xenia/third_party/crunch/example1/example1.cpp

580 lines
23 KiB
C++

// File: example1.cpp - Simple command line tool that uses the crnlib lib and the crn_decomp.h header file library
// to compress, transcode/unpack, and inspect CRN/DDS textures.
// See Copyright Notice and license at the end of inc/crnlib.h
#include <stdlib.h>
#include <stdio.h>
#include <math.h>
#include <algorithm>
// Public crnlib header.
#include "crnlib.h"
// CRN transcoder library.
#include "crn_decomp.h"
// .DDS file format definitions.
#include "dds_defs.h"
// stb_image, for loading/saving image files.
#ifdef _MSC_VER
#pragma warning (disable: 4244) // conversion from 'int' to 'uint8', possible loss of data
#pragma warning (disable: 4100) // unreferenced formal parameter
#endif
#include "stb_image.h"
// windows.h is only needed here for GetSystemInfo().
#define WIN32_LEAN_AND_MEAN
#define NOMINMAX
#include "windows.h"
using namespace crnlib;
const int cDefaultCRNQualityLevel = 128;
static int print_usage()
{
printf("Description: Simple crnlib API example program.\n");
printf("Copyright (c) 2010-2011 Tenacious Software LLC\n");
printf("Usage: example1 [mode: i/c/d] [source_file] [options]\n");
printf("\nModes:\n");
printf("c: Compress to .DDS or .CRN using the crn_compress() func. in crnlib.h\n");
printf(" The default output format is .DDS\n");
printf(" Supported source image formats:\n");
printf(" Baseline JPEG, PNG, BMP, TGA, PSD, and HDR\n");
printf("d: Transcodes a .CRN file to .DDS using the crn_decompress_crn_to_dds() func.,\n");
printf("or unpacks each face and mipmap level in a .DDS file to multiple .TGA files.\n");
printf("i: Display info about source_file.\n");
printf("\nOptions:\n");
printf("-out filename - Force output filename.\n");
printf("\nCompression mode options:\n");
printf("-crn - Generate a .CRN file instead of .DDS\n");
printf("-bitrate # - Specify desired CRN/DDS bits/texel, from [.1-8]\n");
printf(" When writing .DDS: -bitrate or -quality enable clustered DXTn compression.\n");
printf("-quality # - Specify CRN/DDS quality level factor, from [0-255]\n");
printf("-noAdaptiveBlocks - Always use 4x4 blocks instead of up to 8x8 macroblocks\n");
printf("-nonsrgb - Input is not sRGB: disables gamma filtering, perceptual metrics.\n");
printf("-nomips - Don't generate mipmaps\n");
printf("-setalphatoluma - Set alpha channel to luma before compression.\n");
printf("-converttoluma - Set RGB to luma before compression.\n");
printf("-pixelformat fmt - Output file's crn_format: DXT1, DXT1A, DXT3, DXT5_CCxY,\n");
printf(" DXT5_xGxR, DXT5_xGBR, DXT5_AGBR, DXN_XY (ATI 3DC), DXN_YX (ATI 3DC),\n");
printf(" DXT5A (ATN1N)\n");
printf(" If no output format is specified, this example uses either DXT1 or DXT5.\n");
return EXIT_FAILURE;
}
static int error(const char* pMsg, ...)
{
va_list args;
va_start(args, pMsg);
char buf[512];
vsprintf_s(buf, sizeof(buf), pMsg, args);
va_end(args);
printf("%s", buf);
return EXIT_FAILURE;
}
// Loads an entire file into an allocated memory block.
static crn_uint8 *read_file_into_buffer(const char *pFilename, crn_uint32 &size)
{
size = 0;
FILE* pFile = NULL;
fopen_s(&pFile, pFilename, "rb");
if (!pFile)
return NULL;
fseek(pFile, 0, SEEK_END);
size = ftell(pFile);
fseek(pFile, 0, SEEK_SET);
crn_uint8 *pSrc_file_data = static_cast<crn_uint8*>(malloc(std::max(1U, size)));
if ((!pSrc_file_data) || (fread(pSrc_file_data, size, 1, pFile) != 1))
{
fclose(pFile);
free(pSrc_file_data);
size = 0;
return NULL;
}
fclose(pFile);
return pSrc_file_data;
}
// Cracks a CRN's file header using the helper functions in crn_decomp.h.
static bool print_crn_info(const crn_uint8 *pData, crn_uint32 data_size)
{
crnd::crn_file_info file_info;
if (!crnd::crnd_validate_file(pData, data_size, &file_info))
return false;
printf("crnd_validate_file:\n");
printf("File size: %u\nActualDataSize: %u\nHeaderSize: %u\nTotalPaletteSize: %u\nTablesSize: %u\nLevels: %u\n", data_size,
file_info.m_actual_data_size, file_info.m_header_size, file_info.m_total_palette_size, file_info.m_tables_size, file_info.m_levels);
printf("LevelCompressedSize: ");
for (crn_uint32 i = 0; i < cCRNMaxLevels; i++)
printf("%u ", file_info.m_level_compressed_size[i]);
printf("\n");
printf("ColorEndpointPaletteSize: %u\n", file_info.m_color_endpoint_palette_entries);
printf("ColorSelectorPaletteSize: %u\n", file_info.m_color_selector_palette_entries);
printf("AlphaEndpointPaletteSize: %u\n", file_info.m_alpha_endpoint_palette_entries);
printf("AlphaSelectorPaletteSize: %u\n", file_info.m_alpha_selector_palette_entries);
printf("crnd_get_texture_info:\n");
crnd::crn_texture_info tex_info;
if (!crnd::crnd_get_texture_info(pData, data_size, &tex_info))
return false;
printf("Dimensions: %ux%u\nLevels: %u\nFaces: %u\nBytesPerBlock: %u\nUserData0: %u\nUserData1: %u\nCrnFormat: %S\n",
tex_info.m_width, tex_info.m_height, tex_info.m_levels, tex_info.m_faces, tex_info.m_bytes_per_block, tex_info.m_userdata0, tex_info.m_userdata1, crn_get_format_string(tex_info.m_format));
return true;
}
// Cracks the DDS header and dump its contents.
static bool print_dds_info(const void *pData, crn_uint32 data_size)
{
if ((data_size < 128) || (*reinterpret_cast<const crn_uint32*>(pData) != crnlib::cDDSFileSignature))
return false;
const crnlib::DDSURFACEDESC2 &desc = *reinterpret_cast<const crnlib::DDSURFACEDESC2*>((reinterpret_cast<const crn_uint8*>(pData) + sizeof(crn_uint32)));
if (desc.dwSize != sizeof(crnlib::DDSURFACEDESC2))
return false;
printf("DDS file information:\n");
printf("File size: %u\nDimensions: %ux%u\nPitch/LinearSize: %u\n", data_size, desc.dwWidth, desc.dwHeight, desc.dwLinearSize);
printf("MipMapCount: %u\nAlphaBitDepth: %u\n", desc.dwMipMapCount, desc.dwAlphaBitDepth);
const char *pDDSDFlagNames[] =
{
"DDSD_CAPS", "DDSD_HEIGHT", "DDSD_WIDTH", "DDSD_PITCH",
NULL, "DDSD_BACKBUFFERCOUNT", "DDSD_ZBUFFERBITDEPTH", "DDSD_ALPHABITDEPTH",
NULL, NULL, NULL, "DDSD_LPSURFACE",
"DDSD_PIXELFORMAT", "DDSD_CKDESTOVERLAY", "DDSD_CKDESTBLT", "DDSD_CKSRCOVERLAY",
"DDSD_CKSRCBLT", "DDSD_MIPMAPCOUNT", "DDSD_REFRESHRATE", "DDSD_LINEARSIZE",
"DDSD_TEXTURESTAGE", "DDSD_FVF", "DDSD_SRCVBHANDLE", "DDSD_DEPTH"
};
printf("DDSD Flags: 0x%08X ", desc.dwFlags);
for (int i = 0; i < sizeof(pDDSDFlagNames)/sizeof(pDDSDFlagNames[0]); i++)
if ((pDDSDFlagNames[i]) && (desc.dwFlags & (1 << i)))
printf("%s ", pDDSDFlagNames[i]);
printf("\n\n");
printf("ddpfPixelFormat.dwFlags: 0x%08X ", desc.ddpfPixelFormat.dwFlags);
if (desc.ddpfPixelFormat.dwFlags & DDPF_ALPHAPIXELS) printf("DDPF_ALPHAPIXELS ");
if (desc.ddpfPixelFormat.dwFlags & DDPF_ALPHA) printf("DDPF_ALPHA ");
if (desc.ddpfPixelFormat.dwFlags & DDPF_FOURCC) printf("DDPF_FOURCC ");
if (desc.ddpfPixelFormat.dwFlags & DDPF_PALETTEINDEXED8) printf("DDPF_PALETTEINDEXED8 ");
if (desc.ddpfPixelFormat.dwFlags & DDPF_RGB) printf("DDPF_RGB ");
if (desc.ddpfPixelFormat.dwFlags & DDPF_LUMINANCE) printf("DDPF_LUMINANCE ");
printf("\n");
printf("ddpfPixelFormat.dwFourCC: 0x%08X '%c' '%c' '%c' '%c'\n",
desc.ddpfPixelFormat.dwFourCC,
std::max(32U, desc.ddpfPixelFormat.dwFourCC & 0xFF),
std::max(32U, (desc.ddpfPixelFormat.dwFourCC >> 8) & 0xFF),
std::max(32U, (desc.ddpfPixelFormat.dwFourCC >> 16) & 0xFF),
std::max(32U, (desc.ddpfPixelFormat.dwFourCC >> 24) & 0xFF));
printf("dwRGBBitCount: %u 0x%08X\n",
desc.ddpfPixelFormat.dwRGBBitCount, desc.ddpfPixelFormat.dwRGBBitCount);
printf("dwRGBBitCount as FOURCC: '%c' '%c' '%c' '%c'\n",
std::max(32U, desc.ddpfPixelFormat.dwRGBBitCount & 0xFF),
std::max(32U, (desc.ddpfPixelFormat.dwRGBBitCount >> 8) & 0xFF),
std::max(32U, (desc.ddpfPixelFormat.dwRGBBitCount >> 16) & 0xFF),
std::max(32U, (desc.ddpfPixelFormat.dwRGBBitCount >> 24) & 0xFF));
printf("dwRBitMask: 0x%08X\ndwGBitMask: 0x%08X\ndwBBitMask: 0x%08X\ndwRGBAlphaBitMask: 0x%08X\n",
desc.ddpfPixelFormat.dwRBitMask, desc.ddpfPixelFormat.dwGBitMask, desc.ddpfPixelFormat.dwBBitMask, desc.ddpfPixelFormat.dwRGBAlphaBitMask);
printf("\n");
printf("ddsCaps.dwCaps: 0x%08X ", desc.ddsCaps.dwCaps);
if (desc.ddsCaps.dwCaps & DDSCAPS_COMPLEX) printf("DDSCAPS_COMPLEX ");
if (desc.ddsCaps.dwCaps & DDSCAPS_TEXTURE) printf("DDSCAPS_TEXTURE ");
if (desc.ddsCaps.dwCaps & DDSCAPS_MIPMAP) printf("DDSCAPS_MIPMAP");
printf("\n");
printf("ddsCaps.dwCaps2: 0x%08X ", desc.ddsCaps.dwCaps2);
const char *pDDCAPS2FlagNames[] =
{
NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL,
NULL, "DDSCAPS2_CUBEMAP", "DDSCAPS2_CUBEMAP_POSITIVEX", "DDSCAPS2_CUBEMAP_NEGATIVEX",
"DDSCAPS2_CUBEMAP_POSITIVEY", "DDSCAPS2_CUBEMAP_NEGATIVEY", "DDSCAPS2_CUBEMAP_POSITIVEZ", "DDSCAPS2_CUBEMAP_NEGATIVEZ",
NULL, NULL, NULL, NULL,
NULL, "DDSCAPS2_VOLUME"
};
for (int i = 0; i < sizeof(pDDCAPS2FlagNames)/sizeof(pDDCAPS2FlagNames[0]); i++)
if ((pDDCAPS2FlagNames[i]) && (desc.ddsCaps.dwCaps2 & (1 << i)))
printf("%s ", pDDCAPS2FlagNames[i]);
printf("\n");
printf("ddsCaps.dwCaps3: 0x%08X\nddsCaps.dwCaps4: 0x%08X\n",
desc.ddsCaps.dwCaps3, desc.ddsCaps.dwCaps4);
return true;
}
// CRN/DDS compression callback function.
static crn_bool progress_callback_func(crn_uint32 phase_index, crn_uint32 total_phases, crn_uint32 subphase_index, crn_uint32 total_subphases, void* pUser_data_ptr)
{
int percentage_complete = (int)(.5f + (phase_index + float(subphase_index) / total_subphases) * 100.0f) / total_phases;
printf("\b\b\b\b\b\b\b\b\b\b\b\b\b\b\b\b\bProcessing: %u%%", std::min(100, std::max(0, percentage_complete)));
return true;
}
int main(int argc, char *argv[])
{
printf("example1 - Version v%u.%02u Built " __DATE__ ", " __TIME__ "\n", CRNLIB_VERSION / 100, CRNLIB_VERSION % 100);
if (argc < 3)
return print_usage();
// Parse command line options
int mode = argv[1][0];
if ((mode != 'c') && (mode != 'd') && (mode != 'i'))
return error("Invalid mode!\n");
const char *pSrc_filename = argv[2];
char out_filename[FILENAME_MAX] = { '\0' };
float bitrate = 0.0f;
int quality_level = -1;
bool srgb_colorspace = true;
bool create_mipmaps = true;
bool output_crn = false;
crn_format fmt = cCRNFmtInvalid;
bool use_adaptive_block_sizes = true;
bool set_alpha_to_luma = false;
bool convert_to_luma = false;
bool enable_dxt1a = false;
for (int i = 3; i < argc; i++)
{
if (argv[i][0] == '/')
argv[i][0] = '-';
if (!_stricmp(argv[i], "-crn"))
{
output_crn = true;
}
else if (!_stricmp(argv[i], "-pixelformat"))
{
if (++i >= argc)
return error("Expected pixel format!");
if (!_stricmp(argv[i], "dxt1a"))
{
enable_dxt1a = true;
fmt = cCRNFmtDXT1;
}
else
{
uint f;
for (f = 0; f < cCRNFmtTotal; f++)
{
if (!_stricmp(argv[i], crn_get_format_string(static_cast<crn_format>(f))))
{
fmt = static_cast<crn_format>(f);
break;
}
}
if (f == cCRNFmtTotal)
return error("Unrecognized pixel format: %s\n", argv[i]);
}
}
else if (!_stricmp(argv[i], "-bitrate"))
{
if (++i >= argc)
return error("Invalid bitrate!");
bitrate = (float)atof(argv[i]);
if ((bitrate < .1f) || (bitrate > 8.0f))
return error("Invalid bitrate!");
}
else if (!_stricmp(argv[i], "-quality"))
{
if (++i >= argc)
return error("Invalid quality level!");
quality_level = atoi(argv[i]);
if ((quality_level < 0) || (quality_level > cCRNMaxQualityLevel))
return error("Invalid quality level!");
}
else if (!_stricmp(argv[i], "-out"))
{
if (++i >= argc)
return error("Expected output filename!");
strcpy_s(out_filename, sizeof(out_filename), argv[i]);
}
else if (!_stricmp(argv[i], "-nonsrgb"))
srgb_colorspace = false;
else if (!_stricmp(argv[i], "-nomips"))
create_mipmaps = false;
else if (!_stricmp(argv[i], "-noAdaptiveBlocks"))
use_adaptive_block_sizes = false;
else if (!_stricmp(argv[i], "-setalphatoluma"))
set_alpha_to_luma = true;
else if (!_stricmp(argv[i], "-converttoluma"))
convert_to_luma = true;
else
return error("Invalid option: %s\n", argv[i]);
}
char drive_buf[_MAX_DRIVE], dir_buf[_MAX_DIR], fname_buf[_MAX_FNAME], ext_buf[_MAX_EXT];
if (_splitpath_s(pSrc_filename, drive_buf, _MAX_DRIVE, dir_buf, _MAX_DIR, fname_buf, _MAX_FNAME, ext_buf, _MAX_EXT))
return error("Invalid source filename!\n");
// Load the source file into memory.
printf("Loading source file: %s\n", pSrc_filename);
crn_uint32 src_file_size;
crn_uint8 *pSrc_file_data = read_file_into_buffer(pSrc_filename, src_file_size);
if (!pSrc_file_data)
return error("Unable to read source file\n");
if (mode == 'i')
{
// Information
if (_stricmp(ext_buf, ".crn") == 0)
{
if (!print_crn_info(pSrc_file_data, src_file_size))
{
free(pSrc_file_data);
return error("Not a CRN file!\n");
}
}
else if (_stricmp(ext_buf, ".dds") == 0)
{
if (!print_dds_info(pSrc_file_data, src_file_size))
{
free(pSrc_file_data);
return error("Not a DDS file!\n");
}
}
else
{
// Try parsing the source file as a regular image.
int x, y, actual_comps;
stbi_uc *p = stbi_load_from_memory(pSrc_file_data, src_file_size, &x, &y, &actual_comps, 4);
if (!p)
{
free(pSrc_file_data);
return error("Failed reading image file!\n");
}
stbi_image_free(p);
printf("File size: %u\nDimensions: %ix%i\nActual Components: %i\n", src_file_size, x, y, actual_comps);
}
}
else if (mode == 'c')
{
// Compression to DDS or CRN.
// If the user has explicitly specified an output file, check the output file's extension to ensure we write the expected format.
if (out_filename[0])
{
char out_fname_buf[_MAX_FNAME], out_ext_buf[_MAX_EXT];
_splitpath_s(out_filename, NULL, 0, NULL, 0, out_fname_buf, _MAX_FNAME, out_ext_buf, _MAX_EXT);
if (!_stricmp(out_ext_buf, ".crn"))
output_crn = true;
else if (!_stricmp(out_ext_buf, ".dds"))
output_crn = false;
}
// Load source image
int width, height, actual_comps;
crn_uint32 *pSrc_image = (crn_uint32*)stbi_load_from_memory(pSrc_file_data, src_file_size, &width, &height, &actual_comps, 4);
if (!pSrc_image)
{
free(pSrc_file_data);
return error("Failed reading image file!\n");
}
printf("Source file size: %u, Dimensions: %ux%u\nActual Components: %u\n", src_file_size, width, height, actual_comps);
// Fill in compression parameters struct.
bool has_alpha_channel = actual_comps > 3;
if ((fmt == cCRNFmtDXT5A) && (actual_comps <= 3))
set_alpha_to_luma = true;
if ((set_alpha_to_luma) || (convert_to_luma))
{
for (int i = 0; i < width * height; i++)
{
crn_uint32 r = pSrc_image[i] & 0xFF, g = (pSrc_image[i] >> 8) & 0xFF, b = (pSrc_image[i] >> 16) & 0xFF;
// Compute CCIR 601 luma.
crn_uint32 y = (19595U * r + 38470U * g + 7471U * b + 32768) >> 16U;
crn_uint32 a = (pSrc_image[i] >> 24) & 0xFF;
if (set_alpha_to_luma) a = y;
if (convert_to_luma) { r = y; g = y; b = y; }
pSrc_image[i] = r | (g << 8) | (b << 16) | (a << 24);
}
}
crn_comp_params comp_params;
comp_params.m_width = width;
comp_params.m_height = height;
comp_params.set_flag(cCRNCompFlagPerceptual, srgb_colorspace);
comp_params.set_flag(cCRNCompFlagDXT1AForTransparency, enable_dxt1a && has_alpha_channel);
comp_params.set_flag(cCRNCompFlagHierarchical, use_adaptive_block_sizes);
comp_params.m_file_type = output_crn ? cCRNFileTypeCRN : cCRNFileTypeDDS;
comp_params.m_format = (fmt != cCRNFmtInvalid) ? fmt : (has_alpha_channel ? cCRNFmtDXT5 : cCRNFmtDXT1);
// Important note: This example only feeds a single source image to the compressor, and it internaly generates mipmaps from that source image.
// If you want, there's nothing stopping you from generating the mipmaps on your own, then feeding the multiple source images
// to the compressor. Just set the crn_mipmap_params::m_mode member (set below) to cCRNMipModeUseSourceMips.
comp_params.m_pImages[0][0] = pSrc_image;
if (bitrate > 0.0f)
comp_params.m_target_bitrate = bitrate;
else if (quality_level >= 0)
comp_params.m_quality_level = quality_level;
else if (output_crn)
{
// Set a default quality level for CRN, otherwise we'll get the default (highest quality) which leads to huge compressed palettes.
comp_params.m_quality_level = cDefaultCRNQualityLevel;
}
// Determine the # of helper threads (in addition to the main thread) to use during compression. NumberOfCPU's-1 is reasonable.
SYSTEM_INFO g_system_info;
GetSystemInfo(&g_system_info);
int num_helper_threads = std::max<int>(0, (int)g_system_info.dwNumberOfProcessors - 1);
comp_params.m_num_helper_threads = num_helper_threads;
comp_params.m_pProgress_func = progress_callback_func;
// Fill in mipmap parameters struct.
crn_mipmap_params mip_params;
mip_params.m_gamma_filtering = srgb_colorspace;
mip_params.m_mode = create_mipmaps ? cCRNMipModeGenerateMips : cCRNMipModeNoMips;
crn_uint32 actual_quality_level;
float actual_bitrate;
crn_uint32 output_file_size;
printf("Compressing to %s\n", crn_get_format_string(comp_params.m_format));
// Now compress to DDS or CRN.
void *pOutput_file_data = crn_compress(comp_params, mip_params, output_file_size, &actual_quality_level, &actual_bitrate);
printf("\n");
if (!pOutput_file_data)
{
stbi_image_free(pSrc_image);
free(pSrc_file_data);
return error("Compression failed!");
}
printf("Compressed to %u bytes, quality level: %u, effective bitrate: %f\n", output_file_size, actual_quality_level, actual_bitrate);
// Write the output file.
char dst_filename[FILENAME_MAX];
sprintf_s(dst_filename, sizeof(dst_filename), "%s%s%s%s", drive_buf, dir_buf, fname_buf, output_crn ? ".crn" : ".dds");
if (out_filename[0]) strcpy(dst_filename, out_filename);
printf("Writing %s file: %s\n", output_crn ? "CRN" : "DDS", dst_filename);
FILE *pFile = fopen(dst_filename, "wb");
if ((!pFile) || (fwrite(pOutput_file_data, output_file_size, 1, pFile) != 1) || (fclose(pFile) == EOF))
{
free(pSrc_file_data);
crn_free_block(pOutput_file_data);
stbi_image_free(pSrc_image);
return error("Failed writing to output file!\n");
}
crn_free_block(pOutput_file_data);
stbi_image_free(pSrc_image);
}
else if (_stricmp(ext_buf, ".crn") == 0)
{
// Decompress/transcode CRN to DDS.
printf("Decompressing CRN to DDS\n");
// Transcode the CRN file to a DDS file in memory.
crn_uint32 dds_file_size = src_file_size;
void *pDDS_file_data = crn_decompress_crn_to_dds(pSrc_file_data, dds_file_size);
if (!pDDS_file_data)
{
free(pSrc_file_data);
return error("Failed decompressing CRN file!\n");
}
// Now write the DDS file to disk.
char dst_filename[FILENAME_MAX];
sprintf_s(dst_filename, sizeof(dst_filename), "%s%s%s.dds", drive_buf, dir_buf, fname_buf);
if (out_filename[0]) strcpy(dst_filename, out_filename);
printf("Writing file: %s\n", dst_filename);
FILE *pFile = fopen(dst_filename, "wb");
if ((!pFile) || (fwrite(pDDS_file_data, dds_file_size, 1, pFile) != 1) || (fclose(pFile) == EOF))
{
crn_free_block(pDDS_file_data);
free(pSrc_file_data);
return error("Failed writing to output file!\n");
}
printf("\n");
print_dds_info(pDDS_file_data, dds_file_size);
crn_free_block(pDDS_file_data);
}
else if (_stricmp(ext_buf, ".dds") == 0)
{
// Unpack DDS to one or more TGA's.
if (out_filename[0])
_splitpath_s(out_filename, drive_buf, _MAX_DRIVE, dir_buf, _MAX_DIR, fname_buf, _MAX_FNAME, ext_buf, _MAX_EXT);
crn_texture_desc tex_desc;
crn_uint32 *pImages[cCRNMaxFaces * cCRNMaxLevels];
if (!crn_decompress_dds_to_images(pSrc_file_data, src_file_size, pImages, tex_desc))
{
free(pSrc_file_data);
return error("Failed unpacking DDS file!\n");
}
printf("Decompressed texture Dimensions: %ux%u, Faces: %u, Levels: %u, FourCC: 0x%08X '%c' '%c' '%c' '%c'\n",
tex_desc.m_width, tex_desc.m_height, tex_desc.m_faces, tex_desc.m_levels, tex_desc.m_fmt_fourcc,
std::max(32U, tex_desc.m_fmt_fourcc & 0xFF),
std::max(32U, (tex_desc.m_fmt_fourcc >> 8) & 0xFF),
std::max(32U, (tex_desc.m_fmt_fourcc >> 16) & 0xFF),
std::max(32U, (tex_desc.m_fmt_fourcc >> 24) & 0xFF));
for (crn_uint32 face_index = 0; face_index < tex_desc.m_faces; face_index++)
{
for (crn_uint32 level_index = 0; level_index < tex_desc.m_levels; level_index++)
{
int width = std::max(1U, tex_desc.m_width >> level_index);
int height = std::max(1U, tex_desc.m_height >> level_index);
char dst_filename[FILENAME_MAX];
sprintf_s(dst_filename, sizeof(dst_filename), "%s%s%s_face%u_mip%u.tga", drive_buf, dir_buf, fname_buf, face_index, level_index);
printf("Writing file: %s\n", dst_filename);
if (!stbi_write_tga(dst_filename, width, height, 4, pImages[level_index + face_index * tex_desc.m_levels]))
{
crn_free_all_images(pImages, tex_desc);
free(pSrc_file_data);
return error("Failed writing output file!\n");
}
}
}
crn_free_all_images(pImages, tex_desc);
}
else
{
free(pSrc_file_data);
return error("Decompression mode only supports .dds or .crn files!\n");
}
free(pSrc_file_data);
return EXIT_SUCCESS;
}