/* * Copyright © 2009 Corbin Simpson * 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 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: * Corbin Simpson * Joakim Sindholt * Marek Olšák */ #include "radeon_drm_bo.h" #include "radeon_drm_cs.h" #include "radeon_drm_public.h" #include "pipebuffer/pb_bufmgr.h" #include "util/u_memory.h" #include "util/u_hash_table.h" #include #include #include #include #include #include #ifndef RADEON_INFO_ACTIVE_CU_COUNT #define RADEON_INFO_ACTIVE_CU_COUNT 0x20 #endif #ifndef RADEON_INFO_CURRENT_GPU_TEMP #define RADEON_INFO_CURRENT_GPU_TEMP 0x21 #define RADEON_INFO_CURRENT_GPU_SCLK 0x22 #define RADEON_INFO_CURRENT_GPU_MCLK 0x23 #define RADEON_INFO_READ_REG 0x24 #endif #define RADEON_INFO_VA_UNMAP_WORKING 0x25 #ifndef RADEON_INFO_GPU_RESET_COUNTER #define RADEON_INFO_GPU_RESET_COUNTER 0x26 #endif static struct util_hash_table *fd_tab = NULL; pipe_static_mutex(fd_tab_mutex); /* Enable/disable feature access for one command stream. * If enable == TRUE, return TRUE on success. * Otherwise, return FALSE. * * We basically do the same thing kernel does, because we have to deal * with multiple contexts (here command streams) backed by one winsys. */ static boolean radeon_set_fd_access(struct radeon_drm_cs *applier, struct radeon_drm_cs **owner, pipe_mutex *mutex, unsigned request, const char *request_name, boolean enable) { struct drm_radeon_info info; unsigned value = enable ? 1 : 0; memset(&info, 0, sizeof(info)); pipe_mutex_lock(*mutex); /* Early exit if we are sure the request will fail. */ if (enable) { if (*owner) { pipe_mutex_unlock(*mutex); return FALSE; } } else { if (*owner != applier) { pipe_mutex_unlock(*mutex); return FALSE; } } /* Pass through the request to the kernel. */ info.value = (unsigned long)&value; info.request = request; if (drmCommandWriteRead(applier->ws->fd, DRM_RADEON_INFO, &info, sizeof(info)) != 0) { pipe_mutex_unlock(*mutex); return FALSE; } /* Update the rights in the winsys. */ if (enable) { if (value) { *owner = applier; pipe_mutex_unlock(*mutex); return TRUE; } } else { *owner = NULL; } pipe_mutex_unlock(*mutex); return FALSE; } static boolean radeon_get_drm_value(int fd, unsigned request, const char *errname, uint32_t *out) { struct drm_radeon_info info; int retval; memset(&info, 0, sizeof(info)); info.value = (unsigned long)out; info.request = request; retval = drmCommandWriteRead(fd, DRM_RADEON_INFO, &info, sizeof(info)); if (retval) { if (errname) { fprintf(stderr, "radeon: Failed to get %s, error number %d\n", errname, retval); } return FALSE; } return TRUE; } /* Helper function to do the ioctls needed for setup and init. */ static boolean do_winsys_init(struct radeon_drm_winsys *ws) { struct drm_radeon_gem_info gem_info; int retval; drmVersionPtr version; memset(&gem_info, 0, sizeof(gem_info)); /* We do things in a specific order here. * * DRM version first. We need to be sure we're running on a KMS chipset. * This is also for some features. * * Then, the PCI ID. This is essential and should return usable numbers * for all Radeons. If this fails, we probably got handed an FD for some * non-Radeon card. * * The GEM info is actually bogus on the kernel side, as well as our side * (see radeon_gem_info_ioctl in radeon_gem.c) but that's alright because * we don't actually use the info for anything yet. * * The GB and Z pipe requests should always succeed, but they might not * return sensical values for all chipsets, but that's alright because * the pipe drivers already know that. */ /* Get DRM version. */ version = drmGetVersion(ws->fd); if (version->version_major != 2 || version->version_minor < 3) { fprintf(stderr, "%s: DRM version is %d.%d.%d but this driver is " "only compatible with 2.3.x (kernel 2.6.34) or later.\n", __FUNCTION__, version->version_major, version->version_minor, version->version_patchlevel); drmFreeVersion(version); return FALSE; } ws->info.drm_major = version->version_major; ws->info.drm_minor = version->version_minor; ws->info.drm_patchlevel = version->version_patchlevel; drmFreeVersion(version); /* Get PCI ID. */ if (!radeon_get_drm_value(ws->fd, RADEON_INFO_DEVICE_ID, "PCI ID", &ws->info.pci_id)) return FALSE; /* Check PCI ID. */ switch (ws->info.pci_id) { #define CHIPSET(pci_id, name, cfamily) case pci_id: ws->info.family = CHIP_##cfamily; ws->gen = DRV_R300; break; #include "pci_ids/r300_pci_ids.h" #undef CHIPSET #define CHIPSET(pci_id, name, cfamily) case pci_id: ws->info.family = CHIP_##cfamily; ws->gen = DRV_R600; break; #include "pci_ids/r600_pci_ids.h" #undef CHIPSET #define CHIPSET(pci_id, name, cfamily) case pci_id: ws->info.family = CHIP_##cfamily; ws->gen = DRV_SI; break; #include "pci_ids/radeonsi_pci_ids.h" #undef CHIPSET default: fprintf(stderr, "radeon: Invalid PCI ID.\n"); return FALSE; } switch (ws->info.family) { default: case CHIP_UNKNOWN: fprintf(stderr, "radeon: Unknown family.\n"); return FALSE; case CHIP_R300: case CHIP_R350: case CHIP_RV350: case CHIP_RV370: case CHIP_RV380: case CHIP_RS400: case CHIP_RC410: case CHIP_RS480: ws->info.chip_class = R300; break; case CHIP_R420: /* R4xx-based cores. */ case CHIP_R423: case CHIP_R430: case CHIP_R480: case CHIP_R481: case CHIP_RV410: case CHIP_RS600: case CHIP_RS690: case CHIP_RS740: ws->info.chip_class = R400; break; case CHIP_RV515: /* R5xx-based cores. */ case CHIP_R520: case CHIP_RV530: case CHIP_R580: case CHIP_RV560: case CHIP_RV570: ws->info.chip_class = R500; break; case CHIP_R600: case CHIP_RV610: case CHIP_RV630: case CHIP_RV670: case CHIP_RV620: case CHIP_RV635: case CHIP_RS780: case CHIP_RS880: ws->info.chip_class = R600; break; case CHIP_RV770: case CHIP_RV730: case CHIP_RV710: case CHIP_RV740: ws->info.chip_class = R700; break; case CHIP_CEDAR: case CHIP_REDWOOD: case CHIP_JUNIPER: case CHIP_CYPRESS: case CHIP_HEMLOCK: case CHIP_PALM: case CHIP_SUMO: case CHIP_SUMO2: case CHIP_BARTS: case CHIP_TURKS: case CHIP_CAICOS: ws->info.chip_class = EVERGREEN; break; case CHIP_CAYMAN: case CHIP_ARUBA: ws->info.chip_class = CAYMAN; break; case CHIP_TAHITI: case CHIP_PITCAIRN: case CHIP_VERDE: case CHIP_OLAND: case CHIP_HAINAN: ws->info.chip_class = SI; break; case CHIP_BONAIRE: case CHIP_KAVERI: case CHIP_KABINI: case CHIP_HAWAII: case CHIP_MULLINS: ws->info.chip_class = CIK; break; } /* Check for dma */ ws->info.r600_has_dma = FALSE; /* DMA is disabled on R700. There is IB corruption and hangs. */ if (ws->info.chip_class >= EVERGREEN && ws->info.drm_minor >= 27) { ws->info.r600_has_dma = TRUE; } /* Check for UVD and VCE */ ws->info.has_uvd = FALSE; ws->info.vce_fw_version = 0x00000000; if (ws->info.drm_minor >= 32) { uint32_t value = RADEON_CS_RING_UVD; if (radeon_get_drm_value(ws->fd, RADEON_INFO_RING_WORKING, "UVD Ring working", &value)) ws->info.has_uvd = value; value = RADEON_CS_RING_VCE; if (radeon_get_drm_value(ws->fd, RADEON_INFO_RING_WORKING, NULL, &value) && value) { if (radeon_get_drm_value(ws->fd, RADEON_INFO_VCE_FW_VERSION, "VCE FW version", &value)) ws->info.vce_fw_version = value; } } /* Check for userptr support. */ { struct drm_radeon_gem_userptr args = {0}; /* If the ioctl doesn't exist, -EINVAL is returned. * * If the ioctl exists, it should return -EACCES * if RADEON_GEM_USERPTR_READONLY or RADEON_GEM_USERPTR_REGISTER * aren't set. */ ws->info.has_userptr = drmCommandWriteRead(ws->fd, DRM_RADEON_GEM_USERPTR, &args, sizeof(args)) == -EACCES; } /* Get GEM info. */ retval = drmCommandWriteRead(ws->fd, DRM_RADEON_GEM_INFO, &gem_info, sizeof(gem_info)); if (retval) { fprintf(stderr, "radeon: Failed to get MM info, error number %d\n", retval); return FALSE; } ws->info.gart_size = gem_info.gart_size; ws->info.vram_size = gem_info.vram_size; /* Get max clock frequency info and convert it to MHz */ radeon_get_drm_value(ws->fd, RADEON_INFO_MAX_SCLK, NULL, &ws->info.max_sclk); ws->info.max_sclk /= 1000; radeon_get_drm_value(ws->fd, RADEON_INFO_SI_BACKEND_ENABLED_MASK, NULL, &ws->info.si_backend_enabled_mask); ws->num_cpus = sysconf(_SC_NPROCESSORS_ONLN); /* Generation-specific queries. */ if (ws->gen == DRV_R300) { if (!radeon_get_drm_value(ws->fd, RADEON_INFO_NUM_GB_PIPES, "GB pipe count", &ws->info.r300_num_gb_pipes)) return FALSE; if (!radeon_get_drm_value(ws->fd, RADEON_INFO_NUM_Z_PIPES, "Z pipe count", &ws->info.r300_num_z_pipes)) return FALSE; } else if (ws->gen >= DRV_R600) { if (ws->info.drm_minor >= 9 && !radeon_get_drm_value(ws->fd, RADEON_INFO_NUM_BACKENDS, "num backends", &ws->info.r600_num_backends)) return FALSE; /* get the GPU counter frequency, failure is not fatal */ radeon_get_drm_value(ws->fd, RADEON_INFO_CLOCK_CRYSTAL_FREQ, NULL, &ws->info.r600_clock_crystal_freq); radeon_get_drm_value(ws->fd, RADEON_INFO_TILING_CONFIG, NULL, &ws->info.r600_tiling_config); if (ws->info.drm_minor >= 11) { radeon_get_drm_value(ws->fd, RADEON_INFO_NUM_TILE_PIPES, NULL, &ws->info.r600_num_tile_pipes); if (radeon_get_drm_value(ws->fd, RADEON_INFO_BACKEND_MAP, NULL, &ws->info.r600_backend_map)) ws->info.r600_backend_map_valid = TRUE; } ws->info.r600_virtual_address = FALSE; if (ws->info.drm_minor >= 13) { uint32_t ib_vm_max_size; ws->info.r600_virtual_address = TRUE; if (!radeon_get_drm_value(ws->fd, RADEON_INFO_VA_START, NULL, &ws->va_start)) ws->info.r600_virtual_address = FALSE; if (!radeon_get_drm_value(ws->fd, RADEON_INFO_IB_VM_MAX_SIZE, NULL, &ib_vm_max_size)) ws->info.r600_virtual_address = FALSE; radeon_get_drm_value(ws->fd, RADEON_INFO_VA_UNMAP_WORKING, NULL, &ws->va_unmap_working); } if (ws->gen == DRV_R600 && !debug_get_bool_option("RADEON_VA", FALSE)) ws->info.r600_virtual_address = FALSE; } /* Get max pipes, this is only needed for compute shaders. All evergreen+ * chips have at least 2 pipes, so we use 2 as a default. */ ws->info.r600_max_pipes = 2; radeon_get_drm_value(ws->fd, RADEON_INFO_MAX_PIPES, NULL, &ws->info.r600_max_pipes); /* All GPUs have at least one compute unit */ ws->info.num_good_compute_units = 1; radeon_get_drm_value(ws->fd, RADEON_INFO_ACTIVE_CU_COUNT, NULL, &ws->info.num_good_compute_units); radeon_get_drm_value(ws->fd, RADEON_INFO_MAX_SE, NULL, &ws->info.max_se); if (!ws->info.max_se) { switch (ws->info.family) { default: ws->info.max_se = 1; break; case CHIP_CYPRESS: case CHIP_HEMLOCK: case CHIP_BARTS: case CHIP_CAYMAN: case CHIP_TAHITI: case CHIP_PITCAIRN: case CHIP_BONAIRE: ws->info.max_se = 2; break; case CHIP_HAWAII: ws->info.max_se = 4; break; } } radeon_get_drm_value(ws->fd, RADEON_INFO_MAX_SH_PER_SE, NULL, &ws->info.max_sh_per_se); radeon_get_drm_value(ws->fd, RADEON_INFO_ACCEL_WORKING2, NULL, &ws->accel_working2); if (ws->info.family == CHIP_HAWAII && ws->accel_working2 < 2) { fprintf(stderr, "radeon: GPU acceleration for Hawaii disabled, " "returned accel_working2 value %u is smaller than 2. " "Please install a newer kernel.\n", ws->accel_working2); return FALSE; } if (radeon_get_drm_value(ws->fd, RADEON_INFO_SI_TILE_MODE_ARRAY, NULL, ws->info.si_tile_mode_array)) { ws->info.si_tile_mode_array_valid = TRUE; } if (radeon_get_drm_value(ws->fd, RADEON_INFO_CIK_MACROTILE_MODE_ARRAY, NULL, ws->info.cik_macrotile_mode_array)) { ws->info.cik_macrotile_mode_array_valid = TRUE; } /* Hawaii with old firmware needs type2 nop packet. * accel_working2 with value 3 indicates the new firmware. */ ws->info.gfx_ib_pad_with_type2 = ws->info.chip_class <= SI || (ws->info.family == CHIP_HAWAII && ws->accel_working2 < 3); return TRUE; } static void radeon_winsys_destroy(struct radeon_winsys *rws) { struct radeon_drm_winsys *ws = (struct radeon_drm_winsys*)rws; if (ws->thread) { ws->kill_thread = 1; pipe_semaphore_signal(&ws->cs_queued); pipe_thread_wait(ws->thread); } pipe_semaphore_destroy(&ws->cs_queued); pipe_mutex_destroy(ws->hyperz_owner_mutex); pipe_mutex_destroy(ws->cmask_owner_mutex); pipe_mutex_destroy(ws->cs_stack_lock); pb_cache_deinit(&ws->bo_cache); if (ws->gen >= DRV_R600) { radeon_surface_manager_free(ws->surf_man); } util_hash_table_destroy(ws->bo_names); util_hash_table_destroy(ws->bo_handles); util_hash_table_destroy(ws->bo_vas); pipe_mutex_destroy(ws->bo_handles_mutex); pipe_mutex_destroy(ws->bo_va_mutex); if (ws->fd >= 0) close(ws->fd); FREE(rws); } static void radeon_query_info(struct radeon_winsys *rws, struct radeon_info *info) { *info = ((struct radeon_drm_winsys *)rws)->info; } static boolean radeon_cs_request_feature(struct radeon_winsys_cs *rcs, enum radeon_feature_id fid, boolean enable) { struct radeon_drm_cs *cs = radeon_drm_cs(rcs); switch (fid) { case RADEON_FID_R300_HYPERZ_ACCESS: return radeon_set_fd_access(cs, &cs->ws->hyperz_owner, &cs->ws->hyperz_owner_mutex, RADEON_INFO_WANT_HYPERZ, "Hyper-Z", enable); case RADEON_FID_R300_CMASK_ACCESS: return radeon_set_fd_access(cs, &cs->ws->cmask_owner, &cs->ws->cmask_owner_mutex, RADEON_INFO_WANT_CMASK, "AA optimizations", enable); } return FALSE; } static uint64_t radeon_query_value(struct radeon_winsys *rws, enum radeon_value_id value) { struct radeon_drm_winsys *ws = (struct radeon_drm_winsys*)rws; uint64_t retval = 0; switch (value) { case RADEON_REQUESTED_VRAM_MEMORY: return ws->allocated_vram; case RADEON_REQUESTED_GTT_MEMORY: return ws->allocated_gtt; case RADEON_BUFFER_WAIT_TIME_NS: return ws->buffer_wait_time; case RADEON_TIMESTAMP: if (ws->info.drm_minor < 20 || ws->gen < DRV_R600) { assert(0); return 0; } radeon_get_drm_value(ws->fd, RADEON_INFO_TIMESTAMP, "timestamp", (uint32_t*)&retval); return retval; case RADEON_NUM_CS_FLUSHES: return ws->num_cs_flushes; case RADEON_NUM_BYTES_MOVED: radeon_get_drm_value(ws->fd, RADEON_INFO_NUM_BYTES_MOVED, "num-bytes-moved", (uint32_t*)&retval); return retval; case RADEON_VRAM_USAGE: radeon_get_drm_value(ws->fd, RADEON_INFO_VRAM_USAGE, "vram-usage", (uint32_t*)&retval); return retval; case RADEON_GTT_USAGE: radeon_get_drm_value(ws->fd, RADEON_INFO_GTT_USAGE, "gtt-usage", (uint32_t*)&retval); return retval; case RADEON_GPU_TEMPERATURE: radeon_get_drm_value(ws->fd, RADEON_INFO_CURRENT_GPU_TEMP, "gpu-temp", (uint32_t*)&retval); return retval; case RADEON_CURRENT_SCLK: radeon_get_drm_value(ws->fd, RADEON_INFO_CURRENT_GPU_SCLK, "current-gpu-sclk", (uint32_t*)&retval); return retval; case RADEON_CURRENT_MCLK: radeon_get_drm_value(ws->fd, RADEON_INFO_CURRENT_GPU_MCLK, "current-gpu-mclk", (uint32_t*)&retval); return retval; case RADEON_GPU_RESET_COUNTER: radeon_get_drm_value(ws->fd, RADEON_INFO_GPU_RESET_COUNTER, "gpu-reset-counter", (uint32_t*)&retval); return retval; } return 0; } static bool radeon_read_registers(struct radeon_winsys *rws, unsigned reg_offset, unsigned num_registers, uint32_t *out) { struct radeon_drm_winsys *ws = (struct radeon_drm_winsys*)rws; unsigned i; for (i = 0; i < num_registers; i++) { uint32_t reg = reg_offset + i*4; if (!radeon_get_drm_value(ws->fd, RADEON_INFO_READ_REG, NULL, ®)) return false; out[i] = reg; } return true; } static unsigned hash_fd(void *key) { int fd = pointer_to_intptr(key); struct stat stat; fstat(fd, &stat); return stat.st_dev ^ stat.st_ino ^ stat.st_rdev; } static int compare_fd(void *key1, void *key2) { int fd1 = pointer_to_intptr(key1); int fd2 = pointer_to_intptr(key2); struct stat stat1, stat2; fstat(fd1, &stat1); fstat(fd2, &stat2); return stat1.st_dev != stat2.st_dev || stat1.st_ino != stat2.st_ino || stat1.st_rdev != stat2.st_rdev; } void radeon_drm_ws_queue_cs(struct radeon_drm_winsys *ws, struct radeon_drm_cs *cs) { retry: pipe_mutex_lock(ws->cs_stack_lock); if (ws->ncs >= RING_LAST) { /* no room left for a flush */ pipe_mutex_unlock(ws->cs_stack_lock); goto retry; } ws->cs_stack[ws->ncs++] = cs; pipe_mutex_unlock(ws->cs_stack_lock); pipe_semaphore_signal(&ws->cs_queued); } static PIPE_THREAD_ROUTINE(radeon_drm_cs_emit_ioctl, param) { struct radeon_drm_winsys *ws = (struct radeon_drm_winsys *)param; struct radeon_drm_cs *cs; unsigned i; while (1) { pipe_semaphore_wait(&ws->cs_queued); if (ws->kill_thread) break; pipe_mutex_lock(ws->cs_stack_lock); cs = ws->cs_stack[0]; for (i = 1; i < ws->ncs; i++) ws->cs_stack[i - 1] = ws->cs_stack[i]; ws->cs_stack[--ws->ncs] = NULL; pipe_mutex_unlock(ws->cs_stack_lock); if (cs) { radeon_drm_cs_emit_ioctl_oneshot(cs, cs->cst); pipe_semaphore_signal(&cs->flush_completed); } } pipe_mutex_lock(ws->cs_stack_lock); for (i = 0; i < ws->ncs; i++) { pipe_semaphore_signal(&ws->cs_stack[i]->flush_completed); ws->cs_stack[i] = NULL; } ws->ncs = 0; pipe_mutex_unlock(ws->cs_stack_lock); return 0; } DEBUG_GET_ONCE_BOOL_OPTION(thread, "RADEON_THREAD", TRUE) static PIPE_THREAD_ROUTINE(radeon_drm_cs_emit_ioctl, param); static bool radeon_winsys_unref(struct radeon_winsys *ws) { struct radeon_drm_winsys *rws = (struct radeon_drm_winsys*)ws; bool destroy; /* When the reference counter drops to zero, remove the fd from the table. * This must happen while the mutex is locked, so that * radeon_drm_winsys_create in another thread doesn't get the winsys * from the table when the counter drops to 0. */ pipe_mutex_lock(fd_tab_mutex); destroy = pipe_reference(&rws->reference, NULL); if (destroy && fd_tab) util_hash_table_remove(fd_tab, intptr_to_pointer(rws->fd)); pipe_mutex_unlock(fd_tab_mutex); return destroy; } #define PTR_TO_UINT(x) ((unsigned)((intptr_t)(x))) static unsigned handle_hash(void *key) { return PTR_TO_UINT(key); } static int handle_compare(void *key1, void *key2) { return PTR_TO_UINT(key1) != PTR_TO_UINT(key2); } PUBLIC struct radeon_winsys * radeon_drm_winsys_create(int fd, radeon_screen_create_t screen_create) { struct radeon_drm_winsys *ws; pipe_mutex_lock(fd_tab_mutex); if (!fd_tab) { fd_tab = util_hash_table_create(hash_fd, compare_fd); } ws = util_hash_table_get(fd_tab, intptr_to_pointer(fd)); if (ws) { pipe_reference(NULL, &ws->reference); pipe_mutex_unlock(fd_tab_mutex); return &ws->base; } ws = CALLOC_STRUCT(radeon_drm_winsys); if (!ws) { pipe_mutex_unlock(fd_tab_mutex); return NULL; } ws->fd = dup(fd); if (!do_winsys_init(ws)) goto fail1; pb_cache_init(&ws->bo_cache, 500000, 2.0f, 0, MIN2(ws->info.vram_size, ws->info.gart_size), radeon_bo_destroy, radeon_bo_can_reclaim); if (ws->gen >= DRV_R600) { ws->surf_man = radeon_surface_manager_new(ws->fd); if (!ws->surf_man) goto fail; } /* init reference */ pipe_reference_init(&ws->reference, 1); /* Set functions. */ ws->base.unref = radeon_winsys_unref; ws->base.destroy = radeon_winsys_destroy; ws->base.query_info = radeon_query_info; ws->base.cs_request_feature = radeon_cs_request_feature; ws->base.query_value = radeon_query_value; ws->base.read_registers = radeon_read_registers; radeon_drm_bo_init_functions(ws); radeon_drm_cs_init_functions(ws); radeon_surface_init_functions(ws); pipe_mutex_init(ws->hyperz_owner_mutex); pipe_mutex_init(ws->cmask_owner_mutex); pipe_mutex_init(ws->cs_stack_lock); ws->bo_names = util_hash_table_create(handle_hash, handle_compare); ws->bo_handles = util_hash_table_create(handle_hash, handle_compare); ws->bo_vas = util_hash_table_create(handle_hash, handle_compare); pipe_mutex_init(ws->bo_handles_mutex); pipe_mutex_init(ws->bo_va_mutex); ws->va_offset = ws->va_start; list_inithead(&ws->va_holes); /* TTM aligns the BO size to the CPU page size */ ws->size_align = sysconf(_SC_PAGESIZE); ws->ncs = 0; pipe_semaphore_init(&ws->cs_queued, 0); if (ws->num_cpus > 1 && debug_get_option_thread()) ws->thread = pipe_thread_create(radeon_drm_cs_emit_ioctl, ws); /* Create the screen at the end. The winsys must be initialized * completely. * * Alternatively, we could create the screen based on "ws->gen" * and link all drivers into one binary blob. */ ws->base.screen = screen_create(&ws->base); if (!ws->base.screen) { radeon_winsys_destroy(&ws->base); pipe_mutex_unlock(fd_tab_mutex); return NULL; } util_hash_table_set(fd_tab, intptr_to_pointer(ws->fd), ws); /* We must unlock the mutex once the winsys is fully initialized, so that * other threads attempting to create the winsys from the same fd will * get a fully initialized winsys and not just half-way initialized. */ pipe_mutex_unlock(fd_tab_mutex); return &ws->base; fail: pb_cache_deinit(&ws->bo_cache); fail1: pipe_mutex_unlock(fd_tab_mutex); if (ws->surf_man) radeon_surface_manager_free(ws->surf_man); if (ws->fd >= 0) close(ws->fd); FREE(ws); return NULL; }