/* * Mesa 3-D graphics library * * Copyright (C) 2009 VMware, Inc. 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 "main/glheader.h" #include "main/mtypes.h" #include "main/imports.h" #include "main/arbprogram.h" #include "main/arrayobj.h" #include "main/blend.h" #include "main/condrender.h" #include "main/depth.h" #include "main/enable.h" #include "main/enums.h" #include "main/fbobject.h" #include "main/image.h" #include "main/macros.h" #include "main/matrix.h" #include "main/multisample.h" #include "main/objectlabel.h" #include "main/readpix.h" #include "main/scissor.h" #include "main/shaderapi.h" #include "main/texobj.h" #include "main/texenv.h" #include "main/teximage.h" #include "main/texparam.h" #include "main/uniforms.h" #include "main/varray.h" #include "main/viewport.h" #include "swrast/swrast.h" #include "drivers/common/meta.h" #include "util/ralloc.h" /** Return offset in bytes of the field within a vertex struct */ #define OFFSET(FIELD) ((void *) offsetof(struct vertex, FIELD)) static void setup_glsl_msaa_blit_scaled_shader(struct gl_context *ctx, struct blit_state *blit, struct gl_renderbuffer *src_rb, GLenum target) { GLint loc_src_width, loc_src_height; int i, samples; int shader_offset = 0; void *mem_ctx = ralloc_context(NULL); char *fs_source; char *name, *sample_number; const uint8_t *sample_map; char *sample_map_str = rzalloc_size(mem_ctx, 1); char *sample_map_expr = rzalloc_size(mem_ctx, 1); char *texel_fetch_macro = rzalloc_size(mem_ctx, 1); const char *sampler_array_suffix = ""; float x_scale, y_scale; enum blit_msaa_shader shader_index; assert(src_rb); samples = MAX2(src_rb->NumSamples, 1); if (samples == 16) x_scale = 4.0; else x_scale = 2.0; y_scale = samples / x_scale; /* We expect only power of 2 samples in source multisample buffer. */ assert(samples > 0 && _mesa_is_pow_two(samples)); while (samples >> (shader_offset + 1)) { shader_offset++; } /* Update the assert if we plan to support more than 16X MSAA. */ assert(shader_offset > 0 && shader_offset <= 4); assert(target == GL_TEXTURE_2D_MULTISAMPLE || target == GL_TEXTURE_2D_MULTISAMPLE_ARRAY); shader_index = BLIT_2X_MSAA_SHADER_2D_MULTISAMPLE_SCALED_RESOLVE + shader_offset - 1; if (target == GL_TEXTURE_2D_MULTISAMPLE_ARRAY) { shader_index += BLIT_2X_MSAA_SHADER_2D_MULTISAMPLE_ARRAY_SCALED_RESOLVE - BLIT_2X_MSAA_SHADER_2D_MULTISAMPLE_SCALED_RESOLVE; sampler_array_suffix = "Array"; } if (blit->msaa_shaders[shader_index]) { _mesa_meta_use_program(ctx, blit->msaa_shaders[shader_index]); /* Update the uniform values. */ loc_src_width = _mesa_program_resource_location(blit->msaa_shaders[shader_index], GL_UNIFORM, "src_width"); loc_src_height = _mesa_program_resource_location(blit->msaa_shaders[shader_index], GL_UNIFORM, "src_height"); _mesa_Uniform1f(loc_src_width, src_rb->Width); _mesa_Uniform1f(loc_src_height, src_rb->Height); return; } name = ralloc_asprintf(mem_ctx, "vec4 MSAA scaled resolve"); /* Below switch is used to setup the shader expression, which computes * sample index and map it to to a sample number on hardware. */ switch(samples) { case 2: sample_number = "sample_map[int(2 * fract(coord.x))]"; sample_map = ctx->Const.SampleMap2x; break; case 4: sample_number = "sample_map[int(2 * fract(coord.x) + 4 * fract(coord.y))]"; sample_map = ctx->Const.SampleMap4x; break; case 8: sample_number = "sample_map[int(2 * fract(coord.x) + 8 * fract(coord.y))]"; sample_map = ctx->Const.SampleMap8x; break; case 16: sample_number = "sample_map[int(4 * fract(coord.x) + 16 * fract(coord.y))]"; sample_map = ctx->Const.SampleMap16x; break; default: sample_number = NULL; sample_map = NULL; _mesa_problem(ctx, "Unsupported sample count %d\n", samples); unreachable("Unsupported sample count"); } /* Create sample map string. */ for (i = 0 ; i < samples - 1; i++) { ralloc_asprintf_append(&sample_map_str, "%d, ", sample_map[i]); } ralloc_asprintf_append(&sample_map_str, "%d", sample_map[samples - 1]); /* Create sample map expression using above string. */ ralloc_asprintf_append(&sample_map_expr, " const int sample_map[%d] = int[%d](%s);\n", samples, samples, sample_map_str); if (target == GL_TEXTURE_2D_MULTISAMPLE) { ralloc_asprintf_append(&texel_fetch_macro, "#define TEXEL_FETCH(coord) texelFetch(texSampler, ivec2(coord), %s);\n", sample_number); } else { ralloc_asprintf_append(&texel_fetch_macro, "#define TEXEL_FETCH(coord) texelFetch(texSampler, ivec3(coord, layer), %s);\n", sample_number); } static const char vs_source[] = "#version 130\n" "#extension GL_ARB_explicit_attrib_location: enable\n" "layout(location = 0) in vec2 position;\n" "layout(location = 1) in vec3 textureCoords;\n" "out vec2 texCoords;\n" "flat out int layer;\n" "void main()\n" "{\n" " texCoords = textureCoords.xy;\n" " layer = int(textureCoords.z);\n" " gl_Position = vec4(position, 0.0, 1.0);\n" "}\n" ; fs_source = ralloc_asprintf(mem_ctx, "#version 130\n" "#extension GL_ARB_texture_multisample : enable\n" "uniform sampler2DMS%s texSampler;\n" "uniform float src_width, src_height;\n" "in vec2 texCoords;\n" "flat in int layer;\n" "out vec4 out_color;\n" "\n" "void main()\n" "{\n" "%s" " vec2 interp;\n" " const vec2 scale = vec2(%ff, %ff);\n" " const vec2 scale_inv = vec2(%ff, %ff);\n" " const vec2 s_0_offset = vec2(%ff, %ff);\n" " vec2 s_0_coord, s_1_coord, s_2_coord, s_3_coord;\n" " vec4 s_0_color, s_1_color, s_2_color, s_3_color;\n" " vec4 x_0_color, x_1_color;\n" " vec2 tex_coord = texCoords - s_0_offset;\n" "\n" " tex_coord *= scale;\n" " tex_coord.x = clamp(tex_coord.x, 0.0f, scale.x * src_width - 1.0f);\n" " tex_coord.y = clamp(tex_coord.y, 0.0f, scale.y * src_height - 1.0f);\n" " interp = fract(tex_coord);\n" " tex_coord = ivec2(tex_coord) * scale_inv;\n" "\n" " /* Compute the sample coordinates used for filtering. */\n" " s_0_coord = tex_coord;\n" " s_1_coord = tex_coord + vec2(scale_inv.x, 0.0f);\n" " s_2_coord = tex_coord + vec2(0.0f, scale_inv.y);\n" " s_3_coord = tex_coord + vec2(scale_inv.x, scale_inv.y);\n" "\n" " /* Fetch sample color values. */\n" "%s" " s_0_color = TEXEL_FETCH(s_0_coord)\n" " s_1_color = TEXEL_FETCH(s_1_coord)\n" " s_2_color = TEXEL_FETCH(s_2_coord)\n" " s_3_color = TEXEL_FETCH(s_3_coord)\n" "#undef TEXEL_FETCH\n" "\n" " /* Do bilinear filtering on sample colors. */\n" " x_0_color = mix(s_0_color, s_1_color, interp.x);\n" " x_1_color = mix(s_2_color, s_3_color, interp.x);\n" " out_color = mix(x_0_color, x_1_color, interp.y);\n" "}\n", sampler_array_suffix, sample_map_expr, x_scale, y_scale, 1.0f / x_scale, 1.0f / y_scale, 0.5f / x_scale, 0.5f / y_scale, texel_fetch_macro); _mesa_meta_compile_and_link_program(ctx, vs_source, fs_source, name, &blit->msaa_shaders[shader_index]); loc_src_width = _mesa_program_resource_location(blit->msaa_shaders[shader_index], GL_UNIFORM, "src_width"); loc_src_height = _mesa_program_resource_location(blit->msaa_shaders[shader_index], GL_UNIFORM, "src_height"); _mesa_Uniform1f(loc_src_width, src_rb->Width); _mesa_Uniform1f(loc_src_height, src_rb->Height); ralloc_free(mem_ctx); } static void setup_glsl_msaa_blit_shader(struct gl_context *ctx, struct blit_state *blit, const struct gl_framebuffer *drawFb, struct gl_renderbuffer *src_rb, GLenum target) { const char *vs_source; char *fs_source; void *mem_ctx; enum blit_msaa_shader shader_index; bool dst_is_msaa = false; GLenum src_datatype; const char *vec4_prefix; const char *sampler_array_suffix = ""; char *name; const char *texcoord_type = "vec2"; int samples; int shader_offset = 0; if (src_rb) { samples = MAX2(src_rb->NumSamples, 1); src_datatype = _mesa_get_format_datatype(src_rb->Format); } else { /* depth-or-color glCopyTexImage fallback path that passes a NULL rb and * doesn't handle integer. */ samples = 1; src_datatype = GL_UNSIGNED_NORMALIZED; } /* We expect only power of 2 samples in source multisample buffer. */ assert(samples > 0 && _mesa_is_pow_two(samples)); while (samples >> (shader_offset + 1)) { shader_offset++; } /* Update the assert if we plan to support more than 16X MSAA. */ assert(shader_offset >= 0 && shader_offset <= 4); if (drawFb->Visual.samples > 1) { /* If you're calling meta_BlitFramebuffer with the destination * multisampled, this is the only path that will work -- swrast and * CopyTexImage won't work on it either. */ assert(ctx->Extensions.ARB_sample_shading); dst_is_msaa = true; /* We need shader invocation per sample, not per pixel */ _mesa_set_enable(ctx, GL_MULTISAMPLE, GL_TRUE); _mesa_set_enable(ctx, GL_SAMPLE_SHADING, GL_TRUE); _mesa_MinSampleShading(1.0); } switch (target) { case GL_TEXTURE_2D_MULTISAMPLE: case GL_TEXTURE_2D_MULTISAMPLE_ARRAY: if (src_rb && (src_rb->_BaseFormat == GL_DEPTH_COMPONENT || src_rb->_BaseFormat == GL_DEPTH_STENCIL)) { if (dst_is_msaa) shader_index = BLIT_MSAA_SHADER_2D_MULTISAMPLE_DEPTH_COPY; else shader_index = BLIT_MSAA_SHADER_2D_MULTISAMPLE_DEPTH_RESOLVE; } else { if (dst_is_msaa) shader_index = BLIT_MSAA_SHADER_2D_MULTISAMPLE_COPY; else { shader_index = BLIT_1X_MSAA_SHADER_2D_MULTISAMPLE_RESOLVE + shader_offset; } } if (target == GL_TEXTURE_2D_MULTISAMPLE_ARRAY) { shader_index += (BLIT_1X_MSAA_SHADER_2D_MULTISAMPLE_ARRAY_RESOLVE - BLIT_1X_MSAA_SHADER_2D_MULTISAMPLE_RESOLVE); sampler_array_suffix = "Array"; texcoord_type = "vec3"; } break; default: _mesa_problem(ctx, "Unknown texture target %s\n", _mesa_enum_to_string(target)); shader_index = BLIT_2X_MSAA_SHADER_2D_MULTISAMPLE_RESOLVE; } /* We rely on the enum being sorted this way. */ STATIC_ASSERT(BLIT_1X_MSAA_SHADER_2D_MULTISAMPLE_RESOLVE_INT == BLIT_1X_MSAA_SHADER_2D_MULTISAMPLE_RESOLVE + 5); STATIC_ASSERT(BLIT_1X_MSAA_SHADER_2D_MULTISAMPLE_RESOLVE_UINT == BLIT_1X_MSAA_SHADER_2D_MULTISAMPLE_RESOLVE + 10); if (src_datatype == GL_INT) { shader_index += 5; vec4_prefix = "i"; } else if (src_datatype == GL_UNSIGNED_INT) { shader_index += 10; vec4_prefix = "u"; } else { vec4_prefix = ""; } if (blit->msaa_shaders[shader_index]) { _mesa_meta_use_program(ctx, blit->msaa_shaders[shader_index]); return; } mem_ctx = ralloc_context(NULL); if (shader_index == BLIT_MSAA_SHADER_2D_MULTISAMPLE_DEPTH_RESOLVE || shader_index == BLIT_MSAA_SHADER_2D_MULTISAMPLE_ARRAY_DEPTH_RESOLVE || shader_index == BLIT_MSAA_SHADER_2D_MULTISAMPLE_ARRAY_DEPTH_COPY || shader_index == BLIT_MSAA_SHADER_2D_MULTISAMPLE_DEPTH_COPY) { char *sample_index; const char *tex_coords = "texCoords"; if (dst_is_msaa) { sample_index = "gl_SampleID"; name = "depth MSAA copy"; if (ctx->Extensions.ARB_gpu_shader5 && samples >= 16) { /* See comment below for the color copy */ tex_coords = "interpolateAtOffset(texCoords, vec2(0.0))"; } } else { /* From the GL 4.3 spec: * * "If there is a multisample buffer (the value of SAMPLE_BUFFERS * is one), then values are obtained from the depth samples in * this buffer. It is recommended that the depth value of the * centermost sample be used, though implementations may choose * any function of the depth sample values at each pixel. * * We're slacking and instead of choosing centermost, we've got 0. */ sample_index = "0"; name = "depth MSAA resolve"; } vs_source = ralloc_asprintf(mem_ctx, "#version 130\n" "#extension GL_ARB_explicit_attrib_location: enable\n" "layout(location = 0) in vec2 position;\n" "layout(location = 1) in %s textureCoords;\n" "out %s texCoords;\n" "void main()\n" "{\n" " texCoords = textureCoords;\n" " gl_Position = vec4(position, 0.0, 1.0);\n" "}\n", texcoord_type, texcoord_type); fs_source = ralloc_asprintf(mem_ctx, "#version 130\n" "#extension GL_ARB_texture_multisample : enable\n" "#extension GL_ARB_sample_shading : enable\n" "#extension GL_ARB_gpu_shader5 : enable\n" "uniform sampler2DMS%s texSampler;\n" "in %s texCoords;\n" "out vec4 out_color;\n" "\n" "void main()\n" "{\n" " gl_FragDepth = texelFetch(texSampler, i%s(%s), %s).r;\n" "}\n", sampler_array_suffix, texcoord_type, texcoord_type, tex_coords, sample_index); } else { /* You can create 2D_MULTISAMPLE textures with 0 sample count (meaning 1 * sample). Yes, this is ridiculous. */ char *sample_resolve; const char *merge_function; name = ralloc_asprintf(mem_ctx, "%svec4 MSAA %s", vec4_prefix, dst_is_msaa ? "copy" : "resolve"); if (dst_is_msaa) { const char *tex_coords; if (ctx->Extensions.ARB_gpu_shader5 && samples >= 16) { /* If interpolateAtOffset is available then it will be used to * force the interpolation to the center. This is required at * least on Intel hardware because it is possible to have a sample * position on the 0 x or y axis which means it will lie exactly * on the pixel boundary. If we let the hardware interpolate the * coordinates at one of these positions then it is possible for * it to jump to a neighboring texel when converting to ints due * to rounding errors. This is only done for >= 16x MSAA because * it probably has some overhead. It is more likely that some * hardware will use one of these problematic positions at 16x * MSAA because in that case in D3D they are defined to be at * these positions. */ tex_coords = "interpolateAtOffset(texCoords, vec2(0.0))"; } else { tex_coords = "texCoords"; } sample_resolve = ralloc_asprintf(mem_ctx, " out_color = texelFetch(texSampler, " "i%s(%s), gl_SampleID);", texcoord_type, tex_coords); merge_function = ""; } else { int i; int step; if (src_datatype == GL_INT || src_datatype == GL_UNSIGNED_INT) { /* From the OpenGL ES 3.2 spec section 16.2.1: * * "If the source formats are integer types or stencil values, * a single sample's value is selected for each pixel." * * The OpenGL 4.4 spec contains exactly the same language. * * We can accomplish this by making the merge function return just * one of the two samples. The compiler should do the rest. */ merge_function = "gvec4 merge(gvec4 a, gvec4 b) { return a; }\n"; } else { /* The divide will happen at the end for floats. */ merge_function = "vec4 merge(vec4 a, vec4 b) { return (a + b); }\n"; } /* We're assuming power of two samples for this resolution procedure. * * To avoid losing any floating point precision if the samples all * happen to have the same value, we merge pairs of values at a time * (so the floating point exponent just gets increased), rather than * doing a naive sum and dividing. */ assert(_mesa_is_pow_two(samples)); /* Fetch each individual sample. */ sample_resolve = rzalloc_size(mem_ctx, 1); for (i = 0; i < samples; i++) { ralloc_asprintf_append(&sample_resolve, " gvec4 sample_1_%d = texelFetch(texSampler, i%s(texCoords), %d);\n", i, texcoord_type, i); } /* Now, merge each pair of samples, then merge each pair of those, * etc. */ for (step = 2; step <= samples; step *= 2) { for (i = 0; i < samples; i += step) { ralloc_asprintf_append(&sample_resolve, " gvec4 sample_%d_%d = merge(sample_%d_%d, sample_%d_%d);\n", step, i, step / 2, i, step / 2, i + step / 2); } } /* Scale the final result. */ if (src_datatype == GL_UNSIGNED_INT || src_datatype == GL_INT) { ralloc_asprintf_append(&sample_resolve, " out_color = sample_%d_0;\n", samples); } else { ralloc_asprintf_append(&sample_resolve, " gl_FragColor = sample_%d_0 / %f;\n", samples, (float)samples); } } vs_source = ralloc_asprintf(mem_ctx, "#version 130\n" "#extension GL_ARB_explicit_attrib_location: enable\n" "layout(location = 0) in vec2 position;\n" "layout(location = 1) in %s textureCoords;\n" "out %s texCoords;\n" "void main()\n" "{\n" " texCoords = textureCoords;\n" " gl_Position = vec4(position, 0.0, 1.0);\n" "}\n", texcoord_type, texcoord_type); fs_source = ralloc_asprintf(mem_ctx, "#version 130\n" "#extension GL_ARB_texture_multisample : enable\n" "#extension GL_ARB_sample_shading : enable\n" "#extension GL_ARB_gpu_shader5 : enable\n" "#define gvec4 %svec4\n" "uniform %ssampler2DMS%s texSampler;\n" "in %s texCoords;\n" "out gvec4 out_color;\n" "\n" "%s" /* merge_function */ "void main()\n" "{\n" "%s\n" /* sample_resolve */ "}\n", vec4_prefix, vec4_prefix, sampler_array_suffix, texcoord_type, merge_function, sample_resolve); } _mesa_meta_compile_and_link_program(ctx, vs_source, fs_source, name, &blit->msaa_shaders[shader_index]); ralloc_free(mem_ctx); } static void setup_glsl_blit_framebuffer(struct gl_context *ctx, struct blit_state *blit, const struct gl_framebuffer *drawFb, struct gl_renderbuffer *src_rb, GLenum target, GLenum filter, bool is_scaled_blit, bool do_depth) { unsigned texcoord_size; bool is_target_multisample = target == GL_TEXTURE_2D_MULTISAMPLE || target == GL_TEXTURE_2D_MULTISAMPLE_ARRAY; bool is_filter_scaled_resolve = filter == GL_SCALED_RESOLVE_FASTEST_EXT || filter == GL_SCALED_RESOLVE_NICEST_EXT; /* target = GL_TEXTURE_RECTANGLE is not supported in GLES 3.0 */ assert(_mesa_is_desktop_gl(ctx) || target == GL_TEXTURE_2D); texcoord_size = 2 + (src_rb->Depth > 1 ? 1 : 0); _mesa_meta_setup_vertex_objects(ctx, &blit->VAO, &blit->buf_obj, true, 2, texcoord_size, 0); if (is_target_multisample && is_filter_scaled_resolve && is_scaled_blit) { setup_glsl_msaa_blit_scaled_shader(ctx, blit, src_rb, target); } else if (is_target_multisample) { setup_glsl_msaa_blit_shader(ctx, blit, drawFb, src_rb, target); } else { _mesa_meta_setup_blit_shader(ctx, target, do_depth, do_depth ? &blit->shaders_with_depth : &blit->shaders_without_depth); } } /** * Try to do a color or depth glBlitFramebuffer using texturing. * * We can do this when the src renderbuffer is actually a texture, or when the * driver exposes BindRenderbufferTexImage(). */ static bool blitframebuffer_texture(struct gl_context *ctx, const struct gl_framebuffer *readFb, const struct gl_framebuffer *drawFb, GLint srcX0, GLint srcY0, GLint srcX1, GLint srcY1, GLint dstX0, GLint dstY0, GLint dstX1, GLint dstY1, GLenum filter, GLint flipX, GLint flipY, GLboolean glsl_version, GLboolean do_depth) { int att_index = do_depth ? BUFFER_DEPTH : readFb->_ColorReadBufferIndex; const struct gl_renderbuffer_attachment *readAtt = &readFb->Attachment[att_index]; struct blit_state *blit = &ctx->Meta->Blit; struct fb_tex_blit_state fb_tex_blit; const GLint dstX = MIN2(dstX0, dstX1); const GLint dstY = MIN2(dstY0, dstY1); const GLint dstW = abs(dstX1 - dstX0); const GLint dstH = abs(dstY1 - dstY0); const int srcW = abs(srcX1 - srcX0); const int srcH = abs(srcY1 - srcY0); bool scaled_blit = false; struct gl_texture_object *texObj; GLuint srcLevel; GLenum target; struct gl_renderbuffer *rb = readAtt->Renderbuffer; struct temp_texture *meta_temp_texture; if (rb->NumSamples && !ctx->Extensions.ARB_texture_multisample) return false; _mesa_meta_fb_tex_blit_begin(ctx, &fb_tex_blit); if (readAtt->Texture && (readAtt->Texture->Target == GL_TEXTURE_2D || readAtt->Texture->Target == GL_TEXTURE_RECTANGLE || readAtt->Texture->Target == GL_TEXTURE_2D_MULTISAMPLE || readAtt->Texture->Target == GL_TEXTURE_2D_MULTISAMPLE_ARRAY)) { /* If there's a texture attached of a type we can handle, then just use * it directly. */ srcLevel = readAtt->TextureLevel; texObj = readAtt->Texture; } else if (!readAtt->Texture && ctx->Driver.BindRenderbufferTexImage) { if (!_mesa_meta_bind_rb_as_tex_image(ctx, rb, &fb_tex_blit.tempTex, &texObj)) return false; srcLevel = 0; if (_mesa_is_winsys_fbo(readFb)) { GLint temp = srcY0; srcY0 = rb->Height - srcY1; srcY1 = rb->Height - temp; flipY = -flipY; } } else { GLenum tex_base_format; /* Fall back to doing a CopyTexSubImage to get the destination * renderbuffer into a texture. */ if (ctx->Meta->Blit.no_ctsi_fallback) return false; if (rb->NumSamples > 1) return false; if (do_depth) { meta_temp_texture = _mesa_meta_get_temp_depth_texture(ctx); tex_base_format = GL_DEPTH_COMPONENT; } else { meta_temp_texture = _mesa_meta_get_temp_texture(ctx); tex_base_format = _mesa_base_tex_format(ctx, rb->InternalFormat); } srcLevel = 0; texObj = _mesa_lookup_texture(ctx, meta_temp_texture->TexObj); if (texObj == NULL) { return false; } _mesa_meta_setup_copypix_texture(ctx, meta_temp_texture, srcX0, srcY0, srcW, srcH, tex_base_format, filter); assert(texObj->Target == meta_temp_texture->Target); srcX0 = 0; srcY0 = 0; srcX1 = srcW; srcY1 = srcH; } target = texObj->Target; fb_tex_blit.baseLevelSave = texObj->BaseLevel; fb_tex_blit.maxLevelSave = texObj->MaxLevel; fb_tex_blit.stencilSamplingSave = texObj->StencilSampling; scaled_blit = dstW != srcW || dstH != srcH; if (glsl_version) { setup_glsl_blit_framebuffer(ctx, blit, drawFb, rb, target, filter, scaled_blit, do_depth); } else { _mesa_meta_setup_ff_tnl_for_blit(ctx, &ctx->Meta->Blit.VAO, &ctx->Meta->Blit.buf_obj, 2); } /* printf("Blit from texture!\n"); printf(" srcAtt %p dstAtt %p\n", readAtt, drawAtt); printf(" srcTex %p dstText %p\n", texObj, drawAtt->Texture); */ fb_tex_blit.samp_obj = _mesa_meta_setup_sampler(ctx, texObj, target, filter, srcLevel); if (ctx->Extensions.EXT_texture_sRGB_decode) { /* The GL 4.4 spec, section 18.3.1 ("Blitting Pixel Rectangles") says: * * "When values are taken from the read buffer, if FRAMEBUFFER_SRGB * is enabled and the value of FRAMEBUFFER_ATTACHMENT_COLOR_ENCODING * for the framebuffer attachment corresponding to the read buffer * is SRGB (see section 9.2.3), the red, green, and blue components * are converted from the non-linear sRGB color space according to * equation 3.24. * * When values are written to the draw buffers, blit operations * bypass most of the fragment pipeline. The only fragment * operations which affect a blit are the pixel ownership test, * the scissor test, and sRGB conversion (see section 17.3.9)." * * ES 3.0 contains nearly the exact same text, but omits the part * about GL_FRAMEBUFFER_SRGB as that doesn't exist in ES. Mesa * defaults it to on for ES contexts, so we can safely check it. */ const bool decode = ctx->Color.sRGBEnabled && _mesa_get_format_color_encoding(rb->Format) == GL_SRGB; _mesa_set_sampler_srgb_decode(ctx, fb_tex_blit.samp_obj, decode ? GL_DECODE_EXT : GL_SKIP_DECODE_EXT); } if (!glsl_version) { _mesa_TexEnvi(GL_TEXTURE_ENV, GL_TEXTURE_ENV_MODE, GL_REPLACE); _mesa_set_enable(ctx, target, GL_TRUE); } /* Prepare vertex data (the VBO was previously created and bound) */ { struct vertex verts[4]; GLfloat s0, t0, s1, t1; if (target == GL_TEXTURE_2D) { const struct gl_texture_image *texImage = _mesa_select_tex_image(texObj, target, srcLevel); s0 = srcX0 / (float) texImage->Width; s1 = srcX1 / (float) texImage->Width; t0 = srcY0 / (float) texImage->Height; t1 = srcY1 / (float) texImage->Height; } else { assert(target == GL_TEXTURE_RECTANGLE_ARB || target == GL_TEXTURE_2D_MULTISAMPLE || target == GL_TEXTURE_2D_MULTISAMPLE_ARRAY); s0 = (float) srcX0; s1 = (float) srcX1; t0 = (float) srcY0; t1 = (float) srcY1; } /* Silence valgrind warnings about reading uninitialized stack. */ memset(verts, 0, sizeof(verts)); /* setup vertex positions */ verts[0].x = -1.0F * flipX; verts[0].y = -1.0F * flipY; verts[1].x = 1.0F * flipX; verts[1].y = -1.0F * flipY; verts[2].x = 1.0F * flipX; verts[2].y = 1.0F * flipY; verts[3].x = -1.0F * flipX; verts[3].y = 1.0F * flipY; verts[0].tex[0] = s0; verts[0].tex[1] = t0; verts[0].tex[2] = readAtt->Zoffset; verts[1].tex[0] = s1; verts[1].tex[1] = t0; verts[1].tex[2] = readAtt->Zoffset; verts[2].tex[0] = s1; verts[2].tex[1] = t1; verts[2].tex[2] = readAtt->Zoffset; verts[3].tex[0] = s0; verts[3].tex[1] = t1; verts[3].tex[2] = readAtt->Zoffset; _mesa_buffer_sub_data(ctx, blit->buf_obj, 0, sizeof(verts), verts); } /* setup viewport */ _mesa_set_viewport(ctx, 0, dstX, dstY, dstW, dstH); _mesa_ColorMask(!do_depth, !do_depth, !do_depth, !do_depth); _mesa_set_enable(ctx, GL_DEPTH_TEST, do_depth); _mesa_DepthMask(do_depth); _mesa_DepthFunc(GL_ALWAYS); _mesa_DrawArrays(GL_TRIANGLE_FAN, 0, 4); _mesa_meta_fb_tex_blit_end(ctx, target, &fb_tex_blit); return true; } void _mesa_meta_fb_tex_blit_begin(struct gl_context *ctx, struct fb_tex_blit_state *blit) { /* None of the existing callers preinitialize fb_tex_blit_state to zeros, * and both use stack variables. If samp_obj_save is not NULL, * _mesa_reference_sampler_object will try to dereference it. Leaving * random garbage in samp_obj_save can only lead to crashes. * * Since the state isn't persistent across calls, we won't catch ref * counting problems. */ blit->samp_obj_save = NULL; _mesa_reference_sampler_object(ctx, &blit->samp_obj_save, ctx->Texture.Unit[ctx->Texture.CurrentUnit].Sampler); blit->tempTex = 0; } void _mesa_meta_fb_tex_blit_end(struct gl_context *ctx, GLenum target, struct fb_tex_blit_state *blit) { struct gl_texture_object *const texObj = _mesa_get_current_tex_object(ctx, target); /* Either there is no temporary texture or the temporary texture is bound. */ assert(blit->tempTex == 0 || texObj->Name == blit->tempTex); /* Restore texture object state, the texture binding will be restored by * _mesa_meta_end(). If the texture is the temporary texture that is about * to be destroyed, don't bother restoring its state. */ if (blit->tempTex == 0) { /* If the target restricts values for base level or max level, we assume * that the original values were valid. */ if (blit->baseLevelSave != texObj->BaseLevel) _mesa_texture_parameteriv(ctx, texObj, GL_TEXTURE_BASE_LEVEL, &blit->baseLevelSave, false); if (blit->maxLevelSave != texObj->MaxLevel) _mesa_texture_parameteriv(ctx, texObj, GL_TEXTURE_MAX_LEVEL, &blit->maxLevelSave, false); /* If ARB_stencil_texturing is not supported, the mode won't have changed. */ if (texObj->StencilSampling != blit->stencilSamplingSave) { /* GLint so the compiler won't complain about type signedness mismatch * in the call to _mesa_texture_parameteriv below. */ const GLint param = blit->stencilSamplingSave ? GL_STENCIL_INDEX : GL_DEPTH_COMPONENT; _mesa_texture_parameteriv(ctx, texObj, GL_DEPTH_STENCIL_TEXTURE_MODE, ¶m, false); } } _mesa_bind_sampler(ctx, ctx->Texture.CurrentUnit, blit->samp_obj_save); _mesa_reference_sampler_object(ctx, &blit->samp_obj_save, NULL); _mesa_reference_sampler_object(ctx, &blit->samp_obj, NULL); if (blit->tempTex) _mesa_DeleteTextures(1, &blit->tempTex); } GLboolean _mesa_meta_bind_rb_as_tex_image(struct gl_context *ctx, struct gl_renderbuffer *rb, GLuint *tex, struct gl_texture_object **texObj) { struct gl_texture_image *texImage; GLuint tempTex; const GLenum target = rb->NumSamples > 1 ? GL_TEXTURE_2D_MULTISAMPLE : GL_TEXTURE_2D; tempTex = 0; _mesa_GenTextures(1, &tempTex); if (tempTex == 0) return false; *tex = tempTex; _mesa_BindTexture(target, *tex); *texObj = _mesa_lookup_texture(ctx, *tex); texImage = _mesa_get_tex_image(ctx, *texObj, target, 0); if (!ctx->Driver.BindRenderbufferTexImage(ctx, rb, texImage)) { _mesa_DeleteTextures(1, tex); return false; } if (ctx->Driver.FinishRenderTexture && !rb->NeedsFinishRenderTexture) { rb->NeedsFinishRenderTexture = true; ctx->Driver.FinishRenderTexture(ctx, rb); } assert(target == (*texObj)->Target); return true; } struct gl_sampler_object * _mesa_meta_setup_sampler(struct gl_context *ctx, struct gl_texture_object *texObj, GLenum target, GLenum filter, GLuint srcLevel) { struct gl_sampler_object *samp_obj; GLenum tex_filter = (filter == GL_SCALED_RESOLVE_FASTEST_EXT || filter == GL_SCALED_RESOLVE_NICEST_EXT) ? GL_NEAREST : filter; samp_obj = ctx->Driver.NewSamplerObject(ctx, 0xDEADBEEF); if (samp_obj == NULL) return NULL; _mesa_bind_sampler(ctx, ctx->Texture.CurrentUnit, samp_obj); _mesa_set_sampler_filters(ctx, samp_obj, tex_filter, tex_filter); _mesa_set_sampler_wrap(ctx, samp_obj, GL_CLAMP_TO_EDGE, GL_CLAMP_TO_EDGE, samp_obj->WrapR); /* Prepare src texture state */ _mesa_BindTexture(target, texObj->Name); if (target != GL_TEXTURE_RECTANGLE_ARB) { _mesa_texture_parameteriv(ctx, texObj, GL_TEXTURE_BASE_LEVEL, (GLint *) &srcLevel, false); _mesa_texture_parameteriv(ctx, texObj, GL_TEXTURE_MAX_LEVEL, (GLint *) &srcLevel, false); } return samp_obj; } /** * Meta implementation of ctx->Driver.BlitFramebuffer() in terms * of texture mapping and polygon rendering. */ GLbitfield _mesa_meta_BlitFramebuffer(struct gl_context *ctx, const struct gl_framebuffer *readFb, const struct gl_framebuffer *drawFb, GLint srcX0, GLint srcY0, GLint srcX1, GLint srcY1, GLint dstX0, GLint dstY0, GLint dstX1, GLint dstY1, GLbitfield mask, GLenum filter) { const GLint dstW = abs(dstX1 - dstX0); const GLint dstH = abs(dstY1 - dstY0); const GLint dstFlipX = (dstX1 - dstX0) / dstW; const GLint dstFlipY = (dstY1 - dstY0) / dstH; struct { GLint srcX0, srcY0, srcX1, srcY1; GLint dstX0, dstY0, dstX1, dstY1; } clip = { srcX0, srcY0, srcX1, srcY1, dstX0, dstY0, dstX1, dstY1 }; const GLboolean use_glsl_version = ctx->Extensions.ARB_vertex_shader && ctx->Extensions.ARB_fragment_shader; /* Multisample texture blit support requires texture multisample. */ if (readFb->Visual.samples > 0 && !ctx->Extensions.ARB_texture_multisample) { return mask; } /* Clip a copy of the blit coordinates. If these differ from the input * coordinates, then we'll set the scissor. */ if (!_mesa_clip_blit(ctx, readFb, drawFb, &clip.srcX0, &clip.srcY0, &clip.srcX1, &clip.srcY1, &clip.dstX0, &clip.dstY0, &clip.dstX1, &clip.dstY1)) { /* clipped/scissored everything away */ return 0; } /* Only scissor and FRAMEBUFFER_SRGB affect blit. Leave sRGB alone, but * save restore scissor as we'll set a custom scissor if necessary. */ _mesa_meta_begin(ctx, MESA_META_ALL & ~(MESA_META_DRAW_BUFFERS | MESA_META_FRAMEBUFFER_SRGB)); /* Dithering shouldn't be performed for glBlitFramebuffer */ _mesa_set_enable(ctx, GL_DITHER, GL_FALSE); /* If the clipping earlier changed the destination rect at all, then * enable the scissor to clip to it. */ if (clip.dstX0 != dstX0 || clip.dstY0 != dstY0 || clip.dstX1 != dstX1 || clip.dstY1 != dstY1) { _mesa_set_enable(ctx, GL_SCISSOR_TEST, GL_TRUE); _mesa_Scissor(MIN2(clip.dstX0, clip.dstX1), MIN2(clip.dstY0, clip.dstY1), abs(clip.dstX0 - clip.dstX1), abs(clip.dstY0 - clip.dstY1)); } /* Try faster, direct texture approach first */ if (mask & GL_COLOR_BUFFER_BIT) { if (blitframebuffer_texture(ctx, readFb, drawFb, srcX0, srcY0, srcX1, srcY1, dstX0, dstY0, dstX1, dstY1, filter, dstFlipX, dstFlipY, use_glsl_version, false)) { mask &= ~GL_COLOR_BUFFER_BIT; } } if (mask & GL_DEPTH_BUFFER_BIT && use_glsl_version) { if (blitframebuffer_texture(ctx, readFb, drawFb, srcX0, srcY0, srcX1, srcY1, dstX0, dstY0, dstX1, dstY1, filter, dstFlipX, dstFlipY, use_glsl_version, true)) { mask &= ~GL_DEPTH_BUFFER_BIT; } } if (mask & GL_STENCIL_BUFFER_BIT) { /* XXX can't easily do stencil */ } _mesa_meta_end(ctx); return mask; } void _mesa_meta_glsl_blit_cleanup(struct gl_context *ctx, struct blit_state *blit) { if (blit->VAO) { _mesa_DeleteVertexArrays(1, &blit->VAO); blit->VAO = 0; _mesa_reference_buffer_object(ctx, &blit->buf_obj, NULL); } _mesa_meta_blit_shader_table_cleanup(ctx, &blit->shaders_with_depth); _mesa_meta_blit_shader_table_cleanup(ctx, &blit->shaders_without_depth); _mesa_DeleteTextures(1, &blit->depthTex.TexObj); blit->depthTex.TexObj = 0; } void _mesa_meta_and_swrast_BlitFramebuffer(struct gl_context *ctx, struct gl_framebuffer *readFb, struct gl_framebuffer *drawFb, GLint srcX0, GLint srcY0, GLint srcX1, GLint srcY1, GLint dstX0, GLint dstY0, GLint dstX1, GLint dstY1, GLbitfield mask, GLenum filter) { mask = _mesa_meta_BlitFramebuffer(ctx, readFb, drawFb, srcX0, srcY0, srcX1, srcY1, dstX0, dstY0, dstX1, dstY1, mask, filter); if (mask == 0x0) return; _swrast_BlitFramebuffer(ctx, readFb, drawFb, srcX0, srcY0, srcX1, srcY1, dstX0, dstY0, dstX1, dstY1, mask, filter); }