/* * Copyright 2013 Advanced Micro Devices, 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 (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. * * Authors: Marek Olšák * */ #include "r600_pipe_common.h" #include "r600_cs.h" #include "tgsi/tgsi_parse.h" #include "util/u_draw_quad.h" #include "util/u_memory.h" #include "util/u_format_s3tc.h" #include "util/u_upload_mgr.h" #include "vl/vl_decoder.h" #include "vl/vl_video_buffer.h" #include "radeon/radeon_video.h" #include /* * pipe_context */ void r600_draw_rectangle(struct blitter_context *blitter, int x1, int y1, int x2, int y2, float depth, enum blitter_attrib_type type, const union pipe_color_union *attrib) { struct r600_common_context *rctx = (struct r600_common_context*)util_blitter_get_pipe(blitter); struct pipe_viewport_state viewport; struct pipe_resource *buf = NULL; unsigned offset = 0; float *vb; if (type == UTIL_BLITTER_ATTRIB_TEXCOORD) { util_blitter_draw_rectangle(blitter, x1, y1, x2, y2, depth, type, attrib); return; } /* Some operations (like color resolve on r6xx) don't work * with the conventional primitive types. * One that works is PT_RECTLIST, which we use here. */ /* setup viewport */ viewport.scale[0] = 1.0f; viewport.scale[1] = 1.0f; viewport.scale[2] = 1.0f; viewport.scale[3] = 1.0f; viewport.translate[0] = 0.0f; viewport.translate[1] = 0.0f; viewport.translate[2] = 0.0f; viewport.translate[3] = 0.0f; rctx->b.set_viewport_states(&rctx->b, 0, 1, &viewport); /* Upload vertices. The hw rectangle has only 3 vertices, * I guess the 4th one is derived from the first 3. * The vertex specification should match u_blitter's vertex element state. */ u_upload_alloc(rctx->uploader, 0, sizeof(float) * 24, &offset, &buf, (void**)&vb); vb[0] = x1; vb[1] = y1; vb[2] = depth; vb[3] = 1; vb[8] = x1; vb[9] = y2; vb[10] = depth; vb[11] = 1; vb[16] = x2; vb[17] = y1; vb[18] = depth; vb[19] = 1; if (attrib) { memcpy(vb+4, attrib->f, sizeof(float)*4); memcpy(vb+12, attrib->f, sizeof(float)*4); memcpy(vb+20, attrib->f, sizeof(float)*4); } /* draw */ util_draw_vertex_buffer(&rctx->b, NULL, buf, blitter->vb_slot, offset, R600_PRIM_RECTANGLE_LIST, 3, 2); pipe_resource_reference(&buf, NULL); } void r600_need_dma_space(struct r600_common_context *ctx, unsigned num_dw) { /* The number of dwords we already used in the DMA so far. */ num_dw += ctx->rings.dma.cs->cdw; /* Flush if there's not enough space. */ if (num_dw > RADEON_MAX_CMDBUF_DWORDS) { ctx->rings.dma.flush(ctx, RADEON_FLUSH_ASYNC, NULL); } } static void r600_memory_barrier(struct pipe_context *ctx, unsigned flags) { } void r600_preflush_suspend_features(struct r600_common_context *ctx) { /* Disable render condition. */ ctx->saved_render_cond = NULL; ctx->saved_render_cond_cond = FALSE; ctx->saved_render_cond_mode = 0; if (ctx->current_render_cond) { ctx->saved_render_cond = ctx->current_render_cond; ctx->saved_render_cond_cond = ctx->current_render_cond_cond; ctx->saved_render_cond_mode = ctx->current_render_cond_mode; ctx->b.render_condition(&ctx->b, NULL, FALSE, 0); } /* suspend queries */ ctx->nontimer_queries_suspended = false; if (ctx->num_cs_dw_nontimer_queries_suspend) { r600_suspend_nontimer_queries(ctx); ctx->nontimer_queries_suspended = true; } ctx->streamout.suspended = false; if (ctx->streamout.begin_emitted) { r600_emit_streamout_end(ctx); ctx->streamout.suspended = true; } } void r600_postflush_resume_features(struct r600_common_context *ctx) { if (ctx->streamout.suspended) { ctx->streamout.append_bitmask = ctx->streamout.enabled_mask; r600_streamout_buffers_dirty(ctx); } /* resume queries */ if (ctx->nontimer_queries_suspended) { r600_resume_nontimer_queries(ctx); } /* Re-enable render condition. */ if (ctx->saved_render_cond) { ctx->b.render_condition(&ctx->b, ctx->saved_render_cond, ctx->saved_render_cond_cond, ctx->saved_render_cond_mode); } } static void r600_flush_from_st(struct pipe_context *ctx, struct pipe_fence_handle **fence, unsigned flags) { struct r600_common_context *rctx = (struct r600_common_context *)ctx; unsigned rflags = 0; if (flags & PIPE_FLUSH_END_OF_FRAME) rflags |= RADEON_FLUSH_END_OF_FRAME; if (rctx->rings.dma.cs) { rctx->rings.dma.flush(rctx, rflags, NULL); } rctx->rings.gfx.flush(rctx, rflags, fence); } static void r600_flush_dma_ring(void *ctx, unsigned flags, struct pipe_fence_handle **fence) { struct r600_common_context *rctx = (struct r600_common_context *)ctx; struct radeon_winsys_cs *cs = rctx->rings.dma.cs; if (!cs->cdw) { return; } rctx->rings.dma.flushing = true; rctx->ws->cs_flush(cs, flags, fence, 0); rctx->rings.dma.flushing = false; } bool r600_common_context_init(struct r600_common_context *rctx, struct r600_common_screen *rscreen) { util_slab_create(&rctx->pool_transfers, sizeof(struct r600_transfer), 64, UTIL_SLAB_SINGLETHREADED); rctx->screen = rscreen; rctx->ws = rscreen->ws; rctx->family = rscreen->family; rctx->chip_class = rscreen->chip_class; if (rscreen->family == CHIP_HAWAII) rctx->max_db = 16; else if (rscreen->chip_class >= EVERGREEN) rctx->max_db = 8; else rctx->max_db = 4; rctx->b.transfer_map = u_transfer_map_vtbl; rctx->b.transfer_flush_region = u_default_transfer_flush_region; rctx->b.transfer_unmap = u_transfer_unmap_vtbl; rctx->b.transfer_inline_write = u_default_transfer_inline_write; rctx->b.memory_barrier = r600_memory_barrier; rctx->b.flush = r600_flush_from_st; LIST_INITHEAD(&rctx->texture_buffers); r600_init_context_texture_functions(rctx); r600_streamout_init(rctx); r600_query_init(rctx); cayman_init_msaa(&rctx->b); rctx->allocator_so_filled_size = u_suballocator_create(&rctx->b, 4096, 4, 0, PIPE_USAGE_DEFAULT, TRUE); if (!rctx->allocator_so_filled_size) return false; rctx->uploader = u_upload_create(&rctx->b, 1024 * 1024, 256, PIPE_BIND_INDEX_BUFFER | PIPE_BIND_CONSTANT_BUFFER); if (!rctx->uploader) return false; if (rscreen->info.r600_has_dma && !(rscreen->debug_flags & DBG_NO_ASYNC_DMA)) { rctx->rings.dma.cs = rctx->ws->cs_create(rctx->ws, RING_DMA, r600_flush_dma_ring, rctx, NULL); rctx->rings.dma.flush = r600_flush_dma_ring; } return true; } void r600_common_context_cleanup(struct r600_common_context *rctx) { if (rctx->rings.gfx.cs) { rctx->ws->cs_destroy(rctx->rings.gfx.cs); } if (rctx->rings.dma.cs) { rctx->ws->cs_destroy(rctx->rings.dma.cs); } if (rctx->uploader) { u_upload_destroy(rctx->uploader); } util_slab_destroy(&rctx->pool_transfers); if (rctx->allocator_so_filled_size) { u_suballocator_destroy(rctx->allocator_so_filled_size); } } void r600_context_add_resource_size(struct pipe_context *ctx, struct pipe_resource *r) { struct r600_common_context *rctx = (struct r600_common_context *)ctx; struct r600_resource *rr = (struct r600_resource *)r; if (r == NULL) { return; } /* * The idea is to compute a gross estimate of memory requirement of * each draw call. After each draw call, memory will be precisely * accounted. So the uncertainty is only on the current draw call. * In practice this gave very good estimate (+/- 10% of the target * memory limit). */ if (rr->domains & RADEON_DOMAIN_GTT) { rctx->gtt += rr->buf->size; } if (rr->domains & RADEON_DOMAIN_VRAM) { rctx->vram += rr->buf->size; } } /* * pipe_screen */ static const struct debug_named_value common_debug_options[] = { /* logging */ { "tex", DBG_TEX, "Print texture info" }, { "texmip", DBG_TEXMIP, "Print texture info (mipmapped only)" }, { "compute", DBG_COMPUTE, "Print compute info" }, { "vm", DBG_VM, "Print virtual addresses when creating resources" }, { "trace_cs", DBG_TRACE_CS, "Trace cs and write rlockup_.c file with faulty cs" }, /* shaders */ { "fs", DBG_FS, "Print fetch shaders" }, { "vs", DBG_VS, "Print vertex shaders" }, { "gs", DBG_GS, "Print geometry shaders" }, { "ps", DBG_PS, "Print pixel shaders" }, { "cs", DBG_CS, "Print compute shaders" }, /* features */ { "nodma", DBG_NO_ASYNC_DMA, "Disable asynchronous DMA" }, { "hyperz", DBG_HYPERZ, "Enable Hyper-Z" }, /* GL uses the word INVALIDATE, gallium uses the word DISCARD */ { "noinvalrange", DBG_NO_DISCARD_RANGE, "Disable handling of INVALIDATE_RANGE map flags" }, { "no2d", DBG_NO_2D_TILING, "Disable 2D tiling" }, { "notiling", DBG_NO_TILING, "Disable tiling" }, { "switch_on_eop", DBG_SWITCH_ON_EOP, "Program WD/IA to switch on end-of-packet." }, DEBUG_NAMED_VALUE_END /* must be last */ }; static const char* r600_get_vendor(struct pipe_screen* pscreen) { return "X.Org"; } static const char* r600_get_name(struct pipe_screen* pscreen) { struct r600_common_screen *rscreen = (struct r600_common_screen*)pscreen; switch (rscreen->family) { case CHIP_R600: return "AMD R600"; case CHIP_RV610: return "AMD RV610"; case CHIP_RV630: return "AMD RV630"; case CHIP_RV670: return "AMD RV670"; case CHIP_RV620: return "AMD RV620"; case CHIP_RV635: return "AMD RV635"; case CHIP_RS780: return "AMD RS780"; case CHIP_RS880: return "AMD RS880"; case CHIP_RV770: return "AMD RV770"; case CHIP_RV730: return "AMD RV730"; case CHIP_RV710: return "AMD RV710"; case CHIP_RV740: return "AMD RV740"; case CHIP_CEDAR: return "AMD CEDAR"; case CHIP_REDWOOD: return "AMD REDWOOD"; case CHIP_JUNIPER: return "AMD JUNIPER"; case CHIP_CYPRESS: return "AMD CYPRESS"; case CHIP_HEMLOCK: return "AMD HEMLOCK"; case CHIP_PALM: return "AMD PALM"; case CHIP_SUMO: return "AMD SUMO"; case CHIP_SUMO2: return "AMD SUMO2"; case CHIP_BARTS: return "AMD BARTS"; case CHIP_TURKS: return "AMD TURKS"; case CHIP_CAICOS: return "AMD CAICOS"; case CHIP_CAYMAN: return "AMD CAYMAN"; case CHIP_ARUBA: return "AMD ARUBA"; case CHIP_TAHITI: return "AMD TAHITI"; case CHIP_PITCAIRN: return "AMD PITCAIRN"; case CHIP_VERDE: return "AMD CAPE VERDE"; case CHIP_OLAND: return "AMD OLAND"; case CHIP_HAINAN: return "AMD HAINAN"; case CHIP_BONAIRE: return "AMD BONAIRE"; case CHIP_KAVERI: return "AMD KAVERI"; case CHIP_KABINI: return "AMD KABINI"; case CHIP_HAWAII: return "AMD HAWAII"; case CHIP_MULLINS: return "AMD MULLINS"; default: return "AMD unknown"; } } static float r600_get_paramf(struct pipe_screen* pscreen, enum pipe_capf param) { struct r600_common_screen *rscreen = (struct r600_common_screen *)pscreen; switch (param) { case PIPE_CAPF_MAX_LINE_WIDTH: case PIPE_CAPF_MAX_LINE_WIDTH_AA: case PIPE_CAPF_MAX_POINT_WIDTH: case PIPE_CAPF_MAX_POINT_WIDTH_AA: if (rscreen->family >= CHIP_CEDAR) return 16384.0f; else return 8192.0f; case PIPE_CAPF_MAX_TEXTURE_ANISOTROPY: return 16.0f; case PIPE_CAPF_MAX_TEXTURE_LOD_BIAS: return 16.0f; case PIPE_CAPF_GUARD_BAND_LEFT: case PIPE_CAPF_GUARD_BAND_TOP: case PIPE_CAPF_GUARD_BAND_RIGHT: case PIPE_CAPF_GUARD_BAND_BOTTOM: return 0.0f; } return 0.0f; } static int r600_get_video_param(struct pipe_screen *screen, enum pipe_video_profile profile, enum pipe_video_entrypoint entrypoint, enum pipe_video_cap param) { switch (param) { case PIPE_VIDEO_CAP_SUPPORTED: return vl_profile_supported(screen, profile, entrypoint); case PIPE_VIDEO_CAP_NPOT_TEXTURES: return 1; case PIPE_VIDEO_CAP_MAX_WIDTH: case PIPE_VIDEO_CAP_MAX_HEIGHT: return vl_video_buffer_max_size(screen); case PIPE_VIDEO_CAP_PREFERED_FORMAT: return PIPE_FORMAT_NV12; case PIPE_VIDEO_CAP_PREFERS_INTERLACED: return false; case PIPE_VIDEO_CAP_SUPPORTS_INTERLACED: return false; case PIPE_VIDEO_CAP_SUPPORTS_PROGRESSIVE: return true; case PIPE_VIDEO_CAP_MAX_LEVEL: return vl_level_supported(screen, profile); default: return 0; } } const char *r600_get_llvm_processor_name(enum radeon_family family) { switch (family) { case CHIP_R600: case CHIP_RV630: case CHIP_RV635: case CHIP_RV670: return "r600"; case CHIP_RV610: case CHIP_RV620: case CHIP_RS780: case CHIP_RS880: return "rs880"; case CHIP_RV710: return "rv710"; case CHIP_RV730: return "rv730"; case CHIP_RV740: case CHIP_RV770: return "rv770"; case CHIP_PALM: case CHIP_CEDAR: return "cedar"; case CHIP_SUMO: case CHIP_SUMO2: return "sumo"; case CHIP_REDWOOD: return "redwood"; case CHIP_JUNIPER: return "juniper"; case CHIP_HEMLOCK: case CHIP_CYPRESS: return "cypress"; case CHIP_BARTS: return "barts"; case CHIP_TURKS: return "turks"; case CHIP_CAICOS: return "caicos"; case CHIP_CAYMAN: case CHIP_ARUBA: return "cayman"; case CHIP_TAHITI: return "tahiti"; case CHIP_PITCAIRN: return "pitcairn"; case CHIP_VERDE: return "verde"; case CHIP_OLAND: return "oland"; case CHIP_HAINAN: return "hainan"; case CHIP_BONAIRE: return "bonaire"; case CHIP_KABINI: return "kabini"; case CHIP_KAVERI: return "kaveri"; case CHIP_HAWAII: return "hawaii"; case CHIP_MULLINS: #if HAVE_LLVM >= 0x0305 return "mullins"; #else return "kabini"; #endif default: return ""; } } static int r600_get_compute_param(struct pipe_screen *screen, enum pipe_compute_cap param, void *ret) { struct r600_common_screen *rscreen = (struct r600_common_screen *)screen; //TODO: select these params by asic switch (param) { case PIPE_COMPUTE_CAP_IR_TARGET: { const char *gpu; switch(rscreen->family) { /* Clang < 3.6 is missing Hainan in its list of * GPUs, so we need to use the name of a similar GPU. */ #if HAVE_LLVM < 0x0306 case CHIP_HAINAN: gpu = "oland"; break; #endif default: gpu = r600_get_llvm_processor_name(rscreen->family); break; } if (ret) { sprintf(ret, "%s-r600--", gpu); } return (8 + strlen(gpu)) * sizeof(char); } case PIPE_COMPUTE_CAP_GRID_DIMENSION: if (ret) { uint64_t *grid_dimension = ret; grid_dimension[0] = 3; } return 1 * sizeof(uint64_t); case PIPE_COMPUTE_CAP_MAX_GRID_SIZE: if (ret) { uint64_t *grid_size = ret; grid_size[0] = 65535; grid_size[1] = 65535; grid_size[2] = 1; } return 3 * sizeof(uint64_t) ; case PIPE_COMPUTE_CAP_MAX_BLOCK_SIZE: if (ret) { uint64_t *block_size = ret; block_size[0] = 256; block_size[1] = 256; block_size[2] = 256; } return 3 * sizeof(uint64_t); case PIPE_COMPUTE_CAP_MAX_THREADS_PER_BLOCK: if (ret) { uint64_t *max_threads_per_block = ret; *max_threads_per_block = 256; } return sizeof(uint64_t); case PIPE_COMPUTE_CAP_MAX_GLOBAL_SIZE: if (ret) { uint64_t *max_global_size = ret; uint64_t max_mem_alloc_size; r600_get_compute_param(screen, PIPE_COMPUTE_CAP_MAX_MEM_ALLOC_SIZE, &max_mem_alloc_size); /* In OpenCL, the MAX_MEM_ALLOC_SIZE must be at least * 1/4 of the MAX_GLOBAL_SIZE. Since the * MAX_MEM_ALLOC_SIZE is fixed for older kernels, * make sure we never report more than * 4 * MAX_MEM_ALLOC_SIZE. */ *max_global_size = MIN2(4 * max_mem_alloc_size, rscreen->info.gart_size + rscreen->info.vram_size); } return sizeof(uint64_t); case PIPE_COMPUTE_CAP_MAX_LOCAL_SIZE: if (ret) { uint64_t *max_local_size = ret; /* Value reported by the closed source driver. */ *max_local_size = 32768; } return sizeof(uint64_t); case PIPE_COMPUTE_CAP_MAX_INPUT_SIZE: if (ret) { uint64_t *max_input_size = ret; /* Value reported by the closed source driver. */ *max_input_size = 1024; } return sizeof(uint64_t); case PIPE_COMPUTE_CAP_MAX_MEM_ALLOC_SIZE: if (ret) { uint64_t max_global_size; uint64_t *max_mem_alloc_size = ret; /* XXX: The limit in older kernels is 256 MB. We * should add a query here for newer kernels. */ *max_mem_alloc_size = 256 * 1024 * 1024; } return sizeof(uint64_t); case PIPE_COMPUTE_CAP_MAX_CLOCK_FREQUENCY: if (ret) { uint32_t *max_clock_frequency = ret; *max_clock_frequency = rscreen->info.max_sclk; } return sizeof(uint32_t); case PIPE_COMPUTE_CAP_MAX_COMPUTE_UNITS: if (ret) { uint32_t *max_compute_units = ret; *max_compute_units = MAX2(rscreen->info.max_compute_units, 1); } return sizeof(uint32_t); case PIPE_COMPUTE_CAP_IMAGES_SUPPORTED: if (ret) { uint32_t *images_supported = ret; *images_supported = 0; } return sizeof(uint32_t); } fprintf(stderr, "unknown PIPE_COMPUTE_CAP %d\n", param); return 0; } static uint64_t r600_get_timestamp(struct pipe_screen *screen) { struct r600_common_screen *rscreen = (struct r600_common_screen*)screen; return 1000000 * rscreen->ws->query_value(rscreen->ws, RADEON_TIMESTAMP) / rscreen->info.r600_clock_crystal_freq; } static int r600_get_driver_query_info(struct pipe_screen *screen, unsigned index, struct pipe_driver_query_info *info) { struct r600_common_screen *rscreen = (struct r600_common_screen*)screen; struct pipe_driver_query_info list[] = { {"draw-calls", R600_QUERY_DRAW_CALLS, 0}, {"requested-VRAM", R600_QUERY_REQUESTED_VRAM, rscreen->info.vram_size, TRUE}, {"requested-GTT", R600_QUERY_REQUESTED_GTT, rscreen->info.gart_size, TRUE}, {"buffer-wait-time", R600_QUERY_BUFFER_WAIT_TIME, 0, FALSE}, {"num-cs-flushes", R600_QUERY_NUM_CS_FLUSHES, 0, FALSE}, {"num-bytes-moved", R600_QUERY_NUM_BYTES_MOVED, 0, TRUE}, {"VRAM-usage", R600_QUERY_VRAM_USAGE, rscreen->info.vram_size, TRUE}, {"GTT-usage", R600_QUERY_GTT_USAGE, rscreen->info.gart_size, TRUE}, }; if (!info) return Elements(list); if (index >= Elements(list)) return 0; *info = list[index]; return 1; } static void r600_fence_reference(struct pipe_screen *screen, struct pipe_fence_handle **ptr, struct pipe_fence_handle *fence) { struct radeon_winsys *rws = ((struct r600_common_screen*)screen)->ws; rws->fence_reference(ptr, fence); } static boolean r600_fence_signalled(struct pipe_screen *screen, struct pipe_fence_handle *fence) { struct radeon_winsys *rws = ((struct r600_common_screen*)screen)->ws; return rws->fence_wait(rws, fence, 0); } static boolean r600_fence_finish(struct pipe_screen *screen, struct pipe_fence_handle *fence, uint64_t timeout) { struct radeon_winsys *rws = ((struct r600_common_screen*)screen)->ws; return rws->fence_wait(rws, fence, timeout); } static bool r600_interpret_tiling(struct r600_common_screen *rscreen, uint32_t tiling_config) { switch ((tiling_config & 0xe) >> 1) { case 0: rscreen->tiling_info.num_channels = 1; break; case 1: rscreen->tiling_info.num_channels = 2; break; case 2: rscreen->tiling_info.num_channels = 4; break; case 3: rscreen->tiling_info.num_channels = 8; break; default: return false; } switch ((tiling_config & 0x30) >> 4) { case 0: rscreen->tiling_info.num_banks = 4; break; case 1: rscreen->tiling_info.num_banks = 8; break; default: return false; } switch ((tiling_config & 0xc0) >> 6) { case 0: rscreen->tiling_info.group_bytes = 256; break; case 1: rscreen->tiling_info.group_bytes = 512; break; default: return false; } return true; } static bool evergreen_interpret_tiling(struct r600_common_screen *rscreen, uint32_t tiling_config) { switch (tiling_config & 0xf) { case 0: rscreen->tiling_info.num_channels = 1; break; case 1: rscreen->tiling_info.num_channels = 2; break; case 2: rscreen->tiling_info.num_channels = 4; break; case 3: rscreen->tiling_info.num_channels = 8; break; default: return false; } switch ((tiling_config & 0xf0) >> 4) { case 0: rscreen->tiling_info.num_banks = 4; break; case 1: rscreen->tiling_info.num_banks = 8; break; case 2: rscreen->tiling_info.num_banks = 16; break; default: return false; } switch ((tiling_config & 0xf00) >> 8) { case 0: rscreen->tiling_info.group_bytes = 256; break; case 1: rscreen->tiling_info.group_bytes = 512; break; default: return false; } return true; } static bool r600_init_tiling(struct r600_common_screen *rscreen) { uint32_t tiling_config = rscreen->info.r600_tiling_config; /* set default group bytes, overridden by tiling info ioctl */ if (rscreen->chip_class <= R700) { rscreen->tiling_info.group_bytes = 256; } else { rscreen->tiling_info.group_bytes = 512; } if (!tiling_config) return true; if (rscreen->chip_class <= R700) { return r600_interpret_tiling(rscreen, tiling_config); } else { return evergreen_interpret_tiling(rscreen, tiling_config); } } struct pipe_resource *r600_resource_create_common(struct pipe_screen *screen, const struct pipe_resource *templ) { if (templ->target == PIPE_BUFFER) { return r600_buffer_create(screen, templ, 4096); } else { return r600_texture_create(screen, templ); } } bool r600_common_screen_init(struct r600_common_screen *rscreen, struct radeon_winsys *ws) { ws->query_info(ws, &rscreen->info); rscreen->b.get_name = r600_get_name; rscreen->b.get_vendor = r600_get_vendor; rscreen->b.get_compute_param = r600_get_compute_param; rscreen->b.get_paramf = r600_get_paramf; rscreen->b.get_driver_query_info = r600_get_driver_query_info; rscreen->b.get_timestamp = r600_get_timestamp; rscreen->b.fence_finish = r600_fence_finish; rscreen->b.fence_reference = r600_fence_reference; rscreen->b.fence_signalled = r600_fence_signalled; rscreen->b.resource_destroy = u_resource_destroy_vtbl; if (rscreen->info.has_uvd) { rscreen->b.get_video_param = rvid_get_video_param; rscreen->b.is_video_format_supported = rvid_is_format_supported; } else { rscreen->b.get_video_param = r600_get_video_param; rscreen->b.is_video_format_supported = vl_video_buffer_is_format_supported; } r600_init_screen_texture_functions(rscreen); rscreen->ws = ws; rscreen->family = rscreen->info.family; rscreen->chip_class = rscreen->info.chip_class; rscreen->debug_flags = debug_get_flags_option("R600_DEBUG", common_debug_options, 0); if (!r600_init_tiling(rscreen)) { return false; } util_format_s3tc_init(); pipe_mutex_init(rscreen->aux_context_lock); if (rscreen->info.drm_minor >= 28 && (rscreen->debug_flags & DBG_TRACE_CS)) { rscreen->trace_bo = (struct r600_resource*)pipe_buffer_create(&rscreen->b, PIPE_BIND_CUSTOM, PIPE_USAGE_STAGING, 4096); if (rscreen->trace_bo) { rscreen->trace_ptr = rscreen->ws->buffer_map(rscreen->trace_bo->cs_buf, NULL, PIPE_TRANSFER_UNSYNCHRONIZED); } } return true; } void r600_destroy_common_screen(struct r600_common_screen *rscreen) { pipe_mutex_destroy(rscreen->aux_context_lock); rscreen->aux_context->destroy(rscreen->aux_context); if (rscreen->trace_bo) { rscreen->ws->buffer_unmap(rscreen->trace_bo->cs_buf); pipe_resource_reference((struct pipe_resource**)&rscreen->trace_bo, NULL); } rscreen->ws->destroy(rscreen->ws); FREE(rscreen); } static unsigned tgsi_get_processor_type(const struct tgsi_token *tokens) { struct tgsi_parse_context parse; if (tgsi_parse_init( &parse, tokens ) != TGSI_PARSE_OK) { debug_printf("tgsi_parse_init() failed in %s:%i!\n", __func__, __LINE__); return ~0; } return parse.FullHeader.Processor.Processor; } bool r600_can_dump_shader(struct r600_common_screen *rscreen, const struct tgsi_token *tokens) { /* Compute shader don't have tgsi_tokens */ if (!tokens) return (rscreen->debug_flags & DBG_CS) != 0; switch (tgsi_get_processor_type(tokens)) { case TGSI_PROCESSOR_VERTEX: return (rscreen->debug_flags & DBG_VS) != 0; case TGSI_PROCESSOR_GEOMETRY: return (rscreen->debug_flags & DBG_GS) != 0; case TGSI_PROCESSOR_FRAGMENT: return (rscreen->debug_flags & DBG_PS) != 0; case TGSI_PROCESSOR_COMPUTE: return (rscreen->debug_flags & DBG_CS) != 0; default: return false; } } void r600_screen_clear_buffer(struct r600_common_screen *rscreen, struct pipe_resource *dst, unsigned offset, unsigned size, unsigned value) { struct r600_common_context *rctx = (struct r600_common_context*)rscreen->aux_context; pipe_mutex_lock(rscreen->aux_context_lock); rctx->clear_buffer(&rctx->b, dst, offset, size, value); rscreen->aux_context->flush(rscreen->aux_context, NULL, 0); pipe_mutex_unlock(rscreen->aux_context_lock); }