/* * Copyright © 2008 Jérôme Glisse * 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 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 THE COPYRIGHT HOLDERS, 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. * * The above copyright notice and this permission notice (including the * next paragraph) shall be included in all copies or substantial portions * of the Software. */ /* * Authors: * Aapo Tahkola * Nicolai Haehnle * Jérôme Glisse */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include #include #include #include "radeon_cs.h" #include "radeon_cs_int.h" #include "radeon_bo_int.h" #include "radeon_cs_gem.h" #include "radeon_bo_gem.h" #include "drm.h" #include "libdrm.h" #include "xf86drm.h" #include "xf86atomic.h" #include "radeon_drm.h" #include "bof.h" #define CS_BOF_DUMP 0 struct radeon_cs_manager_gem { struct radeon_cs_manager base; uint32_t device_id; unsigned nbof; }; #pragma pack(1) struct cs_reloc_gem { uint32_t handle; uint32_t read_domain; uint32_t write_domain; uint32_t flags; }; #pragma pack() #define RELOC_SIZE (sizeof(struct cs_reloc_gem) / sizeof(uint32_t)) struct cs_gem { struct radeon_cs_int base; struct drm_radeon_cs cs; struct drm_radeon_cs_chunk chunks[2]; unsigned nrelocs; uint32_t *relocs; struct radeon_bo_int **relocs_bo; }; static pthread_mutex_t id_mutex = PTHREAD_MUTEX_INITIALIZER; static uint32_t cs_id_source = 0; /** * result is undefined if called with ~0 */ static uint32_t get_first_zero(const uint32_t n) { /* __builtin_ctz returns number of trailing zeros. */ return 1 << __builtin_ctz(~n); } /** * Returns a free id for cs. * If there is no free id we return zero **/ static uint32_t generate_id(void) { uint32_t r = 0; pthread_mutex_lock( &id_mutex ); /* check for free ids */ if (cs_id_source != ~r) { /* find first zero bit */ r = get_first_zero(cs_id_source); /* set id as reserved */ cs_id_source |= r; } pthread_mutex_unlock( &id_mutex ); return r; } /** * Free the id for later reuse **/ static void free_id(uint32_t id) { pthread_mutex_lock( &id_mutex ); cs_id_source &= ~id; pthread_mutex_unlock( &id_mutex ); } static struct radeon_cs_int *cs_gem_create(struct radeon_cs_manager *csm, uint32_t ndw) { struct cs_gem *csg; /* max cmd buffer size is 64Kb */ if (ndw > (64 * 1024 / 4)) { return NULL; } csg = (struct cs_gem*)calloc(1, sizeof(struct cs_gem)); if (csg == NULL) { return NULL; } csg->base.csm = csm; csg->base.ndw = 64 * 1024 / 4; csg->base.packets = (uint32_t*)calloc(1, 64 * 1024); if (csg->base.packets == NULL) { free(csg); return NULL; } csg->base.relocs_total_size = 0; csg->base.crelocs = 0; csg->base.id = generate_id(); csg->nrelocs = 4096 / (4 * 4) ; csg->relocs_bo = (struct radeon_bo_int**)calloc(1, csg->nrelocs*sizeof(void*)); if (csg->relocs_bo == NULL) { free(csg->base.packets); free(csg); return NULL; } csg->base.relocs = csg->relocs = (uint32_t*)calloc(1, 4096); if (csg->relocs == NULL) { free(csg->relocs_bo); free(csg->base.packets); free(csg); return NULL; } csg->chunks[0].chunk_id = RADEON_CHUNK_ID_IB; csg->chunks[0].length_dw = 0; csg->chunks[0].chunk_data = (uint64_t)(uintptr_t)csg->base.packets; csg->chunks[1].chunk_id = RADEON_CHUNK_ID_RELOCS; csg->chunks[1].length_dw = 0; csg->chunks[1].chunk_data = (uint64_t)(uintptr_t)csg->relocs; return (struct radeon_cs_int*)csg; } static int cs_gem_write_reloc(struct radeon_cs_int *cs, struct radeon_bo *bo, uint32_t read_domain, uint32_t write_domain, uint32_t flags) { struct radeon_bo_int *boi = (struct radeon_bo_int *)bo; struct cs_gem *csg = (struct cs_gem*)cs; struct cs_reloc_gem *reloc; uint32_t idx; unsigned i; assert(boi->space_accounted); /* check domains */ if ((read_domain && write_domain) || (!read_domain && !write_domain)) { /* in one CS a bo can only be in read or write domain but not * in read & write domain at the same sime */ return -EINVAL; } if (read_domain == RADEON_GEM_DOMAIN_CPU) { return -EINVAL; } if (write_domain == RADEON_GEM_DOMAIN_CPU) { return -EINVAL; } /* use bit field hash function to determine if this bo is for sure not in this cs.*/ if ((atomic_read((atomic_t *)radeon_gem_get_reloc_in_cs(bo)) & cs->id)) { /* check if bo is already referenced. * Scanning from end to begin reduces cycles with mesa because * it often relocates same shared dma bo again. */ for(i = cs->crelocs; i != 0;) { --i; idx = i * RELOC_SIZE; reloc = (struct cs_reloc_gem*)&csg->relocs[idx]; if (reloc->handle == bo->handle) { /* Check domains must be in read or write. As we check already * checked that in argument one of the read or write domain was * set we only need to check that if previous reloc as the read * domain set then the read_domain should also be set for this * new relocation. */ /* the DDX expects to read and write from same pixmap */ if (write_domain && (reloc->read_domain & write_domain)) { reloc->read_domain = 0; reloc->write_domain = write_domain; } else if (read_domain & reloc->write_domain) { reloc->read_domain = 0; } else { if (write_domain != reloc->write_domain) return -EINVAL; if (read_domain != reloc->read_domain) return -EINVAL; } reloc->read_domain |= read_domain; reloc->write_domain |= write_domain; /* update flags */ reloc->flags |= (flags & reloc->flags); /* write relocation packet */ radeon_cs_write_dword((struct radeon_cs *)cs, 0xc0001000); radeon_cs_write_dword((struct radeon_cs *)cs, idx); return 0; } } } /* new relocation */ if (csg->base.crelocs >= csg->nrelocs) { /* allocate more memory (TODO: should use a slab allocatore maybe) */ uint32_t *tmp, size; size = ((csg->nrelocs + 1) * sizeof(struct radeon_bo*)); tmp = (uint32_t*)realloc(csg->relocs_bo, size); if (tmp == NULL) { return -ENOMEM; } csg->relocs_bo = (struct radeon_bo_int **)tmp; size = ((csg->nrelocs + 1) * RELOC_SIZE * 4); tmp = (uint32_t*)realloc(csg->relocs, size); if (tmp == NULL) { return -ENOMEM; } cs->relocs = csg->relocs = tmp; csg->nrelocs += 1; csg->chunks[1].chunk_data = (uint64_t)(uintptr_t)csg->relocs; } csg->relocs_bo[csg->base.crelocs] = boi; idx = (csg->base.crelocs++) * RELOC_SIZE; reloc = (struct cs_reloc_gem*)&csg->relocs[idx]; reloc->handle = bo->handle; reloc->read_domain = read_domain; reloc->write_domain = write_domain; reloc->flags = flags; csg->chunks[1].length_dw += RELOC_SIZE; radeon_bo_ref(bo); /* bo might be referenced from another context so have to use atomic opertions */ atomic_add((atomic_t *)radeon_gem_get_reloc_in_cs(bo), cs->id); cs->relocs_total_size += boi->size; radeon_cs_write_dword((struct radeon_cs *)cs, 0xc0001000); radeon_cs_write_dword((struct radeon_cs *)cs, idx); return 0; } static int cs_gem_begin(struct radeon_cs_int *cs, uint32_t ndw, const char *file, const char *func, int line) { if (cs->section_ndw) { fprintf(stderr, "CS already in a section(%s,%s,%d)\n", cs->section_file, cs->section_func, cs->section_line); fprintf(stderr, "CS can't start section(%s,%s,%d)\n", file, func, line); return -EPIPE; } cs->section_ndw = ndw; cs->section_cdw = 0; cs->section_file = file; cs->section_func = func; cs->section_line = line; if (cs->cdw + ndw > cs->ndw) { uint32_t tmp, *ptr; /* round up the required size to a multiple of 1024 */ tmp = (cs->cdw + ndw + 0x3FF) & (~0x3FF); ptr = (uint32_t*)realloc(cs->packets, 4 * tmp); if (ptr == NULL) { return -ENOMEM; } cs->packets = ptr; cs->ndw = tmp; } return 0; } static int cs_gem_end(struct radeon_cs_int *cs, const char *file, const char *func, int line) { if (!cs->section_ndw) { fprintf(stderr, "CS no section to end at (%s,%s,%d)\n", file, func, line); return -EPIPE; } if (cs->section_ndw != cs->section_cdw) { fprintf(stderr, "CS section size missmatch start at (%s,%s,%d) %d vs %d\n", cs->section_file, cs->section_func, cs->section_line, cs->section_ndw, cs->section_cdw); fprintf(stderr, "CS section end at (%s,%s,%d)\n", file, func, line); /* We must reset the section even when there is error. */ cs->section_ndw = 0; return -EPIPE; } cs->section_ndw = 0; return 0; } #if CS_BOF_DUMP static void cs_gem_dump_bof(struct radeon_cs_int *cs) { struct cs_gem *csg = (struct cs_gem*)cs; struct radeon_cs_manager_gem *csm; bof_t *bcs, *blob, *array, *bo, *size, *handle, *device_id, *root; char tmp[256]; unsigned i; csm = (struct radeon_cs_manager_gem *)cs->csm; root = device_id = bcs = blob = array = bo = size = handle = NULL; root = bof_object(); if (root == NULL) goto out_err; device_id = bof_int32(csm->device_id); if (device_id == NULL) return; if (bof_object_set(root, "device_id", device_id)) goto out_err; bof_decref(device_id); device_id = NULL; /* dump relocs */ blob = bof_blob(csg->nrelocs * 16, csg->relocs); if (blob == NULL) goto out_err; if (bof_object_set(root, "reloc", blob)) goto out_err; bof_decref(blob); blob = NULL; /* dump cs */ blob = bof_blob(cs->cdw * 4, cs->packets); if (blob == NULL) goto out_err; if (bof_object_set(root, "pm4", blob)) goto out_err; bof_decref(blob); blob = NULL; /* dump bo */ array = bof_array(); if (array == NULL) goto out_err; for (i = 0; i < csg->base.crelocs; i++) { bo = bof_object(); if (bo == NULL) goto out_err; size = bof_int32(csg->relocs_bo[i]->size); if (size == NULL) goto out_err; if (bof_object_set(bo, "size", size)) goto out_err; bof_decref(size); size = NULL; handle = bof_int32(csg->relocs_bo[i]->handle); if (handle == NULL) goto out_err; if (bof_object_set(bo, "handle", handle)) goto out_err; bof_decref(handle); handle = NULL; radeon_bo_map((struct radeon_bo*)csg->relocs_bo[i], 0); blob = bof_blob(csg->relocs_bo[i]->size, csg->relocs_bo[i]->ptr); radeon_bo_unmap((struct radeon_bo*)csg->relocs_bo[i]); if (blob == NULL) goto out_err; if (bof_object_set(bo, "data", blob)) goto out_err; bof_decref(blob); blob = NULL; if (bof_array_append(array, bo)) goto out_err; bof_decref(bo); bo = NULL; } if (bof_object_set(root, "bo", array)) goto out_err; sprintf(tmp, "d-0x%04X-%08d.bof", csm->device_id, csm->nbof++); bof_dump_file(root, tmp); out_err: bof_decref(blob); bof_decref(array); bof_decref(bo); bof_decref(size); bof_decref(handle); bof_decref(device_id); bof_decref(root); } #endif static int cs_gem_emit(struct radeon_cs_int *cs) { struct cs_gem *csg = (struct cs_gem*)cs; uint64_t chunk_array[2]; unsigned i; int r; while (cs->cdw & 7) radeon_cs_write_dword((struct radeon_cs *)cs, 0x80000000); #if CS_BOF_DUMP cs_gem_dump_bof(cs); #endif csg->chunks[0].length_dw = cs->cdw; chunk_array[0] = (uint64_t)(uintptr_t)&csg->chunks[0]; chunk_array[1] = (uint64_t)(uintptr_t)&csg->chunks[1]; csg->cs.num_chunks = 2; csg->cs.chunks = (uint64_t)(uintptr_t)chunk_array; r = drmCommandWriteRead(cs->csm->fd, DRM_RADEON_CS, &csg->cs, sizeof(struct drm_radeon_cs)); for (i = 0; i < csg->base.crelocs; i++) { csg->relocs_bo[i]->space_accounted = 0; /* bo might be referenced from another context so have to use atomic opertions */ atomic_dec((atomic_t *)radeon_gem_get_reloc_in_cs((struct radeon_bo*)csg->relocs_bo[i]), cs->id); radeon_bo_unref((struct radeon_bo *)csg->relocs_bo[i]); csg->relocs_bo[i] = NULL; } cs->csm->read_used = 0; cs->csm->vram_write_used = 0; cs->csm->gart_write_used = 0; return r; } static int cs_gem_destroy(struct radeon_cs_int *cs) { struct cs_gem *csg = (struct cs_gem*)cs; free_id(cs->id); free(csg->relocs_bo); free(cs->relocs); free(cs->packets); free(cs); return 0; } static int cs_gem_erase(struct radeon_cs_int *cs) { struct cs_gem *csg = (struct cs_gem*)cs; unsigned i; if (csg->relocs_bo) { for (i = 0; i < csg->base.crelocs; i++) { if (csg->relocs_bo[i]) { /* bo might be referenced from another context so have to use atomic opertions */ atomic_dec((atomic_t *)radeon_gem_get_reloc_in_cs((struct radeon_bo*)csg->relocs_bo[i]), cs->id); radeon_bo_unref((struct radeon_bo *)csg->relocs_bo[i]); csg->relocs_bo[i] = NULL; } } } cs->relocs_total_size = 0; cs->cdw = 0; cs->section_ndw = 0; cs->crelocs = 0; csg->chunks[0].length_dw = 0; csg->chunks[1].length_dw = 0; return 0; } static int cs_gem_need_flush(struct radeon_cs_int *cs) { return 0; //(cs->relocs_total_size > (32*1024*1024)); } static void cs_gem_print(struct radeon_cs_int *cs, FILE *file) { struct radeon_cs_manager_gem *csm; unsigned int i; csm = (struct radeon_cs_manager_gem *)cs->csm; fprintf(file, "VENDORID:DEVICEID 0x%04X:0x%04X\n", 0x1002, csm->device_id); for (i = 0; i < cs->cdw; i++) { fprintf(file, "0x%08X\n", cs->packets[i]); } } static struct radeon_cs_funcs radeon_cs_gem_funcs = { cs_gem_create, cs_gem_write_reloc, cs_gem_begin, cs_gem_end, cs_gem_emit, cs_gem_destroy, cs_gem_erase, cs_gem_need_flush, cs_gem_print, }; static int radeon_get_device_id(int fd, uint32_t *device_id) { struct drm_radeon_info info = {}; int r; *device_id = 0; info.request = RADEON_INFO_DEVICE_ID; info.value = (uintptr_t)device_id; r = drmCommandWriteRead(fd, DRM_RADEON_INFO, &info, sizeof(struct drm_radeon_info)); return r; } drm_public struct radeon_cs_manager *radeon_cs_manager_gem_ctor(int fd) { struct radeon_cs_manager_gem *csm; csm = calloc(1, sizeof(struct radeon_cs_manager_gem)); if (csm == NULL) { return NULL; } csm->base.funcs = &radeon_cs_gem_funcs; csm->base.fd = fd; radeon_get_device_id(fd, &csm->device_id); return &csm->base; } drm_public void radeon_cs_manager_gem_dtor(struct radeon_cs_manager *csm) { free(csm); }