/* * Copyright © 2014-2017 Broadcom * * 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 (including the next * paragraph) 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 "util/u_format.h" #include "util/u_half.h" #include "vc5_context.h" #include "broadcom/cle/v3d_packet_v33_pack.h" #include "broadcom/compiler/v3d_compiler.h" static uint8_t vc5_factor(enum pipe_blendfactor factor, bool dst_alpha_one) { /* We may get a bad blendfactor when blending is disabled. */ if (factor == 0) return V3D_BLEND_FACTOR_ZERO; switch (factor) { case PIPE_BLENDFACTOR_ZERO: return V3D_BLEND_FACTOR_ZERO; case PIPE_BLENDFACTOR_ONE: return V3D_BLEND_FACTOR_ONE; case PIPE_BLENDFACTOR_SRC_COLOR: return V3D_BLEND_FACTOR_SRC_COLOR; case PIPE_BLENDFACTOR_INV_SRC_COLOR: return V3D_BLEND_FACTOR_INV_SRC_COLOR; case PIPE_BLENDFACTOR_DST_COLOR: return V3D_BLEND_FACTOR_DST_COLOR; case PIPE_BLENDFACTOR_INV_DST_COLOR: return V3D_BLEND_FACTOR_INV_DST_COLOR; case PIPE_BLENDFACTOR_SRC_ALPHA: return V3D_BLEND_FACTOR_SRC_ALPHA; case PIPE_BLENDFACTOR_INV_SRC_ALPHA: return V3D_BLEND_FACTOR_INV_SRC_ALPHA; case PIPE_BLENDFACTOR_DST_ALPHA: return (dst_alpha_one ? V3D_BLEND_FACTOR_ONE : V3D_BLEND_FACTOR_DST_ALPHA); case PIPE_BLENDFACTOR_INV_DST_ALPHA: return (dst_alpha_one ? V3D_BLEND_FACTOR_ZERO : V3D_BLEND_FACTOR_INV_DST_ALPHA); case PIPE_BLENDFACTOR_CONST_COLOR: return V3D_BLEND_FACTOR_CONST_COLOR; case PIPE_BLENDFACTOR_INV_CONST_COLOR: return V3D_BLEND_FACTOR_INV_CONST_COLOR; case PIPE_BLENDFACTOR_CONST_ALPHA: return V3D_BLEND_FACTOR_CONST_ALPHA; case PIPE_BLENDFACTOR_INV_CONST_ALPHA: return V3D_BLEND_FACTOR_INV_CONST_ALPHA; case PIPE_BLENDFACTOR_SRC_ALPHA_SATURATE: return V3D_BLEND_FACTOR_SRC_ALPHA_SATURATE; default: unreachable("Bad blend factor"); } } static inline uint16_t swizzled_border_color(struct pipe_sampler_state *sampler, struct vc5_sampler_view *sview, int chan) { const struct util_format_description *desc = util_format_description(sview->base.format); uint8_t swiz = chan; /* If we're doing swizzling in the sampler, then only rearrange the * border color for the mismatch between the VC5 texture format and * the PIPE_FORMAT, since GL_ARB_texture_swizzle will be handled by * the sampler's swizzle. * * For swizzling in the shader, we don't do any pre-swizzling of the * border color. */ if (vc5_get_tex_return_size(sview->base.format) != 32) swiz = desc->swizzle[swiz]; switch (swiz) { case PIPE_SWIZZLE_0: return util_float_to_half(0.0); case PIPE_SWIZZLE_1: return util_float_to_half(1.0); default: return util_float_to_half(sampler->border_color.f[swiz]); } } static void emit_one_texture(struct vc5_context *vc5, struct vc5_texture_stateobj *stage_tex, int i) { struct vc5_job *job = vc5->job; struct pipe_sampler_state *psampler = stage_tex->samplers[i]; struct vc5_sampler_state *sampler = vc5_sampler_state(psampler); struct pipe_sampler_view *psview = stage_tex->textures[i]; struct vc5_sampler_view *sview = vc5_sampler_view(psview); struct pipe_resource *prsc = psview->texture; struct vc5_resource *rsc = vc5_resource(prsc); stage_tex->texture_state[i].offset = vc5_cl_ensure_space(&job->indirect, cl_packet_length(TEXTURE_SHADER_STATE), 32); vc5_bo_set_reference(&stage_tex->texture_state[i].bo, job->indirect.bo); struct V3D33_TEXTURE_SHADER_STATE unpacked = { /* XXX */ .border_color_red = swizzled_border_color(psampler, sview, 0), .border_color_green = swizzled_border_color(psampler, sview, 1), .border_color_blue = swizzled_border_color(psampler, sview, 2), .border_color_alpha = swizzled_border_color(psampler, sview, 3), /* In the normal texturing path, the LOD gets clamped between * min/max, and the base_level field (set in the sampler view * from first_level) only decides where the min/mag switch * happens, so we need to use the LOD clamps to keep us * between min and max. * * For txf, the LOD clamp is still used, despite GL not * wanting that. We will need to have a separate * TEXTURE_SHADER_STATE that ignores psview->min/max_lod to * support txf properly. */ .min_level_of_detail = (psview->u.tex.first_level + MAX2(psampler->min_lod, 0)), .max_level_of_detail = MIN2(psview->u.tex.first_level + psampler->max_lod, psview->u.tex.last_level), .texture_base_pointer = cl_address(rsc->bo, rsc->slices[0].offset), }; int min_img_filter = psampler->min_img_filter; int min_mip_filter = psampler->min_mip_filter; int mag_img_filter = psampler->mag_img_filter; if (vc5_get_tex_return_size(psview->format) == 32) { min_mip_filter = PIPE_TEX_MIPFILTER_NEAREST; mag_img_filter = PIPE_TEX_FILTER_NEAREST; mag_img_filter = PIPE_TEX_FILTER_NEAREST; } bool min_nearest = min_img_filter == PIPE_TEX_FILTER_NEAREST; switch (min_mip_filter) { case PIPE_TEX_MIPFILTER_NONE: unpacked.filter += min_nearest ? 2 : 0; break; case PIPE_TEX_MIPFILTER_NEAREST: unpacked.filter += min_nearest ? 4 : 8; break; case PIPE_TEX_MIPFILTER_LINEAR: unpacked.filter += min_nearest ? 4 : 8; unpacked.filter += 2; break; } if (mag_img_filter == PIPE_TEX_FILTER_NEAREST) unpacked.filter++; if (psampler->max_anisotropy > 8) unpacked.filter = V3D_TMU_FILTER_ANISOTROPIC_16_1; else if (psampler->max_anisotropy > 4) unpacked.filter = V3D_TMU_FILTER_ANISOTROPIC_8_1; else if (psampler->max_anisotropy > 2) unpacked.filter = V3D_TMU_FILTER_ANISOTROPIC_4_1; else if (psampler->max_anisotropy) unpacked.filter = V3D_TMU_FILTER_ANISOTROPIC_2_1; uint8_t packed[cl_packet_length(TEXTURE_SHADER_STATE)]; cl_packet_pack(TEXTURE_SHADER_STATE)(&job->indirect, packed, &unpacked); for (int i = 0; i < ARRAY_SIZE(packed); i++) packed[i] |= sview->texture_shader_state[i] | sampler->texture_shader_state[i]; /* TMU indirect structs need to be 32b aligned. */ vc5_cl_ensure_space(&job->indirect, ARRAY_SIZE(packed), 32); cl_emit_prepacked(&job->indirect, &packed); } static void emit_textures(struct vc5_context *vc5, struct vc5_texture_stateobj *stage_tex) { for (int i = 0; i < stage_tex->num_textures; i++) { if (stage_tex->textures[i]) emit_one_texture(vc5, stage_tex, i); } } void vc5_emit_state(struct pipe_context *pctx) { struct vc5_context *vc5 = vc5_context(pctx); struct vc5_job *job = vc5->job; if (vc5->dirty & (VC5_DIRTY_SCISSOR | VC5_DIRTY_VIEWPORT | VC5_DIRTY_RASTERIZER)) { float *vpscale = vc5->viewport.scale; float *vptranslate = vc5->viewport.translate; float vp_minx = -fabsf(vpscale[0]) + vptranslate[0]; float vp_maxx = fabsf(vpscale[0]) + vptranslate[0]; float vp_miny = -fabsf(vpscale[1]) + vptranslate[1]; float vp_maxy = fabsf(vpscale[1]) + vptranslate[1]; /* Clip to the scissor if it's enabled, but still clip to the * drawable regardless since that controls where the binner * tries to put things. * * Additionally, always clip the rendering to the viewport, * since the hardware does guardband clipping, meaning * primitives would rasterize outside of the view volume. */ uint32_t minx, miny, maxx, maxy; if (!vc5->rasterizer->base.scissor) { minx = MAX2(vp_minx, 0); miny = MAX2(vp_miny, 0); maxx = MIN2(vp_maxx, job->draw_width); maxy = MIN2(vp_maxy, job->draw_height); } else { minx = MAX2(vp_minx, vc5->scissor.minx); miny = MAX2(vp_miny, vc5->scissor.miny); maxx = MIN2(vp_maxx, vc5->scissor.maxx); maxy = MIN2(vp_maxy, vc5->scissor.maxy); } cl_emit(&job->bcl, CLIP_WINDOW, clip) { clip.clip_window_left_pixel_coordinate = minx; clip.clip_window_bottom_pixel_coordinate = miny; clip.clip_window_width_in_pixels = maxx - minx; clip.clip_window_height_in_pixels = maxy - miny; } job->draw_min_x = MIN2(job->draw_min_x, minx); job->draw_min_y = MIN2(job->draw_min_y, miny); job->draw_max_x = MAX2(job->draw_max_x, maxx); job->draw_max_y = MAX2(job->draw_max_y, maxy); } if (vc5->dirty & (VC5_DIRTY_RASTERIZER | VC5_DIRTY_ZSA | VC5_DIRTY_BLEND | VC5_DIRTY_COMPILED_FS)) { cl_emit(&job->bcl, CONFIGURATION_BITS, config) { config.enable_forward_facing_primitive = !vc5->rasterizer->base.rasterizer_discard && !(vc5->rasterizer->base.cull_face & PIPE_FACE_FRONT); config.enable_reverse_facing_primitive = !vc5->rasterizer->base.rasterizer_discard && !(vc5->rasterizer->base.cull_face & PIPE_FACE_BACK); /* This seems backwards, but it's what gets the * clipflat test to pass. */ config.clockwise_primitives = vc5->rasterizer->base.front_ccw; config.enable_depth_offset = vc5->rasterizer->base.offset_tri; config.rasterizer_oversample_mode = vc5->rasterizer->base.multisample; config.direct3d_provoking_vertex = vc5->rasterizer->base.flatshade_first; config.blend_enable = vc5->blend->rt[0].blend_enable; config.early_z_updates_enable = true; if (vc5->zsa->base.depth.enabled) { config.z_updates_enable = vc5->zsa->base.depth.writemask; config.early_z_enable = (vc5->zsa->early_z_enable && !vc5->prog.fs->prog_data.fs->writes_z); config.depth_test_function = vc5->zsa->base.depth.func; } else { config.depth_test_function = PIPE_FUNC_ALWAYS; } config.stencil_enable = vc5->zsa->base.stencil[0].enabled; } } if (vc5->dirty & VC5_DIRTY_RASTERIZER && vc5->rasterizer->base.offset_tri) { cl_emit(&job->bcl, DEPTH_OFFSET, depth) { depth.depth_offset_factor = vc5->rasterizer->offset_factor; depth.depth_offset_units = vc5->rasterizer->offset_units; } } if (vc5->dirty & VC5_DIRTY_RASTERIZER) { cl_emit(&job->bcl, POINT_SIZE, point_size) { point_size.point_size = vc5->rasterizer->point_size; } cl_emit(&job->bcl, LINE_WIDTH, line_width) { line_width.line_width = vc5->rasterizer->base.line_width; } } if (vc5->dirty & VC5_DIRTY_VIEWPORT) { cl_emit(&job->bcl, CLIPPER_XY_SCALING, clip) { clip.viewport_half_width_in_1_256th_of_pixel = vc5->viewport.scale[0] * 256.0f; clip.viewport_half_height_in_1_256th_of_pixel = vc5->viewport.scale[1] * 256.0f; } cl_emit(&job->bcl, CLIPPER_Z_SCALE_AND_OFFSET, clip) { clip.viewport_z_offset_zc_to_zs = vc5->viewport.translate[2]; clip.viewport_z_scale_zc_to_zs = vc5->viewport.scale[2]; } if (0 /* XXX */) { cl_emit(&job->bcl, CLIPPER_Z_MIN_MAX_CLIPPING_PLANES, clip) { clip.minimum_zw = (vc5->viewport.translate[2] - vc5->viewport.scale[2]); clip.maximum_zw = (vc5->viewport.translate[2] + vc5->viewport.scale[2]); } } cl_emit(&job->bcl, VIEWPORT_OFFSET, vp) { vp.viewport_centre_x_coordinate = vc5->viewport.translate[0]; vp.viewport_centre_y_coordinate = vc5->viewport.translate[1]; } } if (vc5->dirty & VC5_DIRTY_BLEND && vc5->blend->rt[0].blend_enable) { struct pipe_blend_state *blend = vc5->blend; cl_emit(&job->bcl, BLEND_CONFIG, config) { struct pipe_rt_blend_state *rtblend = &blend->rt[0]; config.colour_blend_mode = rtblend->rgb_func; config.colour_blend_dst_factor = vc5_factor(rtblend->rgb_dst_factor, vc5->blend_dst_alpha_one); config.colour_blend_src_factor = vc5_factor(rtblend->rgb_src_factor, vc5->blend_dst_alpha_one); config.alpha_blend_mode = rtblend->alpha_func; config.alpha_blend_dst_factor = vc5_factor(rtblend->alpha_dst_factor, vc5->blend_dst_alpha_one); config.alpha_blend_src_factor = vc5_factor(rtblend->alpha_src_factor, vc5->blend_dst_alpha_one); } } if (vc5->dirty & VC5_DIRTY_BLEND) { struct pipe_blend_state *blend = vc5->blend; cl_emit(&job->bcl, COLOUR_WRITE_MASKS, mask) { if (blend->independent_blend_enable) { mask.render_target_0_per_colour_component_write_masks = (~blend->rt[0].colormask) & 0xf; mask.render_target_1_per_colour_component_write_masks = (~blend->rt[1].colormask) & 0xf; mask.render_target_2_per_colour_component_write_masks = (~blend->rt[2].colormask) & 0xf; mask.render_target_3_per_colour_component_write_masks = (~blend->rt[3].colormask) & 0xf; } else { uint8_t colormask = (~blend->rt[0].colormask) & 0xf; mask.render_target_0_per_colour_component_write_masks = colormask; mask.render_target_1_per_colour_component_write_masks = colormask; mask.render_target_2_per_colour_component_write_masks = colormask; mask.render_target_3_per_colour_component_write_masks = colormask; } } } if (vc5->dirty & VC5_DIRTY_BLEND_COLOR) { cl_emit(&job->bcl, BLEND_CONSTANT_COLOUR, colour) { colour.red_f16 = (vc5->swap_color_rb ? vc5->blend_color.hf[2] : vc5->blend_color.hf[0]); colour.green_f16 = vc5->blend_color.hf[1]; colour.blue_f16 = (vc5->swap_color_rb ? vc5->blend_color.hf[0] : vc5->blend_color.hf[2]); colour.alpha_f16 = vc5->blend_color.hf[3]; } } if (vc5->dirty & (VC5_DIRTY_ZSA | VC5_DIRTY_STENCIL_REF)) { struct pipe_stencil_state *front = &vc5->zsa->base.stencil[0]; struct pipe_stencil_state *back = &vc5->zsa->base.stencil[1]; if (front->enabled) { cl_emit_with_prepacked(&job->bcl, STENCIL_CONFIG, vc5->zsa->stencil_front, config) { config.stencil_ref_value = vc5->stencil_ref.ref_value[1]; } } if (back->enabled) { cl_emit_with_prepacked(&job->bcl, STENCIL_CONFIG, vc5->zsa->stencil_back, config) { config.stencil_ref_value = vc5->stencil_ref.ref_value[1]; } } } if (vc5->dirty & VC5_DIRTY_FRAGTEX) emit_textures(vc5, &vc5->fragtex); if (vc5->dirty & VC5_DIRTY_VERTTEX) emit_textures(vc5, &vc5->verttex); if (vc5->dirty & VC5_DIRTY_FLAT_SHADE_FLAGS) { /* XXX: Need to handle more than 24 entries. */ cl_emit(&job->bcl, FLAT_SHADE_FLAGS, flags) { flags.varying_offset_v0 = 0; flags.flat_shade_flags_for_varyings_v024 = vc5->prog.fs->prog_data.fs->flat_shade_flags[0] & 0xfffff; if (vc5->rasterizer->base.flatshade) { flags.flat_shade_flags_for_varyings_v024 |= vc5->prog.fs->prog_data.fs->shade_model_flags[0] & 0xfffff; } } } if (vc5->dirty & VC5_DIRTY_STREAMOUT) { struct vc5_streamout_stateobj *so = &vc5->streamout; if (so->num_targets) { cl_emit(&job->bcl, TRANSFORM_FEEDBACK_ENABLE, tfe) { tfe.number_of_32_bit_output_buffer_address_following = so->num_targets; tfe.number_of_16_bit_output_data_specs_following = vc5->prog.bind_vs->num_tf_specs; }; for (int i = 0; i < vc5->prog.bind_vs->num_tf_specs; i++) { cl_emit_prepacked(&job->bcl, &vc5->prog.bind_vs->tf_specs[i]); } for (int i = 0; i < so->num_targets; i++) { const struct pipe_stream_output_target *target = so->targets[i]; struct vc5_resource *rsc = vc5_resource(target->buffer); cl_emit(&job->bcl, TRANSFORM_FEEDBACK_OUTPUT_ADDRESS, output) { output.address = cl_address(rsc->bo, target->buffer_offset); }; vc5_job_add_write_resource(vc5->job, target->buffer); /* XXX: buffer_size? */ } } else { /* XXX? */ } } if (vc5->dirty & VC5_DIRTY_OQ) { cl_emit(&job->bcl, OCCLUSION_QUERY_COUNTER, counter) { job->oq_enabled = vc5->active_queries && vc5->current_oq; if (job->oq_enabled) { counter.address = cl_address(vc5->current_oq, 0); } } } }