raylib/src/textures.c

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/**********************************************************************************************
*
* raylib.textures
*
* Basic functions to load and draw Textures (2d)
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*
* Uses external lib:
* stb_image - Multiple formats image loading (JPEG, PNG, BMP, TGA, PSD, GIF, PIC)
* NOTE: stb_image has been slightly modified, original library: https://github.com/nothings/stb
*
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* Copyright (c) 2014 Ramon Santamaria (@raysan5)
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*
* This software is provided "as-is", without any express or implied warranty. In no event
* will the authors be held liable for any damages arising from the use of this software.
*
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* Permission is granted to anyone to use this software for any purpose, including commercial
* applications, and to alter it and redistribute it freely, subject to the following restrictions:
*
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* 1. The origin of this software must not be misrepresented; you must not claim that you
* wrote the original software. If you use this software in a product, an acknowledgment
* in the product documentation would be appreciated but is not required.
*
* 2. Altered source versions must be plainly marked as such, and must not be misrepresented
* as being the original software.
*
* 3. This notice may not be removed or altered from any source distribution.
*
**********************************************************************************************/
#include "raylib.h"
#include <stdlib.h> // Declares malloc() and free() for memory management
#include <string.h> // Required for strcmp(), strrchr(), strncmp()
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#include "rlgl.h" // raylib OpenGL abstraction layer to OpenGL 1.1, 3.3 or ES2
// Required: rlglLoadTexture() rlDeleteTextures(),
// rlglGenerateMipmaps(), some funcs for DrawTexturePro()
#include "utils.h" // rRES data decompression utility function
// NOTE: Includes Android fopen function map
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#define STB_IMAGE_IMPLEMENTATION
#include "stb_image.h" // Used to read image data (multiple formats support)
#define STB_IMAGE_RESIZE_IMPLEMENTATION
#include "stb_image_resize.h"
//----------------------------------------------------------------------------------
// Defines and Macros
//----------------------------------------------------------------------------------
// Nop...
//----------------------------------------------------------------------------------
// Types and Structures Definition
//----------------------------------------------------------------------------------
// ...
//----------------------------------------------------------------------------------
// Global Variables Definition
//----------------------------------------------------------------------------------
// It's lonely here...
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//----------------------------------------------------------------------------------
// Other Modules Functions Declaration (required by text)
//----------------------------------------------------------------------------------
// ...
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//----------------------------------------------------------------------------------
// Module specific Functions Declaration
//----------------------------------------------------------------------------------
static Image LoadDDS(const char *fileName); // Load DDS file
static Image LoadPKM(const char *fileName); // Load PKM file
static Image LoadKTX(const char *fileName); // Load KTX file
static Image LoadPVR(const char *fileName); // Load PVR file
static Image LoadASTC(const char *fileName); // Load ASTC file
//----------------------------------------------------------------------------------
// Module Functions Definition
//----------------------------------------------------------------------------------
// Load an image into CPU memory (RAM)
Image LoadImage(const char *fileName)
{
Image image;
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// Initialize image default values
image.data = NULL;
image.width = 0;
image.height = 0;
image.mipmaps = 0;
image.format = 0;
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if ((strcmp(GetExtension(fileName),"png") == 0) ||
(strcmp(GetExtension(fileName),"bmp") == 0) ||
(strcmp(GetExtension(fileName),"tga") == 0) ||
(strcmp(GetExtension(fileName),"jpg") == 0) ||
(strcmp(GetExtension(fileName),"gif") == 0) ||
(strcmp(GetExtension(fileName),"psd") == 0) ||
(strcmp(GetExtension(fileName),"pic") == 0))
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{
int imgWidth = 0;
int imgHeight = 0;
int imgBpp = 0;
// NOTE: Using stb_image to load images (Supports: BMP, TGA, PNG, JPG, ...)
image.data = stbi_load(fileName, &imgWidth, &imgHeight, &imgBpp, 0);
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image.width = imgWidth;
image.height = imgHeight;
image.mipmaps = 1;
if (imgBpp == 1) image.format = UNCOMPRESSED_GRAYSCALE;
else if (imgBpp == 2) image.format = UNCOMPRESSED_GRAY_ALPHA;
else if (imgBpp == 3) image.format = UNCOMPRESSED_R8G8B8;
else if (imgBpp == 4) image.format = UNCOMPRESSED_R8G8B8A8;
}
else if (strcmp(GetExtension(fileName),"dds") == 0) image = LoadDDS(fileName);
else if (strcmp(GetExtension(fileName),"pkm") == 0) image = LoadPKM(fileName);
else if (strcmp(GetExtension(fileName),"ktx") == 0) image = LoadKTX(fileName);
else if (strcmp(GetExtension(fileName),"pvr") == 0) image = LoadPVR(fileName);
else if (strcmp(GetExtension(fileName),"astc") == 0) image = LoadASTC(fileName);
if (image.data != NULL)
{
TraceLog(INFO, "[%s] Image loaded successfully (%ix%i)", fileName, image.width, image.height);
}
else TraceLog(WARNING, "[%s] Image could not be loaded, file not recognized", fileName);
return image;
}
// Load image data from Color array data (RGBA - 32bit)
Image LoadImageEx(Color *pixels, int width, int height)
{
Image image;
image.data = NULL;
image.width = width;
image.height = height;
image.mipmaps = 1;
image.format = UNCOMPRESSED_R8G8B8A8;
int k = 0;
image.data = (unsigned char *)malloc(image.width*image.height*4*sizeof(unsigned char));
for (int i = 0; i < image.width*image.height*4; i += 4)
{
((unsigned char *)image.data)[i] = pixels[k].r;
((unsigned char *)image.data)[i + 1] = pixels[k].g;
((unsigned char *)image.data)[i + 2] = pixels[k].b;
((unsigned char *)image.data)[i + 3] = pixels[k].a;
k++;
}
return image;
}
// Load an image from RAW file
Image LoadImageRaw(const char *fileName, int width, int height, int format, int headerSize)
{
Image image;
image.data = NULL;
image.width = 0;
image.height = 0;
image.mipmaps = 0;
image.format = 0;
FILE *rawFile = fopen(fileName, "rb");
if (rawFile == NULL)
{
TraceLog(WARNING, "[%s] RAW image file could not be opened", fileName);
}
else
{
if (headerSize > 0) fseek(rawFile, headerSize, SEEK_SET);
unsigned int size = width*height;
switch (format)
{
case UNCOMPRESSED_GRAYSCALE: image.data = (unsigned char *)malloc(size); break; // 8 bit per pixel (no alpha)
case UNCOMPRESSED_GRAY_ALPHA: image.data = (unsigned char *)malloc(size*2); size *= 2; break; // 16 bpp (2 channels)
case UNCOMPRESSED_R5G6B5: image.data = (unsigned short *)malloc(size); break; // 16 bpp
case UNCOMPRESSED_R8G8B8: image.data = (unsigned char *)malloc(size*3); size *= 3; break; // 24 bpp
case UNCOMPRESSED_R5G5B5A1: image.data = (unsigned short *)malloc(size); break; // 16 bpp (1 bit alpha)
case UNCOMPRESSED_R4G4B4A4: image.data = (unsigned short *)malloc(size); break; // 16 bpp (4 bit alpha)
case UNCOMPRESSED_R8G8B8A8: image.data = (unsigned char *)malloc(size*4); size *= 4; break; // 32 bpp
default: TraceLog(WARNING, "Image format not suported"); break;
}
fread(image.data, size, 1, rawFile);
// TODO: Check if data have been read
image.width = width;
image.height = height;
image.mipmaps = 0;
image.format = format;
fclose(rawFile);
}
return image;
}
// Load an image from rRES file (raylib Resource)
// TODO: Review function to support multiple color modes
Image LoadImageFromRES(const char *rresName, int resId)
{
Image image;
bool found = false;
char id[4]; // rRES file identifier
unsigned char version; // rRES file version and subversion
char useless; // rRES header reserved data
short numRes;
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ResInfoHeader infoHeader;
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FILE *rresFile = fopen(rresName, "rb");
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if (rresFile == NULL)
{
TraceLog(WARNING, "[%s] rRES raylib resource file could not be opened", rresName);
}
else
{
// Read rres file (basic file check - id)
fread(&id[0], sizeof(char), 1, rresFile);
fread(&id[1], sizeof(char), 1, rresFile);
fread(&id[2], sizeof(char), 1, rresFile);
fread(&id[3], sizeof(char), 1, rresFile);
fread(&version, sizeof(char), 1, rresFile);
fread(&useless, sizeof(char), 1, rresFile);
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if ((id[0] != 'r') && (id[1] != 'R') && (id[2] != 'E') &&(id[3] != 'S'))
{
TraceLog(WARNING, "[%s] This is not a valid raylib resource file", rresName);
}
else
{
// Read number of resources embedded
fread(&numRes, sizeof(short), 1, rresFile);
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for (int i = 0; i < numRes; i++)
{
fread(&infoHeader, sizeof(ResInfoHeader), 1, rresFile);
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if (infoHeader.id == resId)
{
found = true;
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// Check data is of valid IMAGE type
if (infoHeader.type == 0) // IMAGE data type
{
// TODO: Check data compression type
// NOTE: We suppose compression type 2 (DEFLATE - default)
short imgWidth, imgHeight;
char colorFormat, mipmaps;
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fread(&imgWidth, sizeof(short), 1, rresFile); // Image width
fread(&imgHeight, sizeof(short), 1, rresFile); // Image height
fread(&colorFormat, 1, 1, rresFile); // Image data color format (default: RGBA 32 bit)
fread(&mipmaps, 1, 1, rresFile); // Mipmap images included (default: 0)
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image.width = (int)imgWidth;
image.height = (int)imgHeight;
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unsigned char *compData = malloc(infoHeader.size);
fread(compData, infoHeader.size, 1, rresFile);
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unsigned char *imgData = DecompressData(compData, infoHeader.size, infoHeader.srcSize);
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// TODO: Review color mode
//image.data = (unsigned char *)malloc(sizeof(unsigned char)*imgWidth*imgHeight*4);
image.data = imgData;
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//free(imgData);
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free(compData);
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TraceLog(INFO, "[%s] Image loaded successfully from resource, size: %ix%i", rresName, image.width, image.height);
}
else
{
TraceLog(WARNING, "[%s] Required resource do not seem to be a valid IMAGE resource", rresName);
}
}
else
{
// Depending on type, skip the right amount of parameters
switch (infoHeader.type)
{
case 0: fseek(rresFile, 6, SEEK_CUR); break; // IMAGE: Jump 6 bytes of parameters
case 1: fseek(rresFile, 6, SEEK_CUR); break; // SOUND: Jump 6 bytes of parameters
case 2: fseek(rresFile, 5, SEEK_CUR); break; // MODEL: Jump 5 bytes of parameters (TODO: Review)
case 3: break; // TEXT: No parameters
case 4: break; // RAW: No parameters
default: break;
}
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// Jump DATA to read next infoHeader
fseek(rresFile, infoHeader.size, SEEK_CUR);
}
}
}
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fclose(rresFile);
}
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if (!found) TraceLog(WARNING, "[%s] Required resource id [%i] could not be found in the raylib resource file", rresName, resId);
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return image;
}
// Load an image as texture into GPU memory
Texture2D LoadTexture(const char *fileName)
{
Texture2D texture;
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Image image = LoadImage(fileName);
if (image.data != NULL)
{
texture = LoadTextureFromImage(image);
UnloadImage(image);
}
else
{
TraceLog(WARNING, "Texture could not be created");
texture.id = 0;
}
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return texture;
}
// Load a texture from raw data into GPU memory
Texture2D LoadTextureEx(void *data, int width, int height, int textureFormat)
{
Texture2D texture;
texture.width = width;
texture.height = height;
texture.mipmaps = 1;
texture.format = textureFormat;
texture.id = rlglLoadTexture(data, width, height, textureFormat, 1);
return texture;
}
// Load an image as texture from rRES file (raylib Resource)
Texture2D LoadTextureFromRES(const char *rresName, int resId)
{
Texture2D texture;
Image image = LoadImageFromRES(rresName, resId);
texture = LoadTextureFromImage(image);
UnloadImage(image);
return texture;
}
// Load a texture from image data
// NOTE: image is not unloaded, it must be done manually
Texture2D LoadTextureFromImage(Image image)
{
Texture2D texture;
// Init texture to default values
texture.id = 0;
texture.width = 0;
texture.height = 0;
texture.mipmaps = 0;
texture.format = 0;
texture.id = rlglLoadTexture(image.data, image.width, image.height, image.format, image.mipmaps);
texture.width = image.width;
texture.height = image.height;
texture.mipmaps = image.mipmaps;
texture.format = image.format;
return texture;
}
// Unload image from CPU memory (RAM)
void UnloadImage(Image image)
{
free(image.data);
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// NOTE: It becomes anoying every time a texture is loaded
//TraceLog(INFO, "Unloaded image data");
}
// Unload texture from GPU memory
void UnloadTexture(Texture2D texture)
{
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if (texture.id != 0)
{
rlDeleteTextures(texture.id);
TraceLog(INFO, "[TEX ID %i] Unloaded texture data from VRAM (GPU)", texture.id);
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}
}
// Get pixel data from image in the form of Color struct array
Color *GetImageData(Image image)
{
Color *pixels = (Color *)malloc(image.width*image.height*sizeof(Color));
int k = 0;
for (int i = 0; i < image.width*image.height; i++)
{
switch (image.format)
{
case UNCOMPRESSED_GRAYSCALE:
{
pixels[i].r = ((unsigned char *)image.data)[k];
pixels[i].g = ((unsigned char *)image.data)[k];
pixels[i].b = ((unsigned char *)image.data)[k];
pixels[i].a = 255;
k++;
} break;
case UNCOMPRESSED_GRAY_ALPHA:
{
pixels[i].r = ((unsigned char *)image.data)[k];
pixels[i].g = ((unsigned char *)image.data)[k];
pixels[i].b = ((unsigned char *)image.data)[k];
pixels[i].a = ((unsigned char *)image.data)[k + 1];
k += 2;
} break;
case UNCOMPRESSED_R5G5B5A1:
{
unsigned short pixel = ((unsigned short *)image.data)[k];
pixels[i].r = (unsigned char)((float)((pixel & 0b1111100000000000) >> 11)*(255/31));
pixels[i].g = (unsigned char)((float)((pixel & 0b0000011111000000) >> 6)*(255/31));
pixels[i].b = (unsigned char)((float)((pixel & 0b0000000000111110) >> 1)*(255/31));
pixels[i].a = (unsigned char)((pixel & 0b0000000000000001)*255);
k++;
} break;
case UNCOMPRESSED_R5G6B5:
{
unsigned short pixel = ((unsigned short *)image.data)[k];
pixels[i].r = (unsigned char)((float)((pixel & 0b1111100000000000) >> 11)*(255/31));
pixels[i].g = (unsigned char)((float)((pixel & 0b0000011111100000) >> 5)*(255/63));
pixels[i].b = (unsigned char)((float)(pixel & 0b0000000000011111)*(255/31));
pixels[i].a = 255;
k++;
} break;
case UNCOMPRESSED_R4G4B4A4:
{
unsigned short pixel = ((unsigned short *)image.data)[k];
pixels[i].r = (unsigned char)((float)((pixel & 0b1111000000000000) >> 12)*(255/15));
pixels[i].g = (unsigned char)((float)((pixel & 0b0000111100000000) >> 8)*(255/15));
pixels[i].b = (unsigned char)((float)((pixel & 0b0000000011110000) >> 4)*(255/15));
pixels[i].a = (unsigned char)((float)(pixel & 0b0000000000001111)*(255/15));
k++;
} break;
case UNCOMPRESSED_R8G8B8A8:
{
pixels[i].r = ((unsigned char *)image.data)[k];
pixels[i].g = ((unsigned char *)image.data)[k + 1];
pixels[i].b = ((unsigned char *)image.data)[k + 2];
pixels[i].a = ((unsigned char *)image.data)[k + 3];
k += 4;
} break;
case UNCOMPRESSED_R8G8B8:
{
pixels[i].r = (unsigned char)((unsigned char *)image.data)[k];
pixels[i].g = (unsigned char)((unsigned char *)image.data)[k + 1];
pixels[i].b = (unsigned char)((unsigned char *)image.data)[k + 2];
pixels[i].a = 255;
k += 3;
} break;
default: TraceLog(WARNING, "Format not supported for pixel data retrieval"); break;
}
}
return pixels;
}
// Get pixel data from GPU texture and return an Image
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// NOTE: Compressed texture formats not supported
Image GetTextureData(Texture2D texture)
{
Image image;
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image.data = NULL;
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if (texture.format < 8)
{
image.data = rlglReadTexturePixels(texture);
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if (image.data != NULL)
{
image.width = texture.width;
image.height = texture.height;
image.mipmaps = 1;
#if defined(GRAPHICS_API_OPENGL_ES2)
// NOTE: Data retrieved on OpenGL ES 2.0 comes as RGB (from framebuffer)
image.format = UNCOMPRESSED_R8G8B8A8;
#else
image.format = texture.format;
#endif
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TraceLog(INFO, "Texture pixel data obtained successfully");
}
else TraceLog(WARNING, "Texture pixel data could not be obtained");
}
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else TraceLog(WARNING, "Compressed texture data could not be obtained");
return image;
}
// Convert image data to desired format
void ImageFormat(Image *image, int newFormat)
{
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if (image->format != newFormat)
{
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if ((image->format < 8) && (newFormat < 8))
{
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Color *pixels = GetImageData(*image);
free(image->data);
image->format = newFormat;
int k = 0;
switch (image->format)
{
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case UNCOMPRESSED_GRAYSCALE:
{
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image->data = (unsigned char *)malloc(image->width*image->height*sizeof(unsigned char));
for (int i = 0; i < image->width*image->height; i++)
{
((unsigned char *)image->data)[i] = (unsigned char)((float)pixels[i].r*0.299f + (float)pixels[i].g*0.587f + (float)pixels[i].b*0.114f);
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}
} break;
case UNCOMPRESSED_GRAY_ALPHA:
{
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image->data = (unsigned char *)malloc(image->width*image->height*2*sizeof(unsigned char));
for (int i = 0; i < image->width*image->height*2; i += 2)
{
((unsigned char *)image->data)[i] = (unsigned char)((float)pixels[k].r*0.299f + (float)pixels[k].g*0.587f + (float)pixels[k].b*0.114f);
((unsigned char *)image->data)[i + 1] = pixels[k].a;
k++;
}
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} break;
case UNCOMPRESSED_R5G6B5:
{
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image->data = (unsigned short *)malloc(image->width*image->height*sizeof(unsigned short));
unsigned char r = 0;
unsigned char g = 0;
unsigned char b = 0;
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for (int i = 0; i < image->width*image->height; i++)
{
r = (unsigned char)(round((float)pixels[k].r*31/255));
g = (unsigned char)(round((float)pixels[k].g*63/255));
b = (unsigned char)(round((float)pixels[k].b*31/255));
((unsigned short *)image->data)[i] = (unsigned short)r << 11 | (unsigned short)g << 5 | (unsigned short)b;
}
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} break;
case UNCOMPRESSED_R8G8B8:
{
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image->data = (unsigned char *)malloc(image->width*image->height*3*sizeof(unsigned char));
for (int i = 0; i < image->width*image->height*3; i += 3)
{
((unsigned char *)image->data)[i] = pixels[k].r;
((unsigned char *)image->data)[i + 1] = pixels[k].g;
((unsigned char *)image->data)[i + 2] = pixels[k].b;
k++;
}
} break;
case UNCOMPRESSED_R5G5B5A1:
{
#define ALPHA_THRESHOLD 50
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image->data = (unsigned short *)malloc(image->width*image->height*sizeof(unsigned short));
unsigned char r = 0;
unsigned char g = 0;
unsigned char b = 0;
unsigned char a = 0;
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for (int i = 0; i < image->width*image->height; i++)
{
r = (unsigned char)(round((float)pixels[i].r*31/255));
g = (unsigned char)(round((float)pixels[i].g*31/255));
b = (unsigned char)(round((float)pixels[i].b*31/255));
a = (pixels[i].a > ALPHA_THRESHOLD) ? 1 : 0;
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((unsigned short *)image->data)[i] = (unsigned short)r << 11 | (unsigned short)g << 6 | (unsigned short)b << 1 | (unsigned short)a;
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}
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} break;
case UNCOMPRESSED_R4G4B4A4:
{
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image->data = (unsigned short *)malloc(image->width*image->height*sizeof(unsigned short));
unsigned char r = 0;
unsigned char g = 0;
unsigned char b = 0;
unsigned char a = 0;
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for (int i = 0; i < image->width*image->height; i++)
{
r = (unsigned char)(round((float)pixels[i].r*15/255));
g = (unsigned char)(round((float)pixels[i].g*15/255));
b = (unsigned char)(round((float)pixels[i].b*15/255));
a = (unsigned char)(round((float)pixels[i].a*15/255));
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((unsigned short *)image->data)[i] = (unsigned short)r << 12 | (unsigned short)g << 8| (unsigned short)b << 4| (unsigned short)a;
}
} break;
case UNCOMPRESSED_R8G8B8A8:
{
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image->data = (unsigned char *)malloc(image->width*image->height*4*sizeof(unsigned char));
for (int i = 0; i < image->width*image->height*4; i += 4)
{
((unsigned char *)image->data)[i] = pixels[k].r;
((unsigned char *)image->data)[i + 1] = pixels[k].g;
((unsigned char *)image->data)[i + 2] = pixels[k].b;
((unsigned char *)image->data)[i + 3] = pixels[k].a;
k++;
}
} break;
default: break;
}
free(pixels);
}
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else TraceLog(WARNING, "Image data format is compressed, can not be converted");
}
}
// Dither image data to 16bpp or lower (Floyd-Steinberg dithering)
// NOTE: In case selected bpp do not represent an known 16bit format,
// dithered data is stored in the LSB part of the unsigned short
void ImageDither(Image *image, int rBpp, int gBpp, int bBpp, int aBpp)
{
if (image->format >= 8)
{
TraceLog(WARNING, "Compressed data formats can not be dithered");
return;
}
if ((rBpp+gBpp+bBpp+aBpp) > 16)
{
TraceLog(WARNING, "Unsupported dithering bpps (%ibpp), only 16bpp or lower modes supported", (rBpp+gBpp+bBpp+aBpp));
}
else
{
Color *pixels = GetImageData(*image);
free(image->data); // free old image data
if ((image->format != UNCOMPRESSED_R8G8B8) && (image->format != UNCOMPRESSED_R8G8B8A8))
{
TraceLog(WARNING, "Image format is already 16bpp or lower, dithering could have no effect");
}
// Define new image format, check if desired bpp match internal known format
if ((rBpp == 5) && (gBpp == 6) && (bBpp == 5) && (aBpp == 0)) image->format = UNCOMPRESSED_R5G6B5;
else if ((rBpp == 5) && (gBpp == 5) && (bBpp == 5) && (aBpp == 1)) image->format = UNCOMPRESSED_R5G5B5A1;
else if ((rBpp == 4) && (gBpp == 4) && (bBpp == 4) && (aBpp == 4)) image->format = UNCOMPRESSED_R4G4B4A4;
else
{
image->format = 0;
TraceLog(WARNING, "Unsupported dithered OpenGL internal format: %ibpp (R%iG%iB%iA%i)", (rBpp+gBpp+bBpp+aBpp), rBpp, gBpp, bBpp, aBpp);
}
// NOTE: We will store the dithered data as unsigned short (16bpp)
image->data = (unsigned short *)malloc(image->width*image->height*sizeof(unsigned short));
Color oldpixel = WHITE;
Color newpixel = WHITE;
int error_r, error_g, error_b;
unsigned short pixel_r, pixel_g, pixel_b, pixel_a; // Used for 16bit pixel composition
#define MIN(a,b) (((a)<(b))?(a):(b))
for (int y = 0; y < image->height; y++)
{
for (int x = 0; x < image->width; x++)
{
oldpixel = pixels[y*image->width + x];
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// NOTE: New pixel obtained by bits truncate, it would be better to round values (check ImageFormat())
newpixel.r = oldpixel.r>>(8 - rBpp); // R bits
newpixel.g = oldpixel.g>>(8 - gBpp); // G bits
newpixel.b = oldpixel.b>>(8 - bBpp); // B bits
newpixel.a = oldpixel.a>>(8 - aBpp); // A bits (not used on dithering)
// NOTE: Error must be computed between new and old pixel but using same number of bits!
// We want to know how much color precision we have lost...
error_r = (int)oldpixel.r - (int)(newpixel.r<<(8 - rBpp));
error_g = (int)oldpixel.g - (int)(newpixel.g<<(8 - gBpp));
error_b = (int)oldpixel.b - (int)(newpixel.b<<(8 - bBpp));
pixels[y*image->width + x] = newpixel;
// NOTE: Some cases are out of the array and should be ignored
if (x < (image->width - 1))
{
pixels[y*image->width + x+1].r = MIN((int)pixels[y*image->width + x+1].r + (int)((float)error_r*7.0f/16), 0xff);
pixels[y*image->width + x+1].g = MIN((int)pixels[y*image->width + x+1].g + (int)((float)error_g*7.0f/16), 0xff);
pixels[y*image->width + x+1].b = MIN((int)pixels[y*image->width + x+1].b + (int)((float)error_b*7.0f/16), 0xff);
}
if ((x > 0) && (y < (image->height - 1)))
{
pixels[(y+1)*image->width + x-1].r = MIN((int)pixels[(y+1)*image->width + x-1].r + (int)((float)error_r*3.0f/16), 0xff);
pixels[(y+1)*image->width + x-1].g = MIN((int)pixels[(y+1)*image->width + x-1].g + (int)((float)error_g*3.0f/16), 0xff);
pixels[(y+1)*image->width + x-1].b = MIN((int)pixels[(y+1)*image->width + x-1].b + (int)((float)error_b*3.0f/16), 0xff);
}
if (y < (image->height - 1))
{
pixels[(y+1)*image->width + x].r = MIN((int)pixels[(y+1)*image->width + x].r + (int)((float)error_r*5.0f/16), 0xff);
pixels[(y+1)*image->width + x].g = MIN((int)pixels[(y+1)*image->width + x].g + (int)((float)error_g*5.0f/16), 0xff);
pixels[(y+1)*image->width + x].b = MIN((int)pixels[(y+1)*image->width + x].b + (int)((float)error_b*5.0f/16), 0xff);
}
if ((x < (image->width - 1)) && (y < (image->height - 1)))
{
pixels[(y+1)*image->width + x+1].r = MIN((int)pixels[(y+1)*image->width + x+1].r + (int)((float)error_r*1.0f/16), 0xff);
pixels[(y+1)*image->width + x+1].g = MIN((int)pixels[(y+1)*image->width + x+1].g + (int)((float)error_g*1.0f/16), 0xff);
pixels[(y+1)*image->width + x+1].b = MIN((int)pixels[(y+1)*image->width + x+1].b + (int)((float)error_b*1.0f/16), 0xff);
}
pixel_r = (unsigned short)newpixel.r;
pixel_g = (unsigned short)newpixel.g;
pixel_b = (unsigned short)newpixel.b;
pixel_a = (unsigned short)newpixel.a;
((unsigned short *)image->data)[y*image->width + x] = (pixel_r<<(gBpp + bBpp + aBpp)) | (pixel_g<<(bBpp + aBpp)) | (pixel_b<<aBpp) | pixel_a;
}
}
free(pixels);
}
}
// Convert image to POT (power-of-two)
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// NOTE: It could be useful on OpenGL ES 2.0 (RPI, HTML5)
void ImageToPOT(Image *image, Color fillColor)
{
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Color *pixels = GetImageData(*image); // Get pixels data
// Just add the required amount of pixels at the right and bottom sides of image...
int potWidth = GetNextPOT(image->width);
int potHeight = GetNextPOT(image->height);
// Check if POT texture generation is required (if texture is not already POT)
if ((potWidth != image->width) || (potHeight != image->height))
{
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Color *pixelsPOT = NULL;
// Generate POT array from NPOT data
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pixelsPOT = (Color *)malloc(potWidth*potHeight*sizeof(Color));
for (int j = 0; j < potHeight; j++)
{
for (int i = 0; i < potWidth; i++)
{
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if ((j < image->height) && (i < image->width)) pixelsPOT[j*potWidth + i] = pixels[j*image->width + i];
else pixelsPOT[j*potWidth + i] = fillColor;
}
}
TraceLog(WARNING, "Image converted to POT: (%ix%i) -> (%ix%i)", image->width, image->height, potWidth, potHeight);
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free(pixels); // Free pixels data
free(image->data); // Free old image data
int format = image->format; // Store image data format to reconvert later
// TODO: Image width and height changes... do we want to store new values or keep the old ones?
// NOTE: Issues when using image.width and image.height for sprite animations...
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*image = LoadImageEx(pixelsPOT, potWidth, potHeight);
free(pixelsPOT); // Free POT pixels data
ImageFormat(image, format); // Reconvert image to previous format
}
}
// Copy an image to a new image
Image ImageCopy(Image image)
{
Image newImage;
int size = image.width*image.height;
switch (image.format)
{
case UNCOMPRESSED_GRAYSCALE: newImage.data = (unsigned char *)malloc(size); break; // 8 bit per pixel (no alpha)
case UNCOMPRESSED_GRAY_ALPHA: newImage.data = (unsigned char *)malloc(size*2); size *= 2; break; // 16 bpp (2 channels)
case UNCOMPRESSED_R5G6B5: newImage.data = (unsigned short *)malloc(size); size *= 2; break; // 16 bpp
case UNCOMPRESSED_R8G8B8: newImage.data = (unsigned char *)malloc(size*3); size *= 3; break; // 24 bpp
case UNCOMPRESSED_R5G5B5A1: newImage.data = (unsigned short *)malloc(size); size *= 2; break; // 16 bpp (1 bit alpha)
case UNCOMPRESSED_R4G4B4A4: newImage.data = (unsigned short *)malloc(size); size *= 2; break; // 16 bpp (4 bit alpha)
case UNCOMPRESSED_R8G8B8A8: newImage.data = (unsigned char *)malloc(size*4); size *= 4; break; // 32 bpp
default: TraceLog(WARNING, "Image format not suported for copy"); break;
}
if (newImage.data != NULL)
{
// NOTE: Size must be provided in bytes
memcpy(newImage.data, image.data, size);
newImage.width = image.width;
newImage.height = image.height;
newImage.mipmaps = image.mipmaps;
newImage.format = image.format;
}
return newImage;
}
// Crop an image to area defined by a rectangle
// NOTE: Security checks are performed in case rectangle goes out of bounds
void ImageCrop(Image *image, Rectangle crop)
{
// Security checks to make sure cropping rectangle is inside margins
if ((crop.x + crop.width) > image->width)
{
crop.width = image->width - crop.x;
TraceLog(WARNING, "Crop rectangle width out of bounds, rescaled crop width: %i", crop.width);
}
if ((crop.y + crop.height) > image->height)
{
crop.height = image->height - crop.y;
TraceLog(WARNING, "Crop rectangle height out of bounds, rescaled crop height: %i", crop.height);
}
if ((crop.x < image->width) && (crop.y < image->height))
{
// Start the cropping process
Color *pixels = GetImageData(*image); // Get data as Color pixels array
Color *cropPixels = (Color *)malloc(crop.width*crop.height*sizeof(Color));
for (int j = crop.y; j < (crop.y + crop.height); j++)
{
for (int i = crop.x; i < (crop.x + crop.width); i++)
{
cropPixels[(j - crop.y)*crop.width + (i - crop.x)] = pixels[j*image->width + i];
}
}
free(pixels);
int format = image->format;
UnloadImage(*image);
*image = LoadImageEx(cropPixels, crop.width, crop.height);
free(cropPixels);
// Reformat 32bit RGBA image to original format
ImageFormat(image, format);
}
else
{
TraceLog(WARNING, "Image can not be cropped, crop rectangle out of bounds");
}
}
// Resize and image to new size
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// NOTE: Uses stb default scaling filters (both bicubic):
// STBIR_DEFAULT_FILTER_UPSAMPLE STBIR_FILTER_CATMULLROM
// STBIR_DEFAULT_FILTER_DOWNSAMPLE STBIR_FILTER_MITCHELL (high-quality Catmull-Rom)
void ImageResize(Image *image, int newWidth, int newHeight)
{
// Get data as Color pixels array to work with it
Color *pixels = GetImageData(*image);
Color *output = (Color *)malloc(newWidth*newHeight*sizeof(Color));
// NOTE: Color data is casted to (unsigned char *), there shouldn't been any problem...
stbir_resize_uint8((unsigned char *)pixels, image->width, image->height, 0, (unsigned char *)output, newWidth, newHeight, 0, 4);
int format = image->format;
UnloadImage(*image);
*image = LoadImageEx(output, newWidth, newHeight);
ImageFormat(image, format); // Reformat 32bit RGBA image to original format
free(output);
free(pixels);
}
// Resize and image to new size using Nearest-Neighbor scaling algorithm
void ImageResizeNN(Image *image,int newWidth,int newHeight)
{
Color *pixels = GetImageData(*image);
Color *output = (Color *)malloc(newWidth*newHeight*sizeof(Color));
// EDIT: added +1 to account for an early rounding problem
int x_ratio = (int)((image->width<<16)/newWidth) + 1;
int y_ratio = (int)((image->height<<16)/newHeight) + 1;
int x2, y2;
for (int i = 0; i < newHeight; i++)
{
for (int j = 0; j < newWidth; j++)
{
x2 = ((j*x_ratio) >> 16);
y2 = ((i*y_ratio) >> 16);
output[(i*newWidth) + j] = pixels[(y2*image->width) + x2] ;
}
}
int format = image->format;
UnloadImage(*image);
*image = LoadImageEx(output, newWidth, newHeight);
ImageFormat(image, format); // Reformat 32bit RGBA image to original format
free(output);
free(pixels);
}
// Draw an image (source) within an image (destination)
void ImageDraw(Image *dst, Image src, Rectangle srcRec, Rectangle dstRec)
{
// Security checks to avoid size and rectangle issues (out of bounds)
// Check that srcRec is inside src image
if (srcRec.x < 0) srcRec.x = 0;
if (srcRec.y < 0) srcRec.y = 0;
if ((srcRec.x + srcRec.width) > src.width)
{
srcRec.width = src.width - srcRec.x;
TraceLog(WARNING, "Source rectangle width out of bounds, rescaled width: %i", srcRec.width);
}
if ((srcRec.y + srcRec.height) > src.height)
{
srcRec.height = src.height - srcRec.y;
TraceLog(WARNING, "Source rectangle height out of bounds, rescaled height: %i", srcRec.height);
}
// Check that dstRec is inside dst image
if (dstRec.x < 0) dstRec.x = 0;
if (dstRec.y < 0) dstRec.y = 0;
if ((dstRec.x + dstRec.width) > dst->width)
{
dstRec.width = dst->width - dstRec.x;
TraceLog(WARNING, "Destination rectangle width out of bounds, rescaled width: %i", dstRec.width);
}
if ((dstRec.y + dstRec.height) > dst->height)
{
dstRec.height = dst->height - dstRec.y;
TraceLog(WARNING, "Destination rectangle height out of bounds, rescaled height: %i", dstRec.height);
}
// Get dstination image data as Color pixels array to work with it
Color *dstPixels = GetImageData(*dst);
Image srcCopy = ImageCopy(src); // Make a copy of source image to work with it
ImageCrop(&srcCopy, srcRec); // Crop source image to desired source rectangle
// Scale source image in case destination rec size is different than source rec size
if ((dstRec.width != srcRec.width) || (dstRec.height != srcRec.height))
{
ImageResize(&srcCopy, dstRec.width, dstRec.height);
}
// Get source image data as Color array
Color *srcPixels = GetImageData(srcCopy);
UnloadImage(srcCopy);
// Blit pixels, copy source image into destination
for (int j = dstRec.y; j < (dstRec.y + dstRec.height); j++)
{
for (int i = dstRec.x; i < (dstRec.x + dstRec.width); i++)
{
dstPixels[j*dst->width + i] = srcPixels[(j - dstRec.y)*dstRec.width + (i - dstRec.x)];
}
}
UnloadImage(*dst); // NOTE: Only dst->data is unloaded
*dst = LoadImageEx(dstPixels, dst->width, dst->height);
ImageFormat(dst, dst->format);
free(srcPixels);
free(dstPixels);
}
// Create an image from text (default font)
Image ImageText(const char *text, int fontSize, Color color)
{
int defaultFontSize = 10; // Default Font chars height in pixel
if (fontSize < defaultFontSize) fontSize = defaultFontSize;
int spacing = fontSize / defaultFontSize;
Image imText = ImageTextEx(GetDefaultFont(), text, fontSize, spacing, color);
return imText;
}
// Create an image from text (custom sprite font)
Image ImageTextEx(SpriteFont font, const char *text, int fontSize, int spacing, Color tint)
{
int length = strlen(text);
int posX = 0;
Vector2 imSize = MeasureTextEx(font, text, font.size, spacing);
// NOTE: GetTextureData() not available in OpenGL ES
Image imFont = GetTextureData(font.texture);
ImageFormat(&imFont, UNCOMPRESSED_R8G8B8A8); // Required for color tint
ImageColorTint(&imFont, tint); // Apply color tint to font
Color *fontPixels = GetImageData(imFont);
// Create image to store text
Color *pixels = (Color *)malloc(sizeof(Color)*(int)imSize.x*(int)imSize.y);
for (int i = 0; i < length; i++)
{
Rectangle letterRec = font.charRecs[(int)text[i] - 32];
for (int y = letterRec.y; y < (letterRec.y + letterRec.height); y++)
{
for (int x = posX; x < (posX + letterRec.width); x++)
{
pixels[(y - letterRec.y)*(int)imSize.x + x] = fontPixels[y*font.texture.width + (x - posX + letterRec.x)];
}
}
posX += letterRec.width + spacing;
}
UnloadImage(imFont);
Image imText = LoadImageEx(pixels, (int)imSize.x, (int)imSize.y);
// Scale image depending on text size
if (fontSize > (int)imSize.y)
{
float scaleFactor = (float)fontSize/imSize.y;
TraceLog(INFO, "Scalefactor: %f", scaleFactor);
// Using nearest-neighbor scaling algorithm for default font
if (font.texture.id == GetDefaultFont().texture.id) ImageResizeNN(&imText, (int)(imSize.x*scaleFactor), (int)(imSize.y*scaleFactor));
else ImageResize(&imText, (int)(imSize.x*scaleFactor), (int)(imSize.y*scaleFactor));
}
free(pixels);
free(fontPixels);
return imText;
}
// Draw text (default font) within an image (destination)
void ImageDrawText(Image *dst, Vector2 position, const char *text, int fontSize, Color color)
{
ImageDrawTextEx(dst, position, GetDefaultFont(), text, fontSize, 0, color);
}
// Draw text (custom sprite font) within an image (destination)
void ImageDrawTextEx(Image *dst, Vector2 position, SpriteFont font, const char *text, int fontSize, int spacing, Color color)
{
Image imText = ImageTextEx(font, text, fontSize, spacing, color);
Rectangle srcRec = { 0, 0, imText.width, imText.height };
Rectangle dstRec = { (int)position.x, (int)position.y, imText.width, imText.height };
ImageDraw(dst, imText, srcRec, dstRec);
UnloadImage(imText);
}
// Flip image vertically
void ImageFlipVertical(Image *image)
{
Color *srcPixels = GetImageData(*image);
Color *dstPixels = (Color *)malloc(sizeof(Color)*image->width*image->height);
for (int y = 0; y < image->height; y++)
{
for (int x = 0; x < image->width; x++)
{
dstPixels[y*image->width + x] = srcPixels[(image->height - 1 - y)*image->width + x];
}
}
Image processed = LoadImageEx(dstPixels, image->width, image->height);
ImageFormat(&processed, image->format);
UnloadImage(*image);
free(srcPixels);
free(dstPixels);
image->data = processed.data;
}
// Flip image horizontally
void ImageFlipHorizontal(Image *image)
{
Color *srcPixels = GetImageData(*image);
Color *dstPixels = (Color *)malloc(sizeof(Color)*image->width*image->height);
for (int y = 0; y < image->height; y++)
{
for (int x = 0; x < image->width; x++)
{
dstPixels[y*image->width + x] = srcPixels[y*image->width + (image->width - 1 - x)];
}
}
Image processed = LoadImageEx(dstPixels, image->width, image->height);
ImageFormat(&processed, image->format);
UnloadImage(*image);
free(srcPixels);
free(dstPixels);
image->data = processed.data;
}
// Modify image color: tint
void ImageColorTint(Image *image, Color color)
{
Color *pixels = GetImageData(*image);
float cR = (float)color.r/255;
float cG = (float)color.g/255;
float cB = (float)color.b/255;
float cA = (float)color.a/255;
for (int y = 0; y < image->height; y++)
{
for (int x = 0; x < image->width; x++)
{
unsigned char r = 255*((float)pixels[y*image->width + x].r/255*cR);
unsigned char g = 255*((float)pixels[y*image->width + x].g/255*cG);
unsigned char b = 255*((float)pixels[y*image->width + x].b/255*cB);
unsigned char a = 255*((float)pixels[y*image->width + x].a/255*cA);
pixels[y*image->width + x].r = r;
pixels[y*image->width + x].g = g;
pixels[y*image->width + x].b = b;
pixels[y*image->width + x].a = a;
}
}
Image processed = LoadImageEx(pixels, image->width, image->height);
ImageFormat(&processed, image->format);
UnloadImage(*image);
free(pixels);
image->data = processed.data;
}
// Modify image color: invert
void ImageColorInvert(Image *image)
{
Color *pixels = GetImageData(*image);
for (int y = 0; y < image->height; y++)
{
for (int x = 0; x < image->width; x++)
{
pixels[y*image->width + x].r = 255 - pixels[y*image->width + x].r;
pixels[y*image->width + x].g = 255 - pixels[y*image->width + x].g;
pixels[y*image->width + x].b = 255 - pixels[y*image->width + x].b;
}
}
Image processed = LoadImageEx(pixels, image->width, image->height);
ImageFormat(&processed, image->format);
UnloadImage(*image);
free(pixels);
image->data = processed.data;
}
// Modify image color: grayscale
void ImageColorGrayscale(Image *image)
{
ImageFormat(image, UNCOMPRESSED_GRAYSCALE);
}
// Modify image color: contrast
// NOTE: Contrast values between -100 and 100
void ImageColorContrast(Image *image, float contrast)
{
if (contrast < -100) contrast = -100;
if (contrast > 100) contrast = 100;
contrast = (100.0 + contrast)/100.0;
contrast *= contrast;
Color *pixels = GetImageData(*image);
for (int y = 0; y < image->height; y++)
{
for (int x = 0; x < image->width; x++)
{
float pR = (float)pixels[y*image->width + x].r/255.0;
pR -= 0.5;
pR *= contrast;
pR += 0.5;
pR *= 255;
if (pR < 0) pR = 0;
if (pR > 255) pR = 255;
float pG = (float)pixels[y*image->width + x].g/255.0;
pG -= 0.5;
pG *= contrast;
pG += 0.5;
pG *= 255;
if (pG < 0) pG = 0;
if (pG > 255) pG = 255;
float pB = (float)pixels[y*image->width + x].b/255.0;
pB -= 0.5;
pB *= contrast;
pB += 0.5;
pB *= 255;
if (pB < 0) pB = 0;
if (pB > 255) pB = 255;
pixels[y*image->width + x].r = (unsigned char)pR;
pixels[y*image->width + x].g = (unsigned char)pG;
pixels[y*image->width + x].b = (unsigned char)pB;
}
}
Image processed = LoadImageEx(pixels, image->width, image->height);
ImageFormat(&processed, image->format);
UnloadImage(*image);
free(pixels);
image->data = processed.data;
}
// Modify image color: brightness
// NOTE: Brightness values between -255 and 255
void ImageColorBrightness(Image *image, int brightness)
{
if (brightness < -255) brightness = -255;
if (brightness > 255) brightness = 255;
Color *pixels = GetImageData(*image);
for (int y = 0; y < image->height; y++)
{
for (int x = 0; x < image->width; x++)
{
int cR = pixels[y*image->width + x].r + brightness;
int cG = pixels[y*image->width + x].g + brightness;
int cB = pixels[y*image->width + x].b + brightness;
if (cR < 0) cR = 1;
if (cR > 255) cR = 255;
if (cG < 0) cG = 1;
if (cG > 255) cG = 255;
if (cB < 0) cB = 1;
if (cB > 255) cB = 255;
pixels[y*image->width + x].r = (unsigned char)cR;
pixels[y*image->width + x].g = (unsigned char)cG;
pixels[y*image->width + x].b = (unsigned char)cB;
}
}
Image processed = LoadImageEx(pixels, image->width, image->height);
ImageFormat(&processed, image->format);
UnloadImage(*image);
free(pixels);
image->data = processed.data;
}
// Generate GPU mipmaps for a texture
void GenTextureMipmaps(Texture2D texture)
{
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#if PLATFORM_WEB
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int potWidth = GetNextPOT(texture.width);
int potHeight = GetNextPOT(texture.height);
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// Check if texture is POT
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if ((potWidth != texture.width) || (potHeight != texture.height))
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{
TraceLog(WARNING, "Limited NPOT support, no mipmaps available for NPOT textures");
}
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else rlglGenerateMipmaps(texture);
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#else
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rlglGenerateMipmaps(texture);
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#endif
}
// Update GPU texture with new data
// NOTE: pixels data must match texture.format
void UpdateTexture(Texture2D texture, void *pixels)
{
rlglUpdateTexture(texture.id, texture.width, texture.height, texture.format, pixels);
}
// Draw a Texture2D
void DrawTexture(Texture2D texture, int posX, int posY, Color tint)
{
DrawTextureEx(texture, (Vector2){ (float)posX, (float)posY }, 0, 1.0f, tint);
}
// Draw a Texture2D with position defined as Vector2
void DrawTextureV(Texture2D texture, Vector2 position, Color tint)
{
DrawTextureEx(texture, position, 0, 1.0f, tint);
}
// Draw a Texture2D with extended parameters
void DrawTextureEx(Texture2D texture, Vector2 position, float rotation, float scale, Color tint)
{
Rectangle sourceRec = { 0, 0, texture.width, texture.height };
Rectangle destRec = { (int)position.x, (int)position.y, texture.width*scale, texture.height*scale };
Vector2 origin = { 0, 0 };
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DrawTexturePro(texture, sourceRec, destRec, origin, rotation, tint);
}
// Draw a part of a texture (defined by a rectangle)
void DrawTextureRec(Texture2D texture, Rectangle sourceRec, Vector2 position, Color tint)
{
Rectangle destRec = { (int)position.x, (int)position.y, abs(sourceRec.width), abs(sourceRec.height) };
Vector2 origin = { 0, 0 };
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DrawTexturePro(texture, sourceRec, destRec, origin, 0.0f, tint);
}
// Draw a part of a texture (defined by a rectangle) with 'pro' parameters
// NOTE: origin is relative to destination rectangle size
void DrawTexturePro(Texture2D texture, Rectangle sourceRec, Rectangle destRec, Vector2 origin, float rotation, Color tint)
{
rlEnableTexture(texture.id);
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rlPushMatrix();
rlTranslatef(destRec.x, destRec.y, 0);
rlRotatef(rotation, 0, 0, 1);
rlTranslatef(-origin.x, -origin.y, 0);
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rlBegin(RL_QUADS);
rlColor4ub(tint.r, tint.g, tint.b, tint.a);
rlNormal3f(0.0f, 0.0f, 1.0f); // Normal vector pointing towards viewer
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// Bottom-left corner for texture and quad
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rlTexCoord2f((float)sourceRec.x / texture.width, (float)sourceRec.y / texture.height);
rlVertex2f(0.0f, 0.0f);
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// Bottom-right corner for texture and quad
rlTexCoord2f((float)sourceRec.x / texture.width, (float)(sourceRec.y + sourceRec.height) / texture.height);
rlVertex2f(0.0f, destRec.height);
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// Top-right corner for texture and quad
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rlTexCoord2f((float)(sourceRec.x + sourceRec.width) / texture.width, (float)(sourceRec.y + sourceRec.height) / texture.height);
rlVertex2f(destRec.width, destRec.height);
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// Top-left corner for texture and quad
rlTexCoord2f((float)(sourceRec.x + sourceRec.width) / texture.width, (float)sourceRec.y / texture.height);
rlVertex2f(destRec.width, 0.0f);
rlEnd();
rlPopMatrix();
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rlDisableTexture();
}
//----------------------------------------------------------------------------------
// Module specific Functions Definition
//----------------------------------------------------------------------------------
// Loading DDS image data (compressed or uncompressed)
static Image LoadDDS(const char *fileName)
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{
// Required extension:
// GL_EXT_texture_compression_s3tc
// Supported tokens (defined by extensions)
// GL_COMPRESSED_RGB_S3TC_DXT1_EXT 0x83F0
// GL_COMPRESSED_RGBA_S3TC_DXT1_EXT 0x83F1
// GL_COMPRESSED_RGBA_S3TC_DXT3_EXT 0x83F2
// GL_COMPRESSED_RGBA_S3TC_DXT5_EXT 0x83F3
#define FOURCC_DXT1 0x31545844 // Equivalent to "DXT1" in ASCII
#define FOURCC_DXT3 0x33545844 // Equivalent to "DXT3" in ASCII
#define FOURCC_DXT5 0x35545844 // Equivalent to "DXT5" in ASCII
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// DDS Pixel Format
typedef struct {
unsigned int size;
unsigned int flags;
unsigned int fourCC;
unsigned int rgbBitCount;
unsigned int rBitMask;
unsigned int gBitMask;
unsigned int bBitMask;
unsigned int aBitMask;
} ddsPixelFormat;
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// DDS Header (124 bytes)
typedef struct {
unsigned int size;
unsigned int flags;
unsigned int height;
unsigned int width;
unsigned int pitchOrLinearSize;
unsigned int depth;
unsigned int mipmapCount;
unsigned int reserved1[11];
ddsPixelFormat ddspf;
unsigned int caps;
unsigned int caps2;
unsigned int caps3;
unsigned int caps4;
unsigned int reserved2;
} ddsHeader;
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Image image;
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image.data = NULL;
image.width = 0;
image.height = 0;
image.mipmaps = 0;
image.format = 0;
FILE *ddsFile = fopen(fileName, "rb");
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if (ddsFile == NULL)
{
TraceLog(WARNING, "[%s] DDS file could not be opened", fileName);
}
else
{
// Verify the type of file
char filecode[4];
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fread(filecode, 1, 4, ddsFile);
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if (strncmp(filecode, "DDS ", 4) != 0)
{
TraceLog(WARNING, "[%s] DDS file does not seem to be a valid image", fileName);
}
else
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{
ddsHeader header;
// Get the image header
fread(&header, sizeof(ddsHeader), 1, ddsFile);
TraceLog(DEBUG, "[%s] DDS file header size: %i", fileName, sizeof(ddsHeader));
TraceLog(DEBUG, "[%s] DDS file pixel format size: %i", fileName, header.ddspf.size);
TraceLog(DEBUG, "[%s] DDS file pixel format flags: 0x%x", fileName, header.ddspf.flags);
TraceLog(DEBUG, "[%s] DDS file format: 0x%x", fileName, header.ddspf.fourCC);
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TraceLog(DEBUG, "[%s] DDS file bit count: 0x%x", fileName, header.ddspf.rgbBitCount);
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image.width = header.width;
image.height = header.height;
image.mipmaps = 1; // Default value, could be changed (header.mipmapCount)
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if (header.ddspf.rgbBitCount == 16) // 16bit mode, no compressed
{
if (header.ddspf.flags == 0x40) // no alpha channel
{
image.data = (unsigned short *)malloc(image.width*image.height*sizeof(unsigned short));
fread(image.data, image.width*image.height*sizeof(unsigned short), 1, ddsFile);
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image.format = UNCOMPRESSED_R5G6B5;
}
else if (header.ddspf.flags == 0x41) // with alpha channel
{
if (header.ddspf.aBitMask == 0x8000) // 1bit alpha
{
image.data = (unsigned short *)malloc(image.width*image.height*sizeof(unsigned short));
fread(image.data, image.width*image.height*sizeof(unsigned short), 1, ddsFile);
unsigned char alpha = 0;
// NOTE: Data comes as A1R5G5B5, it must be reordered to R5G5B5A1
for (int i = 0; i < image.width*image.height; i++)
{
alpha = ((unsigned short *)image.data)[i] >> 15;
((unsigned short *)image.data)[i] = ((unsigned short *)image.data)[i] << 1;
((unsigned short *)image.data)[i] += alpha;
}
image.format = UNCOMPRESSED_R5G5B5A1;
}
else if (header.ddspf.aBitMask == 0xf000) // 4bit alpha
{
image.data = (unsigned short *)malloc(image.width*image.height*sizeof(unsigned short));
fread(image.data, image.width*image.height*sizeof(unsigned short), 1, ddsFile);
unsigned char alpha = 0;
// NOTE: Data comes as A4R4G4B4, it must be reordered R4G4B4A4
for (int i = 0; i < image.width*image.height; i++)
{
alpha = ((unsigned short *)image.data)[i] >> 12;
((unsigned short *)image.data)[i] = ((unsigned short *)image.data)[i] << 4;
((unsigned short *)image.data)[i] += alpha;
}
image.format = UNCOMPRESSED_R4G4B4A4;
}
}
}
if (header.ddspf.flags == 0x40 && header.ddspf.rgbBitCount == 24) // DDS_RGB, no compressed
{
// NOTE: not sure if this case exists...
image.data = (unsigned char *)malloc(image.width*image.height*3*sizeof(unsigned char));
fread(image.data, image.width*image.height*3, 1, ddsFile);
image.format = UNCOMPRESSED_R8G8B8;
}
else if (header.ddspf.flags == 0x41 && header.ddspf.rgbBitCount == 32) // DDS_RGBA, no compressed
{
image.data = (unsigned char *)malloc(image.width*image.height*4*sizeof(unsigned char));
fread(image.data, image.width*image.height*4, 1, ddsFile);
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unsigned char blue = 0;
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// NOTE: Data comes as A8R8G8B8, it must be reordered R8G8B8A8 (view next comment)
// DirecX understand ARGB as a 32bit DWORD but the actual memory byte alignment is BGRA
// So, we must realign B8G8R8A8 to R8G8B8A8
for (int i = 0; i < image.width*image.height*4; i += 4)
{
blue = ((unsigned char *)image.data)[i];
((unsigned char *)image.data)[i] = ((unsigned char *)image.data)[i + 2];
((unsigned char *)image.data)[i + 2] = blue;
}
image.format = UNCOMPRESSED_R8G8B8A8;
}
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else if (((header.ddspf.flags == 0x04) || (header.ddspf.flags == 0x05)) && (header.ddspf.fourCC > 0)) // Compressed
{
int bufsize;
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// Calculate data size, including all mipmaps
if (header.mipmapCount > 1) bufsize = header.pitchOrLinearSize*2;
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else bufsize = header.pitchOrLinearSize;
TraceLog(DEBUG, "Pitch or linear size: %i", header.pitchOrLinearSize);
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image.data = (unsigned char*)malloc(bufsize*sizeof(unsigned char));
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fread(image.data, 1, bufsize, ddsFile);
image.mipmaps = header.mipmapCount;
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switch(header.ddspf.fourCC)
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{
case FOURCC_DXT1:
{
if (header.ddspf.flags == 0x04) image.format = COMPRESSED_DXT1_RGB;
else image.format = COMPRESSED_DXT1_RGBA;
} break;
case FOURCC_DXT3: image.format = COMPRESSED_DXT3_RGBA; break;
case FOURCC_DXT5: image.format = COMPRESSED_DXT5_RGBA; break;
default: break;
}
}
}
fclose(ddsFile); // Close file pointer
}
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return image;
}
// Loading PKM image data (ETC1/ETC2 compression)
// NOTE: KTX is the standard Khronos Group compression format (ETC1/ETC2, mipmaps)
// PKM is a much simpler file format used mainly to contain a single ETC1/ETC2 compressed image (no mipmaps)
static Image LoadPKM(const char *fileName)
{
// Required extensions:
// GL_OES_compressed_ETC1_RGB8_texture (ETC1) (OpenGL ES 2.0)
// GL_ARB_ES3_compatibility (ETC2/EAC) (OpenGL ES 3.0)
// Supported tokens (defined by extensions)
// GL_ETC1_RGB8_OES 0x8D64
// GL_COMPRESSED_RGB8_ETC2 0x9274
// GL_COMPRESSED_RGBA8_ETC2_EAC 0x9278
// PKM file (ETC1) Header (16 bytes)
typedef struct {
char id[4]; // "PKM "
char version[2]; // "10" or "20"
unsigned short format; // Data format (big-endian) (Check list below)
unsigned short width; // Texture width (big-endian) (origWidth rounded to multiple of 4)
unsigned short height; // Texture height (big-endian) (origHeight rounded to multiple of 4)
unsigned short origWidth; // Original width (big-endian)
unsigned short origHeight; // Original height (big-endian)
} pkmHeader;
// Formats list
// version 10: format: 0=ETC1_RGB, [1=ETC1_RGBA, 2=ETC1_RGB_MIP, 3=ETC1_RGBA_MIP] (not used)
// version 20: format: 0=ETC1_RGB, 1=ETC2_RGB, 2=ETC2_RGBA_OLD, 3=ETC2_RGBA, 4=ETC2_RGBA1, 5=ETC2_R, 6=ETC2_RG, 7=ETC2_SIGNED_R, 8=ETC2_SIGNED_R
// NOTE: The extended width and height are the widths rounded up to a multiple of 4.
// NOTE: ETC is always 4bit per pixel (64 bit for each 4x4 block of pixels)
Image image;
image.data = NULL;
image.width = 0;
image.height = 0;
image.mipmaps = 0;
image.format = 0;
FILE *pkmFile = fopen(fileName, "rb");
if (pkmFile == NULL)
{
TraceLog(WARNING, "[%s] PKM file could not be opened", fileName);
}
else
{
pkmHeader header;
// Get the image header
fread(&header, sizeof(pkmHeader), 1, pkmFile);
if (strncmp(header.id, "PKM ", 4) != 0)
{
TraceLog(WARNING, "[%s] PKM file does not seem to be a valid image", fileName);
}
else
{
// NOTE: format, width and height come as big-endian, data must be swapped to little-endian
header.format = ((header.format & 0x00FF) << 8) | ((header.format & 0xFF00) >> 8);
header.width = ((header.width & 0x00FF) << 8) | ((header.width & 0xFF00) >> 8);
header.height = ((header.height & 0x00FF) << 8) | ((header.height & 0xFF00) >> 8);
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TraceLog(DEBUG, "PKM (ETC) image width: %i", header.width);
TraceLog(DEBUG, "PKM (ETC) image height: %i", header.height);
TraceLog(DEBUG, "PKM (ETC) image format: %i", header.format);
image.width = header.width;
image.height = header.height;
image.mipmaps = 1;
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int bpp = 4;
if (header.format == 3) bpp = 8;
int size = image.width*image.height*bpp/8; // Total data size in bytes
image.data = (unsigned char*)malloc(size * sizeof(unsigned char));
fread(image.data, 1, size, pkmFile);
if (header.format == 0) image.format = COMPRESSED_ETC1_RGB;
else if (header.format == 1) image.format = COMPRESSED_ETC2_RGB;
else if (header.format == 3) image.format = COMPRESSED_ETC2_EAC_RGBA;
}
fclose(pkmFile); // Close file pointer
}
return image;
}
// Load KTX compressed image data (ETC1/ETC2 compression)
static Image LoadKTX(const char *fileName)
{
// Required extensions:
// GL_OES_compressed_ETC1_RGB8_texture (ETC1)
// GL_ARB_ES3_compatibility (ETC2/EAC)
// Supported tokens (defined by extensions)
// GL_ETC1_RGB8_OES 0x8D64
// GL_COMPRESSED_RGB8_ETC2 0x9274
// GL_COMPRESSED_RGBA8_ETC2_EAC 0x9278
// KTX file Header (64 bytes)
// https://www.khronos.org/opengles/sdk/tools/KTX/file_format_spec/
typedef struct {
char id[12]; // Identifier: "«KTX 11»\r\n\x1A\n"
unsigned int endianness; // Little endian: 0x01 0x02 0x03 0x04
unsigned int glType; // For compressed textures, glType must equal 0
unsigned int glTypeSize; // For compressed texture data, usually 1
unsigned int glFormat; // For compressed textures is 0
unsigned int glInternalFormat; // Compressed internal format
unsigned int glBaseInternalFormat; // Same as glFormat (RGB, RGBA, ALPHA...)
unsigned int width; // Texture image width in pixels
unsigned int height; // Texture image height in pixels
unsigned int depth; // For 2D textures is 0
unsigned int elements; // Number of array elements, usually 0
unsigned int faces; // Cubemap faces, for no-cubemap = 1
unsigned int mipmapLevels; // Non-mipmapped textures = 1
unsigned int keyValueDataSize; // Used to encode any arbitrary data...
} ktxHeader;
// NOTE: Before start of every mipmap data block, we have: unsigned int dataSize
Image image;
image.width = 0;
image.height = 0;
image.mipmaps = 0;
image.format = 0;
FILE *ktxFile = fopen(fileName, "rb");
if (ktxFile == NULL)
{
TraceLog(WARNING, "[%s] KTX image file could not be opened", fileName);
}
else
{
ktxHeader header;
// Get the image header
fread(&header, sizeof(ktxHeader), 1, ktxFile);
if ((header.id[1] != 'K') || (header.id[2] != 'T') || (header.id[3] != 'X') ||
(header.id[4] != ' ') || (header.id[5] != '1') || (header.id[6] != '1'))
{
TraceLog(WARNING, "[%s] KTX file does not seem to be a valid file", fileName);
}
else
{
image.width = header.width;
image.height = header.height;
image.mipmaps = header.mipmapLevels;
TraceLog(DEBUG, "KTX (ETC) image width: %i", header.width);
TraceLog(DEBUG, "KTX (ETC) image height: %i", header.height);
TraceLog(DEBUG, "KTX (ETC) image format: 0x%x", header.glInternalFormat);
unsigned char unused;
if (header.keyValueDataSize > 0)
{
for (int i = 0; i < header.keyValueDataSize; i++) fread(&unused, 1, 1, ktxFile);
}
int dataSize;
fread(&dataSize, sizeof(unsigned int), 1, ktxFile);
image.data = (unsigned char*)malloc(dataSize * sizeof(unsigned char));
fread(image.data, 1, dataSize, ktxFile);
if (header.glInternalFormat == 0x8D64) image.format = COMPRESSED_ETC1_RGB;
else if (header.glInternalFormat == 0x9274) image.format = COMPRESSED_ETC2_RGB;
else if (header.glInternalFormat == 0x9278) image.format = COMPRESSED_ETC2_EAC_RGBA;
}
fclose(ktxFile); // Close file pointer
}
return image;
}
// Loading PVR image data (uncompressed or PVRT compression)
// NOTE: PVR v2 not supported, use PVR v3 instead
static Image LoadPVR(const char *fileName)
{
// Required extension:
// GL_IMG_texture_compression_pvrtc
// Supported tokens (defined by extensions)
// GL_COMPRESSED_RGB_PVRTC_4BPPV1_IMG 0x8C00
// GL_COMPRESSED_RGBA_PVRTC_4BPPV1_IMG 0x8C02
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#if 0 // Not used...
// PVR file v2 Header (52 bytes)
typedef struct {
unsigned int headerLength;
unsigned int height;
unsigned int width;
unsigned int numMipmaps;
unsigned int flags;
unsigned int dataLength;
unsigned int bpp;
unsigned int bitmaskRed;
unsigned int bitmaskGreen;
unsigned int bitmaskBlue;
unsigned int bitmaskAlpha;
unsigned int pvrTag;
unsigned int numSurfs;
} pvrHeaderV2;
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#endif
// PVR file v3 Header (52 bytes)
// NOTE: After it could be metadata (15 bytes?)
typedef struct {
char id[4];
unsigned int flags;
unsigned char channels[4]; // pixelFormat high part
unsigned char channelDepth[4]; // pixelFormat low part
unsigned int colourSpace;
unsigned int channelType;
unsigned int height;
unsigned int width;
unsigned int depth;
unsigned int numSurfaces;
unsigned int numFaces;
unsigned int numMipmaps;
unsigned int metaDataSize;
} pvrHeaderV3;
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#if 0 // Not used...
// Metadata (usually 15 bytes)
typedef struct {
unsigned int devFOURCC;
unsigned int key;
unsigned int dataSize; // Not used?
unsigned char *data; // Not used?
} pvrMetadata;
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#endif
Image image;
image.data = NULL;
image.width = 0;
image.height = 0;
image.mipmaps = 0;
image.format = 0;
FILE *pvrFile = fopen(fileName, "rb");
if (pvrFile == NULL)
{
TraceLog(WARNING, "[%s] PVR file could not be opened", fileName);
}
else
{
// Check PVR image version
unsigned char pvrVersion = 0;
fread(&pvrVersion, sizeof(unsigned char), 1, pvrFile);
fseek(pvrFile, 0, SEEK_SET);
// Load different PVR data formats
if (pvrVersion == 0x50)
{
pvrHeaderV3 header;
// Get PVR image header
fread(&header, sizeof(pvrHeaderV3), 1, pvrFile);
if ((header.id[0] != 'P') || (header.id[1] != 'V') || (header.id[2] != 'R') || (header.id[3] != 3))
{
TraceLog(WARNING, "[%s] PVR file does not seem to be a valid image", fileName);
}
else
{
image.width = header.width;
image.height = header.height;
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image.mipmaps = header.numMipmaps;
// Check data format
if (((header.channels[0] == 'l') && (header.channels[1] == 0)) && (header.channelDepth[0] == 8)) image.format = UNCOMPRESSED_GRAYSCALE;
else if (((header.channels[0] == 'l') && (header.channels[1] == 'a')) && ((header.channelDepth[0] == 8) && (header.channelDepth[1] == 8))) image.format = UNCOMPRESSED_GRAY_ALPHA;
else if ((header.channels[0] == 'r') && (header.channels[1] == 'g') && (header.channels[2] == 'b'))
{
if (header.channels[3] == 'a')
{
if ((header.channelDepth[0] == 5) && (header.channelDepth[1] == 5) && (header.channelDepth[2] == 5) && (header.channelDepth[3] == 1)) image.format = UNCOMPRESSED_R5G5B5A1;
else if ((header.channelDepth[0] == 4) && (header.channelDepth[1] == 4) && (header.channelDepth[2] == 4) && (header.channelDepth[3] == 4)) image.format = UNCOMPRESSED_R4G4B4A4;
else if ((header.channelDepth[0] == 8) && (header.channelDepth[1] == 8) && (header.channelDepth[2] == 8) && (header.channelDepth[3] == 8)) image.format = UNCOMPRESSED_R8G8B8A8;
}
else if (header.channels[3] == 0)
{
if ((header.channelDepth[0] == 5) && (header.channelDepth[1] == 6) && (header.channelDepth[2] == 5)) image.format = UNCOMPRESSED_R5G6B5;
else if ((header.channelDepth[0] == 8) && (header.channelDepth[1] == 8) && (header.channelDepth[2] == 8)) image.format = UNCOMPRESSED_R8G8B8;
}
}
else if (header.channels[0] == 2) image.format = COMPRESSED_PVRT_RGB;
else if (header.channels[0] == 3) image.format = COMPRESSED_PVRT_RGBA;
// Skip meta data header
unsigned char unused = 0;
for (int i = 0; i < header.metaDataSize; i++) fread(&unused, sizeof(unsigned char), 1, pvrFile);
// Calculate data size (depends on format)
int bpp = 0;
switch (image.format)
{
case UNCOMPRESSED_GRAYSCALE: bpp = 8; break;
case UNCOMPRESSED_GRAY_ALPHA:
case UNCOMPRESSED_R5G5B5A1:
case UNCOMPRESSED_R5G6B5:
case UNCOMPRESSED_R4G4B4A4: bpp = 16; break;
case UNCOMPRESSED_R8G8B8A8: bpp = 32; break;
case UNCOMPRESSED_R8G8B8: bpp = 24; break;
case COMPRESSED_PVRT_RGB:
case COMPRESSED_PVRT_RGBA: bpp = 4; break;
default: break;
}
int dataSize = image.width*image.height*bpp/8; // Total data size in bytes
image.data = (unsigned char*)malloc(dataSize*sizeof(unsigned char));
// Read data from file
fread(image.data, dataSize, 1, pvrFile);
}
}
else if (pvrVersion == 52) TraceLog(INFO, "PVR v2 not supported, update your files to PVR v3");
fclose(pvrFile); // Close file pointer
}
return image;
}
// Load ASTC compressed image data (ASTC compression)
static Image LoadASTC(const char *fileName)
{
// Required extensions:
// GL_KHR_texture_compression_astc_hdr
// GL_KHR_texture_compression_astc_ldr
// Supported tokens (defined by extensions)
// GL_COMPRESSED_RGBA_ASTC_4x4_KHR 0x93b0
// GL_COMPRESSED_RGBA_ASTC_8x8_KHR 0x93b7
// ASTC file Header (16 bytes)
typedef struct {
unsigned char id[4]; // Signature: 0x13 0xAB 0xA1 0x5C
unsigned char blockX; // Block X dimensions
unsigned char blockY; // Block Y dimensions
unsigned char blockZ; // Block Z dimensions (1 for 2D images)
unsigned char width[3]; // Image width in pixels (24bit value)
unsigned char height[3]; // Image height in pixels (24bit value)
unsigned char lenght[3]; // Image Z-size (1 for 2D images)
} astcHeader;
Image image;
image.data = NULL;
image.width = 0;
image.height = 0;
image.mipmaps = 0;
image.format = 0;
FILE *astcFile = fopen(fileName, "rb");
if (astcFile == NULL)
{
TraceLog(WARNING, "[%s] ASTC file could not be opened", fileName);
}
else
{
astcHeader header;
// Get ASTC image header
fread(&header, sizeof(astcHeader), 1, astcFile);
if ((header.id[3] != 0x5c) || (header.id[2] != 0xa1) || (header.id[1] != 0xab) || (header.id[0] != 0x13))
{
TraceLog(WARNING, "[%s] ASTC file does not seem to be a valid image", fileName);
}
else
{
// NOTE: Assuming Little Endian (could it be wrong?)
image.width = 0x00000000 | ((int)header.width[2] << 16) | ((int)header.width[1] << 8) | ((int)header.width[0]);
image.height = 0x00000000 | ((int)header.height[2] << 16) | ((int)header.height[1] << 8) | ((int)header.height[0]);
// NOTE: ASTC format only contains one mipmap level
image.mipmaps = 1;
TraceLog(DEBUG, "ASTC image width: %i", image.width);
TraceLog(DEBUG, "ASTC image height: %i", image.height);
TraceLog(DEBUG, "ASTC image blocks: %ix%i", header.blockX, header.blockY);
// NOTE: Each block is always stored in 128bit so we can calculate the bpp
int bpp = 128/(header.blockX*header.blockY);
// NOTE: Currently we only support 2 blocks configurations: 4x4 and 8x8
if ((bpp == 8) || (bpp == 2))
{
int dataSize = image.width*image.height*bpp/8; // Data size in bytes
image.data = (unsigned char *)malloc(dataSize*sizeof(unsigned char));
fread(image.data, dataSize, 1, astcFile);
if (bpp == 8) image.format = COMPRESSED_ASTC_4x4_RGBA;
else if (bpp == 2) image.format = COMPRESSED_ASTC_4x4_RGBA;
}
else TraceLog(WARNING, "[%s] ASTC block size configuration not supported", fileName);
}
fclose(astcFile);
}
return image;
}