crossxtex/Texconv/texconv.cpp
2015-11-02 17:03:41 -08:00

1803 lines
60 KiB
C++

//--------------------------------------------------------------------------------------
// File: TexConv.cpp
//
// DirectX 11 Texture Converter
//
// Copyright (c) Microsoft Corporation. All rights reserved.
//--------------------------------------------------------------------------------------
#include <stdio.h>
#include <stdlib.h>
#include <assert.h>
#include <memory>
#include <list>
#include <wrl\client.h>
#include <dxgiformat.h>
#include "directxtex.h"
using namespace DirectX;
using Microsoft::WRL::ComPtr;
enum OPTIONS // Note: dwOptions below assumes 64 or less options.
{
OPT_WIDTH = 1,
OPT_HEIGHT,
OPT_MIPLEVELS,
OPT_FORMAT,
OPT_FILTER,
OPT_SRGBI,
OPT_SRGBO,
OPT_SRGB,
OPT_PREFIX,
OPT_SUFFIX,
OPT_OUTPUTDIR,
OPT_FILETYPE,
OPT_HFLIP,
OPT_VFLIP,
OPT_DDS_DWORD_ALIGN,
OPT_USE_DX10,
OPT_NOLOGO,
OPT_TIMING,
OPT_SEPALPHA,
OPT_TYPELESS_UNORM,
OPT_TYPELESS_FLOAT,
OPT_PREMUL_ALPHA,
OPT_EXPAND_LUMINANCE,
OPT_TA_WRAP,
OPT_TA_MIRROR,
OPT_FORCE_SINGLEPROC,
OPT_NOGPU,
OPT_FEATURE_LEVEL,
OPT_FIT_POWEROF2,
OPT_ALPHA_WEIGHT,
OPT_NORMAL_MAP,
OPT_NORMAL_MAP_AMPLITUDE,
OPT_COMPRESS_UNIFORM,
OPT_COMPRESS_MAX,
OPT_COMPRESS_DITHER,
OPT_MAX
};
static_assert( OPT_MAX <= 64, "dwOptions is a DWORD64 bitfield" );
struct SConversion
{
WCHAR szSrc [MAX_PATH];
WCHAR szDest[MAX_PATH];
};
struct SValue
{
LPCWSTR pName;
DWORD dwValue;
};
//////////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////
SValue g_pOptions[] =
{
{ L"w", OPT_WIDTH },
{ L"h", OPT_HEIGHT },
{ L"m", OPT_MIPLEVELS },
{ L"f", OPT_FORMAT },
{ L"if", OPT_FILTER },
{ L"srgbi", OPT_SRGBI },
{ L"srgbo", OPT_SRGBO },
{ L"srgb", OPT_SRGB },
{ L"px", OPT_PREFIX },
{ L"sx", OPT_SUFFIX },
{ L"o", OPT_OUTPUTDIR },
{ L"ft", OPT_FILETYPE },
{ L"hflip", OPT_HFLIP },
{ L"vflip", OPT_VFLIP },
{ L"dword", OPT_DDS_DWORD_ALIGN },
{ L"dx10", OPT_USE_DX10 },
{ L"nologo", OPT_NOLOGO },
{ L"timing", OPT_TIMING },
{ L"sepalpha", OPT_SEPALPHA },
{ L"tu", OPT_TYPELESS_UNORM },
{ L"tf", OPT_TYPELESS_FLOAT },
{ L"pmalpha", OPT_PREMUL_ALPHA },
{ L"xlum", OPT_EXPAND_LUMINANCE },
{ L"wrap", OPT_TA_WRAP },
{ L"mirror", OPT_TA_MIRROR },
{ L"singleproc", OPT_FORCE_SINGLEPROC },
{ L"nogpu", OPT_NOGPU },
{ L"fl", OPT_FEATURE_LEVEL },
{ L"pow2", OPT_FIT_POWEROF2 },
{ L"aw", OPT_ALPHA_WEIGHT },
{ L"nmap", OPT_NORMAL_MAP },
{ L"nmapamp", OPT_NORMAL_MAP_AMPLITUDE },
{ L"bcuniform", OPT_COMPRESS_UNIFORM },
{ L"bcmax", OPT_COMPRESS_MAX },
{ L"bcdither", OPT_COMPRESS_DITHER },
{ nullptr, 0 }
};
#define DEFFMT(fmt) { L#fmt, DXGI_FORMAT_ ## fmt }
SValue g_pFormats[] =
{
// List does not include _TYPELESS or depth/stencil formats
DEFFMT(R32G32B32A32_FLOAT),
DEFFMT(R32G32B32A32_UINT),
DEFFMT(R32G32B32A32_SINT),
DEFFMT(R32G32B32_FLOAT),
DEFFMT(R32G32B32_UINT),
DEFFMT(R32G32B32_SINT),
DEFFMT(R16G16B16A16_FLOAT),
DEFFMT(R16G16B16A16_UNORM),
DEFFMT(R16G16B16A16_UINT),
DEFFMT(R16G16B16A16_SNORM),
DEFFMT(R16G16B16A16_SINT),
DEFFMT(R32G32_FLOAT),
DEFFMT(R32G32_UINT),
DEFFMT(R32G32_SINT),
DEFFMT(R10G10B10A2_UNORM),
DEFFMT(R10G10B10A2_UINT),
DEFFMT(R11G11B10_FLOAT),
DEFFMT(R8G8B8A8_UNORM),
DEFFMT(R8G8B8A8_UNORM_SRGB),
DEFFMT(R8G8B8A8_UINT),
DEFFMT(R8G8B8A8_SNORM),
DEFFMT(R8G8B8A8_SINT),
DEFFMT(R16G16_FLOAT),
DEFFMT(R16G16_UNORM),
DEFFMT(R16G16_UINT),
DEFFMT(R16G16_SNORM),
DEFFMT(R16G16_SINT),
DEFFMT(R32_FLOAT),
DEFFMT(R32_UINT),
DEFFMT(R32_SINT),
DEFFMT(R8G8_UNORM),
DEFFMT(R8G8_UINT),
DEFFMT(R8G8_SNORM),
DEFFMT(R8G8_SINT),
DEFFMT(R16_FLOAT),
DEFFMT(R16_UNORM),
DEFFMT(R16_UINT),
DEFFMT(R16_SNORM),
DEFFMT(R16_SINT),
DEFFMT(R8_UNORM),
DEFFMT(R8_UINT),
DEFFMT(R8_SNORM),
DEFFMT(R8_SINT),
DEFFMT(A8_UNORM),
DEFFMT(R9G9B9E5_SHAREDEXP),
DEFFMT(R8G8_B8G8_UNORM),
DEFFMT(G8R8_G8B8_UNORM),
DEFFMT(BC1_UNORM),
DEFFMT(BC1_UNORM_SRGB),
DEFFMT(BC2_UNORM),
DEFFMT(BC2_UNORM_SRGB),
DEFFMT(BC3_UNORM),
DEFFMT(BC3_UNORM_SRGB),
DEFFMT(BC4_UNORM),
DEFFMT(BC4_SNORM),
DEFFMT(BC5_UNORM),
DEFFMT(BC5_SNORM),
DEFFMT(B5G6R5_UNORM),
DEFFMT(B5G5R5A1_UNORM),
// DXGI 1.1 formats
DEFFMT(B8G8R8A8_UNORM),
DEFFMT(B8G8R8X8_UNORM),
DEFFMT(R10G10B10_XR_BIAS_A2_UNORM),
DEFFMT(B8G8R8A8_UNORM_SRGB),
DEFFMT(B8G8R8X8_UNORM_SRGB),
DEFFMT(BC6H_UF16),
DEFFMT(BC6H_SF16),
DEFFMT(BC7_UNORM),
DEFFMT(BC7_UNORM_SRGB),
// DXGI 1.2 formats
DEFFMT(AYUV),
DEFFMT(Y410),
DEFFMT(Y416),
DEFFMT(YUY2),
DEFFMT(Y210),
DEFFMT(Y216),
// No support for legacy paletted video formats (AI44, IA44, P8, A8P8)
DEFFMT(B4G4R4A4_UNORM),
{ nullptr, DXGI_FORMAT_UNKNOWN }
};
SValue g_pReadOnlyFormats[] =
{
DEFFMT(R32G32B32A32_TYPELESS),
DEFFMT(R32G32B32_TYPELESS),
DEFFMT(R16G16B16A16_TYPELESS),
DEFFMT(R32G32_TYPELESS),
DEFFMT(R32G8X24_TYPELESS),
DEFFMT(D32_FLOAT_S8X24_UINT),
DEFFMT(R32_FLOAT_X8X24_TYPELESS),
DEFFMT(X32_TYPELESS_G8X24_UINT),
DEFFMT(R10G10B10A2_TYPELESS),
DEFFMT(R8G8B8A8_TYPELESS),
DEFFMT(R16G16_TYPELESS),
DEFFMT(R32_TYPELESS),
DEFFMT(D32_FLOAT),
DEFFMT(R24G8_TYPELESS),
DEFFMT(D24_UNORM_S8_UINT),
DEFFMT(R24_UNORM_X8_TYPELESS),
DEFFMT(X24_TYPELESS_G8_UINT),
DEFFMT(R8G8_TYPELESS),
DEFFMT(R16_TYPELESS),
DEFFMT(R8_TYPELESS),
DEFFMT(BC1_TYPELESS),
DEFFMT(BC2_TYPELESS),
DEFFMT(BC3_TYPELESS),
DEFFMT(BC4_TYPELESS),
DEFFMT(BC5_TYPELESS),
// DXGI 1.1 formats
DEFFMT(B8G8R8A8_TYPELESS),
DEFFMT(B8G8R8X8_TYPELESS),
DEFFMT(BC6H_TYPELESS),
DEFFMT(BC7_TYPELESS),
// DXGI 1.2 formats
DEFFMT(NV12),
DEFFMT(P010),
DEFFMT(P016),
DEFFMT(420_OPAQUE),
DEFFMT(NV11),
{ nullptr, DXGI_FORMAT_UNKNOWN }
};
SValue g_pFilters[] =
{
{ L"POINT", TEX_FILTER_POINT },
{ L"LINEAR", TEX_FILTER_LINEAR },
{ L"CUBIC", TEX_FILTER_CUBIC },
{ L"FANT", TEX_FILTER_FANT },
{ L"BOX", TEX_FILTER_BOX },
{ L"TRIANGLE", TEX_FILTER_TRIANGLE },
{ L"POINT_DITHER", TEX_FILTER_POINT | TEX_FILTER_DITHER },
{ L"LINEAR_DITHER", TEX_FILTER_LINEAR | TEX_FILTER_DITHER },
{ L"CUBIC_DITHER", TEX_FILTER_CUBIC | TEX_FILTER_DITHER },
{ L"FANT_DITHER", TEX_FILTER_FANT | TEX_FILTER_DITHER },
{ L"BOX_DITHER", TEX_FILTER_BOX | TEX_FILTER_DITHER },
{ L"TRIANGLE_DITHER", TEX_FILTER_TRIANGLE | TEX_FILTER_DITHER },
{ L"POINT_DITHER_DIFFUSION", TEX_FILTER_POINT | TEX_FILTER_DITHER_DIFFUSION },
{ L"LINEAR_DITHER_DIFFUSION", TEX_FILTER_LINEAR | TEX_FILTER_DITHER_DIFFUSION },
{ L"CUBIC_DITHER_DIFFUSION", TEX_FILTER_CUBIC | TEX_FILTER_DITHER_DIFFUSION },
{ L"FANT_DITHER_DIFFUSION", TEX_FILTER_FANT | TEX_FILTER_DITHER_DIFFUSION },
{ L"BOX_DITHER_DIFFUSION", TEX_FILTER_BOX | TEX_FILTER_DITHER_DIFFUSION },
{ L"TRIANGLE_DITHER_DIFFUSION", TEX_FILTER_TRIANGLE | TEX_FILTER_DITHER_DIFFUSION },
{ nullptr, TEX_FILTER_DEFAULT }
};
#define CODEC_DDS 0xFFFF0001
#define CODEC_TGA 0xFFFF0002
SValue g_pSaveFileTypes[] = // valid formats to write to
{
{ L"BMP", WIC_CODEC_BMP },
{ L"JPG", WIC_CODEC_JPEG },
{ L"JPEG", WIC_CODEC_JPEG },
{ L"PNG", WIC_CODEC_PNG },
{ L"DDS", CODEC_DDS },
{ L"TGA", CODEC_TGA },
{ L"TIF", WIC_CODEC_TIFF },
{ L"TIFF", WIC_CODEC_TIFF },
{ L"WDP", WIC_CODEC_WMP },
{ L"HDP", WIC_CODEC_WMP },
{ nullptr, CODEC_DDS }
};
SValue g_pFeatureLevels[] = // valid feature levels for -fl for maximimum size
{
{ L"9.1", 2048 },
{ L"9.2", 2048 },
{ L"9.3", 4096 },
{ L"10.0", 8192 },
{ L"10.1", 8192 },
{ L"11.0", 16384 },
{ L"11.1", 16384 },
{ L"12.0", 16384 },
{ L"12.1", 16384 },
{ nullptr, 0 },
};
//////////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////
#pragma warning( disable : 4616 6211 )
inline static bool ispow2(size_t x)
{
return ((x != 0) && !(x & (x - 1)));
}
#pragma prefast(disable : 26018, "Only used with static internal arrays")
DWORD LookupByName(const WCHAR *pName, const SValue *pArray)
{
while(pArray->pName)
{
if(!_wcsicmp(pName, pArray->pName))
return pArray->dwValue;
pArray++;
}
return 0;
}
const WCHAR* LookupByValue(DWORD pValue, const SValue *pArray)
{
while(pArray->pName)
{
if(pValue == pArray->dwValue)
return pArray->pName;
pArray++;
}
return L"";
}
void PrintFormat(DXGI_FORMAT Format)
{
for(SValue *pFormat = g_pFormats; pFormat->pName; pFormat++)
{
if((DXGI_FORMAT) pFormat->dwValue == Format)
{
wprintf( pFormat->pName );
return;
}
}
for(SValue *pFormat = g_pReadOnlyFormats; pFormat->pName; pFormat++)
{
if((DXGI_FORMAT) pFormat->dwValue == Format)
{
wprintf( pFormat->pName );
return;
}
}
wprintf( L"*UNKNOWN*" );
}
void PrintInfo( const TexMetadata& info )
{
wprintf( L" (%Iux%Iu", info.width, info.height);
if ( TEX_DIMENSION_TEXTURE3D == info.dimension )
wprintf( L"x%Iu", info.depth);
if ( info.mipLevels > 1 )
wprintf( L",%Iu", info.mipLevels);
if ( info.arraySize > 1 )
wprintf( L",%Iu", info.arraySize);
wprintf( L" ");
PrintFormat( info.format );
switch ( info.dimension )
{
case TEX_DIMENSION_TEXTURE1D:
wprintf( (info.arraySize > 1) ? L" 1DArray" : L" 1D" );
break;
case TEX_DIMENSION_TEXTURE2D:
if ( info.IsCubemap() )
{
wprintf( (info.arraySize > 6) ? L" CubeArray" : L" Cube" );
}
else
{
wprintf( (info.arraySize > 1) ? L" 2DArray" : L" 2D" );
}
break;
case TEX_DIMENSION_TEXTURE3D:
wprintf( L" 3D");
break;
}
wprintf( L")");
}
void PrintList(size_t cch, SValue *pValue)
{
while(pValue->pName)
{
size_t cchName = wcslen(pValue->pName);
if(cch + cchName + 2>= 80)
{
wprintf( L"\n ");
cch = 6;
}
wprintf( L"%ls ", pValue->pName );
cch += cchName + 2;
pValue++;
}
wprintf( L"\n");
}
void PrintLogo()
{
wprintf( L"Microsoft (R) DirectX 11 Texture Converter (DirectXTex version)\n");
wprintf( L"Copyright (C) Microsoft Corp. All rights reserved.\n");
#ifdef _DEBUG
wprintf( L"*** Debug build ***\n");
#endif
wprintf( L"\n");
}
void PrintUsage()
{
PrintLogo();
wprintf( L"Usage: texconv <options> <files>\n");
wprintf( L"\n");
wprintf( L" -w <n> width\n");
wprintf( L" -h <n> height\n");
wprintf( L" -m <n> miplevels\n");
wprintf( L" -f <format> format\n");
wprintf( L" -if <filter> image filtering\n");
wprintf( L" -srgb{i|o} sRGB {input, output}\n");
wprintf( L" -px <string> name prefix\n");
wprintf( L" -sx <string> name suffix\n");
wprintf( L" -o <directory> output directory\n");
wprintf( L" -ft <filetype> output file type\n");
wprintf( L" -hflip horizonal flip of source image\n");
wprintf( L" -vflip vertical flip of source image\n");
wprintf( L" -sepalpha resize/generate mips alpha channel separately\n");
wprintf( L" from color channels\n");
wprintf( L" -wrap, -mirror texture addressing mode (wrap, mirror, or clamp)\n");
wprintf( L" -pmalpha convert final texture to use premultiplied alpha\n");
wprintf( L" -pow2 resize to fit a power-of-2, respecting aspect ratio\n" );
wprintf (L" -nmap <options> converts height-map to normal-map\n"
L" options must be one or more of\n"
L" r, g, b, a, l, m, u, v, i, o\n" );
wprintf (L" -nmapamp <weight> normal map amplitude (defaults to 1.0)\n" );
wprintf( L" -fl <feature-level> Set maximum feature level target (defaults to 11.0)\n");
wprintf( L"\n (DDS input only)\n");
wprintf( L" -t{u|f} TYPELESS format is treated as UNORM or FLOAT\n");
wprintf( L" -dword Use DWORD instead of BYTE alignment\n");
wprintf( L" -xlum expand legacy L8, L16, and A8P8 formats\n");
wprintf( L"\n (DDS output only)\n");
wprintf( L" -dx10 Force use of 'DX10' extended header\n");
wprintf( L"\n -nologo suppress copyright message\n");
wprintf( L" -timing Display elapsed processing time\n\n");
#ifdef _OPENMP
wprintf( L" -singleproc Do not use multi-threaded compression\n");
#endif
wprintf( L" -nogpu Do not use DirectCompute-based codecs\n");
wprintf( L" -bcuniform Use uniform rather than perceptual weighting for BC1-3\n");
wprintf( L" -bcdither Use dithering for BC1-3\n");
wprintf( L" -bcmax Use exchaustive compression (BC7 only)\n");
wprintf( L" -aw <weight> BC7 GPU compressor weighting for alpha error metric\n"
L" (defaults to 1.0)\n" );
wprintf( L"\n");
wprintf( L" <format>: ");
PrintList(13, g_pFormats);
wprintf( L"\n");
wprintf( L" <filter>: ");
PrintList(13, g_pFilters);
wprintf( L"\n");
wprintf( L" <filetype>: ");
PrintList(15, g_pSaveFileTypes);
wprintf( L"\n");
wprintf( L" <feature-level>: ");
PrintList(13, g_pFeatureLevels);
}
_Success_(return != false)
bool CreateDevice( _Outptr_ ID3D11Device** pDevice )
{
if ( !pDevice )
return false;
*pDevice = nullptr;
static PFN_D3D11_CREATE_DEVICE s_DynamicD3D11CreateDevice = nullptr;
if ( !s_DynamicD3D11CreateDevice )
{
HMODULE hModD3D11 = LoadLibrary( L"d3d11.dll" );
if ( !hModD3D11 )
return false;
s_DynamicD3D11CreateDevice = reinterpret_cast<PFN_D3D11_CREATE_DEVICE>( reinterpret_cast<void*>( GetProcAddress( hModD3D11, "D3D11CreateDevice" ) ) );
if ( !s_DynamicD3D11CreateDevice )
return false;
}
D3D_FEATURE_LEVEL featureLevels[] =
{
D3D_FEATURE_LEVEL_11_0,
D3D_FEATURE_LEVEL_10_1,
D3D_FEATURE_LEVEL_10_0,
};
UINT createDeviceFlags = 0;
#ifdef _DEBUG
createDeviceFlags |= D3D11_CREATE_DEVICE_DEBUG;
#endif
D3D_FEATURE_LEVEL fl;
HRESULT hr = s_DynamicD3D11CreateDevice( nullptr, D3D_DRIVER_TYPE_HARDWARE, nullptr, createDeviceFlags, featureLevels, _countof(featureLevels),
D3D11_SDK_VERSION, pDevice, &fl, nullptr );
if ( SUCCEEDED(hr) )
{
if ( fl < D3D_FEATURE_LEVEL_11_0 )
{
D3D11_FEATURE_DATA_D3D10_X_HARDWARE_OPTIONS hwopts;
hr = (*pDevice)->CheckFeatureSupport( D3D11_FEATURE_D3D10_X_HARDWARE_OPTIONS, &hwopts, sizeof(hwopts) );
if ( FAILED(hr) )
memset( &hwopts, 0, sizeof(hwopts) );
if ( !hwopts.ComputeShaders_Plus_RawAndStructuredBuffers_Via_Shader_4_x )
{
if ( *pDevice )
{
(*pDevice)->Release();
*pDevice = nullptr;
}
hr = HRESULT_FROM_WIN32( ERROR_NOT_SUPPORTED );
}
}
}
if ( SUCCEEDED(hr) )
{
ComPtr<IDXGIDevice> dxgiDevice;
hr = (*pDevice)->QueryInterface( __uuidof( IDXGIDevice ), reinterpret_cast< void** >( dxgiDevice.GetAddressOf() ) );
if ( SUCCEEDED(hr) )
{
ComPtr<IDXGIAdapter> pAdapter;
hr = dxgiDevice->GetAdapter( pAdapter.GetAddressOf() );
if ( SUCCEEDED(hr) )
{
DXGI_ADAPTER_DESC desc;
hr = pAdapter->GetDesc( &desc );
if ( SUCCEEDED(hr) )
{
wprintf( L"\n[Using DirectCompute on \"%ls\"]\n", desc.Description );
}
}
}
return true;
}
else
return false;
}
void FitPowerOf2( size_t origx, size_t origy, size_t& targetx, size_t& targety, size_t maxsize )
{
float origAR = float(origx) / float(origy);
if ( origx > origy )
{
size_t x;
for( x = maxsize; x > 1; x >>= 1 ) { if ( x <= targetx ) break; };
targetx = x;
float bestScore = FLT_MAX;
for( size_t y = maxsize; y > 0; y >>= 1 )
{
float score = fabs( (float(x) / float(y)) - origAR );
if ( score < bestScore )
{
bestScore = score;
targety = y;
}
}
}
else
{
size_t y;
for( y = maxsize; y > 1; y >>= 1 ) { if ( y <= targety ) break; };
targety = y;
float bestScore = FLT_MAX;
for( size_t x = maxsize; x > 0; x >>= 1 )
{
float score = fabs( (float(x) / float(y)) - origAR );
if ( score < bestScore )
{
bestScore = score;
targetx = x;
}
}
}
}
//--------------------------------------------------------------------------------------
// Entry-point
//--------------------------------------------------------------------------------------
#pragma prefast(disable : 28198, "Command-line tool, frees all memory on exit")
int __cdecl wmain(_In_ int argc, _In_z_count_(argc) wchar_t* argv[])
{
// Parameters and defaults
size_t width = 0;
size_t height = 0;
size_t mipLevels = 0;
DXGI_FORMAT format = DXGI_FORMAT_UNKNOWN;
DWORD dwFilter = TEX_FILTER_DEFAULT;
DWORD dwSRGB = 0;
DWORD dwCompress = TEX_COMPRESS_DEFAULT;
DWORD dwFilterOpts = 0;
DWORD FileType = CODEC_DDS;
DWORD maxSize = 16384;
float alphaWeight = 1.f;
DWORD dwNormalMap = 0;
float nmapAmplitude = 1.f;
WCHAR szPrefix [MAX_PATH];
WCHAR szSuffix [MAX_PATH];
WCHAR szOutputDir[MAX_PATH];
szPrefix[0] = 0;
szSuffix[0] = 0;
szOutputDir[0] = 0;
// Initialize COM (needed for WIC)
HRESULT hr = CoInitializeEx(nullptr, COINIT_MULTITHREADED);
if( FAILED(hr) )
{
wprintf( L"Failed to initialize COM (%08X)\n", hr);
return 1;
}
// Process command line
DWORD64 dwOptions = 0;
std::list<SConversion> conversion;
for(int iArg = 1; iArg < argc; iArg++)
{
PWSTR pArg = argv[iArg];
if(('-' == pArg[0]) || ('/' == pArg[0]))
{
pArg++;
PWSTR pValue;
for(pValue = pArg; *pValue && (':' != *pValue); pValue++);
if(*pValue)
*pValue++ = 0;
DWORD dwOption = LookupByName(pArg, g_pOptions);
if(!dwOption || (dwOptions & (DWORD64(1) << dwOption)))
{
PrintUsage();
return 1;
}
dwOptions |= (DWORD64(1) << dwOption);
if( (OPT_NOLOGO != dwOption) && (OPT_TIMING != dwOption) && (OPT_TYPELESS_UNORM != dwOption) && (OPT_TYPELESS_FLOAT != dwOption)
&& (OPT_SEPALPHA != dwOption) && (OPT_PREMUL_ALPHA != dwOption) && (OPT_EXPAND_LUMINANCE != dwOption)
&& (OPT_TA_WRAP != dwOption) && (OPT_TA_MIRROR != dwOption)
&& (OPT_FORCE_SINGLEPROC != dwOption) && (OPT_NOGPU != dwOption) && (OPT_FIT_POWEROF2 != dwOption)
&& (OPT_SRGB != dwOption) && (OPT_SRGBI != dwOption) && (OPT_SRGBO != dwOption)
&& (OPT_HFLIP != dwOption) && (OPT_VFLIP != dwOption)
&& (OPT_COMPRESS_UNIFORM != dwOption) && (OPT_COMPRESS_MAX != dwOption) && (OPT_COMPRESS_DITHER != dwOption)
&& (OPT_DDS_DWORD_ALIGN != dwOption) && (OPT_USE_DX10 != dwOption) )
{
if(!*pValue)
{
if((iArg + 1 >= argc))
{
PrintUsage();
return 1;
}
iArg++;
pValue = argv[iArg];
}
}
switch(dwOption)
{
case OPT_WIDTH:
if (swscanf_s(pValue, L"%Iu", &width) != 1)
{
wprintf( L"Invalid value specified with -w (%ls)\n", pValue);
wprintf( L"\n");
PrintUsage();
return 1;
}
break;
case OPT_HEIGHT:
if (swscanf_s(pValue, L"%Iu", &height) != 1)
{
wprintf( L"Invalid value specified with -h (%ls)\n", pValue);
printf("\n");
PrintUsage();
return 1;
}
break;
case OPT_MIPLEVELS:
if (swscanf_s(pValue, L"%Iu", &mipLevels) != 1)
{
wprintf( L"Invalid value specified with -m (%ls)\n", pValue);
wprintf( L"\n");
PrintUsage();
return 1;
}
break;
case OPT_FORMAT:
format = (DXGI_FORMAT) LookupByName(pValue, g_pFormats);
if ( !format )
{
wprintf( L"Invalid value specified with -f (%ls)\n", pValue);
wprintf( L"\n");
PrintUsage();
return 1;
}
break;
case OPT_FILTER:
dwFilter = LookupByName(pValue, g_pFilters);
if ( !dwFilter )
{
wprintf( L"Invalid value specified with -if (%ls)\n", pValue);
wprintf( L"\n");
PrintUsage();
return 1;
}
break;
case OPT_SRGBI:
dwSRGB |= TEX_FILTER_SRGB_IN;
break;
case OPT_SRGBO:
dwSRGB |= TEX_FILTER_SRGB_OUT;
break;
case OPT_SRGB:
dwSRGB |= TEX_FILTER_SRGB;
break;
case OPT_SEPALPHA:
dwFilterOpts |= TEX_FILTER_SEPARATE_ALPHA;
break;
case OPT_PREFIX:
wcscpy_s(szPrefix, MAX_PATH, pValue);
break;
case OPT_SUFFIX:
wcscpy_s(szSuffix, MAX_PATH, pValue);
break;
case OPT_OUTPUTDIR:
wcscpy_s(szOutputDir, MAX_PATH, pValue);
break;
case OPT_FILETYPE:
FileType = LookupByName(pValue, g_pSaveFileTypes);
if ( !FileType )
{
wprintf( L"Invalid value specified with -ft (%ls)\n", pValue);
wprintf( L"\n");
PrintUsage();
return 1;
}
break;
case OPT_TA_WRAP:
if ( dwFilterOpts & TEX_FILTER_MIRROR )
{
wprintf( L"Can't use -wrap and -mirror at same time\n\n");
PrintUsage();
return 1;
}
dwFilterOpts |= TEX_FILTER_WRAP;
break;
case OPT_TA_MIRROR:
if ( dwFilterOpts & TEX_FILTER_WRAP )
{
wprintf( L"Can't use -wrap and -mirror at same time\n\n");
PrintUsage();
return 1;
}
dwFilterOpts |= TEX_FILTER_MIRROR;
break;
case OPT_NORMAL_MAP:
{
dwNormalMap = 0;
if ( wcschr( pValue, L'l' ) )
{
dwNormalMap |= CNMAP_CHANNEL_LUMINANCE;
}
else if ( wcschr( pValue, L'r' ) )
{
dwNormalMap |= CNMAP_CHANNEL_RED;
}
else if ( wcschr( pValue, L'g' ) )
{
dwNormalMap |= CNMAP_CHANNEL_GREEN;
}
else if ( wcschr( pValue, L'b' ) )
{
dwNormalMap |= CNMAP_CHANNEL_BLUE;
}
else if ( wcschr( pValue, L'a' ) )
{
dwNormalMap |= CNMAP_CHANNEL_ALPHA;
}
else
{
wprintf( L"Invalid value specified for -nmap (%ls), missing l, r, g, b, or a\n\n", pValue );
PrintUsage();
return 1;
}
if ( wcschr( pValue, L'm' ) )
{
dwNormalMap |= CNMAP_MIRROR;
}
else
{
if ( wcschr( pValue, L'u' ) )
{
dwNormalMap |= CNMAP_MIRROR_U;
}
if ( wcschr( pValue, L'v' ) )
{
dwNormalMap |= CNMAP_MIRROR_V;
}
}
if ( wcschr( pValue, L'i' ) )
{
dwNormalMap |= CNMAP_INVERT_SIGN;
}
if ( wcschr( pValue, L'o' ) )
{
dwNormalMap |= CNMAP_COMPUTE_OCCLUSION;
}
}
break;
case OPT_NORMAL_MAP_AMPLITUDE:
if ( !dwNormalMap )
{
wprintf( L"-nmapamp requires -nmap\n\n" );
PrintUsage();
return 1;
}
else if (swscanf_s(pValue, L"%f", &nmapAmplitude) != 1)
{
wprintf( L"Invalid value specified with -nmapamp (%ls)\n\n", pValue);
PrintUsage();
return 1;
}
else if ( nmapAmplitude < 0.f )
{
wprintf( L"Normal map amplitude must be positive (%ls)\n\n", pValue);
PrintUsage();
return 1;
}
break;
case OPT_FEATURE_LEVEL:
maxSize = LookupByName( pValue, g_pFeatureLevels );
if ( !maxSize )
{
wprintf( L"Invalid value specified with -fl (%ls)\n", pValue);
wprintf( L"\n");
PrintUsage();
return 1;
}
break;
case OPT_ALPHA_WEIGHT:
if (swscanf_s(pValue, L"%f", &alphaWeight) != 1)
{
wprintf( L"Invalid value specified with -aw (%ls)\n", pValue);
wprintf( L"\n");
PrintUsage();
return 1;
}
else if ( alphaWeight < 0.f )
{
wprintf( L"-aw (%ls) parameter must be positive\n", pValue);
wprintf( L"\n");
return 1;
}
break;
case OPT_COMPRESS_UNIFORM:
dwCompress |= TEX_COMPRESS_UNIFORM;
break;
case OPT_COMPRESS_MAX:
dwCompress |= TEX_COMPRESS_BC7_USE_3SUBSETS;
break;
case OPT_COMPRESS_DITHER:
dwCompress |= TEX_COMPRESS_DITHER;
break;
}
}
else
{
SConversion conv;
wcscpy_s(conv.szSrc, MAX_PATH, pArg);
conv.szDest[0] = 0;
conversion.push_back(conv);
}
}
if(conversion.empty())
{
PrintUsage();
return 0;
}
if(~dwOptions & (DWORD64(1) << OPT_NOLOGO))
PrintLogo();
// Work out out filename prefix and suffix
if(szOutputDir[0] && (L'\\' != szOutputDir[wcslen(szOutputDir) - 1]))
wcscat_s( szOutputDir, MAX_PATH, L"\\" );
if(szPrefix[0])
wcscat_s(szOutputDir, MAX_PATH, szPrefix);
wcscpy_s(szPrefix, MAX_PATH, szOutputDir);
const WCHAR* fileTypeName = LookupByValue(FileType, g_pSaveFileTypes);
if (fileTypeName)
{
wcscat_s(szSuffix, MAX_PATH, L".");
wcscat_s(szSuffix, MAX_PATH, fileTypeName);
}
else
{
wcscat_s(szSuffix, MAX_PATH, L".unknown");
}
if (FileType != CODEC_DDS)
{
mipLevels = 1;
}
LARGE_INTEGER qpcFreq;
if ( !QueryPerformanceFrequency( &qpcFreq ) )
{
qpcFreq.QuadPart = 0;
}
LARGE_INTEGER qpcStart;
if ( !QueryPerformanceCounter( &qpcStart ) )
{
qpcStart.QuadPart = 0;
}
// Convert images
bool nonpow2warn = false;
bool non4bc = false;
ComPtr<ID3D11Device> pDevice;
for( auto pConv = conversion.begin(); pConv != conversion.end(); ++pConv )
{
if ( pConv != conversion.begin() )
wprintf( L"\n");
// Load source image
wprintf( L"reading %ls", pConv->szSrc );
fflush(stdout);
WCHAR ext[_MAX_EXT];
WCHAR fname[_MAX_FNAME];
_wsplitpath_s( pConv->szSrc, nullptr, 0, nullptr, 0, fname, _MAX_FNAME, ext, _MAX_EXT );
TexMetadata info;
std::unique_ptr<ScratchImage> image( new (std::nothrow) ScratchImage );
if ( !image )
{
wprintf( L" ERROR: Memory allocation failed\n" );
return 1;
}
if ( _wcsicmp( ext, L".dds" ) == 0 )
{
DWORD ddsFlags = DDS_FLAGS_NONE;
if ( dwOptions & (DWORD64(1) << OPT_DDS_DWORD_ALIGN) )
ddsFlags |= DDS_FLAGS_LEGACY_DWORD;
if ( dwOptions & (DWORD64(1) << OPT_EXPAND_LUMINANCE) )
ddsFlags |= DDS_FLAGS_EXPAND_LUMINANCE;
hr = LoadFromDDSFile( pConv->szSrc, ddsFlags, &info, *image );
if ( FAILED(hr) )
{
wprintf( L" FAILED (%x)\n", hr);
continue;
}
if ( IsTypeless( info.format ) )
{
if ( dwOptions & (DWORD64(1) << OPT_TYPELESS_UNORM) )
{
info.format = MakeTypelessUNORM( info.format );
}
else if ( dwOptions & (DWORD64(1) << OPT_TYPELESS_FLOAT) )
{
info.format = MakeTypelessFLOAT( info.format );
}
if ( IsTypeless( info.format ) )
{
wprintf( L" FAILED due to Typeless format %d\n", info.format );
continue;
}
image->OverrideFormat( info.format );
}
}
else if ( _wcsicmp( ext, L".tga" ) == 0 )
{
hr = LoadFromTGAFile( pConv->szSrc, &info, *image );
if ( FAILED(hr) )
{
wprintf( L" FAILED (%x)\n", hr);
continue;
}
}
else
{
// WIC shares the same filter values for mode and dither
static_assert( WIC_FLAGS_DITHER == TEX_FILTER_DITHER, "WIC_FLAGS_* & TEX_FILTER_* should match" );
static_assert( WIC_FLAGS_DITHER_DIFFUSION == TEX_FILTER_DITHER_DIFFUSION, "WIC_FLAGS_* & TEX_FILTER_* should match" );
static_assert( WIC_FLAGS_FILTER_POINT == TEX_FILTER_POINT, "WIC_FLAGS_* & TEX_FILTER_* should match" );
static_assert( WIC_FLAGS_FILTER_LINEAR == TEX_FILTER_LINEAR, "WIC_FLAGS_* & TEX_FILTER_* should match" );
static_assert( WIC_FLAGS_FILTER_CUBIC == TEX_FILTER_CUBIC, "WIC_FLAGS_* & TEX_FILTER_* should match" );
static_assert( WIC_FLAGS_FILTER_FANT == TEX_FILTER_FANT, "WIC_FLAGS_* & TEX_FILTER_* should match" );
DWORD wicFlags = dwFilter;
if (FileType == CODEC_DDS)
wicFlags |= WIC_FLAGS_ALL_FRAMES;
hr = LoadFromWICFile( pConv->szSrc, wicFlags, &info, *image );
if ( FAILED(hr) )
{
wprintf( L" FAILED (%x)\n", hr);
continue;
}
}
PrintInfo( info );
size_t tMips = ( !mipLevels && info.mipLevels > 1 ) ? info.mipLevels : mipLevels;
bool sizewarn = false;
size_t twidth = ( !width ) ? info.width : width;
if ( twidth > maxSize )
{
if ( !width )
twidth = maxSize;
else
sizewarn = true;
}
size_t theight = ( !height ) ? info.height : height;
if ( theight > maxSize )
{
if ( !height )
theight = maxSize;
else
sizewarn = true;
}
if ( sizewarn )
{
wprintf( L"\nWARNING: Target size exceeds maximum size for feature level (%u)\n", maxSize );
}
if (dwOptions & (DWORD64(1) << OPT_FIT_POWEROF2))
{
FitPowerOf2( info.width, info.height, twidth, theight, maxSize );
}
// Convert texture
wprintf( L" as");
fflush(stdout);
// --- Planar ------------------------------------------------------------------
if ( IsPlanar( info.format ) )
{
auto img = image->GetImage(0,0,0);
assert( img );
size_t nimg = image->GetImageCount();
std::unique_ptr<ScratchImage> timage( new (std::nothrow) ScratchImage );
if ( !timage )
{
wprintf( L" ERROR: Memory allocation failed\n" );
return 1;
}
hr = ConvertToSinglePlane( img, nimg, info, *timage );
if ( FAILED(hr) )
{
wprintf( L" FAILED [converttosingeplane] (%x)\n", hr);
continue;
}
auto& tinfo = timage->GetMetadata();
info.format = tinfo.format;
assert( info.width == tinfo.width );
assert( info.height == tinfo.height );
assert( info.depth == tinfo.depth );
assert( info.arraySize == tinfo.arraySize );
assert( info.mipLevels == tinfo.mipLevels );
assert( info.miscFlags == tinfo.miscFlags );
assert( info.miscFlags2 == tinfo.miscFlags2 );
assert( info.dimension == tinfo.dimension );
image.swap( timage );
}
DXGI_FORMAT tformat = ( format == DXGI_FORMAT_UNKNOWN ) ? info.format : format;
// --- Decompress --------------------------------------------------------------
std::unique_ptr<ScratchImage> cimage;
if ( IsCompressed( info.format ) )
{
auto img = image->GetImage(0,0,0);
assert( img );
size_t nimg = image->GetImageCount();
std::unique_ptr<ScratchImage> timage( new (std::nothrow) ScratchImage );
if ( !timage )
{
wprintf( L" ERROR: Memory allocation failed\n" );
return 1;
}
hr = Decompress( img, nimg, info, DXGI_FORMAT_UNKNOWN /* picks good default */, *timage );
if ( FAILED(hr) )
{
wprintf( L" FAILED [decompress] (%x)\n", hr);
continue;
}
auto& tinfo = timage->GetMetadata();
info.format = tinfo.format;
assert( info.width == tinfo.width );
assert( info.height == tinfo.height );
assert( info.depth == tinfo.depth );
assert( info.arraySize == tinfo.arraySize );
assert( info.mipLevels == tinfo.mipLevels );
assert( info.miscFlags == tinfo.miscFlags );
assert( info.miscFlags2 == tinfo.miscFlags2 );
assert( info.dimension == tinfo.dimension );
if ( FileType == CODEC_DDS )
{
// Keep the original compressed image in case we can reuse it
cimage.reset( image.release() );
image.reset( timage.release() );
}
else
{
image.swap( timage );
}
}
// --- Flip/Rotate -------------------------------------------------------------
if ( dwOptions & ( (DWORD64(1) << OPT_HFLIP) | (DWORD64(1) << OPT_VFLIP) ) )
{
std::unique_ptr<ScratchImage> timage( new (std::nothrow) ScratchImage );
if ( !timage )
{
wprintf( L" ERROR: Memory allocation failed\n" );
return 1;
}
DWORD dwFlags = 0;
if ( dwOptions & (DWORD64(1) << OPT_HFLIP) )
dwFlags |= TEX_FR_FLIP_HORIZONTAL;
if ( dwOptions & (DWORD64(1) << OPT_VFLIP) )
dwFlags |= TEX_FR_FLIP_VERTICAL;
assert( dwFlags != 0 );
hr = FlipRotate( image->GetImages(), image->GetImageCount(), image->GetMetadata(), dwFlags, *timage );
if ( FAILED(hr) )
{
wprintf( L" FAILED [fliprotate] (%x)\n", hr);
return 1;
}
auto& tinfo = timage->GetMetadata();
assert( tinfo.width == twidth && tinfo.height == theight );
info.width = tinfo.width;
info.height = tinfo.height;
assert( info.depth == tinfo.depth );
assert( info.arraySize == tinfo.arraySize );
assert( info.mipLevels == tinfo.mipLevels );
assert( info.miscFlags == tinfo.miscFlags );
assert( info.miscFlags2 == tinfo.miscFlags2 );
assert( info.format == tinfo.format );
assert( info.dimension == tinfo.dimension );
image.swap( timage );
cimage.reset();
}
// --- Resize ------------------------------------------------------------------
if ( info.width != twidth || info.height != theight )
{
std::unique_ptr<ScratchImage> timage( new (std::nothrow) ScratchImage );
if ( !timage )
{
wprintf( L" ERROR: Memory allocation failed\n" );
return 1;
}
hr = Resize( image->GetImages(), image->GetImageCount(), image->GetMetadata(), twidth, theight, dwFilter | dwFilterOpts, *timage );
if ( FAILED(hr) )
{
wprintf( L" FAILED [resize] (%x)\n", hr);
return 1;
}
auto& tinfo = timage->GetMetadata();
assert( tinfo.width == twidth && tinfo.height == theight && tinfo.mipLevels == 1 );
info.width = tinfo.width;
info.height = tinfo.height;
info.mipLevels = 1;
assert( info.depth == tinfo.depth );
assert( info.arraySize == tinfo.arraySize );
assert( info.miscFlags == tinfo.miscFlags );
assert( info.miscFlags2 == tinfo.miscFlags2 );
assert( info.format == tinfo.format );
assert( info.dimension == tinfo.dimension );
image.swap( timage );
cimage.reset();
}
// --- Convert -----------------------------------------------------------------
if ( dwOptions & (DWORD64(1) << OPT_NORMAL_MAP) )
{
std::unique_ptr<ScratchImage> timage( new (std::nothrow) ScratchImage );
if ( !timage )
{
wprintf( L" ERROR: Memory allocation failed\n" );
return 1;
}
DXGI_FORMAT nmfmt = tformat;
if ( IsCompressed( tformat ) )
{
nmfmt = (dwNormalMap & CNMAP_COMPUTE_OCCLUSION) ? DXGI_FORMAT_R32G32B32A32_FLOAT : DXGI_FORMAT_R32G32B32_FLOAT;
}
hr = ComputeNormalMap( image->GetImages(), image->GetImageCount(), image->GetMetadata(), dwNormalMap, nmapAmplitude, nmfmt, *timage );
if ( FAILED(hr) )
{
wprintf( L" FAILED [normalmap] (%x)\n", hr);
return 1;
}
auto& tinfo = timage->GetMetadata();
assert( tinfo.format == nmfmt );
info.format = tinfo.format;
assert( info.width == tinfo.width );
assert( info.height == tinfo.height );
assert( info.depth == tinfo.depth );
assert( info.arraySize == tinfo.arraySize );
assert( info.mipLevels == tinfo.mipLevels );
assert( info.miscFlags == tinfo.miscFlags );
assert( info.miscFlags2 == tinfo.miscFlags2 );
assert( info.dimension == tinfo.dimension );
image.swap( timage );
cimage.reset();
}
else if ( info.format != tformat && !IsCompressed( tformat ) )
{
std::unique_ptr<ScratchImage> timage( new (std::nothrow) ScratchImage );
if ( !timage )
{
wprintf( L" ERROR: Memory allocation failed\n" );
return 1;
}
hr = Convert( image->GetImages(), image->GetImageCount(), image->GetMetadata(), tformat, dwFilter | dwFilterOpts | dwSRGB, 0.5f, *timage );
if ( FAILED(hr) )
{
wprintf( L" FAILED [convert] (%x)\n", hr);
return 1;
}
auto& tinfo = timage->GetMetadata();
assert( tinfo.format == tformat );
info.format = tinfo.format;
assert( info.width == tinfo.width );
assert( info.height == tinfo.height );
assert( info.depth == tinfo.depth );
assert( info.arraySize == tinfo.arraySize );
assert( info.mipLevels == tinfo.mipLevels );
assert( info.miscFlags == tinfo.miscFlags );
assert( info.miscFlags2 == tinfo.miscFlags2 );
assert( info.dimension == tinfo.dimension );
image.swap( timage );
cimage.reset();
}
// --- Generate mips -----------------------------------------------------------
if ( !ispow2(info.width) || !ispow2(info.height) || !ispow2(info.depth) )
{
if ( info.dimension == TEX_DIMENSION_TEXTURE3D )
{
if ( !tMips )
{
tMips = 1;
}
else
{
wprintf( L" ERROR: Cannot generate mips for non-power-of-2 volume textures\n" );
return 1;
}
}
else if ( !tMips || info.mipLevels != 1 )
{
nonpow2warn = true;
}
}
if ( (!tMips || info.mipLevels != tMips) && ( info.mipLevels != 1 ) )
{
// Mips generation only works on a single base image, so strip off existing mip levels
std::unique_ptr<ScratchImage> timage( new (std::nothrow) ScratchImage );
if ( !timage )
{
wprintf( L" ERROR: Memory allocation failed\n" );
return 1;
}
TexMetadata mdata = info;
mdata.mipLevels = 1;
hr = timage->Initialize( mdata );
if ( FAILED(hr) )
{
wprintf( L" FAILED [copy to single level] (%x)\n", hr);
return 1;
}
if ( info.dimension == TEX_DIMENSION_TEXTURE3D )
{
for( size_t d = 0; d < info.depth; ++d )
{
hr = CopyRectangle( *image->GetImage( 0, 0, d ), Rect( 0, 0, info.width, info.height ),
*timage->GetImage( 0, 0, d ), TEX_FILTER_DEFAULT, 0, 0 );
if ( FAILED(hr) )
{
wprintf( L" FAILED [copy to single level] (%x)\n", hr);
return 1;
}
}
}
else
{
for( size_t i = 0; i < info.arraySize; ++i )
{
hr = CopyRectangle( *image->GetImage( 0, i, 0 ), Rect( 0, 0, info.width, info.height ),
*timage->GetImage( 0, i, 0 ), TEX_FILTER_DEFAULT, 0, 0 );
if ( FAILED(hr) )
{
wprintf( L" FAILED [copy to single level] (%x)\n", hr);
return 1;
}
}
}
image.swap( timage );
info.mipLevels = image->GetMetadata().mipLevels;
if ( cimage && ( tMips == 1 ) )
{
// Special case for trimming mips off compressed images and keeping the original compressed highest level mip
mdata = cimage->GetMetadata();
mdata.mipLevels = 1;
hr = timage->Initialize( mdata );
if ( FAILED(hr) )
{
wprintf( L" FAILED [copy compressed to single level] (%x)\n", hr);
return 1;
}
if ( mdata.dimension == TEX_DIMENSION_TEXTURE3D )
{
for( size_t d = 0; d < mdata.depth; ++d )
{
auto simg = cimage->GetImage( 0, 0, d );
auto dimg = timage->GetImage( 0, 0, d );
memcpy_s( dimg->pixels, dimg->slicePitch, simg->pixels, simg->slicePitch );
}
}
else
{
for( size_t i = 0; i < mdata.arraySize; ++i )
{
auto simg = cimage->GetImage( 0, i, 0 );
auto dimg = timage->GetImage( 0, i, 0 );
memcpy_s( dimg->pixels, dimg->slicePitch, simg->pixels, simg->slicePitch );
}
}
cimage.swap( timage );
}
else
{
cimage.reset();
}
}
if ( ( !tMips || info.mipLevels != tMips ) && ( info.width > 1 || info.height > 1 || info.depth > 1 ) )
{
std::unique_ptr<ScratchImage> timage( new (std::nothrow) ScratchImage );
if ( !timage )
{
wprintf( L" ERROR: Memory allocation failed\n" );
return 1;
}
if ( info.dimension == TEX_DIMENSION_TEXTURE3D )
{
hr = GenerateMipMaps3D( image->GetImages(), image->GetImageCount(), image->GetMetadata(), dwFilter | dwFilterOpts, tMips, *timage );
}
else
{
hr = GenerateMipMaps( image->GetImages(), image->GetImageCount(), image->GetMetadata(), dwFilter | dwFilterOpts, tMips, *timage );
}
if ( FAILED(hr) )
{
wprintf( L" FAILED [mipmaps] (%x)\n", hr);
return 1;
}
auto& tinfo = timage->GetMetadata();
info.mipLevels = tinfo.mipLevels;
assert( info.width == tinfo.width );
assert( info.height == tinfo.height );
assert( info.depth == tinfo.depth );
assert( info.arraySize == tinfo.arraySize );
assert( info.mipLevels == tinfo.mipLevels );
assert( info.miscFlags == tinfo.miscFlags );
assert( info.miscFlags2 == tinfo.miscFlags2 );
assert( info.dimension == tinfo.dimension );
image.swap( timage );
cimage.reset();
}
// --- Premultiplied alpha (if requested) --------------------------------------
if ( ( dwOptions & (DWORD64(1) << OPT_PREMUL_ALPHA) )
&& HasAlpha( info.format )
&& info.format != DXGI_FORMAT_A8_UNORM )
{
if ( info.IsPMAlpha() )
{
printf("WARNING: Image is already using premultiplied alpha\n");
}
else
{
auto img = image->GetImage(0,0,0);
assert( img );
size_t nimg = image->GetImageCount();
std::unique_ptr<ScratchImage> timage( new (std::nothrow) ScratchImage );
if ( !timage )
{
wprintf( L" ERROR: Memory allocation failed\n" );
return 1;
}
hr = PremultiplyAlpha( img, nimg, info, dwSRGB, *timage );
if ( FAILED(hr) )
{
wprintf( L" FAILED [premultiply alpha] (%x)\n", hr);
continue;
}
auto& tinfo = timage->GetMetadata();
info.miscFlags2 = tinfo.miscFlags2;
assert( info.width == tinfo.width );
assert( info.height == tinfo.height );
assert( info.depth == tinfo.depth );
assert( info.arraySize == tinfo.arraySize );
assert( info.mipLevels == tinfo.mipLevels );
assert( info.miscFlags == tinfo.miscFlags );
assert( info.miscFlags2 == tinfo.miscFlags2 );
assert( info.dimension == tinfo.dimension );
image.swap( timage );
cimage.reset();
}
}
// --- Compress ----------------------------------------------------------------
if ( IsCompressed( tformat ) && (FileType == CODEC_DDS) )
{
if ( cimage && ( cimage->GetMetadata().format == tformat ) )
{
// We never changed the image and it was already compressed in our desired format, use original data
image.reset( cimage.release() );
auto& tinfo = image->GetMetadata();
if ( (tinfo.width % 4) != 0 || (tinfo.height % 4) != 0 )
{
non4bc = true;
}
info.format = tinfo.format;
assert( info.width == tinfo.width );
assert( info.height == tinfo.height );
assert( info.depth == tinfo.depth );
assert( info.arraySize == tinfo.arraySize );
assert( info.mipLevels == tinfo.mipLevels );
assert( info.miscFlags == tinfo.miscFlags );
assert( info.miscFlags2 == tinfo.miscFlags2 );
assert( info.dimension == tinfo.dimension );
}
else
{
cimage.reset();
auto img = image->GetImage(0,0,0);
assert( img );
size_t nimg = image->GetImageCount();
std::unique_ptr<ScratchImage> timage( new (std::nothrow) ScratchImage );
if ( !timage )
{
wprintf( L" ERROR: Memory allocation failed\n" );
return 1;
}
bool bc6hbc7=false;
switch( tformat )
{
case DXGI_FORMAT_BC6H_TYPELESS:
case DXGI_FORMAT_BC6H_UF16:
case DXGI_FORMAT_BC6H_SF16:
case DXGI_FORMAT_BC7_TYPELESS:
case DXGI_FORMAT_BC7_UNORM:
case DXGI_FORMAT_BC7_UNORM_SRGB:
bc6hbc7=true;
{
static bool s_tryonce = false;
if ( !s_tryonce )
{
s_tryonce = true;
if ( !(dwOptions & (DWORD64(1) << OPT_NOGPU) ) )
{
if ( !CreateDevice( pDevice.GetAddressOf() ) )
wprintf( L"\nWARNING: DirectCompute is not available, using BC6H / BC7 CPU codec\n" );
}
else
{
wprintf( L"\nWARNING: using BC6H / BC7 CPU codec\n" );
}
}
}
break;
}
DWORD cflags = dwCompress;
#ifdef _OPENMP
if ( !(dwOptions & (DWORD64(1) << OPT_FORCE_SINGLEPROC) ) )
{
cflags |= TEX_COMPRESS_PARALLEL;
}
#endif
if ( (img->width % 4) != 0 || (img->height % 4) != 0 )
{
non4bc = true;
}
if ( bc6hbc7 && pDevice )
{
hr = Compress( pDevice.Get(), img, nimg, info, tformat, dwCompress | dwSRGB, alphaWeight, *timage );
}
else
{
hr = Compress( img, nimg, info, tformat, cflags | dwSRGB, 0.5f, *timage );
}
if ( FAILED(hr) )
{
wprintf( L" FAILED [compress] (%x)\n", hr);
continue;
}
auto& tinfo = timage->GetMetadata();
info.format = tinfo.format;
assert( info.width == tinfo.width );
assert( info.height == tinfo.height );
assert( info.depth == tinfo.depth );
assert( info.arraySize == tinfo.arraySize );
assert( info.mipLevels == tinfo.mipLevels );
assert( info.miscFlags == tinfo.miscFlags );
assert( info.miscFlags2 == tinfo.miscFlags2 );
assert( info.dimension == tinfo.dimension );
image.swap( timage );
}
}
else
{
cimage.reset();
}
// --- Set alpha mode ----------------------------------------------------------
if ( HasAlpha( info.format )
&& info.format != DXGI_FORMAT_A8_UNORM )
{
if ( image->IsAlphaAllOpaque() )
{
info.SetAlphaMode(TEX_ALPHA_MODE_OPAQUE);
}
else if ( info.IsPMAlpha() )
{
// Aleady set TEX_ALPHA_MODE_PREMULTIPLIED
}
else if ( dwOptions & (DWORD64(1) << OPT_SEPALPHA) )
{
info.SetAlphaMode(TEX_ALPHA_MODE_CUSTOM);
}
else
{
info.SetAlphaMode(TEX_ALPHA_MODE_STRAIGHT);
}
}
else
{
info.miscFlags2 &= ~TEX_MISC2_ALPHA_MODE_MASK;
}
// --- Save result -------------------------------------------------------------
{
auto img = image->GetImage(0,0,0);
assert( img );
size_t nimg = image->GetImageCount();
PrintInfo( info );
wprintf( L"\n");
// Figure out dest filename
WCHAR *pchSlash, *pchDot;
wcscpy_s(pConv->szDest, MAX_PATH, szPrefix);
pchSlash = wcsrchr(pConv->szSrc, L'\\');
if(pchSlash != 0)
wcscat_s(pConv->szDest, MAX_PATH, pchSlash + 1);
else
wcscat_s(pConv->szDest, MAX_PATH, pConv->szSrc);
pchSlash = wcsrchr(pConv->szDest, '\\');
pchDot = wcsrchr(pConv->szDest, '.');
if(pchDot > pchSlash)
*pchDot = 0;
wcscat_s(pConv->szDest, MAX_PATH, szSuffix);
// Write texture
wprintf( L"writing %ls", pConv->szDest);
fflush(stdout);
switch( FileType )
{
case CODEC_DDS:
hr = SaveToDDSFile( img, nimg, info,
(dwOptions & (DWORD64(1) << OPT_USE_DX10) ) ? (DDS_FLAGS_FORCE_DX10_EXT|DDS_FLAGS_FORCE_DX10_EXT_MISC2) : DDS_FLAGS_NONE,
pConv->szDest );
break;
case CODEC_TGA:
hr = SaveToTGAFile( img[0], pConv->szDest );
break;
default:
hr = SaveToWICFile( img, nimg, WIC_FLAGS_ALL_FRAMES, GetWICCodec( static_cast<WICCodecs>(FileType) ), pConv->szDest );
break;
}
if(FAILED(hr))
{
wprintf( L" FAILED (%x)\n", hr);
continue;
}
wprintf( L"\n");
}
}
if ( nonpow2warn )
wprintf( L"\n WARNING: Not all feature levels support non-power-of-2 textures with mipmaps\n" );
if ( non4bc )
wprintf( L"\n WARNING: Direct3D requires BC image to be multiple of 4 in width & height\n" );
if(dwOptions & (DWORD64(1) << OPT_TIMING))
{
LARGE_INTEGER qpcEnd;
if ( QueryPerformanceCounter( &qpcEnd ) )
{
LONGLONG delta = qpcEnd.QuadPart - qpcStart.QuadPart;
wprintf( L"\n Processing time: %f seconds\n", double(delta) / double(qpcFreq.QuadPart) );
}
}
return 0;
}