src/libprojectM/Renderer/SOIL/stbi_DDS_aug_c.h - vendor/opensource/projectM - Git at Google


 ///	DDS file support, does decoding, _not_ direct uploading
 ///	(use SOIL for that ;-)

 ///	A bunch of DirectDraw Surface structures and flags
 typedef struct {
     unsigned int    dwMagic;
     unsigned int    dwSize;
     unsigned int    dwFlags;
     unsigned int    dwHeight;
     unsigned int    dwWidth;
     unsigned int    dwPitchOrLinearSize;
     unsigned int    dwDepth;
     unsigned int    dwMipMapCount;
     unsigned int    dwReserved1[ 11 ];

     //  DDPIXELFORMAT
     struct {
       unsigned int    dwSize;
       unsigned int    dwFlags;
       unsigned int    dwFourCC;
       unsigned int    dwRGBBitCount;
       unsigned int    dwRBitMask;
       unsigned int    dwGBitMask;
       unsigned int    dwBBitMask;
       unsigned int    dwAlphaBitMask;
     }               sPixelFormat;

     //  DDCAPS2
     struct {
       unsigned int    dwCaps1;
       unsigned int    dwCaps2;
       unsigned int    dwDDSX;
       unsigned int    dwReserved;
     }               sCaps;
     unsigned int    dwReserved2;
 } DDS_header ;

 //	the following constants were copied directly off the MSDN website

 //	The dwFlags member of the original DDSURFACEDESC2 structure
 //	can be set to one or more of the following values.
 #define DDSD_CAPS	0x00000001
 #define DDSD_HEIGHT	0x00000002
 #define DDSD_WIDTH	0x00000004
 #define DDSD_PITCH	0x00000008
 #define DDSD_PIXELFORMAT	0x00001000
 #define DDSD_MIPMAPCOUNT	0x00020000
 #define DDSD_LINEARSIZE	0x00080000
 #define DDSD_DEPTH	0x00800000

 //	DirectDraw Pixel Format
 #define DDPF_ALPHAPIXELS	0x00000001
 #define DDPF_FOURCC	0x00000004
 #define DDPF_RGB	0x00000040

 //	The dwCaps1 member of the DDSCAPS2 structure can be
 //	set to one or more of the following values.
 #define DDSCAPS_COMPLEX	0x00000008
 #define DDSCAPS_TEXTURE	0x00001000
 #define DDSCAPS_MIPMAP	0x00400000

 //	The dwCaps2 member of the DDSCAPS2 structure can be
 //	set to one or more of the following values.
 #define DDSCAPS2_CUBEMAP	0x00000200
 #define DDSCAPS2_CUBEMAP_POSITIVEX	0x00000400
 #define DDSCAPS2_CUBEMAP_NEGATIVEX	0x00000800
 #define DDSCAPS2_CUBEMAP_POSITIVEY	0x00001000
 #define DDSCAPS2_CUBEMAP_NEGATIVEY	0x00002000
 #define DDSCAPS2_CUBEMAP_POSITIVEZ	0x00004000
 #define DDSCAPS2_CUBEMAP_NEGATIVEZ	0x00008000
 #define DDSCAPS2_VOLUME	0x00200000

 static int dds_test(stbi *s)
 {
 	//	check the magic number
 	if (get8(s) != 'D') return 0;
 	if (get8(s) != 'D') return 0;
 	if (get8(s) != 'S') return 0;
 	if (get8(s) != ' ') return 0;
 	//	check header size
 	if (get32le(s) != 124) return 0;
 	return 1;
 }
 #ifndef STBI_NO_STDIO
 int      stbi_dds_test_file        (FILE *f)
 {
    stbi s;
    int r,n = ftell(f);
    start_file(&s,f);
    r = dds_test(&s);
    fseek(f,n,SEEK_SET);
    return r;
 }
 #endif

 int      stbi_dds_test_memory      (stbi_uc const *buffer, int len)
 {
    stbi s;
    start_mem(&s,buffer, len);
    return dds_test(&s);
 }

 //	helper functions
 int stbi_convert_bit_range( int c, int from_bits, int to_bits )
 {
 	int b = (1 << (from_bits - 1)) + c * ((1 << to_bits) - 1);
 	return (b + (b >> from_bits)) >> from_bits;
 }
 void stbi_rgb_888_from_565( unsigned int c, int *r, int *g, int *b )
 {
 	*r = stbi_convert_bit_range( (c >> 11) & 31, 5, 8 );
 	*g = stbi_convert_bit_range( (c >> 05) & 63, 6, 8 );
 	*b = stbi_convert_bit_range( (c >> 00) & 31, 5, 8 );
 }
 void stbi_decode_DXT1_block(
 			unsigned char uncompressed[16*4],
 			unsigned char compressed[8] )
 {
 	int next_bit = 4*8;
 	int i, r, g, b;
 	int c0, c1;
 	unsigned char decode_colors[4*4];
 	//	find the 2 primary colors
 	c0 = compressed[0] + (compressed[1] << 8);
 	c1 = compressed[2] + (compressed[3] << 8);
 	stbi_rgb_888_from_565( c0, &r, &g, &b );
 	decode_colors[0] = r;
 	decode_colors[1] = g;
 	decode_colors[2] = b;
 	decode_colors[3] = 255;
 	stbi_rgb_888_from_565( c1, &r, &g, &b );
 	decode_colors[4] = r;
 	decode_colors[5] = g;
 	decode_colors[6] = b;
 	decode_colors[7] = 255;
 	if( c0 > c1 )
 	{
 		//	no alpha, 2 interpolated colors
 		decode_colors[8] = (2*decode_colors[0] + decode_colors[4]) / 3;
 		decode_colors[9] = (2*decode_colors[1] + decode_colors[5]) / 3;
 		decode_colors[10] = (2*decode_colors[2] + decode_colors[6]) / 3;
 		decode_colors[11] = 255;
 		decode_colors[12] = (decode_colors[0] + 2*decode_colors[4]) / 3;
 		decode_colors[13] = (decode_colors[1] + 2*decode_colors[5]) / 3;
 		decode_colors[14] = (decode_colors[2] + 2*decode_colors[6]) / 3;
 		decode_colors[15] = 255;
 	} else
 	{
 		//	1 interpolated color, alpha
 		decode_colors[8] = (decode_colors[0] + decode_colors[4]) / 2;
 		decode_colors[9] = (decode_colors[1] + decode_colors[5]) / 2;
 		decode_colors[10] = (decode_colors[2] + decode_colors[6]) / 2;
 		decode_colors[11] = 255;
 		decode_colors[12] = 0;
 		decode_colors[13] = 0;
 		decode_colors[14] = 0;
 		decode_colors[15] = 0;
 	}
 	//	decode the block
 	for( i = 0; i < 16*4; i += 4 )
 	{
 		int idx = ((compressed[next_bit>>3] >> (next_bit & 7)) & 3) * 4;
 		next_bit += 2;
 		uncompressed[i+0] = decode_colors[idx+0];
 		uncompressed[i+1] = decode_colors[idx+1];
 		uncompressed[i+2] = decode_colors[idx+2];
 		uncompressed[i+3] = decode_colors[idx+3];
 	}
 	//	done
 }
 void stbi_decode_DXT23_alpha_block(
 			unsigned char uncompressed[16*4],
 			unsigned char compressed[8] )
 {
 	int i, next_bit = 0;
 	//	each alpha value gets 4 bits
 	for( i = 3; i < 16*4; i += 4 )
 	{
 		uncompressed[i] = stbi_convert_bit_range(
 				(compressed[next_bit>>3] >> (next_bit&7)) & 15,
 				4, 8 );
 		next_bit += 4;
 	}
 }
 void stbi_decode_DXT45_alpha_block(
 			unsigned char uncompressed[16*4],
 			unsigned char compressed[8] )
 {
 	int i, next_bit = 8*2;
 	unsigned char decode_alpha[8];
 	//	each alpha value gets 3 bits, and the 1st 2 bytes are the range
 	decode_alpha[0] = compressed[0];
 	decode_alpha[1] = compressed[1];
 	if( decode_alpha[0] > decode_alpha[1] )
 	{
 		//	6 step intermediate
 		decode_alpha[2] = (6*decode_alpha[0] + 1*decode_alpha[1]) / 7;
 		decode_alpha[3] = (5*decode_alpha[0] + 2*decode_alpha[1]) / 7;
 		decode_alpha[4] = (4*decode_alpha[0] + 3*decode_alpha[1]) / 7;
 		decode_alpha[5] = (3*decode_alpha[0] + 4*decode_alpha[1]) / 7;
 		decode_alpha[6] = (2*decode_alpha[0] + 5*decode_alpha[1]) / 7;
 		decode_alpha[7] = (1*decode_alpha[0] + 6*decode_alpha[1]) / 7;
 	} else
 	{
 		//	4 step intermediate, pluss full and none
 		decode_alpha[2] = (4*decode_alpha[0] + 1*decode_alpha[1]) / 5;
 		decode_alpha[3] = (3*decode_alpha[0] + 2*decode_alpha[1]) / 5;
 		decode_alpha[4] = (2*decode_alpha[0] + 3*decode_alpha[1]) / 5;
 		decode_alpha[5] = (1*decode_alpha[0] + 4*decode_alpha[1]) / 5;
 		decode_alpha[6] = 0;
 		decode_alpha[7] = 255;
 	}
 	for( i = 3; i < 16*4; i += 4 )
 	{
 		int idx = 0, bit;
 		bit = (compressed[next_bit>>3] >> (next_bit&7)) & 1;
 		idx += bit << 0;
 		++next_bit;
 		bit = (compressed[next_bit>>3] >> (next_bit&7)) & 1;
 		idx += bit << 1;
 		++next_bit;
 		bit = (compressed[next_bit>>3] >> (next_bit&7)) & 1;
 		idx += bit << 2;
 		++next_bit;
 		uncompressed[i] = decode_alpha[idx & 7];
 	}
 	//	done
 }
 void stbi_decode_DXT_color_block(
 			unsigned char uncompressed[16*4],
 			unsigned char compressed[8] )
 {
 	int next_bit = 4*8;
 	int i, r, g, b;
 	int c0, c1;
 	unsigned char decode_colors[4*3];
 	//	find the 2 primary colors
 	c0 = compressed[0] + (compressed[1] << 8);
 	c1 = compressed[2] + (compressed[3] << 8);
 	stbi_rgb_888_from_565( c0, &r, &g, &b );
 	decode_colors[0] = r;
 	decode_colors[1] = g;
 	decode_colors[2] = b;
 	stbi_rgb_888_from_565( c1, &r, &g, &b );
 	decode_colors[3] = r;
 	decode_colors[4] = g;
 	decode_colors[5] = b;
 	//	Like DXT1, but no choicees:
 	//	no alpha, 2 interpolated colors
 	decode_colors[6] = (2*decode_colors[0] + decode_colors[3]) / 3;
 	decode_colors[7] = (2*decode_colors[1] + decode_colors[4]) / 3;
 	decode_colors[8] = (2*decode_colors[2] + decode_colors[5]) / 3;
 	decode_colors[9] = (decode_colors[0] + 2*decode_colors[3]) / 3;
 	decode_colors[10] = (decode_colors[1] + 2*decode_colors[4]) / 3;
 	decode_colors[11] = (decode_colors[2] + 2*decode_colors[5]) / 3;
 	//	decode the block
 	for( i = 0; i < 16*4; i += 4 )
 	{
 		int idx = ((compressed[next_bit>>3] >> (next_bit & 7)) & 3) * 3;
 		next_bit += 2;
 		uncompressed[i+0] = decode_colors[idx+0];
 		uncompressed[i+1] = decode_colors[idx+1];
 		uncompressed[i+2] = decode_colors[idx+2];
 	}
 	//	done
 }
 static stbi_uc *dds_load(stbi *s, int *x, int *y, int *comp, int req_comp)
 {
 	//	all variables go up front
 	stbi_uc *dds_data = NULL;
 	stbi_uc block[16*4];
 	stbi_uc compressed[8];
 	int flags, DXT_family;
 	int has_alpha, has_mipmap;
 	int is_compressed, cubemap_faces;
 	int block_pitch, num_blocks;
 	DDS_header header;
 	int i, sz, cf;
 	//	load the header
 	if( sizeof( DDS_header ) != 128 )
 	{
 		return NULL;
 	}
 	getn( s, (stbi_uc*)(&header), 128 );
 	//	and do some checking
 	if( header.dwMagic != (('D' << 0) | ('D' << 8) | ('S' << 16) | (' ' << 24)) ) return NULL;
 	if( header.dwSize != 124 ) return NULL;
 	flags = DDSD_CAPS | DDSD_HEIGHT | DDSD_WIDTH | DDSD_PIXELFORMAT;
 	if( (header.dwFlags & flags) != flags ) return NULL;
 	/*	According to the MSDN spec, the dwFlags should contain
 		DDSD_LINEARSIZE if it's compressed, or DDSD_PITCH if
 		uncompressed.  Some DDS writers do not conform to the
 		spec, so I need to make my reader more tolerant	*/
 	if( header.sPixelFormat.dwSize != 32 ) return NULL;
 	flags = DDPF_FOURCC | DDPF_RGB;
 	if( (header.sPixelFormat.dwFlags & flags) == 0 ) return NULL;
 	if( (header.sCaps.dwCaps1 & DDSCAPS_TEXTURE) == 0 ) return NULL;
 	//	get the image data
 	s->img_x = header.dwWidth;
 	s->img_y = header.dwHeight;
 	s->img_n = 4;
 	is_compressed = (header.sPixelFormat.dwFlags & DDPF_FOURCC) / DDPF_FOURCC;
 	has_alpha = (header.sPixelFormat.dwFlags & DDPF_ALPHAPIXELS) / DDPF_ALPHAPIXELS;
 	has_mipmap = (header.sCaps.dwCaps1 & DDSCAPS_MIPMAP) && (header.dwMipMapCount > 1);
 	cubemap_faces = (header.sCaps.dwCaps2 & DDSCAPS2_CUBEMAP) / DDSCAPS2_CUBEMAP;
 	/*	I need cubemaps to have square faces	*/
 	cubemap_faces &= (s->img_x == s->img_y);
 	cubemap_faces *= 5;
 	cubemap_faces += 1;
 	block_pitch = (s->img_x+3) >> 2;
 	num_blocks = block_pitch * ((s->img_y+3) >> 2);
 	/*	let the user know what's going on	*/
 	*x = s->img_x;
 	*y = s->img_y;
 	*comp = s->img_n;
 	/*	is this uncompressed?	*/
 	if( is_compressed )
 	{
 		/*	compressed	*/
 		//	note: header.sPixelFormat.dwFourCC is something like (('D'<<0)|('X'<<8)|('T'<<16)|('1'<<24))
 		DXT_family = 1 + (header.sPixelFormat.dwFourCC >> 24) - '1';
 		if( (DXT_family < 1) || (DXT_family > 5) ) return NULL;
 		/*	check the expected size...oops, nevermind...
 			those non-compliant writers leave
 			dwPitchOrLinearSize == 0	*/
 		//	passed all the tests, get the RAM for decoding
 		sz = (s->img_x)*(s->img_y)*4*cubemap_faces;
 		dds_data = (unsigned char*)malloc( sz );
 		/*	do this once for each face	*/
 		for( cf = 0; cf < cubemap_faces; ++ cf )
 		{
 			//	now read and decode all the blocks
 			for( i = 0; i < num_blocks; ++i )
 			{
 				//	where are we?
 				int bx, by, bw=4, bh=4;
 				int ref_x = 4 * (i % block_pitch);
 				int ref_y = 4 * (i / block_pitch);
 				//	get the next block's worth of compressed data, and decompress it
 				if( DXT_family == 1 )
 				{
 					//	DXT1
 					getn( s, compressed, 8 );
 					stbi_decode_DXT1_block( block, compressed );
 				} else if( DXT_family < 4 )
 				{
 					//	DXT2/3
 					getn( s, compressed, 8 );
 					stbi_decode_DXT23_alpha_block ( block, compressed );
 					getn( s, compressed, 8 );
 					stbi_decode_DXT_color_block ( block, compressed );
 				} else
 				{
 					//	DXT4/5
 					getn( s, compressed, 8 );
 					stbi_decode_DXT45_alpha_block ( block, compressed );
 					getn( s, compressed, 8 );
 					stbi_decode_DXT_color_block ( block, compressed );
 				}
 				//	is this a partial block?
 				if( ref_x + 4 > s->img_x )
 				{
 					bw = s->img_x - ref_x;
 				}
 				if( ref_y + 4 > s->img_y )
 				{
 					bh = s->img_y - ref_y;
 				}
 				//	now drop our decompressed data into the buffer
 				for( by = 0; by < bh; ++by )
 				{
 					int idx = 4*((ref_y+by+cf*s->img_x)*s->img_x + ref_x);
 					for( bx = 0; bx < bw*4; ++bx )
 					{

 						dds_data[idx+bx] = block[by*16+bx];
 					}
 				}
 			}
 			/*	done reading and decoding the main image...
 				skip MIPmaps if present	*/
 			if( has_mipmap )
 			{
 				int block_size = 16;
 				if( DXT_family == 1 )
 				{
 					block_size = 8;
 				}
 				for( i = 1; i < header.dwMipMapCount; ++i )
 				{
 					int mx = s->img_x >> (i + 2);
 					int my = s->img_y >> (i + 2);
 					if( mx < 1 )
 					{
 						mx = 1;
 					}
 					if( my < 1 )
 					{
 						my = 1;
 					}
 					skip( s, mx*my*block_size );
 				}
 			}
 		}/* per cubemap face */
 	} else
 	{
 		/*	uncompressed	*/
 		DXT_family = 0;
 		s->img_n = 3;
 		if( has_alpha )
 		{
 			s->img_n = 4;
 		}
 		*comp = s->img_n;
 		sz = s->img_x*s->img_y*s->img_n*cubemap_faces;
 		dds_data = (unsigned char*)malloc( sz );
 		/*	do this once for each face	*/
 		for( cf = 0; cf < cubemap_faces; ++ cf )
 		{
 			/*	read the main image for this face	*/
 			getn( s, &dds_data[cf*s->img_x*s->img_y*s->img_n], s->img_x*s->img_y*s->img_n );
 			/*	done reading and decoding the main image...
 				skip MIPmaps if present	*/
 			if( has_mipmap )
 			{
 				for( i = 1; i < header.dwMipMapCount; ++i )
 				{
 					int mx = s->img_x >> i;
 					int my = s->img_y >> i;
 					if( mx < 1 )
 					{
 						mx = 1;
 					}
 					if( my < 1 )
 					{
 						my = 1;
 					}
 					skip( s, mx*my*s->img_n );
 				}
 			}
 		}
 		/*	data was BGR, I need it RGB	*/
 		for( i = 0; i < sz; i += s->img_n )
 		{
 			unsigned char temp = dds_data[i];
 			dds_data[i] = dds_data[i+2];
 			dds_data[i+2] = temp;
 		}
 	}
 	/*	finished decompressing into RGBA,
 		adjust the y size if we have a cubemap
 		note: sz is already up to date	*/
 	s->img_y *= cubemap_faces;
 	*y = s->img_y;
 	//	did the user want something else, or
 	//	see if all the alpha values are 255 (i.e. no transparency)
 	has_alpha = 0;
 	if( s->img_n == 4)
 	{
 		for( i = 3; (i < sz) && (has_alpha == 0); i += 4 )
 		{
 			has_alpha |= (dds_data[i] < 255);
 		}
 	}
 	if( (req_comp <= 4) && (req_comp >= 1) )
 	{
 		//	user has some requirements, meet them
 		if( req_comp != s->img_n )
 		{
 			dds_data = convert_format( dds_data, s->img_n, req_comp, s->img_x, s->img_y );
 			*comp = s->img_n;
 		}
 	} else
 	{
 		//	user had no requirements, only drop to RGB is no alpha
 		if( (has_alpha == 0) && (s->img_n == 4) )
 		{
 			dds_data = convert_format( dds_data, 4, 3, s->img_x, s->img_y );
 			*comp = 3;
 		}
 	}
 	//	OK, done
 	return dds_data;
 }

 #ifndef STBI_NO_STDIO
 stbi_uc *stbi_dds_load_from_file   (FILE *f,                  int *x, int *y, int *comp, int req_comp)
 {
 	stbi s;
    start_file(&s,f);
    return dds_load(&s,x,y,comp,req_comp);
 }

 stbi_uc *stbi_dds_load             (char *filename,           int *x, int *y, int *comp, int req_comp)
 {
    stbi_uc *data;
    FILE *f = fopen(filename, "rb");
    if (!f) return NULL;
    data = stbi_dds_load_from_file(f,x,y,comp,req_comp);
    fclose(f);
    return data;
 }
 #endif

 stbi_uc *stbi_dds_load_from_memory (stbi_uc const *buffer, int len, int *x, int *y, int *comp, int req_comp)
 {
 	stbi s;
    start_mem(&s,buffer, len);
    return dds_load(&s,x,y,comp,req_comp);
 }

	/// DDS file support, does decoding, _not_ direct uploading
	/// (use SOIL for that ;-)

	/// A bunch of DirectDraw Surface structures and flags
	typedef struct {
	unsigned int dwMagic;
	unsigned int dwSize;
	unsigned int dwFlags;
	unsigned int dwHeight;
	unsigned int dwWidth;
	unsigned int dwPitchOrLinearSize;
	unsigned int dwDepth;
	unsigned int dwMipMapCount;
	unsigned int dwReserved1[ 11 ];

	// DDPIXELFORMAT
	struct {
	unsigned int dwSize;
	unsigned int dwFlags;
	unsigned int dwFourCC;
	unsigned int dwRGBBitCount;
	unsigned int dwRBitMask;
	unsigned int dwGBitMask;
	unsigned int dwBBitMask;
	unsigned int dwAlphaBitMask;
	} sPixelFormat;

	// DDCAPS2
	struct {
	unsigned int dwCaps1;
	unsigned int dwCaps2;
	unsigned int dwDDSX;
	unsigned int dwReserved;
	} sCaps;
	unsigned int dwReserved2;
	} DDS_header ;

	// the following constants were copied directly off the MSDN website

	// The dwFlags member of the original DDSURFACEDESC2 structure
	// can be set to one or more of the following values.
	#define DDSD_CAPS 0x00000001
	#define DDSD_HEIGHT 0x00000002
	#define DDSD_WIDTH 0x00000004
	#define DDSD_PITCH 0x00000008
	#define DDSD_PIXELFORMAT 0x00001000
	#define DDSD_MIPMAPCOUNT 0x00020000
	#define DDSD_LINEARSIZE 0x00080000
	#define DDSD_DEPTH 0x00800000

	// DirectDraw Pixel Format
	#define DDPF_ALPHAPIXELS 0x00000001
	#define DDPF_FOURCC 0x00000004
	#define DDPF_RGB 0x00000040

	// The dwCaps1 member of the DDSCAPS2 structure can be
	// set to one or more of the following values.
	#define DDSCAPS_COMPLEX 0x00000008
	#define DDSCAPS_TEXTURE 0x00001000
	#define DDSCAPS_MIPMAP 0x00400000

	// The dwCaps2 member of the DDSCAPS2 structure can be
	// set to one or more of the following values.
	#define DDSCAPS2_CUBEMAP 0x00000200
	#define DDSCAPS2_CUBEMAP_POSITIVEX 0x00000400
	#define DDSCAPS2_CUBEMAP_NEGATIVEX 0x00000800
	#define DDSCAPS2_CUBEMAP_POSITIVEY 0x00001000
	#define DDSCAPS2_CUBEMAP_NEGATIVEY 0x00002000
	#define DDSCAPS2_CUBEMAP_POSITIVEZ 0x00004000
	#define DDSCAPS2_CUBEMAP_NEGATIVEZ 0x00008000
	#define DDSCAPS2_VOLUME 0x00200000

	static int dds_test(stbi *s)
	{
	// check the magic number
	if (get8(s) != 'D') return 0;
	if (get8(s) != 'D') return 0;
	if (get8(s) != 'S') return 0;
	if (get8(s) != ' ') return 0;
	// check header size
	if (get32le(s) != 124) return 0;
	return 1;
	}
	#ifndef STBI_NO_STDIO
	int stbi_dds_test_file (FILE *f)
	{
	stbi s;
	int r,n = ftell(f);
	start_file(&s,f);
	r = dds_test(&s);
	fseek(f,n,SEEK_SET);
	return r;
	}
	#endif

	int stbi_dds_test_memory (stbi_uc const *buffer, int len)
	{
	stbi s;
	start_mem(&s,buffer, len);
	return dds_test(&s);
	}

	// helper functions
	int stbi_convert_bit_range( int c, int from_bits, int to_bits )
	{
	int b = (1 << (from_bits - 1)) + c * ((1 << to_bits) - 1);
	return (b + (b >> from_bits)) >> from_bits;
	}
	void stbi_rgb_888_from_565( unsigned int c, int r, int g, int *b )
	{
	*r = stbi_convert_bit_range( (c >> 11) & 31, 5, 8 );
	*g = stbi_convert_bit_range( (c >> 05) & 63, 6, 8 );
	*b = stbi_convert_bit_range( (c >> 00) & 31, 5, 8 );
	}
	void stbi_decode_DXT1_block(
	unsigned char uncompressed[16*4],
	unsigned char compressed[8] )
	{
	int next_bit = 4*8;
	int i, r, g, b;
	int c0, c1;
	unsigned char decode_colors[4*4];
	// find the 2 primary colors
	c0 = compressed[0] + (compressed[1] << 8);
	c1 = compressed[2] + (compressed[3] << 8);
	stbi_rgb_888_from_565( c0, &r, &g, &b );
	decode_colors[0] = r;
	decode_colors[1] = g;
	decode_colors[2] = b;
	decode_colors[3] = 255;
	stbi_rgb_888_from_565( c1, &r, &g, &b );
	decode_colors[4] = r;
	decode_colors[5] = g;
	decode_colors[6] = b;
	decode_colors[7] = 255;
	if( c0 > c1 )
	{
	// no alpha, 2 interpolated colors
	decode_colors[8] = (2*decode_colors[0] + decode_colors[4]) / 3;
	decode_colors[9] = (2*decode_colors[1] + decode_colors[5]) / 3;
	decode_colors[10] = (2*decode_colors[2] + decode_colors[6]) / 3;
	decode_colors[11] = 255;
	decode_colors[12] = (decode_colors[0] + 2*decode_colors[4]) / 3;
	decode_colors[13] = (decode_colors[1] + 2*decode_colors[5]) / 3;
	decode_colors[14] = (decode_colors[2] + 2*decode_colors[6]) / 3;
	decode_colors[15] = 255;
	} else
	{
	// 1 interpolated color, alpha
	decode_colors[8] = (decode_colors[0] + decode_colors[4]) / 2;
	decode_colors[9] = (decode_colors[1] + decode_colors[5]) / 2;
	decode_colors[10] = (decode_colors[2] + decode_colors[6]) / 2;
	decode_colors[11] = 255;
	decode_colors[12] = 0;
	decode_colors[13] = 0;
	decode_colors[14] = 0;
	decode_colors[15] = 0;
	}
	// decode the block
	for( i = 0; i < 16*4; i += 4 )
	{
	int idx = ((compressed[next_bit>>3] >> (next_bit & 7)) & 3) * 4;
	next_bit += 2;
	uncompressed[i+0] = decode_colors[idx+0];
	uncompressed[i+1] = decode_colors[idx+1];
	uncompressed[i+2] = decode_colors[idx+2];
	uncompressed[i+3] = decode_colors[idx+3];
	}
	// done
	}
	void stbi_decode_DXT23_alpha_block(
	unsigned char uncompressed[16*4],
	unsigned char compressed[8] )
	{
	int i, next_bit = 0;
	// each alpha value gets 4 bits
	for( i = 3; i < 16*4; i += 4 )
	{
	uncompressed[i] = stbi_convert_bit_range(
	(compressed[next_bit>>3] >> (next_bit&7)) & 15,
	4, 8 );
	next_bit += 4;
	}
	}
	void stbi_decode_DXT45_alpha_block(
	unsigned char uncompressed[16*4],
	unsigned char compressed[8] )
	{
	int i, next_bit = 8*2;
	unsigned char decode_alpha[8];
	// each alpha value gets 3 bits, and the 1st 2 bytes are the range
	decode_alpha[0] = compressed[0];
	decode_alpha[1] = compressed[1];
	if( decode_alpha[0] > decode_alpha[1] )
	{
	// 6 step intermediate
	decode_alpha[2] = (6decode_alpha[0] + 1decode_alpha[1]) / 7;
	decode_alpha[3] = (5decode_alpha[0] + 2decode_alpha[1]) / 7;
	decode_alpha[4] = (4decode_alpha[0] + 3decode_alpha[1]) / 7;
	decode_alpha[5] = (3decode_alpha[0] + 4decode_alpha[1]) / 7;
	decode_alpha[6] = (2decode_alpha[0] + 5decode_alpha[1]) / 7;
	decode_alpha[7] = (1decode_alpha[0] + 6decode_alpha[1]) / 7;
	} else
	{
	// 4 step intermediate, pluss full and none
	decode_alpha[2] = (4decode_alpha[0] + 1decode_alpha[1]) / 5;
	decode_alpha[3] = (3decode_alpha[0] + 2decode_alpha[1]) / 5;
	decode_alpha[4] = (2decode_alpha[0] + 3decode_alpha[1]) / 5;
	decode_alpha[5] = (1decode_alpha[0] + 4decode_alpha[1]) / 5;
	decode_alpha[6] = 0;
	decode_alpha[7] = 255;
	}
	for( i = 3; i < 16*4; i += 4 )
	{
	int idx = 0, bit;
	bit = (compressed[next_bit>>3] >> (next_bit&7)) & 1;
	idx += bit << 0;
	++next_bit;
	bit = (compressed[next_bit>>3] >> (next_bit&7)) & 1;
	idx += bit << 1;
	++next_bit;
	bit = (compressed[next_bit>>3] >> (next_bit&7)) & 1;
	idx += bit << 2;
	++next_bit;
	uncompressed[i] = decode_alpha[idx & 7];
	}
	// done
	}
	void stbi_decode_DXT_color_block(
	unsigned char uncompressed[16*4],
	unsigned char compressed[8] )
	{
	int next_bit = 4*8;
	int i, r, g, b;
	int c0, c1;
	unsigned char decode_colors[4*3];
	// find the 2 primary colors
	c0 = compressed[0] + (compressed[1] << 8);
	c1 = compressed[2] + (compressed[3] << 8);
	stbi_rgb_888_from_565( c0, &r, &g, &b );
	decode_colors[0] = r;
	decode_colors[1] = g;
	decode_colors[2] = b;
	stbi_rgb_888_from_565( c1, &r, &g, &b );
	decode_colors[3] = r;
	decode_colors[4] = g;
	decode_colors[5] = b;
	// Like DXT1, but no choicees:
	// no alpha, 2 interpolated colors
	decode_colors[6] = (2*decode_colors[0] + decode_colors[3]) / 3;
	decode_colors[7] = (2*decode_colors[1] + decode_colors[4]) / 3;
	decode_colors[8] = (2*decode_colors[2] + decode_colors[5]) / 3;
	decode_colors[9] = (decode_colors[0] + 2*decode_colors[3]) / 3;
	decode_colors[10] = (decode_colors[1] + 2*decode_colors[4]) / 3;
	decode_colors[11] = (decode_colors[2] + 2*decode_colors[5]) / 3;
	// decode the block
	for( i = 0; i < 16*4; i += 4 )
	{
	int idx = ((compressed[next_bit>>3] >> (next_bit & 7)) & 3) * 3;
	next_bit += 2;
	uncompressed[i+0] = decode_colors[idx+0];
	uncompressed[i+1] = decode_colors[idx+1];
	uncompressed[i+2] = decode_colors[idx+2];
	}
	// done
	}
	static stbi_uc dds_load(stbi s, int x, int y, int *comp, int req_comp)
	{
	// all variables go up front
	stbi_uc *dds_data = NULL;
	stbi_uc block[16*4];
	stbi_uc compressed[8];
	int flags, DXT_family;
	int has_alpha, has_mipmap;
	int is_compressed, cubemap_faces;
	int block_pitch, num_blocks;
	DDS_header header;
	int i, sz, cf;
	// load the header
	if( sizeof( DDS_header ) != 128 )
	{
	return NULL;
	}
	getn( s, (stbi_uc*)(&header), 128 );
	// and do some checking
	if( header.dwMagic != (('D' << 0) \| ('D' << 8) \| ('S' << 16) \| (' ' << 24)) ) return NULL;
	if( header.dwSize != 124 ) return NULL;
	flags = DDSD_CAPS \| DDSD_HEIGHT \| DDSD_WIDTH \| DDSD_PIXELFORMAT;
	if( (header.dwFlags & flags) != flags ) return NULL;
	/* According to the MSDN spec, the dwFlags should contain
	DDSD_LINEARSIZE if it's compressed, or DDSD_PITCH if
	uncompressed. Some DDS writers do not conform to the
	spec, so I need to make my reader more tolerant */
	if( header.sPixelFormat.dwSize != 32 ) return NULL;
	flags = DDPF_FOURCC \| DDPF_RGB;
	if( (header.sPixelFormat.dwFlags & flags) == 0 ) return NULL;
	if( (header.sCaps.dwCaps1 & DDSCAPS_TEXTURE) == 0 ) return NULL;
	// get the image data
	s->img_x = header.dwWidth;
	s->img_y = header.dwHeight;
	s->img_n = 4;
	is_compressed = (header.sPixelFormat.dwFlags & DDPF_FOURCC) / DDPF_FOURCC;
	has_alpha = (header.sPixelFormat.dwFlags & DDPF_ALPHAPIXELS) / DDPF_ALPHAPIXELS;
	has_mipmap = (header.sCaps.dwCaps1 & DDSCAPS_MIPMAP) && (header.dwMipMapCount > 1);
	cubemap_faces = (header.sCaps.dwCaps2 & DDSCAPS2_CUBEMAP) / DDSCAPS2_CUBEMAP;
	/* I need cubemaps to have square faces */
	cubemap_faces &= (s->img_x == s->img_y);
	cubemap_faces *= 5;
	cubemap_faces += 1;
	block_pitch = (s->img_x+3) >> 2;
	num_blocks = block_pitch * ((s->img_y+3) >> 2);
	/* let the user know what's going on */
	*x = s->img_x;
	*y = s->img_y;
	*comp = s->img_n;
	/* is this uncompressed? */
	if( is_compressed )
	{
	/* compressed */
	// note: header.sPixelFormat.dwFourCC is something like (('D'<<0)\|('X'<<8)\|('T'<<16)\|('1'<<24))
	DXT_family = 1 + (header.sPixelFormat.dwFourCC >> 24) - '1';
	if( (DXT_family < 1) \|\| (DXT_family > 5) ) return NULL;
	/* check the expected size...oops, nevermind...
	those non-compliant writers leave
	dwPitchOrLinearSize == 0 */
	// passed all the tests, get the RAM for decoding
	sz = (s->img_x)(s->img_y)4*cubemap_faces;
	dds_data = (unsigned char*)malloc( sz );
	/* do this once for each face */
	for( cf = 0; cf < cubemap_faces; ++ cf )
	{
	// now read and decode all the blocks
	for( i = 0; i < num_blocks; ++i )
	{
	// where are we?
	int bx, by, bw=4, bh=4;
	int ref_x = 4 * (i % block_pitch);
	int ref_y = 4 * (i / block_pitch);
	// get the next block's worth of compressed data, and decompress it
	if( DXT_family == 1 )
	{
	// DXT1
	getn( s, compressed, 8 );
	stbi_decode_DXT1_block( block, compressed );
	} else if( DXT_family < 4 )
	{
	// DXT2/3
	getn( s, compressed, 8 );
	stbi_decode_DXT23_alpha_block ( block, compressed );
	getn( s, compressed, 8 );
	stbi_decode_DXT_color_block ( block, compressed );
	} else
	{
	// DXT4/5
	getn( s, compressed, 8 );
	stbi_decode_DXT45_alpha_block ( block, compressed );
	getn( s, compressed, 8 );
	stbi_decode_DXT_color_block ( block, compressed );
	}
	// is this a partial block?
	if( ref_x + 4 > s->img_x )
	{
	bw = s->img_x - ref_x;
	}
	if( ref_y + 4 > s->img_y )
	{
	bh = s->img_y - ref_y;
	}
	// now drop our decompressed data into the buffer
	for( by = 0; by < bh; ++by )
	{
	int idx = 4((ref_y+by+cfs->img_x)*s->img_x + ref_x);
	for( bx = 0; bx < bw*4; ++bx )
	{

	dds_data[idx+bx] = block[by*16+bx];
	}
	}
	}
	/* done reading and decoding the main image...
	skip MIPmaps if present */
	if( has_mipmap )
	{
	int block_size = 16;
	if( DXT_family == 1 )
	{
	block_size = 8;
	}
	for( i = 1; i < header.dwMipMapCount; ++i )
	{
	int mx = s->img_x >> (i + 2);
	int my = s->img_y >> (i + 2);
	if( mx < 1 )
	{
	mx = 1;
	}
	if( my < 1 )
	{
	my = 1;
	}
	skip( s, mxmyblock_size );
	}
	}
	}/* per cubemap face */
	} else
	{
	/* uncompressed */
	DXT_family = 0;
	s->img_n = 3;
	if( has_alpha )
	{
	s->img_n = 4;
	}
	*comp = s->img_n;
	sz = s->img_xs->img_ys->img_n*cubemap_faces;
	dds_data = (unsigned char*)malloc( sz );
	/* do this once for each face */
	for( cf = 0; cf < cubemap_faces; ++ cf )
	{
	/* read the main image for this face */
	getn( s, &dds_data[cfs->img_xs->img_ys->img_n], s->img_xs->img_y*s->img_n );
	/* done reading and decoding the main image...
	skip MIPmaps if present */
	if( has_mipmap )
	{
	for( i = 1; i < header.dwMipMapCount; ++i )
	{
	int mx = s->img_x >> i;
	int my = s->img_y >> i;
	if( mx < 1 )
	{
	mx = 1;
	}
	if( my < 1 )
	{
	my = 1;
	}
	skip( s, mxmys->img_n );
	}
	}
	}
	/* data was BGR, I need it RGB */
	for( i = 0; i < sz; i += s->img_n )
	{
	unsigned char temp = dds_data[i];
	dds_data[i] = dds_data[i+2];
	dds_data[i+2] = temp;
	}
	}
	/* finished decompressing into RGBA,
	adjust the y size if we have a cubemap
	note: sz is already up to date */
	s->img_y *= cubemap_faces;
	*y = s->img_y;
	// did the user want something else, or
	// see if all the alpha values are 255 (i.e. no transparency)
	has_alpha = 0;
	if( s->img_n == 4)
	{
	for( i = 3; (i < sz) && (has_alpha == 0); i += 4 )
	{
	has_alpha \|= (dds_data[i] < 255);
	}
	}
	if( (req_comp <= 4) && (req_comp >= 1) )
	{
	// user has some requirements, meet them
	if( req_comp != s->img_n )
	{
	dds_data = convert_format( dds_data, s->img_n, req_comp, s->img_x, s->img_y );
	*comp = s->img_n;
	}
	} else
	{
	// user had no requirements, only drop to RGB is no alpha
	if( (has_alpha == 0) && (s->img_n == 4) )
	{
	dds_data = convert_format( dds_data, 4, 3, s->img_x, s->img_y );
	*comp = 3;
	}
	}
	// OK, done
	return dds_data;
	}

	#ifndef STBI_NO_STDIO
	stbi_uc stbi_dds_load_from_file (FILE f, int x, int y, int *comp, int req_comp)
	{
	stbi s;
	start_file(&s,f);
	return dds_load(&s,x,y,comp,req_comp);
	}

	stbi_uc stbi_dds_load (char filename, int x, int y, int *comp, int req_comp)
	{
	stbi_uc *data;
	FILE *f = fopen(filename, "rb");
	if (!f) return NULL;
	data = stbi_dds_load_from_file(f,x,y,comp,req_comp);
	fclose(f);
	return data;
	}
	#endif

	stbi_uc stbi_dds_load_from_memory (stbi_uc const buffer, int len, int x, int y, int *comp, int req_comp)
	{
	stbi s;
	start_mem(&s,buffer, len);
	return dds_load(&s,x,y,comp,req_comp);
	}