/* * Mesa 3-D graphics library * * Copyright (C) 2012-2013 LunarG, Inc. * * 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. * * Authors: * Chia-I Wu */ #ifndef ILO_GPE_GEN6_H #define ILO_GPE_GEN6_H #include "brw_defines.h" #include "intel_reg.h" #include "intel_winsys.h" #include "ilo_common.h" #include "ilo_cp.h" #include "ilo_format.h" #include "ilo_resource.h" #include "ilo_shader.h" #include "ilo_gpe.h" #define ILO_GPE_VALID_GEN(dev, min_gen, max_gen) \ assert((dev)->gen >= ILO_GEN(min_gen) && (dev)->gen <= ILO_GEN(max_gen)) #define ILO_GPE_CMD(pipeline, op, subop) \ (0x3 << 29 | (pipeline) << 27 | (op) << 24 | (subop) << 16) /** * Commands that GEN6 GPE could emit. */ enum ilo_gpe_gen6_command { ILO_GPE_GEN6_STATE_BASE_ADDRESS, /* (0x0, 0x1, 0x01) */ ILO_GPE_GEN6_STATE_SIP, /* (0x0, 0x1, 0x02) */ ILO_GPE_GEN6_3DSTATE_VF_STATISTICS, /* (0x1, 0x0, 0x0b) */ ILO_GPE_GEN6_PIPELINE_SELECT, /* (0x1, 0x1, 0x04) */ ILO_GPE_GEN6_MEDIA_VFE_STATE, /* (0x2, 0x0, 0x00) */ ILO_GPE_GEN6_MEDIA_CURBE_LOAD, /* (0x2, 0x0, 0x01) */ ILO_GPE_GEN6_MEDIA_INTERFACE_DESCRIPTOR_LOAD, /* (0x2, 0x0, 0x02) */ ILO_GPE_GEN6_MEDIA_GATEWAY_STATE, /* (0x2, 0x0, 0x03) */ ILO_GPE_GEN6_MEDIA_STATE_FLUSH, /* (0x2, 0x0, 0x04) */ ILO_GPE_GEN6_MEDIA_OBJECT_WALKER, /* (0x2, 0x1, 0x03) */ ILO_GPE_GEN6_3DSTATE_BINDING_TABLE_POINTERS, /* (0x3, 0x0, 0x01) */ ILO_GPE_GEN6_3DSTATE_SAMPLER_STATE_POINTERS, /* (0x3, 0x0, 0x02) */ ILO_GPE_GEN6_3DSTATE_URB, /* (0x3, 0x0, 0x05) */ ILO_GPE_GEN6_3DSTATE_VERTEX_BUFFERS, /* (0x3, 0x0, 0x08) */ ILO_GPE_GEN6_3DSTATE_VERTEX_ELEMENTS, /* (0x3, 0x0, 0x09) */ ILO_GPE_GEN6_3DSTATE_INDEX_BUFFER, /* (0x3, 0x0, 0x0a) */ ILO_GPE_GEN6_3DSTATE_VIEWPORT_STATE_POINTERS, /* (0x3, 0x0, 0x0d) */ ILO_GPE_GEN6_3DSTATE_CC_STATE_POINTERS, /* (0x3, 0x0, 0x0e) */ ILO_GPE_GEN6_3DSTATE_SCISSOR_STATE_POINTERS, /* (0x3, 0x0, 0x0f) */ ILO_GPE_GEN6_3DSTATE_VS, /* (0x3, 0x0, 0x10) */ ILO_GPE_GEN6_3DSTATE_GS, /* (0x3, 0x0, 0x11) */ ILO_GPE_GEN6_3DSTATE_CLIP, /* (0x3, 0x0, 0x12) */ ILO_GPE_GEN6_3DSTATE_SF, /* (0x3, 0x0, 0x13) */ ILO_GPE_GEN6_3DSTATE_WM, /* (0x3, 0x0, 0x14) */ ILO_GPE_GEN6_3DSTATE_CONSTANT_VS, /* (0x3, 0x0, 0x15) */ ILO_GPE_GEN6_3DSTATE_CONSTANT_GS, /* (0x3, 0x0, 0x16) */ ILO_GPE_GEN6_3DSTATE_CONSTANT_PS, /* (0x3, 0x0, 0x17) */ ILO_GPE_GEN6_3DSTATE_SAMPLE_MASK, /* (0x3, 0x0, 0x18) */ ILO_GPE_GEN6_3DSTATE_DRAWING_RECTANGLE, /* (0x3, 0x1, 0x00) */ ILO_GPE_GEN6_3DSTATE_DEPTH_BUFFER, /* (0x3, 0x1, 0x05) */ ILO_GPE_GEN6_3DSTATE_POLY_STIPPLE_OFFSET, /* (0x3, 0x1, 0x06) */ ILO_GPE_GEN6_3DSTATE_POLY_STIPPLE_PATTERN, /* (0x3, 0x1, 0x07) */ ILO_GPE_GEN6_3DSTATE_LINE_STIPPLE, /* (0x3, 0x1, 0x08) */ ILO_GPE_GEN6_3DSTATE_AA_LINE_PARAMETERS, /* (0x3, 0x1, 0x0a) */ ILO_GPE_GEN6_3DSTATE_GS_SVB_INDEX, /* (0x3, 0x1, 0x0b) */ ILO_GPE_GEN6_3DSTATE_MULTISAMPLE, /* (0x3, 0x1, 0x0d) */ ILO_GPE_GEN6_3DSTATE_STENCIL_BUFFER, /* (0x3, 0x1, 0x0e) */ ILO_GPE_GEN6_3DSTATE_HIER_DEPTH_BUFFER, /* (0x3, 0x1, 0x0f) */ ILO_GPE_GEN6_3DSTATE_CLEAR_PARAMS, /* (0x3, 0x1, 0x10) */ ILO_GPE_GEN6_PIPE_CONTROL, /* (0x3, 0x2, 0x00) */ ILO_GPE_GEN6_3DPRIMITIVE, /* (0x3, 0x3, 0x00) */ ILO_GPE_GEN6_COMMAND_COUNT, }; /** * Indirect states that GEN6 GPE could emit. */ enum ilo_gpe_gen6_state { ILO_GPE_GEN6_INTERFACE_DESCRIPTOR_DATA, ILO_GPE_GEN6_SF_VIEWPORT, ILO_GPE_GEN6_CLIP_VIEWPORT, ILO_GPE_GEN6_CC_VIEWPORT, ILO_GPE_GEN6_COLOR_CALC_STATE, ILO_GPE_GEN6_BLEND_STATE, ILO_GPE_GEN6_DEPTH_STENCIL_STATE, ILO_GPE_GEN6_SCISSOR_RECT, ILO_GPE_GEN6_BINDING_TABLE_STATE, ILO_GPE_GEN6_SURFACE_STATE, ILO_GPE_GEN6_SAMPLER_STATE, ILO_GPE_GEN6_SAMPLER_BORDER_COLOR_STATE, ILO_GPE_GEN6_PUSH_CONSTANT_BUFFER, ILO_GPE_GEN6_STATE_COUNT, }; int ilo_gpe_gen6_estimate_command_size(const struct ilo_dev_info *dev, enum ilo_gpe_gen6_command cmd, int arg); int ilo_gpe_gen6_estimate_state_size(const struct ilo_dev_info *dev, enum ilo_gpe_gen6_state state, int arg); /** * Translate winsys tiling to hardware tiling. */ static inline int ilo_gpe_gen6_translate_winsys_tiling(enum intel_tiling_mode tiling) { switch (tiling) { case INTEL_TILING_NONE: return 0; case INTEL_TILING_X: return BRW_SURFACE_TILED; case INTEL_TILING_Y: return BRW_SURFACE_TILED | BRW_SURFACE_TILED_Y; default: assert(!"unknown tiling"); return 0; } } /** * Translate a pipe primitive type to the matching hardware primitive type. */ static inline int ilo_gpe_gen6_translate_pipe_prim(unsigned prim) { static const int prim_mapping[PIPE_PRIM_MAX] = { [PIPE_PRIM_POINTS] = _3DPRIM_POINTLIST, [PIPE_PRIM_LINES] = _3DPRIM_LINELIST, [PIPE_PRIM_LINE_LOOP] = _3DPRIM_LINELOOP, [PIPE_PRIM_LINE_STRIP] = _3DPRIM_LINESTRIP, [PIPE_PRIM_TRIANGLES] = _3DPRIM_TRILIST, [PIPE_PRIM_TRIANGLE_STRIP] = _3DPRIM_TRISTRIP, [PIPE_PRIM_TRIANGLE_FAN] = _3DPRIM_TRIFAN, [PIPE_PRIM_QUADS] = _3DPRIM_QUADLIST, [PIPE_PRIM_QUAD_STRIP] = _3DPRIM_QUADSTRIP, [PIPE_PRIM_POLYGON] = _3DPRIM_POLYGON, [PIPE_PRIM_LINES_ADJACENCY] = _3DPRIM_LINELIST_ADJ, [PIPE_PRIM_LINE_STRIP_ADJACENCY] = _3DPRIM_LINESTRIP_ADJ, [PIPE_PRIM_TRIANGLES_ADJACENCY] = _3DPRIM_TRILIST_ADJ, [PIPE_PRIM_TRIANGLE_STRIP_ADJACENCY] = _3DPRIM_TRISTRIP_ADJ, }; assert(prim_mapping[prim]); return prim_mapping[prim]; } /** * Translate a pipe texture target to the matching hardware surface type. */ static inline int ilo_gpe_gen6_translate_texture(enum pipe_texture_target target) { switch (target) { case PIPE_BUFFER: return BRW_SURFACE_BUFFER; case PIPE_TEXTURE_1D: case PIPE_TEXTURE_1D_ARRAY: return BRW_SURFACE_1D; case PIPE_TEXTURE_2D: case PIPE_TEXTURE_RECT: case PIPE_TEXTURE_2D_ARRAY: return BRW_SURFACE_2D; case PIPE_TEXTURE_3D: return BRW_SURFACE_3D; case PIPE_TEXTURE_CUBE: case PIPE_TEXTURE_CUBE_ARRAY: return BRW_SURFACE_CUBE; default: assert(!"unknown texture target"); return BRW_SURFACE_BUFFER; } } /** * Fill in DW2 to DW7 of 3DSTATE_SF. */ static inline void ilo_gpe_gen6_fill_3dstate_sf_raster(const struct ilo_dev_info *dev, const struct ilo_rasterizer_state *rasterizer, int num_samples, enum pipe_format depth_format, uint32_t *payload, unsigned payload_len) { assert(payload_len == Elements(rasterizer->sf.payload)); if (rasterizer) { const struct ilo_rasterizer_sf *sf = &rasterizer->sf; memcpy(payload, sf->payload, sizeof(sf->payload)); if (num_samples > 1) payload[1] |= sf->dw_msaa; } else { payload[0] = 0; payload[1] = (num_samples > 1) ? GEN6_SF_MSRAST_ON_PATTERN : 0; payload[2] = 0; payload[3] = 0; payload[4] = 0; payload[5] = 0; } if (dev->gen >= ILO_GEN(7)) { int format; /* separate stencil */ switch (depth_format) { case PIPE_FORMAT_Z16_UNORM: format = BRW_DEPTHFORMAT_D16_UNORM; break; case PIPE_FORMAT_Z32_FLOAT: case PIPE_FORMAT_Z32_FLOAT_S8X24_UINT: format = BRW_DEPTHFORMAT_D32_FLOAT; break; case PIPE_FORMAT_Z24X8_UNORM: case PIPE_FORMAT_Z24_UNORM_S8_UINT: format = BRW_DEPTHFORMAT_D24_UNORM_X8_UINT; break; default: /* FLOAT surface is assumed when there is no depth buffer */ format = BRW_DEPTHFORMAT_D32_FLOAT; break; } payload[0] |= format << GEN7_SF_DEPTH_BUFFER_SURFACE_FORMAT_SHIFT; } } /** * Fill in DW1 and DW8 to DW19 of 3DSTATE_SF. */ static inline void ilo_gpe_gen6_fill_3dstate_sf_sbe(const struct ilo_dev_info *dev, const struct ilo_rasterizer_state *rasterizer, const struct ilo_shader_state *fs, uint32_t *dw, int num_dwords) { int output_count, vue_offset, vue_len; const struct ilo_kernel_routing *routing; ILO_GPE_VALID_GEN(dev, 6, 7.5); assert(num_dwords == 13); if (!fs) { memset(dw, 0, sizeof(dw[0]) * num_dwords); if (dev->gen >= ILO_GEN(7)) dw[0] = 1 << GEN7_SBE_URB_ENTRY_READ_LENGTH_SHIFT; else dw[0] = 1 << GEN6_SF_URB_ENTRY_READ_LENGTH_SHIFT; return; } output_count = ilo_shader_get_kernel_param(fs, ILO_KERNEL_INPUT_COUNT); assert(output_count <= 32); routing = ilo_shader_get_kernel_routing(fs); vue_offset = routing->source_skip; assert(vue_offset % 2 == 0); vue_offset /= 2; vue_len = (routing->source_len + 1) / 2; if (!vue_len) vue_len = 1; if (dev->gen >= ILO_GEN(7)) { dw[0] = output_count << GEN7_SBE_NUM_OUTPUTS_SHIFT | vue_len << GEN7_SBE_URB_ENTRY_READ_LENGTH_SHIFT | vue_offset << GEN7_SBE_URB_ENTRY_READ_OFFSET_SHIFT; if (routing->swizzle_enable) dw[0] |= GEN7_SBE_SWIZZLE_ENABLE; } else { dw[0] = output_count << GEN6_SF_NUM_OUTPUTS_SHIFT | vue_len << GEN6_SF_URB_ENTRY_READ_LENGTH_SHIFT | vue_offset << GEN6_SF_URB_ENTRY_READ_OFFSET_SHIFT; if (routing->swizzle_enable) dw[0] |= GEN6_SF_SWIZZLE_ENABLE; } switch (rasterizer->state.sprite_coord_mode) { case PIPE_SPRITE_COORD_UPPER_LEFT: dw[0] |= GEN6_SF_POINT_SPRITE_UPPERLEFT; break; case PIPE_SPRITE_COORD_LOWER_LEFT: dw[0] |= GEN6_SF_POINT_SPRITE_LOWERLEFT; break; } STATIC_ASSERT(Elements(routing->swizzles) >= 16); memcpy(&dw[1], routing->swizzles, 2 * 16); /* * From the Ivy Bridge PRM, volume 2 part 1, page 268: * * "This field (Point Sprite Texture Coordinate Enable) must be * programmed to 0 when non-point primitives are rendered." * * TODO We do not check that yet. */ dw[9] = routing->point_sprite_enable; dw[10] = routing->const_interp_enable; /* WrapShortest enables */ dw[11] = 0; dw[12] = 0; } static inline void gen6_emit_STATE_BASE_ADDRESS(const struct ilo_dev_info *dev, struct intel_bo *general_state_bo, struct intel_bo *surface_state_bo, struct intel_bo *dynamic_state_bo, struct intel_bo *indirect_object_bo, struct intel_bo *instruction_bo, uint32_t general_state_size, uint32_t dynamic_state_size, uint32_t indirect_object_size, uint32_t instruction_size, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x0, 0x1, 0x01); const uint8_t cmd_len = 10; ILO_GPE_VALID_GEN(dev, 6, 7.5); /* 4K-page aligned */ assert(((general_state_size | dynamic_state_size | indirect_object_size | instruction_size) & 0xfff) == 0); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write_bo(cp, 1, general_state_bo, INTEL_DOMAIN_RENDER, 0); ilo_cp_write_bo(cp, 1, surface_state_bo, INTEL_DOMAIN_SAMPLER, 0); ilo_cp_write_bo(cp, 1, dynamic_state_bo, INTEL_DOMAIN_RENDER | INTEL_DOMAIN_INSTRUCTION, 0); ilo_cp_write_bo(cp, 1, indirect_object_bo, 0, 0); ilo_cp_write_bo(cp, 1, instruction_bo, INTEL_DOMAIN_INSTRUCTION, 0); if (general_state_size) { ilo_cp_write_bo(cp, general_state_size | 1, general_state_bo, INTEL_DOMAIN_RENDER, 0); } else { /* skip range check */ ilo_cp_write(cp, 1); } if (dynamic_state_size) { ilo_cp_write_bo(cp, dynamic_state_size | 1, dynamic_state_bo, INTEL_DOMAIN_RENDER | INTEL_DOMAIN_INSTRUCTION, 0); } else { /* skip range check */ ilo_cp_write(cp, 0xfffff000 + 1); } if (indirect_object_size) { ilo_cp_write_bo(cp, indirect_object_size | 1, indirect_object_bo, 0, 0); } else { /* skip range check */ ilo_cp_write(cp, 0xfffff000 + 1); } if (instruction_size) { ilo_cp_write_bo(cp, instruction_size | 1, instruction_bo, INTEL_DOMAIN_INSTRUCTION, 0); } else { /* skip range check */ ilo_cp_write(cp, 1); } ilo_cp_end(cp); } static inline void gen6_emit_STATE_SIP(const struct ilo_dev_info *dev, uint32_t sip, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x0, 0x1, 0x02); const uint8_t cmd_len = 2; ILO_GPE_VALID_GEN(dev, 6, 7.5); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, sip); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_VF_STATISTICS(const struct ilo_dev_info *dev, bool enable, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x1, 0x0, 0x0b); const uint8_t cmd_len = 1; ILO_GPE_VALID_GEN(dev, 6, 7.5); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | enable); ilo_cp_end(cp); } static inline void gen6_emit_PIPELINE_SELECT(const struct ilo_dev_info *dev, int pipeline, struct ilo_cp *cp) { const int cmd = ILO_GPE_CMD(0x1, 0x1, 0x04); const uint8_t cmd_len = 1; ILO_GPE_VALID_GEN(dev, 6, 7.5); /* 3D or media */ assert(pipeline == 0x0 || pipeline == 0x1); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | pipeline); ilo_cp_end(cp); } static inline void gen6_emit_MEDIA_VFE_STATE(const struct ilo_dev_info *dev, int max_threads, int num_urb_entries, int urb_entry_size, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x2, 0x0, 0x00); const uint8_t cmd_len = 8; uint32_t dw2, dw4; ILO_GPE_VALID_GEN(dev, 6, 6); dw2 = (max_threads - 1) << 16 | num_urb_entries << 8 | 1 << 7 | /* Reset Gateway Timer */ 1 << 6; /* Bypass Gateway Control */ dw4 = urb_entry_size << 16 | /* URB Entry Allocation Size */ 480; /* CURBE Allocation Size */ ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, 0); /* scratch */ ilo_cp_write(cp, dw2); ilo_cp_write(cp, 0); /* MBZ */ ilo_cp_write(cp, dw4); ilo_cp_write(cp, 0); /* scoreboard */ ilo_cp_write(cp, 0); ilo_cp_write(cp, 0); ilo_cp_end(cp); } static inline void gen6_emit_MEDIA_CURBE_LOAD(const struct ilo_dev_info *dev, uint32_t buf, int size, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x2, 0x0, 0x01); const uint8_t cmd_len = 4; ILO_GPE_VALID_GEN(dev, 6, 6); assert(buf % 32 == 0); /* gen6_emit_push_constant_buffer() allocates buffers in 256-bit units */ size = align(size, 32); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, 0); /* MBZ */ ilo_cp_write(cp, size); ilo_cp_write(cp, buf); ilo_cp_end(cp); } static inline void gen6_emit_MEDIA_INTERFACE_DESCRIPTOR_LOAD(const struct ilo_dev_info *dev, uint32_t offset, int num_ids, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x2, 0x0, 0x02); const uint8_t cmd_len = 4; ILO_GPE_VALID_GEN(dev, 6, 6); assert(offset % 32 == 0); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, 0); /* MBZ */ /* every ID has 8 DWords */ ilo_cp_write(cp, num_ids * 8 * 4); ilo_cp_write(cp, offset); ilo_cp_end(cp); } static inline void gen6_emit_MEDIA_GATEWAY_STATE(const struct ilo_dev_info *dev, int id, int byte, int thread_count, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x2, 0x0, 0x03); const uint8_t cmd_len = 2; uint32_t dw1; ILO_GPE_VALID_GEN(dev, 6, 6); dw1 = id << 16 | byte << 8 | thread_count; ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, dw1); ilo_cp_end(cp); } static inline void gen6_emit_MEDIA_STATE_FLUSH(const struct ilo_dev_info *dev, int thread_count_water_mark, int barrier_mask, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x2, 0x0, 0x04); const uint8_t cmd_len = 2; uint32_t dw1; ILO_GPE_VALID_GEN(dev, 6, 6); dw1 = thread_count_water_mark << 16 | barrier_mask; ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, dw1); ilo_cp_end(cp); } static inline void gen6_emit_MEDIA_OBJECT_WALKER(const struct ilo_dev_info *dev, struct ilo_cp *cp) { assert(!"MEDIA_OBJECT_WALKER unsupported"); } static inline void gen6_emit_3DSTATE_BINDING_TABLE_POINTERS(const struct ilo_dev_info *dev, uint32_t vs_binding_table, uint32_t gs_binding_table, uint32_t ps_binding_table, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x01); const uint8_t cmd_len = 4; ILO_GPE_VALID_GEN(dev, 6, 6); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2) | GEN6_BINDING_TABLE_MODIFY_VS | GEN6_BINDING_TABLE_MODIFY_GS | GEN6_BINDING_TABLE_MODIFY_PS); ilo_cp_write(cp, vs_binding_table); ilo_cp_write(cp, gs_binding_table); ilo_cp_write(cp, ps_binding_table); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_SAMPLER_STATE_POINTERS(const struct ilo_dev_info *dev, uint32_t vs_sampler_state, uint32_t gs_sampler_state, uint32_t ps_sampler_state, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x02); const uint8_t cmd_len = 4; ILO_GPE_VALID_GEN(dev, 6, 6); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2) | VS_SAMPLER_STATE_CHANGE | GS_SAMPLER_STATE_CHANGE | PS_SAMPLER_STATE_CHANGE); ilo_cp_write(cp, vs_sampler_state); ilo_cp_write(cp, gs_sampler_state); ilo_cp_write(cp, ps_sampler_state); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_URB(const struct ilo_dev_info *dev, int vs_total_size, int gs_total_size, int vs_entry_size, int gs_entry_size, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x05); const uint8_t cmd_len = 3; const int row_size = 128; /* 1024 bits */ int vs_alloc_size, gs_alloc_size; int vs_num_entries, gs_num_entries; ILO_GPE_VALID_GEN(dev, 6, 6); /* in 1024-bit URB rows */ vs_alloc_size = (vs_entry_size + row_size - 1) / row_size; gs_alloc_size = (gs_entry_size + row_size - 1) / row_size; /* the valid range is [1, 5] */ if (!vs_alloc_size) vs_alloc_size = 1; if (!gs_alloc_size) gs_alloc_size = 1; assert(vs_alloc_size <= 5 && gs_alloc_size <= 5); /* the valid range is [24, 256] in multiples of 4 */ vs_num_entries = (vs_total_size / row_size / vs_alloc_size) & ~3; if (vs_num_entries > 256) vs_num_entries = 256; assert(vs_num_entries >= 24); /* the valid range is [0, 256] in multiples of 4 */ gs_num_entries = (gs_total_size / row_size / gs_alloc_size) & ~3; if (gs_num_entries > 256) gs_num_entries = 256; ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, (vs_alloc_size - 1) << GEN6_URB_VS_SIZE_SHIFT | vs_num_entries << GEN6_URB_VS_ENTRIES_SHIFT); ilo_cp_write(cp, gs_num_entries << GEN6_URB_GS_ENTRIES_SHIFT | (gs_alloc_size - 1) << GEN6_URB_GS_SIZE_SHIFT); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_VERTEX_BUFFERS(const struct ilo_dev_info *dev, const struct ilo_ve_state *ve, const struct ilo_vb_state *vb, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x08); uint8_t cmd_len; unsigned hw_idx; ILO_GPE_VALID_GEN(dev, 6, 7.5); /* * From the Sandy Bridge PRM, volume 2 part 1, page 82: * * "From 1 to 33 VBs can be specified..." */ assert(ve->vb_count <= 33); if (!ve->vb_count) return; cmd_len = 1 + 4 * ve->vb_count; ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); for (hw_idx = 0; hw_idx < ve->vb_count; hw_idx++) { const unsigned instance_divisor = ve->instance_divisors[hw_idx]; const unsigned pipe_idx = ve->vb_mapping[hw_idx]; const struct pipe_vertex_buffer *cso = &vb->states[pipe_idx]; uint32_t dw; dw = hw_idx << GEN6_VB0_INDEX_SHIFT; if (instance_divisor) dw |= GEN6_VB0_ACCESS_INSTANCEDATA; else dw |= GEN6_VB0_ACCESS_VERTEXDATA; if (dev->gen >= ILO_GEN(7)) dw |= GEN7_VB0_ADDRESS_MODIFYENABLE; /* use null vb if there is no buffer or the stride is out of range */ if (cso->buffer && cso->stride <= 2048) { const struct ilo_buffer *buf = ilo_buffer(cso->buffer); const uint32_t start_offset = cso->buffer_offset; /* * As noted in ilo_translate_format(), we treat some 3-component * formats as 4-component formats to work around hardware * limitations. Imagine the case where the vertex buffer holds a * single PIPE_FORMAT_R16G16B16_FLOAT vertex, and buf->bo_size is 6. * The hardware would not be able to fetch it because the vertex * buffer is expected to hold a PIPE_FORMAT_R16G16B16A16_FLOAT vertex * and that takes at least 8 bytes. * * For the workaround to work, we query the physical size, which is * page aligned, to calculate end_offset so that the last vertex has * a better chance to be fetched. */ const uint32_t end_offset = intel_bo_get_size(buf->bo) - 1; dw |= cso->stride << BRW_VB0_PITCH_SHIFT; ilo_cp_write(cp, dw); ilo_cp_write_bo(cp, start_offset, buf->bo, INTEL_DOMAIN_VERTEX, 0); ilo_cp_write_bo(cp, end_offset, buf->bo, INTEL_DOMAIN_VERTEX, 0); ilo_cp_write(cp, instance_divisor); } else { dw |= 1 << 13; ilo_cp_write(cp, dw); ilo_cp_write(cp, 0); ilo_cp_write(cp, 0); ilo_cp_write(cp, instance_divisor); } } ilo_cp_end(cp); } static inline void ve_init_cso_with_components(const struct ilo_dev_info *dev, int comp0, int comp1, int comp2, int comp3, struct ilo_ve_cso *cso) { ILO_GPE_VALID_GEN(dev, 6, 7.5); STATIC_ASSERT(Elements(cso->payload) >= 2); cso->payload[0] = GEN6_VE0_VALID; cso->payload[1] = comp0 << BRW_VE1_COMPONENT_0_SHIFT | comp1 << BRW_VE1_COMPONENT_1_SHIFT | comp2 << BRW_VE1_COMPONENT_2_SHIFT | comp3 << BRW_VE1_COMPONENT_3_SHIFT; } static inline void ve_set_cso_edgeflag(const struct ilo_dev_info *dev, struct ilo_ve_cso *cso) { int format; ILO_GPE_VALID_GEN(dev, 6, 7.5); /* * From the Sandy Bridge PRM, volume 2 part 1, page 94: * * "- This bit (Edge Flag Enable) must only be ENABLED on the last * valid VERTEX_ELEMENT structure. * * - When set, Component 0 Control must be set to VFCOMP_STORE_SRC, * and Component 1-3 Control must be set to VFCOMP_NOSTORE. * * - The Source Element Format must be set to the UINT format. * * - [DevSNB]: Edge Flags are not supported for QUADLIST * primitives. Software may elect to convert QUADLIST primitives * to some set of corresponding edge-flag-supported primitive * types (e.g., POLYGONs) prior to submission to the 3D pipeline." */ cso->payload[0] |= GEN6_VE0_EDGE_FLAG_ENABLE; cso->payload[1] = BRW_VE1_COMPONENT_STORE_SRC << BRW_VE1_COMPONENT_0_SHIFT | BRW_VE1_COMPONENT_NOSTORE << BRW_VE1_COMPONENT_1_SHIFT | BRW_VE1_COMPONENT_NOSTORE << BRW_VE1_COMPONENT_2_SHIFT | BRW_VE1_COMPONENT_NOSTORE << BRW_VE1_COMPONENT_3_SHIFT; /* * Edge flags have format BRW_SURFACEFORMAT_R8_UINT when defined via * glEdgeFlagPointer(), and format BRW_SURFACEFORMAT_R32_FLOAT when defined * via glEdgeFlag(), as can be seen in vbo_attrib_tmp.h. * * Since all the hardware cares about is whether the flags are zero or not, * we can treat them as BRW_SURFACEFORMAT_R32_UINT in the latter case. */ format = (cso->payload[0] >> BRW_VE0_FORMAT_SHIFT) & 0x1ff; if (format == BRW_SURFACEFORMAT_R32_FLOAT) { STATIC_ASSERT(BRW_SURFACEFORMAT_R32_UINT == BRW_SURFACEFORMAT_R32_FLOAT - 1); cso->payload[0] -= (1 << BRW_VE0_FORMAT_SHIFT); } else { assert(format == BRW_SURFACEFORMAT_R8_UINT); } } static inline void gen6_emit_3DSTATE_VERTEX_ELEMENTS(const struct ilo_dev_info *dev, const struct ilo_ve_state *ve, bool last_velement_edgeflag, bool prepend_generated_ids, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x09); uint8_t cmd_len; unsigned i; ILO_GPE_VALID_GEN(dev, 6, 7.5); /* * From the Sandy Bridge PRM, volume 2 part 1, page 93: * * "Up to 34 (DevSNB+) vertex elements are supported." */ assert(ve->count + prepend_generated_ids <= 34); if (!ve->count && !prepend_generated_ids) { struct ilo_ve_cso dummy; ve_init_cso_with_components(dev, BRW_VE1_COMPONENT_STORE_0, BRW_VE1_COMPONENT_STORE_0, BRW_VE1_COMPONENT_STORE_0, BRW_VE1_COMPONENT_STORE_1_FLT, &dummy); cmd_len = 3; ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write_multi(cp, dummy.payload, 2); ilo_cp_end(cp); return; } cmd_len = 2 * (ve->count + prepend_generated_ids) + 1; ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); if (prepend_generated_ids) { struct ilo_ve_cso gen_ids; ve_init_cso_with_components(dev, BRW_VE1_COMPONENT_STORE_VID, BRW_VE1_COMPONENT_STORE_IID, BRW_VE1_COMPONENT_NOSTORE, BRW_VE1_COMPONENT_NOSTORE, &gen_ids); ilo_cp_write_multi(cp, gen_ids.payload, 2); } if (last_velement_edgeflag) { struct ilo_ve_cso edgeflag; for (i = 0; i < ve->count - 1; i++) ilo_cp_write_multi(cp, ve->cso[i].payload, 2); edgeflag = ve->cso[i]; ve_set_cso_edgeflag(dev, &edgeflag); ilo_cp_write_multi(cp, edgeflag.payload, 2); } else { for (i = 0; i < ve->count; i++) ilo_cp_write_multi(cp, ve->cso[i].payload, 2); } ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_INDEX_BUFFER(const struct ilo_dev_info *dev, const struct ilo_ib_state *ib, bool enable_cut_index, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x0a); const uint8_t cmd_len = 3; struct ilo_buffer *buf = ilo_buffer(ib->hw_resource); uint32_t start_offset, end_offset; int format; ILO_GPE_VALID_GEN(dev, 6, 7.5); if (!buf) return; /* this is moved to the new 3DSTATE_VF */ if (dev->gen >= ILO_GEN(7.5)) assert(!enable_cut_index); switch (ib->hw_index_size) { case 4: format = BRW_INDEX_DWORD; break; case 2: format = BRW_INDEX_WORD; break; case 1: format = BRW_INDEX_BYTE; break; default: assert(!"unknown index size"); format = BRW_INDEX_BYTE; break; } /* * set start_offset to 0 here and adjust pipe_draw_info::start with * ib->draw_start_offset in 3DPRIMITIVE */ start_offset = 0; end_offset = buf->bo_size; /* end_offset must also be aligned and is inclusive */ end_offset -= (end_offset % ib->hw_index_size); end_offset--; ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2) | ((enable_cut_index) ? BRW_CUT_INDEX_ENABLE : 0) | format << 8); ilo_cp_write_bo(cp, start_offset, buf->bo, INTEL_DOMAIN_VERTEX, 0); ilo_cp_write_bo(cp, end_offset, buf->bo, INTEL_DOMAIN_VERTEX, 0); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_VIEWPORT_STATE_POINTERS(const struct ilo_dev_info *dev, uint32_t clip_viewport, uint32_t sf_viewport, uint32_t cc_viewport, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x0d); const uint8_t cmd_len = 4; ILO_GPE_VALID_GEN(dev, 6, 6); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2) | GEN6_CLIP_VIEWPORT_MODIFY | GEN6_SF_VIEWPORT_MODIFY | GEN6_CC_VIEWPORT_MODIFY); ilo_cp_write(cp, clip_viewport); ilo_cp_write(cp, sf_viewport); ilo_cp_write(cp, cc_viewport); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_CC_STATE_POINTERS(const struct ilo_dev_info *dev, uint32_t blend_state, uint32_t depth_stencil_state, uint32_t color_calc_state, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x0e); const uint8_t cmd_len = 4; ILO_GPE_VALID_GEN(dev, 6, 6); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, blend_state | 1); ilo_cp_write(cp, depth_stencil_state | 1); ilo_cp_write(cp, color_calc_state | 1); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_SCISSOR_STATE_POINTERS(const struct ilo_dev_info *dev, uint32_t scissor_rect, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x0f); const uint8_t cmd_len = 2; ILO_GPE_VALID_GEN(dev, 6, 7.5); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, scissor_rect); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_VS(const struct ilo_dev_info *dev, const struct ilo_shader_state *vs, int num_samplers, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x10); const uint8_t cmd_len = 6; const struct ilo_shader_cso *cso; uint32_t dw2, dw4, dw5; ILO_GPE_VALID_GEN(dev, 6, 7.5); if (!vs) { ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, 0); ilo_cp_write(cp, 0); ilo_cp_write(cp, 0); ilo_cp_write(cp, 0); ilo_cp_write(cp, 0); ilo_cp_end(cp); return; } cso = ilo_shader_get_kernel_cso(vs); dw2 = cso->payload[0]; dw4 = cso->payload[1]; dw5 = cso->payload[2]; dw2 |= ((num_samplers + 3) / 4) << GEN6_VS_SAMPLER_COUNT_SHIFT; ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, ilo_shader_get_kernel_offset(vs)); ilo_cp_write(cp, dw2); ilo_cp_write(cp, 0); /* scratch */ ilo_cp_write(cp, dw4); ilo_cp_write(cp, dw5); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_GS(const struct ilo_dev_info *dev, const struct ilo_shader_state *gs, const struct ilo_shader_state *vs, int verts_per_prim, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x11); const uint8_t cmd_len = 7; uint32_t dw1, dw2, dw4, dw5, dw6; ILO_GPE_VALID_GEN(dev, 6, 6); if (gs) { const struct ilo_shader_cso *cso; dw1 = ilo_shader_get_kernel_offset(gs); cso = ilo_shader_get_kernel_cso(gs); dw2 = cso->payload[0]; dw4 = cso->payload[1]; dw5 = cso->payload[2]; dw6 = cso->payload[3]; } else if (vs && ilo_shader_get_kernel_param(vs, ILO_KERNEL_VS_GEN6_SO)) { struct ilo_shader_cso cso; enum ilo_kernel_param param; switch (verts_per_prim) { case 1: param = ILO_KERNEL_VS_GEN6_SO_POINT_OFFSET; break; case 2: param = ILO_KERNEL_VS_GEN6_SO_LINE_OFFSET; break; default: param = ILO_KERNEL_VS_GEN6_SO_TRI_OFFSET; break; } dw1 = ilo_shader_get_kernel_offset(vs) + ilo_shader_get_kernel_param(vs, param); /* cannot use VS's CSO */ ilo_gpe_init_gs_cso_gen6(dev, vs, &cso); dw2 = cso.payload[0]; dw4 = cso.payload[1]; dw5 = cso.payload[2]; dw6 = cso.payload[3]; } else { dw1 = 0; dw2 = 0; dw4 = 1 << GEN6_GS_URB_READ_LENGTH_SHIFT; dw5 = GEN6_GS_STATISTICS_ENABLE; dw6 = 0; } ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, dw1); ilo_cp_write(cp, dw2); ilo_cp_write(cp, 0); ilo_cp_write(cp, dw4); ilo_cp_write(cp, dw5); ilo_cp_write(cp, dw6); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_CLIP(const struct ilo_dev_info *dev, const struct ilo_rasterizer_state *rasterizer, const struct ilo_shader_state *fs, bool enable_guardband, int num_viewports, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x12); const uint8_t cmd_len = 4; uint32_t dw1, dw2, dw3; ILO_GPE_VALID_GEN(dev, 6, 7.5); if (rasterizer) { int interps; dw1 = rasterizer->clip.payload[0]; dw2 = rasterizer->clip.payload[1]; dw3 = rasterizer->clip.payload[2]; if (enable_guardband && rasterizer->clip.can_enable_guardband) dw2 |= GEN6_CLIP_GB_TEST; interps = (fs) ? ilo_shader_get_kernel_param(fs, ILO_KERNEL_FS_BARYCENTRIC_INTERPOLATIONS) : 0; if (interps & (1 << BRW_WM_NONPERSPECTIVE_PIXEL_BARYCENTRIC | 1 << BRW_WM_NONPERSPECTIVE_CENTROID_BARYCENTRIC | 1 << BRW_WM_NONPERSPECTIVE_SAMPLE_BARYCENTRIC)) dw2 |= GEN6_CLIP_NON_PERSPECTIVE_BARYCENTRIC_ENABLE; dw3 |= GEN6_CLIP_FORCE_ZERO_RTAINDEX | (num_viewports - 1); } else { dw1 = 0; dw2 = 0; dw3 = 0; } ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, dw1); ilo_cp_write(cp, dw2); ilo_cp_write(cp, dw3); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_SF(const struct ilo_dev_info *dev, const struct ilo_rasterizer_state *rasterizer, const struct ilo_shader_state *fs, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x13); const uint8_t cmd_len = 20; uint32_t payload_raster[6], payload_sbe[13]; ILO_GPE_VALID_GEN(dev, 6, 6); ilo_gpe_gen6_fill_3dstate_sf_raster(dev, rasterizer, 1, PIPE_FORMAT_NONE, payload_raster, Elements(payload_raster)); ilo_gpe_gen6_fill_3dstate_sf_sbe(dev, rasterizer, fs, payload_sbe, Elements(payload_sbe)); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, payload_sbe[0]); ilo_cp_write_multi(cp, payload_raster, 6); ilo_cp_write_multi(cp, &payload_sbe[1], 12); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_WM(const struct ilo_dev_info *dev, const struct ilo_shader_state *fs, int num_samplers, const struct ilo_rasterizer_state *rasterizer, bool dual_blend, bool cc_may_kill, uint32_t hiz_op, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x14); const uint8_t cmd_len = 9; const int num_samples = 1; const struct ilo_shader_cso *fs_cso; uint32_t dw2, dw4, dw5, dw6; ILO_GPE_VALID_GEN(dev, 6, 6); if (!fs) { /* see brwCreateContext() */ const int max_threads = (dev->gt == 2) ? 80 : 40; ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, 0); ilo_cp_write(cp, 0); ilo_cp_write(cp, 0); ilo_cp_write(cp, hiz_op); /* honor the valid range even if dispatching is disabled */ ilo_cp_write(cp, (max_threads - 1) << GEN6_WM_MAX_THREADS_SHIFT); ilo_cp_write(cp, 0); ilo_cp_write(cp, 0); ilo_cp_write(cp, 0); ilo_cp_end(cp); return; } fs_cso = ilo_shader_get_kernel_cso(fs); dw2 = fs_cso->payload[0]; dw4 = fs_cso->payload[1]; dw5 = fs_cso->payload[2]; dw6 = fs_cso->payload[3]; dw2 |= (num_samplers + 3) / 4 << GEN6_WM_SAMPLER_COUNT_SHIFT; /* * From the Sandy Bridge PRM, volume 2 part 1, page 248: * * "This bit (Statistics Enable) must be disabled if either of these * bits is set: Depth Buffer Clear , Hierarchical Depth Buffer Resolve * Enable or Depth Buffer Resolve Enable." */ assert(!hiz_op); dw4 |= GEN6_WM_STATISTICS_ENABLE; if (cc_may_kill) { dw5 |= GEN6_WM_KILL_ENABLE | GEN6_WM_DISPATCH_ENABLE; } if (dual_blend) dw5 |= GEN6_WM_DUAL_SOURCE_BLEND_ENABLE; dw5 |= rasterizer->wm.payload[0]; dw6 |= rasterizer->wm.payload[1]; if (num_samples > 1) { dw6 |= rasterizer->wm.dw_msaa_rast | rasterizer->wm.dw_msaa_disp; } ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, ilo_shader_get_kernel_offset(fs)); ilo_cp_write(cp, dw2); ilo_cp_write(cp, 0); /* scratch */ ilo_cp_write(cp, dw4); ilo_cp_write(cp, dw5); ilo_cp_write(cp, dw6); ilo_cp_write(cp, 0); /* kernel 1 */ ilo_cp_write(cp, 0); /* kernel 2 */ ilo_cp_end(cp); } static inline unsigned gen6_fill_3dstate_constant(const struct ilo_dev_info *dev, const uint32_t *bufs, const int *sizes, int num_bufs, int max_read_length, uint32_t *dw, int num_dwords) { unsigned enabled = 0x0; int total_read_length, i; assert(num_dwords == 4); total_read_length = 0; for (i = 0; i < 4; i++) { if (i < num_bufs && sizes[i]) { /* in 256-bit units minus one */ const int read_len = (sizes[i] + 31) / 32 - 1; assert(bufs[i] % 32 == 0); assert(read_len < 32); enabled |= 1 << i; dw[i] = bufs[i] | read_len; total_read_length += read_len + 1; } else { dw[i] = 0; } } assert(total_read_length <= max_read_length); return enabled; } static inline void gen6_emit_3DSTATE_CONSTANT_VS(const struct ilo_dev_info *dev, const uint32_t *bufs, const int *sizes, int num_bufs, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x15); const uint8_t cmd_len = 5; uint32_t buf_dw[4], buf_enabled; ILO_GPE_VALID_GEN(dev, 6, 6); assert(num_bufs <= 4); /* * From the Sandy Bridge PRM, volume 2 part 1, page 138: * * "The sum of all four read length fields (each incremented to * represent the actual read length) must be less than or equal to 32" */ buf_enabled = gen6_fill_3dstate_constant(dev, bufs, sizes, num_bufs, 32, buf_dw, Elements(buf_dw)); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2) | buf_enabled << 12); ilo_cp_write(cp, buf_dw[0]); ilo_cp_write(cp, buf_dw[1]); ilo_cp_write(cp, buf_dw[2]); ilo_cp_write(cp, buf_dw[3]); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_CONSTANT_GS(const struct ilo_dev_info *dev, const uint32_t *bufs, const int *sizes, int num_bufs, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x16); const uint8_t cmd_len = 5; uint32_t buf_dw[4], buf_enabled; ILO_GPE_VALID_GEN(dev, 6, 6); assert(num_bufs <= 4); /* * From the Sandy Bridge PRM, volume 2 part 1, page 161: * * "The sum of all four read length fields (each incremented to * represent the actual read length) must be less than or equal to 64" */ buf_enabled = gen6_fill_3dstate_constant(dev, bufs, sizes, num_bufs, 64, buf_dw, Elements(buf_dw)); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2) | buf_enabled << 12); ilo_cp_write(cp, buf_dw[0]); ilo_cp_write(cp, buf_dw[1]); ilo_cp_write(cp, buf_dw[2]); ilo_cp_write(cp, buf_dw[3]); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_CONSTANT_PS(const struct ilo_dev_info *dev, const uint32_t *bufs, const int *sizes, int num_bufs, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x17); const uint8_t cmd_len = 5; uint32_t buf_dw[4], buf_enabled; ILO_GPE_VALID_GEN(dev, 6, 6); assert(num_bufs <= 4); /* * From the Sandy Bridge PRM, volume 2 part 1, page 287: * * "The sum of all four read length fields (each incremented to * represent the actual read length) must be less than or equal to 64" */ buf_enabled = gen6_fill_3dstate_constant(dev, bufs, sizes, num_bufs, 64, buf_dw, Elements(buf_dw)); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2) | buf_enabled << 12); ilo_cp_write(cp, buf_dw[0]); ilo_cp_write(cp, buf_dw[1]); ilo_cp_write(cp, buf_dw[2]); ilo_cp_write(cp, buf_dw[3]); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_SAMPLE_MASK(const struct ilo_dev_info *dev, unsigned sample_mask, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x0, 0x18); const uint8_t cmd_len = 2; const unsigned valid_mask = 0xf; ILO_GPE_VALID_GEN(dev, 6, 6); sample_mask &= valid_mask; ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, sample_mask); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_DRAWING_RECTANGLE(const struct ilo_dev_info *dev, unsigned x, unsigned y, unsigned width, unsigned height, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x1, 0x00); const uint8_t cmd_len = 4; unsigned xmax = x + width - 1; unsigned ymax = y + height - 1; int rect_limit; ILO_GPE_VALID_GEN(dev, 6, 7.5); if (dev->gen >= ILO_GEN(7)) { rect_limit = 16383; } else { /* * From the Sandy Bridge PRM, volume 2 part 1, page 230: * * "[DevSNB] Errata: This field (Clipped Drawing Rectangle Y Min) * must be an even number" */ assert(y % 2 == 0); rect_limit = 8191; } if (x > rect_limit) x = rect_limit; if (y > rect_limit) y = rect_limit; if (xmax > rect_limit) xmax = rect_limit; if (ymax > rect_limit) ymax = rect_limit; ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, y << 16 | x); ilo_cp_write(cp, ymax << 16 | xmax); /* * There is no need to set the origin. It is intended to support front * buffer rendering. */ ilo_cp_write(cp, 0); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_DEPTH_BUFFER(const struct ilo_dev_info *dev, const struct ilo_zs_surface *zs, struct ilo_cp *cp) { const uint32_t cmd = (dev->gen >= ILO_GEN(7)) ? ILO_GPE_CMD(0x3, 0x0, 0x05) : ILO_GPE_CMD(0x3, 0x1, 0x05); const uint8_t cmd_len = 7; ILO_GPE_VALID_GEN(dev, 6, 7.5); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, zs->payload[0]); ilo_cp_write_bo(cp, zs->payload[1], zs->bo, INTEL_DOMAIN_RENDER, INTEL_DOMAIN_RENDER); ilo_cp_write(cp, zs->payload[2]); ilo_cp_write(cp, zs->payload[3]); ilo_cp_write(cp, zs->payload[4]); ilo_cp_write(cp, zs->payload[5]); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_POLY_STIPPLE_OFFSET(const struct ilo_dev_info *dev, int x_offset, int y_offset, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x1, 0x06); const uint8_t cmd_len = 2; ILO_GPE_VALID_GEN(dev, 6, 7.5); assert(x_offset >= 0 && x_offset <= 31); assert(y_offset >= 0 && y_offset <= 31); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, x_offset << 8 | y_offset); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_POLY_STIPPLE_PATTERN(const struct ilo_dev_info *dev, const struct pipe_poly_stipple *pattern, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x1, 0x07); const uint8_t cmd_len = 33; int i; ILO_GPE_VALID_GEN(dev, 6, 7.5); assert(Elements(pattern->stipple) == 32); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); for (i = 0; i < 32; i++) ilo_cp_write(cp, pattern->stipple[i]); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_LINE_STIPPLE(const struct ilo_dev_info *dev, unsigned pattern, unsigned factor, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x1, 0x08); const uint8_t cmd_len = 3; unsigned inverse; ILO_GPE_VALID_GEN(dev, 6, 7.5); assert((pattern & 0xffff) == pattern); assert(factor >= 1 && factor <= 256); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, pattern); if (dev->gen >= ILO_GEN(7)) { /* in U1.16 */ inverse = (unsigned) (65536.0f / factor); ilo_cp_write(cp, inverse << 15 | factor); } else { /* in U1.13 */ inverse = (unsigned) (8192.0f / factor); ilo_cp_write(cp, inverse << 16 | factor); } ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_AA_LINE_PARAMETERS(const struct ilo_dev_info *dev, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x1, 0x0a); const uint8_t cmd_len = 3; ILO_GPE_VALID_GEN(dev, 6, 7.5); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, 0 << 16 | 0); ilo_cp_write(cp, 0 << 16 | 0); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_GS_SVB_INDEX(const struct ilo_dev_info *dev, int index, unsigned svbi, unsigned max_svbi, bool load_vertex_count, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x1, 0x0b); const uint8_t cmd_len = 4; uint32_t dw1; ILO_GPE_VALID_GEN(dev, 6, 6); assert(index >= 0 && index < 4); dw1 = index << SVB_INDEX_SHIFT; if (load_vertex_count) dw1 |= SVB_LOAD_INTERNAL_VERTEX_COUNT; ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, dw1); ilo_cp_write(cp, svbi); ilo_cp_write(cp, max_svbi); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_MULTISAMPLE(const struct ilo_dev_info *dev, int num_samples, const uint32_t *packed_sample_pos, bool pixel_location_center, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x1, 0x0d); const uint8_t cmd_len = (dev->gen >= ILO_GEN(7)) ? 4 : 3; uint32_t dw1, dw2, dw3; ILO_GPE_VALID_GEN(dev, 6, 7.5); dw1 = (pixel_location_center) ? MS_PIXEL_LOCATION_CENTER : MS_PIXEL_LOCATION_UPPER_LEFT; switch (num_samples) { case 0: case 1: dw1 |= MS_NUMSAMPLES_1; dw2 = 0; dw3 = 0; break; case 4: dw1 |= MS_NUMSAMPLES_4; dw2 = packed_sample_pos[0]; dw3 = 0; break; case 8: assert(dev->gen >= ILO_GEN(7)); dw1 |= MS_NUMSAMPLES_8; dw2 = packed_sample_pos[0]; dw3 = packed_sample_pos[1]; break; default: assert(!"unsupported sample count"); dw1 |= MS_NUMSAMPLES_1; dw2 = 0; dw3 = 0; break; } ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, dw1); ilo_cp_write(cp, dw2); if (dev->gen >= ILO_GEN(7)) ilo_cp_write(cp, dw3); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_STENCIL_BUFFER(const struct ilo_dev_info *dev, const struct ilo_zs_surface *zs, struct ilo_cp *cp) { const uint32_t cmd = (dev->gen >= ILO_GEN(7)) ? ILO_GPE_CMD(0x3, 0x0, 0x06) : ILO_GPE_CMD(0x3, 0x1, 0x0e); const uint8_t cmd_len = 3; ILO_GPE_VALID_GEN(dev, 6, 7.5); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); /* see ilo_gpe_init_zs_surface() */ ilo_cp_write(cp, zs->payload[6]); ilo_cp_write_bo(cp, zs->payload[7], zs->separate_s8_bo, INTEL_DOMAIN_RENDER, INTEL_DOMAIN_RENDER); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_HIER_DEPTH_BUFFER(const struct ilo_dev_info *dev, const struct ilo_zs_surface *zs, struct ilo_cp *cp) { const uint32_t cmd = (dev->gen >= ILO_GEN(7)) ? ILO_GPE_CMD(0x3, 0x0, 0x07) : ILO_GPE_CMD(0x3, 0x1, 0x0f); const uint8_t cmd_len = 3; ILO_GPE_VALID_GEN(dev, 6, 7.5); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); /* see ilo_gpe_init_zs_surface() */ ilo_cp_write(cp, zs->payload[8]); ilo_cp_write_bo(cp, zs->payload[9], zs->hiz_bo, INTEL_DOMAIN_RENDER, INTEL_DOMAIN_RENDER); ilo_cp_end(cp); } static inline void gen6_emit_3DSTATE_CLEAR_PARAMS(const struct ilo_dev_info *dev, uint32_t clear_val, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x1, 0x10); const uint8_t cmd_len = 2; ILO_GPE_VALID_GEN(dev, 6, 6); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2) | GEN5_DEPTH_CLEAR_VALID); ilo_cp_write(cp, clear_val); ilo_cp_end(cp); } static inline void gen6_emit_PIPE_CONTROL(const struct ilo_dev_info *dev, uint32_t dw1, struct intel_bo *bo, uint32_t bo_offset, bool write_qword, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x2, 0x00); const uint8_t cmd_len = (write_qword) ? 5 : 4; const uint32_t read_domains = INTEL_DOMAIN_INSTRUCTION; const uint32_t write_domain = INTEL_DOMAIN_INSTRUCTION; ILO_GPE_VALID_GEN(dev, 6, 7.5); if (dw1 & PIPE_CONTROL_CS_STALL) { /* * From the Sandy Bridge PRM, volume 2 part 1, page 73: * * "1 of the following must also be set (when CS stall is set): * * * Depth Cache Flush Enable ([0] of DW1) * * Stall at Pixel Scoreboard ([1] of DW1) * * Depth Stall ([13] of DW1) * * Post-Sync Operation ([13] of DW1) * * Render Target Cache Flush Enable ([12] of DW1) * * Notify Enable ([8] of DW1)" * * From the Ivy Bridge PRM, volume 2 part 1, page 61: * * "One of the following must also be set (when CS stall is set): * * * Render Target Cache Flush Enable ([12] of DW1) * * Depth Cache Flush Enable ([0] of DW1) * * Stall at Pixel Scoreboard ([1] of DW1) * * Depth Stall ([13] of DW1) * * Post-Sync Operation ([13] of DW1)" */ uint32_t bit_test = PIPE_CONTROL_WRITE_FLUSH | PIPE_CONTROL_DEPTH_CACHE_FLUSH | PIPE_CONTROL_STALL_AT_SCOREBOARD | PIPE_CONTROL_DEPTH_STALL; /* post-sync op */ bit_test |= PIPE_CONTROL_WRITE_IMMEDIATE | PIPE_CONTROL_WRITE_DEPTH_COUNT | PIPE_CONTROL_WRITE_TIMESTAMP; if (dev->gen == ILO_GEN(6)) bit_test |= PIPE_CONTROL_INTERRUPT_ENABLE; assert(dw1 & bit_test); } if (dw1 & PIPE_CONTROL_DEPTH_STALL) { /* * From the Sandy Bridge PRM, volume 2 part 1, page 73: * * "Following bits must be clear (when Depth Stall is set): * * * Render Target Cache Flush Enable ([12] of DW1) * * Depth Cache Flush Enable ([0] of DW1)" */ assert(!(dw1 & (PIPE_CONTROL_WRITE_FLUSH | PIPE_CONTROL_DEPTH_CACHE_FLUSH))); } ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2)); ilo_cp_write(cp, dw1); ilo_cp_write_bo(cp, bo_offset, bo, read_domains, write_domain); ilo_cp_write(cp, 0); if (write_qword) ilo_cp_write(cp, 0); ilo_cp_end(cp); } static inline void gen6_emit_3DPRIMITIVE(const struct ilo_dev_info *dev, const struct pipe_draw_info *info, const struct ilo_ib_state *ib, bool rectlist, struct ilo_cp *cp) { const uint32_t cmd = ILO_GPE_CMD(0x3, 0x3, 0x00); const uint8_t cmd_len = 6; const int prim = (rectlist) ? _3DPRIM_RECTLIST : ilo_gpe_gen6_translate_pipe_prim(info->mode); const int vb_access = (info->indexed) ? GEN4_3DPRIM_VERTEXBUFFER_ACCESS_RANDOM : GEN4_3DPRIM_VERTEXBUFFER_ACCESS_SEQUENTIAL; const uint32_t vb_start = info->start + ((info->indexed) ? ib->draw_start_offset : 0); ILO_GPE_VALID_GEN(dev, 6, 6); ilo_cp_begin(cp, cmd_len); ilo_cp_write(cp, cmd | (cmd_len - 2) | prim << GEN4_3DPRIM_TOPOLOGY_TYPE_SHIFT | vb_access); ilo_cp_write(cp, info->count); ilo_cp_write(cp, vb_start); ilo_cp_write(cp, info->instance_count); ilo_cp_write(cp, info->start_instance); ilo_cp_write(cp, info->index_bias); ilo_cp_end(cp); } static inline uint32_t gen6_emit_INTERFACE_DESCRIPTOR_DATA(const struct ilo_dev_info *dev, const struct ilo_shader_state **cs, uint32_t *sampler_state, int *num_samplers, uint32_t *binding_table_state, int *num_surfaces, int num_ids, struct ilo_cp *cp) { /* * From the Sandy Bridge PRM, volume 2 part 2, page 34: * * "(Interface Descriptor Total Length) This field must have the same * alignment as the Interface Descriptor Data Start Address. * * It must be DQWord (32-byte) aligned..." * * From the Sandy Bridge PRM, volume 2 part 2, page 35: * * "(Interface Descriptor Data Start Address) Specifies the 32-byte * aligned address of the Interface Descriptor data." */ const int state_align = 32 / 4; const int state_len = (32 / 4) * num_ids; uint32_t state_offset, *dw; int i; ILO_GPE_VALID_GEN(dev, 6, 6); dw = ilo_cp_steal_ptr(cp, "INTERFACE_DESCRIPTOR_DATA", state_len, state_align, &state_offset); for (i = 0; i < num_ids; i++) { dw[0] = ilo_shader_get_kernel_offset(cs[i]); dw[1] = 1 << 18; /* SPF */ dw[2] = sampler_state[i] | (num_samplers[i] + 3) / 4 << 2; dw[3] = binding_table_state[i] | num_surfaces[i]; dw[4] = 0 << 16 | /* CURBE Read Length */ 0; /* CURBE Read Offset */ dw[5] = 0; /* Barrier ID */ dw[6] = 0; dw[7] = 0; dw += 8; } return state_offset; } static inline uint32_t gen6_emit_SF_VIEWPORT(const struct ilo_dev_info *dev, const struct ilo_viewport_cso *viewports, unsigned num_viewports, struct ilo_cp *cp) { const int state_align = 32 / 4; const int state_len = 8 * num_viewports; uint32_t state_offset, *dw; unsigned i; ILO_GPE_VALID_GEN(dev, 6, 6); /* * From the Sandy Bridge PRM, volume 2 part 1, page 262: * * "The viewport-specific state used by the SF unit (SF_VIEWPORT) is * stored as an array of up to 16 elements..." */ assert(num_viewports && num_viewports <= 16); dw = ilo_cp_steal_ptr(cp, "SF_VIEWPORT", state_len, state_align, &state_offset); for (i = 0; i < num_viewports; i++) { const struct ilo_viewport_cso *vp = &viewports[i]; dw[0] = fui(vp->m00); dw[1] = fui(vp->m11); dw[2] = fui(vp->m22); dw[3] = fui(vp->m30); dw[4] = fui(vp->m31); dw[5] = fui(vp->m32); dw[6] = 0; dw[7] = 0; dw += 8; } return state_offset; } static inline uint32_t gen6_emit_CLIP_VIEWPORT(const struct ilo_dev_info *dev, const struct ilo_viewport_cso *viewports, unsigned num_viewports, struct ilo_cp *cp) { const int state_align = 32 / 4; const int state_len = 4 * num_viewports; uint32_t state_offset, *dw; unsigned i; ILO_GPE_VALID_GEN(dev, 6, 6); /* * From the Sandy Bridge PRM, volume 2 part 1, page 193: * * "The viewport-related state is stored as an array of up to 16 * elements..." */ assert(num_viewports && num_viewports <= 16); dw = ilo_cp_steal_ptr(cp, "CLIP_VIEWPORT", state_len, state_align, &state_offset); for (i = 0; i < num_viewports; i++) { const struct ilo_viewport_cso *vp = &viewports[i]; dw[0] = fui(vp->min_gbx); dw[1] = fui(vp->max_gbx); dw[2] = fui(vp->min_gby); dw[3] = fui(vp->max_gby); dw += 4; } return state_offset; } static inline uint32_t gen6_emit_CC_VIEWPORT(const struct ilo_dev_info *dev, const struct ilo_viewport_cso *viewports, unsigned num_viewports, struct ilo_cp *cp) { const int state_align = 32 / 4; const int state_len = 2 * num_viewports; uint32_t state_offset, *dw; unsigned i; ILO_GPE_VALID_GEN(dev, 6, 7.5); /* * From the Sandy Bridge PRM, volume 2 part 1, page 385: * * "The viewport state is stored as an array of up to 16 elements..." */ assert(num_viewports && num_viewports <= 16); dw = ilo_cp_steal_ptr(cp, "CC_VIEWPORT", state_len, state_align, &state_offset); for (i = 0; i < num_viewports; i++) { const struct ilo_viewport_cso *vp = &viewports[i]; dw[0] = fui(vp->min_z); dw[1] = fui(vp->max_z); dw += 2; } return state_offset; } static inline uint32_t gen6_emit_COLOR_CALC_STATE(const struct ilo_dev_info *dev, const struct pipe_stencil_ref *stencil_ref, ubyte alpha_ref, const struct pipe_blend_color *blend_color, struct ilo_cp *cp) { const int state_align = 64 / 4; const int state_len = 6; uint32_t state_offset, *dw; ILO_GPE_VALID_GEN(dev, 6, 7.5); dw = ilo_cp_steal_ptr(cp, "COLOR_CALC_STATE", state_len, state_align, &state_offset); dw[0] = stencil_ref->ref_value[0] << 24 | stencil_ref->ref_value[1] << 16 | BRW_ALPHATEST_FORMAT_UNORM8; dw[1] = alpha_ref; dw[2] = fui(blend_color->color[0]); dw[3] = fui(blend_color->color[1]); dw[4] = fui(blend_color->color[2]); dw[5] = fui(blend_color->color[3]); return state_offset; } static inline uint32_t gen6_emit_BLEND_STATE(const struct ilo_dev_info *dev, const struct ilo_blend_state *blend, const struct ilo_fb_state *fb, const struct ilo_dsa_state *dsa, struct ilo_cp *cp) { const int state_align = 64 / 4; int state_len; uint32_t state_offset, *dw; unsigned num_targets, i; ILO_GPE_VALID_GEN(dev, 6, 7.5); /* * From the Sandy Bridge PRM, volume 2 part 1, page 376: * * "The blend state is stored as an array of up to 8 elements..." */ num_targets = fb->state.nr_cbufs; assert(num_targets <= 8); if (!num_targets) { if (!dsa->dw_alpha) return 0; /* to be able to reference alpha func */ num_targets = 1; } state_len = 2 * num_targets; dw = ilo_cp_steal_ptr(cp, "BLEND_STATE", state_len, state_align, &state_offset); for (i = 0; i < num_targets; i++) { const unsigned idx = (blend->independent_blend_enable) ? i : 0; const struct ilo_blend_cso *cso = &blend->cso[idx]; const int num_samples = fb->num_samples; const struct util_format_description *format_desc = (idx < fb->state.nr_cbufs) ? util_format_description(fb->state.cbufs[idx]->format) : NULL; bool rt_is_unorm, rt_is_pure_integer, rt_dst_alpha_forced_one; rt_is_unorm = true; rt_is_pure_integer = false; rt_dst_alpha_forced_one = false; if (format_desc) { int ch; switch (format_desc->format) { case PIPE_FORMAT_B8G8R8X8_UNORM: /* force alpha to one when the HW format has alpha */ assert(ilo_translate_render_format(PIPE_FORMAT_B8G8R8X8_UNORM) == BRW_SURFACEFORMAT_B8G8R8A8_UNORM); rt_dst_alpha_forced_one = true; break; default: break; } for (ch = 0; ch < 4; ch++) { if (format_desc->channel[ch].type == UTIL_FORMAT_TYPE_VOID) continue; if (format_desc->channel[ch].pure_integer) { rt_is_unorm = false; rt_is_pure_integer = true; break; } if (!format_desc->channel[ch].normalized || format_desc->channel[ch].type != UTIL_FORMAT_TYPE_UNSIGNED) rt_is_unorm = false; } } dw[0] = cso->payload[0]; dw[1] = cso->payload[1]; if (!rt_is_pure_integer) { if (rt_dst_alpha_forced_one) dw[0] |= cso->dw_blend_dst_alpha_forced_one; else dw[0] |= cso->dw_blend; } /* * From the Sandy Bridge PRM, volume 2 part 1, page 365: * * "Logic Ops are only supported on *_UNORM surfaces (excluding * _SRGB variants), otherwise Logic Ops must be DISABLED." * * Since logicop is ignored for non-UNORM color buffers, no special care * is needed. */ if (rt_is_unorm) dw[1] |= cso->dw_logicop; /* * From the Sandy Bridge PRM, volume 2 part 1, page 356: * * "When NumSamples = 1, AlphaToCoverage and AlphaToCoverage * Dither both must be disabled." * * There is no such limitation on GEN7, or for AlphaToOne. But GL * requires that anyway. */ if (num_samples > 1) dw[1] |= cso->dw_alpha_mod; /* * From the Sandy Bridge PRM, volume 2 part 1, page 382: * * "Alpha Test can only be enabled if Pixel Shader outputs a float * alpha value." */ if (!rt_is_pure_integer) dw[1] |= dsa->dw_alpha; dw += 2; } return state_offset; } static inline uint32_t gen6_emit_DEPTH_STENCIL_STATE(const struct ilo_dev_info *dev, const struct ilo_dsa_state *dsa, struct ilo_cp *cp) { const int state_align = 64 / 4; const int state_len = 3; uint32_t state_offset, *dw; ILO_GPE_VALID_GEN(dev, 6, 7.5); dw = ilo_cp_steal_ptr(cp, "DEPTH_STENCIL_STATE", state_len, state_align, &state_offset); dw[0] = dsa->payload[0]; dw[1] = dsa->payload[1]; dw[2] = dsa->payload[2]; return state_offset; } static inline uint32_t gen6_emit_SCISSOR_RECT(const struct ilo_dev_info *dev, const struct ilo_scissor_state *scissor, unsigned num_viewports, struct ilo_cp *cp) { const int state_align = 32 / 4; const int state_len = 2 * num_viewports; uint32_t state_offset, *dw; ILO_GPE_VALID_GEN(dev, 6, 7.5); /* * From the Sandy Bridge PRM, volume 2 part 1, page 263: * * "The viewport-specific state used by the SF unit (SCISSOR_RECT) is * stored as an array of up to 16 elements..." */ assert(num_viewports && num_viewports <= 16); dw = ilo_cp_steal_ptr(cp, "SCISSOR_RECT", state_len, state_align, &state_offset); memcpy(dw, scissor->payload, state_len * 4); return state_offset; } static inline uint32_t gen6_emit_BINDING_TABLE_STATE(const struct ilo_dev_info *dev, uint32_t *surface_states, int num_surface_states, struct ilo_cp *cp) { const int state_align = 32 / 4; const int state_len = num_surface_states; uint32_t state_offset, *dw; ILO_GPE_VALID_GEN(dev, 6, 7.5); /* * From the Sandy Bridge PRM, volume 4 part 1, page 69: * * "It is stored as an array of up to 256 elements..." */ assert(num_surface_states <= 256); if (!num_surface_states) return 0; dw = ilo_cp_steal_ptr(cp, "BINDING_TABLE_STATE", state_len, state_align, &state_offset); memcpy(dw, surface_states, num_surface_states * sizeof(surface_states[0])); return state_offset; } static inline uint32_t gen6_emit_SURFACE_STATE(const struct ilo_dev_info *dev, const struct ilo_view_surface *surf, bool for_render, struct ilo_cp *cp) { const int state_align = 32 / 4; const int state_len = (dev->gen >= ILO_GEN(7)) ? 8 : 6; uint32_t state_offset; uint32_t read_domains, write_domain; ILO_GPE_VALID_GEN(dev, 6, 7.5); if (for_render) { read_domains = INTEL_DOMAIN_RENDER; write_domain = INTEL_DOMAIN_RENDER; } else { read_domains = INTEL_DOMAIN_SAMPLER; write_domain = 0; } ilo_cp_steal(cp, "SURFACE_STATE", state_len, state_align, &state_offset); STATIC_ASSERT(Elements(surf->payload) >= 8); ilo_cp_write(cp, surf->payload[0]); ilo_cp_write_bo(cp, surf->payload[1], surf->bo, read_domains, write_domain); ilo_cp_write(cp, surf->payload[2]); ilo_cp_write(cp, surf->payload[3]); ilo_cp_write(cp, surf->payload[4]); ilo_cp_write(cp, surf->payload[5]); if (dev->gen >= ILO_GEN(7)) { ilo_cp_write(cp, surf->payload[6]); ilo_cp_write(cp, surf->payload[7]); } ilo_cp_end(cp); return state_offset; } static inline uint32_t gen6_emit_so_SURFACE_STATE(const struct ilo_dev_info *dev, const struct pipe_stream_output_target *so, const struct pipe_stream_output_info *so_info, int so_index, struct ilo_cp *cp) { struct ilo_buffer *buf = ilo_buffer(so->buffer); unsigned bo_offset, struct_size; enum pipe_format elem_format; struct ilo_view_surface surf; ILO_GPE_VALID_GEN(dev, 6, 6); bo_offset = so->buffer_offset + so_info->output[so_index].dst_offset * 4; struct_size = so_info->stride[so_info->output[so_index].output_buffer] * 4; switch (so_info->output[so_index].num_components) { case 1: elem_format = PIPE_FORMAT_R32_FLOAT; break; case 2: elem_format = PIPE_FORMAT_R32G32_FLOAT; break; case 3: elem_format = PIPE_FORMAT_R32G32B32_FLOAT; break; case 4: elem_format = PIPE_FORMAT_R32G32B32A32_FLOAT; break; default: assert(!"unexpected SO components length"); elem_format = PIPE_FORMAT_R32_FLOAT; break; } ilo_gpe_init_view_surface_for_buffer_gen6(dev, buf, bo_offset, so->buffer_size, struct_size, elem_format, false, true, &surf); return gen6_emit_SURFACE_STATE(dev, &surf, false, cp); } static inline uint32_t gen6_emit_SAMPLER_STATE(const struct ilo_dev_info *dev, const struct ilo_sampler_cso * const *samplers, const struct pipe_sampler_view * const *views, const uint32_t *sampler_border_colors, int num_samplers, struct ilo_cp *cp) { const int state_align = 32 / 4; const int state_len = 4 * num_samplers; uint32_t state_offset, *dw; int i; ILO_GPE_VALID_GEN(dev, 6, 7.5); /* * From the Sandy Bridge PRM, volume 4 part 1, page 101: * * "The sampler state is stored as an array of up to 16 elements..." */ assert(num_samplers <= 16); if (!num_samplers) return 0; dw = ilo_cp_steal_ptr(cp, "SAMPLER_STATE", state_len, state_align, &state_offset); for (i = 0; i < num_samplers; i++) { const struct ilo_sampler_cso *sampler = samplers[i]; const struct pipe_sampler_view *view = views[i]; const uint32_t border_color = sampler_border_colors[i]; uint32_t dw_filter, dw_wrap; /* there may be holes */ if (!sampler || !view) { /* disabled sampler */ dw[0] = 1 << 31; dw[1] = 0; dw[2] = 0; dw[3] = 0; dw += 4; continue; } /* determine filter and wrap modes */ switch (view->texture->target) { case PIPE_TEXTURE_1D: dw_filter = (sampler->anisotropic) ? sampler->dw_filter_aniso : sampler->dw_filter; dw_wrap = sampler->dw_wrap_1d; break; case PIPE_TEXTURE_3D: /* * From the Sandy Bridge PRM, volume 4 part 1, page 103: * * "Only MAPFILTER_NEAREST and MAPFILTER_LINEAR are supported for * surfaces of type SURFTYPE_3D." */ dw_filter = sampler->dw_filter; dw_wrap = sampler->dw_wrap; break; case PIPE_TEXTURE_CUBE: dw_filter = (sampler->anisotropic) ? sampler->dw_filter_aniso : sampler->dw_filter; dw_wrap = sampler->dw_wrap_cube; break; default: dw_filter = (sampler->anisotropic) ? sampler->dw_filter_aniso : sampler->dw_filter; dw_wrap = sampler->dw_wrap; break; } dw[0] = sampler->payload[0]; dw[1] = sampler->payload[1]; assert(!(border_color & 0x1f)); dw[2] = border_color; dw[3] = sampler->payload[2]; dw[0] |= dw_filter; if (dev->gen >= ILO_GEN(7)) { dw[3] |= dw_wrap; } else { /* * From the Sandy Bridge PRM, volume 4 part 1, page 21: * * "[DevSNB] Errata: Incorrect behavior is observed in cases * where the min and mag mode filters are different and * SurfMinLOD is nonzero. The determination of MagMode uses the * following equation instead of the one in the above * pseudocode: MagMode = (LOD + SurfMinLOD - Base <= 0)" * * As a way to work around that, we set Base to * view->u.tex.first_level. */ dw[0] |= view->u.tex.first_level << 22; dw[1] |= dw_wrap; } dw += 4; } return state_offset; } static inline uint32_t gen6_emit_SAMPLER_BORDER_COLOR_STATE(const struct ilo_dev_info *dev, const struct ilo_sampler_cso *sampler, struct ilo_cp *cp) { const int state_align = 32 / 4; const int state_len = (dev->gen >= ILO_GEN(7)) ? 4 : 12; uint32_t state_offset, *dw; ILO_GPE_VALID_GEN(dev, 6, 7.5); dw = ilo_cp_steal_ptr(cp, "SAMPLER_BORDER_COLOR_STATE", state_len, state_align, &state_offset); /* see ilo_gpe_init_sampler_cso() */ memcpy(dw, &sampler->payload[3], state_len * 4); return state_offset; } static inline uint32_t gen6_emit_push_constant_buffer(const struct ilo_dev_info *dev, int size, void **pcb, struct ilo_cp *cp) { /* * For all VS, GS, FS, and CS push constant buffers, they must be aligned * to 32 bytes, and their sizes are specified in 256-bit units. */ const int state_align = 32 / 4; const int state_len = align(size, 32) / 4; uint32_t state_offset; char *buf; ILO_GPE_VALID_GEN(dev, 6, 7.5); buf = ilo_cp_steal_ptr(cp, "PUSH_CONSTANT_BUFFER", state_len, state_align, &state_offset); /* zero out the unused range */ if (size < state_len * 4) memset(&buf[size], 0, state_len * 4 - size); if (pcb) *pcb = buf; return state_offset; } #endif /* ILO_GPE_GEN6_H */