/* cairo - a vector graphics library with display and print output * * Copyright © 2009 Eric Anholt * Copyright © 2009 Chris Wilson * Copyright © 2005,2010 Red Hat, Inc * * This library is free software; you can redistribute it and/or * modify it either under the terms of the GNU Lesser General Public * License version 2.1 as published by the Free Software Foundation * (the "LGPL") or, at your option, under the terms of the Mozilla * Public License Version 1.1 (the "MPL"). If you do not alter this * notice, a recipient may use your version of this file under either * the MPL or the LGPL. * * You should have received a copy of the LGPL along with this library * in the file COPYING-LGPL-2.1; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Suite 500, Boston, MA 02110-1335, USA * You should have received a copy of the MPL along with this library * in the file COPYING-MPL-1.1 * * The contents of this file are subject to the Mozilla Public License * Version 1.1 (the "License"); you may not use this file except in * compliance with the License. You may obtain a copy of the License at * http://www.mozilla.org/MPL/ * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY * OF ANY KIND, either express or implied. See the LGPL or the MPL for * the specific language governing rights and limitations. * * The Original Code is the cairo graphics library. * * The Initial Developer of the Original Code is Red Hat, Inc. * * Contributor(s): * Benjamin Otte * Carl Worth * Chris Wilson * Eric Anholt */ #include "cairoint.h" #include "cairo-error-private.h" #include "cairo-gl-gradient-private.h" #include "cairo-gl-private.h" static int _cairo_gl_gradient_sample_width (unsigned int n_stops, const cairo_gradient_stop_t *stops) { unsigned int n; int width; width = 8; for (n = 1; n < n_stops; n++) { double dx = stops[n].offset - stops[n-1].offset; double delta, max; int ramp; if (dx == 0) return 1024; /* we need to emulate an infinitely sharp step */ max = fabs (stops[n].color.red - stops[n-1].color.red); delta = fabs (stops[n].color.green - stops[n-1].color.green); if (delta > max) max = delta; delta = fabs (stops[n].color.blue - stops[n-1].color.blue); if (delta > max) max = delta; delta = fabs (stops[n].color.alpha - stops[n-1].color.alpha); if (delta > max) max = delta; ramp = 128 * max / dx; if (ramp > width) width = ramp; } return (width + 7) & -8; } /* # to avoid warning : defined but not used [-Wunused-function] static uint8_t premultiply(double c, double a) { int v = c * a * 256; return v - (v >> 8); } static uint32_t color_stop_to_pixel(const cairo_gradient_stop_t *stop) { uint8_t a, r, g, b; a = stop->color.alpha_short >> 8; r = premultiply(stop->color.red, stop->color.alpha); g = premultiply(stop->color.green, stop->color.alpha); b = premultiply(stop->color.blue, stop->color.alpha); if (_cairo_is_little_endian ()) return a << 24 | r << 16 | g << 8 | b << 0; else return a << 0 | r << 8 | g << 16 | b << 24; } */ static cairo_status_t _cairo_gl_gradient_render (const cairo_gl_context_t *ctx, unsigned int n_stops, const cairo_gradient_stop_t *stops, void *bytes, int width) { pixman_image_t *gradient, *image; pixman_gradient_stop_t pixman_stops_stack[32]; pixman_gradient_stop_t *pixman_stops; pixman_point_fixed_t p1, p2; unsigned int i; pixman_format_code_t gradient_pixman_format; /* * Ensure that the order of the gradient's components in memory is BGRA. * This is done so that the gradient's pixel data is always suitable for * texture upload using format=GL_BGRA and type=GL_UNSIGNED_BYTE. */ if (_cairo_is_little_endian ()) gradient_pixman_format = PIXMAN_a8r8g8b8; else gradient_pixman_format = PIXMAN_b8g8r8a8; pixman_stops = pixman_stops_stack; if (unlikely (n_stops > ARRAY_LENGTH (pixman_stops_stack))) { pixman_stops = _cairo_malloc_ab (n_stops, sizeof (pixman_gradient_stop_t)); if (unlikely (pixman_stops == NULL)) return _cairo_error (CAIRO_STATUS_NO_MEMORY); } for (i = 0; i < n_stops; i++) { pixman_stops[i].x = _cairo_fixed_16_16_from_double (stops[i].offset); pixman_stops[i].color.red = stops[i].color.red_short; pixman_stops[i].color.green = stops[i].color.green_short; pixman_stops[i].color.blue = stops[i].color.blue_short; pixman_stops[i].color.alpha = stops[i].color.alpha_short; } p1.x = _cairo_fixed_16_16_from_double (0.5); p1.y = 0; p2.x = _cairo_fixed_16_16_from_double (width - 0.5); p2.y = 0; gradient = pixman_image_create_linear_gradient (&p1, &p2, pixman_stops, n_stops); if (pixman_stops != pixman_stops_stack) free (pixman_stops); if (unlikely (gradient == NULL)) return _cairo_error (CAIRO_STATUS_NO_MEMORY); pixman_image_set_filter (gradient, PIXMAN_FILTER_BILINEAR, NULL, 0); pixman_image_set_repeat (gradient, PIXMAN_REPEAT_PAD); image = pixman_image_create_bits (gradient_pixman_format, width, 1, bytes, sizeof(uint32_t)*width); if (unlikely (image == NULL)) { pixman_image_unref (gradient); return _cairo_error (CAIRO_STATUS_NO_MEMORY); } pixman_image_composite32 (PIXMAN_OP_SRC, gradient, NULL, image, 0, 0, 0, 0, 0, 0, width, 1); pixman_image_unref (gradient); pixman_image_unref (image); /* We need to fudge pixel 0 to hold the left-most color stop and not * the neareset stop to the zeroth pixel centre in order to correctly * populate the border color. For completeness, do both edges. */ /* This not needed as we have generated pixman pixels by using the * half pixel from left and right border */ /* ((uint32_t*)bytes)[0] = color_stop_to_pixel(&stops[0]); * ((uint32_t*)bytes)[width-1] = color_stop_to_pixel(&stops[n_stops-1]); */ return CAIRO_STATUS_SUCCESS; } static unsigned long _cairo_gl_gradient_hash (unsigned int n_stops, const cairo_gradient_stop_t *stops) { return _cairo_hash_bytes (n_stops, stops, sizeof (cairo_gradient_stop_t) * n_stops); } static cairo_gl_gradient_t * _cairo_gl_gradient_lookup (cairo_gl_context_t *ctx, unsigned long hash, unsigned int n_stops, const cairo_gradient_stop_t *stops) { cairo_gl_gradient_t lookup; lookup.cache_entry.hash = hash, lookup.n_stops = n_stops; lookup.stops = stops; return _cairo_cache_lookup (&ctx->gradients, &lookup.cache_entry); } cairo_bool_t _cairo_gl_gradient_equal (const void *key_a, const void *key_b) { const cairo_gl_gradient_t *a = key_a; const cairo_gl_gradient_t *b = key_b; if (a->n_stops != b->n_stops) return FALSE; return memcmp (a->stops, b->stops, a->n_stops * sizeof (cairo_gradient_stop_t)) == 0; } cairo_int_status_t _cairo_gl_gradient_create (cairo_gl_context_t *ctx, unsigned int n_stops, const cairo_gradient_stop_t *stops, cairo_gl_gradient_t **gradient_out) { unsigned long hash; cairo_gl_gradient_t *gradient; cairo_status_t status; int tex_width; GLint internal_format; void *data; if ((unsigned int) ctx->max_texture_size / 2 <= n_stops) return CAIRO_INT_STATUS_UNSUPPORTED; hash = _cairo_gl_gradient_hash (n_stops, stops); gradient = _cairo_gl_gradient_lookup (ctx, hash, n_stops, stops); if (gradient) { *gradient_out = _cairo_gl_gradient_reference (gradient); return CAIRO_STATUS_SUCCESS; } gradient = malloc (sizeof (cairo_gl_gradient_t) + sizeof (cairo_gradient_stop_t) * (n_stops - 1)); if (gradient == NULL) return _cairo_error (CAIRO_STATUS_NO_MEMORY); tex_width = _cairo_gl_gradient_sample_width (n_stops, stops); if (tex_width > ctx->max_texture_size) tex_width = ctx->max_texture_size; CAIRO_REFERENCE_COUNT_INIT (&gradient->ref_count, 2); gradient->cache_entry.hash = hash; gradient->cache_entry.size = tex_width; gradient->device = &ctx->base; gradient->n_stops = n_stops; gradient->stops = gradient->stops_embedded; memcpy (gradient->stops_embedded, stops, n_stops * sizeof (cairo_gradient_stop_t)); if (n_stops != 2) { ctx->dispatch.GenTextures (1, &gradient->tex); _cairo_gl_context_activate (ctx, CAIRO_GL_TEX_TEMP); ctx->dispatch.BindTexture (ctx->tex_target, gradient->tex); data = _cairo_malloc_ab (tex_width, sizeof (uint32_t)); if (unlikely (data == NULL)) { status = _cairo_error (CAIRO_STATUS_NO_MEMORY); goto cleanup_gradient; } status = _cairo_gl_gradient_render (ctx, n_stops, stops, data, tex_width); if (unlikely (status)) goto cleanup_data; /* * In OpenGL ES 2.0 no format conversion is allowed i.e. 'internalFormat' * must match 'format' in glTexImage2D. */ if (_cairo_gl_get_flavor (&ctx->dispatch) == CAIRO_GL_FLAVOR_ES2 || _cairo_gl_get_flavor (&ctx->dispatch) == CAIRO_GL_FLAVOR_ES3) internal_format = GL_BGRA; else internal_format = GL_RGBA; ctx->dispatch.TexImage2D (ctx->tex_target, 0, internal_format, tex_width, 1, 0, GL_BGRA, GL_UNSIGNED_BYTE, data); free (data); } /* we ignore errors here and just return an uncached gradient */ if (unlikely (_cairo_cache_insert (&ctx->gradients, &gradient->cache_entry))) CAIRO_REFERENCE_COUNT_INIT (&gradient->ref_count, 1); *gradient_out = gradient; return CAIRO_STATUS_SUCCESS; cleanup_data: free (data); cleanup_gradient: free (gradient); return status; } cairo_gl_gradient_t * _cairo_gl_gradient_reference (cairo_gl_gradient_t *gradient) { assert (CAIRO_REFERENCE_COUNT_HAS_REFERENCE (&gradient->ref_count)); _cairo_reference_count_inc (&gradient->ref_count); return gradient; } void _cairo_gl_gradient_destroy (cairo_gl_gradient_t *gradient) { cairo_gl_context_t *ctx; cairo_status_t ignore; assert (CAIRO_REFERENCE_COUNT_HAS_REFERENCE (&gradient->ref_count)); if (! _cairo_reference_count_dec_and_test (&gradient->ref_count)) return; if (_cairo_gl_context_acquire (gradient->device, &ctx) == CAIRO_STATUS_SUCCESS) { /* The gradient my still be active in the last operation, so flush */ _cairo_gl_composite_flush (ctx); ctx->dispatch.DeleteTextures (1, &gradient->tex); ignore = _cairo_gl_context_release (ctx, CAIRO_STATUS_SUCCESS); } free (gradient); }