/********************************************************** * Copyright 2008-2009 VMware, Inc. All rights reserved. * * Permission is hereby granted, free of charge, to any person * obtaining a copy of this software and associated documentation * files (the "Software"), to deal in the Software without * restriction, including without limitation the rights to use, copy, * modify, merge, publish, distribute, sublicense, and/or sell copies * of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS * BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN * ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. * **********************************************************/ #include "svga3d_reg.h" #include "svga3d_surfacedefs.h" #include "pipe/p_state.h" #include "pipe/p_defines.h" #include "os/os_thread.h" #include "util/u_format.h" #include "util/u_inlines.h" #include "util/u_math.h" #include "util/u_memory.h" #include "util/u_resource.h" #include "util/u_upload_mgr.h" #include "svga_cmd.h" #include "svga_format.h" #include "svga_screen.h" #include "svga_context.h" #include "svga_resource_texture.h" #include "svga_resource_buffer.h" #include "svga_sampler_view.h" #include "svga_winsys.h" #include "svga_debug.h" static void svga_transfer_dma_band(struct svga_context *svga, struct svga_transfer *st, SVGA3dTransferType transfer, unsigned x, unsigned y, unsigned z, unsigned w, unsigned h, unsigned d, unsigned srcx, unsigned srcy, unsigned srcz, SVGA3dSurfaceDMAFlags flags) { struct svga_texture *texture = svga_texture(st->base.resource); SVGA3dCopyBox box; enum pipe_error ret; assert(!st->use_direct_map); box.x = x; box.y = y; box.z = z; box.w = w; box.h = h; box.d = d; box.srcx = srcx; box.srcy = srcy; box.srcz = srcz; SVGA_DBG(DEBUG_DMA, "dma %s sid %p, face %u, (%u, %u, %u) - " "(%u, %u, %u), %ubpp\n", transfer == SVGA3D_WRITE_HOST_VRAM ? "to" : "from", texture->handle, st->slice, x, y, z, x + w, y + h, z + 1, util_format_get_blocksize(texture->b.b.format) * 8 / (util_format_get_blockwidth(texture->b.b.format) * util_format_get_blockheight(texture->b.b.format))); ret = SVGA3D_SurfaceDMA(svga->swc, st, transfer, &box, 1, flags); if (ret != PIPE_OK) { svga_context_flush(svga, NULL); ret = SVGA3D_SurfaceDMA(svga->swc, st, transfer, &box, 1, flags); assert(ret == PIPE_OK); } } static void svga_transfer_dma(struct svga_context *svga, struct svga_transfer *st, SVGA3dTransferType transfer, SVGA3dSurfaceDMAFlags flags) { struct svga_texture *texture = svga_texture(st->base.resource); struct svga_screen *screen = svga_screen(texture->b.b.screen); struct svga_winsys_screen *sws = screen->sws; struct pipe_fence_handle *fence = NULL; assert(!st->use_direct_map); if (transfer == SVGA3D_READ_HOST_VRAM) { SVGA_DBG(DEBUG_PERF, "%s: readback transfer\n", __FUNCTION__); } /* Ensure any pending operations on host surfaces are queued on the command * buffer first. */ svga_surfaces_flush( svga ); if (!st->swbuf) { /* Do the DMA transfer in a single go */ svga_transfer_dma_band(svga, st, transfer, st->box.x, st->box.y, st->box.z, st->box.w, st->box.h, st->box.d, 0, 0, 0, flags); if (transfer == SVGA3D_READ_HOST_VRAM) { svga_context_flush(svga, &fence); sws->fence_finish(sws, fence, PIPE_TIMEOUT_INFINITE, 0); sws->fence_reference(sws, &fence, NULL); } } else { int y, h, srcy; unsigned blockheight = util_format_get_blockheight(st->base.resource->format); h = st->hw_nblocksy * blockheight; srcy = 0; for (y = 0; y < st->box.h; y += h) { unsigned offset, length; void *hw, *sw; if (y + h > st->box.h) h = st->box.h - y; /* Transfer band must be aligned to pixel block boundaries */ assert(y % blockheight == 0); assert(h % blockheight == 0); offset = y * st->base.stride / blockheight; length = h * st->base.stride / blockheight; sw = (uint8_t *) st->swbuf + offset; if (transfer == SVGA3D_WRITE_HOST_VRAM) { unsigned usage = PIPE_TRANSFER_WRITE; /* Wait for the previous DMAs to complete */ /* TODO: keep one DMA (at half the size) in the background */ if (y) { svga_context_flush(svga, NULL); usage |= PIPE_TRANSFER_DISCARD_WHOLE_RESOURCE; } hw = sws->buffer_map(sws, st->hwbuf, usage); assert(hw); if (hw) { memcpy(hw, sw, length); sws->buffer_unmap(sws, st->hwbuf); } } svga_transfer_dma_band(svga, st, transfer, st->box.x, y, st->box.z, st->box.w, h, st->box.d, 0, srcy, 0, flags); /* * Prevent the texture contents to be discarded on the next band * upload. */ flags.discard = FALSE; if (transfer == SVGA3D_READ_HOST_VRAM) { svga_context_flush(svga, &fence); sws->fence_finish(sws, fence, PIPE_TIMEOUT_INFINITE, 0); hw = sws->buffer_map(sws, st->hwbuf, PIPE_TRANSFER_READ); assert(hw); if (hw) { memcpy(sw, hw, length); sws->buffer_unmap(sws, st->hwbuf); } } } } } static boolean svga_texture_get_handle(struct pipe_screen *screen, struct pipe_resource *texture, struct winsys_handle *whandle) { struct svga_winsys_screen *sws = svga_winsys_screen(texture->screen); unsigned stride; assert(svga_texture(texture)->key.cachable == 0); svga_texture(texture)->key.cachable = 0; stride = util_format_get_nblocksx(texture->format, texture->width0) * util_format_get_blocksize(texture->format); return sws->surface_get_handle(sws, svga_texture(texture)->handle, stride, whandle); } static void svga_texture_destroy(struct pipe_screen *screen, struct pipe_resource *pt) { struct svga_screen *ss = svga_screen(screen); struct svga_texture *tex = svga_texture(pt); ss->texture_timestamp++; svga_sampler_view_reference(&tex->cached_view, NULL); /* DBG("%s deleting %p\n", __FUNCTION__, (void *) tex); */ SVGA_DBG(DEBUG_DMA, "unref sid %p (texture)\n", tex->handle); svga_screen_surface_destroy(ss, &tex->key, &tex->handle); /* Destroy the backed surface handle if exists */ if (tex->backed_handle) svga_screen_surface_destroy(ss, &tex->backed_key, &tex->backed_handle); ss->hud.total_resource_bytes -= tex->size; FREE(tex->defined); FREE(tex->rendered_to); FREE(tex->dirty); FREE(tex); assert(ss->hud.num_resources > 0); if (ss->hud.num_resources > 0) ss->hud.num_resources--; } /** * Determine if we need to read back a texture image before mapping it. */ static inline boolean need_tex_readback(struct svga_transfer *st) { if (st->base.usage & PIPE_TRANSFER_READ) return TRUE; if ((st->base.usage & PIPE_TRANSFER_WRITE) && ((st->base.usage & PIPE_TRANSFER_DISCARD_WHOLE_RESOURCE) == 0)) { return svga_was_texture_rendered_to(svga_texture(st->base.resource), st->slice, st->base.level); } return FALSE; } static enum pipe_error readback_image_vgpu9(struct svga_context *svga, struct svga_winsys_surface *surf, unsigned slice, unsigned level) { enum pipe_error ret; ret = SVGA3D_ReadbackGBImage(svga->swc, surf, slice, level); if (ret != PIPE_OK) { svga_context_flush(svga, NULL); ret = SVGA3D_ReadbackGBImage(svga->swc, surf, slice, level); } return ret; } static enum pipe_error readback_image_vgpu10(struct svga_context *svga, struct svga_winsys_surface *surf, unsigned slice, unsigned level, unsigned numMipLevels) { enum pipe_error ret; unsigned subResource; subResource = slice * numMipLevels + level; ret = SVGA3D_vgpu10_ReadbackSubResource(svga->swc, surf, subResource); if (ret != PIPE_OK) { svga_context_flush(svga, NULL); ret = SVGA3D_vgpu10_ReadbackSubResource(svga->swc, surf, subResource); } return ret; } /** * Use DMA for the transfer request */ static void * svga_texture_transfer_map_dma(struct svga_context *svga, struct svga_transfer *st) { struct svga_winsys_screen *sws = svga_screen(svga->pipe.screen)->sws; struct pipe_resource *texture = st->base.resource; unsigned nblocksx, nblocksy; unsigned d; unsigned usage = st->base.usage; /* we'll put the data into a tightly packed buffer */ nblocksx = util_format_get_nblocksx(texture->format, st->box.w); nblocksy = util_format_get_nblocksy(texture->format, st->box.h); d = st->box.d; st->base.stride = nblocksx*util_format_get_blocksize(texture->format); st->base.layer_stride = st->base.stride * nblocksy; st->hw_nblocksy = nblocksy; st->hwbuf = svga_winsys_buffer_create(svga, 1, 0, st->hw_nblocksy * st->base.stride * d); while (!st->hwbuf && (st->hw_nblocksy /= 2)) { st->hwbuf = svga_winsys_buffer_create(svga, 1, 0, st->hw_nblocksy * st->base.stride * d); } if (!st->hwbuf) return NULL; if (st->hw_nblocksy < nblocksy) { /* We couldn't allocate a hardware buffer big enough for the transfer, * so allocate regular malloc memory instead */ if (0) { debug_printf("%s: failed to allocate %u KB of DMA, " "splitting into %u x %u KB DMA transfers\n", __FUNCTION__, (nblocksy * st->base.stride + 1023) / 1024, (nblocksy + st->hw_nblocksy - 1) / st->hw_nblocksy, (st->hw_nblocksy * st->base.stride + 1023) / 1024); } st->swbuf = MALLOC(nblocksy * st->base.stride * d); if (!st->swbuf) { sws->buffer_destroy(sws, st->hwbuf); return NULL; } } if (usage & PIPE_TRANSFER_READ) { SVGA3dSurfaceDMAFlags flags; memset(&flags, 0, sizeof flags); svga_transfer_dma(svga, st, SVGA3D_READ_HOST_VRAM, flags); } if (st->swbuf) { return st->swbuf; } else { return sws->buffer_map(sws, st->hwbuf, usage); } } /** * Use direct map for the transfer request */ static void * svga_texture_transfer_map_direct(struct svga_context *svga, struct svga_transfer *st) { struct svga_winsys_screen *sws = svga_screen(svga->pipe.screen)->sws; struct pipe_transfer *transfer = &st->base; struct pipe_resource *texture = transfer->resource; struct svga_texture *tex = svga_texture(texture); struct svga_winsys_surface *surf = tex->handle; unsigned level = st->base.level; unsigned w, h, nblocksx, nblocksy, i; unsigned usage = st->base.usage; if (need_tex_readback(st)) { enum pipe_error ret; svga_surfaces_flush(svga); for (i = 0; i < st->box.d; i++) { if (svga_have_vgpu10(svga)) { ret = readback_image_vgpu10(svga, surf, st->slice + i, level, tex->b.b.last_level + 1); } else { ret = readback_image_vgpu9(svga, surf, st->slice + i, level); } } svga->hud.num_readbacks++; SVGA_STATS_COUNT_INC(sws, SVGA_STATS_COUNT_TEXREADBACK); assert(ret == PIPE_OK); (void) ret; svga_context_flush(svga, NULL); /* * Note: if PIPE_TRANSFER_DISCARD_WHOLE_RESOURCE were specified * we could potentially clear the flag for all faces/layers/mips. */ svga_clear_texture_rendered_to(tex, st->slice, level); } else { assert(usage & PIPE_TRANSFER_WRITE); if ((usage & PIPE_TRANSFER_UNSYNCHRONIZED) == 0) { if (svga_is_texture_dirty(tex, st->slice, level)) { /* * do a surface flush if the subresource has been modified * in this command buffer. */ svga_surfaces_flush(svga); if (!sws->surface_is_flushed(sws, surf)) { svga->hud.surface_write_flushes++; SVGA_STATS_COUNT_INC(sws, SVGA_STATS_COUNT_SURFACEWRITEFLUSH); svga_context_flush(svga, NULL); } } } } /* we'll directly access the guest-backed surface */ w = u_minify(texture->width0, level); h = u_minify(texture->height0, level); nblocksx = util_format_get_nblocksx(texture->format, w); nblocksy = util_format_get_nblocksy(texture->format, h); st->hw_nblocksy = nblocksy; st->base.stride = nblocksx*util_format_get_blocksize(texture->format); st->base.layer_stride = st->base.stride * nblocksy; /* * Begin mapping code */ { SVGA3dSize baseLevelSize; uint8_t *map; boolean retry; unsigned offset, mip_width, mip_height; map = svga->swc->surface_map(svga->swc, surf, usage, &retry); if (map == NULL && retry) { /* * At this point, the svga_surfaces_flush() should already have * called in svga_texture_get_transfer(). */ svga->hud.surface_write_flushes++; svga_context_flush(svga, NULL); map = svga->swc->surface_map(svga->swc, surf, usage, &retry); } /* * Make sure we return NULL if the map fails */ if (!map) { return NULL; } /** * Compute the offset to the specific texture slice in the buffer. */ baseLevelSize.width = tex->b.b.width0; baseLevelSize.height = tex->b.b.height0; baseLevelSize.depth = tex->b.b.depth0; if ((tex->b.b.target == PIPE_TEXTURE_1D_ARRAY) || (tex->b.b.target == PIPE_TEXTURE_2D_ARRAY) || (tex->b.b.target == PIPE_TEXTURE_CUBE_ARRAY)) { st->base.layer_stride = svga3dsurface_get_image_offset(tex->key.format, baseLevelSize, tex->b.b.last_level + 1, 1, 0); } offset = svga3dsurface_get_image_offset(tex->key.format, baseLevelSize, tex->b.b.last_level + 1, /* numMips */ st->slice, level); if (level > 0) { assert(offset > 0); } mip_width = u_minify(tex->b.b.width0, level); mip_height = u_minify(tex->b.b.height0, level); offset += svga3dsurface_get_pixel_offset(tex->key.format, mip_width, mip_height, st->box.x, st->box.y, st->box.z); return (void *) (map + offset); } } /** * Request a transfer map to the texture resource */ static void * svga_texture_transfer_map(struct pipe_context *pipe, struct pipe_resource *texture, unsigned level, unsigned usage, const struct pipe_box *box, struct pipe_transfer **ptransfer) { struct svga_context *svga = svga_context(pipe); struct svga_winsys_screen *sws = svga_screen(pipe->screen)->sws; struct svga_texture *tex = svga_texture(texture); struct svga_transfer *st; struct svga_winsys_surface *surf = tex->handle; boolean use_direct_map = svga_have_gb_objects(svga) && !svga_have_gb_dma(svga); void *map = NULL; int64_t begin = svga_get_time(svga); SVGA_STATS_TIME_PUSH(sws, SVGA_STATS_TIME_TEXTRANSFERMAP); if (!surf) goto done; /* We can't map texture storage directly unless we have GB objects */ if (usage & PIPE_TRANSFER_MAP_DIRECTLY) { if (svga_have_gb_objects(svga)) use_direct_map = TRUE; else goto done; } st = CALLOC_STRUCT(svga_transfer); if (!st) goto done; st->base.level = level; st->base.usage = usage; st->base.box = *box; /* The modified transfer map box with the array index removed from z. * The array index is specified in slice. */ st->box.x = box->x; st->box.y = box->y; st->box.z = box->z; st->box.w = box->width; st->box.h = box->height; st->box.d = box->depth; switch (tex->b.b.target) { case PIPE_TEXTURE_CUBE: st->slice = st->base.box.z; st->box.z = 0; /* so we don't apply double offsets below */ break; case PIPE_TEXTURE_1D_ARRAY: case PIPE_TEXTURE_2D_ARRAY: case PIPE_TEXTURE_CUBE_ARRAY: st->slice = st->base.box.z; st->box.z = 0; /* so we don't apply double offsets below */ /* Force direct map for transfering multiple slices */ if (st->base.box.depth > 1) use_direct_map = svga_have_gb_objects(svga); break; default: st->slice = 0; break; } /* Force direct map for multisample surface */ if (texture->nr_samples > 1) { assert(svga_have_gb_objects(svga)); assert(sws->have_sm4_1); use_direct_map = TRUE; } st->use_direct_map = use_direct_map; pipe_resource_reference(&st->base.resource, texture); /* If this is the first time mapping to the surface in this * command buffer, clear the dirty masks of this surface. */ if (sws->surface_is_flushed(sws, surf)) { svga_clear_texture_dirty(tex); } if (!use_direct_map) { /* upload to the DMA buffer */ map = svga_texture_transfer_map_dma(svga, st); } else { boolean can_use_upload = tex->can_use_upload && !(st->base.usage & PIPE_TRANSFER_READ); boolean was_rendered_to = svga_was_texture_rendered_to(svga_texture(texture), st->slice, st->base.level); /* If the texture was already rendered to and upload buffer * is supported, then we will use upload buffer to * avoid the need to read back the texture content; otherwise, * we'll first try to map directly to the GB surface, if it is blocked, * then we'll try the upload buffer. */ if (was_rendered_to && can_use_upload) { map = svga_texture_transfer_map_upload(svga, st); } else { unsigned orig_usage = st->base.usage; /* First try directly map to the GB surface */ if (can_use_upload) st->base.usage |= PIPE_TRANSFER_DONTBLOCK; map = svga_texture_transfer_map_direct(svga, st); st->base.usage = orig_usage; if (!map && can_use_upload) { /* if direct map with DONTBLOCK fails, then try upload to the * texture upload buffer. */ map = svga_texture_transfer_map_upload(svga, st); } } /* If upload fails, then try direct map again without forcing it * to DONTBLOCK. */ if (!map) { map = svga_texture_transfer_map_direct(svga, st); } } if (!map) { FREE(st); } else { *ptransfer = &st->base; svga->hud.num_textures_mapped++; if (usage & PIPE_TRANSFER_WRITE) { /* record texture upload for HUD */ svga->hud.num_bytes_uploaded += st->base.layer_stride * st->box.d; /* mark this texture level as dirty */ svga_set_texture_dirty(tex, st->slice, level); } } done: svga->hud.map_buffer_time += (svga_get_time(svga) - begin); SVGA_STATS_TIME_POP(sws); (void) sws; return map; } /** * Unmap a GB texture surface. */ static void svga_texture_surface_unmap(struct svga_context *svga, struct pipe_transfer *transfer) { struct svga_winsys_surface *surf = svga_texture(transfer->resource)->handle; struct svga_winsys_context *swc = svga->swc; boolean rebind; assert(surf); swc->surface_unmap(swc, surf, &rebind); if (rebind) { enum pipe_error ret; ret = SVGA3D_BindGBSurface(swc, surf); if (ret != PIPE_OK) { /* flush and retry */ svga_context_flush(svga, NULL); ret = SVGA3D_BindGBSurface(swc, surf); assert(ret == PIPE_OK); } } } static enum pipe_error update_image_vgpu9(struct svga_context *svga, struct svga_winsys_surface *surf, const SVGA3dBox *box, unsigned slice, unsigned level) { enum pipe_error ret; ret = SVGA3D_UpdateGBImage(svga->swc, surf, box, slice, level); if (ret != PIPE_OK) { svga_context_flush(svga, NULL); ret = SVGA3D_UpdateGBImage(svga->swc, surf, box, slice, level); } return ret; } static enum pipe_error update_image_vgpu10(struct svga_context *svga, struct svga_winsys_surface *surf, const SVGA3dBox *box, unsigned slice, unsigned level, unsigned numMipLevels) { enum pipe_error ret; unsigned subResource; subResource = slice * numMipLevels + level; ret = SVGA3D_vgpu10_UpdateSubResource(svga->swc, surf, box, subResource); if (ret != PIPE_OK) { svga_context_flush(svga, NULL); ret = SVGA3D_vgpu10_UpdateSubResource(svga->swc, surf, box, subResource); } return ret; } /** * unmap DMA transfer request */ static void svga_texture_transfer_unmap_dma(struct svga_context *svga, struct svga_transfer *st) { struct svga_winsys_screen *sws = svga_screen(svga->pipe.screen)->sws; if (st->hwbuf) sws->buffer_unmap(sws, st->hwbuf); if (st->base.usage & PIPE_TRANSFER_WRITE) { /* Use DMA to transfer texture data */ SVGA3dSurfaceDMAFlags flags; memset(&flags, 0, sizeof flags); if (st->base.usage & PIPE_TRANSFER_DISCARD_WHOLE_RESOURCE) { flags.discard = TRUE; } if (st->base.usage & PIPE_TRANSFER_UNSYNCHRONIZED) { flags.unsynchronized = TRUE; } svga_transfer_dma(svga, st, SVGA3D_WRITE_HOST_VRAM, flags); } FREE(st->swbuf); sws->buffer_destroy(sws, st->hwbuf); } /** * unmap direct map transfer request */ static void svga_texture_transfer_unmap_direct(struct svga_context *svga, struct svga_transfer *st) { struct pipe_transfer *transfer = &st->base; struct svga_texture *tex = svga_texture(transfer->resource); svga_texture_surface_unmap(svga, transfer); /* Now send an update command to update the content in the backend. */ if (st->base.usage & PIPE_TRANSFER_WRITE) { struct svga_winsys_surface *surf = tex->handle; enum pipe_error ret; assert(svga_have_gb_objects(svga)); /* update the effected region */ SVGA3dBox box = st->box; unsigned nlayers; switch (tex->b.b.target) { case PIPE_TEXTURE_2D_ARRAY: case PIPE_TEXTURE_CUBE_ARRAY: case PIPE_TEXTURE_1D_ARRAY: nlayers = box.d; box.d = 1; break; default: nlayers = 1; break; } if (0) debug_printf("%s %d, %d, %d %d x %d x %d\n", __FUNCTION__, box.x, box.y, box.z, box.w, box.h, box.d); if (svga_have_vgpu10(svga)) { unsigned i; for (i = 0; i < nlayers; i++) { ret = update_image_vgpu10(svga, surf, &box, st->slice + i, transfer->level, tex->b.b.last_level + 1); assert(ret == PIPE_OK); } } else { assert(nlayers == 1); ret = update_image_vgpu9(svga, surf, &box, st->slice, transfer->level); assert(ret == PIPE_OK); } (void) ret; } } static void svga_texture_transfer_unmap(struct pipe_context *pipe, struct pipe_transfer *transfer) { struct svga_context *svga = svga_context(pipe); struct svga_screen *ss = svga_screen(pipe->screen); struct svga_winsys_screen *sws = ss->sws; struct svga_transfer *st = svga_transfer(transfer); struct svga_texture *tex = svga_texture(transfer->resource); SVGA_STATS_TIME_PUSH(sws, SVGA_STATS_TIME_TEXTRANSFERUNMAP); if (!st->use_direct_map) { svga_texture_transfer_unmap_dma(svga, st); } else if (st->upload.buf) { svga_texture_transfer_unmap_upload(svga, st); } else { svga_texture_transfer_unmap_direct(svga, st); } if (st->base.usage & PIPE_TRANSFER_WRITE) { svga->hud.num_resource_updates++; /* Mark the texture level as dirty */ ss->texture_timestamp++; svga_age_texture_view(tex, transfer->level); if (transfer->resource->target == PIPE_TEXTURE_CUBE) svga_define_texture_level(tex, st->slice, transfer->level); else svga_define_texture_level(tex, 0, transfer->level); } pipe_resource_reference(&st->base.resource, NULL); FREE(st); SVGA_STATS_TIME_POP(sws); (void) sws; } /** * Does format store depth values? */ static inline boolean format_has_depth(enum pipe_format format) { const struct util_format_description *desc = util_format_description(format); return util_format_has_depth(desc); } struct u_resource_vtbl svga_texture_vtbl = { svga_texture_get_handle, /* get_handle */ svga_texture_destroy, /* resource_destroy */ svga_texture_transfer_map, /* transfer_map */ u_default_transfer_flush_region, /* transfer_flush_region */ svga_texture_transfer_unmap, /* transfer_unmap */ }; struct pipe_resource * svga_texture_create(struct pipe_screen *screen, const struct pipe_resource *template) { struct svga_screen *svgascreen = svga_screen(screen); struct svga_texture *tex; unsigned bindings = template->bind; SVGA_STATS_TIME_PUSH(svgascreen->sws, SVGA_STATS_TIME_CREATETEXTURE); assert(template->last_level < SVGA_MAX_TEXTURE_LEVELS); if (template->last_level >= SVGA_MAX_TEXTURE_LEVELS) { goto fail_notex; } /* Verify the number of mipmap levels isn't impossibly large. For example, * if the base 2D image is 16x16, we can't have 8 mipmap levels. * The state tracker should never ask us to create a resource with invalid * parameters. */ { unsigned max_dim = template->width0; switch (template->target) { case PIPE_TEXTURE_1D: case PIPE_TEXTURE_1D_ARRAY: // nothing break; case PIPE_TEXTURE_2D: case PIPE_TEXTURE_CUBE: case PIPE_TEXTURE_CUBE_ARRAY: case PIPE_TEXTURE_2D_ARRAY: max_dim = MAX2(max_dim, template->height0); break; case PIPE_TEXTURE_3D: max_dim = MAX3(max_dim, template->height0, template->depth0); break; case PIPE_TEXTURE_RECT: case PIPE_BUFFER: assert(template->last_level == 0); /* the assertion below should always pass */ break; default: debug_printf("Unexpected texture target type\n"); } assert(1 << template->last_level <= max_dim); } tex = CALLOC_STRUCT(svga_texture); if (!tex) { goto fail_notex; } tex->defined = CALLOC(template->depth0 * template->array_size, sizeof(tex->defined[0])); if (!tex->defined) { FREE(tex); goto fail_notex; } tex->rendered_to = CALLOC(template->depth0 * template->array_size, sizeof(tex->rendered_to[0])); if (!tex->rendered_to) { goto fail; } tex->dirty = CALLOC(template->depth0 * template->array_size, sizeof(tex->dirty[0])); if (!tex->dirty) { goto fail; } tex->b.b = *template; tex->b.vtbl = &svga_texture_vtbl; pipe_reference_init(&tex->b.b.reference, 1); tex->b.b.screen = screen; tex->key.flags = 0; tex->key.size.width = template->width0; tex->key.size.height = template->height0; tex->key.size.depth = template->depth0; tex->key.arraySize = 1; tex->key.numFaces = 1; /* nr_samples=1 must be treated as a non-multisample texture */ if (tex->b.b.nr_samples == 1) { tex->b.b.nr_samples = 0; } else if (tex->b.b.nr_samples > 1) { assert(svgascreen->sws->have_sm4_1); tex->key.flags |= SVGA3D_SURFACE_MULTISAMPLE; } tex->key.sampleCount = tex->b.b.nr_samples; if (svgascreen->sws->have_vgpu10) { switch (template->target) { case PIPE_TEXTURE_1D: tex->key.flags |= SVGA3D_SURFACE_1D; break; case PIPE_TEXTURE_1D_ARRAY: tex->key.flags |= SVGA3D_SURFACE_1D; /* fall-through */ case PIPE_TEXTURE_2D_ARRAY: tex->key.flags |= SVGA3D_SURFACE_ARRAY; tex->key.arraySize = template->array_size; break; case PIPE_TEXTURE_3D: tex->key.flags |= SVGA3D_SURFACE_VOLUME; break; case PIPE_TEXTURE_CUBE: tex->key.flags |= (SVGA3D_SURFACE_CUBEMAP | SVGA3D_SURFACE_ARRAY); tex->key.numFaces = 6; break; case PIPE_TEXTURE_CUBE_ARRAY: assert(svgascreen->sws->have_sm4_1); tex->key.flags |= (SVGA3D_SURFACE_CUBEMAP | SVGA3D_SURFACE_ARRAY); tex->key.numFaces = 1; // arraySize already includes the 6 faces tex->key.arraySize = template->array_size; break; default: break; } } else { switch (template->target) { case PIPE_TEXTURE_3D: tex->key.flags |= SVGA3D_SURFACE_VOLUME; break; case PIPE_TEXTURE_CUBE: tex->key.flags |= SVGA3D_SURFACE_CUBEMAP; tex->key.numFaces = 6; break; default: break; } } tex->key.cachable = 1; if ((bindings & (PIPE_BIND_RENDER_TARGET | PIPE_BIND_DEPTH_STENCIL)) && !(bindings & PIPE_BIND_SAMPLER_VIEW)) { /* Also check if the format can be sampled from */ if (screen->is_format_supported(screen, template->format, template->target, template->nr_samples, template->nr_storage_samples, PIPE_BIND_SAMPLER_VIEW)) { bindings |= PIPE_BIND_SAMPLER_VIEW; } } if (bindings & PIPE_BIND_SAMPLER_VIEW) { tex->key.flags |= SVGA3D_SURFACE_HINT_TEXTURE; tex->key.flags |= SVGA3D_SURFACE_BIND_SHADER_RESOURCE; if (!(bindings & PIPE_BIND_RENDER_TARGET)) { /* Also check if the format is color renderable */ if (screen->is_format_supported(screen, template->format, template->target, template->nr_samples, template->nr_storage_samples, PIPE_BIND_RENDER_TARGET)) { bindings |= PIPE_BIND_RENDER_TARGET; } } if (!(bindings & PIPE_BIND_DEPTH_STENCIL)) { /* Also check if the format is depth/stencil renderable */ if (screen->is_format_supported(screen, template->format, template->target, template->nr_samples, template->nr_storage_samples, PIPE_BIND_DEPTH_STENCIL)) { bindings |= PIPE_BIND_DEPTH_STENCIL; } } } if (bindings & PIPE_BIND_DISPLAY_TARGET) { tex->key.cachable = 0; } if (bindings & PIPE_BIND_SHARED) { tex->key.cachable = 0; } if (bindings & (PIPE_BIND_SCANOUT | PIPE_BIND_CURSOR)) { tex->key.scanout = 1; tex->key.cachable = 0; } /* * Note: Previously we never passed the * SVGA3D_SURFACE_HINT_RENDERTARGET hint. Mesa cannot * know beforehand whether a texture will be used as a rendertarget or not * and it always requests PIPE_BIND_RENDER_TARGET, therefore * passing the SVGA3D_SURFACE_HINT_RENDERTARGET here defeats its purpose. * * However, this was changed since other state trackers * (XA for example) uses it accurately and certain device versions * relies on it in certain situations to render correctly. */ if ((bindings & PIPE_BIND_RENDER_TARGET) && !util_format_is_s3tc(template->format)) { tex->key.flags |= SVGA3D_SURFACE_HINT_RENDERTARGET; tex->key.flags |= SVGA3D_SURFACE_BIND_RENDER_TARGET; } if (bindings & PIPE_BIND_DEPTH_STENCIL) { tex->key.flags |= SVGA3D_SURFACE_HINT_DEPTHSTENCIL; tex->key.flags |= SVGA3D_SURFACE_BIND_DEPTH_STENCIL; } tex->key.numMipLevels = template->last_level + 1; tex->key.format = svga_translate_format(svgascreen, template->format, bindings); if (tex->key.format == SVGA3D_FORMAT_INVALID) { goto fail; } /* Use typeless formats for sRGB and depth resources. Typeless * formats can be reinterpreted as other formats. For example, * SVGA3D_R8G8B8A8_UNORM_TYPELESS can be interpreted as * SVGA3D_R8G8B8A8_UNORM_SRGB or SVGA3D_R8G8B8A8_UNORM. */ if (svgascreen->sws->have_vgpu10 && (util_format_is_srgb(template->format) || format_has_depth(template->format))) { SVGA3dSurfaceFormat typeless = svga_typeless_format(tex->key.format); if (0) { debug_printf("Convert resource type %s -> %s (bind 0x%x)\n", svga_format_name(tex->key.format), svga_format_name(typeless), bindings); } if (svga_format_is_uncompressed_snorm(tex->key.format)) { /* We can't normally render to snorm surfaces, but once we * substitute a typeless format, we can if the rendertarget view * is unorm. This can happen with GL_ARB_copy_image. */ tex->key.flags |= SVGA3D_SURFACE_HINT_RENDERTARGET; tex->key.flags |= SVGA3D_SURFACE_BIND_RENDER_TARGET; } tex->key.format = typeless; } SVGA_DBG(DEBUG_DMA, "surface_create for texture\n", tex->handle); tex->handle = svga_screen_surface_create(svgascreen, bindings, tex->b.b.usage, &tex->validated, &tex->key); if (!tex->handle) { goto fail; } SVGA_DBG(DEBUG_DMA, " --> got sid %p (texture)\n", tex->handle); debug_reference(&tex->b.b.reference, (debug_reference_descriptor)debug_describe_resource, 0); tex->size = util_resource_size(template); /* Determine if texture upload buffer can be used to upload this texture */ tex->can_use_upload = svga_texture_transfer_map_can_upload(svgascreen, &tex->b.b); /* Initialize the backing resource cache */ tex->backed_handle = NULL; svgascreen->hud.total_resource_bytes += tex->size; svgascreen->hud.num_resources++; SVGA_STATS_TIME_POP(svgascreen->sws); return &tex->b.b; fail: if (tex->dirty) FREE(tex->dirty); if (tex->rendered_to) FREE(tex->rendered_to); if (tex->defined) FREE(tex->defined); FREE(tex); fail_notex: SVGA_STATS_TIME_POP(svgascreen->sws); return NULL; } struct pipe_resource * svga_texture_from_handle(struct pipe_screen *screen, const struct pipe_resource *template, struct winsys_handle *whandle) { struct svga_winsys_screen *sws = svga_winsys_screen(screen); struct svga_screen *ss = svga_screen(screen); struct svga_winsys_surface *srf; struct svga_texture *tex; enum SVGA3dSurfaceFormat format = 0; assert(screen); /* Only supports one type */ if ((template->target != PIPE_TEXTURE_2D && template->target != PIPE_TEXTURE_RECT) || template->last_level != 0 || template->depth0 != 1) { return NULL; } srf = sws->surface_from_handle(sws, whandle, &format); if (!srf) return NULL; if (!svga_format_is_shareable(ss, template->format, format, template->bind, true)) goto out_unref; tex = CALLOC_STRUCT(svga_texture); if (!tex) goto out_unref; tex->defined = CALLOC(template->depth0 * template->array_size, sizeof(tex->defined[0])); if (!tex->defined) goto out_no_defined; tex->b.b = *template; tex->b.vtbl = &svga_texture_vtbl; pipe_reference_init(&tex->b.b.reference, 1); tex->b.b.screen = screen; SVGA_DBG(DEBUG_DMA, "wrap surface sid %p\n", srf); tex->key.cachable = 0; tex->key.format = format; tex->handle = srf; tex->rendered_to = CALLOC(1, sizeof(tex->rendered_to[0])); if (!tex->rendered_to) goto out_no_rendered_to; tex->dirty = CALLOC(1, sizeof(tex->dirty[0])); if (!tex->dirty) goto out_no_dirty; tex->imported = TRUE; ss->hud.num_resources++; return &tex->b.b; out_no_dirty: FREE(tex->rendered_to); out_no_rendered_to: FREE(tex->defined); out_no_defined: FREE(tex); out_unref: sws->surface_reference(sws, &srf, NULL); return NULL; } boolean svga_texture_generate_mipmap(struct pipe_context *pipe, struct pipe_resource *pt, enum pipe_format format, unsigned base_level, unsigned last_level, unsigned first_layer, unsigned last_layer) { struct pipe_sampler_view templ, *psv; struct svga_pipe_sampler_view *sv; struct svga_context *svga = svga_context(pipe); struct svga_texture *tex = svga_texture(pt); enum pipe_error ret; assert(svga_have_vgpu10(svga)); /* Only support 2D texture for now */ if (pt->target != PIPE_TEXTURE_2D) return FALSE; /* Fallback to the mipmap generation utility for those formats that * do not support hw generate mipmap */ if (!svga_format_support_gen_mips(format)) return FALSE; /* Make sure the texture surface was created with * SVGA3D_SURFACE_BIND_RENDER_TARGET */ if (!tex->handle || !(tex->key.flags & SVGA3D_SURFACE_BIND_RENDER_TARGET)) return FALSE; templ.format = format; templ.u.tex.first_layer = first_layer; templ.u.tex.last_layer = last_layer; templ.u.tex.first_level = base_level; templ.u.tex.last_level = last_level; psv = pipe->create_sampler_view(pipe, pt, &templ); if (psv == NULL) return FALSE; sv = svga_pipe_sampler_view(psv); ret = svga_validate_pipe_sampler_view(svga, sv); if (ret != PIPE_OK) { svga_context_flush(svga, NULL); ret = svga_validate_pipe_sampler_view(svga, sv); assert(ret == PIPE_OK); } ret = SVGA3D_vgpu10_GenMips(svga->swc, sv->id, tex->handle); if (ret != PIPE_OK) { svga_context_flush(svga, NULL); ret = SVGA3D_vgpu10_GenMips(svga->swc, sv->id, tex->handle); } pipe_sampler_view_reference(&psv, NULL); svga->hud.num_generate_mipmap++; return TRUE; } /* texture upload buffer default size in bytes */ #define TEX_UPLOAD_DEFAULT_SIZE (1024 * 1024) /** * Create a texture upload buffer */ boolean svga_texture_transfer_map_upload_create(struct svga_context *svga) { svga->tex_upload = u_upload_create(&svga->pipe, TEX_UPLOAD_DEFAULT_SIZE, 0, PIPE_USAGE_STAGING, 0); return svga->tex_upload != NULL; } /** * Destroy the texture upload buffer */ void svga_texture_transfer_map_upload_destroy(struct svga_context *svga) { u_upload_destroy(svga->tex_upload); } /** * Returns true if this transfer map request can use the upload buffer. */ boolean svga_texture_transfer_map_can_upload(const struct svga_screen *svgascreen, const struct pipe_resource *texture) { if (svgascreen->sws->have_transfer_from_buffer_cmd == FALSE) return FALSE; /* TransferFromBuffer command is not well supported with multi-samples surface */ if (texture->nr_samples > 1) return FALSE; if (util_format_is_compressed(texture->format)) { /* XXX Need to take a closer look to see why texture upload * with 3D texture with compressed format fails */ if (texture->target == PIPE_TEXTURE_3D) return FALSE; } else if (texture->format == PIPE_FORMAT_R9G9B9E5_FLOAT) { return FALSE; } return TRUE; } /** * Use upload buffer for the transfer map request. */ void * svga_texture_transfer_map_upload(struct svga_context *svga, struct svga_transfer *st) { struct pipe_resource *texture = st->base.resource; struct pipe_resource *tex_buffer = NULL; void *tex_map; unsigned nblocksx, nblocksy; unsigned offset; unsigned upload_size; assert(svga->tex_upload); st->upload.box.x = st->base.box.x; st->upload.box.y = st->base.box.y; st->upload.box.z = st->base.box.z; st->upload.box.w = st->base.box.width; st->upload.box.h = st->base.box.height; st->upload.box.d = st->base.box.depth; st->upload.nlayers = 1; switch (texture->target) { case PIPE_TEXTURE_CUBE: st->upload.box.z = 0; break; case PIPE_TEXTURE_2D_ARRAY: case PIPE_TEXTURE_CUBE_ARRAY: st->upload.nlayers = st->base.box.depth; st->upload.box.z = 0; st->upload.box.d = 1; break; case PIPE_TEXTURE_1D_ARRAY: st->upload.nlayers = st->base.box.depth; st->upload.box.y = st->upload.box.z = 0; st->upload.box.d = 1; break; default: break; } nblocksx = util_format_get_nblocksx(texture->format, st->base.box.width); nblocksy = util_format_get_nblocksy(texture->format, st->base.box.height); st->base.stride = nblocksx * util_format_get_blocksize(texture->format); st->base.layer_stride = st->base.stride * nblocksy; /* In order to use the TransferFromBuffer command to update the * texture content from the buffer, the layer stride for a multi-layers * surface needs to be in multiples of 16 bytes. */ if (st->upload.nlayers > 1 && st->base.layer_stride & 15) return NULL; upload_size = st->base.layer_stride * st->base.box.depth; upload_size = align(upload_size, 16); #ifdef DEBUG if (util_format_is_compressed(texture->format)) { struct svga_texture *tex = svga_texture(texture); unsigned blockw, blockh, bytesPerBlock; svga_format_size(tex->key.format, &blockw, &blockh, &bytesPerBlock); /* dest box must start on block boundary */ assert((st->base.box.x % blockw) == 0); assert((st->base.box.y % blockh) == 0); } #endif /* If the upload size exceeds the default buffer size, the * upload buffer manager code will try to allocate a new buffer * with the new buffer size. */ u_upload_alloc(svga->tex_upload, 0, upload_size, 16, &offset, &tex_buffer, &tex_map); if (!tex_map) { return NULL; } st->upload.buf = tex_buffer; st->upload.map = tex_map; st->upload.offset = offset; return tex_map; } /** * Unmap upload map transfer request */ void svga_texture_transfer_unmap_upload(struct svga_context *svga, struct svga_transfer *st) { struct svga_winsys_surface *srcsurf; struct svga_winsys_surface *dstsurf; struct pipe_resource *texture = st->base.resource; struct svga_texture *tex = svga_texture(texture); enum pipe_error ret; unsigned subResource; unsigned numMipLevels; unsigned i, layer; unsigned offset = st->upload.offset; assert(svga->tex_upload); assert(st->upload.buf); /* unmap the texture upload buffer */ u_upload_unmap(svga->tex_upload); srcsurf = svga_buffer_handle(svga, st->upload.buf, 0); dstsurf = svga_texture(texture)->handle; assert(dstsurf); numMipLevels = texture->last_level + 1; for (i = 0, layer = st->slice; i < st->upload.nlayers; i++, layer++) { subResource = layer * numMipLevels + st->base.level; /* send a transferFromBuffer command to update the host texture surface */ assert((offset & 15) == 0); ret = SVGA3D_vgpu10_TransferFromBuffer(svga->swc, srcsurf, offset, st->base.stride, st->base.layer_stride, dstsurf, subResource, &st->upload.box); if (ret != PIPE_OK) { svga_context_flush(svga, NULL); ret = SVGA3D_vgpu10_TransferFromBuffer(svga->swc, srcsurf, offset, st->base.stride, st->base.layer_stride, dstsurf, subResource, &st->upload.box); assert(ret == PIPE_OK); } offset += st->base.layer_stride; /* Set rendered-to flag */ svga_set_texture_rendered_to(tex, layer, st->base.level); } pipe_resource_reference(&st->upload.buf, NULL); } /** * Does the device format backing this surface have an * alpha channel? * * \param texture[in] The texture whose format we're querying * \return TRUE if the format has an alpha channel, FALSE otherwise * * For locally created textures, the device (svga) format is typically * identical to svga_format(texture->format), and we can use the gallium * format tests to determine whether the device format has an alpha channel * or not. However, for textures backed by imported svga surfaces that is * not always true, and we have to look at the SVGA3D utilities. */ boolean svga_texture_device_format_has_alpha(struct pipe_resource *texture) { /* the svga_texture() call below is invalid for PIPE_BUFFER resources */ assert(texture->target != PIPE_BUFFER); enum svga3d_block_desc block_desc = svga3dsurface_get_desc(svga_texture(texture)->key.format)->block_desc; return !!(block_desc & SVGA3DBLOCKDESC_ALPHA); }