/* * Copyright 2011 Nouveau Project * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. * * Authors: Christoph Bumiller */ #define NVC0_PUSH_EXPLICIT_SPACE_CHECKING #include "nvc0/nvc0_context.h" #include "nv_object.xml.h" #include "nvc0/nve4_compute.xml.h" #include "nvc0/nvc0_compute.xml.h" #define NVC0_QUERY_STATE_READY 0 #define NVC0_QUERY_STATE_ACTIVE 1 #define NVC0_QUERY_STATE_ENDED 2 #define NVC0_QUERY_STATE_FLUSHED 3 struct nvc0_query { uint32_t *data; uint16_t type; uint16_t index; int8_t ctr[4]; uint32_t sequence; struct nouveau_bo *bo; uint32_t base; uint32_t offset; /* base + i * rotate */ uint8_t state; boolean is64bit; uint8_t rotate; int nesting; /* only used for occlusion queries */ union { struct nouveau_mm_allocation *mm; uint64_t value; } u; struct nouveau_fence *fence; }; #define NVC0_QUERY_ALLOC_SPACE 256 static void nvc0_mp_pm_query_begin(struct nvc0_context *, struct nvc0_query *); static void nvc0_mp_pm_query_end(struct nvc0_context *, struct nvc0_query *); static boolean nvc0_mp_pm_query_result(struct nvc0_context *, struct nvc0_query *, void *, boolean); static INLINE struct nvc0_query * nvc0_query(struct pipe_query *pipe) { return (struct nvc0_query *)pipe; } static boolean nvc0_query_allocate(struct nvc0_context *nvc0, struct nvc0_query *q, int size) { struct nvc0_screen *screen = nvc0->screen; int ret; if (q->bo) { nouveau_bo_ref(NULL, &q->bo); if (q->u.mm) { if (q->state == NVC0_QUERY_STATE_READY) nouveau_mm_free(q->u.mm); else nouveau_fence_work(screen->base.fence.current, nouveau_mm_free_work, q->u.mm); } } if (size) { q->u.mm = nouveau_mm_allocate(screen->base.mm_GART, size, &q->bo, &q->base); if (!q->bo) return FALSE; q->offset = q->base; ret = nouveau_bo_map(q->bo, 0, screen->base.client); if (ret) { nvc0_query_allocate(nvc0, q, 0); return FALSE; } q->data = (uint32_t *)((uint8_t *)q->bo->map + q->base); } return TRUE; } static void nvc0_query_destroy(struct pipe_context *pipe, struct pipe_query *pq) { nvc0_query_allocate(nvc0_context(pipe), nvc0_query(pq), 0); nouveau_fence_ref(NULL, &nvc0_query(pq)->fence); FREE(nvc0_query(pq)); } static struct pipe_query * nvc0_query_create(struct pipe_context *pipe, unsigned type, unsigned index) { struct nvc0_context *nvc0 = nvc0_context(pipe); struct nvc0_query *q; unsigned space = NVC0_QUERY_ALLOC_SPACE; q = CALLOC_STRUCT(nvc0_query); if (!q) return NULL; switch (type) { case PIPE_QUERY_OCCLUSION_COUNTER: case PIPE_QUERY_OCCLUSION_PREDICATE: q->rotate = 32; space = NVC0_QUERY_ALLOC_SPACE; break; case PIPE_QUERY_PIPELINE_STATISTICS: q->is64bit = TRUE; space = 512; break; case PIPE_QUERY_SO_STATISTICS: case PIPE_QUERY_SO_OVERFLOW_PREDICATE: q->is64bit = TRUE; space = 64; break; case PIPE_QUERY_PRIMITIVES_GENERATED: case PIPE_QUERY_PRIMITIVES_EMITTED: q->is64bit = TRUE; q->index = index; space = 32; break; case PIPE_QUERY_TIME_ELAPSED: case PIPE_QUERY_TIMESTAMP: case PIPE_QUERY_TIMESTAMP_DISJOINT: case PIPE_QUERY_GPU_FINISHED: space = 32; break; case NVC0_QUERY_TFB_BUFFER_OFFSET: space = 16; break; default: #ifdef NOUVEAU_ENABLE_DRIVER_STATISTICS if (type >= NVC0_QUERY_DRV_STAT(0) && type <= NVC0_QUERY_DRV_STAT_LAST) { space = 0; q->is64bit = true; q->index = type - NVC0_QUERY_DRV_STAT(0); break; } else #endif if (nvc0->screen->base.device->drm_version >= 0x01000101) { if (type >= NVE4_PM_QUERY(0) && type <= NVE4_PM_QUERY_LAST) { /* for each MP: * [00] = WS0.C0 * [04] = WS0.C1 * [08] = WS0.C2 * [0c] = WS0.C3 * [10] = WS1.C0 * [14] = WS1.C1 * [18] = WS1.C2 * [1c] = WS1.C3 * [20] = WS2.C0 * [24] = WS2.C1 * [28] = WS2.C2 * [2c] = WS2.C3 * [30] = WS3.C0 * [34] = WS3.C1 * [38] = WS3.C2 * [3c] = WS3.C3 * [40] = MP.C4 * [44] = MP.C5 * [48] = MP.C6 * [4c] = MP.C7 * [50] = WS0.sequence * [54] = WS1.sequence * [58] = WS2.sequence * [5c] = WS3.sequence */ space = (4 * 4 + 4 + 4) * nvc0->screen->mp_count * sizeof(uint32_t); break; } else if (type >= NVC0_PM_QUERY(0) && type <= NVC0_PM_QUERY_LAST) { /* for each MP: * [00] = MP.C0 * [04] = MP.C1 * [08] = MP.C2 * [0c] = MP.C3 * [10] = MP.C4 * [14] = MP.C5 * [18] = MP.C6 * [1c] = MP.C7 * [20] = MP.sequence */ space = (8 + 1) * nvc0->screen->mp_count * sizeof(uint32_t); break; } } debug_printf("invalid query type: %u\n", type); FREE(q); return NULL; } if (!nvc0_query_allocate(nvc0, q, space)) { FREE(q); return NULL; } q->type = type; if (q->rotate) { /* we advance before query_begin ! */ q->offset -= q->rotate; q->data -= q->rotate / sizeof(*q->data); } else if (!q->is64bit) q->data[0] = 0; /* initialize sequence */ return (struct pipe_query *)q; } static void nvc0_query_get(struct nouveau_pushbuf *push, struct nvc0_query *q, unsigned offset, uint32_t get) { offset += q->offset; PUSH_SPACE(push, 5); PUSH_REFN (push, q->bo, NOUVEAU_BO_GART | NOUVEAU_BO_WR); BEGIN_NVC0(push, NVC0_3D(QUERY_ADDRESS_HIGH), 4); PUSH_DATAh(push, q->bo->offset + offset); PUSH_DATA (push, q->bo->offset + offset); PUSH_DATA (push, q->sequence); PUSH_DATA (push, get); } static void nvc0_query_rotate(struct nvc0_context *nvc0, struct nvc0_query *q) { q->offset += q->rotate; q->data += q->rotate / sizeof(*q->data); if (q->offset - q->base == NVC0_QUERY_ALLOC_SPACE) nvc0_query_allocate(nvc0, q, NVC0_QUERY_ALLOC_SPACE); } static void nvc0_query_begin(struct pipe_context *pipe, struct pipe_query *pq) { struct nvc0_context *nvc0 = nvc0_context(pipe); struct nouveau_pushbuf *push = nvc0->base.pushbuf; struct nvc0_query *q = nvc0_query(pq); /* For occlusion queries we have to change the storage, because a previous * query might set the initial render conition to FALSE even *after* we re- * initialized it to TRUE. */ if (q->rotate) { nvc0_query_rotate(nvc0, q); /* XXX: can we do this with the GPU, and sync with respect to a previous * query ? */ q->data[0] = q->sequence; /* initialize sequence */ q->data[1] = 1; /* initial render condition = TRUE */ q->data[4] = q->sequence + 1; /* for comparison COND_MODE */ q->data[5] = 0; } q->sequence++; switch (q->type) { case PIPE_QUERY_OCCLUSION_COUNTER: case PIPE_QUERY_OCCLUSION_PREDICATE: q->nesting = nvc0->screen->num_occlusion_queries_active++; if (q->nesting) { nvc0_query_get(push, q, 0x10, 0x0100f002); } else { PUSH_SPACE(push, 3); BEGIN_NVC0(push, NVC0_3D(COUNTER_RESET), 1); PUSH_DATA (push, NVC0_3D_COUNTER_RESET_SAMPLECNT); IMMED_NVC0(push, NVC0_3D(SAMPLECNT_ENABLE), 1); } break; case PIPE_QUERY_PRIMITIVES_GENERATED: nvc0_query_get(push, q, 0x10, 0x09005002 | (q->index << 5)); break; case PIPE_QUERY_PRIMITIVES_EMITTED: nvc0_query_get(push, q, 0x10, 0x05805002 | (q->index << 5)); break; case PIPE_QUERY_SO_STATISTICS: nvc0_query_get(push, q, 0x20, 0x05805002 | (q->index << 5)); nvc0_query_get(push, q, 0x30, 0x06805002 | (q->index << 5)); break; case PIPE_QUERY_SO_OVERFLOW_PREDICATE: nvc0_query_get(push, q, 0x10, 0x03005002 | (q->index << 5)); break; case PIPE_QUERY_TIME_ELAPSED: nvc0_query_get(push, q, 0x10, 0x00005002); break; case PIPE_QUERY_PIPELINE_STATISTICS: nvc0_query_get(push, q, 0xc0 + 0x00, 0x00801002); /* VFETCH, VERTICES */ nvc0_query_get(push, q, 0xc0 + 0x10, 0x01801002); /* VFETCH, PRIMS */ nvc0_query_get(push, q, 0xc0 + 0x20, 0x02802002); /* VP, LAUNCHES */ nvc0_query_get(push, q, 0xc0 + 0x30, 0x03806002); /* GP, LAUNCHES */ nvc0_query_get(push, q, 0xc0 + 0x40, 0x04806002); /* GP, PRIMS_OUT */ nvc0_query_get(push, q, 0xc0 + 0x50, 0x07804002); /* RAST, PRIMS_IN */ nvc0_query_get(push, q, 0xc0 + 0x60, 0x08804002); /* RAST, PRIMS_OUT */ nvc0_query_get(push, q, 0xc0 + 0x70, 0x0980a002); /* ROP, PIXELS */ nvc0_query_get(push, q, 0xc0 + 0x80, 0x0d808002); /* TCP, LAUNCHES */ nvc0_query_get(push, q, 0xc0 + 0x90, 0x0e809002); /* TEP, LAUNCHES */ break; default: #ifdef NOUVEAU_ENABLE_DRIVER_STATISTICS if (q->type >= NVC0_QUERY_DRV_STAT(0) && q->type <= NVC0_QUERY_DRV_STAT_LAST) { if (q->index >= 5) q->u.value = nvc0->screen->base.stats.v[q->index]; else q->u.value = 0; } else #endif if ((q->type >= NVE4_PM_QUERY(0) && q->type <= NVE4_PM_QUERY_LAST) || (q->type >= NVC0_PM_QUERY(0) && q->type <= NVC0_PM_QUERY_LAST)) { nvc0_mp_pm_query_begin(nvc0, q); } break; } q->state = NVC0_QUERY_STATE_ACTIVE; } static void nvc0_query_end(struct pipe_context *pipe, struct pipe_query *pq) { struct nvc0_context *nvc0 = nvc0_context(pipe); struct nouveau_pushbuf *push = nvc0->base.pushbuf; struct nvc0_query *q = nvc0_query(pq); if (q->state != NVC0_QUERY_STATE_ACTIVE) { /* some queries don't require 'begin' to be called (e.g. GPU_FINISHED) */ if (q->rotate) nvc0_query_rotate(nvc0, q); q->sequence++; } q->state = NVC0_QUERY_STATE_ENDED; switch (q->type) { case PIPE_QUERY_OCCLUSION_COUNTER: case PIPE_QUERY_OCCLUSION_PREDICATE: nvc0_query_get(push, q, 0, 0x0100f002); if (--nvc0->screen->num_occlusion_queries_active == 0) { PUSH_SPACE(push, 1); IMMED_NVC0(push, NVC0_3D(SAMPLECNT_ENABLE), 0); } break; case PIPE_QUERY_PRIMITIVES_GENERATED: nvc0_query_get(push, q, 0, 0x09005002 | (q->index << 5)); break; case PIPE_QUERY_PRIMITIVES_EMITTED: nvc0_query_get(push, q, 0, 0x05805002 | (q->index << 5)); break; case PIPE_QUERY_SO_STATISTICS: nvc0_query_get(push, q, 0x00, 0x05805002 | (q->index << 5)); nvc0_query_get(push, q, 0x10, 0x06805002 | (q->index << 5)); break; case PIPE_QUERY_SO_OVERFLOW_PREDICATE: /* TODO: How do we sum over all streams for render condition ? */ /* PRIMS_DROPPED doesn't write sequence, use a ZERO query to sync on */ nvc0_query_get(push, q, 0x00, 0x03005002 | (q->index << 5)); nvc0_query_get(push, q, 0x20, 0x00005002); break; case PIPE_QUERY_TIMESTAMP: case PIPE_QUERY_TIME_ELAPSED: nvc0_query_get(push, q, 0, 0x00005002); break; case PIPE_QUERY_GPU_FINISHED: nvc0_query_get(push, q, 0, 0x1000f010); break; case PIPE_QUERY_PIPELINE_STATISTICS: nvc0_query_get(push, q, 0x00, 0x00801002); /* VFETCH, VERTICES */ nvc0_query_get(push, q, 0x10, 0x01801002); /* VFETCH, PRIMS */ nvc0_query_get(push, q, 0x20, 0x02802002); /* VP, LAUNCHES */ nvc0_query_get(push, q, 0x30, 0x03806002); /* GP, LAUNCHES */ nvc0_query_get(push, q, 0x40, 0x04806002); /* GP, PRIMS_OUT */ nvc0_query_get(push, q, 0x50, 0x07804002); /* RAST, PRIMS_IN */ nvc0_query_get(push, q, 0x60, 0x08804002); /* RAST, PRIMS_OUT */ nvc0_query_get(push, q, 0x70, 0x0980a002); /* ROP, PIXELS */ nvc0_query_get(push, q, 0x80, 0x0d808002); /* TCP, LAUNCHES */ nvc0_query_get(push, q, 0x90, 0x0e809002); /* TEP, LAUNCHES */ break; case NVC0_QUERY_TFB_BUFFER_OFFSET: /* indexed by TFB buffer instead of by vertex stream */ nvc0_query_get(push, q, 0x00, 0x0d005002 | (q->index << 5)); break; default: #ifdef NOUVEAU_ENABLE_DRIVER_STATISTICS if (q->type >= NVC0_QUERY_DRV_STAT(0) && q->type <= NVC0_QUERY_DRV_STAT_LAST) { q->u.value = nvc0->screen->base.stats.v[q->index] - q->u.value; return; } else #endif if ((q->type >= NVE4_PM_QUERY(0) && q->type <= NVE4_PM_QUERY_LAST) || (q->type >= NVC0_PM_QUERY(0) && q->type <= NVC0_PM_QUERY_LAST)) { nvc0_mp_pm_query_end(nvc0, q); } break; } if (q->is64bit) nouveau_fence_ref(nvc0->screen->base.fence.current, &q->fence); } static INLINE void nvc0_query_update(struct nouveau_client *cli, struct nvc0_query *q) { if (q->is64bit) { if (nouveau_fence_signalled(q->fence)) q->state = NVC0_QUERY_STATE_READY; } else { if (q->data[0] == q->sequence) q->state = NVC0_QUERY_STATE_READY; } } static boolean nvc0_query_result(struct pipe_context *pipe, struct pipe_query *pq, boolean wait, union pipe_query_result *result) { struct nvc0_context *nvc0 = nvc0_context(pipe); struct nvc0_query *q = nvc0_query(pq); uint64_t *res64 = (uint64_t*)result; uint32_t *res32 = (uint32_t*)result; boolean *res8 = (boolean*)result; uint64_t *data64 = (uint64_t *)q->data; unsigned i; #ifdef NOUVEAU_ENABLE_DRIVER_STATISTICS if (q->type >= NVC0_QUERY_DRV_STAT(0) && q->type <= NVC0_QUERY_DRV_STAT_LAST) { res64[0] = q->u.value; return TRUE; } else #endif if ((q->type >= NVE4_PM_QUERY(0) && q->type <= NVE4_PM_QUERY_LAST) || (q->type >= NVC0_PM_QUERY(0) && q->type <= NVC0_PM_QUERY_LAST)) { return nvc0_mp_pm_query_result(nvc0, q, result, wait); } if (q->state != NVC0_QUERY_STATE_READY) nvc0_query_update(nvc0->screen->base.client, q); if (q->state != NVC0_QUERY_STATE_READY) { if (!wait) { if (q->state != NVC0_QUERY_STATE_FLUSHED) { q->state = NVC0_QUERY_STATE_FLUSHED; /* flush for silly apps that spin on GL_QUERY_RESULT_AVAILABLE */ PUSH_KICK(nvc0->base.pushbuf); } return FALSE; } if (nouveau_bo_wait(q->bo, NOUVEAU_BO_RD, nvc0->screen->base.client)) return FALSE; NOUVEAU_DRV_STAT(&nvc0->screen->base, query_sync_count, 1); } q->state = NVC0_QUERY_STATE_READY; switch (q->type) { case PIPE_QUERY_GPU_FINISHED: res8[0] = TRUE; break; case PIPE_QUERY_OCCLUSION_COUNTER: /* u32 sequence, u32 count, u64 time */ res64[0] = q->data[1] - q->data[5]; break; case PIPE_QUERY_OCCLUSION_PREDICATE: res8[0] = q->data[1] != q->data[5]; break; case PIPE_QUERY_PRIMITIVES_GENERATED: /* u64 count, u64 time */ case PIPE_QUERY_PRIMITIVES_EMITTED: /* u64 count, u64 time */ res64[0] = data64[0] - data64[2]; break; case PIPE_QUERY_SO_STATISTICS: res64[0] = data64[0] - data64[4]; res64[1] = data64[2] - data64[6]; break; case PIPE_QUERY_SO_OVERFLOW_PREDICATE: res8[0] = data64[0] != data64[2]; break; case PIPE_QUERY_TIMESTAMP: res64[0] = data64[1]; break; case PIPE_QUERY_TIMESTAMP_DISJOINT: res64[0] = 1000000000; res8[8] = FALSE; break; case PIPE_QUERY_TIME_ELAPSED: res64[0] = data64[1] - data64[3]; break; case PIPE_QUERY_PIPELINE_STATISTICS: for (i = 0; i < 10; ++i) res64[i] = data64[i * 2] - data64[24 + i * 2]; break; case NVC0_QUERY_TFB_BUFFER_OFFSET: res32[0] = q->data[1]; break; default: assert(0); /* can't happen, we don't create queries with invalid type */ return FALSE; } return TRUE; } void nvc0_query_fifo_wait(struct nouveau_pushbuf *push, struct pipe_query *pq) { struct nvc0_query *q = nvc0_query(pq); unsigned offset = q->offset; if (q->type == PIPE_QUERY_SO_OVERFLOW_PREDICATE) offset += 0x20; PUSH_SPACE(push, 5); PUSH_REFN (push, q->bo, NOUVEAU_BO_GART | NOUVEAU_BO_RD); BEGIN_NVC0(push, SUBC_3D(NV84_SUBCHAN_SEMAPHORE_ADDRESS_HIGH), 4); PUSH_DATAh(push, q->bo->offset + offset); PUSH_DATA (push, q->bo->offset + offset); PUSH_DATA (push, q->sequence); PUSH_DATA (push, (1 << 12) | NV84_SUBCHAN_SEMAPHORE_TRIGGER_ACQUIRE_EQUAL); } static void nvc0_render_condition(struct pipe_context *pipe, struct pipe_query *pq, boolean condition, uint mode) { struct nvc0_context *nvc0 = nvc0_context(pipe); struct nouveau_pushbuf *push = nvc0->base.pushbuf; struct nvc0_query *q; uint32_t cond; boolean wait = mode != PIPE_RENDER_COND_NO_WAIT && mode != PIPE_RENDER_COND_BY_REGION_NO_WAIT; if (!pq) { cond = NVC0_3D_COND_MODE_ALWAYS; } else { q = nvc0_query(pq); /* NOTE: comparison of 2 queries only works if both have completed */ switch (q->type) { case PIPE_QUERY_SO_OVERFLOW_PREDICATE: cond = condition ? NVC0_3D_COND_MODE_EQUAL : NVC0_3D_COND_MODE_NOT_EQUAL; wait = TRUE; break; case PIPE_QUERY_OCCLUSION_COUNTER: case PIPE_QUERY_OCCLUSION_PREDICATE: if (likely(!condition)) { if (unlikely(q->nesting)) cond = wait ? NVC0_3D_COND_MODE_NOT_EQUAL : NVC0_3D_COND_MODE_ALWAYS; else cond = NVC0_3D_COND_MODE_RES_NON_ZERO; } else { cond = wait ? NVC0_3D_COND_MODE_EQUAL : NVC0_3D_COND_MODE_ALWAYS; } break; default: assert(!"render condition query not a predicate"); cond = NVC0_3D_COND_MODE_ALWAYS; break; } } nvc0->cond_query = pq; nvc0->cond_cond = condition; nvc0->cond_condmode = cond; nvc0->cond_mode = mode; if (!pq) { PUSH_SPACE(push, 1); IMMED_NVC0(push, NVC0_3D(COND_MODE), cond); return; } if (wait) nvc0_query_fifo_wait(push, pq); PUSH_SPACE(push, 7); PUSH_REFN (push, q->bo, NOUVEAU_BO_GART | NOUVEAU_BO_RD); BEGIN_NVC0(push, NVC0_3D(COND_ADDRESS_HIGH), 3); PUSH_DATAh(push, q->bo->offset + q->offset); PUSH_DATA (push, q->bo->offset + q->offset); PUSH_DATA (push, cond); BEGIN_NVC0(push, NVC0_2D(COND_ADDRESS_HIGH), 2); PUSH_DATAh(push, q->bo->offset + q->offset); PUSH_DATA (push, q->bo->offset + q->offset); } void nvc0_query_pushbuf_submit(struct nouveau_pushbuf *push, struct pipe_query *pq, unsigned result_offset) { struct nvc0_query *q = nvc0_query(pq); #define NVC0_IB_ENTRY_1_NO_PREFETCH (1 << (31 - 8)) nouveau_pushbuf_space(push, 0, 0, 1); nouveau_pushbuf_data(push, q->bo, q->offset + result_offset, 4 | NVC0_IB_ENTRY_1_NO_PREFETCH); } void nvc0_so_target_save_offset(struct pipe_context *pipe, struct pipe_stream_output_target *ptarg, unsigned index, boolean *serialize) { struct nvc0_so_target *targ = nvc0_so_target(ptarg); if (*serialize) { *serialize = FALSE; PUSH_SPACE(nvc0_context(pipe)->base.pushbuf, 1); IMMED_NVC0(nvc0_context(pipe)->base.pushbuf, NVC0_3D(SERIALIZE), 0); NOUVEAU_DRV_STAT(nouveau_screen(pipe->screen), gpu_serialize_count, 1); } nvc0_query(targ->pq)->index = index; nvc0_query_end(pipe, targ->pq); } /* === DRIVER STATISTICS === */ #ifdef NOUVEAU_ENABLE_DRIVER_STATISTICS static const char *nvc0_drv_stat_names[] = { "drv-tex_obj_current_count", "drv-tex_obj_current_bytes", "drv-buf_obj_current_count", "drv-buf_obj_current_bytes_vid", "drv-buf_obj_current_bytes_sys", "drv-tex_transfers_rd", "drv-tex_transfers_wr", "drv-tex_copy_count", "drv-tex_blit_count", "drv-tex_cache_flush_count", "drv-buf_transfers_rd", "drv-buf_transfers_wr", "drv-buf_read_bytes_staging_vid", "drv-buf_write_bytes_direct", "drv-buf_write_bytes_staging_vid", "drv-buf_write_bytes_staging_sys", "drv-buf_copy_bytes", "drv-buf_non_kernel_fence_sync_count", "drv-any_non_kernel_fence_sync_count", "drv-query_sync_count", "drv-gpu_serialize_count", "drv-draw_calls_array", "drv-draw_calls_indexed", "drv-draw_calls_fallback_count", "drv-user_buffer_upload_bytes", "drv-constbuf_upload_count", "drv-constbuf_upload_bytes", "drv-pushbuf_count", "drv-resource_validate_count" }; #endif /* NOUVEAU_ENABLE_DRIVER_STATISTICS */ /* === PERFORMANCE MONITORING COUNTERS for NVE4+ === */ /* Code to read out MP counters: They are accessible via mmio, too, but let's * just avoid mapping registers in userspace. We'd have to know which MPs are * enabled/present, too, and that information is not presently exposed. * We could add a kernel interface for it, but reading the counters like this * has the advantage of being async (if get_result isn't called immediately). */ static const uint64_t nve4_read_mp_pm_counters_code[] = { /* sched 0x20 0x20 0x20 0x20 0x20 0x20 0x20 * mov b32 $r8 $tidx * mov b32 $r12 $physid * mov b32 $r0 $pm0 * mov b32 $r1 $pm1 * mov b32 $r2 $pm2 * mov b32 $r3 $pm3 * mov b32 $r4 $pm4 * sched 0x20 0x20 0x23 0x04 0x20 0x04 0x2b * mov b32 $r5 $pm5 * mov b32 $r6 $pm6 * mov b32 $r7 $pm7 * set $p0 0x1 eq u32 $r8 0x0 * mov b32 $r10 c0[0x0] * ext u32 $r8 $r12 0x414 * mov b32 $r11 c0[0x4] * sched 0x04 0x2e 0x04 0x20 0x20 0x28 0x04 * ext u32 $r9 $r12 0x208 * (not $p0) exit * set $p1 0x1 eq u32 $r9 0x0 * mul $r8 u32 $r8 u32 96 * mul $r12 u32 $r9 u32 16 * mul $r13 u32 $r9 u32 4 * add b32 $r9 $r8 $r13 * sched 0x28 0x04 0x2c 0x04 0x2c 0x04 0x2c * add b32 $r8 $r8 $r12 * mov b32 $r12 $r10 * add b32 $r10 $c $r10 $r8 * mov b32 $r13 $r11 * add b32 $r11 $r11 0x0 $c * add b32 $r12 $c $r12 $r9 * st b128 wt g[$r10d] $r0q * sched 0x4 0x2c 0x20 0x04 0x2e 0x00 0x00 * mov b32 $r0 c0[0x8] * add b32 $r13 $r13 0x0 $c * $p1 st b128 wt g[$r12d+0x40] $r4q * st b32 wt g[$r12d+0x50] $r0 * exit */ 0x2202020202020207ULL, 0x2c00000084021c04ULL, 0x2c0000000c031c04ULL, 0x2c00000010001c04ULL, 0x2c00000014005c04ULL, 0x2c00000018009c04ULL, 0x2c0000001c00dc04ULL, 0x2c00000020011c04ULL, 0x22b0420042320207ULL, 0x2c00000024015c04ULL, 0x2c00000028019c04ULL, 0x2c0000002c01dc04ULL, 0x190e0000fc81dc03ULL, 0x2800400000029de4ULL, 0x7000c01050c21c03ULL, 0x280040001002dde4ULL, 0x204282020042e047ULL, 0x7000c00820c25c03ULL, 0x80000000000021e7ULL, 0x190e0000fc93dc03ULL, 0x1000000180821c02ULL, 0x1000000040931c02ULL, 0x1000000010935c02ULL, 0x4800000034825c03ULL, 0x22c042c042c04287ULL, 0x4800000030821c03ULL, 0x2800000028031de4ULL, 0x4801000020a29c03ULL, 0x280000002c035de4ULL, 0x0800000000b2dc42ULL, 0x4801000024c31c03ULL, 0x9400000000a01fc5ULL, 0x200002e04202c047ULL, 0x2800400020001de4ULL, 0x0800000000d35c42ULL, 0x9400000100c107c5ULL, 0x9400000140c01f85ULL, 0x8000000000001de7ULL }; /* NOTE: intentionally using the same names as NV */ static const char *nve4_pm_query_names[] = { /* MP counters */ "prof_trigger_00", "prof_trigger_01", "prof_trigger_02", "prof_trigger_03", "prof_trigger_04", "prof_trigger_05", "prof_trigger_06", "prof_trigger_07", "warps_launched", "threads_launched", "sm_cta_launched", "inst_issued1", "inst_issued2", "inst_executed", "local_load", "local_store", "shared_load", "shared_store", "l1_local_load_hit", "l1_local_load_miss", "l1_local_store_hit", "l1_local_store_miss", "gld_request", "gst_request", "l1_global_load_hit", "l1_global_load_miss", "uncached_global_load_transaction", "global_store_transaction", "branch", "divergent_branch", "active_warps", "active_cycles", "inst_issued", "atom_count", "gred_count", "shared_load_replay", "shared_store_replay", "local_load_transactions", "local_store_transactions", "l1_shared_load_transactions", "l1_shared_store_transactions", "global_ld_mem_divergence_replays", "global_st_mem_divergence_replays", /* metrics, i.e. functions of the MP counters */ "metric-ipc", /* inst_executed, clock */ "metric-ipac", /* inst_executed, active_cycles */ "metric-ipec", /* inst_executed, (bool)inst_executed */ "metric-achieved_occupancy", /* active_warps, active_cycles */ "metric-sm_efficiency", /* active_cycles, clock */ "metric-inst_replay_overhead" /* inst_issued, inst_executed */ }; /* For simplicity, we will allocate as many group slots as we allocate counter * slots. This means that a single counter which wants to source from 2 groups * will have to be declared as using 2 counter slots. This shouldn't really be * a problem because such queries don't make much sense ... (unless someone is * really creative). */ struct nvc0_mp_counter_cfg { uint32_t func : 16; /* mask or 4-bit logic op (depending on mode) */ uint32_t mode : 4; /* LOGOP,B6,LOGOP_B6(_PULSE) */ uint32_t num_src : 3; /* number of sources (1 - 6, only for NVC0:NVE4) */ uint32_t sig_dom : 1; /* if 0, MP_PM_A (per warp-sched), if 1, MP_PM_B */ uint32_t sig_sel : 8; /* signal group */ uint64_t src_sel; /* signal selection for up to 6 sources (48 bit) */ }; #define NVC0_COUNTER_OPn_SUM 0 #define NVC0_COUNTER_OPn_OR 1 #define NVC0_COUNTER_OPn_AND 2 #define NVC0_COUNTER_OP2_REL_SUM_MM 3 /* (sum(ctr0) - sum(ctr1)) / sum(ctr0) */ #define NVC0_COUNTER_OP2_DIV_SUM_M0 4 /* sum(ctr0) / ctr1 of MP[0]) */ #define NVC0_COUNTER_OP2_AVG_DIV_MM 5 /* avg(ctr0 / ctr1) */ #define NVC0_COUNTER_OP2_AVG_DIV_M0 6 /* avg(ctr0) / ctr1 of MP[0]) */ struct nvc0_mp_pm_query_cfg { struct nvc0_mp_counter_cfg ctr[4]; uint8_t num_counters; uint8_t op; uint8_t norm[2]; /* normalization num,denom */ }; #define _Q1A(n, f, m, g, s, nu, dn) [NVE4_PM_QUERY_##n] = { { { f, NVE4_COMPUTE_MP_PM_FUNC_MODE_##m, 0, 0, NVE4_COMPUTE_MP_PM_A_SIGSEL_##g, s }, {}, {}, {} }, 1, NVC0_COUNTER_OPn_SUM, { nu, dn } } #define _Q1B(n, f, m, g, s, nu, dn) [NVE4_PM_QUERY_##n] = { { { f, NVE4_COMPUTE_MP_PM_FUNC_MODE_##m, 0, 1, NVE4_COMPUTE_MP_PM_B_SIGSEL_##g, s }, {}, {}, {} }, 1, NVC0_COUNTER_OPn_SUM, { nu, dn } } #define _M2A(n, f0, m0, g0, s0, f1, m1, g1, s1, o, nu, dn) [NVE4_PM_QUERY_METRIC_##n] = { { \ { f0, NVE4_COMPUTE_MP_PM_FUNC_MODE_##m0, 0, 0, NVE4_COMPUTE_MP_PM_A_SIGSEL_##g0, s0 }, \ { f1, NVE4_COMPUTE_MP_PM_FUNC_MODE_##m1, 0, 0, NVE4_COMPUTE_MP_PM_A_SIGSEL_##g1, s1 }, \ {}, {}, }, 2, NVC0_COUNTER_OP2_##o, { nu, dn } } #define _M2B(n, f0, m0, g0, s0, f1, m1, g1, s1, o, nu, dn) [NVE4_PM_QUERY_METRIC_##n] = { { \ { f0, NVE4_COMPUTE_MP_PM_FUNC_MODE_##m0, 0, 1, NVE4_COMPUTE_MP_PM_B_SIGSEL_##g0, s0 }, \ { f1, NVE4_COMPUTE_MP_PM_FUNC_MODE_##m1, 0, 1, NVE4_COMPUTE_MP_PM_B_SIGSEL_##g1, s1 }, \ {}, {}, }, 2, NVC0_COUNTER_OP2_##o, { nu, dn } } #define _M2AB(n, f0, m0, g0, s0, f1, m1, g1, s1, o, nu, dn) [NVE4_PM_QUERY_METRIC_##n] = { { \ { f0, NVE4_COMPUTE_MP_PM_FUNC_MODE_##m0, 0, 0, NVE4_COMPUTE_MP_PM_A_SIGSEL_##g0, s0 }, \ { f1, NVE4_COMPUTE_MP_PM_FUNC_MODE_##m1, 0, 1, NVE4_COMPUTE_MP_PM_B_SIGSEL_##g1, s1 }, \ {}, {}, }, 2, NVC0_COUNTER_OP2_##o, { nu, dn } } /* NOTES: * active_warps: bit 0 alternates btw 0 and 1 for odd nr of warps * inst_executed etc.: we only count a single warp scheduler * metric-ipXc: we simply multiply by 4 to account for the 4 warp schedulers; * this is inaccurate ! */ static const struct nvc0_mp_pm_query_cfg nve4_mp_pm_queries[] = { _Q1A(PROF_TRIGGER_0, 0x0001, B6, USER, 0x00000000, 1, 1), _Q1A(PROF_TRIGGER_1, 0x0001, B6, USER, 0x00000004, 1, 1), _Q1A(PROF_TRIGGER_2, 0x0001, B6, USER, 0x00000008, 1, 1), _Q1A(PROF_TRIGGER_3, 0x0001, B6, USER, 0x0000000c, 1, 1), _Q1A(PROF_TRIGGER_4, 0x0001, B6, USER, 0x00000010, 1, 1), _Q1A(PROF_TRIGGER_5, 0x0001, B6, USER, 0x00000014, 1, 1), _Q1A(PROF_TRIGGER_6, 0x0001, B6, USER, 0x00000018, 1, 1), _Q1A(PROF_TRIGGER_7, 0x0001, B6, USER, 0x0000001c, 1, 1), _Q1A(LAUNCHED_WARPS, 0x0001, B6, LAUNCH, 0x00000004, 1, 1), _Q1A(LAUNCHED_THREADS, 0x003f, B6, LAUNCH, 0x398a4188, 1, 1), _Q1B(LAUNCHED_CTA, 0x0001, B6, WARP, 0x0000001c, 1, 1), _Q1A(INST_ISSUED1, 0x0001, B6, ISSUE, 0x00000004, 1, 1), _Q1A(INST_ISSUED2, 0x0001, B6, ISSUE, 0x00000008, 1, 1), _Q1A(INST_ISSUED, 0x0003, B6, ISSUE, 0x00000104, 1, 1), _Q1A(INST_EXECUTED, 0x0003, B6, EXEC, 0x00000398, 1, 1), _Q1A(LD_SHARED, 0x0001, B6, LDST, 0x00000000, 1, 1), _Q1A(ST_SHARED, 0x0001, B6, LDST, 0x00000004, 1, 1), _Q1A(LD_LOCAL, 0x0001, B6, LDST, 0x00000008, 1, 1), _Q1A(ST_LOCAL, 0x0001, B6, LDST, 0x0000000c, 1, 1), _Q1A(GLD_REQUEST, 0x0001, B6, LDST, 0x00000010, 1, 1), _Q1A(GST_REQUEST, 0x0001, B6, LDST, 0x00000014, 1, 1), _Q1B(L1_LOCAL_LOAD_HIT, 0x0001, B6, L1, 0x00000000, 1, 1), _Q1B(L1_LOCAL_LOAD_MISS, 0x0001, B6, L1, 0x00000004, 1, 1), _Q1B(L1_LOCAL_STORE_HIT, 0x0001, B6, L1, 0x00000008, 1, 1), _Q1B(L1_LOCAL_STORE_MISS, 0x0001, B6, L1, 0x0000000c, 1, 1), _Q1B(L1_GLOBAL_LOAD_HIT, 0x0001, B6, L1, 0x00000010, 1, 1), _Q1B(L1_GLOBAL_LOAD_MISS, 0x0001, B6, L1, 0x00000014, 1, 1), _Q1B(GLD_TRANSACTIONS_UNCACHED, 0x0001, B6, MEM, 0x00000000, 1, 1), _Q1B(GST_TRANSACTIONS, 0x0001, B6, MEM, 0x00000004, 1, 1), _Q1A(BRANCH, 0x0001, B6, BRANCH, 0x0000000c, 1, 1), _Q1A(BRANCH_DIVERGENT, 0x0001, B6, BRANCH, 0x00000010, 1, 1), _Q1B(ACTIVE_WARPS, 0x003f, B6, WARP, 0x31483104, 2, 1), _Q1B(ACTIVE_CYCLES, 0x0001, B6, WARP, 0x00000000, 1, 1), _Q1A(ATOM_COUNT, 0x0001, B6, BRANCH, 0x00000000, 1, 1), _Q1A(GRED_COUNT, 0x0001, B6, BRANCH, 0x00000008, 1, 1), _Q1B(LD_SHARED_REPLAY, 0x0001, B6, REPLAY, 0x00000008, 1, 1), _Q1B(ST_SHARED_REPLAY, 0x0001, B6, REPLAY, 0x0000000c, 1, 1), _Q1B(LD_LOCAL_TRANSACTIONS, 0x0001, B6, TRANSACTION, 0x00000000, 1, 1), _Q1B(ST_LOCAL_TRANSACTIONS, 0x0001, B6, TRANSACTION, 0x00000004, 1, 1), _Q1B(L1_LD_SHARED_TRANSACTIONS, 0x0001, B6, TRANSACTION, 0x00000008, 1, 1), _Q1B(L1_ST_SHARED_TRANSACTIONS, 0x0001, B6, TRANSACTION, 0x0000000c, 1, 1), _Q1B(GLD_MEM_DIV_REPLAY, 0x0001, B6, REPLAY, 0x00000010, 1, 1), _Q1B(GST_MEM_DIV_REPLAY, 0x0001, B6, REPLAY, 0x00000014, 1, 1), _M2AB(IPC, 0x3, B6, EXEC, 0x398, 0xffff, LOGOP, WARP, 0x0, DIV_SUM_M0, 10, 1), _M2AB(IPAC, 0x3, B6, EXEC, 0x398, 0x1, B6, WARP, 0x0, AVG_DIV_MM, 10, 1), _M2A(IPEC, 0x3, B6, EXEC, 0x398, 0xe, LOGOP, EXEC, 0x398, AVG_DIV_MM, 10, 1), _M2A(INST_REPLAY_OHEAD, 0x3, B6, ISSUE, 0x104, 0x3, B6, EXEC, 0x398, REL_SUM_MM, 100, 1), _M2B(MP_OCCUPANCY, 0x3f, B6, WARP, 0x31483104, 0x01, B6, WARP, 0x0, AVG_DIV_MM, 200, 64), _M2B(MP_EFFICIENCY, 0x01, B6, WARP, 0x0, 0xffff, LOGOP, WARP, 0x0, AVG_DIV_M0, 100, 1), }; #undef _Q1A #undef _Q1B #undef _M2A #undef _M2B /* === PERFORMANCE MONITORING COUNTERS for NVC0:NVE4 === */ static const uint64_t nvc0_read_mp_pm_counters_code[] = { /* mov b32 $r8 $tidx * mov b32 $r9 $physid * mov b32 $r0 $pm0 * mov b32 $r1 $pm1 * mov b32 $r2 $pm2 * mov b32 $r3 $pm3 * mov b32 $r4 $pm4 * mov b32 $r5 $pm5 * mov b32 $r6 $pm6 * mov b32 $r7 $pm7 * set $p0 0x1 eq u32 $r8 0x0 * mov b32 $r10 c0[0x0] * mov b32 $r11 c0[0x4] * ext u32 $r8 $r9 0x414 * (not $p0) exit * mul $r8 u32 $r8 u32 36 * add b32 $r10 $c $r10 $r8 * add b32 $r11 $r11 0x0 $c * mov b32 $r8 c0[0x8] * st b128 wt g[$r10d+0x00] $r0q * st b128 wt g[$r10d+0x10] $r4q * st b32 wt g[$r10d+0x20] $r8 * exit */ 0x2c00000084021c04ULL, 0x2c0000000c025c04ULL, 0x2c00000010001c04ULL, 0x2c00000014005c04ULL, 0x2c00000018009c04ULL, 0x2c0000001c00dc04ULL, 0x2c00000020011c04ULL, 0x2c00000024015c04ULL, 0x2c00000028019c04ULL, 0x2c0000002c01dc04ULL, 0x190e0000fc81dc03ULL, 0x2800400000029de4ULL, 0x280040001002dde4ULL, 0x7000c01050921c03ULL, 0x80000000000021e7ULL, 0x1000000090821c02ULL, 0x4801000020a29c03ULL, 0x0800000000b2dc42ULL, 0x2800400020021de4ULL, 0x9400000000a01fc5ULL, 0x9400000040a11fc5ULL, 0x9400000080a21f85ULL, 0x8000000000001de7ULL }; static const char *nvc0_pm_query_names[] = { /* MP counters */ "inst_executed", "branch", "divergent_branch", "active_warps", "active_cycles", "warps_launched", "threads_launched", "shared_load", "shared_store", "local_load", "local_store", "gred_count", "atom_count", "gld_request", "gst_request", "inst_issued1_0", "inst_issued1_1", "inst_issued2_0", "inst_issued2_1", "thread_inst_executed_0", "thread_inst_executed_1", "thread_inst_executed_2", "thread_inst_executed_3", "prof_trigger_00", "prof_trigger_01", "prof_trigger_02", "prof_trigger_03", "prof_trigger_04", "prof_trigger_05", "prof_trigger_06", "prof_trigger_07", }; #define _Q(n, f, m, g, c, s0, s1, s2, s3, s4, s5) [NVC0_PM_QUERY_##n] = { { { f, NVC0_COMPUTE_MP_PM_OP_MODE_##m, c, 0, g, s0|(s1 << 8)|(s2 << 16)|(s3 << 24)|(s4##ULL << 32)|(s5##ULL << 40) }, {}, {}, {} }, 1, NVC0_COUNTER_OPn_SUM, { 1, 1 } } static const struct nvc0_mp_pm_query_cfg nvc0_mp_pm_queries[] = { _Q(INST_EXECUTED, 0xaaaa, LOGOP, 0x2d, 3, 0x00, 0x11, 0x22, 0x00, 0x00, 0x00), _Q(BRANCH, 0xaaaa, LOGOP, 0x1a, 2, 0x00, 0x11, 0x00, 0x00, 0x00, 0x00), _Q(BRANCH_DIVERGENT, 0xaaaa, LOGOP, 0x19, 2, 0x20, 0x31, 0x00, 0x00, 0x00, 0x00), _Q(ACTIVE_WARPS, 0xaaaa, LOGOP, 0x24, 6, 0x10, 0x21, 0x32, 0x43, 0x54, 0x65), _Q(ACTIVE_CYCLES, 0xaaaa, LOGOP, 0x11, 1, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(LAUNCHED_WARPS, 0xaaaa, LOGOP, 0x26, 1, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(LAUNCHED_THREADS, 0xaaaa, LOGOP, 0x26, 6, 0x10, 0x21, 0x32, 0x43, 0x54, 0x65), _Q(LD_SHARED, 0xaaaa, LOGOP, 0x64, 1, 0x10, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(ST_SHARED, 0xaaaa, LOGOP, 0x64, 1, 0x40, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(LD_LOCAL, 0xaaaa, LOGOP, 0x64, 1, 0x20, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(ST_LOCAL, 0xaaaa, LOGOP, 0x64, 1, 0x50, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(GRED_COUNT, 0xaaaa, LOGOP, 0x63, 1, 0x40, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(ATOM_COUNT, 0xaaaa, LOGOP, 0x63, 1, 0x30, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(GLD_REQUEST, 0xaaaa, LOGOP, 0x64, 1, 0x30, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(GST_REQUEST, 0xaaaa, LOGOP, 0x64, 1, 0x60, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(INST_ISSUED1_0, 0xaaaa, LOGOP, 0x7e, 1, 0x10, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(INST_ISSUED1_1, 0xaaaa, LOGOP, 0x7e, 1, 0x40, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(INST_ISSUED2_0, 0xaaaa, LOGOP, 0x7e, 1, 0x20, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(INST_ISSUED2_1, 0xaaaa, LOGOP, 0x7e, 1, 0x50, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(TH_INST_EXECUTED_0, 0xaaaa, LOGOP, 0xa3, 6, 0x00, 0x11, 0x22, 0x33, 0x44, 0x55), _Q(TH_INST_EXECUTED_1, 0xaaaa, LOGOP, 0xa5, 6, 0x00, 0x11, 0x22, 0x33, 0x44, 0x55), _Q(TH_INST_EXECUTED_2, 0xaaaa, LOGOP, 0xa4, 6, 0x00, 0x11, 0x22, 0x33, 0x44, 0x55), _Q(TH_INST_EXECUTED_3, 0xaaaa, LOGOP, 0xa6, 6, 0x00, 0x11, 0x22, 0x33, 0x44, 0x55), _Q(PROF_TRIGGER_0, 0xaaaa, LOGOP, 0x01, 1, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(PROF_TRIGGER_1, 0xaaaa, LOGOP, 0x01, 1, 0x10, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(PROF_TRIGGER_2, 0xaaaa, LOGOP, 0x01, 1, 0x20, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(PROF_TRIGGER_3, 0xaaaa, LOGOP, 0x01, 1, 0x30, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(PROF_TRIGGER_4, 0xaaaa, LOGOP, 0x01, 1, 0x40, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(PROF_TRIGGER_5, 0xaaaa, LOGOP, 0x01, 1, 0x50, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(PROF_TRIGGER_6, 0xaaaa, LOGOP, 0x01, 1, 0x60, 0x00, 0x00, 0x00, 0x00, 0x00), _Q(PROF_TRIGGER_7, 0xaaaa, LOGOP, 0x01, 1, 0x70, 0x00, 0x00, 0x00, 0x00, 0x00), }; #undef _Q static const struct nvc0_mp_pm_query_cfg * nvc0_mp_pm_query_get_cfg(struct nvc0_context *nvc0, struct nvc0_query *q) { struct nvc0_screen *screen = nvc0->screen; if (screen->base.class_3d >= NVE4_3D_CLASS) return &nve4_mp_pm_queries[q->type - PIPE_QUERY_DRIVER_SPECIFIC]; return &nvc0_mp_pm_queries[q->type - NVC0_PM_QUERY(0)]; } void nvc0_mp_pm_query_begin(struct nvc0_context *nvc0, struct nvc0_query *q) { struct nvc0_screen *screen = nvc0->screen; struct nouveau_pushbuf *push = nvc0->base.pushbuf; const boolean is_nve4 = screen->base.class_3d >= NVE4_3D_CLASS; const struct nvc0_mp_pm_query_cfg *cfg; unsigned i, c; unsigned num_ab[2] = { 0, 0 }; cfg = nvc0_mp_pm_query_get_cfg(nvc0, q); /* check if we have enough free counter slots */ for (i = 0; i < cfg->num_counters; ++i) num_ab[cfg->ctr[i].sig_dom]++; if (screen->pm.num_mp_pm_active[0] + num_ab[0] > 4 || screen->pm.num_mp_pm_active[1] + num_ab[1] > 4) { NOUVEAU_ERR("Not enough free MP counter slots !\n"); return; } assert(cfg->num_counters <= 4); PUSH_SPACE(push, 4 * 8 * (is_nve4 ? 1 : 6) + 6); if (!screen->pm.mp_counters_enabled) { screen->pm.mp_counters_enabled = TRUE; BEGIN_NVC0(push, SUBC_SW(0x06ac), 1); PUSH_DATA (push, 0x1fcb); } /* set sequence field to 0 (used to check if result is available) */ for (i = 0; i < screen->mp_count; ++i) q->data[i * 10 + 10] = 0; for (i = 0; i < cfg->num_counters; ++i) { const unsigned d = cfg->ctr[i].sig_dom; if (!screen->pm.num_mp_pm_active[d]) { uint32_t m = (1 << 22) | (1 << (7 + (8 * !d))); if (screen->pm.num_mp_pm_active[!d]) m |= 1 << (7 + (8 * d)); BEGIN_NVC0(push, SUBC_SW(0x0600), 1); PUSH_DATA (push, m); } screen->pm.num_mp_pm_active[d]++; for (c = d * 4; c < (d * 4 + 4); ++c) { if (!screen->pm.mp_counter[c]) { q->ctr[i] = c; screen->pm.mp_counter[c] = (struct pipe_query *)q; break; } } assert(c <= (d * 4 + 3)); /* must succeed, already checked for space */ /* configure and reset the counter(s) */ if (is_nve4) { if (d == 0) BEGIN_NVC0(push, NVE4_COMPUTE(MP_PM_A_SIGSEL(c & 3)), 1); else BEGIN_NVC0(push, NVE4_COMPUTE(MP_PM_B_SIGSEL(c & 3)), 1); PUSH_DATA (push, cfg->ctr[i].sig_sel); BEGIN_NVC0(push, NVE4_COMPUTE(MP_PM_SRCSEL(c)), 1); PUSH_DATA (push, cfg->ctr[i].src_sel + 0x2108421 * (c & 3)); BEGIN_NVC0(push, NVE4_COMPUTE(MP_PM_FUNC(c)), 1); PUSH_DATA (push, (cfg->ctr[i].func << 4) | cfg->ctr[i].mode); BEGIN_NVC0(push, NVE4_COMPUTE(MP_PM_SET(c)), 1); PUSH_DATA (push, 0); } else { unsigned s; for (s = 0; s < cfg->ctr[i].num_src; s++) { BEGIN_NVC0(push, NVC0_COMPUTE(MP_PM_SIGSEL(s)), 1); PUSH_DATA (push, cfg->ctr[i].sig_sel); BEGIN_NVC0(push, NVC0_COMPUTE(MP_PM_SRCSEL(s)), 1); PUSH_DATA (push, (cfg->ctr[i].src_sel >> (s * 8)) & 0xff); BEGIN_NVC0(push, NVC0_COMPUTE(MP_PM_OP(s)), 1); PUSH_DATA (push, (cfg->ctr[i].func << 4) | cfg->ctr[i].mode); BEGIN_NVC0(push, NVC0_COMPUTE(MP_PM_SET(s)), 1); PUSH_DATA (push, 0); } } } } static void nvc0_mp_pm_query_end(struct nvc0_context *nvc0, struct nvc0_query *q) { struct nvc0_screen *screen = nvc0->screen; struct pipe_context *pipe = &nvc0->base.pipe; struct nouveau_pushbuf *push = nvc0->base.pushbuf; const boolean is_nve4 = screen->base.class_3d >= NVE4_3D_CLASS; uint32_t mask; uint32_t input[3]; const uint block[3] = { 32, is_nve4 ? 4 : 1, 1 }; const uint grid[3] = { screen->mp_count, 1, 1 }; unsigned c; const struct nvc0_mp_pm_query_cfg *cfg; cfg = nvc0_mp_pm_query_get_cfg(nvc0, q); if (unlikely(!screen->pm.prog)) { struct nvc0_program *prog = CALLOC_STRUCT(nvc0_program); prog->type = PIPE_SHADER_COMPUTE; prog->translated = TRUE; prog->num_gprs = 14; prog->parm_size = 12; if (is_nve4) { prog->code = (uint32_t *)nve4_read_mp_pm_counters_code; prog->code_size = sizeof(nve4_read_mp_pm_counters_code); } else { prog->code = (uint32_t *)nvc0_read_mp_pm_counters_code; prog->code_size = sizeof(nvc0_read_mp_pm_counters_code); } screen->pm.prog = prog; } /* disable all counting */ PUSH_SPACE(push, 8); for (c = 0; c < 8; ++c) if (screen->pm.mp_counter[c]) { if (is_nve4) { IMMED_NVC0(push, NVE4_COMPUTE(MP_PM_FUNC(c)), 0); } else { IMMED_NVC0(push, NVC0_COMPUTE(MP_PM_OP(c)), 0); } } /* release counters for this query */ for (c = 0; c < 8; ++c) { if (nvc0_query(screen->pm.mp_counter[c]) == q) { screen->pm.num_mp_pm_active[c / 4]--; screen->pm.mp_counter[c] = NULL; } } BCTX_REFN_bo(nvc0->bufctx_cp, CP_QUERY, NOUVEAU_BO_GART | NOUVEAU_BO_WR, q->bo); PUSH_SPACE(push, 1); IMMED_NVC0(push, SUBC_COMPUTE(NV50_GRAPH_SERIALIZE), 0); pipe->bind_compute_state(pipe, screen->pm.prog); input[0] = (q->bo->offset + q->base); input[1] = (q->bo->offset + q->base) >> 32; input[2] = q->sequence; pipe->launch_grid(pipe, block, grid, 0, input); nouveau_bufctx_reset(nvc0->bufctx_cp, NVC0_BIND_CP_QUERY); /* re-activate other counters */ PUSH_SPACE(push, 16); mask = 0; for (c = 0; c < 8; ++c) { unsigned i; q = nvc0_query(screen->pm.mp_counter[c]); if (!q) continue; cfg = nvc0_mp_pm_query_get_cfg(nvc0, q); for (i = 0; i < cfg->num_counters; ++i) { if (mask & (1 << q->ctr[i])) break; mask |= 1 << q->ctr[i]; if (is_nve4) { BEGIN_NVC0(push, NVE4_COMPUTE(MP_PM_FUNC(q->ctr[i])), 1); } else { BEGIN_NVC0(push, NVC0_COMPUTE(MP_PM_OP(q->ctr[i])), 1); } PUSH_DATA (push, (cfg->ctr[i].func << 4) | cfg->ctr[i].mode); } } } static INLINE boolean nvc0_mp_pm_query_read_data(uint32_t count[32][4], struct nvc0_context *nvc0, boolean wait, struct nvc0_query *q, const struct nvc0_mp_pm_query_cfg *cfg, unsigned mp_count) { unsigned p, c; for (p = 0; p < mp_count; ++p) { const unsigned b = (0x24 / 4) * p; for (c = 0; c < cfg->num_counters; ++c) { if (q->data[b + 8] != q->sequence) { if (!wait) return FALSE; if (nouveau_bo_wait(q->bo, NOUVEAU_BO_RD, nvc0->base.client)) return FALSE; } count[p][c] = q->data[b + q->ctr[c]]; } } return TRUE; } static INLINE boolean nve4_mp_pm_query_read_data(uint32_t count[32][4], struct nvc0_context *nvc0, boolean wait, struct nvc0_query *q, const struct nvc0_mp_pm_query_cfg *cfg, unsigned mp_count) { unsigned p, c, d; for (p = 0; p < mp_count; ++p) { const unsigned b = (0x60 / 4) * p; for (c = 0; c < cfg->num_counters; ++c) { count[p][c] = 0; for (d = 0; d < ((q->ctr[c] & ~3) ? 1 : 4); ++d) { if (q->data[b + 20 + d] != q->sequence) { if (!wait) return FALSE; if (nouveau_bo_wait(q->bo, NOUVEAU_BO_RD, nvc0->base.client)) return FALSE; } if (q->ctr[c] & ~0x3) count[p][c] = q->data[b + 16 + (q->ctr[c] & 3)]; else count[p][c] += q->data[b + d * 4 + q->ctr[c]]; } } } return TRUE; } /* Metric calculations: * sum(x) ... sum of x over all MPs * avg(x) ... average of x over all MPs * * IPC : sum(inst_executed) / clock * INST_REPLAY_OHEAD: (sum(inst_issued) - sum(inst_executed)) / sum(inst_issued) * MP_OCCUPANCY : avg((active_warps / 64) / active_cycles) * MP_EFFICIENCY : avg(active_cycles / clock) * * NOTE: Interpretation of IPC requires knowledge of MP count. */ static boolean nvc0_mp_pm_query_result(struct nvc0_context *nvc0, struct nvc0_query *q, void *result, boolean wait) { uint32_t count[32][4]; uint64_t value = 0; unsigned mp_count = MIN2(nvc0->screen->mp_count_compute, 32); unsigned p, c; const struct nvc0_mp_pm_query_cfg *cfg; boolean ret; cfg = nvc0_mp_pm_query_get_cfg(nvc0, q); if (nvc0->screen->base.class_3d >= NVE4_3D_CLASS) ret = nve4_mp_pm_query_read_data(count, nvc0, wait, q, cfg, mp_count); else ret = nvc0_mp_pm_query_read_data(count, nvc0, wait, q, cfg, mp_count); if (!ret) return FALSE; if (cfg->op == NVC0_COUNTER_OPn_SUM) { for (c = 0; c < cfg->num_counters; ++c) for (p = 0; p < mp_count; ++p) value += count[p][c]; value = (value * cfg->norm[0]) / cfg->norm[1]; } else if (cfg->op == NVC0_COUNTER_OPn_OR) { uint32_t v = 0; for (c = 0; c < cfg->num_counters; ++c) for (p = 0; p < mp_count; ++p) v |= count[p][c]; value = (v * cfg->norm[0]) / cfg->norm[1]; } else if (cfg->op == NVC0_COUNTER_OPn_AND) { uint32_t v = ~0; for (c = 0; c < cfg->num_counters; ++c) for (p = 0; p < mp_count; ++p) v &= count[p][c]; value = (v * cfg->norm[0]) / cfg->norm[1]; } else if (cfg->op == NVC0_COUNTER_OP2_REL_SUM_MM) { uint64_t v[2] = { 0, 0 }; for (p = 0; p < mp_count; ++p) { v[0] += count[p][0]; v[1] += count[p][1]; } if (v[0]) value = ((v[0] - v[1]) * cfg->norm[0]) / (v[0] * cfg->norm[1]); } else if (cfg->op == NVC0_COUNTER_OP2_DIV_SUM_M0) { for (p = 0; p < mp_count; ++p) value += count[p][0]; if (count[0][1]) value = (value * cfg->norm[0]) / (count[0][1] * cfg->norm[1]); else value = 0; } else if (cfg->op == NVC0_COUNTER_OP2_AVG_DIV_MM) { unsigned mp_used = 0; for (p = 0; p < mp_count; ++p, mp_used += !!count[p][0]) if (count[p][1]) value += (count[p][0] * cfg->norm[0]) / count[p][1]; if (mp_used) value /= mp_used * cfg->norm[1]; } else if (cfg->op == NVC0_COUNTER_OP2_AVG_DIV_M0) { unsigned mp_used = 0; for (p = 0; p < mp_count; ++p, mp_used += !!count[p][0]) value += count[p][0]; if (count[0][1] && mp_used) { value *= cfg->norm[0]; value /= count[0][1] * mp_used * cfg->norm[1]; } else { value = 0; } } *(uint64_t *)result = value; return TRUE; } int nvc0_screen_get_driver_query_info(struct pipe_screen *pscreen, unsigned id, struct pipe_driver_query_info *info) { struct nvc0_screen *screen = nvc0_screen(pscreen); int count = 0; count += NVC0_QUERY_DRV_STAT_COUNT; if (screen->base.device->drm_version >= 0x01000101) { if (screen->base.class_3d >= NVE4_3D_CLASS) { count += NVE4_PM_QUERY_COUNT; } else if (screen->compute) { count += NVC0_PM_QUERY_COUNT; /* NVC0_COMPUTE is not always enabled */ } } if (!info) return count; #ifdef NOUVEAU_ENABLE_DRIVER_STATISTICS if (id < NVC0_QUERY_DRV_STAT_COUNT) { info->name = nvc0_drv_stat_names[id]; info->query_type = NVC0_QUERY_DRV_STAT(id); info->max_value = ~0ULL; info->uses_byte_units = !!strstr(info->name, "bytes"); return 1; } else #endif if (id < count) { if (screen->base.class_3d >= NVE4_3D_CLASS) { info->name = nve4_pm_query_names[id - NVC0_QUERY_DRV_STAT_COUNT]; info->query_type = NVE4_PM_QUERY(id - NVC0_QUERY_DRV_STAT_COUNT); info->max_value = (id < NVE4_PM_QUERY_METRIC_MP_OCCUPANCY) ? ~0ULL : 100; info->uses_byte_units = FALSE; return 1; } else if (screen->compute) { info->name = nvc0_pm_query_names[id - NVC0_QUERY_DRV_STAT_COUNT]; info->query_type = NVC0_PM_QUERY(id - NVC0_QUERY_DRV_STAT_COUNT); info->max_value = ~0ULL; info->uses_byte_units = FALSE; return 1; } } /* user asked for info about non-existing query */ info->name = "this_is_not_the_query_you_are_looking_for"; info->query_type = 0xdeadd01d; info->max_value = 0; info->uses_byte_units = FALSE; return 0; } void nvc0_init_query_functions(struct nvc0_context *nvc0) { struct pipe_context *pipe = &nvc0->base.pipe; pipe->create_query = nvc0_query_create; pipe->destroy_query = nvc0_query_destroy; pipe->begin_query = nvc0_query_begin; pipe->end_query = nvc0_query_end; pipe->get_query_result = nvc0_query_result; pipe->render_condition = nvc0_render_condition; }