/* See LICENSE file for copyright and license details. */ #ifndef LIBGLITTER_H #define LIBGLITTER_H #include #include /** * The application will use `double`-typed rasters */ #define LIBGLITTER_FEATURE_DOUBLE_TYPE UINT64_C(0x0000000000000001) /** * The application will use `float`-typed rasters */ #define LIBGLITTER_FEATURE_FLOAT_TYPE UINT64_C(0x0000000000000002) /** * The application will use `uint64_t`-typed rasters */ #define LIBGLITTER_FEATURE_UINT64_TYPE UINT64_C(0x0000000000000004) /** * The application will use `uint32_t`-typed rasters */ #define LIBGLITTER_FEATURE_UINT32_TYPE UINT64_C(0x0000000000000008) /** * The application will use `uint16_t`-typed rasters */ #define LIBGLITTER_FEATURE_UINT16_TYPE UINT64_C(0x0000000000000010) /** * The application will use `uint8_t`-typed rasters */ #define LIBGLITTER_FEATURE_UINT8_TYPE UINT64_C(0x0000000000000020) /** * The allocation will use at least one of the functions * `libglitter_compose_double`, * `libglitter_compose_float`, * `libglitter_compose_uint64`, * `libglitter_compose_uint32`, * `libglitter_compose_uint16`, and * `libglitter_compose_uint8` */ #define LIBGLITTER_FEATURE_COMPOSE UINT64_C(0x0000000000000040) /** * The allocation will use at least one of the functions * `libglitter_desaturate_double`, and * `libglitter_desaturate_float` */ #define LIBGLITTER_FEATURE_DESATURATION UINT64_C(0x0000000000000080) /** * The allocation will use at least one of the functions * `libglitter_colour_space_convert_rasters_double`, and * `libglitter_colour_space_convert_rasters_float` */ #define LIBGLITTER_FEATURE_COLOUR_SPACE UINT64_C(0x0000000000000100) /** * The CIE xyY values of the D65 illuminant */ #define LIBGLITTER_ILLUMINANT_D65\ 0.312726871026564878786047074755,\ 0.329023206641284038376227272238, 1.0\ /** * Rendering context for an input raster's specifications * * Render context's are thread-safe, however updating them are not */ typedef struct libglitter_render_context LIBGLITTER_RENDER_CONTEXT; /** * Output primary colour */ enum libglitter_colour { /** * Red primary colour */ LIBGLITTER_CHANNEL_RED = 0, /** * Green primary colour */ LIBGLITTER_CHANNEL_GREEN = 1, /** * Blue primary colour */ LIBGLITTER_CHANNEL_BLUE = 2 }; /** * Attempt to enable hardware acceleration * * Currently this function doesn't do anything but call the * callback function and return 0; it is provided for application * to use know and get hardware acceleration when it is implemented * * @param features Set of features to enable hardware acceleration * for, unrecognised bits are silently ignored. * Recognised bit values are: * - LIBGLITTER_FEATURE_DOUBLE_TYPE, * - LIBGLITTER_FEATURE_FLOAT_TYPE, * - LIBGLITTER_FEATURE_UINT64_TYPE, * - LIBGLITTER_FEATURE_UINT32_TYPE, * - LIBGLITTER_FEATURE_UINT16_TYPE, * - LIBGLITTER_FEATURE_UINT8_TYPE, * - LIBGLITTER_FEATURE_COMPOSE, * - LIBGLITTER_FEATURE_DESATURATION, and * - LIBGLITTER_FEATURE_COLOUR_SPACE. * @param async Whether the function shall return immediately * rather than when complete * @param callback Callback function that is called at function * completion, the first argument will be either * 1 on success with hardware acceleration enabled, * 0 on success without hardware acceleration enabled, * or -1 on failure; the second argument will be 0 * on success or an error code on failure; the third * argument will be `userdata`. This argument may * also be `NULL` if no callback function shall be * called * @param userdata User-specific data to pass into `callback`, may be `NULL` * @return 1 on success with hardware acceleration enabled, * 0 on success without hardware acceleration enabled, * or -1 on failure */ int libglitter_enable_acceleration(uint64_t, int, void (*)(int, int, void *), void *); /** * Create a render context for an input raster's specifications * * Render context's are thread-safe * * @param noutputs The number of output buffers * @param rowsize The number of cells per row in the input raster * @param widthmul The horizontal number of cells per pixel in the input raster * @param heightmul The vertical number of cells per pixel in the input raster * @param cellmap Subpixel map of size `heightmul * widthmul` that maps a * cell for a pixel in the input raster to an output raster * (the output raster's index); this is row-major map, and * each valid value must appear at least once * @param ncellvalues For each `i` in [0, `noutputs`), `ncellvalues[i]` * shall be the number of times the value `i` occurs * in `cellmap` * @return A render context that can be deallocate using * `libglitter_free_render_context` or updated with * `libglitter_update_render_context`; `NULL` on failure * * @throws ENOMEM Couldn't not allocate enough memory * * If `noutputs` is 3 and either `widthmul` or `heightmul` is 3 and * the other one is 1, `ncellvalues` will not be used as it is preknown * that all its values are 1 */ LIBGLITTER_RENDER_CONTEXT *libglitter_create_render_context(size_t, size_t, size_t, size_t, const uint8_t *, const uint8_t *); /** * Update a render context (created by `libglitter_create_render_context`) * for a new input raster buffer * * Updating a render context is not thread-safe * * @param this The render context to refresh * @param rowsize The number of cells per row in the input raster */ void libglitter_update_render_context(LIBGLITTER_RENDER_CONTEXT *, size_t); /** * Deallocates a render context (created by `libglitter_create_render_context`) * * @param this The render context to deallocate */ void libglitter_free_render_context(LIBGLITTER_RENDER_CONTEXT *); /** * Create one raster per monitor colour from a raster of * subpixels (which may be further divided in the raster) * * Note that this function does not regard the colour * model's transfer function: it does not directly give * you appropriate sRGB values * * @param outputs Array of output rasters, one for each subpixel colour. * The function may change the offset for each raster, * as such, the given pointer shall not be used anywhere * else during the execution of the function and the * inner pointers shall be considered undefined after * the execution of the function. * @param input Input raster; cells are adjacent * @param output_rowsize The number of cells in a row in each output raster * @param output_cellsize The number of values stored in each output raster, * between each cell, plus 1 (that is, the number of * values per cell) * @param width The horizontal number of pixels in the rasters * @param height The vertical number of pixels in the rasters * @param render_ctx Rendering context created for the input raster's * specification */ void libglitter_compose_double(double **, const double *restrict, size_t, size_t, size_t, size_t, const LIBGLITTER_RENDER_CONTEXT *); /** * This value is identical to `libglitter_compose_double`, * apart from it parameter types, see `libglitter_compose_double` * for details about this function */ void libglitter_compose_float(float **, const float *restrict, size_t, size_t, size_t, size_t, const LIBGLITTER_RENDER_CONTEXT *); /** * Create one raster per monitor colour from a raster of * subpixels (which may be further divided in the raster) * * Note that this function does not regard the colour * model's transfer function: it does not directly give * you appropriate sRGB values * * @param outputs Array of output rasters, one for each subpixel colour. * The function may change the offset for each raster, * as such, the given pointer shall not be used anywhere * else during the execution of the function and the * inner pointers shall be considered undefined after * the execution of the function. * @param input Input raster; cells are adjacent * @param output_rowsize The number of cells in a row in each output raster * @param output_cellsize The number of values stored in each output raster, * between each cell, plus 1 (that is, the number of * values per cell) * @param width The horizontal number of pixels in the rasters * @param height The vertical number of pixels in the rasters * @param render_ctx Rendering context created for the input raster's * specification */ void libglitter_compose_uint64(uint64_t **, const uint64_t *restrict, size_t, size_t, size_t, size_t, const LIBGLITTER_RENDER_CONTEXT *); /** * This value is identical to `libglitter_compose_uint64`, * apart from it parameter types, see `libglitter_compose_uint64` * for details about this function */ void libglitter_compose_uint32(uint32_t **, const uint32_t *restrict, size_t, size_t, size_t, size_t, const LIBGLITTER_RENDER_CONTEXT *); /** * This value is identical to `libglitter_compose_uint64`, * apart from it parameter types, see `libglitter_compose_uint64` * for details about this function */ void libglitter_compose_uint16(uint16_t **, const uint16_t *restrict, size_t, size_t, size_t, size_t, const LIBGLITTER_RENDER_CONTEXT *); /** * This value is identical to `libglitter_compose_uint64`, * apart from it parameter types, see `libglitter_compose_uint64` * for details about this function */ void libglitter_compose_uint8(uint8_t **, const uint8_t *restrict, size_t, size_t, size_t, size_t, const LIBGLITTER_RENDER_CONTEXT *); /** * Reorders a set of three rasters * * When the function `libglitter_create_render_context` is called, * the parameter named `cellmap` contains the values 0, 1, and 2, * representing different channels: indices in the raster array. * The values are not necessarily 0 for red, 1 for green, and 2 for blue, * but this function lets the user reorder the rasters so that before * calling this function the rasters may be in this order, but when * call a `libglitter_compose_*` function after calling this function, * that function will write to the correct rasters * * @param rasters The array of the three rasters, on input the rasters * shall be in the order (0) red, (1) green, (2) blue; * the function will reorder them * @param colour1 The colour of the channel value 0 represents in `cellmap` * @param colour2 The colour of the channel value 1 represents in `cellmap` * @param colour3 The colour of the channel value 2 represents in `cellmap` * * The values `colour1`, `colour2`, `colour3` must be valid but distinct */ void libglitter_reorder_rasters(void **, enum libglitter_colour, enum libglitter_colour, enum libglitter_colour); /** * Splits a `uint64_t` raster into one `uint16_t` raster per channel * * @param rasters Output array for the rasters, they will be in the * order (0) red, (1) green, (2) blue * @param alphap Output parameter for the alpha mask raster, or `NULL` * @param raster The raster that is being split * @param red The value `0xFFFF` shifted such that value * expresses pure red (closest primary colour) * @param green The value `0xFFFF` shifted such that value * expresses pure green (closest primary colour) * @param blue The value `0xFFFF` shifted such that value * expresses pure blue (closest primary colour) */ void libglitter_split_uint64_raster(uint16_t *[3], uint16_t **, uint64_t *, uint64_t, uint64_t, uint64_t); /** * Splits a `uint32_t` raster into one `uint8_t` raster per channel * * @param rasters Output array for the rasters, they will be in the * order (0) red, (1) green, (2) blue * @param alphap Output parameter for the alpha mask raster, or `NULL` * @param raster The raster that is being split * @param red The value `0xFF` shifted such that value * expresses pure red (closest primary colour) * @param green The value `0xFF` shifted such that value * expresses pure green (closest primary colour) * @param blue The value `0xFF` shifted such that value * expresses pure blue (closest primary colour) */ void libglitter_split_uint32_raster(uint8_t *[3], uint8_t **, uint32_t *, uint32_t, uint32_t, uint32_t); /** * Transform rasters from fully using subpixel rendering to * balance between subpixel rendering and greyscale antialiasing * * @param rasters Array of rasters, one for each subpixel colour. * The function may change the offset for each raster, * as such, the given pointer shall not be used anywhere * else during the execution of the function and the * inner pointers shall be considered undefined after * the execution of the function * @param nrasters The number of rasters * @param rowsize The number of cells in a row in each raster * @param cellsize The number of values stored in each raster, * between each cell, plus 1 (that is, the number of * values per cell) * @param width The horizontal number of pixels in the rasters * @param height The vertical number of pixels in the rasters * @param saturation The subpixel rendering saturation, 1 for regular * subpixel rendering, 0 for greyscale, values * in between for a compromise * @param primary_ys The CIE Y value (in e.g. CIE xyY or CIE XYZ) for * each subpixel colour; or `NULL` for the sRGB values * (this is only allowed if there are exactly 3 rasters) */ void libglitter_desaturate_double(double **, size_t, size_t, size_t, size_t, size_t, double, const double *restrict); /** * This value is identical to `libglitter_desaturate_double`, * apart from it parameter types, see `libglitter_desaturate_double` * for details about this function */ void libglitter_desaturate_float(float **, size_t, size_t, size_t, size_t, size_t, float, const float *restrict); /** * Transform rasters from fully using subpixel rendering to * balance between subpixel rendering and greyscale antialiasing * * @param rasters Array of rasters, one for each subpixel colour. * The function may change the offset for each raster, * as such, the given pointer shall not be used anywhere * else during the execution of the function and the * inner pointers shall be considered undefined after * the execution of the function. * @param nrasters The number of rasters * @param rowsize The number of cells in a row in each raster * @param cellsize The number of values stored in each raster, * between each cell, plus 1 (that is, the number of * values per cell) * @param width The horizontal number of pixels in the rasters * @param height The vertical number of pixels in the rasters * @param saturations The subpixel rendering saturation for each raster, * 1 for regular subpixel rendering, 0 for greyscale, * values in between for a compromise * @param primary_ys The CIE Y value (in e.g. CIE xyY or CIE XYZ) for * each subpixel colour; or `NULL` for the sRGB values * (this is only allowed if there are exactly 3 rasters) */ void libglitter_per_channel_desaturate_double(double **, size_t, size_t, size_t, size_t, size_t, const double *restrict, const double *restrict); /** * This value is identical to `libglitter_per_channel_desaturate_double`, * apart from it parameter types, see `libglitter_per_channel_desaturate_double` * for details about this function */ void libglitter_per_channel_desaturate_float(float **, size_t, size_t, size_t, size_t, size_t, const float *restrict, const float *restrict); /** * Get the matrix each pixel shall be multiplied with * to convert it from the output's colour space to sRGB * or CIE XYZ * * This is useful when the output does not use sRGB, or * CIE XYZ, but the application does. If the application * uses some other colour space, this function can output * the conversion matrix for the CIE XYZ colour space, * which can that be right-hand multiplied to get the * conversion matrix for some other colour; but be aware * that the output matrix is in column-major order, not * row-major order * * @param matrix Output buffer for the conversion matrix, in column-major order * @param c1x The CIE x value (as in CIE xyY) of the output's first primary colour * @param c1y The CIE y value (as in CIE xyY) of the output's first primary colour * @param c2x The CIE x value (as in CIE xyY) of the output's second primary colour * @param c2y The CIE y value (as in CIE xyY) of the output's second primary colour * @param c3x The CIE x value (as in CIE xyY) of the output's third primary colour * @param c3y The CIE y value (as in CIE xyY) of the output's third primary colour * @param white_x The CIE x value (as in CIE xyY) of the output's white point * @param white_y The CIE y value (as in CIE xyY) of the output's white point * @param white_Y The CIE Y value (as in CIE xyY) of the output's white point, normally 1 * @param xyz Whether the output conversion matrix should be to CIE XYZ rather the sRGB * * `LIBGLITTER_ILLUMINANT_D65` can be input in place of * `white_x, white_y, white_Y` (it expands to three arguments) * if the output's whitepoint is the D65 illuminant */ void libglitter_get_colour_space_conversion_matrix_double(double[3][3], double, double, double, double, double, double, double, double, double, int); /** * This value is identical to `libglitter_get_colour_space_conversion_matrix_double`, * apart from it parameter types, see `libglitter_get_colour_space_conversion_matrix_double` * for details about this function */ void libglitter_get_colour_space_conversion_matrix_float(float[3][3], float, float, float, float, float, float, float, float, float, int); /** * Convert set of rasters from one colour space to another * * @param n The number of input rasters * @param m The number of output rasters * @param outputs Array of output rasters. The function may change * the offset for each raster, as such, the given * pointer shall not be used anywhere else during * the execution of the function and the inner * pointers shall be considered undefined after the * execution of the function. * @param inputs Array of input rasters. The function may change * the offset for each raster, as such, the given * pointer shall not be used anywhere else during * the execution of the function and the inner * pointers shall be considered undefined after the * execution of the function. * @param output_rowsize The number of cells in a row in each output raster * @param output_cellsize The number of values stored in each output raster, * between each cell, plus 1 (that is, the number of * values per cell) * @param input_rowsize The number of cells in a row in each input raster * @param input_cellsize The number of values stored in each input raster, * between each cell, plus 1 (that is, the number of * values per cell) * @param width The horizontal number of pixels in the rasters * @param height The vertical number of pixels in the rasters * @param matrix Colour space conversion matrix, in column-major order */ void libglitter_colour_space_convert_rasters_double(size_t n, size_t m, double **, const double **, size_t, size_t, size_t, size_t, size_t, size_t, const double[n][m]); /** * This value is identical to `libglitter_colour_space_convert_rasters_double`, * apart from it parameter types, see `libglitter_colour_space_convert_rasters_double` * for details about this function */ void libglitter_colour_space_convert_rasters_float(size_t n, size_t m, float **, const float **, size_t, size_t, size_t, size_t, size_t, size_t, const float[n][m]); #endif