    "y": 0,
    "width": 0,
    "height": 0,
    "vsync": true,
    "allowTearing": false
  },
  "colorPipeline": {
    "ocioEnabled": false,
    "ocioConfig": "",
    "inputColorSpace": "scene_linear",
    "workingColorSpace": "scene_linear",
    "outputColorSpace": "rec709",
    "display": "sRGB",
    "view": "Rec.709",
    "look": "",
    "exposure": 0,
    "gamma": 1,
    "workingFormat": "rgba16f",
    "linearWorkingSpace": true
  },
  "previewEnabled": true,
  "previewFps": 59.94,
  "runtimeShaderId": "",
  "serverPort": 8080,
  "shaderLibrary": "shaders"
 }
--- a/config/runtime-host.schema.json
+++ b/config/runtime-host.schema.json
@@ -0,0 +1,361 @@
 {
  "$schema": "https://json-schema.org/draft/2020-12/schema",
  "$id": "https://render-cadence.local/schemas/runtime-host.schema.json",
  "title": "Render Cadence Runtime Host Configuration",
  "description": "Startup configuration for the Render Cadence native host. This schema documents the settings currently read by AppConfigProvider.",
  "type": "object",
  "additionalProperties": false,
  "properties": {
    "$schema": {
      "type": "string",
      "description": "Editor-only schema reference. The native host ignores this field."
    },
    "shaderLibrary": {
      "type": "string",
      "default": "shaders",
      "description": "Path to the shader package library directory. Relative paths are resolved from the process/repo working location."
    },
    "serverPort": {
      "type": "integer",
      "minimum": 1,
      "maximum": 65535,
      "default": 8080,
      "description": "Preferred HTTP control server port."
    },
    "oscBindAddress": {
      "type": "string",
      "default": "0.0.0.0",
      "description": "OSC bind address reserved for the control surface. The current native host reports this through an OSC status stub but does not start the UDP listener yet."
    },
    "oscPort": {
      "type": "integer",
      "minimum": 0,
      "maximum": 65535,
      "default": 9000,
      "description": "OSC UDP port reserved for the control surface. Use 0 to mark the OSC stub disabled."
    },
    "oscSmoothing": {
      "type": "number",
      "minimum": 0,
      "default": 0.18,
      "description": "Reserved OSC smoothing amount reported through the OSC status stub."
    },
    "input": {
      "$ref": "#/$defs/input"
    },
    "output": {
      "$ref": "#/$defs/output"
    },
    "windowOutput": {
      "$ref": "#/$defs/windowOutput"
    },
    "colorPipeline": {
      "$ref": "#/$defs/colorPipeline"
    },
    "autoReload": {
      "type": "boolean",
      "default": true,
      "description": "When true, the runtime control layer may automatically rescan/reload shader packages when requested by the app flow."
    },
    "maxTemporalHistoryFrames": {
      "type": "integer",
      "minimum": 0,
      "default": 12,
      "description": "Maximum temporal history frames exposed to shaders that request history."
    },
    "previewEnabled": {
      "type": "boolean",
      "default": false,
      "description": "Starts the optional preview window on its own thread."
    },
    "previewFps": {
      "type": "number",
      "exclusiveMinimum": 0,
      "default": 59.94,
      "description": "Target repaint rate for the optional preview window. It does not change render/output cadence."
    },
    "runtimeShaderId": {
      "type": "string",
      "default": "",
      "description": "Optional startup shader package id used only when no saved runtime layer stack is restored. Leave empty to keep the simple fallback renderer until layers are added or restored."
    }
  },
  "required": [
    "shaderLibrary",
    "serverPort",
    "input",
    "output"
  ],
  "$defs": {
    "inputBackend": {
      "type": "string",
      "enum": [
        "decklink",
        "ndi",
        "window",
        "fullscreen",
        "borderless",
        "none",
        "disabled",
        "off"
      ]
    },
    "outputBackend": {
      "type": "string",
      "enum": [
        "decklink",
        "ndi",
        "none",
        "disabled",
        "off"
      ]
    },
    "resolution": {
      "type": "string",
      "enum": [
        "720p",
        "1080i",
        "1080p",
        "2160p",
        "4k",
        "uhd"
      ]
    },
    "frameRate": {
      "type": "string",
      "enum": [
        "23.98",
        "24",
        "25",
        "29.97",
        "30",
        "50",
        "59.94",
        "60"
      ]
    },
    "input": {
      "type": "object",
      "additionalProperties": false,
      "description": "Video input backend configuration. DeckLink uses the configured resolution/frameRate as a capture mode. NDI adapts to the received source shape and logs if it differs from these expected values.",
      "properties": {
        "backend": {
          "$ref": "#/$defs/inputBackend",
          "default": "decklink",
          "description": "Input backend. Use 'decklink' for Blackmagic capture, 'ndi' for NDI receive, or 'none'/'disabled'/'off' for black fallback input."
        },
        "device": {
          "type": "string",
          "default": "default",
          "description": "Input device/source selector. DeckLink currently uses 'default'. NDI accepts 'default'/'auto' for the first discovered source or an exact NDI source name."
        },
        "resolution": {
          "$ref": "#/$defs/resolution",
          "default": "1080p",
          "description": "Expected input resolution/mode. For NDI this is advisory only; received source dimensions are used."
        },
        "frameRate": {
          "$ref": "#/$defs/frameRate",
          "default": "59.94",
          "description": "Expected input frame rate. DeckLink uses this to resolve the hardware mode; NDI currently treats it as an expectation for logging/state."
        }
      },
      "required": [
        "backend",
        "device",
        "resolution",
        "frameRate"
      ]
    },
    "output": {
      "type": "object",
      "additionalProperties": false,
      "description": "Video output backend configuration.",
      "properties": {
        "backend": {
          "$ref": "#/$defs/outputBackend",
          "default": "decklink",
          "description": "Output backend. Use 'decklink' for Blackmagic playout, 'ndi' for NDI send, or 'none'/'disabled'/'off' to disable scheduled output."
        },
        "device": {
          "type": "string",
          "default": "default",
          "description": "Output device selector. DeckLink currently uses the first compatible/default output device. NDI uses this as the advertised sender name; 'default' becomes 'Render Cadence'."
        },
        "resolution": {
          "$ref": "#/$defs/resolution",
          "default": "1080p",
          "description": "Output render and video mode resolution."
        },
        "frameRate": {
          "$ref": "#/$defs/frameRate",
          "default": "59.94",
          "description": "Output render cadence and video mode frame rate."
        },
        "pixelFormat": {
          "type": "string",
          "enum": [
            "auto",
            "bgra8",
            "uyvy8"
          ],
          "default": "auto",
          "description": "Requested system-memory output pixel format. Auto uses UYVY8 for DeckLink/NDI unless Output alpha is enabled, then BGRA8."
        },
        "keying": {
          "type": "object",
          "additionalProperties": false,
          "description": "Output alpha options. The control UI exposes these as a single Output alpha control.",
          "properties": {
            "external": {
              "type": "boolean",
              "default": false,
              "description": "DeckLink external-keyer backing field. The control UI only writes this true for DeckLink output."
            },
            "alphaRequired": {
              "type": "boolean",
              "default": false,
              "description": "General output alpha request. When true, automatic output pixel-format selection uses an alpha-carrying system-frame format."
            }
          },
          "required": [
            "external",
            "alphaRequired"
          ]
        }
      },
      "required": [
        "backend",
        "device",
        "resolution",
        "frameRate"
      ]
    },
    "windowOutput": {
      "type": "object",
      "additionalProperties": false,
      "description": "Reserved settings for a future full-resolution/full-frame-rate borderless or fullscreen video output backend. These are not used by the preview window.",
      "properties": {
        "fullscreen": {
          "type": "boolean",
          "default": true,
          "description": "When the future window backend is implemented, request exclusive/fullscreen-style presentation."
        },
        "borderless": {
          "type": "boolean",
          "default": true,
          "description": "When true, the future window backend should create a borderless output window."
        },
        "display": {
          "type": "string",
          "default": "default",
          "description": "Display/monitor selector for the future window backend."
        },
        "x": {
          "type": "integer",
          "default": 0,
          "description": "Window X position used when fullscreen is false or when a backend needs explicit placement."
        },
        "y": {
          "type": "integer",
          "default": 0,
          "description": "Window Y position used when fullscreen is false or when a backend needs explicit placement."
        },
        "width": {
          "type": "integer",
          "minimum": 0,
          "default": 0,
          "description": "Optional window width override. Zero means use output resolution."
        },
        "height": {
          "type": "integer",
          "minimum": 0,
          "default": 0,
          "description": "Optional window height override. Zero means use output resolution."
        },
        "vsync": {
          "type": "boolean",
          "default": true,
          "description": "Presentation sync request for the future window backend."
        },
        "allowTearing": {
          "type": "boolean",
          "default": false,
          "description": "Allow tearing for the future window backend when the graphics API and OS support it."
        }
      }
    },
    "colorPipeline": {
      "type": "object",
      "additionalProperties": false,
      "description": "Reserved color-management settings for a future OCIO-backed linear RGBA16F render pipeline.",
      "properties": {
        "ocioEnabled": {
          "type": "boolean",
          "default": false,
          "description": "Enable future OpenColorIO transforms. Currently parsed and reported only."
        },
        "ocioConfig": {
          "type": "string",
          "default": "",
          "description": "Path to an OCIO config file or package-relative config identifier."
        },
        "inputColorSpace": {
          "type": "string",
          "default": "scene_linear",
          "description": "Input/video color space to convert from at the input edge."
        },
        "workingColorSpace": {
          "type": "string",
          "default": "scene_linear",
          "description": "Linear working space shader packages should be able to assume."
        },
        "outputColorSpace": {
          "type": "string",
          "default": "rec709",
          "description": "Output transform target color space for scheduled video output."
        },
        "display": {
          "type": "string",
          "default": "sRGB",
          "description": "OCIO display name for preview/window/display transforms."
        },
        "view": {
          "type": "string",
          "default": "Rec.709",
          "description": "OCIO view name for preview/window/display transforms."
        },
        "look": {
          "type": "string",
          "default": "",
          "description": "Optional OCIO look name."
        },
        "exposure": {
          "type": "number",
          "default": 0,
          "description": "Reserved display transform exposure adjustment."
        },
        "gamma": {
          "type": "number",
          "exclusiveMinimum": 0,
          "default": 1,
          "description": "Reserved display transform gamma adjustment."
        },
        "workingFormat": {
          "type": "string",
          "enum": [
            "rgba16f",
            "rgba32f"
          ],
          "default": "rgba16f",
          "description": "Future render target/intermediate working format."
        },
        "linearWorkingSpace": {
          "type": "boolean",
          "default": true,
          "description": "Documents the intended linear-light working pipeline."
        }
      }
    }
  }
 }
--- a/docs/CURRENT_SYSTEM_ARCHITECTURE.md
+++ b/docs/CURRENT_SYSTEM_ARCHITECTURE.md
@@ -0,0 +1,198 @@
 # Current System Architecture
 This document describes how the current `RenderCadenceCompositor` app works.
 The implementation is cadence-first: the render/output path owns frame timing, while shader compilation, HTTP control, preview, persistence, and video I/O edges stay outside the render cadence loop wherever possible. The guardrails in [Render Cadence Golden Rules](RENDER_CADENCE_GOLDEN_RULES.md) are the operating contract.
 ## Application Shape
 The app is a native C++ OpenGL compositor with:
 - optional DeckLink input
 - optional DeckLink scheduled output
 - a render-thread-owned OpenGL context
 - a pluggable app-side runtime-content controller
 - the default runtime Slang shader package stack from `shaders/`
 - a local HTTP/WebSocket control server
 - optional Win32/GDI preview from system-memory output frames
 - background runtime-state persistence
 - cadence telemetry and log output
 Primary source areas:
 - `src/app`: startup/shutdown orchestration, config loading, video backend factory, runtime-content controller boundary, and the default shader runtime-content controller
 - `src/render`: cadence clock, input texture upload, render-content boundary, readback, and runtime GL support
 - `src/render/thread`: render thread lifecycle, cadence loop, metrics, and runtime shader commit mailbox
 - `src/render/runtime`: render-thread-owned runtime shader scene, renderer, text texture upload cache, and shared-context shader prepare worker
 - `src/frames`: system-memory frame exchange
 - `src/video/core`: generic video IO edge contracts, mode descriptions, formats, and output scheduling thread
 - `src/video/decklink`: current DeckLink input/output backend
 - `src/video/playout`: backend-adjacent playout policy, queues, frame pools, and scheduling helpers
 - `src/video/legacy`: older backend pipeline pieces kept separate from the current app path
 - `src/runtime/catalog`: supported shader catalog and package filtering
 - `src/runtime/layers`: app-side runtime layer model, restore, reload, and render snapshot construction
 - `src/runtime/shader`: background Slang build bridge and prepared shader artifact types
 - `src/runtime/state`: runtime JSON helpers, parameter normalization, and debounced runtime-state persistence
 - `src/runtime/text`: MSDF/MTSDF font atlas build and CPU-side prepared text texture composition
 - `src/control`: command parsing, HTTP/WebSocket transport helpers, OSC status stub, OpenAPI state JSON
 - `src/app/RenderCadenceHttpRoutes.*`: this app's current HTTP endpoint map
 - `src/preview`: optional non-consuming preview window
 - `src/telemetry` and `src/logging`: runtime observation and logging
 ## Startup
 Startup broadly proceeds as:
 1. Load `config/runtime-host.json` through `AppConfigProvider`, then apply CLI overrides.
 2. Initialize the active `IRuntimeContentController`. The checked-in app uses `ShaderRuntimeContentController`, which loads the supported shader catalog, starts runtime-state persistence, and tries to restore `runtime/runtime_state.json`.
 3. If restore fails or no usable state exists, the shader controller falls back to the optional configured startup shader. The checked-in config leaves `runtimeShaderId` empty, so a fresh host keeps the simple fallback renderer.
 4. Start the render thread.
 5. Start the active runtime-content controller. The shader controller queues background Slang builds for every pending active layer.
 6. Build a small completed-frame reserve.
 7. Start optional preview, optional video output, telemetry, and HTTP control.
 The runtime-state restore is intentionally app/control side work. The render thread does not read JSON, inspect the shader library, or decide what to compile.
 ## Runtime Content And Shader Layer State
 `RenderCadenceApp` owns startup, video output, preview, telemetry, OSC status, and HTTP server lifetime. It does not own the Slang shader stack directly. Runtime content plugs in through `IRuntimeContentController`.
 The checked-in implementation is `ShaderRuntimeContentController`. It wraps `RuntimeLayerController`, exposes shader catalog/layer JSON for `/api/state`, handles shader layer POST commands, and publishes render-ready shader layer snapshots to the render thread.
 `RuntimeLayerController` owns the app-side layer model and coordinates:
 - supported shader catalog loading
 - layer add/remove/reorder/bypass/shader assignment
 - parameter update/reset
 - startup restore
 - reload reconciliation
 - background Slang builds
 - render-layer publication
 - runtime-state persistence requests
 `RuntimeLayerModel` owns the in-memory active stack:
 - layer id
 - shader id and display name
 - build state and message
 - bypass state
 - manifest parameter definitions
 - optional shader-declared custom UI metadata
 - current parameter values
 - render-ready artifacts
 The current durable runtime state is stored in `runtime/runtime_state.json`. It contains the active stack order, shader ids, bypass flags, and parameter values. On startup, valid saved layers are restored in order. Missing shader packages are skipped, invalid saved parameter values fall back to manifest defaults, and a missing or unusable file falls back to the optional configured startup shader.
 Manual stack preset routes are present in the UI/OpenAPI surface but are not implemented in the current native command path yet. `runtime_state.json` is the supported latest-working-state mechanism.
 ## Persistence
 `RuntimeStatePersistenceWriter` performs debounced background writes to `runtime/runtime_state.json`.
 Durable UI/API mutations request persistence after they are accepted:
 - add/remove layer
 - reorder layer
 - set bypass
 - set shader
 - update parameter
 - reset parameters
 - reload compatibility refresh
 The mutation path snapshots the current layer model and hands serialized state to the writer. File IO happens on the persistence worker, not on the render thread or cadence path. Shutdown flushes the latest pending snapshot.
 OSC-driven changes are intentionally not part of this autosave path yet.
 The host configuration editor is separate from runtime layer persistence. The UI reads active and saved startup config through `/api/config`, saves `config/runtime-host.json` through `/api/config/save`, and requests a native host restart through `/api/app/restart`. Render cadence, video input/output selection, resolution, frame rate, output pixel format, HTTP port, and preview settings are still startup-owned; they are not hot-swapped inside the cadence path.
 ## Shader Reload
 `POST /api/reload` and the control UI reload button:
 - rescan `shaders/`
 - re-read manifests
 - rebuild the supported shader catalog
 - refresh optional shader custom UI metadata
 - update active layer metadata and parameter definitions from changed manifests
 - preserve compatible parameter values
 - default new or incompatible parameter values
 - queue recompilation for every catalog-valid layer in the active stack
 Reload does not compile every package in the shader library. A package is compiled when it is part of the active layer stack. If an active layer references a shader that no longer exists, that layer is marked failed and skipped. Existing render output remains active where possible until replacement builds are ready.
 `autoReload` is still exposed in config/state for compatibility, but automatic file watching is not currently wired.
 ## Render Ownership
 The render thread owns the app OpenGL context during normal operation.
 The render path consumes published render-layer snapshots. It does not:
 - parse JSON
 - scan files
 - launch Slang
 - run font atlas generation
 - perform persistence
 - handle HTTP or OSC
 - call DeckLink discovery/setup APIs
 When a runtime shader build completes, the default shader runtime-content controller publishes a render-layer artifact. The render thread forwards pending layer snapshots to the active render-content adapter. The default `RuntimeShaderRenderContent` owns the runtime scene, diffs the snapshot, and queues changed pass programs to the shared-context prepare worker. The render thread swaps in an already-prepared render plan at a frame boundary through that adapter.
 ## Video And Preview
 Video input and output are optional edges. `input.backend` and `output.backend` select the concrete backend through the app-side backend factory. DeckLink and NDI are the current concrete backends, and `none` disables an edge. `input` and `output` also carry the device selector plus resolution/frame-rate settings. Configured video modes are represented in `src/video/core` and translated to backend-specific modes only inside the concrete edge.
 The input edge writes CPU frames into `InputFrameMailbox`. The current DeckLink backend captures BGRA8 directly where possible, or raw UYVY8 for render-thread GPU decode. The input edge does not call GL, render, preview, screenshot, shader, or output scheduling code.
 The output edge consumes completed system-memory frames from `SystemFrameExchange`. The render thread owns output pixel packing before readback: BGRA8 is read directly, and UYVY8 is packed on the GPU into a half-width RGBA8 target before async PBO readback. DeckLink and NDI output then schedule/send those completed CPU frames without invoking GL or converting pixels. If video output is unavailable, the app continues running render cadence, control, preview, telemetry, and logging.
 Runtime state exposes backend-neutral output telemetry through `videoOutput`. Portable fields such as `enabled`, `backend`, and `scheduleFailures` stay at that level; backend-specific counters live under `videoOutput.backendMetrics`.
 `PreviewWindowThread` is optional and uses a non-consuming system-memory tap. It paints BGRA8 directly, decodes UYVY8 only for preview presentation, and skips preview ticks instead of blocking the frame exchange.
 Screenshot routes are present in the UI/OpenAPI surface but are not implemented in the current native command path yet.
 ## Control Surface
 The HTTP server runs on its own thread. `HttpControlServer` owns socket lifetime, HTTP parsing, static asset helpers, OpenAPI/Swagger helper serving, and WebSocket state transport. `RenderCadenceHttpRoutes` owns this app's current endpoint map:
 - UI assets
 - shader package custom UI assets under `/shader-assets/{shaderId}/...`
 - OpenAPI/Swagger docs
 - `GET /api/state`
 - `/ws` state updates
 - layer mutation POST routes, dispatched to the active runtime-content controller
 - `/api/reload`
 Known but not implemented in the current native command path:
 - `/api/layers/move`
 - `/api/stack-presets/save`
 - `/api/stack-presets/load`
 - `/api/screenshot`
 Unsupported routes return an action response with `ok: false`.
 Forks can reuse the HTTP/WebSocket shell without keeping these endpoints by installing a different route callback.
 `OscControlServer` is currently a lifecycle/status stub. It consumes startup OSC config, exposes configured/disabled/not-listening state through `/api/state`, and leaves UDP socket receive, OSC decode, and runtime dispatch unimplemented until that ingress boundary is built deliberately.
 ## Tests
 Native tests cover the main non-GL contracts:
 - JSON parsing/serialization
 - runtime parameter normalization
 - shader package registry and Slang validation
 - supported shader catalog
 - runtime layer restore/reload behavior
 - runtime-state persistence writer
 - HTTP transport and app-route dispatch
 - frame exchange and input mailbox behavior
 - video format and scheduling helpers
 Run:
 ```powershell
 cmake --build --preset build-debug --target RUN_TESTS --parallel
 ```
--- a/docs/OSC_CONTROL.md
+++ b/docs/OSC_CONTROL.md
@@ -1,6 +1,6 @@
 # OSC Control
-Video Shader Toys can listen for local OSC messages and map them onto shader layer parameters.
+This is the intended OSC control contract, but OSC ingress is not wired in the current `RenderCadenceCompositor` native host yet. The native host has an OSC service stub that consumes config and reports status in `/api/state`; it does not open a UDP listener or dispatch messages yet. Use the REST layer parameter endpoints or the control UI for live parameter changes today.
 ## Configuration
@@ -8,11 +8,13 @@ Set the UDP port in `config/runtime-host.json`:
 ```json
 {
-  "oscPort": 9000
+  "oscBindAddress": "127.0.0.1",
  "oscPort": 9000,
  "oscSmoothing": 0.18
 }
 ```
-Set `oscPort` to `0` to disable the OSC listener.
+Today, `oscPort: 0` marks the OSC stub disabled and any nonzero port marks it configured but not listening. When OSC ingress is implemented, `oscBindAddress: "127.0.0.1"` should keep OSC local to the host, and `oscBindAddress: "0.0.0.0"` should listen on all IPv4 interfaces. `oscSmoothing` is reserved for a per-frame easing amount on numeric OSC controls.
 ## Address Pattern
@@ -47,6 +49,8 @@ Matching is exact first. If that fails, names are compared in a simplified form
 If multiple layers use the same shader package ID or display name, the first matching layer in the stack is controlled. Use the internal layer ID shown in the UI when you need to target one duplicate layer precisely.
 In the control UI, each parameter row has a small **OSC** button. Clicking it copies that parameter's exact OSC address to the clipboard, which is the safest way to target controls with long names or duplicate shader layers.
 ## Values
 The listener accepts these OSC argument types:
@@ -59,17 +63,21 @@ The listener accepts these OSC argument types:
 Single-argument messages become scalar JSON values. Multi-argument messages become JSON arrays, which lets OSC drive `vec2` and `color` parameters.
 OSC updates are coalesced by target route and applied once per render tick, so rapid controller motion does not force one runtime mutation, disk write, and UI push per incoming UDP packet. Numeric OSC controls can also be slightly smoothed with `oscSmoothing`.
 Examples:
 ```text
 /VideoShaderToys/fisheye-reproject/panDegrees 45.0
 /VideoShaderToys/fisheye-reproject/fisheyeModel "equisolid"
 /VideoShaderToys/video-transform/pan 0.25 -0.5
-/VideoShaderToys/composition-guides/lineColor 1.0 0.8 0.1 1.0
+/VideoShaderToys/safe-area-guides/lineColor 1.0 0.8 0.1 1.0
 ```
 Values are validated with the same shader parameter rules used by the REST API. Invalid values or unknown addresses are ignored and reported to the native debug output.
 OSC-driven parameter changes are not autosaved to `runtime/runtime_state.json`. Stack edits made through the UI and preset operations still persist as before. Smoothing only applies to numeric controls such as floats, `vec2`, and `color`; booleans, enums, text, and triggers stay immediate.
 For `trigger` parameters, the OSC value is treated as a pulse. A simple integer or boolean message is enough:
 ```text
@@ -112,10 +120,21 @@ send('127.0.0.1:9000', '/VideoShaderToys/fisheye-reproject/tiltDegrees', {type:
 ## Network
-The listener binds to localhost only:
+By default the listener binds to localhost only:
 ```text
 127.0.0.1:<oscPort>
 ```
 This keeps the control surface local to the machine running Video Shader Toys.
 To accept OSC from other machines on the network, set:
 ```json
 {
  "oscBindAddress": "0.0.0.0",
  "oscPort": 9000
 }
 ```
 That listens on all IPv4 interfaces, so make sure your firewall and network are configured appropriately.
--- a/docs/RENDER_CADENCE_GOLDEN_RULES.md
+++ b/docs/RENDER_CADENCE_GOLDEN_RULES.md
@@ -0,0 +1,164 @@
 # Render Cadence Golden Rules
 These are the non-negotiable rules for the new render-cadence architecture.
 They exist because the old app drifted into a place where DeckLink timing, render work, shader build work, state coordination, readback, and recovery behavior all influenced each other. The new app should stay boring, explicit, and easy to reason about.
 ## 1. The Render Thread Owns Its Render Context
 Only the render thread may bind and use its primary OpenGL context.
 For a fork that replaces the renderer with D3D or another graphics API, read this rule as the same ownership contract: the cadence/render thread owns the primary render device/context path, and non-render services exchange prepared data with it rather than calling rendering APIs themselves.
 Allowed on the render thread:
 - GL resource creation and destruction for resources it owns
 - GL shader/program swap from an already-prepared GL program
 - drawing the next frame
 - async readback queueing and completion polling
 - publishing completed system-memory frames
 Not allowed on the render thread:
 - Slang compiler invocation
 - manifest scanning/parsing
 - filesystem discovery
 - image/font/LUT decoding
 - persistence
 - network/API/OSC handling
 - DeckLink scheduling
 - blocking console logging
 - config file discovery or parsing
 If GL preparation happens off-thread, use an explicit shared-context GL prepare thread. Do not smuggle non-render work back into the cadence loop.
 ## 2. Render Cadence Does Not Chase Buffers
 The render thread runs at the selected render cadence.
 It must not speed up to fill a DeckLink/system-memory buffer, and it must not slow down because a consumer is late. If the GPU is genuinely overloaded, record that as render overrun telemetry.
 Buffers absorb timing differences. They do not control render cadence.
 ## 3. Video I/O Never Renders
 DeckLink output consumes already-rendered system-memory frames.
 The output/scheduling side may:
 - schedule completed frames
 - release frames after DeckLink completion
 - report late/dropped/schedule telemetry
 - record app-side poll misses
 - conservatively realign the DeckLink schedule cursor after measured timing pressure
 It must not:
 - render fallback frames
 - invoke GL
 - compile shaders
 - block the render cadence waiting for DeckLink
 - continuously rewrite healthy scheduled timestamps
 If no completed frame is available, record the miss and keep the ownership boundary intact.
 Output pixel-format packing that requires GL belongs in the render-owned readback path before frame publication. Video I/O edges may select supported system-memory formats, but they must not invoke GL or become hidden pixel-conversion renderers.
 DeckLink input is also an edge, not a renderer. It may capture/copy the latest supported CPU frame into an input mailbox and update input telemetry, but it must not call GL, schedule output, compile shaders, or drive render cadence. Format decode that requires GL belongs to the render-owned input upload path.
 ## 4. Runtime Build Work Produces Artifacts
 Runtime shader work is split into two phases:
 1. CPU/build phase outside the render thread
 2. shared-context GL preparation outside the render thread where practical
 3. GL program swap on the render thread
 The CPU/build phase may parse manifests, invoke Slang, validate package shape, and prepare CPU-side data.
 The render thread receives completed render-layer artifacts, asks the shared-context prepare worker to compile/link changed GL programs, and only swaps in prepared programs at a frame boundary. A failed artifact or failed GL preparation must not disturb the current renderer.
 The display/render layer model is app-owned. It may track requested shaders, build state, display metadata, and render-ready artifacts, but it must not perform GL work or drive render cadence directly.
 ## 5. No Hidden Blocking In The Cadence Path
 The render loop must not do work with unbounded or OS-dependent latency.
 Examples to avoid:
 - file reads
 - directory scans
 - image decoding
 - process launches
 - waits on worker threads
 - blocking locks around slow code
 - synchronous GPU readback waits
 - console I/O
 Short mutex use for exchanging small already-prepared objects is acceptable. Holding a lock while doing heavy work is not.
 ## 6. System Memory Frames Are A Handoff, Not A Render Driver
 The system-memory frame exchange stores completed frames as a bounded FIFO reserve and protects frames scheduled to DeckLink.
 Render acquire must not evict completed frames that are waiting for playout, and it must never force the render thread to wait for the output side to consume a frame.
 If the completed reserve overflows, the exchange may drop the oldest completed, unscheduled frame and record `completedDrops`. That is an app-side reserve drop, not a DeckLink dropped frame.
 ## 7. Startup Uses Warmup, Not Burst Rendering
 DeckLink playback starts only after the render thread has produced enough real frames for preroll.
 Warmup should happen at normal render cadence. Do not temporarily accelerate the renderer to fill buffers.
 ## 8. Telemetry Must Name Ownership Clearly
 Counters should say which subsystem had the event.
 Good examples:
 - `renderFps`
 - `scheduleFps`
 - `completedPollMisses`
 - `scheduleFailures`
 - `decklinkBuffered`
 - `deckLinkScheduleLeadFrames`
 - `deckLinkScheduleRealignments`
 - `inputCaptureFps`
 - `inputSubmitMs`
 - `inputUploadMs`
 - `inputConvertMs`
 - `shaderCommitted`
 - `shaderFailures`
 Avoid ambiguous names like `underrun` unless it is clear whether it means app-ready underrun, DeckLink buffered-frame underrun, render overrun, or schedule failure.
 ## 9. Keep Files Small And Role-Based
 A file should have one clear reason to change.
 Preferred boundaries:
 - app orchestration
 - render cadence/thread ownership
 - GL rendering
 - runtime artifact build/bridge
 - app-owned display/render layer model
 - parameter packing
 - system-memory frame exchange
 - DeckLink output scheduling
 - telemetry
 - local control/API edge
 - config loading
 - JSON presentation/serialization
 - logging
 If a file starts coordinating multiple subsystems and doing detailed work for each of them, split it before it becomes the new old app.
 ## 10. Prefer Explicit Unsupported States
 If a feature needs storage, timing behavior, or ownership we have not designed yet, reject it clearly.
 For example, in the current new app it is better to reject texture/LUT/text/temporal/feedback shaders than to quietly load files or allocate history state on the render thread.
 Unsupported is healthy when it protects the architecture.
--- a/docs/openapi.yaml
+++ b/docs/openapi.yaml
--- a/runtime/README.md
+++ b/runtime/README.md
@@ -14,11 +14,12 @@ Packaged documentation:
 Generated files:
- `shader_cache/active_shader_wrapper.slang`: generated Slang wrapper for the active shader/layer.
+- `shader_cache/active_shader_wrapper.slang`: generated Slang wrapper for the most recently compiled shader pass.
- `shader_cache/active_shader.raw.frag`: raw GLSL emitted by `slangc`.
+- `shader_cache/active_shader.raw.frag`: raw GLSL emitted by `slangc` for the most recently compiled pass.
- `shader_cache/active_shader.frag`: patched GLSL consumed by the OpenGL path.
+- `shader_cache/active_shader.frag`: patched GLSL consumed by the OpenGL path for the most recently compiled pass.
- `runtime_state.json`: autosaved latest layer stack, layer order, bypass state, shader assignments, and parameter values. The host reloads this file on startup.
+- `runtime_state.json`: debounced autosave of the latest layer stack, layer order, bypass state, shader assignments, and parameter values. The host reloads this file on startup and falls back to the configured default shader if the file is missing or unusable.
- `stack_presets/*.json`: user-saved layer stack presets.
+- `stack_presets/*.json`: planned user-saved layer stack presets. Preset routes are present in the API surface but not implemented in the current native host.
 - `screenshots/*.png`: planned screenshot output. Screenshot capture is present in the API surface but not implemented in the current native host.
 Git policy:
--- a/runtime/templates/shader_wrapper.slang.in
+++ b/runtime/templates/shader_wrapper.slang.in
@@ -19,6 +19,7 @@ struct ShaderContext
 	float bypass;
 	int sourceHistoryLength;
 	int temporalHistoryLength;
 	int feedbackAvailable;
 };
 cbuffer GlobalParams
@@ -34,16 +35,23 @@ cbuffer GlobalParams
 	float gBypass;
 	int gSourceHistoryLength;
 	int gTemporalHistoryLength;
 	int gFeedbackAvailable;
 {{PARAMETER_UNIFORMS}}};
 Sampler2D<float4> gVideoInput;
-{{SOURCE_HISTORY_SAMPLERS}}{{TEMPORAL_HISTORY_SAMPLERS}}{{TEXTURE_SAMPLERS}}
+Sampler2D<float4> gLayerInput;
 {{SOURCE_HISTORY_SAMPLERS}}{{TEMPORAL_HISTORY_SAMPLERS}}{{FEEDBACK_SAMPLER}}{{TEXTURE_SAMPLERS}}
 {{TEXT_SAMPLERS}}
 float4 sampleVideo(float2 tc)
 {
 	return gVideoInput.Sample(tc);
 }
 float4 sampleLayerInput(float2 tc)
 {
 	return gLayerInput.Sample(tc);
 }
 float4 sampleSourceHistory(int framesAgo, float2 tc)
 {
 	if (gSourceHistoryLength <= 0)
@@ -74,6 +82,8 @@ float4 sampleTemporalHistory(int framesAgo, float2 tc)
 	}
 }
 {{FEEDBACK_HELPER}}
 {{TEXT_HELPERS}}
 #include "{{USER_SHADER_INCLUDE}}"
@@ -94,6 +104,7 @@ float4 fragmentMain(FragmentInput input) : SV_Target
 	context.bypass = gBypass;
 	context.sourceHistoryLength = gSourceHistoryLength;
 	context.temporalHistoryLength = gTemporalHistoryLength;
 	context.feedbackAvailable = gFeedbackAvailable;
 	float4 effectedColor = {{ENTRY_POINT_CALL}};
 	float mixValue = clamp(gBypass > 0.5 ? 0.0 : gMixAmount, 0.0, 1.0);
 	return lerp(context.sourceColor, effectedColor, mixValue);
--- a/shaders/SHADER_CONTRACT.md
+++ b/shaders/SHADER_CONTRACT.md
@@ -55,7 +55,7 @@ float4 shadeVideo(ShaderContext context)
 }
 ```
-With `autoReload` enabled in `config/runtime-host.json`, edits to shader source, manifests, and declared texture assets are picked up automatically.
+With `autoReload` enabled in `config/runtime-host.json`, edits to shader source, manifests, and declared texture assets are picked up automatically. You can also use **Reload shaders** in the control UI to manually rescan the shader library.
 ## Guidance For Shaders
@@ -80,7 +80,7 @@ Important rules:
 - If adapting third-party code, include attribution and source URL in the manifest description when the license allows adaptation.
 - If the source license is unclear or incompatible, do not add the shader package.
-Before finishing, compile-check the shader through the runtime wrapper or launch the app and verify the shader appears without an error in the selector.
+Before finishing, compile-check the shader through the runtime wrapper or launch the app and verify the shader appears without an error in the selector. CI also runs shader validation, so every available package in `shaders/` should compile successfully. Intentionally broken examples should stay visibly marked as broken rather than pretending to be production shaders.
 ## Manifest Fields
@@ -97,9 +97,21 @@ Optional fields:
 - `description`: display/help text for the shader library.
 - `category`: UI grouping label.
 - `entryPoint`: Slang function to call. Defaults to `shadeVideo`.
 - `passes`: advanced render-pass declarations. Omit this for normal single-pass shaders.
 - `textures`: texture assets to load and expose as samplers.
 - `fonts`: packaged font assets for live text parameters.
 - `temporal`: history-buffer requirements.
 - `feedback`: optional previous-frame shader-local feedback surface.
 - `ui`: optional custom control UI module for this shader.
 Parameter objects may also include an optional `description` string. The control UI displays it as one-line helper text with the full text available on hover, so use it for short operational guidance rather than long documentation.
 Metadata conventions:
 - Keep `name` short, human-facing, and in title case.
 - Keep `category` consistent with existing library groups such as `Color`, `Transform`, `Projection`, `Temporal`, `Scopes & Guides`, `Utility`, `Feedback`, and `Calibration`.
 - Keep `description` to one clear sentence in present tense that explains what the shader does for an operator.
 - Avoid placeholder, joke, or overly implementation-heavy descriptions unless the shader is intentionally a diagnostic or broken example.
 Shader-visible identifiers must be valid Slang-style identifiers:
@@ -110,6 +122,251 @@ Shader-visible identifiers must be valid Slang-style identifiers:
 Use letters, numbers, and underscores only, and start with a letter or underscore. For example, `logoTexture` is valid; `logo-texture` is not valid as a shader-visible texture ID.
 ## Custom Control UI
 Shaders may optionally declare a custom browser control panel implemented as a standard Web Component. This only changes the bundled React control surface; it does not change shader validation, parameter storage, render cadence, or video I/O behavior.
 Manifest example:
 ```json
 {
  "ui": {
    "type": "webComponent",
    "entry": "ui/controls.js",
    "tag": "my-shader-controls"
  }
 }
 ```
 The `entry` file is loaded as a JavaScript module from:
 ```text
 /shader-assets/{shaderId}/ui/controls.js
 ```
 Rules:
 - `type` must be `webComponent`.
 - `entry` must be a safe relative `.js` or `.mjs` path inside the shader package. Use the package `ui/` directory for UI assets.
 - `tag` must be a valid custom element name with a hyphen, for example `my-shader-controls`.
 - The `entry` file must exist when the manifest is loaded.
 - Custom UI controls must update declared manifest parameters. They cannot create hidden runtime parameters or bypass host validation.
 - The React UI still provides a **Default controls** fallback for each layer.
 Custom element API:
 ```js
 class MyShaderControls extends HTMLElement {
  set layer(value) {}
  set parameters(value) {}
  set values(value) {}
  connectedCallback() {}
 }
 customElements.define("my-shader-controls", MyShaderControls);
 ```
 The host sets these properties whenever layer state changes:
 - `layer`: full layer object from `/api/state`.
 - `parameters`: array of manifest parameter definitions with current `value`.
 - `values`: object keyed by parameter id.
 - `setParameter(id, value)`: updates a declared layer parameter through the same route used by the default controls.
 - `requestReset()`: resets the layer parameters through the normal reset route.
 A custom element may either call the functions directly:
 ```js
 this.setParameter("strength", 0.75);
 this.requestReset();
 ```
 or dispatch events:
 ```js
 this.dispatchEvent(new CustomEvent("shader-parameter-change", {
  detail: { parameterId: "strength", value: 0.75 }
 }));
 this.dispatchEvent(new CustomEvent("shader-reset-parameters"));
 ```
 When the host updates the element's properties, it also dispatches `shader-layer-update` with `{ layer, parameters, values }` in `event.detail`.
 ## Render Passes
 Most shaders should omit `passes`. The runtime then creates one implicit pass:
 ```json
 {
  "id": "main",
  "source": "shader.slang",
  "entryPoint": "shadeVideo",
  "output": "layerOutput"
 }
 ```
 Advanced shaders may declare explicit passes. All passes may live in one `.slang` file by using different `entryPoint` values, or they may be split across multiple source files:
 ```json
 {
  "passes": [
    {
      "id": "blurX",
      "source": "blur-x.slang",
      "entryPoint": "blurHorizontal",
      "inputs": ["layerInput"],
      "output": "blurredX"
    },
    {
      "id": "final",
      "source": "final.slang",
      "entryPoint": "finish",
      "inputs": ["blurredX"],
      "output": "layerOutput"
    }
  ]
 }
 ```
 Pass fields:
 - `id`: required pass identifier. It must be a valid shader identifier and unique inside the package.
 - `source`: required Slang source path relative to the package directory.
 - `entryPoint`: optional Slang function for this pass. Defaults to the package-level `entryPoint`.
 - `inputs`: optional list of named inputs. The first input is used as the pass input texture.
 - `output`: optional output name. Use `layerOutput` for the final visible layer result.
 Pass input names:
 - `layerInput`: the input to this layer, before any of its passes run.
 - `previousPass`: the previous pass output in this layer. If there is no previous pass, this falls back to `layerInput`.
 - Any earlier pass `id` or `output` name from the same layer.
 If `inputs` is omitted, the first pass samples `layerInput` and later passes sample `previousPass`.
 Single-file multipass example:
 ```json
 {
  "passes": [
    {
      "id": "mask",
      "source": "shader.slang",
      "entryPoint": "makeMask",
      "output": "maskBuffer"
    },
    {
      "id": "final",
      "source": "shader.slang",
      "entryPoint": "finish",
      "inputs": ["maskBuffer"],
      "output": "layerOutput"
    }
  ]
 }
 ```
 Pass output names:
 - `layerOutput`: the final visible output of this layer.
 - Any other name creates an intermediate 16-bit float render target that later passes may sample.
 If the final declared pass does not explicitly output `layerOutput`, the runtime still treats that final pass as the visible layer output. Existing single-pass shaders are unaffected.
 ## Feedback Surface
 Shaders may opt in to a persistent previous-frame feedback surface:
 ```json
 {
  "feedback": {
    "enabled": true,
    "writePass": "final"
  }
 }
 ```
 Fields:
 - `enabled`: when `true`, the runtime allocates one persistent `RGBA16F` feedback surface for this shader at the current render resolution.
 - `writePass`: optional pass `id` whose output should become next frame's feedback surface. If omitted, the runtime uses the final declared pass, or the implicit `main` pass for single-pass shaders.
 Behavior:
 - all passes may sample the same previous-frame feedback surface
 - one designated pass writes the next feedback surface
 - feedback is previous-frame state, not same-frame pass chaining
 Guardrails:
 - Feedback is best suited to image-like state such as trails, masks, luminance fields, decay maps, and shader-local analysis buffers.
 - Feedback is not a precise long-term data store. The surface uses `RGBA16F`, so repeated accumulation, exact counters, and tightly packed metadata can drift or clamp over time.
 - The feedback surface is currently filtered like an image, not configured as strict texel-addressed storage. If you reserve texels as data slots, sample them carefully and do not assume exact CPU-style array semantics.
 - Each feedback-enabled layer allocates two full-resolution feedback textures for ping-pong state. This increases VRAM use and adds one extra full-frame feedback copy per rendered frame.
 - In multipass shaders, feedback remains previous-frame state even when a pass also consumes same-frame pass outputs. Do not treat feedback as another same-frame intermediate buffer.
 Single-pass example:
 ```json
 {
  "id": "feedback-glow",
  "name": "Feedback Glow",
  "feedback": {
    "enabled": true
  },
  "parameters": []
 }
 ```
 Multipass example:
 ```json
 {
  "passes": [
    {
      "id": "analysis",
      "source": "shader.slang",
      "entryPoint": "analyzeFrame",
      "output": "analysisBuffer"
    },
    {
      "id": "final",
      "source": "shader.slang",
      "entryPoint": "finishFrame",
      "inputs": ["analysisBuffer"],
      "output": "layerOutput"
    }
  ],
  "feedback": {
    "enabled": true,
    "writePass": "final"
  }
 }
 ```
 The wrapper exposes:
 ```slang
 float4 sampleFeedback(float2 uv);
 ```
 On the first frame, or after a reset, `sampleFeedback` returns transparent black.
 Feedback resets when:
 - a layer bypass state changes
 - a layer changes shader
 - the layer itself is removed
 - a shader is reloaded or recompiled
 - render dimensions change
 - the app restarts
 Ordinary stack add/remove/reorder operations on other layers are intended to preserve feedback state for unchanged feedback-enabled layers.
 So feedback should be treated as live runtime state, not durable saved state.
 ## Slang Entry Point
 Your shader file must implement the manifest `entryPoint`.
@@ -155,6 +412,7 @@ struct ShaderContext
    float bypass;
    int sourceHistoryLength;
    int temporalHistoryLength;
    int feedbackAvailable;
 };
 ```
@@ -163,7 +421,7 @@ Fields:
 - `uv`: normalized texture coordinates, usually `0..1`.
 - `sourceColor`: decoded RGBA source video at `uv`.
 - `inputResolution`: decoded input video resolution in pixels.
- `outputResolution`: shader render resolution in pixels. The current pipeline renders the shader stack at input resolution, then scales the final frame to the configured DeckLink output mode.
+- `outputResolution`: shader render resolution in pixels. The current pipeline renders the shader stack at input resolution, then scales the final frame to the configured video I/O output mode.
 - `time`: elapsed runtime time in seconds.
 - `utcTimeSeconds`: current UTC time of day from the host PC clock, expressed as seconds since UTC midnight.
 - `utcOffsetSeconds`: host PC local UTC offset in seconds. Add this to `utcTimeSeconds` and wrap to `0..86400` to get local time of day.
@@ -173,12 +431,13 @@ Fields:
 - `bypass`: `1.0` when the layer is bypassed, otherwise `0.0`.
 - `sourceHistoryLength`: number of usable source-history frames currently available.
 - `temporalHistoryLength`: number of usable temporal frames currently available for this layer.
 - `feedbackAvailable`: `1` when previous-frame feedback exists for this layer, otherwise `0`.
 Color/precision notes:
 - `context.sourceColor`, `sampleVideo()`, and temporal history samples are display-referred Rec.709-like RGB, not linear-light RGB.
- The host prefers 10-bit DeckLink YUV capture and output when the card/mode supports it, with automatic 8-bit fallback.
+- The current DeckLink backend prefers 10-bit YUV capture and output when the card/mode supports it, with automatic 8-bit fallback. If external keying is enabled, output prefers 10-bit YUVA (`Ay10`) when supported so shader alpha can drive the key signal, then falls back to 8-bit BGRA.
- Internal decoded, layer, composite, output, and temporal render targets are 16-bit floating point, so gradients and LUT work have more headroom than the packed DeckLink byte formats.
+- Internal decoded, layer, composite, output, and temporal render targets are 16-bit floating point, so gradients and LUT work have more headroom than packed byte video I/O formats.
 - Do not add extra Rec.709 or linear conversions unless the shader intentionally documents that behavior.
 ## Helper Functions
@@ -186,17 +445,23 @@ Color/precision notes:
 The wrapper provides:
 ```slang
 float4 sampleLayerInput(float2 uv);
 float4 sampleVideo(float2 uv);
 float4 sampleSourceHistory(int framesAgo, float2 uv);
 float4 sampleTemporalHistory(int framesAgo, float2 uv);
 float4 sampleFeedback(float2 uv);
 ```
-`sampleVideo` samples the live decoded source video.
+`sampleLayerInput` samples the input arriving at this shader layer before any of the layer's own passes run. If this layer follows another shader, it sees that previous shader's output. If this is the first shader layer, it sees the decoded source image.
 `sampleVideo` samples the current pass input texture. In single-pass shaders this is usually the layer input. In multipass shaders it may instead be a named pass output or `previousPass`, depending on the manifest routing for that pass.
 `sampleSourceHistory` samples previous decoded source frames. `framesAgo` is clamped into the available range. If no history is available, it falls back to `sampleVideo`.
 `sampleTemporalHistory` samples previous pre-layer input frames for temporal shaders that request `preLayerInput` history. `framesAgo` is clamped into the available range. If no temporal history is available, it falls back to `sampleVideo`.
 `sampleFeedback` samples the shader-local previous-frame feedback surface. If feedback has not been written yet, it returns transparent black.
 Example:
 ```slang
@@ -207,6 +472,57 @@ float4 shadeVideo(ShaderContext context)
 }
 ```
 Layer-input example:
 ```slang
 float4 finishPass(ShaderContext context)
 {
    float3 baseColor = sampleLayerInput(context.uv).rgb;
    float3 passResult = context.sourceColor.rgb;
    return float4(baseColor + passResult * 0.25, 1.0);
 }
 ```
 Feedback example:
 ```slang
 float4 shadeVideo(ShaderContext context)
 {
    float4 previous = sampleFeedback(context.uv);
    float4 current = context.sourceColor;
    return lerp(current, previous, 0.2);
 }
 ```
 Multipass feedback example:
 ```slang
 float4 analyzeFrame(ShaderContext context)
 {
    float4 previous = sampleFeedback(context.uv);
    float luma = dot(context.sourceColor.rgb, float3(0.2126, 0.7152, 0.0722));
    return float4(lerp(previous.rgb, float3(luma), 0.1), 1.0);
 }
 float4 finishFrame(ShaderContext context)
 {
    float4 analysis = context.sourceColor;
    return float4(analysis.rgb, 1.0);
 }
 ```
 In that multipass case:
 - `analyzeFrame` reads last frame's feedback
 - `finishFrame` receives the same-frame pass output through normal multipass routing
 - the `writePass` decides which pass output becomes next frame's feedback
 That means:
 - use `context.sourceColor` or `sampleVideo()` when you want this pass's routed input
 - use `sampleLayerInput()` when you want the pre-pass layer input
 - use `sampleFeedback()` when you want previous-frame persistent shader-local state
 ## Parameters
 Manifest parameters are exposed to Slang as global values with the same `id`.
@@ -349,6 +665,40 @@ float4 premultipliedText = drawTitleText(textUv, float4(1.0, 1.0, 1.0, 1.0));
 Text is currently limited to printable ASCII. `maxLength` defaults to `64` and is clamped to `1..256`. The optional `font` field references a packaged font declared in `fonts`; if no font is specified, the runtime uses its fallback sans-serif renderer.
 Text parameters can also choose their font from an enum parameter by setting `fontParameter` to that enum parameter's `id`:
 ```json
 {
  "fonts": [
    { "id": "inter", "path": "fonts/Inter-Regular.ttf" },
    { "id": "mono", "path": "fonts/Mono-Regular.ttf" }
  ],
  "parameters": [
    {
      "id": "font",
      "label": "Font",
      "type": "enum",
      "default": "inter",
      "options": [
        { "value": "inter", "label": "Inter" },
        { "value": "mono", "label": "Mono" }
      ]
    },
    {
      "id": "titleText",
      "label": "Title",
      "type": "text",
      "default": "LIVE",
      "font": "inter",
      "fontParameter": "font",
      "maxLength": 64
    }
  ]
 }
 ```
 Every option `value` in the font selector enum must match a declared font asset `id`. The `font` field remains useful as the default/fallback font for the text parameter, while `fontParameter` lets operators switch atlases at runtime without adding shader-specific code.
 Trigger example:
 ```json
@@ -376,6 +726,7 @@ Parameter validation:
 - `color` must have exactly 4 numbers.
 - Enum defaults must match one of the declared option values.
 - Text defaults must be strings. Non-printable characters are dropped and values are clamped to `maxLength`.
 - Text `fontParameter` values must reference an enum parameter whose option values are declared font asset IDs.
 - Trigger values are incremented by the host when triggered. The shader sees the trigger count and last trigger time.
 - Non-finite numeric values are rejected.
@@ -547,6 +898,8 @@ When a shader compiles, the runtime writes generated files under `runtime/shader
 These files are ignored by git and are useful for debugging compiler output. If a shader fails to compile, inspect the wrapper first; it shows the exact generated Slang code including your included shader.
 For multipass shaders, these files reflect the most recently compiled pass. If a package has several passes, the reported compile error and pass name are usually more useful than assuming the cache contains the first pass.
 ## Common Pitfalls
 - Do not use hyphens in parameter IDs, texture IDs, or entry point names.
@@ -555,6 +908,7 @@ These files are ignored by git and are useful for debugging compiler output. If
 - Remember enum globals are integer indexes, not strings.
 - Declare every texture in `shader.json`; undeclared texture samplers will not be bound.
 - Declare packaged fonts in `shader.json` when text parameters should use a specific font.
 - For selectable fonts, use a text parameter `fontParameter` that points at an enum whose option values are font IDs.
 - Keep temporal history requests modest. They consume texture units and memory and are capped by runtime config.
 - If a parameter appears in the UI but not in Slang, the shader may still compile, but the control has no effect.
 - If a Slang name collides with a generated global, rename your parameter or local symbol.
@@ -570,5 +924,7 @@ Before committing a new shader package:
 - Texture files referenced by `textures` exist.
 - Font files referenced by `fonts` exist.
 - Enum defaults are present in their `options`.
 - Text `fontParameter` selectors reference valid font assets through their enum options.
 - Custom UI entries, when present, load from a safe package-relative JavaScript module and register the declared web component tag.
 - Temporal shaders handle short or empty history gracefully.
 - The app can reload and compile the shader without errors.
--- a/shaders/anamorphic-desqueeze/shader.json
+++ b/shaders/anamorphic-desqueeze/shader.json
@@ -11,11 +11,24 @@
      "type": "enum",
      "default": "x1_33",
      "options": [
-        { "value": "x1_3", "label": "1.3x" },
+        {
-        { "value": "x1_33", "label": "1.33x" },
+          "value": "x1_3",
-        { "value": "x1_5", "label": "1.5x" },
+          "label": "1.3x"
-        { "value": "x2_0", "label": "2x" }
+        },
-      ]
+        {
          "value": "x1_33",
          "label": "1.33x"
        },
        {
          "value": "x1_5",
          "label": "1.5x"
        },
        {
          "value": "x2_0",
          "label": "2x"
        }
      ],
      "description": "Horizontal stretch factor matching the anamorphic lens or adapter."
    },
    {
      "id": "framing",
@@ -23,24 +36,50 @@
      "type": "enum",
      "default": "fit",
      "options": [
-        { "value": "fit", "label": "Fit" },
+        {
-        { "value": "fill", "label": "Fill" }
+          "value": "fit",
-      ]
+          "label": "Fit"
        },
        {
          "value": "fill",
          "label": "Fill"
        }
      ],
      "description": "Fit preserves the whole image; Fill crops to remove borders."
    },
    {
      "id": "pan",
      "label": "Pan",
      "type": "vec2",
-      "default": [0.0, 0.0],
+      "default": [
-      "min": [-1.0, -1.0],
+        0,
-      "max": [1.0, 1.0],
+        0
-      "step": [0.001, 0.001]
+      ],
      "min": [
        -1,
        -1
      ],
      "max": [
        1,
        1
      ],
      "step": [
        0.001,
        0.001
      ],
      "description": "Reframes the desqueezed image after fit/fill scaling."
    },
    {
      "id": "outsideColor",
      "label": "Outside Color",
      "type": "color",
-      "default": [0.0, 0.0, 0.0, 1.0]
+      "default": [
        0,
        0,
        0,
        1
      ],
      "description": "Color used where the remapped image samples outside the source frame."
    }
  ]
 }
--- a/shaders/balatro-swirl/shader.json
+++ b/shaders/balatro-swirl/shader.json
@@ -9,37 +9,41 @@
      "id": "spinRotation",
      "label": "Spin Rotation",
      "type": "float",
-      "default": -2.0,
+      "default": -2,
-      "min": -8.0,
+      "min": -8,
-      "max": 8.0,
+      "max": 8,
-      "step": 0.05
+      "step": 0.05,
      "description": "Base rotation applied to the swirl field."
    },
    {
      "id": "spinSpeed",
      "label": "Spin Speed",
      "type": "float",
-      "default": 7.0,
+      "default": 7,
-      "min": 0.0,
+      "min": 0,
-      "max": 20.0,
+      "max": 20,
-      "step": 0.1
+      "step": 0.1,
      "description": "How quickly the swirl pattern rotates."
    },
    {
      "id": "spinAmount",
      "label": "Spin Amount",
      "type": "float",
      "default": 0.25,
-      "min": 0.0,
+      "min": 0,
-      "max": 1.0,
+      "max": 1,
-      "step": 0.01
+      "step": 0.01,
      "description": "Amount of radial twisting in the swirl."
    },
    {
      "id": "spinEase",
      "label": "Spin Ease",
      "type": "float",
-      "default": 1.0,
+      "default": 1,
-      "min": 0.0,
+      "min": 0,
-      "max": 3.0,
+      "max": 3,
-      "step": 0.01
+      "step": 0.01,
      "description": "Changes how strongly the twist falls off from the center."
    },
    {
      "id": "contrast",
@@ -47,59 +51,94 @@
      "type": "float",
      "default": 3.5,
      "min": 0.5,
-      "max": 8.0,
+      "max": 8,
-      "step": 0.05
+      "step": 0.05,
      "description": "Adjusts separation between dark and bright areas."
    },
    {
      "id": "lighting",
      "label": "Lighting",
      "type": "float",
      "default": 0.4,
-      "min": 0.0,
+      "min": 0,
      "max": 1.5,
-      "step": 0.01
+      "step": 0.01,
      "description": "Strength of the highlight/shadow modulation."
    },
    {
      "id": "offset",
      "label": "Offset",
      "type": "vec2",
-      "default": [0.0, 0.0],
+      "default": [
-      "min": [-1.0, -1.0],
+        0,
-      "max": [1.0, 1.0],
+        0
-      "step": [0.001, 0.001]
+      ],
      "min": [
        -1,
        -1
      ],
      "max": [
        1,
        1
      ],
      "step": [
        0.001,
        0.001
      ],
      "description": "Moves the generated field in normalized coordinates."
    },
    {
      "id": "colour1",
      "label": "Colour 1",
      "type": "color",
-      "default": [0.871, 0.267, 0.231, 1.0]
+      "default": [
        0.871,
        0.267,
        0.231,
        1
      ],
      "description": "Primary warm swirl color."
    },
    {
      "id": "colour2",
      "label": "Colour 2",
      "type": "color",
-      "default": [0.0, 0.42, 0.706, 1.0]
+      "default": [
        0,
        0.42,
        0.706,
        1
      ],
      "description": "Secondary cool swirl color."
    },
    {
      "id": "colour3",
      "label": "Colour 3",
      "type": "color",
-      "default": [0.086, 0.137, 0.145, 1.0]
+      "default": [
        0.086,
        0.137,
        0.145,
        1
      ],
      "description": "Dark base color in the swirl."
    },
    {
      "id": "isRotate",
      "label": "Rotate Field",
      "type": "bool",
-      "default": false
+      "default": false,
      "description": "Rotates the whole generated field over time."
    },
    {
      "id": "sourceMix",
      "label": "Source Mix",
      "type": "float",
-      "default": 0.0,
+      "default": 0,
-      "min": 0.0,
+      "min": 0,
-      "max": 1.0,
+      "max": 1,
-      "step": 0.01
+      "step": 0.01,
      "description": "Blends the generated effect with the incoming video."
    }
  ]
 }
--- a/shaders/balatro-swirl/shader.slang
+++ b/shaders/balatro-swirl/shader.slang
@@ -6,6 +6,8 @@ float4 balatroSwirl(float2 screenSize, float2 screenCoords, float time, float se
 	float2 uv = (screenCoords - 0.5 * screenSize) / safeScreenLength - offset - seedOffset;
 	float uvLength = length(uv);
 	// First warp: convert to polar space and twist the angle more near the
 	// center, creating the large spiral motion.
 	float speed = spinRotation * spinEase * 0.2;
 	if (isRotate)
 		speed = time * speed;
@@ -19,6 +21,8 @@ float4 balatroSwirl(float2 screenSize, float2 screenCoords, float time, float se
 	speed = (time + seed * 17.0) * spinSpeed;
 	float2 uv2 = float2(uv.x + uv.y, uv.x + uv.y);
 	// Second warp: a short iterative feedback loop turns the spiral into
 	// painterly bands while preserving a fixed compile-time loop bound.
 	for (int i = 0; i < 5; ++i)
 	{
 		uv2 += float2(sin(max(uv.x, uv.y)), sin(max(uv.x, uv.y))) + uv;
@@ -32,6 +36,8 @@ float4 balatroSwirl(float2 screenSize, float2 screenCoords, float time, float se
 	float c1p = max(0.0, 1.0 - contrastMod * abs(1.0 - paintRes));
 	float c2p = max(0.0, 1.0 - contrastMod * abs(paintRes));
 	float c3p = 1.0 - min(1.0, c1p + c2p);
 	// Three soft band weights drive the palette; lighting rides on the brightest
 	// bands so the swirl keeps dimensional highlights.
 	float light = (lighting - 0.2) * max(c1p * 5.0 - 4.0, 0.0) + lighting * max(c2p * 5.0 - 4.0, 0.0);
 	float safeContrast = max(contrast, 0.001);
--- a/shaders/broken-shader-example/shader.json
+++ b/shaders/broken-shader-example/shader.json
@@ -9,7 +9,8 @@
      "id": "badToggle",
      "label": "Bad Toggle",
      "type": "boolean",
-      "default": true
+      "default": true,
      "description": "Intentionally unsupported parameter type used to test shader error handling."
    }
  ]
 }
--- a/shaders/composition-guides/shader.json
+++ b/shaders/composition-guides/shader.json
@@ -9,55 +9,67 @@
      "id": "showThirds",
      "label": "Rule of Thirds",
      "type": "bool",
-      "default": true
+      "default": true,
      "description": "Shows vertical and horizontal thirds lines."
    },
    {
      "id": "showCrosshair",
      "label": "Center Crosshair",
      "type": "bool",
-      "default": true
+      "default": true,
      "description": "Shows a center crosshair for lens/framing alignment."
    },
    {
      "id": "lineColor",
      "label": "Line Color",
      "type": "color",
-      "default": [1.0, 1.0, 1.0, 1.0]
+      "default": [
        1,
        1,
        1,
        1
      ],
      "description": "Color used for guide lines and marks."
    },
    {
      "id": "lineOpacity",
      "label": "Line Opacity",
      "type": "float",
      "default": 0.65,
-      "min": 0.0,
+      "min": 0,
-      "max": 1.0,
+      "max": 1,
-      "step": 0.01
+      "step": 0.01,
      "description": "Overall visibility of the guide lines."
    },
    {
      "id": "lineThicknessPixels",
      "label": "Line Thickness",
      "type": "float",
-      "default": 2.0,
+      "default": 2,
      "min": 0.5,
-      "max": 12.0,
+      "max": 12,
-      "step": 0.1
+      "step": 0.1,
      "description": "Guide line width in output pixels."
    },
    {
      "id": "crosshairSizePixels",
      "label": "Crosshair Size",
      "type": "float",
-      "default": 54.0,
+      "default": 54,
-      "min": 8.0,
+      "min": 8,
-      "max": 240.0,
+      "max": 240,
-      "step": 1.0
+      "step": 1,
      "description": "Length of each crosshair arm in output pixels."
    },
    {
      "id": "crosshairGapPixels",
      "label": "Crosshair Gap",
      "type": "float",
-      "default": 10.0,
+      "default": 10,
-      "min": 0.0,
+      "min": 0,
-      "max": 80.0,
+      "max": 80,
-      "step": 1.0
+      "step": 1,
      "description": "Empty gap around the exact frame center."
    }
  ]
 }
--- a/shaders/crt-bulge/shader.json
+++ b/shaders/crt-bulge/shader.json
@@ -0,0 +1,102 @@
 {
  "id": "crt-bulge",
  "name": "CRT Bulge",
  "description": "Warps the image like convex CRT glass, with optional rounded screen edges and vignette darkening.",
  "category": "Distortion",
  "entryPoint": "shadeVideo",
  "parameters": [
    {
      "id": "bulgeAmount",
      "label": "Bulge",
      "type": "float",
      "default": -0.04,
      "min": -0.5,
      "max": 0.8,
      "step": 0.01,
      "description": "Positive values swell the center outward; negative values pinch it inward."
    },
    {
      "id": "zoom",
      "label": "Zoom",
      "type": "float",
      "default": 1.04,
      "min": 0.5,
      "max": 2,
      "step": 0.01,
      "description": "Scales the source before distortion, useful for hiding warped edges."
    },
    {
      "id": "edgeRoundness",
      "label": "Edge Roundness",
      "type": "float",
      "default": 0.08,
      "min": 0,
      "max": 0.35,
      "step": 0.01,
      "description": "Rounds the visible screen corners like older CRT glass."
    },
    {
      "id": "edgeFeather",
      "label": "Edge Feather",
      "type": "float",
      "default": 2,
      "min": 0,
      "max": 24,
      "step": 0.1,
      "description": "Softens the rounded screen edge in pixels."
    },
    {
      "id": "sourceEdgeFeather",
      "label": "Source Edge Feather",
      "type": "float",
      "default": 1.5,
      "min": 0,
      "max": 16,
      "step": 0.1,
      "description": "Antialiases warped source edges when the distortion reveals outside-frame pixels."
    },
    {
      "id": "vignetteAmount",
      "label": "Vignette",
      "type": "float",
      "default": 0.18,
      "min": 0,
      "max": 1,
      "step": 0.01,
      "description": "Darkens the glass toward the screen edges."
    },
    {
      "id": "edgeMode",
      "label": "Edge Mode",
      "type": "enum",
      "default": "black",
      "options": [
        {
          "value": "black",
          "label": "Black"
        },
        {
          "value": "clamp",
          "label": "Clamp"
        },
        {
          "value": "mirror",
          "label": "Mirror"
        }
      ],
      "description": "Chooses how warped samples outside the source frame are filled."
    },
    {
      "id": "outsideColor",
      "label": "Outside Color",
      "type": "color",
      "default": [
        0,
        0,
        0,
        1
      ],
      "description": "Color used outside the curved screen or source frame."
    }
  ]
 }
--- a/shaders/crt-bulge/shader.slang
+++ b/shaders/crt-bulge/shader.slang
@@ -0,0 +1,71 @@
 float mirroredCoordinate(float coordinate)
 {
 	float wrapped = frac(coordinate * 0.5) * 2.0;
 	return wrapped <= 1.0 ? wrapped : 2.0 - wrapped;
 }
 float roundedBoxMask(float2 point, float2 halfSize, float radius, float feather)
 {
 	float2 distanceToEdge = abs(point) - (halfSize - radius);
 	float outsideDistance = length(max(distanceToEdge, float2(0.0, 0.0))) - radius;
 	float insideDistance = min(max(distanceToEdge.x, distanceToEdge.y), 0.0);
 	float signedDistance = outsideDistance + insideDistance;
 	return 1.0 - smoothstep(0.0, max(feather, 0.00001), signedDistance);
 }
 float sourceBoundsMask(float2 uv, float2 resolution)
 {
 	float2 pixel = 1.0 / max(resolution, float2(1.0, 1.0));
 	float2 feather = pixel * max(sourceEdgeFeather, 0.0);
 	float left = smoothstep(0.0, max(feather.x, 0.00001), uv.x);
 	float right = 1.0 - smoothstep(1.0 - max(feather.x, 0.00001), 1.0, uv.x);
 	float top = smoothstep(0.0, max(feather.y, 0.00001), uv.y);
 	float bottom = 1.0 - smoothstep(1.0 - max(feather.y, 0.00001), 1.0, uv.y);
 	return saturate(left * right * top * bottom);
 }
 float2 applyBulge(float2 uv, float2 resolution)
 {
 	float2 centered = uv * 2.0 - 1.0;
 	float aspect = resolution.x / max(resolution.y, 1.0);
 	float2 aspectCentered = float2(centered.x * aspect, centered.y);
 	float radiusSq = dot(aspectCentered, aspectCentered);
 	float amount = clamp(bulgeAmount, -0.95, 0.95);
 	float scale = 1.0 / max(1.0 + amount * radiusSq, 0.05);
 	return centered * scale / max(zoom, 0.001) * 0.5 + 0.5;
 }
 float4 sampleWarped(float2 uv, float2 resolution, out bool insideSource)
 {
 	insideSource = uv.x >= 0.0 && uv.x <= 1.0 && uv.y >= 0.0 && uv.y <= 1.0;
 	if (edgeMode == 1)
 		return sampleLayerInput(clamp(uv, 0.0, 1.0));
 	if (edgeMode == 2)
 		return sampleLayerInput(float2(mirroredCoordinate(uv.x), mirroredCoordinate(uv.y)));
 	float edgeMask = sourceBoundsMask(uv, resolution);
 	float4 color = sampleLayerInput(clamp(uv, 0.0, 1.0));
 	return lerp(outsideColor, color, edgeMask);
 }
 float4 shadeVideo(ShaderContext context)
 {
 	float2 resolution = max(context.outputResolution, float2(1.0, 1.0));
 	float2 sourceUv = applyBulge(context.uv, resolution);
 	bool insideSource = false;
 	float4 color = sampleWarped(sourceUv, resolution, insideSource);
 	float2 centered = context.uv * 2.0 - 1.0;
 	float feather = max(edgeFeather, 0.0) / min(resolution.x, resolution.y);
 	float screenMask = roundedBoxMask(centered, float2(1.0, 1.0), saturate(edgeRoundness), feather);
 	color = lerp(outsideColor, color, screenMask);
 	float2 aspectCentered = float2(centered.x * resolution.x / max(resolution.y, 1.0), centered.y);
 	float edgeDistance = saturate(length(aspectCentered) * 0.72);
 	float vignette = lerp(1.0, 1.0 - saturate(vignetteAmount), smoothstep(0.35, 1.05, edgeDistance));
 	color.rgb *= vignette;
 	return saturate(color);
 }
--- a/shaders/data-mosh/shader.json
+++ b/shaders/data-mosh/shader.json
@@ -15,36 +15,52 @@
      "label": "Amount",
      "type": "float",
      "default": 0.45,
-      "min": 0.0,
+      "min": 0,
-      "max": 1.0,
+      "max": 1,
-      "step": 0.01
+      "step": 0.01,
      "description": "Strength of the blocky temporal smear."
    },
    {
      "id": "blockCount",
      "label": "Block Count",
      "type": "vec2",
-      "default": [32.0, 18.0],
+      "default": [
-      "min": [2.0, 2.0],
+        32,
-      "max": [160.0, 120.0],
+        18
-      "step": [1.0, 1.0]
+      ],
      "min": [
        2,
        2
      ],
      "max": [
        160,
        120
      ],
      "step": [
        1,
        1
      ],
      "description": "Number of glitch blocks across X and Y."
    },
    {
      "id": "tearAmount",
      "label": "Tear",
      "type": "float",
      "default": 0.18,
-      "min": 0.0,
+      "min": 0,
-      "max": 1.0,
+      "max": 1,
-      "step": 0.01
+      "step": 0.01,
      "description": "Horizontal scanline tearing intensity."
    },
    {
      "id": "chromaShift",
      "label": "Chroma Shift",
      "type": "float",
      "default": 1.8,
-      "min": 0.0,
+      "min": 0,
-      "max": 12.0,
+      "max": 12,
-      "step": 0.1
+      "step": 0.1,
      "description": "Separate color-channel offset in pixels."
    }
  ]
 }
--- a/shaders/dvd-bounce/shader.json
+++ b/shaders/dvd-bounce/shader.json
@@ -18,7 +18,8 @@
      "default": 0.28,
      "min": 0.12,
      "max": 0.5,
-      "step": 0.01
+      "step": 0.01,
      "description": "Logo size relative to the frame."
    },
    {
      "id": "bounceSpeed",
@@ -27,34 +28,38 @@
      "default": 0.22,
      "min": 0.02,
      "max": 0.8,
-      "step": 0.01
+      "step": 0.01,
      "description": "How fast the logo moves between edge hits."
    },
    {
      "id": "edgePadding",
      "label": "Edge Padding",
      "type": "float",
      "default": 0.018,
-      "min": 0.0,
+      "min": 0,
      "max": 0.08,
-      "step": 0.001
+      "step": 0.001,
      "description": "Inset distance from the frame edges."
    },
    {
      "id": "glowAmount",
      "label": "Glow",
      "type": "float",
      "default": 0.18,
-      "min": 0.0,
+      "min": 0,
      "max": 0.75,
-      "step": 0.01
+      "step": 0.01,
      "description": "Adds a soft colored glow around the logo."
    },
    {
      "id": "baseAlpha",
      "label": "Alpha",
      "type": "float",
-      "default": 1.0,
+      "default": 1,
      "min": 0.05,
-      "max": 1.0,
+      "max": 1,
-      "step": 0.01
+      "step": 0.01,
      "description": "Overall opacity of the overlay."
    }
  ]
 }
--- a/shaders/ether/shader.json
+++ b/shaders/ether/shader.json
@@ -9,10 +9,11 @@
      "id": "speed",
      "label": "Speed",
      "type": "float",
-      "default": 1.0,
+      "default": 1,
-      "min": 0.0,
+      "min": 0,
-      "max": 4.0,
+      "max": 4,
-      "step": 0.01
+      "step": 0.01,
      "description": "Animation speed multiplier; set to 0 to pause motion."
    },
    {
      "id": "depth",
@@ -20,65 +21,95 @@
      "type": "float",
      "default": 2.5,
      "min": 0.2,
-      "max": 8.0,
+      "max": 8,
-      "step": 0.01
+      "step": 0.01,
      "description": "Raymarch depth through the ether volume."
    },
    {
      "id": "density",
      "label": "Density",
      "type": "float",
      "default": 0.7,
-      "min": 0.0,
+      "min": 0,
-      "max": 2.0,
+      "max": 2,
-      "step": 0.01
+      "step": 0.01,
      "description": "Density of the volumetric strands."
    },
    {
      "id": "brightness",
      "label": "Brightness",
      "type": "float",
-      "default": 1.0,
+      "default": 1,
-      "min": 0.0,
+      "min": 0,
-      "max": 3.0,
+      "max": 3,
-      "step": 0.01
+      "step": 0.01,
      "description": "Adjusts the generated effect brightness."
    },
    {
      "id": "contrast",
      "label": "Contrast",
      "type": "float",
-      "default": 1.0,
+      "default": 1,
      "min": 0.25,
-      "max": 3.0,
+      "max": 3,
-      "step": 0.01
+      "step": 0.01,
      "description": "Adjusts separation between dark and bright areas."
    },
    {
      "id": "offset",
      "label": "Offset",
      "type": "vec2",
-      "default": [0.9, 0.5],
+      "default": [
-      "min": [0.0, 0.0],
+        0.9,
-      "max": [2.0, 2.0],
+        0.5
-      "step": [0.001, 0.001]
+      ],
      "min": [
        0,
        0
      ],
      "max": [
        2,
        2
      ],
      "step": [
        0.001,
        0.001
      ],
      "description": "Moves the generated field in normalized coordinates."
    },
    {
      "id": "baseColor",
      "label": "Base Color",
      "type": "color",
-      "default": [0.1, 0.3, 0.4, 1.0]
+      "default": [
        0.1,
        0.3,
        0.4,
        1
      ],
      "description": "Low-energy color used in the generated field."
    },
    {
      "id": "energyColor",
      "label": "Energy Color",
      "type": "color",
-      "default": [1.0, 0.5, 0.6, 1.0]
+      "default": [
        1,
        0.5,
        0.6,
        1
      ],
      "description": "High-energy color used in the generated field."
    },
    {
      "id": "sourceMix",
      "label": "Source Mix",
      "type": "float",
-      "default": 0.0,
+      "default": 0,
-      "min": 0.0,
+      "min": 0,
-      "max": 1.0,
+      "max": 1,
-      "step": 0.01
+      "step": 0.01,
      "description": "Blends the generated effect with the incoming video."
    }
  ]
 }
--- a/shaders/false-color/shader.json
+++ b/shaders/false-color/shader.json
@@ -9,34 +9,38 @@
      "id": "blendAmount",
      "label": "Blend",
      "type": "float",
-      "default": 1.0,
+      "default": 1,
-      "min": 0.0,
+      "min": 0,
-      "max": 1.0,
+      "max": 1,
-      "step": 0.01
+      "step": 0.01,
      "description": "Mix amount for the processed result."
    },
    {
      "id": "showLuma",
      "label": "Show Luma",
      "type": "bool",
-      "default": false
+      "default": false,
      "description": "Shows grayscale luminance before applying false-color mapping."
    },
    {
      "id": "lift",
      "label": "Lift",
      "type": "float",
-      "default": 0.0,
+      "default": 0,
      "min": -0.25,
      "max": 0.25,
-      "step": 0.001
+      "step": 0.001,
      "description": "Offsets luminance before false-color mapping."
    },
    {
      "id": "gain",
      "label": "Gain",
      "type": "float",
-      "default": 1.0,
+      "default": 1,
      "min": 0.25,
-      "max": 2.0,
+      "max": 2,
-      "step": 0.01
+      "step": 0.01,
      "description": "Scales luminance before false-color mapping."
    }
  ]
 }
--- a/shaders/feedback-data-blocks/shader.json
+++ b/shaders/feedback-data-blocks/shader.json
@@ -0,0 +1,66 @@
 {
  "id": "feedback-data-blocks",
  "name": "Feedback Data Blocks",
  "description": "Demonstrates coarse shader-local data storage by reserving eight 3x3 feedback cells for sampled colors and one hidden metadata cell for refresh state.",
  "category": "Feedback",
  "entryPoint": "storeProbeData",
  "passes": [
    {
      "id": "store",
      "source": "shader.slang",
      "entryPoint": "storeProbeData",
      "output": "dataBuffer"
    },
    {
      "id": "display",
      "source": "shader.slang",
      "entryPoint": "displayProbeData",
      "inputs": [
        "dataBuffer"
      ],
      "output": "layerOutput"
    }
  ],
  "feedback": {
    "enabled": true,
    "writePass": "store"
  },
  "parameters": [
    {
      "id": "refresh",
      "label": "Refresh",
      "type": "trigger",
      "description": "Forces the stored probe colors to resample immediately."
    },
    {
      "id": "refreshSeconds",
      "label": "Refresh Seconds",
      "type": "float",
      "default": 15.0,
      "min": 1.0,
      "max": 60.0,
      "step": 0.1,
      "description": "Automatic interval for resampling all stored probe colors."
    },
    {
      "id": "overlayOpacity",
      "label": "Overlay Opacity",
      "type": "float",
      "default": 1.0,
      "min": 0.0,
      "max": 1.0,
      "step": 0.01,
      "description": "Strength of the swatch overlay drawn from the stored data cells."
    },
    {
      "id": "swatchSize",
      "label": "Swatch Size",
      "type": "vec2",
      "default": [0.045, 0.055],
      "min": [0.02, 0.02],
      "max": [0.12, 0.12],
      "step": [0.001, 0.001],
      "description": "Size of the top-left preview swatches that show the stored cell values."
    }
  ]
 }
--- a/shaders/feedback-data-blocks/shader.slang
+++ b/shaders/feedback-data-blocks/shader.slang
@@ -0,0 +1,152 @@
 static const int kProbeCount = 8;
 static const int kMetadataIndex = 8;
 float2 probeUvForIndex(int index)
 {
    if (index == 0)
        return float2(0.18, 0.28);
    if (index == 1)
        return float2(0.39, 0.28);
    if (index == 2)
        return float2(0.61, 0.28);
    if (index == 3)
        return float2(0.82, 0.28);
    if (index == 4)
        return float2(0.18, 0.72);
    if (index == 5)
        return float2(0.39, 0.72);
    if (index == 6)
        return float2(0.61, 0.72);
    return float2(0.82, 0.72);
 }
 float2 cellCenterPixelForIndex(int index)
 {
    return float2(1.0 + float(index) * 3.0, 1.0);
 }
 float2 cellCenterUvForIndex(ShaderContext context, int index)
 {
    return (cellCenterPixelForIndex(index) + 0.5) / context.outputResolution;
 }
 bool pixelIsInsideCell(float2 pixelCoord, int index)
 {
    float minX = float(index) * 3.0;
    float maxX = minX + 3.0;
    return pixelCoord.x >= minX && pixelCoord.x < maxX && pixelCoord.y >= 0.0 && pixelCoord.y < 3.0;
 }
 float4 readStoredCell(ShaderContext context, int index)
 {
    if (context.feedbackAvailable <= 0)
        return float4(0.0, 0.0, 0.0, 0.0);
    return sampleFeedback(cellCenterUvForIndex(context, index));
 }
 bool shouldRefreshStoredData(ShaderContext context)
 {
    if (context.feedbackAvailable <= 0)
        return true;
    float4 metadata = readStoredCell(context, kMetadataIndex);
    float previousRefreshBucket = metadata.r;
    float previousTriggerCount = metadata.g;
    float refreshInterval = max(refreshSeconds, 0.001);
    float currentRefreshBucket = floor(context.time / refreshInterval);
    float currentTriggerCount = float(refresh);
    return currentRefreshBucket > previousRefreshBucket + 0.5 || currentTriggerCount > previousTriggerCount + 0.5;
 }
 float4 metadataValueForFrame(ShaderContext context, bool refreshNow)
 {
    float refreshInterval = max(refreshSeconds, 0.001);
    float currentRefreshBucket = floor(context.time / refreshInterval);
    float currentTriggerCount = float(refresh);
    if (!refreshNow && context.feedbackAvailable > 0)
        return readStoredCell(context, kMetadataIndex);
    return float4(currentRefreshBucket, currentTriggerCount, refreshTime, 1.0);
 }
 float4 storedProbeValueForFrame(ShaderContext context, int index, bool refreshNow)
 {
    float3 liveColor = sampleLayerInput(probeUvForIndex(index)).rgb;
    if (refreshNow || context.feedbackAvailable <= 0)
        return float4(liveColor, 1.0);
    return readStoredCell(context, index);
 }
 float4 storeProbeData(ShaderContext context)
 {
    // Reserve nine 3x3 texel cells along the top edge of the feedback surface:
    // eight cells for visible probe colors and one hidden metadata cell that
    // tracks the timed refresh bucket and last trigger count.
    float2 pixelCoord = floor(context.uv * context.outputResolution);
    bool refreshNow = shouldRefreshStoredData(context);
    for (int index = 0; index < kProbeCount; ++index)
    {
        if (pixelIsInsideCell(pixelCoord, index))
            return storedProbeValueForFrame(context, index, refreshNow);
    }
    if (pixelIsInsideCell(pixelCoord, kMetadataIndex))
        return metadataValueForFrame(context, refreshNow);
    return float4(0.0, 0.0, 0.0, 1.0);
 }
 float rectMask(float2 uv, float2 minUv, float2 maxUv)
 {
    if (uv.x < minUv.x || uv.x > maxUv.x)
        return 0.0;
    if (uv.y < minUv.y || uv.y > maxUv.y)
        return 0.0;
    return 1.0;
 }
 float borderMask(float2 uv, float2 minUv, float2 maxUv, float thickness)
 {
    float outer = rectMask(uv, minUv, maxUv);
    float inner = rectMask(uv, minUv + thickness, maxUv - thickness);
    return saturate(outer - inner);
 }
 float4 displayProbeData(ShaderContext context)
 {
    float3 baseColor = sampleLayerInput(context.uv).rgb;
    float3 swatchColor = baseColor;
    float swatchMask = 0.0;
    float2 panelOrigin = float2(0.03, 0.04);
    float2 gap = float2(swatchSize.x + 0.012, swatchSize.y + 0.012);
    float borderThickness = min(swatchSize.x, swatchSize.y) * 0.08;
    for (int index = 0; index < kProbeCount; ++index)
    {
        int column = index % 4;
        int row = index / 4;
        float2 swatchMin = panelOrigin + float2(float(column) * gap.x, float(row) * gap.y);
        float2 swatchMax = swatchMin + swatchSize;
        float3 storedColor = sampleVideo(cellCenterUvForIndex(context, index)).rgb;
        float fill = rectMask(context.uv, swatchMin, swatchMax);
        float outline = borderMask(context.uv, swatchMin, swatchMax, borderThickness);
        if (fill > 0.5)
        {
            swatchColor = storedColor;
            swatchMask = 1.0;
        }
        if (outline > 0.5)
        {
            swatchColor = float3(0.0, 0.0, 0.0);
            swatchMask = 1.0;
        }
    }
    float opacity = saturate(overlayOpacity) * swatchMask;
    float3 displayColor = lerp(baseColor, swatchColor, opacity);
    return float4(saturate(displayColor), 1.0);
 }
--- a/shaders/feedback-highlight-accumulator/shader.json
+++ b/shaders/feedback-highlight-accumulator/shader.json
@@ -0,0 +1,110 @@
 {
  "id": "feedback-highlight-accumulator",
  "name": "Feedback Background Memory",
  "description": "Learns a persistent per-pixel background plate in shader-local feedback and compares the live frame against that evolving full-frame state.",
  "category": "Feedback",
  "entryPoint": "updateBackgroundModel",
  "passes": [
    {
      "id": "background",
      "source": "shader.slang",
      "entryPoint": "updateBackgroundModel",
      "output": "backgroundModel"
    },
    {
      "id": "display",
      "source": "shader.slang",
      "entryPoint": "displayBackgroundDifference",
      "inputs": [
        "backgroundModel"
      ],
      "output": "layerOutput"
    }
  ],
  "feedback": {
    "enabled": true,
    "writePass": "background"
  },
  "parameters": [
    {
      "id": "learnRate",
      "label": "Learn Rate",
      "type": "float",
      "default": 0.03,
      "min": 0.001,
      "max": 0.5,
      "step": 0.001,
      "description": "How quickly the stored background model adapts toward the current frame."
    },
    {
      "id": "differenceThreshold",
      "label": "Difference Threshold",
      "type": "float",
      "default": 0.12,
      "min": 0.001,
      "max": 1.0,
      "step": 0.001,
      "description": "Minimum difference between the live frame and stored background before the overlay becomes visible."
    },
    {
      "id": "softness",
      "label": "Threshold Softness",
      "type": "float",
      "default": 0.08,
      "min": 0.001,
      "max": 0.5,
      "step": 0.001,
      "description": "Softens the transition around the difference threshold."
    },
    {
      "id": "overlayOpacity",
      "label": "Overlay Opacity",
      "type": "float",
      "default": 0.85,
      "min": 0.0,
      "max": 1.0,
      "step": 0.01,
      "description": "Strength of the motion/difference overlay on top of the live image."
    },
    {
      "id": "backgroundMix",
      "label": "Background Mix",
      "type": "float",
      "default": 0.15,
      "min": 0.0,
      "max": 1.0,
      "step": 0.01,
      "description": "Amount of the learned background model shown underneath the live source."
    },
    {
      "id": "overlayTint",
      "label": "Overlay Tint",
      "type": "color",
      "default": [
        1.0,
        0.45,
        0.08,
        1.0
      ],
      "min": [
        0.0,
        0.0,
        0.0,
        0.0
      ],
      "max": [
        1.0,
        1.0,
        1.0,
        1.0
      ],
      "step": [
        0.01,
        0.01,
        0.01,
        0.01
      ],
      "description": "Tint used for areas that differ from the learned background."
    }
  ]
 }
--- a/shaders/feedback-highlight-accumulator/shader.slang
+++ b/shaders/feedback-highlight-accumulator/shader.slang
@@ -0,0 +1,39 @@
 float luminance(float3 color)
 {
    return dot(color, float3(0.2126, 0.7152, 0.0722));
 }
 float4 updateBackgroundModel(ShaderContext context)
 {
    float3 liveColor = context.sourceColor.rgb;
    if (context.feedbackAvailable <= 0)
        return float4(liveColor, 1.0);
    float3 previousBackground = sampleFeedback(context.uv).rgb;
    float rate = saturate(learnRate);
    float3 nextBackground = lerp(previousBackground, liveColor, rate);
    return float4(saturate(nextBackground), 1.0);
 }
 float4 displayBackgroundDifference(ShaderContext context)
 {
    // In the display pass, context.sourceColor is the same-frame background
    // model produced by updateBackgroundModel().
    float3 backgroundModel = context.sourceColor.rgb;
    float3 liveColor = sampleLayerInput(context.uv).rgb;
    float3 delta = abs(liveColor - backgroundModel);
    float difference = max(delta.r, max(delta.g, delta.b));
    float thresholdWidth = max(softness, 0.0001);
    float motionMask = smoothstep(
        differenceThreshold - thresholdWidth,
        differenceThreshold + thresholdWidth,
        difference);
    float3 baseColor = lerp(liveColor, backgroundModel, saturate(backgroundMix));
    float3 overlayColor = overlayTint.rgb * max(luminance(liveColor), 0.15);
    float overlayAmount = motionMask * saturate(overlayOpacity) * overlayTint.a;
    float3 displayColor = lerp(baseColor, baseColor + overlayColor, overlayAmount);
    return float4(saturate(displayColor), 1.0);
 }
--- a/shaders/fisheye-equirectangular-mirror/shader.json
+++ b/shaders/fisheye-equirectangular-mirror/shader.json
@@ -9,55 +9,85 @@
      "id": "lensFovDegrees",
      "label": "Lens FOV",
      "type": "float",
-      "default": 190.0,
+      "default": 190,
-      "min": 1.0,
+      "min": 1,
-      "max": 220.0,
+      "max": 220,
-      "step": 0.1
+      "step": 0.1,
      "description": "Actual fisheye lens field of view in degrees."
    },
    {
      "id": "center",
      "label": "Optical Center",
      "type": "vec2",
-      "default": [0.5, 0.5],
+      "default": [
-      "min": [0.0, 0.0],
+        0.5,
-      "max": [1.0, 1.0],
+        0.5
-      "step": [0.001, 0.001]
+      ],
      "min": [
        0,
        0
      ],
      "max": [
        1,
        1
      ],
      "step": [
        0.001,
        0.001
      ],
      "description": "Normalized position in the frame, where 0.5, 0.5 is center."
    },
    {
      "id": "radius",
      "label": "Fisheye Radius",
      "type": "vec2",
-      "default": [0.5, 0.8889],
+      "default": [
-      "min": [0.001, 0.001],
+        0.5,
-      "max": [2.0, 2.0],
+        0.8889
-      "step": [0.001, 0.001]
+      ],
      "min": [
        0.001,
        0.001
      ],
      "max": [
        2,
        2
      ],
      "step": [
        0.001,
        0.001
      ],
      "description": "Normalized fisheye radius; adjust X/Y when the image is cropped or squeezed."
    },
    {
      "id": "yawDegrees",
      "label": "Yaw",
      "type": "float",
-      "default": 0.0,
+      "default": 0,
-      "min": -180.0,
+      "min": -180,
-      "max": 180.0,
+      "max": 180,
-      "step": 0.1
+      "step": 0.1,
      "description": "Rotates the virtual view horizontally."
    },
    {
      "id": "pitchDegrees",
      "label": "Pitch",
      "type": "float",
-      "default": 0.0,
+      "default": 0,
-      "min": -120.0,
+      "min": -120,
-      "max": 120.0,
+      "max": 120,
-      "step": 0.1
+      "step": 0.1,
      "description": "Rotates the virtual view vertically."
    },
    {
      "id": "rollDegrees",
      "label": "Roll",
      "type": "float",
-      "default": 0.0,
+      "default": 0,
-      "min": -180.0,
+      "min": -180,
-      "max": 180.0,
+      "max": 180,
-      "step": 0.1
+      "step": 0.1,
      "description": "Live roll rotation around the viewing axis."
    },
    {
      "id": "fisheyeModel",
@@ -65,35 +95,56 @@
      "type": "enum",
      "default": "equidistant",
      "options": [
-        { "value": "equidistant", "label": "Equidistant" },
+        {
-        { "value": "equisolid", "label": "Equisolid" },
+          "value": "equidistant",
-        { "value": "stereographic", "label": "Stereographic" },
+          "label": "Equidistant"
-        { "value": "orthographic", "label": "Orthographic" }
+        },
-      ]
+        {
          "value": "equisolid",
          "label": "Equisolid"
        },
        {
          "value": "stereographic",
          "label": "Stereographic"
        },
        {
          "value": "orthographic",
          "label": "Orthographic"
        }
      ],
      "description": "Projection model used by the physical fisheye lens."
    },
    {
      "id": "edgeFill",
      "label": "Edge Fill",
      "type": "float",
      "default": 0.06,
-      "min": 0.0,
+      "min": 0,
      "max": 0.3,
-      "step": 0.001
+      "step": 0.001,
      "description": "Extends edge samples outward to cover small missing areas."
    },
    {
      "id": "edgeBlur",
      "label": "Edge Blur",
      "type": "float",
      "default": 0.018,
-      "min": 0.0,
+      "min": 0,
      "max": 0.12,
-      "step": 0.001
+      "step": 0.001,
      "description": "Softens the dilated edge fill."
    },
    {
      "id": "outsideColor",
      "label": "Outside Color",
      "type": "color",
-      "default": [0.0, 0.0, 0.0, 1.0]
+      "default": [
        0,
        0,
        0,
        1
      ],
      "description": "Color used where the remapped image samples outside the source frame."
    }
  ]
 }
--- a/shaders/fisheye-equirectangular-mirror/shader.slang
+++ b/shaders/fisheye-equirectangular-mirror/shader.slang
@@ -31,6 +31,8 @@ float normalizedFisheyeRadius(float theta, float halfFov)
 {
 	float safeHalfFov = max(halfFov, 0.0001);
 	// Match common fisheye projection families while keeping the selected FOV
 	// normalized to the same source-image radius.
 	if (fisheyeModel == 1)
 	{
 		return sin(theta * 0.5) / max(sin(safeHalfFov * 0.5), 0.0001);
@@ -49,6 +51,7 @@ float normalizedFisheyeRadius(float theta, float halfFov)
 float3 equirectangularRay(float2 uv)
 {
 	// Convert equirectangular UVs into longitude/latitude on the unit sphere.
 	float longitude = (uv.x - 0.5) * TWO_PI;
 	float latitude = (0.5 - uv.y) * PI;
 	float latitudeCos = cos(latitude);
@@ -82,6 +85,8 @@ float4 sampleEdgeFilledVideo(float2 sourceUv, ShaderContext context)
 	float inwardLength = max(length(inward), 0.000001);
 	inward /= inwardLength;
 	// Outside the fisheye image, sample back inward from the nearest edge so the
 	// fill looks like stretched lens content instead of a hard color plate.
 	float blurDistance = max(edgeBlur, 0.0);
 	float4 color = sampleVideo(clampedUv) * 0.32;
 	color += sampleVideo(saturate(clampedUv + inward * blurDistance * 0.35)) * 0.26;
@@ -114,6 +119,7 @@ float4 shadeVideo(ShaderContext context)
 	float phi = atan2(ray.y, ray.x);
 	float fisheyeRadius = normalizedFisheyeRadius(theta, halfFov);
 	// Project the mirrored sphere ray back into the circular fisheye source.
 	float2 sourceUv = float2(
 		center.x + cos(phi) * fisheyeRadius * radius.x,
 		center.y - sin(phi) * fisheyeRadius * radius.y
--- a/shaders/fisheye-reproject/shader.json
+++ b/shaders/fisheye-reproject/shader.json
@@ -9,91 +9,145 @@
      "id": "lensFovDegrees",
      "label": "Lens FOV",
      "type": "float",
-      "default": 190.0,
+      "default": 190,
-      "min": 1.0,
+      "min": 1,
-      "max": 220.0,
+      "max": 220,
-      "step": 0.1
+      "step": 0.1,
      "description": "Actual fisheye lens field of view in degrees."
    },
    {
      "id": "center",
      "label": "Optical Center",
      "type": "vec2",
-      "default": [0.5, 0.5],
+      "default": [
-      "min": [0.0, 0.0],
+        0.5,
-      "max": [1.0, 1.0],
+        0.5
-      "step": [0.001, 0.001]
+      ],
      "min": [
        0,
        0
      ],
      "max": [
        1,
        1
      ],
      "step": [
        0.001,
        0.001
      ],
      "description": "Normalized position in the frame, where 0.5, 0.5 is center."
    },
    {
      "id": "radius",
      "label": "Fisheye Radius",
      "type": "vec2",
-      "default": [0.5, 0.885],
+      "default": [
-      "min": [0.001, 0.001],
+        0.5,
-      "max": [2.0, 2.0],
+        0.885
-      "step": [0.001, 0.001]
+      ],
      "min": [
        0.001,
        0.001
      ],
      "max": [
        2,
        2
      ],
      "step": [
        0.001,
        0.001
      ],
      "description": "Normalized fisheye radius; adjust X/Y when the image is cropped or squeezed."
    },
    {
      "id": "sourceEdgeCut",
      "label": "Source Edge Cut",
      "type": "float",
      "default": 0.01,
      "min": 0,
      "max": 0.2,
      "step": 0.001,
      "description": "Cuts slightly inward from all four source-frame edges before sampling to hide empty border regions."
    },
    {
      "id": "sourceEdgeFeather",
      "label": "Source Edge Feather",
      "type": "float",
      "default": 0.02,
      "min": 0,
      "max": 0.2,
      "step": 0.001,
      "description": "Softens the trimmed source edges into the outside color for easier background blending."
    },
    {
      "id": "virtualFovDegrees",
      "label": "Virtual FOV",
      "type": "float",
-      "default": 75.0,
+      "default": 75,
-      "min": 1.0,
+      "min": 1,
-      "max": 175.0,
+      "max": 175,
-      "step": 0.1
+      "step": 0.1,
      "description": "Field of view of the generated virtual camera."
    },
    {
      "id": "basePanDegrees",
      "label": "Base Pan",
      "type": "float",
-      "default": 0.0,
+      "default": 0,
-      "min": -180.0,
+      "min": -180,
-      "max": 180.0,
+      "max": 180,
-      "step": 0.1
+      "step": 0.1,
      "description": "Permanent horizontal alignment offset before live pan."
    },
    {
      "id": "baseTiltDegrees",
      "label": "Base Tilt",
      "type": "float",
-      "default": 0.0,
+      "default": 0,
-      "min": -120.0,
+      "min": -120,
-      "max": 120.0,
+      "max": 120,
-      "step": 0.1
+      "step": 0.1,
      "description": "Permanent vertical alignment offset before live tilt."
    },
    {
      "id": "baseRollDegrees",
      "label": "Base Roll",
      "type": "float",
-      "default": 0.0,
+      "default": 0,
-      "min": -180.0,
+      "min": -180,
-      "max": 180.0,
+      "max": 180,
-      "step": 0.1
+      "step": 0.1,
      "description": "Permanent roll alignment offset before live roll."
    },
    {
      "id": "panDegrees",
      "label": "Pan",
      "type": "float",
-      "default": 0.0,
+      "default": 0,
-      "min": -180.0,
+      "min": -180,
-      "max": 180.0,
+      "max": 180,
-      "step": 0.1
+      "step": 0.1,
      "description": "Live horizontal view rotation."
    },
    {
      "id": "tiltDegrees",
      "label": "Tilt",
      "type": "float",
-      "default": 0.0,
+      "default": 0,
-      "min": -120.0,
+      "min": -120,
-      "max": 120.0,
+      "max": 120,
-      "step": 0.1
+      "step": 0.1,
      "description": "Live vertical view rotation."
    },
    {
      "id": "rollDegrees",
      "label": "Roll",
      "type": "float",
-      "default": 0.0,
+      "default": 0,
-      "min": -180.0,
+      "min": -180,
-      "max": 180.0,
+      "max": 180,
-      "step": 0.1
+      "step": 0.1,
      "description": "Live roll rotation around the viewing axis."
    },
    {
      "id": "fisheyeModel",
@@ -101,11 +155,24 @@
      "type": "enum",
      "default": "equidistant",
      "options": [
-        { "value": "equidistant", "label": "Equidistant" },
+        {
-        { "value": "equisolid", "label": "Equisolid" },
+          "value": "equidistant",
-        { "value": "stereographic", "label": "Stereographic" },
+          "label": "Equidistant"
-        { "value": "orthographic", "label": "Orthographic" }
+        },
-      ]
+        {
          "value": "equisolid",
          "label": "Equisolid"
        },
        {
          "value": "stereographic",
          "label": "Stereographic"
        },
        {
          "value": "orthographic",
          "label": "Orthographic"
        }
      ],
      "description": "Projection model used by the physical fisheye lens."
    },
    {
      "id": "outputProjection",
@@ -113,15 +180,28 @@
      "type": "enum",
      "default": "rectilinear",
      "options": [
-        { "value": "rectilinear", "label": "Rectilinear" },
+        {
-        { "value": "cylindrical", "label": "Cylindrical" }
+          "value": "rectilinear",
-      ]
+          "label": "Rectilinear"
        },
        {
          "value": "cylindrical",
          "label": "Cylindrical"
        }
      ],
      "description": "Chooses rectilinear perspective or cylindrical reprojection."
    },
    {
      "id": "outsideColor",
      "label": "Outside Color",
      "type": "color",
-      "default": [0.0, 0.0, 0.0, 1.0]
+      "default": [
        0,
        0,
        0,
        1
      ],
      "description": "Color used where the remapped image samples outside the source frame."
    }
  ]
 }
--- a/shaders/fisheye-reproject/shader.slang
+++ b/shaders/fisheye-reproject/shader.slang
@@ -43,6 +43,8 @@ float normalizedFisheyeRadius(float theta, float halfFov)
 {
 	float safeHalfFov = max(halfFov, 0.0001);
 	// Different fisheye lenses map angle to image radius differently. Normalize
 	// each model by the selected half-FOV so the outer lens edge stays at 1.0.
 	if (fisheyeModel == 1)
 	{
 		return sin(theta * 0.5) / max(sin(safeHalfFov * 0.5), 0.0001);
@@ -59,6 +61,20 @@ float normalizedFisheyeRadius(float theta, float halfFov)
 	return theta / safeHalfFov;
 }
 float sourceUvRectMask(float2 uv, float2 inputResolution)
 {
 	float2 pixel = 1.0 / max(inputResolution, float2(1.0, 1.0));
 	float cut = max(sourceEdgeCut, 0.0);
 	float feather = max(sourceEdgeFeather, 0.0);
 	float2 featherSize = max(float2(feather, feather), pixel * 0.5);
 	float left = smoothstep(cut, cut + featherSize.x, uv.x);
 	float right = 1.0 - smoothstep(1.0 - cut - featherSize.x, 1.0 - cut, uv.x);
 	float top = smoothstep(cut, cut + featherSize.y, uv.y);
 	float bottom = 1.0 - smoothstep(1.0 - cut - featherSize.y, 1.0 - cut, uv.y);
 	return saturate(left * right * top * bottom);
 }
 float4 shadeVideo(ShaderContext context)
 {
 	float2 screen = float2(context.uv.x * 2.0 - 1.0, 1.0 - context.uv.y * 2.0);
@@ -67,6 +83,8 @@ float4 shadeVideo(ShaderContext context)
 	float virtualFov = radiansFromDegrees(clamp(virtualFovDegrees, 1.0, 175.0));
 	float tanHalfFov = tan(virtualFov * 0.5);
 	// Build a virtual output-camera ray, then rotate it into the fisheye lens
 	// coordinate system before asking where that ray lands on the source image.
 	float3 ray = outputProjection == 1
 		? buildCylindricalRay(screen, outputAspect, tanHalfFov)
 		: buildRectilinearRay(screen, outputAspect, tanHalfFov);
@@ -86,6 +104,7 @@ float4 shadeVideo(ShaderContext context)
 	float phi = atan2(ray.y, ray.x);
 	float fisheyeRadius = normalizedFisheyeRadius(theta, halfFov);
 	// Polar lens coordinates become UVs inside the circular fisheye image.
 	float2 sourceUv = float2(
 		center.x + cos(phi) * fisheyeRadius * radius.x,
 		center.y - sin(phi) * fisheyeRadius * radius.y
@@ -94,5 +113,7 @@ float4 shadeVideo(ShaderContext context)
 	if (sourceUv.x < 0.0 || sourceUv.x > 1.0 || sourceUv.y < 0.0 || sourceUv.y > 1.0)
 		return outsideColor;
-	return sampleVideo(sourceUv);
+	float sourceMask = sourceUvRectMask(sourceUv, context.inputResolution);
 	float4 sourceColor = sampleVideo(sourceUv);
 	return saturate(lerp(outsideColor, sourceColor, sourceMask));
 }
--- a/shaders/gaussian-blur/shader.json
+++ b/shaders/gaussian-blur/shader.json
@@ -1,36 +1,59 @@
 {
  "id": "gaussian-blur",
  "name": "Gaussian Blur",
-  "description": "Applies a simple Gaussian-style blur to the decoded video input.",
+  "description": "Applies a separable two-pass Gaussian-style blur to the decoded video input.",
  "category": "Transform",
  "entryPoint": "shadeVideo",
  "passes": [
    {
      "id": "horizontal",
      "source": "shader.slang",
      "entryPoint": "blurHorizontal",
      "inputs": [
        "layerInput"
      ],
      "output": "blurHorizontal"
    },
    {
      "id": "vertical",
      "source": "shader.slang",
      "entryPoint": "blurVertical",
      "inputs": [
        "blurHorizontal"
      ],
      "output": "layerOutput"
    }
  ],
  "parameters": [
    {
      "id": "radius",
      "label": "Radius",
      "type": "float",
-      "default": 2.0,
+      "default": 2,
-      "min": 0.0,
+      "min": 0,
-      "max": 8.0,
+      "max": 8,
-      "step": 0.1
+      "step": 0.1,
      "description": "Blur radius in pixels for each separable pass."
    },
    {
      "id": "strength",
      "label": "Strength",
      "type": "float",
-      "default": 1.0,
+      "default": 1,
-      "min": 0.0,
+      "min": 0,
-      "max": 1.0,
+      "max": 1,
-      "step": 0.01
+      "step": 0.01,
      "description": "Blends between the original and blurred result."
    },
    {
      "id": "samples",
      "label": "Samples",
      "type": "float",
-      "default": 2.0,
+      "default": 2,
-      "min": 0.0,
+      "min": 0,
-      "max": 25.0,
+      "max": 25,
-      "step": 1.0
+      "step": 1,
      "description": "Number of taps per direction; higher values cost more GPU time."
    }
  ]
 }
--- a/shaders/gaussian-blur/shader.slang
+++ b/shaders/gaussian-blur/shader.slang
@@ -1,25 +1,22 @@
-float4 shadeVideo(ShaderContext context)
+float4 gaussianBlurDirection(ShaderContext context, float2 direction)
 {
 	float2 texel = 1.0 / max(context.inputResolution, float2(1.0, 1.0));
-	float blurRadius = max(radius, 0.0);
+	float blurRadius = max(radius, 0.0) * saturate(strength);
-	float2 sampleStep = texel * blurRadius;
+	float2 sampleStep = texel * blurRadius * direction;
 	int sampleRadius = int(clamp(samples, 0.0, 8.0) + 0.5);
 	float4 center = sampleVideo(context.uv);
 	float4 blur = float4(0.0, 0.0, 0.0, 0.0);
 	float totalWeight = 0.0;
-	for (int y = -sampleRadius; y <= sampleRadius; ++y)
+	for (int x = -sampleRadius; x <= sampleRadius; ++x)
 	{
-		for (int x = -sampleRadius; x <= sampleRadius; ++x)
+		float distanceSquared = float(x * x);
-		{
+		float sigma = max(float(sampleRadius) * 0.5, 0.5);
-			float distanceSquared = float(x * x + y * y);
+		float weight = exp(-distanceSquared / (2.0 * sigma * sigma));
-			float sigma = max(float(sampleRadius) * 0.5, 0.5);
+		float2 offset = float(x) * sampleStep;
-			float weight = exp(-distanceSquared / (2.0 * sigma * sigma));
+		blur += sampleVideo(context.uv + offset) * weight;
-			float2 offset = float2(float(x), float(y)) * sampleStep;
+		totalWeight += weight;
 			blur += sampleVideo(context.uv + offset) * weight;
 			totalWeight += weight;
 		}
 	}
 	if (sampleRadius == 0)
@@ -29,7 +26,20 @@ float4 shadeVideo(ShaderContext context)
 	}
 	blur /= max(totalWeight, 0.0001);
-
+	return blur;
-	float mixValue = saturate(strength);
+}
-	return lerp(center, blur, mixValue);
+
 float4 blurHorizontal(ShaderContext context)
 {
 	return gaussianBlurDirection(context, float2(1.0, 0.0));
 }
 float4 blurVertical(ShaderContext context)
 {
 	return gaussianBlurDirection(context, float2(0.0, 1.0));
 }
 float4 shadeVideo(ShaderContext context)
 {
 	return blurVertical(context);
 }
--- a/shaders/greenscreen-key/shader.json
+++ b/shaders/greenscreen-key/shader.json
@@ -1,90 +1,347 @@
 {
  "id": "greenscreen-key",
  "name": "Greenscreen Key",
-  "description": "Keys out a green screen background and outputs transparent alpha for compositing.",
+  "description": "Production-style green/blue screen keyer with matte refinement, despill, edge treatment, and debug views.",
  "category": "Keying",
  "entryPoint": "shadeVideo",
  "passes": [
    {
      "id": "rawMatte",
      "source": "shader.slang",
      "entryPoint": "buildRawMatte",
      "inputs": [
        "layerInput"
      ],
      "output": "rawMatte"
    },
    {
      "id": "refinedMatte",
      "source": "shader.slang",
      "entryPoint": "refineMatte",
      "inputs": [
        "rawMatte"
      ],
      "output": "refinedMatte"
    },
    {
      "id": "final",
      "source": "shader.slang",
      "entryPoint": "applyKey",
      "inputs": [
        "refinedMatte"
      ],
      "output": "layerOutput"
    }
  ],
  "parameters": [
    {
      "id": "screenColor",
      "label": "Screen Color",
      "type": "color",
-      "default": [0.15, 0.85, 0.2, 1.0],
+      "default": [
-      "min": [0.0, 0.0, 0.0, 0.0],
+        0.15,
-      "max": [1.0, 1.0, 1.0, 1.0],
+        0.85,
-      "step": [0.01, 0.01, 0.01, 0.01]
+        0.2,
        1
      ],
      "min": [
        0,
        0,
        0,
        0
      ],
      "max": [
        1,
        1,
        1,
        1
      ],
      "step": [
        0.01,
        0.01,
        0.01,
        0.01
      ],
      "description": "Target screen color to remove; use green or blue depending on the backdrop."
    },
    {
      "id": "threshold",
-      "label": "Threshold",
+      "label": "Screen Gain",
      "type": "float",
      "default": 0.24,
      "min": 0.01,
      "max": 0.8,
-      "step": 0.005
+      "step": 0.005,
      "description": "Higher values keep more foreground; lower values remove more screen."
    },
    {
      "id": "softness",
      "label": "Softness",
      "type": "float",
-      "default": 0.12,
+      "default": 0.16,
      "min": 0.001,
      "max": 0.5,
-      "step": 0.005
+      "step": 0.005,
      "description": "Feathers the transition between foreground and keyed screen."
    },
    {
-      "id": "edgeSoftness",
+      "id": "screenBalance",
-      "label": "Edge Softness",
+      "label": "Screen Balance",
      "type": "float",
-      "default": 0.08,
+      "default": 0.5,
-      "min": 0.0,
+      "min": 0,
-      "max": 0.4,
+      "max": 1,
-      "step": 0.005
+      "step": 0.005,
      "description": "Balances chroma-distance keying against color-direction keying."
    },
    {
      "id": "screenPreBlur",
      "label": "Screen PreBlur",
      "type": "float",
      "default": 1,
      "min": 0,
      "max": 8,
      "step": 0.1,
      "description": "Blurs source color before matte generation to reduce noisy edges."
    },
    {
      "id": "erodeDilate",
      "label": "Erode/Dilate",
      "type": "float",
-      "default": 0.0,
+      "default": 0,
      "min": -0.3,
      "max": 0.3,
-      "step": 0.005
+      "step": 0.005,
      "description": "Negative erodes the matte; positive expands it."
    },
    {
      "id": "matteBlur",
      "label": "Matte Blur",
      "type": "float",
      "default": 1.25,
      "min": 0,
      "max": 6,
      "step": 0.1,
      "description": "Softens the generated matte after keying."
    },
    {
      "id": "matteGamma",
      "label": "Matte Gamma",
      "type": "float",
      "default": 1,
      "min": 0.25,
      "max": 4,
      "step": 0.01,
      "description": "Shapes midtone opacity in the matte."
    },
    {
      "id": "matteContrast",
      "label": "Matte Contrast",
      "type": "float",
      "default": 1,
      "min": 0.25,
      "max": 4,
      "step": 0.01,
      "description": "Increases or reduces matte separation around 50 percent alpha."
    },
    {
      "id": "blackCleanup",
      "label": "Black Cleanup",
      "type": "float",
      "default": 0,
      "min": 0,
      "max": 1,
      "step": 0.005,
      "description": "Pushes semi-transparent dark matte areas toward transparent."
    },
    {
      "id": "whiteCleanup",
      "label": "White Cleanup",
      "type": "float",
      "default": 0,
      "min": 0,
      "max": 1,
      "step": 0.005,
      "description": "Pushes semi-transparent light matte areas toward opaque."
    },
    {
      "id": "despill",
      "label": "Despill",
      "type": "float",
      "default": 0.45,
-      "min": 0.0,
+      "min": 0,
      "max": 1.5,
-      "step": 0.01
+      "step": 0.01,
      "description": "Removes screen-colored contamination from foreground edges."
    },
    {
-      "id": "edgeBoost",
+      "id": "despillBias",
-      "label": "Edge Boost",
+      "label": "Despill Bias",
      "type": "float",
-      "default": 0.08,
+      "default": 0,
-      "min": -0.2,
+      "min": -0.5,
-      "max": 0.3,
+      "max": 0.5,
-      "step": 0.005
+      "step": 0.005,
      "description": "Offsets spill detection when foreground colors are close to the screen color."
    },
    {
      "id": "spillTint",
      "label": "Spill Tint",
      "type": "color",
      "default": [
        1,
        1,
        1,
        1
      ],
      "min": [
        0,
        0,
        0,
        0
      ],
      "max": [
        1,
        1,
        1,
        1
      ],
      "step": [
        0.01,
        0.01,
        0.01,
        0.01
      ],
      "description": "Tint used when neutralizing spill."
    },
    {
      "id": "edgeRecover",
      "label": "Edge Recover",
      "type": "float",
      "default": 0.18,
      "min": 0,
      "max": 1,
      "step": 0.005,
      "description": "Adds color recovery along semi-transparent matte edges."
    },
    {
      "id": "edgeColor",
      "label": "Edge Color",
      "type": "color",
      "default": [
        1,
        1,
        1,
        1
      ],
      "min": [
        0,
        0,
        0,
        0
      ],
      "max": [
        1,
        1,
        1,
        1
      ],
      "step": [
        0.01,
        0.01,
        0.01,
        0.01
      ],
      "description": "Tint applied to recovered edge detail."
    },
    {
      "id": "clipBlack",
      "label": "Clip Black",
      "type": "float",
-      "default": 0.0,
+      "default": 0,
-      "min": 0.0,
+      "min": 0,
      "max": 0.5,
-      "step": 0.005
+      "step": 0.005,
      "description": "Matte values below this become transparent."
    },
    {
      "id": "clipWhite",
      "label": "Clip White",
      "type": "float",
-      "default": 1.0,
+      "default": 1,
      "min": 0.5,
-      "max": 1.0,
+      "max": 1,
-      "step": 0.005
+      "step": 0.005,
      "description": "Matte values above this become opaque."
    },
    {
      "id": "cropLeft",
      "label": "Crop Left",
      "description": "Trims the final matte from the left edge as a fraction of frame width.",
      "type": "float",
      "default": 0,
      "min": 0,
      "max": 0.5,
      "step": 0.001
    },
    {
      "id": "cropRight",
      "label": "Crop Right",
      "description": "Trims the final matte from the right edge as a fraction of frame width.",
      "type": "float",
      "default": 0,
      "min": 0,
      "max": 0.5,
      "step": 0.001
    },
    {
      "id": "cropTop",
      "label": "Crop Top",
      "description": "Trims the final matte from the top edge as a fraction of frame height.",
      "type": "float",
      "default": 0,
      "min": 0,
      "max": 0.5,
      "step": 0.001
    },
    {
      "id": "cropBottom",
      "label": "Crop Bottom",
      "description": "Trims the final matte from the bottom edge as a fraction of frame height.",
      "type": "float",
      "default": 0,
      "min": 0,
      "max": 0.5,
      "step": 0.001
    },
    {
      "id": "viewMode",
      "label": "View",
      "type": "enum",
      "default": "composite",
      "options": [
        {
          "value": "composite",
          "label": "Composite"
        },
        {
          "value": "matte",
          "label": "Matte"
        },
        {
          "value": "spill",
          "label": "Spill"
        },
        {
          "value": "despill",
          "label": "Despill"
        },
        {
          "value": "status",
          "label": "Status"
        }
      ],
      "description": "Debug output mode for inspecting matte, spill, and despill stages."
    }
  ]
 }
--- a/Show More
+++ b/Show More