/* * Mesa 3-D graphics library * * Copyright (C) 2014 Intel Corporation All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included * in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. */ #include "format_utils.h" #include "glformats.h" #include "format_pack.h" #include "format_unpack.h" const mesa_array_format RGBA32_FLOAT = MESA_ARRAY_FORMAT(4, 1, 1, 1, 4, 0, 1, 2, 3); const mesa_array_format RGBA8_UBYTE = MESA_ARRAY_FORMAT(1, 0, 0, 1, 4, 0, 1, 2, 3); const mesa_array_format RGBA32_UINT = MESA_ARRAY_FORMAT(4, 0, 0, 0, 4, 0, 1, 2, 3); const mesa_array_format RGBA32_INT = MESA_ARRAY_FORMAT(4, 1, 0, 0, 4, 0, 1, 2, 3); static void invert_swizzle(uint8_t dst[4], const uint8_t src[4]) { int i, j; dst[0] = MESA_FORMAT_SWIZZLE_NONE; dst[1] = MESA_FORMAT_SWIZZLE_NONE; dst[2] = MESA_FORMAT_SWIZZLE_NONE; dst[3] = MESA_FORMAT_SWIZZLE_NONE; for (i = 0; i < 4; ++i) for (j = 0; j < 4; ++j) if (src[j] == i && dst[i] == MESA_FORMAT_SWIZZLE_NONE) dst[i] = j; } /* Takes a src to RGBA swizzle and applies a rebase swizzle to it. This * is used when we need to rebase a format to match a different * base internal format. * * The rebase swizzle can be NULL, which means that no rebase is necessary, * in which case the src to RGBA swizzle is copied to the output without * changes. * * The resulting rebased swizzle and well as the input swizzles are * all 4-element swizzles, but the rebase swizzle can be NULL if no rebase * is necessary. */ static void compute_rebased_rgba_component_mapping(uint8_t *src2rgba, uint8_t *rebase_swizzle, uint8_t *rebased_src2rgba) { int i; if (rebase_swizzle) { for (i = 0; i < 4; i++) { if (rebase_swizzle[i] > MESA_FORMAT_SWIZZLE_W) rebased_src2rgba[i] = rebase_swizzle[i]; else rebased_src2rgba[i] = src2rgba[rebase_swizzle[i]]; } } else { /* No rebase needed, so src2rgba is all that we need */ memcpy(rebased_src2rgba, src2rgba, 4 * sizeof(uint8_t)); } } /* Computes the final swizzle transform to apply from src to dst in a * conversion that might involve a rebase swizzle. * * This is used to compute the swizzle transform to apply in conversions * between array formats where we have a src2rgba swizzle, a rgba2dst swizzle * and possibly, a rebase swizzle. * * The final swizzle transform to apply (src2dst) when a rebase swizzle is * involved is: src -> rgba -> base -> rgba -> dst */ static void compute_src2dst_component_mapping(uint8_t *src2rgba, uint8_t *rgba2dst, uint8_t *rebase_swizzle, uint8_t *src2dst) { int i; if (!rebase_swizzle) { for (i = 0; i < 4; i++) { if (rgba2dst[i] > MESA_FORMAT_SWIZZLE_W) { src2dst[i] = rgba2dst[i]; } else { src2dst[i] = src2rgba[rgba2dst[i]]; } } } else { for (i = 0; i < 4; i++) { if (rgba2dst[i] > MESA_FORMAT_SWIZZLE_W) { src2dst[i] = rgba2dst[i]; } else if (rebase_swizzle[rgba2dst[i]] > MESA_FORMAT_SWIZZLE_W) { src2dst[i] = rebase_swizzle[rgba2dst[i]]; } else { src2dst[i] = src2rgba[rebase_swizzle[rgba2dst[i]]]; } } } } /** * This function is used by clients of _mesa_format_convert to obtain * the rebase swizzle to use in a format conversion based on the base * format involved. * * \param baseFormat the base internal format involved in the conversion. * \param map the rebase swizzle to consider * * This function computes 'map' as rgba -> baseformat -> rgba and returns true * if the resulting swizzle transform is not the identity transform (thus, a * rebase is needed). If the function returns false then a rebase swizzle * is not necessary and the value of 'map' is undefined. In this situation * clients of _mesa_format_convert should pass NULL in the 'rebase_swizzle' * parameter. */ bool _mesa_compute_rgba2base2rgba_component_mapping(GLenum baseFormat, uint8_t *map) { uint8_t rgba2base[6], base2rgba[6]; int i; switch (baseFormat) { case GL_ALPHA: case GL_RED: case GL_GREEN: case GL_BLUE: case GL_RG: case GL_RGB: case GL_BGR: case GL_RGBA: case GL_BGRA: case GL_ABGR_EXT: case GL_LUMINANCE: case GL_INTENSITY: case GL_LUMINANCE_ALPHA: { bool needRebase = false; _mesa_compute_component_mapping(GL_RGBA, baseFormat, rgba2base); _mesa_compute_component_mapping(baseFormat, GL_RGBA, base2rgba); for (i = 0; i < 4; i++) { if (base2rgba[i] > MESA_FORMAT_SWIZZLE_W) { map[i] = base2rgba[i]; } else { map[i] = rgba2base[base2rgba[i]]; } if (map[i] != i) needRebase = true; } return needRebase; } default: unreachable("Unexpected base format"); } } /** * Special case conversion function to swap r/b channels from the source * image to the dest image. */ static void convert_ubyte_rgba_to_bgra(size_t width, size_t height, const uint8_t *src, size_t src_stride, uint8_t *dst, size_t dst_stride) { int row; if (sizeof(void *) == 8 && src_stride % 8 == 0 && dst_stride % 8 == 0 && (GLsizeiptr) src % 8 == 0 && (GLsizeiptr) dst % 8 == 0) { /* use 64-bit word to swizzle two 32-bit pixels. We need 8-byte * alignment for src/dst addresses and strides. */ for (row = 0; row < height; row++) { const GLuint64 *s = (const GLuint64 *) src; GLuint64 *d = (GLuint64 *) dst; int i; for (i = 0; i < width/2; i++) { d[i] = ( (s[i] & 0xff00ff00ff00ff00) | ((s[i] & 0xff000000ff) << 16) | ((s[i] & 0xff000000ff0000) >> 16)); } if (width & 1) { /* handle the case of odd widths */ const GLuint s = ((const GLuint *) src)[width - 1]; GLuint *d = (GLuint *) dst + width - 1; *d = ( (s & 0xff00ff00) | ((s & 0xff) << 16) | ((s & 0xff0000) >> 16)); } src += src_stride; dst += dst_stride; } } else { for (row = 0; row < height; row++) { const GLuint *s = (const GLuint *) src; GLuint *d = (GLuint *) dst; int i; for (i = 0; i < width; i++) { d[i] = ( (s[i] & 0xff00ff00) | ((s[i] & 0xff) << 16) | ((s[i] & 0xff0000) >> 16)); } src += src_stride; dst += dst_stride; } } } /** * This can be used to convert between most color formats. * * Limitations: * - This function doesn't handle GL_COLOR_INDEX or YCBCR formats. * - This function doesn't handle byte-swapping or transferOps, these should * be handled by the caller. * * \param void_dst The address where converted color data will be stored. * The caller must ensure that the buffer is large enough * to hold the converted pixel data. * \param dst_format The destination color format. It can be a mesa_format * or a mesa_array_format represented as an uint32_t. * \param dst_stride The stride of the destination format in bytes. * \param void_src The address of the source color data to convert. * \param src_format The source color format. It can be a mesa_format * or a mesa_array_format represented as an uint32_t. * \param src_stride The stride of the source format in bytes. * \param width The width, in pixels, of the source image to convert. * \param height The height, in pixels, of the source image to convert. * \param rebase_swizzle A swizzle transform to apply during the conversion, * typically used to match a different internal base * format involved. NULL if no rebase transform is needed * (i.e. the internal base format and the base format of * the dst or the src -depending on whether we are doing * an upload or a download respectively- are the same). */ void _mesa_format_convert(void *void_dst, uint32_t dst_format, size_t dst_stride, void *void_src, uint32_t src_format, size_t src_stride, size_t width, size_t height, uint8_t *rebase_swizzle) { uint8_t *dst = (uint8_t *)void_dst; uint8_t *src = (uint8_t *)void_src; mesa_array_format src_array_format, dst_array_format; bool src_format_is_mesa_array_format, dst_format_is_mesa_array_format; uint8_t src2dst[4], src2rgba[4], rgba2dst[4], dst2rgba[4]; uint8_t rebased_src2rgba[4]; enum mesa_array_format_datatype src_type = 0, dst_type = 0, common_type; bool normalized, dst_integer, src_integer, is_signed; int src_num_channels = 0, dst_num_channels = 0; uint8_t (*tmp_ubyte)[4]; float (*tmp_float)[4]; uint32_t (*tmp_uint)[4]; int bits; size_t row; if (_mesa_format_is_mesa_array_format(src_format)) { src_format_is_mesa_array_format = true; src_array_format = src_format; } else { assert(_mesa_is_format_color_format(src_format)); src_format_is_mesa_array_format = false; src_array_format = _mesa_format_to_array_format(src_format); } if (_mesa_format_is_mesa_array_format(dst_format)) { dst_format_is_mesa_array_format = true; dst_array_format = dst_format; } else { assert(_mesa_is_format_color_format(dst_format)); dst_format_is_mesa_array_format = false; dst_array_format = _mesa_format_to_array_format(dst_format); } /* First we see if we can implement the conversion with a direct pack * or unpack. * * In this case we want to be careful when we need to apply a swizzle to * match an internal base format, since in these cases a simple pack/unpack * to the dst format from the src format may not match the requirements * of the internal base format. For now we decide to be safe and * avoid this path in these scenarios but in the future we may want to * enable it for specific combinations that are known to work. */ if (!rebase_swizzle) { /* Handle the cases where we can directly unpack */ if (!src_format_is_mesa_array_format) { if (dst_array_format == RGBA32_FLOAT) { for (row = 0; row < height; ++row) { _mesa_unpack_rgba_row(src_format, width, src, (float (*)[4])dst); src += src_stride; dst += dst_stride; } return; } else if (dst_array_format == RGBA8_UBYTE) { assert(!_mesa_is_format_integer_color(src_format)); for (row = 0; row < height; ++row) { _mesa_unpack_ubyte_rgba_row(src_format, width, src, (uint8_t (*)[4])dst); src += src_stride; dst += dst_stride; } return; } else if (dst_array_format == RGBA32_UINT && _mesa_is_format_unsigned(src_format)) { assert(_mesa_is_format_integer_color(src_format)); for (row = 0; row < height; ++row) { _mesa_unpack_uint_rgba_row(src_format, width, src, (uint32_t (*)[4])dst); src += src_stride; dst += dst_stride; } return; } } /* Handle the cases where we can directly pack */ if (!dst_format_is_mesa_array_format) { if (src_array_format == RGBA32_FLOAT) { for (row = 0; row < height; ++row) { _mesa_pack_float_rgba_row(dst_format, width, (const float (*)[4])src, dst); src += src_stride; dst += dst_stride; } return; } else if (src_array_format == RGBA8_UBYTE) { assert(!_mesa_is_format_integer_color(dst_format)); if (dst_format == MESA_FORMAT_B8G8R8A8_UNORM) { convert_ubyte_rgba_to_bgra(width, height, src, src_stride, dst, dst_stride); } else { for (row = 0; row < height; ++row) { _mesa_pack_ubyte_rgba_row(dst_format, width, (const uint8_t (*)[4])src, dst); src += src_stride; dst += dst_stride; } } return; } else if (src_array_format == RGBA32_UINT && _mesa_is_format_unsigned(dst_format)) { assert(_mesa_is_format_integer_color(dst_format)); for (row = 0; row < height; ++row) { _mesa_pack_uint_rgba_row(dst_format, width, (const uint32_t (*)[4])src, dst); src += src_stride; dst += dst_stride; } return; } } } /* Handle conversions between array formats */ normalized = false; if (src_array_format) { src_type = _mesa_array_format_get_datatype(src_array_format); src_num_channels = _mesa_array_format_get_num_channels(src_array_format); _mesa_array_format_get_swizzle(src_array_format, src2rgba); normalized = _mesa_array_format_is_normalized(src_array_format); } if (dst_array_format) { dst_type = _mesa_array_format_get_datatype(dst_array_format); dst_num_channels = _mesa_array_format_get_num_channels(dst_array_format); _mesa_array_format_get_swizzle(dst_array_format, dst2rgba); invert_swizzle(rgba2dst, dst2rgba); normalized |= _mesa_array_format_is_normalized(dst_array_format); } if (src_array_format && dst_array_format) { assert(_mesa_array_format_is_normalized(src_array_format) == _mesa_array_format_is_normalized(dst_array_format)); compute_src2dst_component_mapping(src2rgba, rgba2dst, rebase_swizzle, src2dst); for (row = 0; row < height; ++row) { _mesa_swizzle_and_convert(dst, dst_type, dst_num_channels, src, src_type, src_num_channels, src2dst, normalized, width); src += src_stride; dst += dst_stride; } return; } /* At this point, we're fresh out of fast-paths and we need to convert * to float, uint32, or, if we're lucky, uint8. */ dst_integer = false; src_integer = false; if (src_array_format) { if (!_mesa_array_format_is_float(src_array_format) && !_mesa_array_format_is_normalized(src_array_format)) src_integer = true; } else { switch (_mesa_get_format_datatype(src_format)) { case GL_UNSIGNED_INT: case GL_INT: src_integer = true; break; } } /* If the destination format is signed but the source is unsigned, then we * don't loose any data by converting to a signed intermediate format above * and beyond the precision that we loose in the conversion itself. If the * destination is unsigned then, by using an unsigned intermediate format, * we make the conversion function that converts from the source to the * intermediate format take care of truncating at zero. The exception here * is if the intermediate format is float, in which case the first * conversion will leave it signed and the second conversion will truncate * at zero. */ is_signed = false; if (dst_array_format) { if (!_mesa_array_format_is_float(dst_array_format) && !_mesa_array_format_is_normalized(dst_array_format)) dst_integer = true; is_signed = _mesa_array_format_is_signed(dst_array_format); bits = 8 * _mesa_array_format_get_type_size(dst_array_format); } else { switch (_mesa_get_format_datatype(dst_format)) { case GL_UNSIGNED_NORMALIZED: is_signed = false; break; case GL_SIGNED_NORMALIZED: is_signed = true; break; case GL_FLOAT: is_signed = true; break; case GL_UNSIGNED_INT: is_signed = false; dst_integer = true; break; case GL_INT: is_signed = true; dst_integer = true; break; } bits = _mesa_get_format_max_bits(dst_format); } assert(src_integer == dst_integer); if (src_integer && dst_integer) { tmp_uint = malloc(width * height * sizeof(*tmp_uint)); /* The [un]packing functions for unsigned datatypes treat the 32-bit * integer array as signed for signed formats and as unsigned for * unsigned formats. This is a bit of a problem if we ever convert from * a signed to an unsigned format because the unsigned packing function * doesn't know that the input is signed and will treat it as unsigned * and not do the trunctation. The thing that saves us here is that all * of the packed formats are unsigned, so we can just always use * _mesa_swizzle_and_convert for signed formats, which is aware of the * truncation problem. */ common_type = is_signed ? MESA_ARRAY_FORMAT_TYPE_INT : MESA_ARRAY_FORMAT_TYPE_UINT; if (src_array_format) { compute_rebased_rgba_component_mapping(src2rgba, rebase_swizzle, rebased_src2rgba); for (row = 0; row < height; ++row) { _mesa_swizzle_and_convert(tmp_uint + row * width, common_type, 4, src, src_type, src_num_channels, rebased_src2rgba, normalized, width); src += src_stride; } } else { for (row = 0; row < height; ++row) { _mesa_unpack_uint_rgba_row(src_format, width, src, tmp_uint + row * width); if (rebase_swizzle) _mesa_swizzle_and_convert(tmp_uint + row * width, common_type, 4, tmp_uint + row * width, common_type, 4, rebase_swizzle, false, width); src += src_stride; } } /* At this point, we have already done the truncation if the source is * signed but the destination is unsigned, so no need to force the * _mesa_swizzle_and_convert path. */ if (dst_format_is_mesa_array_format) { for (row = 0; row < height; ++row) { _mesa_swizzle_and_convert(dst, dst_type, dst_num_channels, tmp_uint + row * width, common_type, 4, rgba2dst, normalized, width); dst += dst_stride; } } else { for (row = 0; row < height; ++row) { _mesa_pack_uint_rgba_row(dst_format, width, (const uint32_t (*)[4])tmp_uint + row * width, dst); dst += dst_stride; } } free(tmp_uint); } else if (is_signed || bits > 8) { tmp_float = malloc(width * height * sizeof(*tmp_float)); if (src_format_is_mesa_array_format) { compute_rebased_rgba_component_mapping(src2rgba, rebase_swizzle, rebased_src2rgba); for (row = 0; row < height; ++row) { _mesa_swizzle_and_convert(tmp_float + row * width, MESA_ARRAY_FORMAT_TYPE_FLOAT, 4, src, src_type, src_num_channels, rebased_src2rgba, normalized, width); src += src_stride; } } else { for (row = 0; row < height; ++row) { _mesa_unpack_rgba_row(src_format, width, src, tmp_float + row * width); if (rebase_swizzle) _mesa_swizzle_and_convert(tmp_float + row * width, MESA_ARRAY_FORMAT_TYPE_FLOAT, 4, tmp_float + row * width, MESA_ARRAY_FORMAT_TYPE_FLOAT, 4, rebase_swizzle, normalized, width); src += src_stride; } } if (dst_format_is_mesa_array_format) { for (row = 0; row < height; ++row) { _mesa_swizzle_and_convert(dst, dst_type, dst_num_channels, tmp_float + row * width, MESA_ARRAY_FORMAT_TYPE_FLOAT, 4, rgba2dst, normalized, width); dst += dst_stride; } } else { for (row = 0; row < height; ++row) { _mesa_pack_float_rgba_row(dst_format, width, (const float (*)[4])tmp_float + row * width, dst); dst += dst_stride; } } free(tmp_float); } else { tmp_ubyte = malloc(width * height * sizeof(*tmp_ubyte)); if (src_format_is_mesa_array_format) { compute_rebased_rgba_component_mapping(src2rgba, rebase_swizzle, rebased_src2rgba); for (row = 0; row < height; ++row) { _mesa_swizzle_and_convert(tmp_ubyte + row * width, MESA_ARRAY_FORMAT_TYPE_UBYTE, 4, src, src_type, src_num_channels, rebased_src2rgba, normalized, width); src += src_stride; } } else { for (row = 0; row < height; ++row) { _mesa_unpack_ubyte_rgba_row(src_format, width, src, tmp_ubyte + row * width); if (rebase_swizzle) _mesa_swizzle_and_convert(tmp_ubyte + row * width, MESA_ARRAY_FORMAT_TYPE_UBYTE, 4, tmp_ubyte + row * width, MESA_ARRAY_FORMAT_TYPE_UBYTE, 4, rebase_swizzle, normalized, width); src += src_stride; } } if (dst_format_is_mesa_array_format) { for (row = 0; row < height; ++row) { _mesa_swizzle_and_convert(dst, dst_type, dst_num_channels, tmp_ubyte + row * width, MESA_ARRAY_FORMAT_TYPE_UBYTE, 4, rgba2dst, normalized, width); dst += dst_stride; } } else { for (row = 0; row < height; ++row) { _mesa_pack_ubyte_rgba_row(dst_format, width, (const uint8_t (*)[4])tmp_ubyte + row * width, dst); dst += dst_stride; } } free(tmp_ubyte); } } static const uint8_t map_identity[7] = { 0, 1, 2, 3, 4, 5, 6 }; static const uint8_t map_3210[7] = { 3, 2, 1, 0, 4, 5, 6 }; static const uint8_t map_1032[7] = { 1, 0, 3, 2, 4, 5, 6 }; /** * Describes a format as an array format, if possible * * A helper function for figuring out if a (possibly packed) format is * actually an array format and, if so, what the array parameters are. * * \param[in] format the mesa format * \param[out] type the GL type of the array (GL_BYTE, etc.) * \param[out] num_components the number of components in the array * \param[out] swizzle a swizzle describing how to get from the * given format to RGBA * \param[out] normalized for integer formats, this represents whether * the format is a normalized integer or a * regular integer * \return true if this format is an array format, false otherwise */ bool _mesa_format_to_array(mesa_format format, GLenum *type, int *num_components, uint8_t swizzle[4], bool *normalized) { int i; GLuint format_components; uint8_t packed_swizzle[4]; const uint8_t *endian; if (_mesa_is_format_compressed(format)) return false; *normalized = !_mesa_is_format_integer(format); _mesa_uncompressed_format_to_type_and_comps(format, type, &format_components); switch (_mesa_get_format_layout(format)) { case MESA_FORMAT_LAYOUT_ARRAY: *num_components = format_components; _mesa_get_format_swizzle(format, swizzle); return true; case MESA_FORMAT_LAYOUT_PACKED: switch (*type) { case GL_UNSIGNED_BYTE: case GL_BYTE: if (_mesa_get_format_max_bits(format) != 8) return false; *num_components = _mesa_get_format_bytes(format); switch (*num_components) { case 1: endian = map_identity; break; case 2: endian = _mesa_little_endian() ? map_identity : map_1032; break; case 4: endian = _mesa_little_endian() ? map_identity : map_3210; break; default: endian = map_identity; assert(!"Invalid number of components"); } break; case GL_UNSIGNED_SHORT: case GL_SHORT: case GL_HALF_FLOAT: if (_mesa_get_format_max_bits(format) != 16) return false; *num_components = _mesa_get_format_bytes(format) / 2; switch (*num_components) { case 1: endian = map_identity; break; case 2: endian = _mesa_little_endian() ? map_identity : map_1032; break; default: endian = map_identity; assert(!"Invalid number of components"); } break; case GL_UNSIGNED_INT: case GL_INT: case GL_FLOAT: /* This isn't packed. At least not really. */ assert(format_components == 1); if (_mesa_get_format_max_bits(format) != 32) return false; *num_components = format_components; endian = map_identity; break; default: return false; } _mesa_get_format_swizzle(format, packed_swizzle); for (i = 0; i < 4; ++i) swizzle[i] = endian[packed_swizzle[i]]; return true; case MESA_FORMAT_LAYOUT_OTHER: default: return false; } } /** * Attempts to perform the given swizzle-and-convert operation with memcpy * * This function determines if the given swizzle-and-convert operation can * be done with a simple memcpy and, if so, does the memcpy. If not, it * returns false and we fall back to the standard version below. * * The arguments are exactly the same as for _mesa_swizzle_and_convert * * \return true if it successfully performed the swizzle-and-convert * operation with memcpy, false otherwise */ static bool swizzle_convert_try_memcpy(void *dst, enum mesa_array_format_datatype dst_type, int num_dst_channels, const void *src, enum mesa_array_format_datatype src_type, int num_src_channels, const uint8_t swizzle[4], bool normalized, int count) { int i; if (src_type != dst_type) return false; if (num_src_channels != num_dst_channels) return false; for (i = 0; i < num_dst_channels; ++i) if (swizzle[i] != i && swizzle[i] != MESA_FORMAT_SWIZZLE_NONE) return false; memcpy(dst, src, count * num_src_channels * _mesa_array_format_datatype_get_size(src_type)); return true; } /** * Represents a single instance of the standard swizzle-and-convert loop * * Any swizzle-and-convert operation simply loops through the pixels and * performs the transformation operation one pixel at a time. This macro * embodies one instance of the conversion loop. This way we can do all * control flow outside of the loop and allow the compiler to unroll * everything inside the loop. * * Note: This loop is carefully crafted for performance. Be careful when * changing it and run some benchmarks to ensure no performance regressions * if you do. * * \param DST_TYPE the C datatype of the destination * \param DST_CHANS the number of destination channels * \param SRC_TYPE the C datatype of the source * \param SRC_CHANS the number of source channels * \param CONV an expression for converting from the source data, * storred in the variable "src", to the destination * format */ #define SWIZZLE_CONVERT_LOOP(DST_TYPE, DST_CHANS, SRC_TYPE, SRC_CHANS, CONV) \ do { \ int s, j; \ for (s = 0; s < count; ++s) { \ for (j = 0; j < SRC_CHANS; ++j) { \ SRC_TYPE src = typed_src[j]; \ tmp[j] = CONV; \ } \ \ typed_dst[0] = tmp[swizzle_x]; \ if (DST_CHANS > 1) { \ typed_dst[1] = tmp[swizzle_y]; \ if (DST_CHANS > 2) { \ typed_dst[2] = tmp[swizzle_z]; \ if (DST_CHANS > 3) { \ typed_dst[3] = tmp[swizzle_w]; \ } \ } \ } \ typed_src += SRC_CHANS; \ typed_dst += DST_CHANS; \ } \ } while (0) /** * Represents a single swizzle-and-convert operation * * This macro represents everything done in a single swizzle-and-convert * operation. The actual work is done by the SWIZZLE_CONVERT_LOOP macro. * This macro acts as a wrapper that uses a nested switch to ensure that * all looping parameters get unrolled. * * This macro makes assumptions about variables etc. in the calling * function. Changes to _mesa_swizzle_and_convert may require changes to * this macro. * * \param DST_TYPE the C datatype of the destination * \param SRC_TYPE the C datatype of the source * \param CONV an expression for converting from the source data, * storred in the variable "src", to the destination * format */ #define SWIZZLE_CONVERT(DST_TYPE, SRC_TYPE, CONV) \ do { \ const uint8_t swizzle_x = swizzle[0]; \ const uint8_t swizzle_y = swizzle[1]; \ const uint8_t swizzle_z = swizzle[2]; \ const uint8_t swizzle_w = swizzle[3]; \ const SRC_TYPE *typed_src = void_src; \ DST_TYPE *typed_dst = void_dst; \ DST_TYPE tmp[7]; \ tmp[4] = 0; \ tmp[5] = one; \ switch (num_dst_channels) { \ case 1: \ switch (num_src_channels) { \ case 1: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 1, SRC_TYPE, 1, CONV); \ break; \ case 2: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 1, SRC_TYPE, 2, CONV); \ break; \ case 3: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 1, SRC_TYPE, 3, CONV); \ break; \ case 4: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 1, SRC_TYPE, 4, CONV); \ break; \ } \ break; \ case 2: \ switch (num_src_channels) { \ case 1: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 2, SRC_TYPE, 1, CONV); \ break; \ case 2: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 2, SRC_TYPE, 2, CONV); \ break; \ case 3: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 2, SRC_TYPE, 3, CONV); \ break; \ case 4: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 2, SRC_TYPE, 4, CONV); \ break; \ } \ break; \ case 3: \ switch (num_src_channels) { \ case 1: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 3, SRC_TYPE, 1, CONV); \ break; \ case 2: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 3, SRC_TYPE, 2, CONV); \ break; \ case 3: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 3, SRC_TYPE, 3, CONV); \ break; \ case 4: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 3, SRC_TYPE, 4, CONV); \ break; \ } \ break; \ case 4: \ switch (num_src_channels) { \ case 1: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 4, SRC_TYPE, 1, CONV); \ break; \ case 2: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 4, SRC_TYPE, 2, CONV); \ break; \ case 3: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 4, SRC_TYPE, 3, CONV); \ break; \ case 4: \ SWIZZLE_CONVERT_LOOP(DST_TYPE, 4, SRC_TYPE, 4, CONV); \ break; \ } \ break; \ } \ } while (0) static void convert_float(void *void_dst, int num_dst_channels, const void *void_src, GLenum src_type, int num_src_channels, const uint8_t swizzle[4], bool normalized, int count) { const float one = 1.0f; switch (src_type) { case MESA_ARRAY_FORMAT_TYPE_FLOAT: SWIZZLE_CONVERT(float, float, src); break; case MESA_ARRAY_FORMAT_TYPE_HALF: SWIZZLE_CONVERT(float, uint16_t, _mesa_half_to_float(src)); break; case MESA_ARRAY_FORMAT_TYPE_UBYTE: if (normalized) { SWIZZLE_CONVERT(float, uint8_t, _mesa_unorm_to_float(src, 8)); } else { SWIZZLE_CONVERT(float, uint8_t, src); } break; case MESA_ARRAY_FORMAT_TYPE_BYTE: if (normalized) { SWIZZLE_CONVERT(float, int8_t, _mesa_snorm_to_float(src, 8)); } else { SWIZZLE_CONVERT(float, int8_t, src); } break; case MESA_ARRAY_FORMAT_TYPE_USHORT: if (normalized) { SWIZZLE_CONVERT(float, uint16_t, _mesa_unorm_to_float(src, 16)); } else { SWIZZLE_CONVERT(float, uint16_t, src); } break; case MESA_ARRAY_FORMAT_TYPE_SHORT: if (normalized) { SWIZZLE_CONVERT(float, int16_t, _mesa_snorm_to_float(src, 16)); } else { SWIZZLE_CONVERT(float, int16_t, src); } break; case MESA_ARRAY_FORMAT_TYPE_UINT: if (normalized) { SWIZZLE_CONVERT(float, uint32_t, _mesa_unorm_to_float(src, 32)); } else { SWIZZLE_CONVERT(float, uint32_t, src); } break; case MESA_ARRAY_FORMAT_TYPE_INT: if (normalized) { SWIZZLE_CONVERT(float, int32_t, _mesa_snorm_to_float(src, 32)); } else { SWIZZLE_CONVERT(float, int32_t, src); } break; default: assert(!"Invalid channel type combination"); } } static void convert_half_float(void *void_dst, int num_dst_channels, const void *void_src, GLenum src_type, int num_src_channels, const uint8_t swizzle[4], bool normalized, int count) { const uint16_t one = _mesa_float_to_half(1.0f); switch (src_type) { case MESA_ARRAY_FORMAT_TYPE_FLOAT: SWIZZLE_CONVERT(uint16_t, float, _mesa_float_to_half(src)); break; case MESA_ARRAY_FORMAT_TYPE_HALF: SWIZZLE_CONVERT(uint16_t, uint16_t, src); break; case MESA_ARRAY_FORMAT_TYPE_UBYTE: if (normalized) { SWIZZLE_CONVERT(uint16_t, uint8_t, _mesa_unorm_to_half(src, 8)); } else { SWIZZLE_CONVERT(uint16_t, uint8_t, _mesa_float_to_half(src)); } break; case MESA_ARRAY_FORMAT_TYPE_BYTE: if (normalized) { SWIZZLE_CONVERT(uint16_t, int8_t, _mesa_snorm_to_half(src, 8)); } else { SWIZZLE_CONVERT(uint16_t, int8_t, _mesa_float_to_half(src)); } break; case MESA_ARRAY_FORMAT_TYPE_USHORT: if (normalized) { SWIZZLE_CONVERT(uint16_t, uint16_t, _mesa_unorm_to_half(src, 16)); } else { SWIZZLE_CONVERT(uint16_t, uint16_t, _mesa_float_to_half(src)); } break; case MESA_ARRAY_FORMAT_TYPE_SHORT: if (normalized) { SWIZZLE_CONVERT(uint16_t, int16_t, _mesa_snorm_to_half(src, 16)); } else { SWIZZLE_CONVERT(uint16_t, int16_t, _mesa_float_to_half(src)); } break; case MESA_ARRAY_FORMAT_TYPE_UINT: if (normalized) { SWIZZLE_CONVERT(uint16_t, uint32_t, _mesa_unorm_to_half(src, 32)); } else { SWIZZLE_CONVERT(uint16_t, uint32_t, _mesa_float_to_half(src)); } break; case MESA_ARRAY_FORMAT_TYPE_INT: if (normalized) { SWIZZLE_CONVERT(uint16_t, int32_t, _mesa_snorm_to_half(src, 32)); } else { SWIZZLE_CONVERT(uint16_t, int32_t, _mesa_float_to_half(src)); } break; default: assert(!"Invalid channel type combination"); } } static void convert_ubyte(void *void_dst, int num_dst_channels, const void *void_src, GLenum src_type, int num_src_channels, const uint8_t swizzle[4], bool normalized, int count) { const uint8_t one = normalized ? UINT8_MAX : 1; switch (src_type) { case MESA_ARRAY_FORMAT_TYPE_FLOAT: if (normalized) { SWIZZLE_CONVERT(uint8_t, float, _mesa_float_to_unorm(src, 8)); } else { SWIZZLE_CONVERT(uint8_t, float, _mesa_float_to_unsigned(src, 8)); } break; case MESA_ARRAY_FORMAT_TYPE_HALF: if (normalized) { SWIZZLE_CONVERT(uint8_t, uint16_t, _mesa_half_to_unorm(src, 8)); } else { SWIZZLE_CONVERT(uint8_t, uint16_t, _mesa_half_to_unsigned(src, 8)); } break; case MESA_ARRAY_FORMAT_TYPE_UBYTE: SWIZZLE_CONVERT(uint8_t, uint8_t, src); break; case MESA_ARRAY_FORMAT_TYPE_BYTE: if (normalized) { SWIZZLE_CONVERT(uint8_t, int8_t, _mesa_snorm_to_unorm(src, 8, 8)); } else { SWIZZLE_CONVERT(uint8_t, int8_t, _mesa_signed_to_unsigned(src, 8)); } break; case MESA_ARRAY_FORMAT_TYPE_USHORT: if (normalized) { SWIZZLE_CONVERT(uint8_t, uint16_t, _mesa_unorm_to_unorm(src, 16, 8)); } else { SWIZZLE_CONVERT(uint8_t, uint16_t, _mesa_unsigned_to_unsigned(src, 8)); } break; case MESA_ARRAY_FORMAT_TYPE_SHORT: if (normalized) { SWIZZLE_CONVERT(uint8_t, int16_t, _mesa_snorm_to_unorm(src, 16, 8)); } else { SWIZZLE_CONVERT(uint8_t, int16_t, _mesa_signed_to_unsigned(src, 8)); } break; case MESA_ARRAY_FORMAT_TYPE_UINT: if (normalized) { SWIZZLE_CONVERT(uint8_t, uint32_t, _mesa_unorm_to_unorm(src, 32, 8)); } else { SWIZZLE_CONVERT(uint8_t, uint32_t, _mesa_unsigned_to_unsigned(src, 8)); } break; case MESA_ARRAY_FORMAT_TYPE_INT: if (normalized) { SWIZZLE_CONVERT(uint8_t, int32_t, _mesa_snorm_to_unorm(src, 32, 8)); } else { SWIZZLE_CONVERT(uint8_t, int32_t, _mesa_signed_to_unsigned(src, 8)); } break; default: assert(!"Invalid channel type combination"); } } static void convert_byte(void *void_dst, int num_dst_channels, const void *void_src, GLenum src_type, int num_src_channels, const uint8_t swizzle[4], bool normalized, int count) { const int8_t one = normalized ? INT8_MAX : 1; switch (src_type) { case MESA_ARRAY_FORMAT_TYPE_FLOAT: if (normalized) { SWIZZLE_CONVERT(uint8_t, float, _mesa_float_to_snorm(src, 8)); } else { SWIZZLE_CONVERT(uint8_t, float, _mesa_float_to_signed(src, 8)); } break; case MESA_ARRAY_FORMAT_TYPE_HALF: if (normalized) { SWIZZLE_CONVERT(uint8_t, uint16_t, _mesa_half_to_snorm(src, 8)); } else { SWIZZLE_CONVERT(uint8_t, uint16_t, _mesa_half_to_signed(src, 8)); } break; case MESA_ARRAY_FORMAT_TYPE_UBYTE: if (normalized) { SWIZZLE_CONVERT(int8_t, uint8_t, _mesa_unorm_to_snorm(src, 8, 8)); } else { SWIZZLE_CONVERT(int8_t, uint8_t, _mesa_unsigned_to_signed(src, 8)); } break; case MESA_ARRAY_FORMAT_TYPE_BYTE: SWIZZLE_CONVERT(int8_t, int8_t, src); break; case MESA_ARRAY_FORMAT_TYPE_USHORT: if (normalized) { SWIZZLE_CONVERT(int8_t, uint16_t, _mesa_unorm_to_snorm(src, 16, 8)); } else { SWIZZLE_CONVERT(int8_t, uint16_t, _mesa_unsigned_to_signed(src, 8)); } break; case MESA_ARRAY_FORMAT_TYPE_SHORT: if (normalized) { SWIZZLE_CONVERT(int8_t, int16_t, _mesa_snorm_to_snorm(src, 16, 8)); } else { SWIZZLE_CONVERT(int8_t, int16_t, _mesa_signed_to_signed(src, 8)); } break; case MESA_ARRAY_FORMAT_TYPE_UINT: if (normalized) { SWIZZLE_CONVERT(int8_t, uint32_t, _mesa_unorm_to_snorm(src, 32, 8)); } else { SWIZZLE_CONVERT(int8_t, uint32_t, _mesa_unsigned_to_signed(src, 8)); } break; case MESA_ARRAY_FORMAT_TYPE_INT: if (normalized) { SWIZZLE_CONVERT(int8_t, int32_t, _mesa_snorm_to_snorm(src, 32, 8)); } else { SWIZZLE_CONVERT(int8_t, int32_t, _mesa_signed_to_signed(src, 8)); } break; default: assert(!"Invalid channel type combination"); } } static void convert_ushort(void *void_dst, int num_dst_channels, const void *void_src, GLenum src_type, int num_src_channels, const uint8_t swizzle[4], bool normalized, int count) { const uint16_t one = normalized ? UINT16_MAX : 1; switch (src_type) { case MESA_ARRAY_FORMAT_TYPE_FLOAT: if (normalized) { SWIZZLE_CONVERT(uint16_t, float, _mesa_float_to_unorm(src, 16)); } else { SWIZZLE_CONVERT(uint16_t, float, _mesa_float_to_unsigned(src, 16)); } break; case MESA_ARRAY_FORMAT_TYPE_HALF: if (normalized) { SWIZZLE_CONVERT(uint16_t, uint16_t, _mesa_half_to_unorm(src, 16)); } else { SWIZZLE_CONVERT(uint16_t, uint16_t, _mesa_half_to_unsigned(src, 16)); } break; case MESA_ARRAY_FORMAT_TYPE_UBYTE: if (normalized) { SWIZZLE_CONVERT(uint16_t, uint8_t, _mesa_unorm_to_unorm(src, 8, 16)); } else { SWIZZLE_CONVERT(uint16_t, uint8_t, src); } break; case MESA_ARRAY_FORMAT_TYPE_BYTE: if (normalized) { SWIZZLE_CONVERT(uint16_t, int8_t, _mesa_snorm_to_unorm(src, 8, 16)); } else { SWIZZLE_CONVERT(uint16_t, int8_t, _mesa_signed_to_unsigned(src, 16)); } break; case MESA_ARRAY_FORMAT_TYPE_USHORT: SWIZZLE_CONVERT(uint16_t, uint16_t, src); break; case MESA_ARRAY_FORMAT_TYPE_SHORT: if (normalized) { SWIZZLE_CONVERT(uint16_t, int16_t, _mesa_snorm_to_unorm(src, 16, 16)); } else { SWIZZLE_CONVERT(uint16_t, int16_t, _mesa_signed_to_unsigned(src, 16)); } break; case MESA_ARRAY_FORMAT_TYPE_UINT: if (normalized) { SWIZZLE_CONVERT(uint16_t, uint32_t, _mesa_unorm_to_unorm(src, 32, 16)); } else { SWIZZLE_CONVERT(uint16_t, uint32_t, _mesa_unsigned_to_unsigned(src, 16)); } break; case MESA_ARRAY_FORMAT_TYPE_INT: if (normalized) { SWIZZLE_CONVERT(uint16_t, int32_t, _mesa_snorm_to_unorm(src, 32, 16)); } else { SWIZZLE_CONVERT(uint16_t, int32_t, _mesa_signed_to_unsigned(src, 16)); } break; default: assert(!"Invalid channel type combination"); } } static void convert_short(void *void_dst, int num_dst_channels, const void *void_src, GLenum src_type, int num_src_channels, const uint8_t swizzle[4], bool normalized, int count) { const int16_t one = normalized ? INT16_MAX : 1; switch (src_type) { case MESA_ARRAY_FORMAT_TYPE_FLOAT: if (normalized) { SWIZZLE_CONVERT(uint16_t, float, _mesa_float_to_snorm(src, 16)); } else { SWIZZLE_CONVERT(uint16_t, float, _mesa_float_to_signed(src, 16)); } break; case MESA_ARRAY_FORMAT_TYPE_HALF: if (normalized) { SWIZZLE_CONVERT(uint16_t, uint16_t, _mesa_half_to_snorm(src, 16)); } else { SWIZZLE_CONVERT(uint16_t, uint16_t, _mesa_half_to_signed(src, 16)); } break; case MESA_ARRAY_FORMAT_TYPE_UBYTE: if (normalized) { SWIZZLE_CONVERT(int16_t, uint8_t, _mesa_unorm_to_snorm(src, 8, 16)); } else { SWIZZLE_CONVERT(int16_t, uint8_t, src); } break; case MESA_ARRAY_FORMAT_TYPE_BYTE: if (normalized) { SWIZZLE_CONVERT(int16_t, int8_t, _mesa_snorm_to_snorm(src, 8, 16)); } else { SWIZZLE_CONVERT(int16_t, int8_t, src); } break; case MESA_ARRAY_FORMAT_TYPE_USHORT: if (normalized) { SWIZZLE_CONVERT(int16_t, uint16_t, _mesa_unorm_to_snorm(src, 16, 16)); } else { SWIZZLE_CONVERT(int16_t, uint16_t, _mesa_unsigned_to_signed(src, 16)); } break; case MESA_ARRAY_FORMAT_TYPE_SHORT: SWIZZLE_CONVERT(int16_t, int16_t, src); break; case MESA_ARRAY_FORMAT_TYPE_UINT: if (normalized) { SWIZZLE_CONVERT(int16_t, uint32_t, _mesa_unorm_to_snorm(src, 32, 16)); } else { SWIZZLE_CONVERT(int16_t, uint32_t, _mesa_unsigned_to_signed(src, 16)); } break; case MESA_ARRAY_FORMAT_TYPE_INT: if (normalized) { SWIZZLE_CONVERT(int16_t, int32_t, _mesa_snorm_to_snorm(src, 32, 16)); } else { SWIZZLE_CONVERT(int16_t, int32_t, _mesa_signed_to_signed(src, 16)); } break; default: assert(!"Invalid channel type combination"); } } static void convert_uint(void *void_dst, int num_dst_channels, const void *void_src, GLenum src_type, int num_src_channels, const uint8_t swizzle[4], bool normalized, int count) { const uint32_t one = normalized ? UINT32_MAX : 1; switch (src_type) { case MESA_ARRAY_FORMAT_TYPE_FLOAT: if (normalized) { SWIZZLE_CONVERT(uint32_t, float, _mesa_float_to_unorm(src, 32)); } else { SWIZZLE_CONVERT(uint32_t, float, _mesa_float_to_unsigned(src, 32)); } break; case MESA_ARRAY_FORMAT_TYPE_HALF: if (normalized) { SWIZZLE_CONVERT(uint32_t, uint16_t, _mesa_half_to_unorm(src, 32)); } else { SWIZZLE_CONVERT(uint32_t, uint16_t, _mesa_half_to_unsigned(src, 32)); } break; case MESA_ARRAY_FORMAT_TYPE_UBYTE: if (normalized) { SWIZZLE_CONVERT(uint32_t, uint8_t, _mesa_unorm_to_unorm(src, 8, 32)); } else { SWIZZLE_CONVERT(uint32_t, uint8_t, src); } break; case MESA_ARRAY_FORMAT_TYPE_BYTE: if (normalized) { SWIZZLE_CONVERT(uint32_t, int8_t, _mesa_snorm_to_unorm(src, 8, 32)); } else { SWIZZLE_CONVERT(uint32_t, int8_t, _mesa_signed_to_unsigned(src, 32)); } break; case MESA_ARRAY_FORMAT_TYPE_USHORT: if (normalized) { SWIZZLE_CONVERT(uint32_t, uint16_t, _mesa_unorm_to_unorm(src, 16, 32)); } else { SWIZZLE_CONVERT(uint32_t, uint16_t, src); } break; case MESA_ARRAY_FORMAT_TYPE_SHORT: if (normalized) { SWIZZLE_CONVERT(uint32_t, int16_t, _mesa_snorm_to_unorm(src, 16, 32)); } else { SWIZZLE_CONVERT(uint32_t, int16_t, _mesa_signed_to_unsigned(src, 32)); } break; case MESA_ARRAY_FORMAT_TYPE_UINT: SWIZZLE_CONVERT(uint32_t, uint32_t, src); break; case MESA_ARRAY_FORMAT_TYPE_INT: if (normalized) { SWIZZLE_CONVERT(uint32_t, int32_t, _mesa_snorm_to_unorm(src, 32, 32)); } else { SWIZZLE_CONVERT(uint32_t, int32_t, _mesa_signed_to_unsigned(src, 32)); } break; default: assert(!"Invalid channel type combination"); } } static void convert_int(void *void_dst, int num_dst_channels, const void *void_src, GLenum src_type, int num_src_channels, const uint8_t swizzle[4], bool normalized, int count) { const int32_t one = normalized ? INT32_MAX : 1; switch (src_type) { case MESA_ARRAY_FORMAT_TYPE_FLOAT: if (normalized) { SWIZZLE_CONVERT(uint32_t, float, _mesa_float_to_snorm(src, 32)); } else { SWIZZLE_CONVERT(uint32_t, float, _mesa_float_to_signed(src, 32)); } break; case MESA_ARRAY_FORMAT_TYPE_HALF: if (normalized) { SWIZZLE_CONVERT(uint32_t, uint16_t, _mesa_half_to_snorm(src, 32)); } else { SWIZZLE_CONVERT(uint32_t, uint16_t, _mesa_half_to_signed(src, 32)); } break; case MESA_ARRAY_FORMAT_TYPE_UBYTE: if (normalized) { SWIZZLE_CONVERT(int32_t, uint8_t, _mesa_unorm_to_snorm(src, 8, 32)); } else { SWIZZLE_CONVERT(int32_t, uint8_t, src); } break; case MESA_ARRAY_FORMAT_TYPE_BYTE: if (normalized) { SWIZZLE_CONVERT(int32_t, int8_t, _mesa_snorm_to_snorm(src, 8, 32)); } else { SWIZZLE_CONVERT(int32_t, int8_t, src); } break; case MESA_ARRAY_FORMAT_TYPE_USHORT: if (normalized) { SWIZZLE_CONVERT(int32_t, uint16_t, _mesa_unorm_to_snorm(src, 16, 32)); } else { SWIZZLE_CONVERT(int32_t, uint16_t, src); } break; case MESA_ARRAY_FORMAT_TYPE_SHORT: if (normalized) { SWIZZLE_CONVERT(int32_t, int16_t, _mesa_snorm_to_snorm(src, 16, 32)); } else { SWIZZLE_CONVERT(int32_t, int16_t, src); } break; case MESA_ARRAY_FORMAT_TYPE_UINT: if (normalized) { SWIZZLE_CONVERT(int32_t, uint32_t, _mesa_unorm_to_snorm(src, 32, 32)); } else { SWIZZLE_CONVERT(int32_t, uint32_t, _mesa_unsigned_to_signed(src, 32)); } break; case MESA_ARRAY_FORMAT_TYPE_INT: SWIZZLE_CONVERT(int32_t, int32_t, src); break; default: assert(!"Invalid channel type combination"); } } /** * Convert between array-based color formats. * * Most format conversion operations required by GL can be performed by * converting one channel at a time, shuffling the channels around, and * optionally filling missing channels with zeros and ones. This function * does just that in a general, yet efficient, way. * * The swizzle parameter is an array of 4 numbers (see * _mesa_get_format_swizzle) that describes where each channel in the * destination should come from in the source. If swizzle[i] < 4 then it * means that dst[i] = CONVERT(src[swizzle[i]]). If swizzle[i] is * MESA_FORMAT_SWIZZLE_ZERO or MESA_FORMAT_SWIZZLE_ONE, the corresponding * dst[i] will be filled with the appropreate representation of zero or one * respectively. * * Under most circumstances, the source and destination images must be * different as no care is taken not to clobber one with the other. * However, if they have the same number of bits per pixel, it is safe to * do an in-place conversion. * * \param[out] dst pointer to where the converted data should * be stored * * \param[in] dst_type the destination GL type of the converted * data (GL_BYTE, etc.) * * \param[in] num_dst_channels the number of channels in the converted * data * * \param[in] src pointer to the source data * * \param[in] src_type the GL type of the source data (GL_BYTE, * etc.) * * \param[in] num_src_channels the number of channels in the source data * (the number of channels total, not just * the number used) * * \param[in] swizzle describes how to get the destination data * from the source data. * * \param[in] normalized for integer types, this indicates whether * the data should be considered as integers * or as normalized integers; * * \param[in] count the number of pixels to convert */ void _mesa_swizzle_and_convert(void *void_dst, enum mesa_array_format_datatype dst_type, int num_dst_channels, const void *void_src, enum mesa_array_format_datatype src_type, int num_src_channels, const uint8_t swizzle[4], bool normalized, int count) { if (swizzle_convert_try_memcpy(void_dst, dst_type, num_dst_channels, void_src, src_type, num_src_channels, swizzle, normalized, count)) return; switch (dst_type) { case MESA_ARRAY_FORMAT_TYPE_FLOAT: convert_float(void_dst, num_dst_channels, void_src, src_type, num_src_channels, swizzle, normalized, count); break; case MESA_ARRAY_FORMAT_TYPE_HALF: convert_half_float(void_dst, num_dst_channels, void_src, src_type, num_src_channels, swizzle, normalized, count); break; case MESA_ARRAY_FORMAT_TYPE_UBYTE: convert_ubyte(void_dst, num_dst_channels, void_src, src_type, num_src_channels, swizzle, normalized, count); break; case MESA_ARRAY_FORMAT_TYPE_BYTE: convert_byte(void_dst, num_dst_channels, void_src, src_type, num_src_channels, swizzle, normalized, count); break; case MESA_ARRAY_FORMAT_TYPE_USHORT: convert_ushort(void_dst, num_dst_channels, void_src, src_type, num_src_channels, swizzle, normalized, count); break; case MESA_ARRAY_FORMAT_TYPE_SHORT: convert_short(void_dst, num_dst_channels, void_src, src_type, num_src_channels, swizzle, normalized, count); break; case MESA_ARRAY_FORMAT_TYPE_UINT: convert_uint(void_dst, num_dst_channels, void_src, src_type, num_src_channels, swizzle, normalized, count); break; case MESA_ARRAY_FORMAT_TYPE_INT: convert_int(void_dst, num_dst_channels, void_src, src_type, num_src_channels, swizzle, normalized, count); break; default: assert(!"Invalid channel type"); } }