UVAtlas/UVAtlasTool/UVAtlas.cpp
2022-03-12 17:28:02 -08:00

1658 lines
55 KiB
C++

//--------------------------------------------------------------------------------------
// File: UVAtlas.cpp
//
// UVAtlas command-line tool (sample for UVAtlas library)
//
// Copyright (c) Microsoft Corporation.
// Licensed under the MIT License.
//
// http://go.microsoft.com/fwlink/?LinkID=512686
//--------------------------------------------------------------------------------------
#pragma warning(push)
#pragma warning(disable : 4005)
#define WIN32_LEAN_AND_MEAN
#define NOMINMAX
#define NODRAWTEXT
#define NOGDI
#define NOMCX
#define NOSERVICE
#define NOHELP
#pragma warning(pop)
#include <algorithm>
#include <cassert>
#include <cstddef>
#include <cstdint>
#include <cstdio>
#include <cstdlib>
#include <cwchar>
#include <cwctype>
#include <fstream>
#include <iterator>
#include <list>
#include <locale>
#include <memory>
#include <new>
#include <set>
#include <string>
#include <tuple>
#include <conio.h>
#include <dxgiformat.h>
#include "UVAtlas.h"
#include "DirectXTex.h"
#include "Mesh.h"
//Uncomment to add support for OpenEXR (.exr)
//#define USE_OPENEXR
#ifdef USE_OPENEXR
// See <https://github.com/Microsoft/DirectXTex/wiki/Adding-OpenEXR> for details
#include "DirectXTexEXR.h"
#endif
using namespace DirectX;
namespace
{
enum OPTIONS : uint64_t
{
OPT_RECURSIVE = 1,
OPT_QUALITY,
OPT_MAXCHARTS,
OPT_MAXSTRETCH,
OPT_LIMIT_MERGE_STRETCH,
OPT_LIMIT_FACE_STRETCH,
OPT_GUTTER,
OPT_WIDTH,
OPT_HEIGHT,
OPT_TOPOLOGICAL_ADJ,
OPT_GEOMETRIC_ADJ,
OPT_NORMALS,
OPT_WEIGHT_BY_AREA,
OPT_WEIGHT_BY_EQUAL,
OPT_TANGENTS,
OPT_CTF,
OPT_COLOR_MESH,
OPT_UV_MESH,
OPT_IMT_TEXFILE,
OPT_IMT_VERTEX,
OPT_OUTPUTFILE,
OPT_TOLOWER,
OPT_SDKMESH,
OPT_SDKMESH_V2,
OPT_CMO,
OPT_VBO,
OPT_WAVEFRONT_OBJ,
OPT_CLOCKWISE,
OPT_FORCE_32BIT_IB,
OPT_OVERWRITE,
OPT_NODDS,
OPT_FLIP,
OPT_FLIPU,
OPT_FLIPV,
OPT_FLIPZ,
OPT_VERT_NORMAL_FORMAT,
OPT_VERT_UV_FORMAT,
OPT_VERT_COLOR_FORMAT,
OPT_SECOND_UV,
OPT_NOLOGO,
OPT_FILELIST,
OPT_MAX
};
static_assert(OPT_MAX <= 64, "dwOptions is a unsigned int bitfield");
enum CHANNELS
{
CHANNEL_NONE = 0,
CHANNEL_NORMAL,
CHANNEL_COLOR,
CHANNEL_TEXCOORD,
};
struct SConversion
{
wchar_t szSrc[MAX_PATH];
};
template<typename T>
struct SValue
{
const wchar_t* name;
T value;
};
const XMFLOAT3 g_ColorList[8] =
{
XMFLOAT3(1.0f, 0.5f, 0.5f),
XMFLOAT3(0.5f, 1.0f, 0.5f),
XMFLOAT3(1.0f, 1.0f, 0.5f),
XMFLOAT3(0.5f, 1.0f, 1.0f),
XMFLOAT3(1.0f, 0.5f, 0.75f),
XMFLOAT3(0.0f, 0.5f, 0.75f),
XMFLOAT3(0.5f, 0.5f, 0.75f),
XMFLOAT3(0.5f, 0.5f, 1.0f),
};
//////////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////
const SValue<uint64_t> g_pOptions[] =
{
{ L"r", OPT_RECURSIVE },
{ L"q", OPT_QUALITY },
{ L"n", OPT_MAXCHARTS },
{ L"st", OPT_MAXSTRETCH },
{ L"lms", OPT_LIMIT_MERGE_STRETCH },
{ L"lfs", OPT_LIMIT_FACE_STRETCH },
{ L"g", OPT_GUTTER },
{ L"w", OPT_WIDTH },
{ L"h", OPT_HEIGHT },
{ L"ta", OPT_TOPOLOGICAL_ADJ },
{ L"ga", OPT_GEOMETRIC_ADJ },
{ L"nn", OPT_NORMALS },
{ L"na", OPT_WEIGHT_BY_AREA },
{ L"ne", OPT_WEIGHT_BY_EQUAL },
{ L"tt", OPT_TANGENTS },
{ L"tb", OPT_CTF },
{ L"c", OPT_COLOR_MESH },
{ L"t", OPT_UV_MESH },
{ L"it", OPT_IMT_TEXFILE },
{ L"iv", OPT_IMT_VERTEX },
{ L"o", OPT_OUTPUTFILE },
{ L"l", OPT_TOLOWER },
{ L"sdkmesh", OPT_SDKMESH },
{ L"sdkmesh2", OPT_SDKMESH_V2 },
{ L"cmo", OPT_CMO },
{ L"vbo", OPT_VBO },
{ L"wf", OPT_WAVEFRONT_OBJ },
{ L"cw", OPT_CLOCKWISE },
{ L"ib32", OPT_FORCE_32BIT_IB },
{ L"y", OPT_OVERWRITE },
{ L"nodds", OPT_NODDS },
{ L"flip", OPT_FLIP },
{ L"flipu", OPT_FLIPU },
{ L"flipv", OPT_FLIPV },
{ L"flipz", OPT_FLIPZ },
{ L"fn", OPT_VERT_NORMAL_FORMAT },
{ L"fuv", OPT_VERT_UV_FORMAT },
{ L"fc", OPT_VERT_COLOR_FORMAT },
{ L"uv2", OPT_SECOND_UV },
{ L"nologo", OPT_NOLOGO },
{ L"flist", OPT_FILELIST },
{ nullptr, 0 }
};
const SValue<uint32_t> g_vertexNormalFormats[] =
{
{ L"float3", DXGI_FORMAT_R32G32B32_FLOAT },
{ L"float16_4", DXGI_FORMAT_R16G16B16A16_FLOAT },
{ L"r11g11b10", DXGI_FORMAT_R11G11B10_FLOAT },
{ nullptr, 0 }
};
const SValue<uint32_t> g_vertexUVFormats[] =
{
{ L"float2", DXGI_FORMAT_R32G32_FLOAT },
{ L"float16_2", DXGI_FORMAT_R16G16_FLOAT },
{ nullptr, 0 }
};
const SValue<uint32_t> g_vertexColorFormats[] =
{
{ L"bgra", DXGI_FORMAT_B8G8R8A8_UNORM },
{ L"rgba", DXGI_FORMAT_R8G8B8A8_UNORM },
{ L"float4", DXGI_FORMAT_R32G32B32A32_FLOAT },
{ L"float16_4", DXGI_FORMAT_R16G16B16A16_FLOAT },
{ L"rgba_10", DXGI_FORMAT_R10G10B10A2_UNORM },
{ L"r11g11b10", DXGI_FORMAT_R11G11B10_FLOAT },
{ nullptr, 0 }
};
}
//////////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////
HRESULT LoadFromOBJ(const wchar_t* szFilename,
std::unique_ptr<Mesh>& inMesh, std::vector<Mesh::Material>& inMaterial,
bool ccw, bool dds);
//////////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////
namespace
{
inline HANDLE safe_handle(HANDLE h) noexcept { return (h == INVALID_HANDLE_VALUE) ? nullptr : h; }
struct find_closer { void operator()(HANDLE h) noexcept { assert(h != INVALID_HANDLE_VALUE); if (h) FindClose(h); } };
using ScopedFindHandle = std::unique_ptr<void, find_closer>;
#ifdef __PREFAST__
#pragma prefast(disable : 26018, "Only used with static internal arrays")
#endif
template<typename T>
T LookupByName(const wchar_t *pName, const SValue<T> *pArray)
{
while (pArray->name)
{
if (!_wcsicmp(pName, pArray->name))
return pArray->value;
pArray++;
}
return 0;
}
void SearchForFiles(const wchar_t* path, std::list<SConversion>& files, bool recursive)
{
// Process files
WIN32_FIND_DATAW findData = {};
ScopedFindHandle hFile(safe_handle(FindFirstFileExW(path,
FindExInfoBasic, &findData,
FindExSearchNameMatch, nullptr,
FIND_FIRST_EX_LARGE_FETCH)));
if (hFile)
{
for (;;)
{
if (!(findData.dwFileAttributes & (FILE_ATTRIBUTE_HIDDEN | FILE_ATTRIBUTE_SYSTEM | FILE_ATTRIBUTE_DIRECTORY)))
{
wchar_t drive[_MAX_DRIVE] = {};
wchar_t dir[_MAX_DIR] = {};
_wsplitpath_s(path, drive, _MAX_DRIVE, dir, _MAX_DIR, nullptr, 0, nullptr, 0);
SConversion conv = {};
_wmakepath_s(conv.szSrc, drive, dir, findData.cFileName, nullptr);
files.push_back(conv);
}
if (!FindNextFileW(hFile.get(), &findData))
break;
}
}
// Process directories
if (recursive)
{
wchar_t searchDir[MAX_PATH] = {};
{
wchar_t drive[_MAX_DRIVE] = {};
wchar_t dir[_MAX_DIR] = {};
_wsplitpath_s(path, drive, _MAX_DRIVE, dir, _MAX_DIR, nullptr, 0, nullptr, 0);
_wmakepath_s(searchDir, drive, dir, L"*", nullptr);
}
hFile.reset(safe_handle(FindFirstFileExW(searchDir,
FindExInfoBasic, &findData,
FindExSearchLimitToDirectories, nullptr,
FIND_FIRST_EX_LARGE_FETCH)));
if (!hFile)
return;
for (;;)
{
if (findData.dwFileAttributes & FILE_ATTRIBUTE_DIRECTORY)
{
if (findData.cFileName[0] != L'.')
{
wchar_t subdir[MAX_PATH] = {};
{
wchar_t drive[_MAX_DRIVE] = {};
wchar_t dir[_MAX_DIR] = {};
wchar_t fname[_MAX_FNAME] = {};
wchar_t ext[_MAX_FNAME] = {};
_wsplitpath_s(path, drive, dir, fname, ext);
wcscat_s(dir, findData.cFileName);
_wmakepath_s(subdir, drive, dir, fname, ext);
}
SearchForFiles(subdir, files, recursive);
}
}
if (!FindNextFileW(hFile.get(), &findData))
break;
}
}
}
void ProcessFileList(std::wifstream& inFile, std::list<SConversion>& files)
{
std::list<SConversion> flist;
std::set<std::wstring> excludes;
wchar_t fname[1024] = {};
for (;;)
{
inFile >> fname;
if (!inFile)
break;
if (*fname == L'#')
{
// Comment
}
else if (*fname == L'-')
{
if (flist.empty())
{
wprintf(L"WARNING: Ignoring the line '%ls' in -flist\n", fname);
}
else
{
if (wcspbrk(fname, L"?*") != nullptr)
{
std::list<SConversion> removeFiles;
SearchForFiles(&fname[1], removeFiles, false);
for (auto it : removeFiles)
{
_wcslwr_s(it.szSrc);
excludes.insert(it.szSrc);
}
}
else
{
std::wstring name = (fname + 1);
std::transform(name.begin(), name.end(), name.begin(), towlower);
excludes.insert(name);
}
}
}
else if (wcspbrk(fname, L"?*") != nullptr)
{
SearchForFiles(fname, flist, false);
}
else
{
SConversion conv = {};
wcscpy_s(conv.szSrc, MAX_PATH, fname);
flist.push_back(conv);
}
inFile.ignore(1000, '\n');
}
inFile.close();
if (!excludes.empty())
{
// Remove any excluded files
for (auto it = flist.begin(); it != flist.end();)
{
std::wstring name = it->szSrc;
std::transform(name.begin(), name.end(), name.begin(), towlower);
auto item = it;
++it;
if (excludes.find(name) != excludes.end())
{
flist.erase(item);
}
}
}
if (flist.empty())
{
wprintf(L"WARNING: No file names found in -flist\n");
}
else
{
files.splice(files.end(), flist);
}
}
void PrintList(size_t cch, const SValue<uint32_t>* pValue)
{
while (pValue->name)
{
const size_t cchName = wcslen(pValue->name);
if (cch + cchName + 2 >= 80)
{
wprintf(L"\n ");
cch = 6;
}
wprintf(L"%ls ", pValue->name);
cch += cchName + 2;
pValue++;
}
wprintf(L"\n");
}
void PrintLogo()
{
wchar_t version[32] = {};
wchar_t appName[_MAX_PATH] = {};
if (GetModuleFileNameW(nullptr, appName, static_cast<DWORD>(std::size(appName))))
{
const DWORD size = GetFileVersionInfoSizeW(appName, nullptr);
if (size > 0)
{
auto verInfo = std::make_unique<uint8_t[]>(size);
if (GetFileVersionInfoW(appName, 0, size, verInfo.get()))
{
LPVOID lpstr = nullptr;
UINT strLen = 0;
if (VerQueryValueW(verInfo.get(), L"\\StringFileInfo\\040904B0\\ProductVersion", &lpstr, &strLen))
{
wcsncpy_s(version, reinterpret_cast<const wchar_t*>(lpstr), strLen);
}
}
}
}
if (!*version || wcscmp(version, L"1.0.0.0") == 0)
{
swprintf_s(version, L"%03d (library)", UVATLAS_VERSION);
}
wprintf(L"Microsoft (R) UVAtlas Command-line Tool Version %ls\n", version);
wprintf(L"Copyright (C) Microsoft Corp.\n");
#ifdef _DEBUG
wprintf(L"*** Debug build ***\n");
#endif
wprintf(L"\n");
}
void PrintUsage()
{
PrintLogo();
wprintf(L"Usage: uvatlas <options> <files>\n");
wprintf(L"\n");
wprintf(L" Input file type must be Wavefront Object (.obj)\n\n");
wprintf(L" Output file type:\n");
wprintf(L" -sdkmesh DirectX SDK .sdkmesh format (default)\n");
wprintf(L" -sdkmesh2 .sdkmesh format version 2 (PBR materials)\n");
wprintf(L" -cmo Visual Studio Content Pipeline .cmo format\n");
wprintf(L" -vbo Vertex Buffer Object (.vbo) format\n");
wprintf(L" -wf WaveFront Object (.obj) format\n\n");
wprintf(L" -r wildcard filename search is recursive\n");
wprintf(L" -q <level> sets quality level to DEFAULT, FAST or QUALITY\n");
wprintf(L" -n <number> maximum number of charts to generate (def: 0)\n");
wprintf(L" -st <float> maximum amount of stretch 0.0 to 1.0 (def: 0.16667)\n");
wprintf(L" -lms enable limit merge stretch option\n");
wprintf(L" -lfs enable limit face stretch option\n");
wprintf(L" -g <float> the gutter width betwen charts in texels (def: 2.0)\n");
wprintf(L" -w <number> texture width (def: 512)\n");
wprintf(L" -h <number> texture height (def: 512)\n");
wprintf(L" -ta | -ga generate topological vs. geometric adjancecy (def: ta)\n");
wprintf(L" -nn | -na | -ne generate normals weighted by angle/area/equal\n");
wprintf(L" -tt generate tangents\n");
wprintf(L" -tb generate tangents & bi-tangents\n");
wprintf(L" -cw faces are clockwise (defaults to counter-clockwise)\n");
wprintf(L" -c generate mesh with colors showing charts\n");
wprintf(L" -t generates a separate mesh with uvs - (*_texture)\n");
wprintf(L" -it <filename> calculate IMT for the mesh using this texture map\n");
wprintf(
L" -iv <channel> calculate IMT using per-vertex data\n"
L" NORMAL, COLOR, TEXCOORD\n");
wprintf(L" -nodds prevents extension renaming in exported materials\n");
wprintf(L" -flip reverse winding of faces\n");
wprintf(L" -flipu inverts the u texcoords\n");
wprintf(L" -flipv inverts the v texcoords\n");
wprintf(L" -flipz flips the handedness of the positions/normals\n");
wprintf(L" -o <filename> output filename\n");
wprintf(L" -l force output filename to lower case\n");
wprintf(L" -y overwrite existing output file (if any)\n");
wprintf(L" -nologo suppress copyright message\n");
wprintf(L" -flist <filename> use text file with a list of input files (one per line)\n");
wprintf(L"\n (sdkmesh/sdkmesh2 only)\n");
wprintf(L" -ib32 use 32-bit index buffer\n");
wprintf(L" -fn <normal-format> format to use for writing normals/tangents/normals\n");
wprintf(L" -fuv <uv-format> format to use for texture coordinates\n");
wprintf(L" -fc <color-format> format to use for writing colors\n");
wprintf(L" -uv2 place uvatlas uvs into a second texture coordinate channel\n");
wprintf(L"\n <normal-format>: ");
PrintList(13, g_vertexNormalFormats);
wprintf(L"\n <uv-format>: ");
PrintList(13, g_vertexUVFormats);
wprintf(L"\n <color-format>: ");
PrintList(13, g_vertexColorFormats);
}
const wchar_t* GetErrorDesc(HRESULT hr)
{
static wchar_t desc[1024] = {};
LPWSTR errorText = nullptr;
const DWORD result = FormatMessageW(FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS | FORMAT_MESSAGE_ALLOCATE_BUFFER,
nullptr, static_cast<DWORD>(hr),
MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT), reinterpret_cast<LPWSTR>(&errorText), 0, nullptr);
*desc = 0;
if (result > 0 && errorText)
{
swprintf_s(desc, L": %ls", errorText);
size_t len = wcslen(desc);
if (len >= 1)
{
desc[len - 1] = 0;
}
if (errorText)
LocalFree(errorText);
}
return desc;
}
//--------------------------------------------------------------------------------------
HRESULT __cdecl UVAtlasCallback(float fPercentDone)
{
static ULONGLONG s_lastTick = 0;
const ULONGLONG tick = GetTickCount64();
if ((tick - s_lastTick) > 1000)
{
wprintf(L"%.2f%% \r", double(fPercentDone) * 100);
s_lastTick = tick;
}
if (_kbhit())
{
if (_getch() == 27)
{
wprintf(L"*** ABORT ***");
return E_ABORT;
}
}
return S_OK;
}
}
//--------------------------------------------------------------------------------------
// Entry-point
//--------------------------------------------------------------------------------------
#ifdef __PREFAST__
#pragma prefast(disable : 28198, "Command-line tool, frees all memory on exit")
#endif
int __cdecl wmain(_In_ int argc, _In_z_count_(argc) wchar_t* argv[])
{
// Parameters and defaults
size_t maxCharts = 0;
float maxStretch = 0.16667f;
float gutter = 2.f;
size_t width = 512;
size_t height = 512;
CHANNELS perVertex = CHANNEL_NONE;
UVATLAS uvOptions = UVATLAS_DEFAULT;
UVATLAS uvOptionsEx = UVATLAS_DEFAULT;
DXGI_FORMAT normalFormat = DXGI_FORMAT_R32G32B32_FLOAT;
DXGI_FORMAT uvFormat = DXGI_FORMAT_R32G32_FLOAT;
DXGI_FORMAT colorFormat = DXGI_FORMAT_B8G8R8A8_UNORM;
wchar_t szTexFile[MAX_PATH] = {};
wchar_t szOutputFile[MAX_PATH] = {};
// Set locale for output since GetErrorDesc can get localized strings.
std::locale::global(std::locale(""));
// Initialize COM (needed for WIC)
HRESULT hr = CoInitializeEx(nullptr, COINIT_MULTITHREADED);
if (FAILED(hr))
{
wprintf(L"Failed to initialize COM (%08X%ls)\n", static_cast<unsigned int>(hr), GetErrorDesc(hr));
return 1;
}
// Process command line
uint64_t 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;
const uint64_t dwOption = LookupByName(pArg, g_pOptions);
if (!dwOption || (dwOptions & (uint64_t(1) << dwOption)))
{
wprintf(L"ERROR: unknown command-line option '%ls'\n\n", pArg);
PrintUsage();
return 1;
}
dwOptions |= (uint64_t(1) << dwOption);
// Handle options with additional value parameter
switch (dwOption)
{
case OPT_QUALITY:
case OPT_MAXCHARTS:
case OPT_MAXSTRETCH:
case OPT_GUTTER:
case OPT_WIDTH:
case OPT_HEIGHT:
case OPT_IMT_TEXFILE:
case OPT_IMT_VERTEX:
case OPT_OUTPUTFILE:
case OPT_VERT_NORMAL_FORMAT:
case OPT_VERT_UV_FORMAT:
case OPT_VERT_COLOR_FORMAT:
case OPT_FILELIST:
if (!*pValue)
{
if ((iArg + 1 >= argc))
{
wprintf(L"ERROR: missing value for command-line option '%ls'\n\n", pArg);
PrintUsage();
return 1;
}
iArg++;
pValue = argv[iArg];
}
break;
}
switch (dwOption)
{
case OPT_QUALITY:
if (!_wcsicmp(pValue, L"DEFAULT"))
{
uvOptions = UVATLAS_DEFAULT;
}
else if (!_wcsicmp(pValue, L"FAST"))
{
uvOptions = UVATLAS_GEODESIC_FAST;
}
else if (!_wcsicmp(pValue, L"QUALITY"))
{
uvOptions = UVATLAS_GEODESIC_QUALITY;
}
else
{
wprintf(L"Invalid value specified with -q (%ls)\n", pValue);
return 1;
}
break;
case OPT_LIMIT_MERGE_STRETCH:
uvOptionsEx |= UVATLAS_LIMIT_MERGE_STRETCH;
break;
case OPT_LIMIT_FACE_STRETCH:
uvOptionsEx |= UVATLAS_LIMIT_FACE_STRETCH;
break;
case OPT_MAXCHARTS:
if (swscanf_s(pValue, L"%zu", &maxCharts) != 1)
{
wprintf(L"Invalid value specified with -n (%ls)\n", pValue);
return 1;
}
break;
case OPT_MAXSTRETCH:
if (swscanf_s(pValue, L"%f", &maxStretch) != 1
|| maxStretch < 0.f
|| maxStretch > 1.f)
{
wprintf(L"Invalid value specified with -st (%ls)\n", pValue);
return 1;
}
break;
case OPT_GUTTER:
if (swscanf_s(pValue, L"%f", &gutter) != 1
|| gutter < 0.f)
{
wprintf(L"Invalid value specified with -g (%ls)\n", pValue);
return 1;
}
break;
case OPT_WIDTH:
if (swscanf_s(pValue, L"%zu", &width) != 1)
{
wprintf(L"Invalid value specified with -w (%ls)\n", pValue);
return 1;
}
break;
case OPT_HEIGHT:
if (swscanf_s(pValue, L"%zu", &height) != 1)
{
wprintf(L"Invalid value specified with -h (%ls)\n", pValue);
return 1;
}
break;
case OPT_WEIGHT_BY_AREA:
if (dwOptions & (uint64_t(1) << OPT_WEIGHT_BY_EQUAL))
{
wprintf(L"Can only use one of nn, na, or ne\n");
return 1;
}
dwOptions |= (uint64_t(1) << OPT_NORMALS);
break;
case OPT_WEIGHT_BY_EQUAL:
if (dwOptions & (uint64_t(1) << OPT_WEIGHT_BY_AREA))
{
wprintf(L"Can only use one of nn, na, or ne\n");
return 1;
}
dwOptions |= (uint64_t(1) << OPT_NORMALS);
break;
case OPT_IMT_TEXFILE:
if (dwOptions & (uint64_t(1) << OPT_IMT_VERTEX))
{
wprintf(L"Cannot use both if and iv at the same time\n");
return 1;
}
wcscpy_s(szTexFile, MAX_PATH, pValue);
break;
case OPT_IMT_VERTEX:
if (dwOptions & (uint64_t(1) << OPT_IMT_TEXFILE))
{
wprintf(L"Cannot use both if and iv at the same time\n");
return 1;
}
if (!_wcsicmp(pValue, L"COLOR"))
{
perVertex = CHANNEL_COLOR;
}
else if (!_wcsicmp(pValue, L"NORMAL"))
{
perVertex = CHANNEL_NORMAL;
}
else if (!_wcsicmp(pValue, L"TEXCOORD"))
{
perVertex = CHANNEL_TEXCOORD;
}
else
{
wprintf(L"Invalid value specified with -iv (%ls)\n", pValue);
return 1;
}
break;
case OPT_OUTPUTFILE:
wcscpy_s(szOutputFile, MAX_PATH, pValue);
break;
case OPT_TOPOLOGICAL_ADJ:
if (dwOptions & (uint64_t(1) << OPT_GEOMETRIC_ADJ))
{
wprintf(L"Cannot use both ta and ga at the same time\n");
return 1;
}
break;
case OPT_GEOMETRIC_ADJ:
if (dwOptions & (uint64_t(1) << OPT_TOPOLOGICAL_ADJ))
{
wprintf(L"Cannot use both ta and ga at the same time\n");
return 1;
}
break;
case OPT_SDKMESH:
case OPT_SDKMESH_V2:
if (dwOptions & ((uint64_t(1) << OPT_VBO) | (uint64_t(1) << OPT_CMO) | (uint64_t(1) << OPT_WAVEFRONT_OBJ)))
{
wprintf(L"Can only use one of sdkmesh, cmo, vbo, or wf\n");
return 1;
}
if (dwOption == OPT_SDKMESH_V2)
{
dwOptions |= (uint64_t(1) << OPT_SDKMESH);
}
break;
case OPT_CMO:
if (dwOptions & (uint64_t(1) << OPT_SECOND_UV))
{
wprintf(L"-uv2 is not supported by CMO\n");
return 1;
}
if (dwOptions & ((uint64_t(1) << OPT_VBO) | (uint64_t(1) << OPT_SDKMESH) | (uint64_t(1) << OPT_WAVEFRONT_OBJ)))
{
wprintf(L"Can only use one of sdkmesh, cmo, vbo, or wf\n");
return 1;
}
break;
case OPT_VBO:
if (dwOptions & (uint64_t(1) << OPT_SECOND_UV))
{
wprintf(L"-uv2 is not supported by VBO\n");
return 1;
}
if (dwOptions & ((uint64_t(1) << OPT_SDKMESH) | (uint64_t(1) << OPT_CMO) | (uint64_t(1) << OPT_WAVEFRONT_OBJ)))
{
wprintf(L"Can only use one of sdkmesh, cmo, vbo, or wf\n");
return 1;
}
break;
case OPT_WAVEFRONT_OBJ:
if (dwOptions & (uint64_t(1) << OPT_SECOND_UV))
{
wprintf(L"-uv2 is not supported by Wavefront OBJ\n");
return 1;
}
if (dwOptions & ((uint64_t(1) << OPT_VBO) | (uint64_t(1) << OPT_SDKMESH) | (uint64_t(1) << OPT_CMO)))
{
wprintf(L"Can only use one of sdkmesh, cmo, vbo, or wf\n");
return 1;
}
break;
case OPT_SECOND_UV:
if (dwOptions & ((uint64_t(1) << OPT_VBO) | (uint64_t(1) << OPT_CMO) | (uint64_t(1) << OPT_WAVEFRONT_OBJ)))
{
wprintf(L"-uv2 is only supported by sdkmesh\n");
return 1;
}
break;
case OPT_VERT_NORMAL_FORMAT:
normalFormat = static_cast<DXGI_FORMAT>(LookupByName(pValue, g_vertexNormalFormats));
if (!normalFormat)
{
wprintf(L"Invalid value specified with -fn (%ls)\n", pValue);
wprintf(L"\n");
PrintUsage();
return 1;
}
break;
case OPT_VERT_UV_FORMAT:
uvFormat = static_cast<DXGI_FORMAT>(LookupByName(pValue, g_vertexUVFormats));
if (!uvFormat)
{
wprintf(L"Invalid value specified with -fuv (%ls)\n", pValue);
wprintf(L"\n");
PrintUsage();
return 1;
}
break;
case OPT_VERT_COLOR_FORMAT:
colorFormat = static_cast<DXGI_FORMAT>(LookupByName(pValue, g_vertexColorFormats));
if (!colorFormat)
{
wprintf(L"Invalid value specified with -fc (%ls)\n", pValue);
wprintf(L"\n");
PrintUsage();
return 1;
}
break;
case OPT_FILELIST:
{
std::wifstream inFile(pValue);
if (!inFile)
{
wprintf(L"Error opening -flist file %ls\n", pValue);
return 1;
}
inFile.imbue(std::locale::classic());
ProcessFileList(inFile, conversion);
}
break;
}
}
else if (wcspbrk(pArg, L"?*") != nullptr)
{
const size_t count = conversion.size();
SearchForFiles(pArg, conversion, (dwOptions & (uint64_t(1) << OPT_RECURSIVE)) != 0);
if (conversion.size() <= count)
{
wprintf(L"No matching files found for %ls\n", pArg);
return 1;
}
}
else
{
SConversion conv = {};
wcscpy_s(conv.szSrc, MAX_PATH, pArg);
conversion.push_back(conv);
}
}
if (conversion.empty())
{
PrintUsage();
return 0;
}
if (*szOutputFile && conversion.size() > 1)
{
wprintf(L"Cannot use -o with multiple input files\n");
return 1;
}
if (~dwOptions & (uint64_t(1) << OPT_NOLOGO))
PrintLogo();
// Process files
for (auto pConv = conversion.begin(); pConv != conversion.end(); ++pConv)
{
wchar_t ext[_MAX_EXT] = {};
wchar_t fname[_MAX_FNAME] = {};
_wsplitpath_s(pConv->szSrc, nullptr, 0, nullptr, 0, fname, _MAX_FNAME, ext, _MAX_EXT);
if (pConv != conversion.begin())
wprintf(L"\n");
wprintf(L"reading %ls", pConv->szSrc);
fflush(stdout);
std::unique_ptr<Mesh> inMesh;
std::vector<Mesh::Material> inMaterial;
hr = E_NOTIMPL;
if (_wcsicmp(ext, L".vbo") == 0)
{
hr = Mesh::CreateFromVBO(pConv->szSrc, inMesh);
}
else if (_wcsicmp(ext, L".sdkmesh") == 0)
{
wprintf(L"\nERROR: Importing SDKMESH files not supported\n");
return 1;
}
else if (_wcsicmp(ext, L".cmo") == 0)
{
wprintf(L"\nERROR: Importing Visual Studio CMO files not supported\n");
return 1;
}
else if (_wcsicmp(ext, L".x") == 0)
{
wprintf(L"\nERROR: Legacy Microsoft X files not supported\n");
return 1;
}
else if (_wcsicmp(ext, L".fbx") == 0)
{
wprintf(L"\nERROR: Autodesk FBX files not supported\n");
return 1;
}
else
{
hr = LoadFromOBJ(pConv->szSrc, inMesh, inMaterial,
(dwOptions & (uint64_t(1) << OPT_CLOCKWISE)) ? false : true,
(dwOptions & (uint64_t(1) << OPT_NODDS)) ? false : true);
}
if (FAILED(hr))
{
wprintf(L" FAILED (%08X%ls)\n", static_cast<unsigned int>(hr), GetErrorDesc(hr));
return 1;
}
size_t nVerts = inMesh->GetVertexCount();
const size_t nFaces = inMesh->GetFaceCount();
if (!nVerts || !nFaces)
{
wprintf(L"\nERROR: Invalid mesh\n");
return 1;
}
assert(inMesh->GetPositionBuffer() != nullptr);
assert(inMesh->GetIndexBuffer() != nullptr);
wprintf(L"\n%zu vertices, %zu faces", nVerts, nFaces);
if (dwOptions & (uint64_t(1) << OPT_FLIPU))
{
hr = inMesh->InvertUTexCoord();
if (FAILED(hr))
{
wprintf(L"\nERROR: Failed inverting u texcoord (%08X%ls)\n",
static_cast<unsigned int>(hr), GetErrorDesc(hr));
return 1;
}
}
if (dwOptions & (uint64_t(1) << OPT_FLIPV))
{
hr = inMesh->InvertVTexCoord();
if (FAILED(hr))
{
wprintf(L"\nERROR: Failed inverting v texcoord (%08X%ls)\n",
static_cast<unsigned int>(hr), GetErrorDesc(hr));
return 1;
}
}
if (dwOptions & (uint64_t(1) << OPT_FLIPZ))
{
hr = inMesh->ReverseHandedness();
if (FAILED(hr))
{
wprintf(L"\nERROR: Failed reversing handedness (%08X%ls)\n",
static_cast<unsigned int>(hr), GetErrorDesc(hr));
return 1;
}
}
// Prepare mesh for processing
{
// Adjacency
const float epsilon = (dwOptions & (uint64_t(1) << OPT_GEOMETRIC_ADJ)) ? 1e-5f : 0.f;
hr = inMesh->GenerateAdjacency(epsilon);
if (FAILED(hr))
{
wprintf(L"\nERROR: Failed generating adjacency (%08X%ls)\n",
static_cast<unsigned int>(hr), GetErrorDesc(hr));
return 1;
}
// Validation
std::wstring msgs;
hr = inMesh->Validate(VALIDATE_BACKFACING | VALIDATE_BOWTIES, &msgs);
if (!msgs.empty())
{
wprintf(L"\nWARNING: \n");
wprintf(L"%ls", msgs.c_str());
}
// Clean
hr = inMesh->Clean(true);
if (FAILED(hr))
{
wprintf(L"\nERROR: Failed mesh clean (%08X%ls)\n",
static_cast<unsigned int>(hr), GetErrorDesc(hr));
return 1;
}
else
{
const size_t nNewVerts = inMesh->GetVertexCount();
if (nVerts != nNewVerts)
{
wprintf(L" [%zu vertex dups] ", nNewVerts - nVerts);
nVerts = nNewVerts;
}
}
}
if (!inMesh->GetNormalBuffer())
{
dwOptions |= uint64_t(1) << OPT_NORMALS;
}
if (!inMesh->GetTangentBuffer() && (dwOptions & (uint64_t(1) << OPT_CMO)))
{
dwOptions |= uint64_t(1) << OPT_TANGENTS;
}
// Compute vertex normals from faces
if ((dwOptions & (uint64_t(1) << OPT_NORMALS))
|| ((dwOptions & ((uint64_t(1) << OPT_TANGENTS) | (uint64_t(1) << OPT_CTF))) && !inMesh->GetNormalBuffer()))
{
CNORM_FLAGS flags = CNORM_DEFAULT;
if (dwOptions & (uint64_t(1) << OPT_WEIGHT_BY_EQUAL))
{
flags |= CNORM_WEIGHT_EQUAL;
}
else if (dwOptions & (uint64_t(1) << OPT_WEIGHT_BY_AREA))
{
flags |= CNORM_WEIGHT_BY_AREA;
}
if (dwOptions & (uint64_t(1) << OPT_CLOCKWISE))
{
flags |= CNORM_WIND_CW;
}
hr = inMesh->ComputeNormals(flags);
if (FAILED(hr))
{
wprintf(L"\nERROR: Failed computing normals (flags:%lX, %08X%ls)\n", flags,
static_cast<unsigned int>(hr), GetErrorDesc(hr));
return 1;
}
}
// Compute tangents and bitangents
if (dwOptions & ((uint64_t(1) << OPT_TANGENTS) | (uint64_t(1) << OPT_CTF)))
{
if (!inMesh->GetTexCoordBuffer())
{
wprintf(L"\nERROR: Computing tangents/bi-tangents requires texture coordinates\n");
return 1;
}
hr = inMesh->ComputeTangentFrame((dwOptions & (uint64_t(1) << OPT_CTF)) ? true : false);
if (FAILED(hr))
{
wprintf(L"\nERROR: Failed computing tangent frame (%08X%ls)\n",
static_cast<unsigned int>(hr), GetErrorDesc(hr));
return 1;
}
}
// Compute IMT
std::unique_ptr<float[]> IMTData;
if (dwOptions & ((uint64_t(1) << OPT_IMT_TEXFILE) | (uint64_t(1) << OPT_IMT_VERTEX)))
{
if (dwOptions & (uint64_t(1) << OPT_IMT_TEXFILE))
{
if (!inMesh->GetTexCoordBuffer())
{
wprintf(L"\nERROR: Computing IMT from texture requires texture coordinates\n");
return 1;
}
wchar_t txext[_MAX_EXT] = {};
_wsplitpath_s(szTexFile, nullptr, 0, nullptr, 0, nullptr, 0, txext, _MAX_EXT);
ScratchImage iimage;
if (_wcsicmp(txext, L".dds") == 0)
{
hr = LoadFromDDSFile(szTexFile, DDS_FLAGS_NONE, nullptr, iimage);
}
else if (_wcsicmp(ext, L".tga") == 0)
{
hr = LoadFromTGAFile(szTexFile, nullptr, iimage);
}
else if (_wcsicmp(ext, L".hdr") == 0)
{
hr = LoadFromHDRFile(szTexFile, nullptr, iimage);
}
#ifdef USE_OPENEXR
else if (_wcsicmp(ext, L".exr") == 0)
{
hr = LoadFromEXRFile(szTexFile, nullptr, iimage);
}
#endif
else
{
hr = LoadFromWICFile(szTexFile, WIC_FLAGS_NONE, nullptr, iimage);
}
if (FAILED(hr))
{
wprintf(L"\nWARNING: Failed to load texture for IMT (%08X%ls):\n%ls\n",
static_cast<unsigned int>(hr), GetErrorDesc(hr), szTexFile);
}
else
{
const Image* img = iimage.GetImage(0, 0, 0);
ScratchImage floatImage;
if (img->format != DXGI_FORMAT_R32G32B32A32_FLOAT)
{
hr = Convert(*iimage.GetImage(0, 0, 0), DXGI_FORMAT_R32G32B32A32_FLOAT, TEX_FILTER_DEFAULT,
TEX_THRESHOLD_DEFAULT, floatImage);
if (FAILED(hr))
{
img = nullptr;
wprintf(L"\nWARNING: Failed converting texture for IMT (%08X%ls):\n%ls\n",
static_cast<unsigned int>(hr), GetErrorDesc(hr), szTexFile);
}
else
{
img = floatImage.GetImage(0, 0, 0);
}
}
if (img)
{
wprintf(L"\nComputing IMT from file %ls...\n", szTexFile);
IMTData.reset(new (std::nothrow) float[nFaces * 3]);
if (!IMTData)
{
wprintf(L"\nERROR: out of memory\n");
return 1;
}
hr = UVAtlasComputeIMTFromTexture(inMesh->GetPositionBuffer(), inMesh->GetTexCoordBuffer(), nVerts,
inMesh->GetIndexBuffer(), DXGI_FORMAT_R32_UINT, nFaces,
reinterpret_cast<const float*>(img->pixels), img->width, img->height,
UVATLAS_IMT_DEFAULT, UVAtlasCallback, IMTData.get());
if (FAILED(hr))
{
IMTData.reset();
wprintf(L"WARNING: Failed to compute IMT from texture (%08X%ls):\n%ls\n",
static_cast<unsigned int>(hr), GetErrorDesc(hr), szTexFile);
}
}
}
}
else
{
const wchar_t* szChannel = L"*unknown*";
const float* pSignal = nullptr;
size_t signalDim = 0;
size_t signalStride = 0;
switch (perVertex)
{
case CHANNEL_NORMAL:
szChannel = L"normals";
if (inMesh->GetNormalBuffer())
{
pSignal = reinterpret_cast<const float*>(inMesh->GetNormalBuffer());
signalDim = 3;
signalStride = sizeof(XMFLOAT3);
}
break;
case CHANNEL_COLOR:
szChannel = L"vertex colors";
if (inMesh->GetColorBuffer())
{
pSignal = reinterpret_cast<const float*>(inMesh->GetColorBuffer());
signalDim = 4;
signalStride = sizeof(XMFLOAT4);
}
break;
case CHANNEL_TEXCOORD:
szChannel = L"texture coordinates";
if (inMesh->GetTexCoordBuffer())
{
pSignal = reinterpret_cast<const float*>(inMesh->GetTexCoordBuffer());
signalDim = 2;
signalStride = sizeof(XMFLOAT2);
}
break;
}
if (!pSignal)
{
wprintf(L"\nWARNING: Mesh does not have channel %ls for IMT\n", szChannel);
}
else
{
wprintf(L"\nComputing IMT from %ls...\n", szChannel);
IMTData.reset(new (std::nothrow) float[nFaces * 3]);
if (!IMTData)
{
wprintf(L"\nERROR: out of memory\n");
return 1;
}
hr = UVAtlasComputeIMTFromPerVertexSignal(inMesh->GetPositionBuffer(), nVerts,
inMesh->GetIndexBuffer(), DXGI_FORMAT_R32_UINT, nFaces,
pSignal, signalDim, signalStride, UVAtlasCallback, IMTData.get());
if (FAILED(hr))
{
IMTData.reset();
wprintf(L"WARNING: Failed to compute IMT from channel %ls (%08X%ls)\n",
szChannel, static_cast<unsigned int>(hr), GetErrorDesc(hr));
}
}
}
}
else
{
wprintf(L"\n");
}
// Perform UVAtlas isocharting
wprintf(L"Computing isochart atlas on mesh...\n");
std::vector<UVAtlasVertex> vb;
std::vector<uint8_t> ib;
float outStretch = 0.f;
size_t outCharts = 0;
std::vector<uint32_t> facePartitioning;
std::vector<uint32_t> vertexRemapArray;
hr = UVAtlasCreate(inMesh->GetPositionBuffer(), nVerts,
inMesh->GetIndexBuffer(), DXGI_FORMAT_R32_UINT, nFaces,
maxCharts, maxStretch, width, height, gutter,
inMesh->GetAdjacencyBuffer(), nullptr,
IMTData.get(),
UVAtlasCallback, UVATLAS_DEFAULT_CALLBACK_FREQUENCY,
uvOptions | uvOptionsEx, vb, ib,
&facePartitioning,
&vertexRemapArray,
&outStretch, &outCharts);
if (FAILED(hr))
{
if (hr == HRESULT_FROM_WIN32(ERROR_INVALID_DATA))
{
wprintf(L"\nERROR: Non-manifold mesh\n");
return 1;
}
else
{
wprintf(L"\nERROR: Failed creating isocharts (%08X%ls)\n", static_cast<unsigned int>(hr), GetErrorDesc(hr));
return 1;
}
}
wprintf(L"Output # of charts: %zu, resulting stretching %f, %zu verts\n", outCharts, double(outStretch), vb.size());
assert((ib.size() / sizeof(uint32_t)) == (nFaces * 3));
assert(facePartitioning.size() == nFaces);
assert(vertexRemapArray.size() == vb.size());
hr = inMesh->UpdateFaces(nFaces, reinterpret_cast<const uint32_t*>(ib.data()));
if (FAILED(hr))
{
wprintf(L"\nERROR: Failed applying atlas indices (%08X%ls)\n", static_cast<unsigned int>(hr), GetErrorDesc(hr));
return 1;
}
hr = inMesh->VertexRemap(vertexRemapArray.data(), vertexRemapArray.size());
if (FAILED(hr))
{
wprintf(L"\nERROR: Failed applying atlas vertex remap (%08X%ls)\n", static_cast<unsigned int>(hr), GetErrorDesc(hr));
return 1;
}
nVerts = vb.size();
#ifdef _DEBUG
std::wstring msgs;
hr = inMesh->Validate(VALIDATE_DEFAULT, &msgs);
if (!msgs.empty())
{
wprintf(L"\nWARNING: \n%ls\n", msgs.c_str());
}
#endif
// Copy isochart UVs into mesh
{
std::unique_ptr<XMFLOAT2[]> texcoord(new (std::nothrow) XMFLOAT2[nVerts]);
if (!texcoord)
{
wprintf(L"\nERROR: out of memory\n");
return 1;
}
auto txptr = texcoord.get();
size_t j = 0;
for (auto it = vb.cbegin(); it != vb.cend() && j < nVerts; ++it, ++txptr)
{
*txptr = it->uv;
}
hr = inMesh->UpdateUVs(nVerts, texcoord.get(), (dwOptions & (uint64_t(1) << OPT_SECOND_UV)));
if (FAILED(hr))
{
wprintf(L"\nERROR: Failed to update with isochart UVs\n");
return 1;
}
}
if (dwOptions & (uint64_t(1) << OPT_COLOR_MESH))
{
inMaterial.clear();
inMaterial.reserve(std::size(g_ColorList));
for (size_t j = 0; j < std::size(g_ColorList) && (j < outCharts); ++j)
{
Mesh::Material mtl = {};
wchar_t matname[32] = {};
swprintf_s(matname, L"Chart%02zu", j + 1);
mtl.name = matname;
mtl.specularPower = 1.f;
mtl.alpha = 1.f;
XMVECTOR v = XMLoadFloat3(&g_ColorList[j]);
XMStoreFloat3(&mtl.diffuseColor, v);
v = XMVectorScale(v, 0.2f);
XMStoreFloat3(&mtl.ambientColor, v);
inMaterial.push_back(mtl);
}
std::unique_ptr<uint32_t[]> attr(new (std::nothrow) uint32_t[nFaces]);
if (!attr)
{
wprintf(L"\nERROR: out of memory\n");
return 1;
}
size_t j = 0;
for (auto it = facePartitioning.cbegin(); it != facePartitioning.cend(); ++it, ++j)
{
attr[j] = *it % std::size(g_ColorList);
}
hr = inMesh->UpdateAttributes(nFaces, attr.get());
if (FAILED(hr))
{
wprintf(L"\nERROR: Failed applying atlas attributes (%08X%ls)\n",
static_cast<unsigned int>(hr), GetErrorDesc(hr));
return 1;
}
}
if (dwOptions & (uint64_t(1) << OPT_FLIP))
{
hr = inMesh->ReverseWinding();
if (FAILED(hr))
{
wprintf(L"\nERROR: Failed reversing winding (%08X%ls)\n", static_cast<unsigned int>(hr), GetErrorDesc(hr));
return 1;
}
}
// Write results
wprintf(L"\n\t->\n");
wchar_t outputPath[MAX_PATH] = {};
wchar_t outputExt[_MAX_EXT] = {};
if (*szOutputFile)
{
wcscpy_s(outputPath, szOutputFile);
_wsplitpath_s(szOutputFile, nullptr, 0, nullptr, 0, nullptr, 0, outputExt, _MAX_EXT);
}
else
{
if (dwOptions & (uint64_t(1) << OPT_VBO))
{
wcscpy_s(outputExt, L".vbo");
}
else if (dwOptions & (uint64_t(1) << OPT_CMO))
{
wcscpy_s(outputExt, L".cmo");
}
else if (dwOptions & (uint64_t(1) << OPT_WAVEFRONT_OBJ))
{
wcscpy_s(outputExt, L".obj");
}
else
{
wcscpy_s(outputExt, L".sdkmesh");
}
wchar_t outFilename[_MAX_FNAME] = {};
wcscpy_s(outFilename, fname);
_wmakepath_s(outputPath, nullptr, nullptr, outFilename, outputExt);
}
if (dwOptions & (uint64_t(1) << OPT_TOLOWER))
{
std::ignore = _wcslwr_s(outputPath);
}
if (~dwOptions & (uint64_t(1) << OPT_OVERWRITE))
{
if (GetFileAttributesW(outputPath) != INVALID_FILE_ATTRIBUTES)
{
wprintf(L"\nERROR: Output file already exists, use -y to overwrite:\n'%ls'\n", outputPath);
return 1;
}
}
if (!_wcsicmp(outputExt, L".vbo"))
{
if (!inMesh->GetNormalBuffer() || !inMesh->GetTexCoordBuffer())
{
wprintf(L"\nERROR: VBO requires position, normal, and texcoord\n");
return 1;
}
if (!inMesh->Is16BitIndexBuffer() || (dwOptions & (uint64_t(1) << OPT_FORCE_32BIT_IB)))
{
wprintf(L"\nERROR: VBO only supports 16-bit indices\n");
return 1;
}
hr = inMesh->ExportToVBO(outputPath);
}
else if (!_wcsicmp(outputExt, L".sdkmesh"))
{
hr = inMesh->ExportToSDKMESH(
outputPath,
inMaterial.size(), inMaterial.empty() ? nullptr : inMaterial.data(),
(dwOptions & (uint64_t(1) << OPT_FORCE_32BIT_IB)) ? true : false,
(dwOptions & (uint64_t(1) << OPT_SDKMESH_V2)) ? true : false,
normalFormat,
uvFormat,
colorFormat);
}
else if (!_wcsicmp(outputExt, L".cmo"))
{
if (!inMesh->GetNormalBuffer() || !inMesh->GetTexCoordBuffer() || !inMesh->GetTangentBuffer())
{
wprintf(L"\nERROR: Visual Studio CMO requires position, normal, tangents, and texcoord\n");
return 1;
}
if (!inMesh->Is16BitIndexBuffer() || (dwOptions & (uint64_t(1) << OPT_FORCE_32BIT_IB)))
{
wprintf(L"\nERROR: Visual Studio CMO only supports 16-bit indices\n");
return 1;
}
hr = inMesh->ExportToCMO(outputPath, inMaterial.size(), inMaterial.empty() ? nullptr : inMaterial.data());
}
else if (!_wcsicmp(outputExt, L".obj") || !_wcsicmp(outputExt, L"._obj"))
{
hr = inMesh->ExportToOBJ(outputPath, inMaterial.size(), inMaterial.empty() ? nullptr : inMaterial.data());
}
else if (!_wcsicmp(outputExt, L".x"))
{
wprintf(L"\nERROR: Legacy Microsoft X files not supported\n");
return 1;
}
else
{
wprintf(L"\nERROR: Unknown output file type '%ls'\n", outputExt);
return 1;
}
if (FAILED(hr))
{
wprintf(L"\nERROR: Failed write (%08X%ls):-> '%ls'\n",
static_cast<unsigned int>(hr), GetErrorDesc(hr), outputPath);
return 1;
}
wprintf(L" %zu vertices, %zu faces written:\n'%ls'\n", nVerts, nFaces, outputPath);
// Write out UV mesh visualization
if (dwOptions & (uint64_t(1) << OPT_UV_MESH))
{
hr = inMesh->VisualizeUVs(dwOptions & (uint64_t(1) << OPT_SECOND_UV));
if (FAILED(hr))
{
wprintf(L"\nERROR: Failed to create UV visualization mesh\n");
return 1;
}
wchar_t uvFilename[_MAX_FNAME] = {};
wcscpy_s(uvFilename, fname);
wcscat_s(uvFilename, L"_texture");
_wmakepath_s(outputPath, nullptr, nullptr, uvFilename, outputExt);
if (dwOptions & (uint64_t(1) << OPT_TOLOWER))
{
std::ignore = _wcslwr_s(outputPath);
}
if (~dwOptions & (uint64_t(1) << OPT_OVERWRITE))
{
if (GetFileAttributesW(outputPath) != INVALID_FILE_ATTRIBUTES)
{
wprintf(L"\nERROR: UV visualization mesh file already exists, use -y to overwrite:\n'%ls'\n", outputPath);
return 1;
}
}
hr = E_NOTIMPL;
if (!_wcsicmp(outputExt, L".vbo"))
{
hr = inMesh->ExportToVBO(outputPath);
}
else if (!_wcsicmp(outputExt, L".sdkmesh"))
{
hr = inMesh->ExportToSDKMESH(
outputPath,
inMaterial.size(), inMaterial.empty() ? nullptr : inMaterial.data(),
(dwOptions & (uint64_t(1) << OPT_FORCE_32BIT_IB)) ? true : false,
(dwOptions & (uint64_t(1) << OPT_SDKMESH_V2)) ? true : false,
normalFormat,
uvFormat,
colorFormat);
}
else if (!_wcsicmp(outputExt, L".cmo"))
{
hr = inMesh->ExportToCMO(outputPath, inMaterial.size(), inMaterial.empty() ? nullptr : inMaterial.data());
}
else if (!_wcsicmp(outputExt, L".obj") || !_wcsicmp(outputExt, L"._obj"))
{
wprintf(L"\nWARNING: WaveFront Object (.obj) not supported for UV visualization (requires Vertex Colors)\n");
}
if (FAILED(hr))
{
wprintf(L"\nERROR: Failed uv mesh write (%08X%ls):-> '%ls'\n",
static_cast<unsigned int>(hr), GetErrorDesc(hr), outputPath);
return 1;
}
wprintf(L"uv mesh visualization '%ls'\n", outputPath);
}
}
return 0;
}