/* * 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 */ #include "util/u_surface.h" #include "util/u_transfer.h" #include "util/u_format_etc.h" #include "ilo_blit.h" #include "ilo_cp.h" #include "ilo_context.h" #include "ilo_resource.h" #include "ilo_state.h" #include "ilo_transfer.h" static bool is_bo_busy(struct ilo_context *ilo, struct intel_bo *bo, bool *need_flush) { const bool referenced = intel_bo_has_reloc(ilo->cp->bo, bo); if (need_flush) *need_flush = referenced; if (referenced) return true; return intel_bo_is_busy(bo); } static void * map_bo_for_transfer(struct ilo_context *ilo, struct intel_bo *bo, const struct ilo_transfer *xfer) { void *ptr; switch (xfer->method) { case ILO_TRANSFER_MAP_CPU: ptr = intel_bo_map(bo, (xfer->base.usage & PIPE_TRANSFER_WRITE)); break; case ILO_TRANSFER_MAP_GTT: ptr = intel_bo_map_gtt(bo); break; case ILO_TRANSFER_MAP_UNSYNC: ptr = intel_bo_map_unsynchronized(bo); break; default: assert(!"unknown mapping method"); ptr = NULL; break; } return ptr; } /** * Choose the best mapping method, depending on the transfer usage and whether * the bo is busy. */ static bool choose_transfer_method(struct ilo_context *ilo, struct ilo_transfer *xfer) { struct pipe_resource *res = xfer->base.resource; const unsigned usage = xfer->base.usage; /* prefer map() when there is the last-level cache */ const bool prefer_cpu = (ilo->dev->has_llc || (usage & PIPE_TRANSFER_READ)); struct ilo_texture *tex; struct ilo_buffer *buf; struct intel_bo *bo; bool tiled, need_flush; if (res->target == PIPE_BUFFER) { tex = NULL; buf = ilo_buffer(res); bo = buf->bo; tiled = false; } else { buf = NULL; tex = ilo_texture(res); bo = tex->bo; tiled = (tex->tiling != INTEL_TILING_NONE); } /* choose between mapping through CPU or GTT */ if (usage & PIPE_TRANSFER_MAP_DIRECTLY) { /* we do not want fencing */ if (tiled || prefer_cpu) xfer->method = ILO_TRANSFER_MAP_CPU; else xfer->method = ILO_TRANSFER_MAP_GTT; } else { if (!tiled && prefer_cpu) xfer->method = ILO_TRANSFER_MAP_CPU; else xfer->method = ILO_TRANSFER_MAP_GTT; } /* see if we can avoid stalling */ if (is_bo_busy(ilo, bo, &need_flush)) { bool will_stall = true; if (usage & PIPE_TRANSFER_MAP_DIRECTLY) { /* nothing we can do */ } else if (usage & PIPE_TRANSFER_UNSYNCHRONIZED) { /* unsynchronized gtt mapping does not stall */ xfer->method = ILO_TRANSFER_MAP_UNSYNC; will_stall = false; } else if (usage & PIPE_TRANSFER_DISCARD_WHOLE_RESOURCE) { /* discard old bo and allocate a new one for mapping */ if ((tex && ilo_texture_alloc_bo(tex)) || (buf && ilo_buffer_alloc_bo(buf))) { ilo_mark_states_with_resource_dirty(ilo, res); will_stall = false; } } else if (usage & PIPE_TRANSFER_FLUSH_EXPLICIT) { /* * We could allocate and return a system buffer here. When a region of * the buffer is explicitly flushed, we pwrite() the region to a * temporary bo and emit pipelined copy blit. * * For now, do nothing. */ } else if (usage & PIPE_TRANSFER_DISCARD_RANGE) { /* * We could allocate a temporary bo for mapping, and emit pipelined copy * blit upon unmapping. * * For now, do nothing. */ } if (will_stall) { if (usage & PIPE_TRANSFER_DONTBLOCK) return false; /* flush to make bo busy (so that map() stalls as it should be) */ if (need_flush) ilo_cp_flush(ilo->cp, "syncing for transfers"); } } if (tex && !(usage & PIPE_TRANSFER_MAP_DIRECTLY)) { if (tex->separate_s8 || tex->bo_format == PIPE_FORMAT_S8_UINT) xfer->method = ILO_TRANSFER_MAP_SW_ZS; /* need to convert on-the-fly */ else if (tex->bo_format != tex->base.format) xfer->method = ILO_TRANSFER_MAP_SW_CONVERT; } return true; } static void tex_get_box_origin(const struct ilo_texture *tex, unsigned level, unsigned slice, const struct pipe_box *box, unsigned *mem_x, unsigned *mem_y) { const struct ilo_texture_slice *s = ilo_texture_get_slice(tex, level, slice + box->z); unsigned x, y; x = s->x + box->x; y = s->y + box->y; assert(x % tex->block_width == 0 && y % tex->block_height == 0); *mem_x = x / tex->block_width * tex->block_size; *mem_y = y / tex->block_height; } static unsigned tex_get_box_offset(const struct ilo_texture *tex, unsigned level, const struct pipe_box *box) { unsigned mem_x, mem_y; tex_get_box_origin(tex, level, 0, box, &mem_x, &mem_y); return mem_y * tex->bo_stride + mem_x; } static unsigned tex_get_slice_stride(const struct ilo_texture *tex, unsigned level) { const struct ilo_texture_slice *s0, *s1; unsigned qpitch; /* there is no 3D array texture */ assert(tex->base.array_size == 1 || tex->base.depth0 == 1); if (tex->base.array_size == 1) { /* non-array, non-3D */ if (tex->base.depth0 == 1) return 0; /* only the first level has a fixed slice stride */ if (level > 0) { assert(!"no slice stride for 3D texture with level > 0"); return 0; } } s0 = ilo_texture_get_slice(tex, level, 0); s1 = ilo_texture_get_slice(tex, level, 1); qpitch = s1->y - s0->y; assert(qpitch % tex->block_height == 0); return (qpitch / tex->block_height) * tex->bo_stride; } static unsigned tex_tile_x_swizzle(unsigned addr) { /* * From the Ivy Bridge PRM, volume 1 part 2, page 24: * * "As shown in the tiling algorithm, the new address bit[6] should be: * * Address bit[6] <= TiledAddr bit[6] XOR * TiledAddr bit[9] XOR * TiledAddr bit[10]" */ return addr ^ (((addr >> 3) ^ (addr >> 4)) & 0x40); } static unsigned tex_tile_y_swizzle(unsigned addr) { /* * From the Ivy Bridge PRM, volume 1 part 2, page 24: * * "As shown in the tiling algorithm, The new address bit[6] becomes: * * Address bit[6] <= TiledAddr bit[6] XOR * TiledAddr bit[9]" */ return addr ^ ((addr >> 3) & 0x40); } static unsigned tex_tile_x_offset(unsigned mem_x, unsigned mem_y, unsigned tiles_per_row, bool swizzle) { /* * From the Sandy Bridge PRM, volume 1 part 2, page 21, we know that a * X-major tile has 8 rows and 32 OWord columns (512 bytes). Tiles in the * tiled region are numbered in row-major order, starting from zero. The * tile number can thus be calculated as follows: * * tile = (mem_y / 8) * tiles_per_row + (mem_x / 512) * * OWords in that tile are also numbered in row-major order, starting from * zero. The OWord number can thus be calculated as follows: * * oword = (mem_y % 8) * 32 + ((mem_x % 512) / 16) * * and the tiled offset is * * offset = tile * 4096 + oword * 16 + (mem_x % 16) * = tile * 4096 + (mem_y % 8) * 512 + (mem_x % 512) */ unsigned tile, offset; tile = (mem_y >> 3) * tiles_per_row + (mem_x >> 9); offset = tile << 12 | (mem_y & 0x7) << 9 | (mem_x & 0x1ff); return (swizzle) ? tex_tile_x_swizzle(offset) : offset; } static unsigned tex_tile_y_offset(unsigned mem_x, unsigned mem_y, unsigned tiles_per_row, bool swizzle) { /* * From the Sandy Bridge PRM, volume 1 part 2, page 22, we know that a * Y-major tile has 32 rows and 8 OWord columns (128 bytes). Tiles in the * tiled region are numbered in row-major order, starting from zero. The * tile number can thus be calculated as follows: * * tile = (mem_y / 32) * tiles_per_row + (mem_x / 128) * * OWords in that tile are numbered in column-major order, starting from * zero. The OWord number can thus be calculated as follows: * * oword = ((mem_x % 128) / 16) * 32 + (mem_y % 32) * * and the tiled offset is * * offset = tile * 4096 + oword * 16 + (mem_x % 16) */ unsigned tile, oword, offset; tile = (mem_y >> 5) * tiles_per_row + (mem_x >> 7); oword = (mem_x & 0x70) << 1 | (mem_y & 0x1f); offset = tile << 12 | oword << 4 | (mem_x & 0xf); return (swizzle) ? tex_tile_y_swizzle(offset) : offset; } static unsigned tex_tile_w_offset(unsigned mem_x, unsigned mem_y, unsigned tiles_per_row, bool swizzle) { /* * From the Sandy Bridge PRM, volume 1 part 2, page 23, we know that a * W-major tile has 8 8x8-block rows and 8 8x8-block columns. Tiles in the * tiled region are numbered in row-major order, starting from zero. The * tile number can thus be calculated as follows: * * tile = (mem_y / 64) * tiles_per_row + (mem_x / 64) * * 8x8-blocks in that tile are numbered in column-major order, starting * from zero. The 8x8-block number can thus be calculated as follows: * * blk8 = ((mem_x % 64) / 8) * 8 + ((mem_y % 64) / 8) * * Each 8x8-block is divided into 4 4x4-blocks, in row-major order. Each * 4x4-block is further divided into 4 2x2-blocks, also in row-major order. * We have * * blk4 = (((mem_y % 64) / 4) & 1) * 2 + (((mem_x % 64) / 4) & 1) * blk2 = (((mem_y % 64) / 2) & 1) * 2 + (((mem_x % 64) / 2) & 1) * blk1 = (((mem_y % 64) ) & 1) * 2 + (((mem_x % 64) ) & 1) * * and the tiled offset is * * offset = tile * 4096 + blk8 * 64 + blk4 * 16 + blk2 * 4 + blk1 */ unsigned tile, blk8, blk4, blk2, blk1, offset; tile = (mem_y >> 6) * tiles_per_row + (mem_x >> 6); blk8 = ((mem_x >> 3) & 0x7) << 3 | ((mem_y >> 3) & 0x7); blk4 = ((mem_y >> 2) & 0x1) << 1 | ((mem_x >> 2) & 0x1); blk2 = ((mem_y >> 1) & 0x1) << 1 | ((mem_x >> 1) & 0x1); blk1 = ((mem_y ) & 0x1) << 1 | ((mem_x ) & 0x1); offset = tile << 12 | blk8 << 6 | blk4 << 4 | blk2 << 2 | blk1; return (swizzle) ? tex_tile_y_swizzle(offset) : offset; } static unsigned tex_tile_none_offset(unsigned mem_x, unsigned mem_y, unsigned tiles_per_row, bool swizzle) { return mem_y * tiles_per_row + mem_x; } typedef unsigned (*tex_tile_offset_func)(unsigned mem_x, unsigned mem_y, unsigned tiles_per_row, bool swizzle); static tex_tile_offset_func tex_tile_choose_offset_func(const struct ilo_texture *tex, unsigned *tiles_per_row) { switch (tex->tiling) { case INTEL_TILING_X: *tiles_per_row = tex->bo_stride / 512; return tex_tile_x_offset; case INTEL_TILING_Y: *tiles_per_row = tex->bo_stride / 128; return tex_tile_y_offset; case INTEL_TILING_NONE: default: /* W-tiling */ if (tex->bo_format == PIPE_FORMAT_S8_UINT) { *tiles_per_row = tex->bo_stride / 64; return tex_tile_w_offset; } else { *tiles_per_row = tex->bo_stride; return tex_tile_none_offset; } } } static void * tex_staging_sys_map_bo(const struct ilo_context *ilo, struct ilo_texture *tex, bool for_read_back, bool linear_view) { const bool prefer_cpu = (ilo->dev->has_llc || for_read_back); void *ptr; if (prefer_cpu && (tex->tiling == INTEL_TILING_NONE || !linear_view)) ptr = intel_bo_map(tex->bo, !for_read_back); else ptr = intel_bo_map_gtt(tex->bo); return ptr; } static void tex_staging_sys_unmap_bo(const struct ilo_context *ilo, const struct ilo_texture *tex) { intel_bo_unmap(tex->bo); } static bool tex_staging_sys_zs_read(struct ilo_context *ilo, struct ilo_texture *tex, const struct ilo_transfer *xfer) { const bool swizzle = ilo->dev->has_address_swizzling; const struct pipe_box *box = &xfer->base.box; const uint8_t *src; tex_tile_offset_func tile_offset; unsigned tiles_per_row; int slice; src = tex_staging_sys_map_bo(ilo, tex, true, false); if (!src) return false; tile_offset = tex_tile_choose_offset_func(tex, &tiles_per_row); assert(tex->block_width == 1 && tex->block_height == 1); if (tex->separate_s8) { struct ilo_texture *s8_tex = tex->separate_s8; const uint8_t *s8_src; tex_tile_offset_func s8_tile_offset; unsigned s8_tiles_per_row; int dst_cpp, dst_s8_pos, src_cpp_used; s8_src = tex_staging_sys_map_bo(ilo, s8_tex, true, false); if (!s8_src) { tex_staging_sys_unmap_bo(ilo, tex); return false; } s8_tile_offset = tex_tile_choose_offset_func(s8_tex, &s8_tiles_per_row); if (tex->base.format == PIPE_FORMAT_Z24_UNORM_S8_UINT) { assert(tex->bo_format == PIPE_FORMAT_Z24X8_UNORM); dst_cpp = 4; dst_s8_pos = 3; src_cpp_used = 3; } else { assert(tex->base.format == PIPE_FORMAT_Z32_FLOAT_S8X24_UINT); assert(tex->bo_format == PIPE_FORMAT_Z32_FLOAT); dst_cpp = 8; dst_s8_pos = 4; src_cpp_used = 4; } for (slice = 0; slice < box->depth; slice++) { unsigned mem_x, mem_y, s8_mem_x, s8_mem_y; uint8_t *dst; int i, j; tex_get_box_origin(tex, xfer->base.level, slice, box, &mem_x, &mem_y); tex_get_box_origin(s8_tex, xfer->base.level, slice, box, &s8_mem_x, &s8_mem_y); dst = xfer->staging_sys + xfer->base.layer_stride * slice; for (i = 0; i < box->height; i++) { unsigned x = mem_x, s8_x = s8_mem_x; uint8_t *d = dst; for (j = 0; j < box->width; j++) { const unsigned offset = tile_offset(x, mem_y, tiles_per_row, swizzle); const unsigned s8_offset = s8_tile_offset(s8_x, s8_mem_y, s8_tiles_per_row, swizzle); memcpy(d, src + offset, src_cpp_used); d[dst_s8_pos] = s8_src[s8_offset]; d += dst_cpp; x += tex->block_size; s8_x++; } dst += xfer->base.stride; mem_y++; s8_mem_y++; } } tex_staging_sys_unmap_bo(ilo, s8_tex); } else { assert(tex->bo_format == PIPE_FORMAT_S8_UINT); for (slice = 0; slice < box->depth; slice++) { unsigned mem_x, mem_y; uint8_t *dst; int i, j; tex_get_box_origin(tex, xfer->base.level, slice, box, &mem_x, &mem_y); dst = xfer->staging_sys + xfer->base.layer_stride * slice; for (i = 0; i < box->height; i++) { unsigned x = mem_x; uint8_t *d = dst; for (j = 0; j < box->width; j++) { const unsigned offset = tile_offset(x, mem_y, tiles_per_row, swizzle); *d = src[offset]; d++; x++; } dst += xfer->base.stride; mem_y++; } } } tex_staging_sys_unmap_bo(ilo, tex); return true; } static bool tex_staging_sys_zs_write(struct ilo_context *ilo, struct ilo_texture *tex, const struct ilo_transfer *xfer) { const bool swizzle = ilo->dev->has_address_swizzling; const struct pipe_box *box = &xfer->base.box; uint8_t *dst; tex_tile_offset_func tile_offset; unsigned tiles_per_row; int slice; dst = tex_staging_sys_map_bo(ilo, tex, false, false); if (!dst) return false; tile_offset = tex_tile_choose_offset_func(tex, &tiles_per_row); assert(tex->block_width == 1 && tex->block_height == 1); if (tex->separate_s8) { struct ilo_texture *s8_tex = tex->separate_s8; uint8_t *s8_dst; tex_tile_offset_func s8_tile_offset; unsigned s8_tiles_per_row; int src_cpp, src_s8_pos, dst_cpp_used; s8_dst = tex_staging_sys_map_bo(ilo, s8_tex, false, false); if (!s8_dst) { tex_staging_sys_unmap_bo(ilo, s8_tex); return false; } s8_tile_offset = tex_tile_choose_offset_func(s8_tex, &s8_tiles_per_row); if (tex->base.format == PIPE_FORMAT_Z24_UNORM_S8_UINT) { assert(tex->bo_format == PIPE_FORMAT_Z24X8_UNORM); src_cpp = 4; src_s8_pos = 3; dst_cpp_used = 3; } else { assert(tex->base.format == PIPE_FORMAT_Z32_FLOAT_S8X24_UINT); assert(tex->bo_format == PIPE_FORMAT_Z32_FLOAT); src_cpp = 8; src_s8_pos = 4; dst_cpp_used = 4; } for (slice = 0; slice < box->depth; slice++) { unsigned mem_x, mem_y, s8_mem_x, s8_mem_y; const uint8_t *src; int i, j; tex_get_box_origin(tex, xfer->base.level, slice, box, &mem_x, &mem_y); tex_get_box_origin(s8_tex, xfer->base.level, slice, box, &s8_mem_x, &s8_mem_y); src = xfer->staging_sys + xfer->base.layer_stride * slice; for (i = 0; i < box->height; i++) { unsigned x = mem_x, s8_x = s8_mem_x; const uint8_t *s = src; for (j = 0; j < box->width; j++) { const unsigned offset = tile_offset(x, mem_y, tiles_per_row, swizzle); const unsigned s8_offset = s8_tile_offset(s8_x, s8_mem_y, s8_tiles_per_row, swizzle); memcpy(dst + offset, s, dst_cpp_used); s8_dst[s8_offset] = s[src_s8_pos]; s += src_cpp; x += tex->block_size; s8_x++; } src += xfer->base.stride; mem_y++; s8_mem_y++; } } tex_staging_sys_unmap_bo(ilo, s8_tex); } else { assert(tex->bo_format == PIPE_FORMAT_S8_UINT); for (slice = 0; slice < box->depth; slice++) { unsigned mem_x, mem_y; const uint8_t *src; int i, j; tex_get_box_origin(tex, xfer->base.level, slice, box, &mem_x, &mem_y); src = xfer->staging_sys + xfer->base.layer_stride * slice; for (i = 0; i < box->height; i++) { unsigned x = mem_x; const uint8_t *s = src; for (j = 0; j < box->width; j++) { const unsigned offset = tile_offset(x, mem_y, tiles_per_row, swizzle); dst[offset] = *s; s++; x++; } src += xfer->base.stride; mem_y++; } } } tex_staging_sys_unmap_bo(ilo, tex); return true; } static bool tex_staging_sys_convert_write(struct ilo_context *ilo, struct ilo_texture *tex, const struct ilo_transfer *xfer) { const struct pipe_box *box = &xfer->base.box; unsigned dst_slice_stride; void *dst; int slice; dst = tex_staging_sys_map_bo(ilo, tex, false, true); if (!dst) return false; dst += tex_get_box_offset(tex, xfer->base.level, box); /* slice stride is not always available */ if (box->depth > 1) dst_slice_stride = tex_get_slice_stride(tex, xfer->base.level); else dst_slice_stride = 0; if (unlikely(tex->bo_format == tex->base.format)) { util_copy_box(dst, tex->bo_format, tex->bo_stride, dst_slice_stride, 0, 0, 0, box->width, box->height, box->depth, xfer->staging_sys, xfer->base.stride, xfer->base.layer_stride, 0, 0, 0); tex_staging_sys_unmap_bo(ilo, tex); return true; } switch (tex->base.format) { case PIPE_FORMAT_ETC1_RGB8: assert(tex->bo_format == PIPE_FORMAT_R8G8B8X8_UNORM); for (slice = 0; slice < box->depth; slice++) { const void *src = xfer->staging_sys + xfer->base.layer_stride * slice; util_format_etc1_rgb8_unpack_rgba_8unorm(dst, tex->bo_stride, src, xfer->base.stride, box->width, box->height); dst += dst_slice_stride; } break; default: assert(!"unable to convert the staging data"); break; } tex_staging_sys_unmap_bo(ilo, tex); return true; } static void tex_staging_sys_unmap(struct ilo_context *ilo, struct ilo_texture *tex, struct ilo_transfer *xfer) { bool success; if (!(xfer->base.usage & PIPE_TRANSFER_WRITE)) { FREE(xfer->staging_sys); return; } switch (xfer->method) { case ILO_TRANSFER_MAP_SW_CONVERT: success = tex_staging_sys_convert_write(ilo, tex, xfer); break; case ILO_TRANSFER_MAP_SW_ZS: success = tex_staging_sys_zs_write(ilo, tex, xfer); break; default: assert(!"unknown mapping method"); success = false; break; } if (!success) ilo_err("failed to map resource for moving staging data\n"); FREE(xfer->staging_sys); } static bool tex_staging_sys_map(struct ilo_context *ilo, struct ilo_texture *tex, struct ilo_transfer *xfer) { const struct pipe_box *box = &xfer->base.box; const size_t stride = util_format_get_stride(tex->base.format, box->width); const size_t size = util_format_get_2d_size(tex->base.format, stride, box->height); bool read_back = false, success; xfer->staging_sys = MALLOC(size * box->depth); if (!xfer->staging_sys) return false; xfer->base.stride = stride; xfer->base.layer_stride = size; xfer->ptr = xfer->staging_sys; /* see if we need to read the resource back */ if (xfer->base.usage & PIPE_TRANSFER_READ) { read_back = true; } else if (xfer->base.usage & PIPE_TRANSFER_WRITE) { const unsigned discard_flags = (PIPE_TRANSFER_DISCARD_RANGE | PIPE_TRANSFER_DISCARD_WHOLE_RESOURCE); if (!(xfer->base.usage & discard_flags)) read_back = true; } if (!read_back) return true; switch (xfer->method) { case ILO_TRANSFER_MAP_SW_CONVERT: assert(!"no on-the-fly format conversion for mapping"); success = false; break; case ILO_TRANSFER_MAP_SW_ZS: success = tex_staging_sys_zs_read(ilo, tex, xfer); break; default: assert(!"unknown mapping method"); success = false; break; } return success; } static void tex_direct_unmap(struct ilo_context *ilo, struct ilo_texture *tex, struct ilo_transfer *xfer) { intel_bo_unmap(tex->bo); } static bool tex_direct_map(struct ilo_context *ilo, struct ilo_texture *tex, struct ilo_transfer *xfer) { xfer->ptr = map_bo_for_transfer(ilo, tex->bo, xfer); if (!xfer->ptr) return false; xfer->ptr += tex_get_box_offset(tex, xfer->base.level, &xfer->base.box); /* note that stride is for a block row, not a texel row */ xfer->base.stride = tex->bo_stride; /* slice stride is not always available */ if (xfer->base.box.depth > 1) xfer->base.layer_stride = tex_get_slice_stride(tex, xfer->base.level); else xfer->base.layer_stride = 0; return true; } static bool tex_map(struct ilo_context *ilo, struct ilo_transfer *xfer) { struct ilo_texture *tex = ilo_texture(xfer->base.resource); bool success; if (!choose_transfer_method(ilo, xfer)) return false; switch (xfer->method) { case ILO_TRANSFER_MAP_CPU: case ILO_TRANSFER_MAP_GTT: case ILO_TRANSFER_MAP_UNSYNC: success = tex_direct_map(ilo, tex, xfer); break; case ILO_TRANSFER_MAP_SW_CONVERT: case ILO_TRANSFER_MAP_SW_ZS: success = tex_staging_sys_map(ilo, tex, xfer); break; default: assert(!"unknown mapping method"); success = false; break; } return success; } static void tex_unmap(struct ilo_context *ilo, struct ilo_transfer *xfer) { struct ilo_texture *tex = ilo_texture(xfer->base.resource); switch (xfer->method) { case ILO_TRANSFER_MAP_CPU: case ILO_TRANSFER_MAP_GTT: case ILO_TRANSFER_MAP_UNSYNC: tex_direct_unmap(ilo, tex, xfer); break; case ILO_TRANSFER_MAP_SW_CONVERT: case ILO_TRANSFER_MAP_SW_ZS: tex_staging_sys_unmap(ilo, tex, xfer); break; default: assert(!"unknown mapping method"); break; } } static bool buf_map(struct ilo_context *ilo, struct ilo_transfer *xfer) { struct ilo_buffer *buf = ilo_buffer(xfer->base.resource); if (!choose_transfer_method(ilo, xfer)) return false; xfer->ptr = map_bo_for_transfer(ilo, buf->bo, xfer); if (!xfer->ptr) return false; assert(xfer->base.level == 0); assert(xfer->base.box.y == 0); assert(xfer->base.box.z == 0); assert(xfer->base.box.height == 1); assert(xfer->base.box.depth == 1); xfer->ptr += xfer->base.box.x; xfer->base.stride = 0; xfer->base.layer_stride = 0; return true; } static void buf_unmap(struct ilo_context *ilo, struct ilo_transfer *xfer) { struct ilo_buffer *buf = ilo_buffer(xfer->base.resource); intel_bo_unmap(buf->bo); } static void buf_pwrite(struct ilo_context *ilo, struct ilo_buffer *buf, unsigned usage, int offset, int size, const void *data) { bool need_flush; /* see if we can avoid stalling */ if (is_bo_busy(ilo, buf->bo, &need_flush)) { bool will_stall = true; if (usage & PIPE_TRANSFER_DISCARD_WHOLE_RESOURCE) { /* old data not needed so discard the old bo to avoid stalling */ if (ilo_buffer_alloc_bo(buf)) { ilo_mark_states_with_resource_dirty(ilo, &buf->base); will_stall = false; } } else { /* * We could allocate a temporary bo to hold the data and emit * pipelined copy blit to move them to buf->bo. But for now, do * nothing. */ } /* flush to make bo busy (so that pwrite() stalls as it should be) */ if (will_stall && need_flush) ilo_cp_flush(ilo->cp, "syncing for pwrites"); } intel_bo_pwrite(buf->bo, offset, size, data); } static void ilo_transfer_flush_region(struct pipe_context *pipe, struct pipe_transfer *transfer, const struct pipe_box *box) { } static void ilo_transfer_unmap(struct pipe_context *pipe, struct pipe_transfer *transfer) { struct ilo_context *ilo = ilo_context(pipe); struct ilo_transfer *xfer = ilo_transfer(transfer); if (xfer->base.resource->target == PIPE_BUFFER) buf_unmap(ilo, xfer); else tex_unmap(ilo, xfer); pipe_resource_reference(&xfer->base.resource, NULL); util_slab_free(&ilo->transfer_mempool, xfer); } static void * ilo_transfer_map(struct pipe_context *pipe, struct pipe_resource *res, unsigned level, unsigned usage, const struct pipe_box *box, struct pipe_transfer **transfer) { struct ilo_context *ilo = ilo_context(pipe); struct ilo_transfer *xfer; bool success; xfer = util_slab_alloc(&ilo->transfer_mempool); if (!xfer) { *transfer = NULL; return NULL; } xfer->base.resource = NULL; pipe_resource_reference(&xfer->base.resource, res); xfer->base.level = level; xfer->base.usage = usage; xfer->base.box = *box; ilo_blit_resolve_transfer(ilo, &xfer->base); if (res->target == PIPE_BUFFER) success = buf_map(ilo, xfer); else success = tex_map(ilo, xfer); if (!success) { pipe_resource_reference(&xfer->base.resource, NULL); FREE(xfer); *transfer = NULL; return NULL; } *transfer = &xfer->base; return xfer->ptr; } static void ilo_transfer_inline_write(struct pipe_context *pipe, struct pipe_resource *res, unsigned level, unsigned usage, const struct pipe_box *box, const void *data, unsigned stride, unsigned layer_stride) { if (likely(res->target == PIPE_BUFFER) && !(usage & PIPE_TRANSFER_UNSYNCHRONIZED)) { /* they should specify just an offset and a size */ assert(level == 0); assert(box->y == 0); assert(box->z == 0); assert(box->height == 1); assert(box->depth == 1); buf_pwrite(ilo_context(pipe), ilo_buffer(res), usage, box->x, box->width, data); } else { u_default_transfer_inline_write(pipe, res, level, usage, box, data, stride, layer_stride); } } /** * Initialize transfer-related functions. */ void ilo_init_transfer_functions(struct ilo_context *ilo) { ilo->base.transfer_map = ilo_transfer_map; ilo->base.transfer_flush_region = ilo_transfer_flush_region; ilo->base.transfer_unmap = ilo_transfer_unmap; ilo->base.transfer_inline_write = ilo_transfer_inline_write; }