TechniqueToon::~TechniqueToon()
{
//Delete the color schemes loaded during
//initialization.
FreeTexture(mLookups[0]);
FreeTexture(mLookups[1]);
FreeTexture(mLookups[2]);
}
void TextureCache::Cleanup(int _frameCount)
{
TexCache::iterator iter = textures_by_address.begin();
TexCache::iterator tcend = textures_by_address.end();
while (iter != tcend)
{
if (iter->second->frameCount == FRAMECOUNT_INVALID)
{
iter->second->frameCount = _frameCount;
++iter;
}
else if (_frameCount > TEXTURE_KILL_THRESHOLD + iter->second->frameCount)
{
if (iter->second->IsEfbCopy())
{
// Only remove EFB copies when they wouldn't be used anymore(changed hash), because EFB copies living on the
// host GPU are unrecoverable. Perform this check only every TEXTURE_KILL_THRESHOLD for performance reasons
if ((_frameCount - iter->second->frameCount) % TEXTURE_KILL_THRESHOLD == 1 &&
iter->second->hash != iter->second->CalculateHash())
{
iter = FreeTexture(iter);
}
else
{
++iter;
}
}
else
{
iter = FreeTexture(iter);
}
}
else
{
++iter;
}
}
TexPool::iterator iter2 = texture_pool.begin();
TexPool::iterator tcend2 = texture_pool.end();
while (iter2 != tcend2)
{
if (iter2->second->frameCount == FRAMECOUNT_INVALID)
{
iter2->second->frameCount = _frameCount;
}
if (_frameCount > TEXTURE_POOL_KILL_THRESHOLD + iter2->second->frameCount)
{
delete iter2->second;
iter2 = texture_pool.erase(iter2);
}
else
{
++iter2;
}
}
}
void Chowdren::LoadTexture( Gwen::Texture* pTexture )
{
pTexture->failed = true;
return;
if (pTexture->data)
FreeTexture(pTexture);
pTexture->data = (void*)new FileImage(pTexture->name.c_str(), 0, 0,
0, 0, TransparentColor());
if (((FileImage*)pTexture->data)->tex == 0) {
pTexture->failed = true;
FreeTexture(pTexture);
}
}
void Texture::InitializeBuffer( unsigned int nWidth, unsigned int nHeight,
const std::vector<unsigned char> & vBuffer,
unsigned int nGLTextureFormat )
{
FreeTexture();
m_nWidth = nWidth;
m_nHeight = nHeight;
m_vBuffer = vBuffer;
// figure out scaling factors
m_nTexWidth = 1;
while ( m_nTexWidth < nWidth )
m_nTexWidth *= 2;
float fScaleX = (float)m_nTexWidth / (float)nWidth;
m_nTexHeight = 1;
while ( m_nTexHeight < nHeight )
m_nTexHeight *= 2;
float fScaleY = (float)m_nTexHeight / (float)nHeight;
m_fScaleX = (fScaleX < fScaleY) ? fScaleX : fScaleY;
m_fScaleX = 1.0f / m_fScaleX; // scale tex coords *down* to scale image *up*
lgASSERT( (unsigned int)vBuffer.size() % (nWidth * nHeight) == 0 );
m_nComponents = (unsigned int)vBuffer.size() / (nWidth * nHeight);
m_nGLTextureFormat = nGLTextureFormat;
}
void SDL2Renderer::LoadTexture(Gwen::Texture* pTexture)
{
if (!pTexture)
return;
if (pTexture->data)
FreeTexture(pTexture);
SDL_Texture *tex = NULL;
// Don't need to read. Just load straight into render format.
tex = IMG_LoadTexture(m_renderer, pTexture->name.c_str());
if (tex)
{
int w, h;
SDL_QueryTexture(tex, NULL, NULL, &w, &h);
pTexture->data = tex;
pTexture->width = w;
pTexture->height = h;
pTexture->failed = false;
}
else
{
pTexture->data = NULL;
pTexture->failed = true;
}
}
int CTextureManager::GetNewTextureID (int nPossibleTextureID) {
// First check if the possible textureID has already been
// used, however the default value is -1, err that is what
// this method is passed from LoadTexture ()
if (nPossibleTextureID != -1) {
for (int i = 0; i < m_Singleton->nAvailable; i++) {
if (m_Singleton->nTexIDs [i] == nPossibleTextureID) {
FreeTexture (nPossibleTextureID); // sets nTexIDs [i] to -1...
m_Singleton->nNumTextures--; // since we will add the ID again...
break;
}
}
}
// Actually look for a new one
int nNewTextureID;
if (nPossibleTextureID == -1) {
unsigned int nGLID;
glGenTextures (1, &nGLID);
nNewTextureID = (int) nGLID;
}
else // If the user is handle the textureIDs
nNewTextureID = nPossibleTextureID;
// find an empty slot in the TexID array
int nIndex = 0;
while (m_Singleton->nTexIDs [nIndex] != -1 && nIndex < m_Singleton->nAvailable)
nIndex++;
// all space exaused, make MORE!
if (nIndex >= m_Singleton->nAvailable) {
int *pNewIDs = new int [m_Singleton->nAvailable + TEXTURE_STEP];
int i;
// copy the old
for (i = 0; i < m_Singleton->nAvailable; i++)
pNewIDs [i] = m_Singleton->nTexIDs [i];
// set the last increment to the newest ID
pNewIDs [m_Singleton->nAvailable] = nNewTextureID;
// set the new to '-1'
for (i = 1; i < TEXTURE_STEP; i++)
pNewIDs [i + m_Singleton->nAvailable] = -1;
m_Singleton->nAvailable += TEXTURE_STEP;
delete [] m_Singleton->nTexIDs;
m_Singleton->nTexIDs = pNewIDs;
}
else
m_Singleton->nTexIDs [nIndex] = nNewTextureID;
// Welcome to our Texture Array!
m_Singleton->nNumTextures++;
return nNewTextureID;
}
// free all textures
void FreeTextures(void)
{
// TODO: Медленно же!!111
for(;;)
{
if(texture_count > 0)
FreeTexture(&textures[texture_count-1]);
else
break;
}
}
void TextureCacheBase::Invalidate()
{
UnbindTextures();
TexCache::iterator iter = textures_by_address.begin();
TexCache::iterator end = textures_by_address.end();
while (iter != end)
{
iter = FreeTexture(iter);
}
textures_by_address.clear();
textures_by_hash.clear();
}
/*
Function: Main entry point ( Application main )
Flow:
- Init GLUT
- Setup Window Buffers ( Double render buffer as well as support
for Alpha, and Depth buffer)
- Setup Window Width, Height, X, Y Position
- Create Window with title
- Setup Lighting
- Set callback to display function for rendering
- Set callback to reshape function for changing the size of the viewport
- Set callback to keyPressed and keyUp to handle keyboard input
- Tell GLUT to enter main loop
E.g
while( running ) {
doApplicationStuff();
}
End State:
Creation and running of an application as well as closing and
releasing all resources used by the application
*/
int main(int argc, char **argv)
{
int windowWidth = 500;
int windowHeight = 500;
int windowXPos = 100;
int windowYPos = 100;
// Initialize GLUT with command line input
glutInit(&argc, argv);
// Set up a basic buffer (only single buffered for now)
glutInitDisplayMode(GLUT_DOUBLE | GLUT_DEPTH);
glutGameModeString("1440x900:32@60");
glutEnterGameMode();
// Set width ,height, X Pos and Y pos of window
//glutInitWindowSize(windowWidth, windowHeight);
//glutInitWindowPosition(windowXPos, windowYPos);
// Create window with title
//glutCreateWindow("Basic Window with lighting!");
// Clear keyboard state
initKeyboardState();
// Setup lighting
initLighting();
// Initiate object lists
CreateCube();
// Setup Idle and Display to both use the 'display' function,
// set the reshape event to use the 'reshape' funciton
glutDisplayFunc(display);
glutIdleFunc(display);
glutReshapeFunc(reshape);
// Set keyboard callback function to handle key pressing and releasing
glutKeyboardFunc(keyPressed);
glutKeyboardUpFunc(keyUp);
glutSpecialFunc(keySpecialPressed);
glutSpecialUpFunc(keySpecialUp);
// Run the main loop which will handle closing of the application
glutMainLoop();
// Free the texture
FreeTexture( texture );
}
static void FreeAllTextures(void)
{
int i;
TC_Texture_t *WorkPtr;
WorkPtr = c_textures;
i = MAX_CACHED_TEXTURES;
do {
if (WorkPtr->used) { /* Is this used? */
FreeTexture(WorkPtr); /* Zap this texture */
}
++WorkPtr; /* Continue traversal */
} while (--i);
c_num_textures = 0;
}
void Gwen::Renderer::SFML2::LoadTexture( Gwen::Texture* pTexture )
{
if ( !pTexture ) return;
if ( pTexture->data ) FreeTexture( pTexture );
sf::Texture* tex = new sf::Texture();
tex->setSmooth( true );
if ( !tex->loadFromFile( pTexture->name.Get() ) )
{
delete( tex );
pTexture->failed = true;
return;
}
pTexture->height = tex->getSize().x;
pTexture->width = tex->getSize().y;
pTexture->data = new TextureData( tex );
}
void ClanLib::LoadTexture( Gwen::Texture* pTexture )
{
if ( !pTexture ) { return; }
if ( pTexture->data ) { FreeTexture( pTexture ); }
clan::Image* tex = new clan::Image(m_Target, pTexture->name.Get(), m_FileSystem);
//tex->SetSmooth( true );
//if ( !tex->LoadFromFile( pTexture->name.Get() ) )
if (tex->is_null())
{
delete( tex );
pTexture->failed = true;
return;
}
pTexture->height = tex->get_height();
pTexture->width = tex->get_width();
pTexture->data = new TextureData( tex );
};
void SDL2::LoadTexture(Gwen::Texture* pTexture)
{
if (!pTexture)
return;
if (pTexture->data)
FreeTexture(pTexture);
SDL_Texture *tex = NULL;
if (pTexture->readable)
{
// You cannot find the format of a texture once loaded to read from it
// in SDL2 so we have to keep the surface to read from.
SDL_Surface *surf = IMG_Load(pTexture->name.c_str());
tex = SDL_CreateTextureFromSurface(m_renderer, surf);
pTexture->surface = surf;
}
else
{
// Don't need to read. Just load straight into render format.
tex = IMG_LoadTexture(m_renderer, pTexture->name.c_str());
}
if (tex)
{
int w, h;
SDL_QueryTexture(tex, NULL, NULL, &w, &h);
pTexture->data = tex;
pTexture->width = w;
pTexture->height = h;
pTexture->failed = false;
}
else
{
pTexture->data = NULL;
pTexture->failed = true;
}
}
/**
* Texture wrapper class
* @return bool
* @param fileName The file path of the image
*/
bool Texture::LoadFromFile (std::string fileName )
{
//Clean up first
FreeTexture();
//The final texture
SDL_Texture* newTexture = NULL;
//Load image at specified path
SDL_Surface* loadedSurface = IMG_Load( fileName.c_str() );
if( loadedSurface == NULL )
{
printf( "Unable to load image %s! SDL_image Error: %s\n", fileName.c_str(), IMG_GetError() );
}
else
{
//Create texture from surface pixels
newTexture = SDL_CreateTextureFromSurface( ResourceManager::getResourceManager().GetGlobalRenderer(),
loadedSurface );
if( newTexture == NULL )
{
printf( "Unable to create texture from %s! SDL Error: %s\n", fileName.c_str(), SDL_GetError() );
}
else
{
//Get image dimensions
mWidth = loadedSurface->w;
mHeight = loadedSurface->h;
}
//Get rid of old loaded surface
SDL_FreeSurface( loadedSurface );
}
//Return success
mTexture = newTexture;
return mTexture != NULL;
}
int main(int argc, char **argv)
{
glutInit(&argc, argv); // Initializes glut
// Sets up a double buffer with RGBA components and a depth component
glutInitDisplayMode(GLUT_DOUBLE | GLUT_DEPTH | GLUT_RGBA);
// Sets the window size to 512*512 square pixels
glutInitWindowSize(512, 512);
// Sets the window position to the upper left
glutInitWindowPosition(0, 0);
// Creates a window using internal glut functionality
glutCreateWindow("Hello!");
// passes reshape and display functions to the OpenGL machine for callback
// glutReshapeFunc(reshape);
glutDisplayFunc(display);
glutIdleFunc(display);
init();
g_texture = LoadTextureRAW("texture.raw", true);
if (!g_texture)
{
printf("texture load error!\n");
return -1;
}
// Starts the program.
glutMainLoop();
FreeTexture(g_texture);
return 0;
}
void SFML::LoadTexture( Gwen::Texture* pTexture )
{
if ( !pTexture ) return;
if ( pTexture->data ) FreeTexture( pTexture );
#if SFML_VERSION_MAJOR == 2
sf::Texture* tex = new sf::Texture();
#else
sf::Image* tex = new sf::Image();
#endif
tex->SetSmooth( true );
if ( !tex->LoadFromFile( pTexture->name.Get() ) )
{
delete( tex );
pTexture->failed = true;
return;
}
pTexture->height = tex->GetHeight();
pTexture->width = tex->GetWidth();
pTexture->data = tex;
};
TextureCache::TCacheEntryBase* TextureCache::Load(const u32 stage)
{
const FourTexUnits &tex = bpmem.tex[stage >> 2];
const u32 id = stage & 3;
const u32 address = (tex.texImage3[id].image_base/* & 0x1FFFFF*/) << 5;
u32 width = tex.texImage0[id].width + 1;
u32 height = tex.texImage0[id].height + 1;
const int texformat = tex.texImage0[id].format;
const u32 tlutaddr = tex.texTlut[id].tmem_offset << 9;
const u32 tlutfmt = tex.texTlut[id].tlut_format;
const bool use_mipmaps = (tex.texMode0[id].min_filter & 3) != 0;
u32 tex_levels = use_mipmaps ? ((tex.texMode1[id].max_lod + 0xf) / 0x10 + 1) : 1;
const bool from_tmem = tex.texImage1[id].image_type != 0;
if (0 == address)
return nullptr;
// TexelSizeInNibbles(format) * width * height / 16;
const unsigned int bsw = TexDecoder_GetBlockWidthInTexels(texformat);
const unsigned int bsh = TexDecoder_GetBlockHeightInTexels(texformat);
unsigned int expandedWidth = ROUND_UP(width, bsw);
unsigned int expandedHeight = ROUND_UP(height, bsh);
const unsigned int nativeW = width;
const unsigned int nativeH = height;
// Hash assigned to texcache entry (also used to generate filenames used for texture dumping and custom texture lookup)
u64 base_hash = TEXHASH_INVALID;
u64 full_hash = TEXHASH_INVALID;
u32 full_format = texformat;
const bool isPaletteTexture = (texformat == GX_TF_C4 || texformat == GX_TF_C8 || texformat == GX_TF_C14X2);
// Reject invalid tlut format.
if (isPaletteTexture && tlutfmt > GX_TL_RGB5A3)
return nullptr;
if (isPaletteTexture)
full_format = texformat | (tlutfmt << 16);
const u32 texture_size = TexDecoder_GetTextureSizeInBytes(expandedWidth, expandedHeight, texformat);
u32 additional_mips_size = 0; // not including level 0, which is texture_size
// GPUs don't like when the specified mipmap count would require more than one 1x1-sized LOD in the mipmap chain
// e.g. 64x64 with 7 LODs would have the mipmap chain 64x64,32x32,16x16,8x8,4x4,2x2,1x1,0x0, so we limit the mipmap count to 6 there
tex_levels = std::min<u32>(IntLog2(std::max(width, height)) + 1, tex_levels);
for (u32 level = 1; level != tex_levels; ++level)
{
// We still need to calculate the original size of the mips
const u32 expanded_mip_width = ROUND_UP(CalculateLevelSize(width, level), bsw);
const u32 expanded_mip_height = ROUND_UP(CalculateLevelSize(height, level), bsh);
additional_mips_size += TexDecoder_GetTextureSizeInBytes(expanded_mip_width, expanded_mip_height, texformat);
}
// If we are recording a FifoLog, keep track of what memory we read.
// FifiRecorder does it's own memory modification tracking independant of the texture hashing below.
if (g_bRecordFifoData && !from_tmem)
FifoRecorder::GetInstance().UseMemory(address, texture_size + additional_mips_size, MemoryUpdate::TEXTURE_MAP);
const u8* src_data;
if (from_tmem)
src_data = &texMem[bpmem.tex[stage / 4].texImage1[stage % 4].tmem_even * TMEM_LINE_SIZE];
else
src_data = Memory::GetPointer(address);
// TODO: This doesn't hash GB tiles for preloaded RGBA8 textures (instead, it's hashing more data from the low tmem bank than it should)
base_hash = GetHash64(src_data, texture_size, g_ActiveConfig.iSafeTextureCache_ColorSamples);
u32 palette_size = 0;
if (isPaletteTexture)
{
palette_size = TexDecoder_GetPaletteSize(texformat);
full_hash = base_hash ^ GetHash64(&texMem[tlutaddr], palette_size, g_ActiveConfig.iSafeTextureCache_ColorSamples);
}
else
{
full_hash = base_hash;
}
// Search the texture cache for textures by address
//
// Find all texture cache entries for the current texture address, and decide whether to use one of
// them, or to create a new one
//
// In most cases, the fastest way is to use only one texture cache entry for the same address. Usually,
// when a texture changes, the old version of the texture is unlikely to be used again. If there were
// new cache entries created for normal texture updates, there would be a slowdown due to a huge amount
// of unused cache entries. Also thanks to texture pooling, overwriting an existing cache entry is
// faster than creating a new one from scratch.
//
// Some games use the same address for different textures though. If the same cache entry was used in
// this case, it would be constantly overwritten, and effectively there wouldn't be any caching for
// those textures. Examples for this are Metroid Prime and Castlevania 3. Metroid Prime has multiple
// sets of fonts on each other stored in a single texture and uses the palette to make different
// characters visible or invisible. In Castlevania 3 some textures are used for 2 different things or
// at least in 2 different ways(size 1024x1024 vs 1024x256).
//
// To determine whether to use multiple cache entries or a single entry, use the following heuristic:
// If the same texture address is used several times during the same frame, assume the address is used
// for different purposes and allow creating an additional cache entry. If there's at least one entry
// that hasn't been used for the same frame, then overwrite it, in order to keep the cache as small as
// possible. If the current texture is found in the cache, use that entry.
//
// For efb copies, the entry created in CopyRenderTargetToTexture always has to be used, or else it was
// done in vain.
std::pair<TexCache::iterator, TexCache::iterator> iter_range = textures_by_address.equal_range((u64)address);
TexCache::iterator iter = iter_range.first;
TexCache::iterator oldest_entry = iter;
int temp_frameCount = 0x7fffffff;
TexCache::iterator unconverted_copy = textures_by_address.end();
while (iter != iter_range.second)
{
TCacheEntryBase* entry = iter->second;
// Do not load strided EFB copies, they are not meant to be used directly
if (entry->IsEfbCopy() && entry->native_width == nativeW && entry->native_height == nativeH &&
entry->memory_stride == entry->CacheLinesPerRow() * 32)
{
// EFB copies have slightly different rules as EFB copy formats have different
// meanings from texture formats.
if ((base_hash == entry->hash && (!isPaletteTexture || g_Config.backend_info.bSupportsPaletteConversion)) ||
IsPlayingBackFifologWithBrokenEFBCopies)
{
// TODO: We should check format/width/height/levels for EFB copies. Checking
// format is complicated because EFB copy formats don't exactly match
// texture formats. I'm not sure what effect checking width/height/levels
// would have.
if (!isPaletteTexture || !g_Config.backend_info.bSupportsPaletteConversion)
return ReturnEntry(stage, entry);
// Note that we found an unconverted EFB copy, then continue. We'll
// perform the conversion later. Currently, we only convert EFB copies to
// palette textures; we could do other conversions if it proved to be
// beneficial.
unconverted_copy = iter;
}
else
{
// Aggressively prune EFB copies: if it isn't useful here, it will probably
// never be useful again. It's theoretically possible for a game to do
// something weird where the copy could become useful in the future, but in
// practice it doesn't happen.
iter = FreeTexture(iter);
continue;
}
}
else
{
// For normal textures, all texture parameters need to match
if (entry->hash == full_hash && entry->format == full_format && entry->native_levels >= tex_levels &&
entry->native_width == nativeW && entry->native_height == nativeH)
{
entry = DoPartialTextureUpdates(iter);
return ReturnEntry(stage, entry);
}
}
// Find the texture which hasn't been used for the longest time. Count paletted
// textures as the same texture here, when the texture itself is the same. This
// improves the performance a lot in some games that use paletted textures.
// Example: Sonic the Fighters (inside Sonic Gems Collection)
// Skip EFB copies here, so they can be used for partial texture updates
if (entry->frameCount != FRAMECOUNT_INVALID && entry->frameCount < temp_frameCount &&
!entry->IsEfbCopy() && !(isPaletteTexture && entry->base_hash == base_hash))
{
temp_frameCount = entry->frameCount;
oldest_entry = iter;
}
++iter;
}
if (unconverted_copy != textures_by_address.end())
{
// Perform palette decoding.
TCacheEntryBase *entry = unconverted_copy->second;
TCacheEntryConfig config;
config.rendertarget = true;
config.width = entry->config.width;
config.height = entry->config.height;
config.layers = FramebufferManagerBase::GetEFBLayers();
TCacheEntryBase *decoded_entry = AllocateTexture(config);
decoded_entry->SetGeneralParameters(address, texture_size, full_format);
decoded_entry->SetDimensions(entry->native_width, entry->native_height, 1);
decoded_entry->SetHashes(base_hash, full_hash);
decoded_entry->frameCount = FRAMECOUNT_INVALID;
decoded_entry->is_efb_copy = false;
g_texture_cache->ConvertTexture(decoded_entry, entry, &texMem[tlutaddr], (TlutFormat)tlutfmt);
textures_by_address.emplace((u64)address, decoded_entry);
return ReturnEntry(stage, decoded_entry);
}
// Search the texture cache for normal textures by hash
//
// If the texture was fully hashed, the address does not need to match. Identical duplicate textures cause unnecessary slowdowns
// Example: Tales of Symphonia (GC) uses over 500 small textures in menus, but only around 70 different ones
if (g_ActiveConfig.iSafeTextureCache_ColorSamples == 0 ||
std::max(texture_size, palette_size) <= (u32)g_ActiveConfig.iSafeTextureCache_ColorSamples * 8)
{
iter_range = textures_by_hash.equal_range(full_hash);
iter = iter_range.first;
while (iter != iter_range.second)
{
TCacheEntryBase* entry = iter->second;
// All parameters, except the address, need to match here
if (entry->format == full_format && entry->native_levels >= tex_levels &&
entry->native_width == nativeW && entry->native_height == nativeH)
{
entry = DoPartialTextureUpdates(iter);
return ReturnEntry(stage, entry);
}
++iter;
}
}
// If at least one entry was not used for the same frame, overwrite the oldest one
if (temp_frameCount != 0x7fffffff)
{
// pool this texture and make a new one later
FreeTexture(oldest_entry);
}
std::shared_ptr<HiresTexture> hires_tex;
if (g_ActiveConfig.bHiresTextures)
{
hires_tex = HiresTexture::Search(
src_data, texture_size,
&texMem[tlutaddr], palette_size,
width, height,
texformat, use_mipmaps
);
if (hires_tex)
{
auto& l = hires_tex->m_levels[0];
if (l.width != width || l.height != height)
{
width = l.width;
height = l.height;
}
expandedWidth = l.width;
expandedHeight = l.height;
CheckTempSize(l.data_size);
memcpy(temp, l.data, l.data_size);
}
}
if (!hires_tex)
{
if (!(texformat == GX_TF_RGBA8 && from_tmem))
{
const u8* tlut = &texMem[tlutaddr];
TexDecoder_Decode(temp, src_data, expandedWidth, expandedHeight, texformat, tlut, (TlutFormat)tlutfmt);
}
else
{
u8* src_data_gb = &texMem[bpmem.tex[stage / 4].texImage2[stage % 4].tmem_odd * TMEM_LINE_SIZE];
TexDecoder_DecodeRGBA8FromTmem(temp, src_data, src_data_gb, expandedWidth, expandedHeight);
}
}
// how many levels the allocated texture shall have
const u32 texLevels = hires_tex ? (u32)hires_tex->m_levels.size() : tex_levels;
// create the entry/texture
TCacheEntryConfig config;
config.width = width;
config.height = height;
config.levels = texLevels;
TCacheEntryBase* entry = AllocateTexture(config);
GFX_DEBUGGER_PAUSE_AT(NEXT_NEW_TEXTURE, true);
iter = textures_by_address.emplace((u64)address, entry);
if (g_ActiveConfig.iSafeTextureCache_ColorSamples == 0 ||
std::max(texture_size, palette_size) <= (u32)g_ActiveConfig.iSafeTextureCache_ColorSamples * 8)
{
entry->textures_by_hash_iter = textures_by_hash.emplace(full_hash, entry);
}
entry->SetGeneralParameters(address, texture_size, full_format);
entry->SetDimensions(nativeW, nativeH, tex_levels);
entry->SetHashes(base_hash, full_hash);
entry->is_efb_copy = false;
entry->is_custom_tex = hires_tex != nullptr;
// load texture
entry->Load(width, height, expandedWidth, 0);
std::string basename = "";
if (g_ActiveConfig.bDumpTextures && !hires_tex)
{
basename = HiresTexture::GenBaseName(
src_data, texture_size,
&texMem[tlutaddr], palette_size,
width, height,
texformat, use_mipmaps,
true
);
DumpTexture(entry, basename, 0);
}
if (hires_tex)
{
for (u32 level = 1; level != texLevels; ++level)
{
auto& l = hires_tex->m_levels[level];
CheckTempSize(l.data_size);
memcpy(temp, l.data, l.data_size);
entry->Load(l.width, l.height, l.width, level);
}
}
else
{
// load mips - TODO: Loading mipmaps from tmem is untested!
src_data += texture_size;
const u8* ptr_even = nullptr;
const u8* ptr_odd = nullptr;
if (from_tmem)
{
ptr_even = &texMem[bpmem.tex[stage / 4].texImage1[stage % 4].tmem_even * TMEM_LINE_SIZE + texture_size];
ptr_odd = &texMem[bpmem.tex[stage / 4].texImage2[stage % 4].tmem_odd * TMEM_LINE_SIZE];
}
for (u32 level = 1; level != texLevels; ++level)
{
const u32 mip_width = CalculateLevelSize(width, level);
const u32 mip_height = CalculateLevelSize(height, level);
const u32 expanded_mip_width = ROUND_UP(mip_width, bsw);
const u32 expanded_mip_height = ROUND_UP(mip_height, bsh);
const u8*& mip_src_data = from_tmem
? ((level % 2) ? ptr_odd : ptr_even)
: src_data;
const u8* tlut = &texMem[tlutaddr];
TexDecoder_Decode(temp, mip_src_data, expanded_mip_width, expanded_mip_height, texformat, tlut, (TlutFormat)tlutfmt);
mip_src_data += TexDecoder_GetTextureSizeInBytes(expanded_mip_width, expanded_mip_height, texformat);
entry->Load(mip_width, mip_height, expanded_mip_width, level);
if (g_ActiveConfig.bDumpTextures)
DumpTexture(entry, basename, level);
}
}
INCSTAT(stats.numTexturesUploaded);
SETSTAT(stats.numTexturesAlive, textures_by_address.size());
entry = DoPartialTextureUpdates(iter);
return ReturnEntry(stage, entry);
}
void TextureCacheBase::ScaleTextureCacheEntryTo(TextureCacheBase::TCacheEntryBase** entry, u32 new_width, u32 new_height)
{
if ((*entry)->config.width == new_width && (*entry)->config.height == new_height)
{
return;
}
u32 max = g_renderer->GetMaxTextureSize();
if (max < new_width || max < new_height)
{
ERROR_LOG(VIDEO, "Texture too big, width = %d, height = %d", new_width, new_height);
return;
}
TextureCacheBase::TCacheEntryConfig newconfig;
newconfig.width = new_width;
newconfig.height = new_height;
newconfig.layers = (*entry)->config.layers;
newconfig.rendertarget = true;
TCacheEntryBase* newentry = AllocateTexture(newconfig);
if (newentry)
{
newentry->SetGeneralParameters((*entry)->addr, (*entry)->size_in_bytes, (*entry)->format);
newentry->SetDimensions((*entry)->native_width, (*entry)->native_height, 1);
newentry->SetHashes((*entry)->base_hash, (*entry)->hash);
newentry->frameCount = frameCount;
newentry->is_efb_copy = (*entry)->is_efb_copy;
MathUtil::Rectangle<int> srcrect, dstrect;
srcrect.left = 0;
srcrect.top = 0;
srcrect.right = (*entry)->config.width;
srcrect.bottom = (*entry)->config.height;
dstrect.left = 0;
dstrect.top = 0;
dstrect.right = new_width;
dstrect.bottom = new_height;
newentry->CopyRectangleFromTexture(*entry, srcrect, dstrect);
// Keep track of the pointer for textures_by_hash
if ((*entry)->textures_by_hash_iter != textures_by_hash.end())
{
newentry->textures_by_hash_iter = textures_by_hash.emplace((*entry)->hash, newentry);
}
// Remove the old texture
std::pair<TexCache::iterator, TexCache::iterator>iter_range = textures_by_address.equal_range((*entry)->addr);
TexCache::iterator iter = iter_range.first;
while (iter != iter_range.second)
{
if (iter->second == *entry)
{
FreeTexture(iter);
iter = iter_range.second;
}
else
{
iter++;
}
}
*entry = newentry;
textures_by_address.emplace((*entry)->addr, *entry);
}
else
{
ERROR_LOG(VIDEO, "Scaling failed");
}
}
OpenGL_DebugFont::~OpenGL_DebugFont()
{
FreeTexture( m_pFontTexture );
delete m_pFontTexture;
}
void CTextureMap::Flush()
{
if (!m_referenceCount)
FreeTexture();
}
TextureCacheBase::TCacheEntryBase* TextureCacheBase::DoPartialTextureUpdates(TexCache::iterator iter_t)
{
TCacheEntryBase* entry_to_update = iter_t->second;
const bool isPaletteTexture = (entry_to_update->format == GX_TF_C4
|| entry_to_update->format == GX_TF_C8
|| entry_to_update->format == GX_TF_C14X2
|| entry_to_update->format >= 0x10000);
// Efb copies and paletted textures are excluded from these updates, until there's an example where a game would
// benefit from this. Both would require more work to be done.
if (entry_to_update->IsEfbCopy()
|| isPaletteTexture)
return entry_to_update;
u32 block_width = TexDecoder_GetBlockWidthInTexels(entry_to_update->format & 0xf);
u32 block_height = TexDecoder_GetBlockHeightInTexels(entry_to_update->format & 0xf);
u32 block_size = block_width * block_height * TexDecoder_GetTexelSizeInNibbles(entry_to_update->format & 0xf) / 2;
u32 numBlocksX = (entry_to_update->native_width + block_width - 1) / block_width;
TexCache::iterator iter = textures_by_address.lower_bound(entry_to_update->addr);
TexCache::iterator iterend = textures_by_address.upper_bound(entry_to_update->addr + entry_to_update->size_in_bytes);
while (iter != iterend)
{
TCacheEntryBase* entry = iter->second;
if (entry != entry_to_update
&& entry->IsEfbCopy()
&& entry->OverlapsMemoryRange(entry_to_update->addr, entry_to_update->size_in_bytes)
&& entry->frameCount == FRAMECOUNT_INVALID
&& entry->memory_stride == numBlocksX * block_size)
{
if (entry->hash == entry->CalculateHash())
{
u32 src_x, src_y, dst_x, dst_y;
// Note for understanding the math:
// Normal textures can't be strided, so the 2 missing cases with src_x > 0 don't exist
if (entry->addr >= entry_to_update->addr)
{
u32 block_offset = (entry->addr - entry_to_update->addr) / block_size;
u32 block_x = block_offset % numBlocksX;
u32 block_y = block_offset / numBlocksX;
src_x = 0;
src_y = 0;
dst_x = block_x * block_width;
dst_y = block_y * block_height;
}
else
{
u32 block_offset = (entry_to_update->addr - entry->addr) / block_size;
u32 block_x = (~block_offset + 1) % numBlocksX;
u32 block_y = (block_offset + block_x) / numBlocksX;
src_x = 0;
src_y = block_y * block_height;
dst_x = block_x * block_width;
dst_y = 0;
}
u32 copy_width = std::min(entry->native_width - src_x, entry_to_update->native_width - dst_x);
u32 copy_height = std::min(entry->native_height - src_y, entry_to_update->native_height - dst_y);
// If one of the textures is scaled, scale both with the current efb scaling factor
if (entry_to_update->native_width != entry_to_update->config.width
|| entry_to_update->native_height != entry_to_update->config.height
|| entry->native_width != entry->config.width || entry->native_height != entry->config.height)
{
ScaleTextureCacheEntryTo(&entry_to_update, Renderer::EFBToScaledX(entry_to_update->native_width), Renderer::EFBToScaledY(entry_to_update->native_height));
ScaleTextureCacheEntryTo(&entry, Renderer::EFBToScaledX(entry->native_width), Renderer::EFBToScaledY(entry->native_height));
src_x = Renderer::EFBToScaledX(src_x);
src_y = Renderer::EFBToScaledY(src_y);
dst_x = Renderer::EFBToScaledX(dst_x);
dst_y = Renderer::EFBToScaledY(dst_y);
copy_width = Renderer::EFBToScaledX(copy_width);
copy_height = Renderer::EFBToScaledY(copy_height);
}
MathUtil::Rectangle<int> srcrect, dstrect;
srcrect.left = src_x;
srcrect.top = src_y;
srcrect.right = (src_x + copy_width);
srcrect.bottom = (src_y + copy_height);
dstrect.left = dst_x;
dstrect.top = dst_y;
dstrect.right = (dst_x + copy_width);
dstrect.bottom = (dst_y + copy_height);
entry_to_update->CopyRectangleFromTexture(entry, srcrect, dstrect);
// Mark the texture update as used, so it isn't applied more than once
entry->frameCount = frameCount;
}
else
{
// If the hash does not match, this EFB copy will not be used for anything, so remove it
iter = FreeTexture(iter);
continue;
}
}
++iter;
}
return entry_to_update;
}
CCommonWnd::~CCommonWnd()
{
if(m_pBackTexture)
FreeTexture(m_pBackTexture);
}
CTextureMap::~CTextureMap()
{
FreeTexture();
}
void CTex::FreeTexture (std::string name)
{
FreeTexture (GetTexID (name));
}
/**
* Destructor
*/
Texture::~Texture ( )
{
FreeTexture();
}
void FreeTexture(const char* texture_name)
{
// just find font by name and free it, using FS_FreeFont(font_t*)
FreeTexture(TextureByName(texture_name));
}
TextureCache::TCacheEntryBase* TextureCache::DoPartialTextureUpdates(TexCache::iterator iter_t)
{
TCacheEntryBase* entry_to_update = iter_t->second;
const bool isPaletteTexture = (entry_to_update->format == GX_TF_C4
|| entry_to_update->format == GX_TF_C8
|| entry_to_update->format == GX_TF_C14X2
|| entry_to_update->format >= 0x10000);
// Efb copies and paletted textures are excluded from these updates, until there's an example where a game would
// benefit from this. Both would require more work to be done.
// TODO: Implement upscaling support for normal textures, and then remove the efb to ram and the scaled efb restrictions
if (entry_to_update->IsEfbCopy()
|| isPaletteTexture)
return entry_to_update;
u32 block_width = TexDecoder_GetBlockWidthInTexels(entry_to_update->format);
u32 block_height = TexDecoder_GetBlockHeightInTexels(entry_to_update->format);
u32 block_size = block_width * block_height * TexDecoder_GetTexelSizeInNibbles(entry_to_update->format) / 2;
u32 numBlocksX = (entry_to_update->native_width + block_width - 1) / block_width;
TexCache::iterator iter = textures_by_address.lower_bound(entry_to_update->addr);
TexCache::iterator iterend = textures_by_address.upper_bound(entry_to_update->addr + entry_to_update->size_in_bytes);
bool entry_need_scaling = true;
while (iter != iterend)
{
TCacheEntryBase* entry = iter->second;
if (entry != entry_to_update
&& entry->IsEfbCopy()
&& entry_to_update->addr <= entry->addr
&& entry->addr + entry->size_in_bytes <= entry_to_update->addr + entry_to_update->size_in_bytes
&& entry->frameCount == FRAMECOUNT_INVALID
&& entry->memory_stride == numBlocksX * block_size)
{
u32 block_offset = (entry->addr - entry_to_update->addr) / block_size;
u32 block_x = block_offset % numBlocksX;
u32 block_y = block_offset / numBlocksX;
u32 x = block_x * block_width;
u32 y = block_y * block_height;
MathUtil::Rectangle<int> srcrect, dstrect;
srcrect.left = 0;
srcrect.top = 0;
dstrect.left = 0;
dstrect.top = 0;
if (entry_need_scaling)
{
entry_need_scaling = false;
u32 w = entry_to_update->native_width * entry->config.width / entry->native_width;
u32 h = entry_to_update->native_height * entry->config.height / entry->native_height;
u32 max = g_renderer->GetMaxTextureSize();
if (max < w || max < h)
{
iter++;
continue;
}
if (entry_to_update->config.width != w || entry_to_update->config.height != h)
{
TextureCache::TCacheEntryConfig newconfig;
newconfig.width = w;
newconfig.height = h;
newconfig.rendertarget = true;
TCacheEntryBase* newentry = AllocateTexture(newconfig);
newentry->SetGeneralParameters(entry_to_update->addr, entry_to_update->size_in_bytes, entry_to_update->format);
newentry->SetDimensions(entry_to_update->native_width, entry_to_update->native_height, 1);
newentry->SetHashes(entry_to_update->base_hash, entry_to_update->hash);
newentry->frameCount = frameCount;
newentry->is_efb_copy = false;
srcrect.right = entry_to_update->config.width;
srcrect.bottom = entry_to_update->config.height;
dstrect.right = w;
dstrect.bottom = h;
newentry->CopyRectangleFromTexture(entry_to_update, srcrect, dstrect);
entry_to_update = newentry;
u64 key = iter_t->first;
iter_t = FreeTexture(iter_t);
textures_by_address.emplace(key, entry_to_update);
}
}
srcrect.right = entry->config.width;
srcrect.bottom = entry->config.height;
dstrect.left = x * entry_to_update->config.width / entry_to_update->native_width;
dstrect.top = y * entry_to_update->config.height / entry_to_update->native_height;
dstrect.right = (x + entry->native_width) * entry_to_update->config.width / entry_to_update->native_width;
dstrect.bottom = (y + entry->native_height) * entry_to_update->config.height / entry_to_update->native_height;
entry_to_update->CopyRectangleFromTexture(entry, srcrect, dstrect);
// Mark the texture update as used, so it isn't applied more than once
entry->frameCount = frameCount;
}
++iter;
}
return entry_to_update;
}
// WinMain
int WINAPI WinMain(HINSTANCE hinstance, HINSTANCE hprev, PSTR cmdline, int ishow)
{
MSG msg = {0};
HWND hwnd = NULL;
WNDCLASSEX wndclassex = {0};
// Fill the fields we care about
wndclassex.cbSize = sizeof(WNDCLASSEX);
wndclassex.style = CS_HREDRAW | CS_VREDRAW;
wndclassex.lpfnWndProc = WinProc;
wndclassex.hInstance = hinstance;
wndclassex.lpszClassName = class_name;
wndclassex.hbrBackground = (HBRUSH)GetStockObject(BLACK_BRUSH);
wndclassex.hCursor = (HCURSOR)LoadImage(NULL, MAKEINTRESOURCE(IDC_ARROW),
IMAGE_CURSOR, 0, 0, LR_SHARED);
RegisterClassEx(&wndclassex); // Register the class
RECT rect = { 0, 0, WIN_WID, WIN_HGT }; // Desired window client rect
DWORD winStyleEx = WS_EX_APPWINDOW;
DWORD winStyle = WS_CAPTION | WS_SYSMENU; // Window style
// Adjust window rect so it gives us our desired client rect when we
// create the window
AdjustWindowRectEx(&rect, winStyle, false, winStyleEx);
// Create our window -- Notice how we set use different "variables" when creating
// the window based upon if we were able to switch to full screen or not
hwnd = CreateWindowEx(winStyleEx,
class_name,
"www.GameTutorials.com -- Texture Mapping",
winStyle,
CW_USEDEFAULT,
CW_USEDEFAULT,
rect.right - rect.left, // Window width
rect.bottom - rect.top, // Window height
NULL,
NULL,
hinstance,
NULL);
// Error Check
if(!hwnd)
goto CLEAN_UP; // Here we are going to use goto in a "good" way
// We have a few things we want to initialize so if
// any of them fail, we just go to the "clean up code"
// Get the client RECT
GetClientRect(hwnd, &rect);
// If the client width or height isn't what we requested, there's been
// an error somewhere and we're going to bail ship
if(rect.right != WIN_WID || rect.bottom != WIN_HGT)
goto CLEAN_UP;
HDC hdc = GetDC(hwnd); // Get the window's hdc
// Initialize OpenGL
if(gGLObj.init(hdc, 32, 32) == false)
goto CLEAN_UP;
// Load the texture
if(LoadTexture() == false)
goto CLEAN_UP;
// Set up the view port
gGLObj.setViewPort(WIN_WID,WIN_HGT,45.0);
// Show and update window
ShowWindow(hwnd, ishow);
UpdateWindow(hwnd);
while(1)
{
if(PeekMessage(&msg,NULL,0,0,PM_REMOVE))
{
if(msg.message == WM_QUIT)
break;
TranslateMessage(&msg);
DispatchMessage(&msg);
}
else
{
gGLObj.begin(); // Begin to draw
// Bind the texture
glBindTexture(GL_TEXTURE_2D, gTextureID);
// Draw a quad (ie a square)
glBegin(GL_QUADS);
// glTexCoord2f() takes a U and V (U,V) into our texture. The U and V are
// in the range from 0 to 1. And work like this:
/* (0,1) (1,1)
_______
| |
| |
| | Just like Cartesian coordinates :)
-------
(0,0) (1,0)
*/
// Display the top left vertex
glTexCoord2f(0.0f, 1.0f);
glVertex3f(-1, 1, 0);
// Display the bottom left vertex
glTexCoord2f(0.0f, 0.0f);
glVertex3f(-1, -1, 0);
// Display the bottom right vertex
glTexCoord2f(1.0f, 0.0f);
glVertex3f(1, -1, 0);
// Display the top right vertex
glTexCoord2f(1.0f, 1.0f);
glVertex3f(1, 1, 0);
glEnd(); // Stop drawing QUADS
gGLObj.end(); // End drawing in 3D and blit to the screen
}
} // end of while(1)
CLEAN_UP:
if(hdc)
ReleaseDC(hwnd, hdc); // Be sure to free up the window's HDC
FreeTexture(); // Free the texture
UnregisterClass(class_name,hinstance); // Free up the WNDCLASSEX
return msg.wParam;
}
void TextureCache::CopyRenderTargetToTexture(u32 dstAddr, unsigned int dstFormat, u32 dstStride, PEControl::PixelFormat srcFormat,
const EFBRectangle& srcRect, bool isIntensity, bool scaleByHalf)
{
// Emulation methods:
//
// - EFB to RAM:
// Encodes the requested EFB data at its native resolution to the emulated RAM using shaders.
// Load() decodes the data from there again (using TextureDecoder) if the EFB copy is being used as a texture again.
// Advantage: CPU can read data from the EFB copy and we don't lose any important updates to the texture
// Disadvantage: Encoding+decoding steps often are redundant because only some games read or modify EFB copies before using them as textures.
//
// - EFB to texture:
// Copies the requested EFB data to a texture object in VRAM, performing any color conversion using shaders.
// Advantage: Works for many games, since in most cases EFB copies aren't read or modified at all before being used as a texture again.
// Since we don't do any further encoding or decoding here, this method is much faster.
// It also allows enhancing the visual quality by doing scaled EFB copies.
//
// - Hybrid EFB copies:
// 1a) Whenever this function gets called, encode the requested EFB data to RAM (like EFB to RAM)
// 1b) Set type to TCET_EC_DYNAMIC for all texture cache entries in the destination address range.
// If EFB copy caching is enabled, further checks will (try to) prevent redundant EFB copies.
// 2) Check if a texture cache entry for the specified dstAddr already exists (i.e. if an EFB copy was triggered to that address before):
// 2a) Entry doesn't exist:
// - Also copy the requested EFB data to a texture object in VRAM (like EFB to texture)
// - Create a texture cache entry for the target (type = TCET_EC_VRAM)
// - Store a hash of the encoded RAM data in the texcache entry.
// 2b) Entry exists AND type is TCET_EC_VRAM:
// - Like case 2a, but reuse the old texcache entry instead of creating a new one.
// 2c) Entry exists AND type is TCET_EC_DYNAMIC:
// - Only encode the texture to RAM (like EFB to RAM) and store a hash of the encoded data in the existing texcache entry.
// - Do NOT copy the requested EFB data to a VRAM object. Reason: the texture is dynamic, i.e. the CPU is modifying it. Storing a VRAM copy is useless, because we'd always end up deleting it and reloading the data from RAM anyway.
// 3) If the EFB copy gets used as a texture, compare the source RAM hash with the hash you stored when encoding the EFB data to RAM.
// 3a) If the two hashes match AND type is TCET_EC_VRAM, reuse the VRAM copy you created
// 3b) If the two hashes differ AND type is TCET_EC_VRAM, screw your existing VRAM copy. Set type to TCET_EC_DYNAMIC.
// Redecode the source RAM data to a VRAM object. The entry basically behaves like a normal texture now.
// 3c) If type is TCET_EC_DYNAMIC, treat the EFB copy like a normal texture.
// Advantage: Non-dynamic EFB copies can be visually enhanced like with EFB to texture.
// Compatibility is as good as EFB to RAM.
// Disadvantage: Slower than EFB to texture and often even slower than EFB to RAM.
// EFB copy cache depends on accurate texture hashing being enabled. However, with accurate hashing you end up being as slow as without a copy cache anyway.
//
// Disadvantage of all methods: Calling this function requires the GPU to perform a pipeline flush which stalls any further CPU processing.
//
// For historical reasons, Dolphin doesn't actually implement "pure" EFB to RAM emulation, but only EFB to texture and hybrid EFB copies.
float colmat[28] = { 0 };
float *const fConstAdd = colmat + 16;
float *const ColorMask = colmat + 20;
ColorMask[0] = ColorMask[1] = ColorMask[2] = ColorMask[3] = 255.0f;
ColorMask[4] = ColorMask[5] = ColorMask[6] = ColorMask[7] = 1.0f / 255.0f;
unsigned int cbufid = -1;
bool efbHasAlpha = bpmem.zcontrol.pixel_format == PEControl::RGBA6_Z24;
if (srcFormat == PEControl::Z24)
{
switch (dstFormat)
{
case 0: // Z4
colmat[3] = colmat[7] = colmat[11] = colmat[15] = 1.0f;
cbufid = 0;
dstFormat |= _GX_TF_CTF;
break;
case 8: // Z8H
dstFormat |= _GX_TF_CTF;
case 1: // Z8
colmat[0] = colmat[4] = colmat[8] = colmat[12] = 1.0f;
cbufid = 1;
break;
case 3: // Z16
colmat[1] = colmat[5] = colmat[9] = colmat[12] = 1.0f;
cbufid = 2;
break;
case 11: // Z16 (reverse order)
colmat[0] = colmat[4] = colmat[8] = colmat[13] = 1.0f;
cbufid = 3;
dstFormat |= _GX_TF_CTF;
break;
case 6: // Z24X8
colmat[0] = colmat[5] = colmat[10] = 1.0f;
cbufid = 4;
break;
case 9: // Z8M
colmat[1] = colmat[5] = colmat[9] = colmat[13] = 1.0f;
cbufid = 5;
dstFormat |= _GX_TF_CTF;
break;
case 10: // Z8L
colmat[2] = colmat[6] = colmat[10] = colmat[14] = 1.0f;
cbufid = 6;
dstFormat |= _GX_TF_CTF;
break;
case 12: // Z16L - copy lower 16 depth bits
// expected to be used as an IA8 texture (upper 8 bits stored as intensity, lower 8 bits stored as alpha)
// Used e.g. in Zelda: Skyward Sword
colmat[1] = colmat[5] = colmat[9] = colmat[14] = 1.0f;
cbufid = 7;
dstFormat |= _GX_TF_CTF;
break;
default:
ERROR_LOG(VIDEO, "Unknown copy zbuf format: 0x%x", dstFormat);
colmat[2] = colmat[5] = colmat[8] = 1.0f;
cbufid = 8;
break;
}
dstFormat |= _GX_TF_ZTF;
}
else if (isIntensity)
{
fConstAdd[0] = fConstAdd[1] = fConstAdd[2] = 16.0f / 255.0f;
switch (dstFormat)
{
case 0: // I4
case 1: // I8
case 2: // IA4
case 3: // IA8
case 8: // I8
// TODO - verify these coefficients
colmat[0] = 0.257f; colmat[1] = 0.504f; colmat[2] = 0.098f;
colmat[4] = 0.257f; colmat[5] = 0.504f; colmat[6] = 0.098f;
colmat[8] = 0.257f; colmat[9] = 0.504f; colmat[10] = 0.098f;
if (dstFormat < 2 || dstFormat == 8)
{
colmat[12] = 0.257f; colmat[13] = 0.504f; colmat[14] = 0.098f;
fConstAdd[3] = 16.0f / 255.0f;
if (dstFormat == 0)
{
ColorMask[0] = ColorMask[1] = ColorMask[2] = 15.0f;
ColorMask[4] = ColorMask[5] = ColorMask[6] = 1.0f / 15.0f;
cbufid = 9;
}
else
{
cbufid = 10;
}
}
else// alpha
{
colmat[15] = 1;
if (dstFormat == 2)
{
ColorMask[0] = ColorMask[1] = ColorMask[2] = ColorMask[3] = 15.0f;
ColorMask[4] = ColorMask[5] = ColorMask[6] = ColorMask[7] = 1.0f / 15.0f;
cbufid = 11;
}
else
{
cbufid = 12;
}
}
break;
default:
ERROR_LOG(VIDEO, "Unknown copy intensity format: 0x%x", dstFormat);
colmat[0] = colmat[5] = colmat[10] = colmat[15] = 1.0f;
cbufid = 13;
break;
}
}
else
{
switch (dstFormat)
{
case 0: // R4
colmat[0] = colmat[4] = colmat[8] = colmat[12] = 1;
ColorMask[0] = 15.0f;
ColorMask[4] = 1.0f / 15.0f;
cbufid = 14;
dstFormat |= _GX_TF_CTF;
break;
case 1: // R8
case 8: // R8
colmat[0] = colmat[4] = colmat[8] = colmat[12] = 1;
cbufid = 15;
dstFormat |= _GX_TF_CTF;
break;
case 2: // RA4
colmat[0] = colmat[4] = colmat[8] = colmat[15] = 1.0f;
ColorMask[0] = ColorMask[3] = 15.0f;
ColorMask[4] = ColorMask[7] = 1.0f / 15.0f;
cbufid = 16;
if (!efbHasAlpha)
{
ColorMask[3] = 0.0f;
fConstAdd[3] = 1.0f;
cbufid = 17;
}
dstFormat |= _GX_TF_CTF;
break;
case 3: // RA8
colmat[0] = colmat[4] = colmat[8] = colmat[15] = 1.0f;
cbufid = 18;
if (!efbHasAlpha)
{
ColorMask[3] = 0.0f;
fConstAdd[3] = 1.0f;
cbufid = 19;
}
dstFormat |= _GX_TF_CTF;
break;
case 7: // A8
colmat[3] = colmat[7] = colmat[11] = colmat[15] = 1.0f;
cbufid = 20;
if (!efbHasAlpha)
{
ColorMask[3] = 0.0f;
fConstAdd[0] = 1.0f;
fConstAdd[1] = 1.0f;
fConstAdd[2] = 1.0f;
fConstAdd[3] = 1.0f;
cbufid = 21;
}
dstFormat |= _GX_TF_CTF;
break;
case 9: // G8
colmat[1] = colmat[5] = colmat[9] = colmat[13] = 1.0f;
cbufid = 22;
dstFormat |= _GX_TF_CTF;
break;
case 10: // B8
colmat[2] = colmat[6] = colmat[10] = colmat[14] = 1.0f;
cbufid = 23;
dstFormat |= _GX_TF_CTF;
break;
case 11: // RG8
colmat[0] = colmat[4] = colmat[8] = colmat[13] = 1.0f;
cbufid = 24;
dstFormat |= _GX_TF_CTF;
break;
case 12: // GB8
colmat[1] = colmat[5] = colmat[9] = colmat[14] = 1.0f;
cbufid = 25;
dstFormat |= _GX_TF_CTF;
break;
case 4: // RGB565
colmat[0] = colmat[5] = colmat[10] = 1.0f;
ColorMask[0] = ColorMask[2] = 31.0f;
ColorMask[4] = ColorMask[6] = 1.0f / 31.0f;
ColorMask[1] = 63.0f;
ColorMask[5] = 1.0f / 63.0f;
fConstAdd[3] = 1.0f; // set alpha to 1
cbufid = 26;
break;
case 5: // RGB5A3
colmat[0] = colmat[5] = colmat[10] = colmat[15] = 1.0f;
ColorMask[0] = ColorMask[1] = ColorMask[2] = 31.0f;
ColorMask[4] = ColorMask[5] = ColorMask[6] = 1.0f / 31.0f;
ColorMask[3] = 7.0f;
ColorMask[7] = 1.0f / 7.0f;
cbufid = 27;
if (!efbHasAlpha)
{
ColorMask[3] = 0.0f;
fConstAdd[3] = 1.0f;
cbufid = 28;
}
break;
case 6: // RGBA8
colmat[0] = colmat[5] = colmat[10] = colmat[15] = 1.0f;
cbufid = 29;
if (!efbHasAlpha)
{
ColorMask[3] = 0.0f;
fConstAdd[3] = 1.0f;
cbufid = 30;
}
break;
default:
ERROR_LOG(VIDEO, "Unknown copy color format: 0x%x", dstFormat);
colmat[0] = colmat[5] = colmat[10] = colmat[15] = 1.0f;
cbufid = 31;
break;
}
}
u8* dst = Memory::GetPointer(dstAddr);
if (dst == nullptr)
{
ERROR_LOG(VIDEO, "Trying to copy from EFB to invalid address 0x%8x", dstAddr);
return;
}
const unsigned int tex_w = scaleByHalf ? srcRect.GetWidth() / 2 : srcRect.GetWidth();
const unsigned int tex_h = scaleByHalf ? srcRect.GetHeight() / 2 : srcRect.GetHeight();
unsigned int scaled_tex_w = g_ActiveConfig.bCopyEFBScaled ? Renderer::EFBToScaledX(tex_w) : tex_w;
unsigned int scaled_tex_h = g_ActiveConfig.bCopyEFBScaled ? Renderer::EFBToScaledY(tex_h) : tex_h;
// remove all texture cache entries at dstAddr
{
std::pair<TexCache::iterator, TexCache::iterator> iter_range = textures_by_address.equal_range((u64)dstAddr);
TexCache::iterator iter = iter_range.first;
while (iter != iter_range.second)
{
iter = FreeTexture(iter);
}
}
// create the texture
TCacheEntryConfig config;
config.rendertarget = true;
config.width = scaled_tex_w;
config.height = scaled_tex_h;
config.layers = FramebufferManagerBase::GetEFBLayers();
TCacheEntryBase* entry = AllocateTexture(config);
entry->SetGeneralParameters(dstAddr, 0, dstFormat);
entry->SetDimensions(tex_w, tex_h, 1);
entry->frameCount = FRAMECOUNT_INVALID;
entry->SetEfbCopy(dstStride);
entry->is_custom_tex = false;
entry->FromRenderTarget(dst, dstFormat, dstStride, srcFormat, srcRect, isIntensity, scaleByHalf, cbufid, colmat);
u64 hash = entry->CalculateHash();
entry->SetHashes(hash, hash);
// Invalidate all textures that overlap the range of our efb copy.
// Unless our efb copy has a weird stride, then we want avoid invalidating textures which
// we might be able to do a partial texture update on.
if (entry->memory_stride == entry->CacheLinesPerRow() * 32)
{
TexCache::iterator iter = textures_by_address.begin();
while (iter != textures_by_address.end())
{
if (iter->second->OverlapsMemoryRange(dstAddr, entry->size_in_bytes))
iter = FreeTexture(iter);
else
++iter;
}
}
if (g_ActiveConfig.bDumpEFBTarget)
{
static int count = 0;
entry->Save(StringFromFormat("%sefb_frame_%i.png", File::GetUserPath(D_DUMPTEXTURES_IDX).c_str(),
count++), 0);
}
if (g_bRecordFifoData)
{
// Mark the memory behind this efb copy as dynamicly generated for the Fifo log
u32 address = dstAddr;
for (u32 i = 0; i < entry->NumBlocksY(); i++)
{
FifoRecorder::GetInstance().UseMemory(address, entry->CacheLinesPerRow() * 32, MemoryUpdate::TEXTURE_MAP, true);
address += entry->memory_stride;
}
}
textures_by_address.emplace((u64)dstAddr, entry);
}
void display (void) {
glClearColor (0.0,0.0,0.0,1.0); //clear the screen to black
glClear (GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT); //clear the color buffer and the depth buffer
glMatrixMode( GL_MODELVIEW );
glColor4f(1.0f,0.0f,0.0f,1.0f);
glEnable(GL_SCISSOR_TEST);
glMatrixMode (GL_PROJECTION); //set the matrix to projection
// Draw the primary view
glViewport (0, 0, (GLsizei)screen_width, (GLsizei)screen_height); //set the viewport to the current window specifications
glScissor(0, 0, (GLsizei)screen_width, (GLsizei)screen_height);
glLoadIdentity ();
if (lighting) {
GLfloat AmbientLight[] = {0.1, 0.1, 0.2};
glLightfv (GL_LIGHT0, GL_AMBIENT, AmbientLight);
GLfloat DiffuseLight[] = {1, 1, 1};
glLightfv (GL_LIGHT1, GL_DIFFUSE, DiffuseLight);
GLfloat LightPosition[] = {xpos, ypos, zpos, 1};
glLightfv(GL_LIGHT1, GL_POSITION, LightPosition);
}
gluPerspective (60, (GLfloat)screen_width / (GLfloat)screen_height, 1.0, 100.0);
gluLookAt (0.0, 0.0, 5.0, 0.0, 0.0, 0.0, 0.0, 1.0, 0.0); //camera position, x,y,z, looking at x,y,z, Up Positions of the camera
camera();
glPushMatrix();
if (lighting) {
texture1 = LoadTexture( "texture.raw", 256, 256 );
texture2 = LoadTexture( "/dev/urandom", 256, 256 );
texture3 = LoadTexture( "water.raw", 500, 375 );
texture4 = LoadTexture( "bubbles.raw", 200, 200 );
glEnable( GL_TEXTURE_2D ); //enable 2D texturing
glEnable(GL_TEXTURE_GEN_S); //enable texture coordinate generation
glEnable(GL_TEXTURE_GEN_T);
if (fog) {
GLfloat fogColor[4]= {0.5f, 1.0f, 0.5f, 1}; // Fog Color
glFogi(GL_FOG_MODE, GL_EXP); // Fog Mode
glFogfv(GL_FOG_COLOR, fogColor); // Set Fog Color
glFogf(GL_FOG_DENSITY, 1.0f); // How Dense Will The Fog Be
glHint(GL_FOG_HINT, GL_DONT_CARE); // Fog Hint Value
glFogf(GL_FOG_START, n*space); // Fog Start Depth
glFogf(GL_FOG_END,-n*space); // Fog End Depth
}
if (nurb) {
glPushMatrix();
glRotatef(270,0.0,1.0,0.0);
glTranslated(n*space/2,n*space/2,-n*space);
GLfloat ctlpoints[4][4][3];
GLUnurbsObj *theNurb;
GLfloat knots[8] = {0.0, 0.0, 0.0, 0.0, 1.0, 1.0, 1.0, 1.0};
int u, v;
for (u = 0; u < 4; u++) {
for (v = 0; v < 4; v++) {
ctlpoints[u][v][0] = 2.0*((GLfloat)u - 1.5);
ctlpoints[u][v][1] = 2.0*((GLfloat)v - 1.5);
if ( (u == 1 || u == 2) && (v == 1 || v == 2))
ctlpoints[u][v][2] = 3.0;
else
ctlpoints[u][v][2] = -3.0;
}
}
theNurb = gluNewNurbsRenderer();
gluNurbsProperty(theNurb, GLU_SAMPLING_TOLERANCE, 25.0);
gluNurbsProperty(theNurb, GLU_DISPLAY_MODE, GLU_FILL);
gluBeginSurface(theNurb);
gluNurbsSurface(theNurb,
8, knots, 8, knots,
4 * 3, 3, &ctlpoints[0][0][0],
4, 4, GL_MAP2_VERTEX_3);
gluEndSurface(theNurb);
glPopMatrix();
}
}
cube(); //call the cube drawing function
glPopMatrix();
if (lighting) {
FreeTexture( texture1 );
FreeTexture( texture2 );
FreeTexture( texture3 );
FreeTexture( texture4 );
}
glPushMatrix();
glTranslated(space*((n/2)+1),space*(n/2),space*(n/2));
glutWireCube(space*n);
glPopMatrix();
// Draw the secondary view
glViewport (3*(screen_width/4), 3*(screen_height/4), screen_width/4, screen_width/4); //set the viewport to the current window specifications
glScissor(3*(screen_width/4), 3*(screen_height/4), screen_width/4, screen_width/4);
glLoadIdentity();
glOrtho(-1, 13, -1, 13, -1, 13);
glRotatef(90,0.0,1.0,0.0);
cube();
glDisable(GL_SCISSOR_TEST);
glutSwapBuffers(); //swap the buffers
}
