/************************************************************************** * * Copyright 2011 Marek Olšák * 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, sub license, 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 NON-INFRINGEMENT. * IN NO EVENT SHALL AUTHORS AND/OR ITS SUPPLIERS 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. * **************************************************************************/ /** * This module uploads user buffers and translates the vertex buffers which * contain incompatible vertices (i.e. not supported by the driver/hardware) * into compatible ones, based on the Gallium CAPs. * * It does not upload index buffers. * * The module heavily uses bitmasks to represent per-buffer and * per-vertex-element flags to avoid looping over the list of buffers just * to see if there's a non-zero stride, or user buffer, or unsupported format, * etc. * * There are 3 categories of vertex elements, which are processed separately: * - per-vertex attribs (stride != 0, instance_divisor == 0) * - instanced attribs (stride != 0, instance_divisor > 0) * - constant attribs (stride == 0) * * All needed uploads and translations are performed every draw command, but * only the subset of vertices needed for that draw command is uploaded or * translated. (the module never translates whole buffers) * * * The module consists of two main parts: * * * 1) Translate (u_vbuf_translate_begin/end) * * This is pretty much a vertex fetch fallback. It translates vertices from * one vertex buffer to another in an unused vertex buffer slot. It does * whatever is needed to make the vertices readable by the hardware (changes * vertex formats and aligns offsets and strides). The translate module is * used here. * * Each of the 3 categories is translated to a separate buffer. * Only the [min_index, max_index] range is translated. For instanced attribs, * the range is [start_instance, start_instance+instance_count]. For constant * attribs, the range is [0, 1]. * * * 2) User buffer uploading (u_vbuf_upload_buffers) * * Only the [min_index, max_index] range is uploaded (just like Translate) * with a single memcpy. * * This method works best for non-indexed draw operations or indexed draw * operations where the [min_index, max_index] range is not being way bigger * than the vertex count. * * If the range is too big (e.g. one triangle with indices {0, 1, 10000}), * the per-vertex attribs are uploaded via the translate module, all packed * into one vertex buffer, and the indexed draw call is turned into * a non-indexed one in the process. This adds additional complexity * to the translate part, but it prevents bad apps from bringing your frame * rate down. * * * If there is nothing to do, it forwards every command to the driver. * The module also has its own CSO cache of vertex element states. */ #include "util/u_vbuf.h" #include "util/u_dump.h" #include "util/u_format.h" #include "util/u_inlines.h" #include "util/u_memory.h" #include "util/u_upload_mgr.h" #include "translate/translate.h" #include "translate/translate_cache.h" #include "cso_cache/cso_cache.h" #include "cso_cache/cso_hash.h" struct u_vbuf_elements { unsigned count; struct pipe_vertex_element ve[PIPE_MAX_ATTRIBS]; unsigned src_format_size[PIPE_MAX_ATTRIBS]; /* If (velem[i].src_format != native_format[i]), the vertex buffer * referenced by the vertex element cannot be used for rendering and * its vertex data must be translated to native_format[i]. */ enum pipe_format native_format[PIPE_MAX_ATTRIBS]; unsigned native_format_size[PIPE_MAX_ATTRIBS]; /* Which buffers are used by the vertex element state. */ uint32_t used_vb_mask; /* This might mean two things: * - src_format != native_format, as discussed above. * - src_offset % 4 != 0 (if the caps don't allow such an offset). */ uint32_t incompatible_elem_mask; /* each bit describes a corresp. attrib */ /* Which buffer has at least one vertex element referencing it * incompatible. */ uint32_t incompatible_vb_mask_any; /* Which buffer has all vertex elements referencing it incompatible. */ uint32_t incompatible_vb_mask_all; /* Which buffer has at least one vertex element referencing it * compatible. */ uint32_t compatible_vb_mask_any; /* Which buffer has all vertex elements referencing it compatible. */ uint32_t compatible_vb_mask_all; /* Which buffer has at least one vertex element referencing it * non-instanced. */ uint32_t noninstance_vb_mask_any; void *driver_cso; }; enum { VB_VERTEX = 0, VB_INSTANCE = 1, VB_CONST = 2, VB_NUM = 3 }; struct u_vbuf { struct u_vbuf_caps caps; struct pipe_context *pipe; struct translate_cache *translate_cache; struct cso_cache *cso_cache; struct u_upload_mgr *uploader; /* This is what was set in set_vertex_buffers. * May contain user buffers. */ struct pipe_vertex_buffer vertex_buffer[PIPE_MAX_ATTRIBS]; uint32_t enabled_vb_mask; /* Saved vertex buffer. */ unsigned aux_vertex_buffer_slot; struct pipe_vertex_buffer aux_vertex_buffer_saved; /* Vertex buffers for the driver. * There are usually no user buffers. */ struct pipe_vertex_buffer real_vertex_buffer[PIPE_MAX_ATTRIBS]; uint32_t dirty_real_vb_mask; /* which buffers are dirty since the last call of set_vertex_buffers */ /* The index buffer. */ struct pipe_index_buffer index_buffer; /* Vertex elements. */ struct u_vbuf_elements *ve, *ve_saved; /* Vertex elements used for the translate fallback. */ struct pipe_vertex_element fallback_velems[PIPE_MAX_ATTRIBS]; /* If non-NULL, this is a vertex element state used for the translate * fallback and therefore used for rendering too. */ boolean using_translate; /* The vertex buffer slot index where translated vertices have been * stored in. */ unsigned fallback_vbs[VB_NUM]; /* Which buffer is a user buffer. */ uint32_t user_vb_mask; /* each bit describes a corresp. buffer */ /* Which buffer is incompatible (unaligned). */ uint32_t incompatible_vb_mask; /* each bit describes a corresp. buffer */ /* Which buffer has a non-zero stride. */ uint32_t nonzero_stride_vb_mask; /* each bit describes a corresp. buffer */ }; static void * u_vbuf_create_vertex_elements(struct u_vbuf *mgr, unsigned count, const struct pipe_vertex_element *attribs); static void u_vbuf_delete_vertex_elements(struct u_vbuf *mgr, void *cso); void u_vbuf_get_caps(struct pipe_screen *screen, struct u_vbuf_caps *caps) { caps->format_fixed32 = screen->is_format_supported(screen, PIPE_FORMAT_R32_FIXED, PIPE_BUFFER, 0, PIPE_BIND_VERTEX_BUFFER); caps->format_float16 = screen->is_format_supported(screen, PIPE_FORMAT_R16_FLOAT, PIPE_BUFFER, 0, PIPE_BIND_VERTEX_BUFFER); caps->format_float64 = screen->is_format_supported(screen, PIPE_FORMAT_R64_FLOAT, PIPE_BUFFER, 0, PIPE_BIND_VERTEX_BUFFER); caps->format_norm32 = screen->is_format_supported(screen, PIPE_FORMAT_R32_UNORM, PIPE_BUFFER, 0, PIPE_BIND_VERTEX_BUFFER) && screen->is_format_supported(screen, PIPE_FORMAT_R32_SNORM, PIPE_BUFFER, 0, PIPE_BIND_VERTEX_BUFFER); caps->format_scaled32 = screen->is_format_supported(screen, PIPE_FORMAT_R32_USCALED, PIPE_BUFFER, 0, PIPE_BIND_VERTEX_BUFFER) && screen->is_format_supported(screen, PIPE_FORMAT_R32_SSCALED, PIPE_BUFFER, 0, PIPE_BIND_VERTEX_BUFFER); caps->buffer_offset_unaligned = !screen->get_param(screen, PIPE_CAP_VERTEX_BUFFER_OFFSET_4BYTE_ALIGNED_ONLY); caps->buffer_stride_unaligned = !screen->get_param(screen, PIPE_CAP_VERTEX_BUFFER_STRIDE_4BYTE_ALIGNED_ONLY); caps->velem_src_offset_unaligned = !screen->get_param(screen, PIPE_CAP_VERTEX_ELEMENT_SRC_OFFSET_4BYTE_ALIGNED_ONLY); caps->user_vertex_buffers = screen->get_param(screen, PIPE_CAP_USER_VERTEX_BUFFERS); } struct u_vbuf * u_vbuf_create(struct pipe_context *pipe, struct u_vbuf_caps *caps, unsigned aux_vertex_buffer_index) { struct u_vbuf *mgr = CALLOC_STRUCT(u_vbuf); mgr->caps = *caps; mgr->aux_vertex_buffer_slot = aux_vertex_buffer_index; mgr->pipe = pipe; mgr->cso_cache = cso_cache_create(); mgr->translate_cache = translate_cache_create(); memset(mgr->fallback_vbs, ~0, sizeof(mgr->fallback_vbs)); mgr->uploader = u_upload_create(pipe, 1024 * 1024, 4, PIPE_BIND_VERTEX_BUFFER); return mgr; } /* u_vbuf uses its own caching for vertex elements, because it needs to keep * its own preprocessed state per vertex element CSO. */ static struct u_vbuf_elements * u_vbuf_set_vertex_elements_internal(struct u_vbuf *mgr, unsigned count, const struct pipe_vertex_element *states) { struct pipe_context *pipe = mgr->pipe; unsigned key_size, hash_key; struct cso_hash_iter iter; struct u_vbuf_elements *ve; struct cso_velems_state velems_state; /* need to include the count into the stored state data too. */ key_size = sizeof(struct pipe_vertex_element) * count + sizeof(unsigned); velems_state.count = count; memcpy(velems_state.velems, states, sizeof(struct pipe_vertex_element) * count); hash_key = cso_construct_key((void*)&velems_state, key_size); iter = cso_find_state_template(mgr->cso_cache, hash_key, CSO_VELEMENTS, (void*)&velems_state, key_size); if (cso_hash_iter_is_null(iter)) { struct cso_velements *cso = MALLOC_STRUCT(cso_velements); memcpy(&cso->state, &velems_state, key_size); cso->data = u_vbuf_create_vertex_elements(mgr, count, states); cso->delete_state = (cso_state_callback)u_vbuf_delete_vertex_elements; cso->context = (void*)mgr; iter = cso_insert_state(mgr->cso_cache, hash_key, CSO_VELEMENTS, cso); ve = cso->data; } else { ve = ((struct cso_velements *)cso_hash_iter_data(iter))->data; } assert(ve); if (ve != mgr->ve) pipe->bind_vertex_elements_state(pipe, ve->driver_cso); return ve; } void u_vbuf_set_vertex_elements(struct u_vbuf *mgr, unsigned count, const struct pipe_vertex_element *states) { mgr->ve = u_vbuf_set_vertex_elements_internal(mgr, count, states); } void u_vbuf_destroy(struct u_vbuf *mgr) { struct pipe_screen *screen = mgr->pipe->screen; unsigned i; unsigned num_vb = screen->get_shader_param(screen, PIPE_SHADER_VERTEX, PIPE_SHADER_CAP_MAX_INPUTS); mgr->pipe->set_index_buffer(mgr->pipe, NULL); pipe_resource_reference(&mgr->index_buffer.buffer, NULL); mgr->pipe->set_vertex_buffers(mgr->pipe, 0, num_vb, NULL); for (i = 0; i < PIPE_MAX_ATTRIBS; i++) { pipe_resource_reference(&mgr->vertex_buffer[i].buffer, NULL); } for (i = 0; i < PIPE_MAX_ATTRIBS; i++) { pipe_resource_reference(&mgr->real_vertex_buffer[i].buffer, NULL); } pipe_resource_reference(&mgr->aux_vertex_buffer_saved.buffer, NULL); translate_cache_destroy(mgr->translate_cache); u_upload_destroy(mgr->uploader); cso_cache_delete(mgr->cso_cache); FREE(mgr); } static enum pipe_error u_vbuf_translate_buffers(struct u_vbuf *mgr, struct translate_key *key, unsigned vb_mask, unsigned out_vb, int start_vertex, unsigned num_vertices, int start_index, unsigned num_indices, int min_index, boolean unroll_indices) { struct translate *tr; struct pipe_transfer *vb_transfer[PIPE_MAX_ATTRIBS] = {0}; struct pipe_resource *out_buffer = NULL; uint8_t *out_map; unsigned out_offset, mask; enum pipe_error err; /* Get a translate object. */ tr = translate_cache_find(mgr->translate_cache, key); /* Map buffers we want to translate. */ mask = vb_mask; while (mask) { struct pipe_vertex_buffer *vb; unsigned offset; uint8_t *map; unsigned i = u_bit_scan(&mask); vb = &mgr->vertex_buffer[i]; offset = vb->buffer_offset + vb->stride * start_vertex; if (vb->user_buffer) { map = (uint8_t*)vb->user_buffer + offset; } else { unsigned size = vb->stride ? num_vertices * vb->stride : sizeof(double)*4; if (offset+size > vb->buffer->width0) { size = vb->buffer->width0 - offset; } map = pipe_buffer_map_range(mgr->pipe, vb->buffer, offset, size, PIPE_TRANSFER_READ, &vb_transfer[i]); } /* Subtract min_index so that indexing with the index buffer works. */ if (unroll_indices) { map -= vb->stride * min_index; } tr->set_buffer(tr, i, map, vb->stride, ~0); } /* Translate. */ if (unroll_indices) { struct pipe_index_buffer *ib = &mgr->index_buffer; struct pipe_transfer *transfer = NULL; unsigned offset = ib->offset + start_index * ib->index_size; uint8_t *map; assert((ib->buffer || ib->user_buffer) && ib->index_size); /* Create and map the output buffer. */ err = u_upload_alloc(mgr->uploader, 0, key->output_stride * num_indices, &out_offset, &out_buffer, (void**)&out_map); if (err != PIPE_OK) return err; if (ib->user_buffer) { map = (uint8_t*)ib->user_buffer + offset; } else { map = pipe_buffer_map_range(mgr->pipe, ib->buffer, offset, num_indices * ib->index_size, PIPE_TRANSFER_READ, &transfer); } switch (ib->index_size) { case 4: tr->run_elts(tr, (unsigned*)map, num_indices, 0, 0, out_map); break; case 2: tr->run_elts16(tr, (uint16_t*)map, num_indices, 0, 0, out_map); break; case 1: tr->run_elts8(tr, map, num_indices, 0, 0, out_map); break; } if (transfer) { pipe_buffer_unmap(mgr->pipe, transfer); } } else { /* Create and map the output buffer. */ err = u_upload_alloc(mgr->uploader, key->output_stride * start_vertex, key->output_stride * num_vertices, &out_offset, &out_buffer, (void**)&out_map); if (err != PIPE_OK) return err; out_offset -= key->output_stride * start_vertex; tr->run(tr, 0, num_vertices, 0, 0, out_map); } /* Unmap all buffers. */ mask = vb_mask; while (mask) { unsigned i = u_bit_scan(&mask); if (vb_transfer[i]) { pipe_buffer_unmap(mgr->pipe, vb_transfer[i]); } } /* Setup the new vertex buffer. */ mgr->real_vertex_buffer[out_vb].buffer_offset = out_offset; mgr->real_vertex_buffer[out_vb].stride = key->output_stride; /* Move the buffer reference. */ pipe_resource_reference( &mgr->real_vertex_buffer[out_vb].buffer, NULL); mgr->real_vertex_buffer[out_vb].buffer = out_buffer; return PIPE_OK; } static boolean u_vbuf_translate_find_free_vb_slots(struct u_vbuf *mgr, unsigned mask[VB_NUM]) { unsigned type; unsigned fallback_vbs[VB_NUM]; /* Set the bit for each buffer which is incompatible, or isn't set. */ uint32_t unused_vb_mask = mgr->ve->incompatible_vb_mask_all | mgr->incompatible_vb_mask | ~mgr->enabled_vb_mask; memset(fallback_vbs, ~0, sizeof(fallback_vbs)); /* Find free slots for each type if needed. */ for (type = 0; type < VB_NUM; type++) { if (mask[type]) { uint32_t index; if (!unused_vb_mask) { return FALSE; } index = ffs(unused_vb_mask) - 1; fallback_vbs[type] = index; /*printf("found slot=%i for type=%i\n", index, type);*/ } } for (type = 0; type < VB_NUM; type++) { if (mask[type]) { mgr->dirty_real_vb_mask |= 1 << fallback_vbs[type]; } } memcpy(mgr->fallback_vbs, fallback_vbs, sizeof(fallback_vbs)); return TRUE; } static boolean u_vbuf_translate_begin(struct u_vbuf *mgr, int start_vertex, unsigned num_vertices, int start_instance, unsigned num_instances, int start_index, unsigned num_indices, int min_index, boolean unroll_indices) { unsigned mask[VB_NUM] = {0}; struct translate_key key[VB_NUM]; unsigned elem_index[VB_NUM][PIPE_MAX_ATTRIBS]; /* ... into key.elements */ unsigned i, type; unsigned incompatible_vb_mask = mgr->incompatible_vb_mask & mgr->ve->used_vb_mask; int start[VB_NUM] = { start_vertex, /* VERTEX */ start_instance, /* INSTANCE */ 0 /* CONST */ }; unsigned num[VB_NUM] = { num_vertices, /* VERTEX */ num_instances, /* INSTANCE */ 1 /* CONST */ }; memset(key, 0, sizeof(key)); memset(elem_index, ~0, sizeof(elem_index)); /* See if there are vertex attribs of each type to translate and * which ones. */ for (i = 0; i < mgr->ve->count; i++) { unsigned vb_index = mgr->ve->ve[i].vertex_buffer_index; if (!mgr->vertex_buffer[vb_index].stride) { if (!(mgr->ve->incompatible_elem_mask & (1 << i)) && !(incompatible_vb_mask & (1 << vb_index))) { continue; } mask[VB_CONST] |= 1 << vb_index; } else if (mgr->ve->ve[i].instance_divisor) { if (!(mgr->ve->incompatible_elem_mask & (1 << i)) && !(incompatible_vb_mask & (1 << vb_index))) { continue; } mask[VB_INSTANCE] |= 1 << vb_index; } else { if (!unroll_indices && !(mgr->ve->incompatible_elem_mask & (1 << i)) && !(incompatible_vb_mask & (1 << vb_index))) { continue; } mask[VB_VERTEX] |= 1 << vb_index; } } assert(mask[VB_VERTEX] || mask[VB_INSTANCE] || mask[VB_CONST]); /* Find free vertex buffer slots. */ if (!u_vbuf_translate_find_free_vb_slots(mgr, mask)) { return FALSE; } /* Initialize the translate keys. */ for (i = 0; i < mgr->ve->count; i++) { struct translate_key *k; struct translate_element *te; unsigned bit, vb_index = mgr->ve->ve[i].vertex_buffer_index; bit = 1 << vb_index; if (!(mgr->ve->incompatible_elem_mask & (1 << i)) && !(incompatible_vb_mask & (1 << vb_index)) && (!unroll_indices || !(mask[VB_VERTEX] & bit))) { continue; } /* Set type to what we will translate. * Whether vertex, instance, or constant attribs. */ for (type = 0; type < VB_NUM; type++) { if (mask[type] & bit) { break; } } assert(type < VB_NUM); assert(translate_is_output_format_supported(mgr->ve->native_format[i])); /*printf("velem=%i type=%i\n", i, type);*/ /* Add the vertex element. */ k = &key[type]; elem_index[type][i] = k->nr_elements; te = &k->element[k->nr_elements]; te->type = TRANSLATE_ELEMENT_NORMAL; te->instance_divisor = 0; te->input_buffer = vb_index; te->input_format = mgr->ve->ve[i].src_format; te->input_offset = mgr->ve->ve[i].src_offset; te->output_format = mgr->ve->native_format[i]; te->output_offset = k->output_stride; k->output_stride += mgr->ve->native_format_size[i]; k->nr_elements++; } /* Translate buffers. */ for (type = 0; type < VB_NUM; type++) { if (key[type].nr_elements) { enum pipe_error err; err = u_vbuf_translate_buffers(mgr, &key[type], mask[type], mgr->fallback_vbs[type], start[type], num[type], start_index, num_indices, min_index, unroll_indices && type == VB_VERTEX); if (err != PIPE_OK) return FALSE; /* Fixup the stride for constant attribs. */ if (type == VB_CONST) { mgr->real_vertex_buffer[mgr->fallback_vbs[VB_CONST]].stride = 0; } } } /* Setup new vertex elements. */ for (i = 0; i < mgr->ve->count; i++) { for (type = 0; type < VB_NUM; type++) { if (elem_index[type][i] < key[type].nr_elements) { struct translate_element *te = &key[type].element[elem_index[type][i]]; mgr->fallback_velems[i].instance_divisor = mgr->ve->ve[i].instance_divisor; mgr->fallback_velems[i].src_format = te->output_format; mgr->fallback_velems[i].src_offset = te->output_offset; mgr->fallback_velems[i].vertex_buffer_index = mgr->fallback_vbs[type]; /* elem_index[type][i] can only be set for one type. */ assert(type > VB_INSTANCE || elem_index[type+1][i] == ~0); assert(type > VB_VERTEX || elem_index[type+2][i] == ~0); break; } } /* No translating, just copy the original vertex element over. */ if (type == VB_NUM) { memcpy(&mgr->fallback_velems[i], &mgr->ve->ve[i], sizeof(struct pipe_vertex_element)); } } u_vbuf_set_vertex_elements_internal(mgr, mgr->ve->count, mgr->fallback_velems); mgr->using_translate = TRUE; return TRUE; } static void u_vbuf_translate_end(struct u_vbuf *mgr) { unsigned i; /* Restore vertex elements. */ mgr->pipe->bind_vertex_elements_state(mgr->pipe, mgr->ve->driver_cso); mgr->using_translate = FALSE; /* Unreference the now-unused VBOs. */ for (i = 0; i < VB_NUM; i++) { unsigned vb = mgr->fallback_vbs[i]; if (vb != ~0) { pipe_resource_reference(&mgr->real_vertex_buffer[vb].buffer, NULL); mgr->fallback_vbs[i] = ~0; /* This will cause the buffer to be unbound in the driver later. */ mgr->dirty_real_vb_mask |= 1 << vb; } } } #define FORMAT_REPLACE(what, withwhat) \ case PIPE_FORMAT_##what: format = PIPE_FORMAT_##withwhat; break static void * u_vbuf_create_vertex_elements(struct u_vbuf *mgr, unsigned count, const struct pipe_vertex_element *attribs) { struct pipe_context *pipe = mgr->pipe; unsigned i; struct pipe_vertex_element driver_attribs[PIPE_MAX_ATTRIBS]; struct u_vbuf_elements *ve = CALLOC_STRUCT(u_vbuf_elements); uint32_t used_buffers = 0; ve->count = count; memcpy(ve->ve, attribs, sizeof(struct pipe_vertex_element) * count); memcpy(driver_attribs, attribs, sizeof(struct pipe_vertex_element) * count); /* Set the best native format in case the original format is not * supported. */ for (i = 0; i < count; i++) { enum pipe_format format = ve->ve[i].src_format; ve->src_format_size[i] = util_format_get_blocksize(format); used_buffers |= 1 << ve->ve[i].vertex_buffer_index; if (!ve->ve[i].instance_divisor) { ve->noninstance_vb_mask_any |= 1 << ve->ve[i].vertex_buffer_index; } /* Choose a native format. * For now we don't care about the alignment, that's going to * be sorted out later. */ if (!mgr->caps.format_fixed32) { switch (format) { FORMAT_REPLACE(R32_FIXED, R32_FLOAT); FORMAT_REPLACE(R32G32_FIXED, R32G32_FLOAT); FORMAT_REPLACE(R32G32B32_FIXED, R32G32B32_FLOAT); FORMAT_REPLACE(R32G32B32A32_FIXED, R32G32B32A32_FLOAT); default:; } } if (!mgr->caps.format_float16) { switch (format) { FORMAT_REPLACE(R16_FLOAT, R32_FLOAT); FORMAT_REPLACE(R16G16_FLOAT, R32G32_FLOAT); FORMAT_REPLACE(R16G16B16_FLOAT, R32G32B32_FLOAT); FORMAT_REPLACE(R16G16B16A16_FLOAT, R32G32B32A32_FLOAT); default:; } } if (!mgr->caps.format_float64) { switch (format) { FORMAT_REPLACE(R64_FLOAT, R32_FLOAT); FORMAT_REPLACE(R64G64_FLOAT, R32G32_FLOAT); FORMAT_REPLACE(R64G64B64_FLOAT, R32G32B32_FLOAT); FORMAT_REPLACE(R64G64B64A64_FLOAT, R32G32B32A32_FLOAT); default:; } } if (!mgr->caps.format_norm32) { switch (format) { FORMAT_REPLACE(R32_UNORM, R32_FLOAT); FORMAT_REPLACE(R32G32_UNORM, R32G32_FLOAT); FORMAT_REPLACE(R32G32B32_UNORM, R32G32B32_FLOAT); FORMAT_REPLACE(R32G32B32A32_UNORM, R32G32B32A32_FLOAT); FORMAT_REPLACE(R32_SNORM, R32_FLOAT); FORMAT_REPLACE(R32G32_SNORM, R32G32_FLOAT); FORMAT_REPLACE(R32G32B32_SNORM, R32G32B32_FLOAT); FORMAT_REPLACE(R32G32B32A32_SNORM, R32G32B32A32_FLOAT); default:; } } if (!mgr->caps.format_scaled32) { switch (format) { FORMAT_REPLACE(R32_USCALED, R32_FLOAT); FORMAT_REPLACE(R32G32_USCALED, R32G32_FLOAT); FORMAT_REPLACE(R32G32B32_USCALED, R32G32B32_FLOAT); FORMAT_REPLACE(R32G32B32A32_USCALED,R32G32B32A32_FLOAT); FORMAT_REPLACE(R32_SSCALED, R32_FLOAT); FORMAT_REPLACE(R32G32_SSCALED, R32G32_FLOAT); FORMAT_REPLACE(R32G32B32_SSCALED, R32G32B32_FLOAT); FORMAT_REPLACE(R32G32B32A32_SSCALED,R32G32B32A32_FLOAT); default:; } } driver_attribs[i].src_format = format; ve->native_format[i] = format; ve->native_format_size[i] = util_format_get_blocksize(ve->native_format[i]); if (ve->ve[i].src_format != format || (!mgr->caps.velem_src_offset_unaligned && ve->ve[i].src_offset % 4 != 0)) { ve->incompatible_elem_mask |= 1 << i; ve->incompatible_vb_mask_any |= 1 << ve->ve[i].vertex_buffer_index; } else { ve->compatible_vb_mask_any |= 1 << ve->ve[i].vertex_buffer_index; } } ve->used_vb_mask = used_buffers; ve->compatible_vb_mask_all = ~ve->incompatible_vb_mask_any & used_buffers; ve->incompatible_vb_mask_all = ~ve->compatible_vb_mask_any & used_buffers; /* Align the formats to the size of DWORD if needed. */ if (!mgr->caps.velem_src_offset_unaligned) { for (i = 0; i < count; i++) { ve->native_format_size[i] = align(ve->native_format_size[i], 4); } } ve->driver_cso = pipe->create_vertex_elements_state(pipe, count, driver_attribs); return ve; } static void u_vbuf_delete_vertex_elements(struct u_vbuf *mgr, void *cso) { struct pipe_context *pipe = mgr->pipe; struct u_vbuf_elements *ve = cso; pipe->delete_vertex_elements_state(pipe, ve->driver_cso); FREE(ve); } void u_vbuf_set_vertex_buffers(struct u_vbuf *mgr, unsigned start_slot, unsigned count, const struct pipe_vertex_buffer *bufs) { unsigned i; /* which buffers are enabled */ uint32_t enabled_vb_mask = 0; /* which buffers are in user memory */ uint32_t user_vb_mask = 0; /* which buffers are incompatible with the driver */ uint32_t incompatible_vb_mask = 0; /* which buffers have a non-zero stride */ uint32_t nonzero_stride_vb_mask = 0; uint32_t mask = ~(((1ull << count) - 1) << start_slot); /* Zero out the bits we are going to rewrite completely. */ mgr->user_vb_mask &= mask; mgr->incompatible_vb_mask &= mask; mgr->nonzero_stride_vb_mask &= mask; mgr->enabled_vb_mask &= mask; if (!bufs) { struct pipe_context *pipe = mgr->pipe; /* Unbind. */ mgr->dirty_real_vb_mask &= mask; for (i = 0; i < count; i++) { unsigned dst_index = start_slot + i; pipe_resource_reference(&mgr->vertex_buffer[dst_index].buffer, NULL); pipe_resource_reference(&mgr->real_vertex_buffer[dst_index].buffer, NULL); } pipe->set_vertex_buffers(pipe, start_slot, count, NULL); return; } for (i = 0; i < count; i++) { unsigned dst_index = start_slot + i; const struct pipe_vertex_buffer *vb = &bufs[i]; struct pipe_vertex_buffer *orig_vb = &mgr->vertex_buffer[dst_index]; struct pipe_vertex_buffer *real_vb = &mgr->real_vertex_buffer[dst_index]; if (!vb->buffer && !vb->user_buffer) { pipe_resource_reference(&orig_vb->buffer, NULL); pipe_resource_reference(&real_vb->buffer, NULL); real_vb->user_buffer = NULL; continue; } pipe_resource_reference(&orig_vb->buffer, vb->buffer); orig_vb->user_buffer = vb->user_buffer; real_vb->buffer_offset = orig_vb->buffer_offset = vb->buffer_offset; real_vb->stride = orig_vb->stride = vb->stride; if (vb->stride) { nonzero_stride_vb_mask |= 1 << dst_index; } enabled_vb_mask |= 1 << dst_index; if ((!mgr->caps.buffer_offset_unaligned && vb->buffer_offset % 4 != 0) || (!mgr->caps.buffer_stride_unaligned && vb->stride % 4 != 0)) { incompatible_vb_mask |= 1 << dst_index; pipe_resource_reference(&real_vb->buffer, NULL); continue; } if (!mgr->caps.user_vertex_buffers && vb->user_buffer) { user_vb_mask |= 1 << dst_index; pipe_resource_reference(&real_vb->buffer, NULL); continue; } pipe_resource_reference(&real_vb->buffer, vb->buffer); real_vb->user_buffer = vb->user_buffer; } mgr->user_vb_mask |= user_vb_mask; mgr->incompatible_vb_mask |= incompatible_vb_mask; mgr->nonzero_stride_vb_mask |= nonzero_stride_vb_mask; mgr->enabled_vb_mask |= enabled_vb_mask; /* All changed buffers are marked as dirty, even the NULL ones, * which will cause the NULL buffers to be unbound in the driver later. */ mgr->dirty_real_vb_mask |= ~mask; } void u_vbuf_set_index_buffer(struct u_vbuf *mgr, const struct pipe_index_buffer *ib) { struct pipe_context *pipe = mgr->pipe; if (ib) { assert(ib->offset % ib->index_size == 0); pipe_resource_reference(&mgr->index_buffer.buffer, ib->buffer); memcpy(&mgr->index_buffer, ib, sizeof(*ib)); } else { pipe_resource_reference(&mgr->index_buffer.buffer, NULL); } pipe->set_index_buffer(pipe, ib); } static enum pipe_error u_vbuf_upload_buffers(struct u_vbuf *mgr, int start_vertex, unsigned num_vertices, int start_instance, unsigned num_instances) { unsigned i; unsigned nr_velems = mgr->ve->count; struct pipe_vertex_element *velems = mgr->using_translate ? mgr->fallback_velems : mgr->ve->ve; unsigned start_offset[PIPE_MAX_ATTRIBS]; unsigned end_offset[PIPE_MAX_ATTRIBS]; uint32_t buffer_mask = 0; /* Determine how much data needs to be uploaded. */ for (i = 0; i < nr_velems; i++) { struct pipe_vertex_element *velem = &velems[i]; unsigned index = velem->vertex_buffer_index; struct pipe_vertex_buffer *vb = &mgr->vertex_buffer[index]; unsigned instance_div, first, size, index_bit; /* Skip the buffers generated by translate. */ if (index == mgr->fallback_vbs[VB_VERTEX] || index == mgr->fallback_vbs[VB_INSTANCE] || index == mgr->fallback_vbs[VB_CONST]) { continue; } if (!vb->user_buffer) { continue; } instance_div = velem->instance_divisor; first = vb->buffer_offset + velem->src_offset; if (!vb->stride) { /* Constant attrib. */ size = mgr->ve->src_format_size[i]; } else if (instance_div) { /* Per-instance attrib. */ unsigned count = (num_instances + instance_div - 1) / instance_div; first += vb->stride * start_instance; size = vb->stride * (count - 1) + mgr->ve->src_format_size[i]; } else { /* Per-vertex attrib. */ first += vb->stride * start_vertex; size = vb->stride * (num_vertices - 1) + mgr->ve->src_format_size[i]; } index_bit = 1 << index; /* Update offsets. */ if (!(buffer_mask & index_bit)) { start_offset[index] = first; end_offset[index] = first + size; } else { if (first < start_offset[index]) start_offset[index] = first; if (first + size > end_offset[index]) end_offset[index] = first + size; } buffer_mask |= index_bit; } /* Upload buffers. */ while (buffer_mask) { unsigned start, end; struct pipe_vertex_buffer *real_vb; const uint8_t *ptr; enum pipe_error err; i = u_bit_scan(&buffer_mask); start = start_offset[i]; end = end_offset[i]; assert(start < end); real_vb = &mgr->real_vertex_buffer[i]; ptr = mgr->vertex_buffer[i].user_buffer; err = u_upload_data(mgr->uploader, start, end - start, ptr + start, &real_vb->buffer_offset, &real_vb->buffer); if (err != PIPE_OK) return err; real_vb->buffer_offset -= start; } return PIPE_OK; } static boolean u_vbuf_need_minmax_index(struct u_vbuf *mgr) { /* See if there are any per-vertex attribs which will be uploaded or * translated. Use bitmasks to get the info instead of looping over vertex * elements. */ return (mgr->ve->used_vb_mask & ((mgr->user_vb_mask | mgr->incompatible_vb_mask | mgr->ve->incompatible_vb_mask_any) & mgr->ve->noninstance_vb_mask_any & mgr->nonzero_stride_vb_mask)) != 0; } static boolean u_vbuf_mapping_vertex_buffer_blocks(struct u_vbuf *mgr) { /* Return true if there are hw buffers which don't need to be translated. * * We could query whether each buffer is busy, but that would * be way more costly than this. */ return (mgr->ve->used_vb_mask & (~mgr->user_vb_mask & ~mgr->incompatible_vb_mask & mgr->ve->compatible_vb_mask_all & mgr->ve->noninstance_vb_mask_any & mgr->nonzero_stride_vb_mask)) != 0; } static void u_vbuf_get_minmax_index(struct pipe_context *pipe, struct pipe_index_buffer *ib, const struct pipe_draw_info *info, int *out_min_index, int *out_max_index) { struct pipe_transfer *transfer = NULL; const void *indices; unsigned i; unsigned restart_index = info->restart_index; if (ib->user_buffer) { indices = (uint8_t*)ib->user_buffer + ib->offset + info->start * ib->index_size; } else { indices = pipe_buffer_map_range(pipe, ib->buffer, ib->offset + info->start * ib->index_size, info->count * ib->index_size, PIPE_TRANSFER_READ, &transfer); } switch (ib->index_size) { case 4: { const unsigned *ui_indices = (const unsigned*)indices; unsigned max_ui = 0; unsigned min_ui = ~0U; if (info->primitive_restart) { for (i = 0; i < info->count; i++) { if (ui_indices[i] != restart_index) { if (ui_indices[i] > max_ui) max_ui = ui_indices[i]; if (ui_indices[i] < min_ui) min_ui = ui_indices[i]; } } } else { for (i = 0; i < info->count; i++) { if (ui_indices[i] > max_ui) max_ui = ui_indices[i]; if (ui_indices[i] < min_ui) min_ui = ui_indices[i]; } } *out_min_index = min_ui; *out_max_index = max_ui; break; } case 2: { const unsigned short *us_indices = (const unsigned short*)indices; unsigned max_us = 0; unsigned min_us = ~0U; if (info->primitive_restart) { for (i = 0; i < info->count; i++) { if (us_indices[i] != restart_index) { if (us_indices[i] > max_us) max_us = us_indices[i]; if (us_indices[i] < min_us) min_us = us_indices[i]; } } } else { for (i = 0; i < info->count; i++) { if (us_indices[i] > max_us) max_us = us_indices[i]; if (us_indices[i] < min_us) min_us = us_indices[i]; } } *out_min_index = min_us; *out_max_index = max_us; break; } case 1: { const unsigned char *ub_indices = (const unsigned char*)indices; unsigned max_ub = 0; unsigned min_ub = ~0U; if (info->primitive_restart) { for (i = 0; i < info->count; i++) { if (ub_indices[i] != restart_index) { if (ub_indices[i] > max_ub) max_ub = ub_indices[i]; if (ub_indices[i] < min_ub) min_ub = ub_indices[i]; } } } else { for (i = 0; i < info->count; i++) { if (ub_indices[i] > max_ub) max_ub = ub_indices[i]; if (ub_indices[i] < min_ub) min_ub = ub_indices[i]; } } *out_min_index = min_ub; *out_max_index = max_ub; break; } default: assert(0); *out_min_index = 0; *out_max_index = 0; } if (transfer) { pipe_buffer_unmap(pipe, transfer); } } static void u_vbuf_set_driver_vertex_buffers(struct u_vbuf *mgr) { struct pipe_context *pipe = mgr->pipe; unsigned start_slot, count; start_slot = ffs(mgr->dirty_real_vb_mask) - 1; count = util_last_bit(mgr->dirty_real_vb_mask >> start_slot); pipe->set_vertex_buffers(pipe, start_slot, count, mgr->real_vertex_buffer + start_slot); mgr->dirty_real_vb_mask = 0; } void u_vbuf_draw_vbo(struct u_vbuf *mgr, const struct pipe_draw_info *info) { struct pipe_context *pipe = mgr->pipe; int start_vertex, min_index; unsigned num_vertices; boolean unroll_indices = FALSE; uint32_t used_vb_mask = mgr->ve->used_vb_mask; uint32_t user_vb_mask = mgr->user_vb_mask & used_vb_mask; uint32_t incompatible_vb_mask = mgr->incompatible_vb_mask & used_vb_mask; /* Normal draw. No fallback and no user buffers. */ if (!incompatible_vb_mask && !mgr->ve->incompatible_elem_mask && !user_vb_mask) { /* Set vertex buffers if needed. */ if (mgr->dirty_real_vb_mask & used_vb_mask) { u_vbuf_set_driver_vertex_buffers(mgr); } pipe->draw_vbo(pipe, info); return; } if (info->indexed) { /* See if anything needs to be done for per-vertex attribs. */ if (u_vbuf_need_minmax_index(mgr)) { int max_index; if (info->max_index != ~0) { min_index = info->min_index; max_index = info->max_index; } else { u_vbuf_get_minmax_index(mgr->pipe, &mgr->index_buffer, info, &min_index, &max_index); } assert(min_index <= max_index); start_vertex = min_index + info->index_bias; num_vertices = max_index + 1 - min_index; /* Primitive restart doesn't work when unrolling indices. * We would have to break this drawing operation into several ones. */ /* Use some heuristic to see if unrolling indices improves * performance. */ if (!info->primitive_restart && num_vertices > info->count*2 && num_vertices-info->count > 32 && !u_vbuf_mapping_vertex_buffer_blocks(mgr)) { /*printf("num_vertices=%i count=%i\n", num_vertices, info->count);*/ unroll_indices = TRUE; user_vb_mask &= ~(mgr->nonzero_stride_vb_mask & mgr->ve->noninstance_vb_mask_any); } } else { /* Nothing to do for per-vertex attribs. */ start_vertex = 0; num_vertices = 0; min_index = 0; } } else { start_vertex = info->start; num_vertices = info->count; min_index = 0; } /* Translate vertices with non-native layouts or formats. */ if (unroll_indices || incompatible_vb_mask || mgr->ve->incompatible_elem_mask) { if (!u_vbuf_translate_begin(mgr, start_vertex, num_vertices, info->start_instance, info->instance_count, info->start, info->count, min_index, unroll_indices)) { debug_warn_once("u_vbuf_translate_begin() failed"); return; } user_vb_mask &= ~(incompatible_vb_mask | mgr->ve->incompatible_vb_mask_all); } /* Upload user buffers. */ if (user_vb_mask) { if (u_vbuf_upload_buffers(mgr, start_vertex, num_vertices, info->start_instance, info->instance_count) != PIPE_OK) { debug_warn_once("u_vbuf_upload_buffers() failed"); return; } mgr->dirty_real_vb_mask |= user_vb_mask; } /* if (unroll_indices) { printf("unrolling indices: start_vertex = %i, num_vertices = %i\n", start_vertex, num_vertices); util_dump_draw_info(stdout, info); printf("\n"); } unsigned i; for (i = 0; i < mgr->nr_vertex_buffers; i++) { printf("input %i: ", i); util_dump_vertex_buffer(stdout, mgr->vertex_buffer+i); printf("\n"); } for (i = 0; i < mgr->nr_real_vertex_buffers; i++) { printf("real %i: ", i); util_dump_vertex_buffer(stdout, mgr->real_vertex_buffer+i); printf("\n"); } */ u_upload_unmap(mgr->uploader); u_vbuf_set_driver_vertex_buffers(mgr); if (unlikely(unroll_indices)) { struct pipe_draw_info new_info = *info; new_info.indexed = FALSE; new_info.index_bias = 0; new_info.min_index = 0; new_info.max_index = info->count - 1; new_info.start = 0; pipe->draw_vbo(pipe, &new_info); } else { pipe->draw_vbo(pipe, info); } if (mgr->using_translate) { u_vbuf_translate_end(mgr); } } void u_vbuf_save_vertex_elements(struct u_vbuf *mgr) { assert(!mgr->ve_saved); mgr->ve_saved = mgr->ve; } void u_vbuf_restore_vertex_elements(struct u_vbuf *mgr) { if (mgr->ve != mgr->ve_saved) { struct pipe_context *pipe = mgr->pipe; mgr->ve = mgr->ve_saved; pipe->bind_vertex_elements_state(pipe, mgr->ve ? mgr->ve->driver_cso : NULL); } mgr->ve_saved = NULL; } void u_vbuf_save_aux_vertex_buffer_slot(struct u_vbuf *mgr) { struct pipe_vertex_buffer *vb = &mgr->vertex_buffer[mgr->aux_vertex_buffer_slot]; pipe_resource_reference(&mgr->aux_vertex_buffer_saved.buffer, vb->buffer); memcpy(&mgr->aux_vertex_buffer_saved, vb, sizeof(*vb)); } void u_vbuf_restore_aux_vertex_buffer_slot(struct u_vbuf *mgr) { u_vbuf_set_vertex_buffers(mgr, mgr->aux_vertex_buffer_slot, 1, &mgr->aux_vertex_buffer_saved); pipe_resource_reference(&mgr->aux_vertex_buffer_saved.buffer, NULL); }