// SPDX-License-Identifier: GPL-2.0 WITH Linux-syscall-note /* * * (C) COPYRIGHT 2018-2022 ARM Limited. All rights reserved. * * This program is free software and is provided to you under the terms of the * GNU General Public License version 2 as published by the Free Software * Foundation, and any use by you of this program is subject to the terms * of such GNU license. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, you can access it online at * http://www.gnu.org/licenses/gpl-2.0.html. * */ #include "hwcnt/mali_kbase_hwcnt_gpu.h" #include "hwcnt/mali_kbase_hwcnt_types.h" #include /** enum enable_map_idx - index into a block enable map that spans multiple u64 array elements */ enum enable_map_idx { EM_LO, EM_HI, EM_COUNT, }; static void kbasep_get_fe_block_type(u64 *dst, enum kbase_hwcnt_set counter_set, bool is_csf) { switch (counter_set) { case KBASE_HWCNT_SET_PRIMARY: *dst = KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_FE; break; case KBASE_HWCNT_SET_SECONDARY: if (is_csf) *dst = KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_FE2; else *dst = KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_FE_UNDEFINED; break; case KBASE_HWCNT_SET_TERTIARY: if (is_csf) *dst = KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_FE3; else *dst = KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_FE_UNDEFINED; break; default: WARN_ON(true); } } static void kbasep_get_tiler_block_type(u64 *dst, enum kbase_hwcnt_set counter_set) { switch (counter_set) { case KBASE_HWCNT_SET_PRIMARY: *dst = KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_TILER; break; case KBASE_HWCNT_SET_SECONDARY: case KBASE_HWCNT_SET_TERTIARY: *dst = KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_TILER_UNDEFINED; break; default: WARN_ON(true); } } static void kbasep_get_sc_block_type(u64 *dst, enum kbase_hwcnt_set counter_set, bool is_csf) { switch (counter_set) { case KBASE_HWCNT_SET_PRIMARY: *dst = KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC; break; case KBASE_HWCNT_SET_SECONDARY: *dst = KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC2; break; case KBASE_HWCNT_SET_TERTIARY: if (is_csf) *dst = KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC3; else *dst = KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC_UNDEFINED; break; default: WARN_ON(true); } } static void kbasep_get_memsys_block_type(u64 *dst, enum kbase_hwcnt_set counter_set) { switch (counter_set) { case KBASE_HWCNT_SET_PRIMARY: *dst = KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_MEMSYS; break; case KBASE_HWCNT_SET_SECONDARY: *dst = KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_MEMSYS2; break; case KBASE_HWCNT_SET_TERTIARY: *dst = KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_MEMSYS_UNDEFINED; break; default: WARN_ON(true); } } /** * kbasep_hwcnt_backend_gpu_metadata_create() - Create hardware counter metadata * for the GPU. * @gpu_info: Non-NULL pointer to hwcnt info for current GPU. * @is_csf: true for CSF GPU, otherwise false. * @counter_set: The performance counter set to use. * @metadata: Non-NULL pointer to where created metadata is stored * on success. * * Return: 0 on success, else error code. */ static int kbasep_hwcnt_backend_gpu_metadata_create(const struct kbase_hwcnt_gpu_info *gpu_info, const bool is_csf, enum kbase_hwcnt_set counter_set, const struct kbase_hwcnt_metadata **metadata) { struct kbase_hwcnt_description desc; struct kbase_hwcnt_group_description group; struct kbase_hwcnt_block_description blks[KBASE_HWCNT_V5_BLOCK_TYPE_COUNT]; size_t non_sc_block_count; size_t sc_block_count; WARN_ON(!gpu_info); WARN_ON(!metadata); /* Calculate number of block instances that aren't shader cores */ non_sc_block_count = 2 + gpu_info->l2_count; /* Calculate number of block instances that are shader cores */ sc_block_count = fls64(gpu_info->core_mask); /* * A system can have up to 64 shader cores, but the 64-bit * availability mask can't physically represent that many cores as well * as the other hardware blocks. * Error out if there are more blocks than our implementation can * support. */ if ((sc_block_count + non_sc_block_count) > KBASE_HWCNT_AVAIL_MASK_BITS) return -EINVAL; /* One Front End block */ kbasep_get_fe_block_type(&blks[0].type, counter_set, is_csf); blks[0].inst_cnt = 1; blks[0].hdr_cnt = KBASE_HWCNT_V5_HEADERS_PER_BLOCK; blks[0].ctr_cnt = gpu_info->prfcnt_values_per_block - KBASE_HWCNT_V5_HEADERS_PER_BLOCK; /* One Tiler block */ kbasep_get_tiler_block_type(&blks[1].type, counter_set); blks[1].inst_cnt = 1; blks[1].hdr_cnt = KBASE_HWCNT_V5_HEADERS_PER_BLOCK; blks[1].ctr_cnt = gpu_info->prfcnt_values_per_block - KBASE_HWCNT_V5_HEADERS_PER_BLOCK; /* l2_count memsys blks */ kbasep_get_memsys_block_type(&blks[2].type, counter_set); blks[2].inst_cnt = gpu_info->l2_count; blks[2].hdr_cnt = KBASE_HWCNT_V5_HEADERS_PER_BLOCK; blks[2].ctr_cnt = gpu_info->prfcnt_values_per_block - KBASE_HWCNT_V5_HEADERS_PER_BLOCK; /* * There are as many shader cores in the system as there are bits set in * the core mask. However, the dump buffer memory requirements need to * take into account the fact that the core mask may be non-contiguous. * * For example, a system with a core mask of 0b1011 has the same dump * buffer memory requirements as a system with 0b1111, but requires more * memory than a system with 0b0111. However, core 2 of the system with * 0b1011 doesn't physically exist, and the dump buffer memory that * accounts for that core will never be written to when we do a counter * dump. * * We find the core mask's last set bit to determine the memory * requirements, and embed the core mask into the availability mask so * we can determine later which shader cores physically exist. */ kbasep_get_sc_block_type(&blks[3].type, counter_set, is_csf); blks[3].inst_cnt = sc_block_count; blks[3].hdr_cnt = KBASE_HWCNT_V5_HEADERS_PER_BLOCK; blks[3].ctr_cnt = gpu_info->prfcnt_values_per_block - KBASE_HWCNT_V5_HEADERS_PER_BLOCK; WARN_ON(KBASE_HWCNT_V5_BLOCK_TYPE_COUNT != 4); group.type = KBASE_HWCNT_GPU_GROUP_TYPE_V5; group.blk_cnt = KBASE_HWCNT_V5_BLOCK_TYPE_COUNT; group.blks = blks; desc.grp_cnt = 1; desc.grps = &group; desc.clk_cnt = gpu_info->clk_cnt; /* The JM, Tiler, and L2s are always available, and are before cores */ desc.avail_mask = (1ull << non_sc_block_count) - 1; /* Embed the core mask directly in the availability mask */ desc.avail_mask |= (gpu_info->core_mask << non_sc_block_count); return kbase_hwcnt_metadata_create(&desc, metadata); } /** * kbasep_hwcnt_backend_jm_dump_bytes() - Get the raw dump buffer size for the * GPU. * @gpu_info: Non-NULL pointer to hwcnt info for the GPU. * * Return: Size of buffer the GPU needs to perform a counter dump. */ static size_t kbasep_hwcnt_backend_jm_dump_bytes(const struct kbase_hwcnt_gpu_info *gpu_info) { WARN_ON(!gpu_info); return (2 + gpu_info->l2_count + fls64(gpu_info->core_mask)) * gpu_info->prfcnt_values_per_block * KBASE_HWCNT_VALUE_HW_BYTES; } int kbase_hwcnt_jm_metadata_create(const struct kbase_hwcnt_gpu_info *gpu_info, enum kbase_hwcnt_set counter_set, const struct kbase_hwcnt_metadata **out_metadata, size_t *out_dump_bytes) { int errcode; const struct kbase_hwcnt_metadata *metadata; size_t dump_bytes; if (!gpu_info || !out_metadata || !out_dump_bytes) return -EINVAL; /* * For architectures where a max_config interface is available * from the arbiter, the v5 dump bytes and the metadata v5 are * based on the maximum possible allocation of the HW in the * GPU cause it needs to be prepared for the worst case where * all the available L2 cache and Shader cores are allocated. */ dump_bytes = kbasep_hwcnt_backend_jm_dump_bytes(gpu_info); errcode = kbasep_hwcnt_backend_gpu_metadata_create(gpu_info, false, counter_set, &metadata); if (errcode) return errcode; /* * The physical dump size should be half of dump abstraction size in * metadata since physical HW uses 32-bit per value but metadata * specifies 64-bit per value. */ WARN_ON(dump_bytes * 2 != metadata->dump_buf_bytes); *out_metadata = metadata; *out_dump_bytes = dump_bytes; return 0; } void kbase_hwcnt_jm_metadata_destroy(const struct kbase_hwcnt_metadata *metadata) { if (!metadata) return; kbase_hwcnt_metadata_destroy(metadata); } int kbase_hwcnt_csf_metadata_create(const struct kbase_hwcnt_gpu_info *gpu_info, enum kbase_hwcnt_set counter_set, const struct kbase_hwcnt_metadata **out_metadata) { int errcode; const struct kbase_hwcnt_metadata *metadata; if (!gpu_info || !out_metadata) return -EINVAL; errcode = kbasep_hwcnt_backend_gpu_metadata_create(gpu_info, true, counter_set, &metadata); if (errcode) return errcode; *out_metadata = metadata; return 0; } void kbase_hwcnt_csf_metadata_destroy(const struct kbase_hwcnt_metadata *metadata) { if (!metadata) return; kbase_hwcnt_metadata_destroy(metadata); } static bool is_block_type_shader(const u64 grp_type, const u64 blk_type, const size_t blk) { bool is_shader = false; /* Warn on unknown group type */ if (WARN_ON(grp_type != KBASE_HWCNT_GPU_GROUP_TYPE_V5)) return false; if (blk_type == KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC || blk_type == KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC2 || blk_type == KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC3 || blk_type == KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC_UNDEFINED) is_shader = true; return is_shader; } static bool is_block_type_l2_cache(const u64 grp_type, const u64 blk_type) { bool is_l2_cache = false; switch (grp_type) { case KBASE_HWCNT_GPU_GROUP_TYPE_V5: if (blk_type == KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_MEMSYS || blk_type == KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_MEMSYS2 || blk_type == KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_MEMSYS_UNDEFINED) is_l2_cache = true; break; default: /* Warn on unknown group type */ WARN_ON(true); } return is_l2_cache; } int kbase_hwcnt_jm_dump_get(struct kbase_hwcnt_dump_buffer *dst, u64 *src, const struct kbase_hwcnt_enable_map *dst_enable_map, u64 pm_core_mask, const struct kbase_hwcnt_curr_config *curr_config, bool accumulate) { const struct kbase_hwcnt_metadata *metadata; size_t grp, blk, blk_inst; const u64 *dump_src = src; size_t src_offset = 0; u64 core_mask = pm_core_mask; /* Variables to deal with the current configuration */ int l2_count = 0; if (!dst || !src || !dst_enable_map || (dst_enable_map->metadata != dst->metadata)) return -EINVAL; metadata = dst->metadata; kbase_hwcnt_metadata_for_each_block(metadata, grp, blk, blk_inst) { const size_t hdr_cnt = kbase_hwcnt_metadata_block_headers_count(metadata, grp, blk); const size_t ctr_cnt = kbase_hwcnt_metadata_block_counters_count(metadata, grp, blk); const u64 blk_type = kbase_hwcnt_metadata_block_type(metadata, grp, blk); const bool is_shader_core = is_block_type_shader( kbase_hwcnt_metadata_group_type(metadata, grp), blk_type, blk); const bool is_l2_cache = is_block_type_l2_cache( kbase_hwcnt_metadata_group_type(metadata, grp), blk_type); const bool is_undefined = kbase_hwcnt_is_block_type_undefined( kbase_hwcnt_metadata_group_type(metadata, grp), blk_type); bool hw_res_available = true; /* * If l2 blocks is greater than the current allocated number of * L2 slices, there is no hw allocated to that block. */ if (is_l2_cache) { l2_count++; if (l2_count > curr_config->num_l2_slices) hw_res_available = false; else hw_res_available = true; } /* * For the shader cores, the current shader_mask allocated is * always a subgroup of the maximum shader_mask, so after * jumping any L2 cache not available the available shader cores * will always have a matching set of blk instances available to * accumulate them. */ else hw_res_available = true; /* * Skip block if no values in the destination block are enabled. */ if (kbase_hwcnt_enable_map_block_enabled(dst_enable_map, grp, blk, blk_inst)) { u64 *dst_blk = kbase_hwcnt_dump_buffer_block_instance(dst, grp, blk, blk_inst); const u64 *src_blk = dump_src + src_offset; bool blk_powered; if (!is_shader_core) { /* Under the current PM system, counters will * only be enabled after all non shader core * blocks are powered up. */ blk_powered = true; } else { /* Check the PM core mask to see if the shader * core is powered up. */ blk_powered = core_mask & 1; } if (blk_powered && !is_undefined && hw_res_available) { /* Only powered and defined blocks have valid data. */ if (accumulate) { kbase_hwcnt_dump_buffer_block_accumulate(dst_blk, src_blk, hdr_cnt, ctr_cnt); } else { kbase_hwcnt_dump_buffer_block_copy(dst_blk, src_blk, (hdr_cnt + ctr_cnt)); } } else { /* Even though the block might be undefined, the * user has enabled counter collection for it. * We should not propagate garbage data. */ if (accumulate) { /* No-op to preserve existing values */ } else { /* src is garbage, so zero the dst */ kbase_hwcnt_dump_buffer_block_zero(dst_blk, (hdr_cnt + ctr_cnt)); } } } /* Just increase the src_offset if the HW is available */ if (hw_res_available) src_offset += (hdr_cnt + ctr_cnt); if (is_shader_core) core_mask = core_mask >> 1; } return 0; } int kbase_hwcnt_csf_dump_get(struct kbase_hwcnt_dump_buffer *dst, u64 *src, const struct kbase_hwcnt_enable_map *dst_enable_map, bool accumulate) { const struct kbase_hwcnt_metadata *metadata; const u64 *dump_src = src; size_t src_offset = 0; size_t grp, blk, blk_inst; if (!dst || !src || !dst_enable_map || (dst_enable_map->metadata != dst->metadata)) return -EINVAL; metadata = dst->metadata; kbase_hwcnt_metadata_for_each_block(metadata, grp, blk, blk_inst) { const size_t hdr_cnt = kbase_hwcnt_metadata_block_headers_count(metadata, grp, blk); const size_t ctr_cnt = kbase_hwcnt_metadata_block_counters_count(metadata, grp, blk); const uint64_t blk_type = kbase_hwcnt_metadata_block_type(metadata, grp, blk); const bool is_undefined = kbase_hwcnt_is_block_type_undefined( kbase_hwcnt_metadata_group_type(metadata, grp), blk_type); /* * Skip block if no values in the destination block are enabled. */ if (kbase_hwcnt_enable_map_block_enabled(dst_enable_map, grp, blk, blk_inst)) { u64 *dst_blk = kbase_hwcnt_dump_buffer_block_instance(dst, grp, blk, blk_inst); const u64 *src_blk = dump_src + src_offset; if (!is_undefined) { if (accumulate) { kbase_hwcnt_dump_buffer_block_accumulate(dst_blk, src_blk, hdr_cnt, ctr_cnt); } else { kbase_hwcnt_dump_buffer_block_copy(dst_blk, src_blk, (hdr_cnt + ctr_cnt)); } } else { /* Even though the block might be undefined, the * user has enabled counter collection for it. * We should not propagate garbage data. */ if (accumulate) { /* No-op to preserve existing values */ } else { /* src is garbage, so zero the dst */ kbase_hwcnt_dump_buffer_block_zero(dst_blk, (hdr_cnt + ctr_cnt)); } } } src_offset += (hdr_cnt + ctr_cnt); } return 0; } /** * kbasep_hwcnt_backend_gpu_block_map_from_physical() - Convert from a physical * block enable map to a * block enable map * abstraction. * @phys: Physical 32-bit block enable map * @lo: Non-NULL pointer to where low 64 bits of block enable map abstraction * will be stored. * @hi: Non-NULL pointer to where high 64 bits of block enable map abstraction * will be stored. */ static inline void kbasep_hwcnt_backend_gpu_block_map_from_physical(u32 phys, u64 *lo, u64 *hi) { u64 dwords[2] = { 0, 0 }; size_t dword_idx; for (dword_idx = 0; dword_idx < 2; dword_idx++) { const u16 packed = phys >> (16 * dword_idx); u64 dword = 0; size_t hword_bit; for (hword_bit = 0; hword_bit < 16; hword_bit++) { const size_t dword_bit = hword_bit * 4; const u64 mask = (packed >> (hword_bit)) & 0x1; dword |= mask << (dword_bit + 0); dword |= mask << (dword_bit + 1); dword |= mask << (dword_bit + 2); dword |= mask << (dword_bit + 3); } dwords[dword_idx] = dword; } *lo = dwords[0]; *hi = dwords[1]; } void kbase_hwcnt_gpu_enable_map_to_physical(struct kbase_hwcnt_physical_enable_map *dst, const struct kbase_hwcnt_enable_map *src) { const struct kbase_hwcnt_metadata *metadata; u64 fe_bm[EM_COUNT] = { 0 }; u64 shader_bm[EM_COUNT] = { 0 }; u64 tiler_bm[EM_COUNT] = { 0 }; u64 mmu_l2_bm[EM_COUNT] = { 0 }; size_t grp, blk, blk_inst; if (WARN_ON(!src) || WARN_ON(!dst)) return; metadata = src->metadata; kbase_hwcnt_metadata_for_each_block(metadata, grp, blk, blk_inst) { const u64 grp_type = kbase_hwcnt_metadata_group_type(metadata, grp); const u64 blk_type = kbase_hwcnt_metadata_block_type(metadata, grp, blk); const u64 *blk_map = kbase_hwcnt_enable_map_block_instance(src, grp, blk, blk_inst); if ((enum kbase_hwcnt_gpu_group_type)grp_type == KBASE_HWCNT_GPU_GROUP_TYPE_V5) { const size_t map_stride = kbase_hwcnt_metadata_block_enable_map_stride(metadata, grp, blk); size_t map_idx; for (map_idx = 0; map_idx < map_stride; ++map_idx) { if (WARN_ON(map_idx >= EM_COUNT)) break; switch ((enum kbase_hwcnt_gpu_v5_block_type)blk_type) { case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_FE_UNDEFINED: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC_UNDEFINED: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_TILER_UNDEFINED: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_MEMSYS_UNDEFINED: /* Nothing to do in this case. */ break; case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_FE: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_FE2: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_FE3: fe_bm[map_idx] |= blk_map[map_idx]; break; case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_TILER: tiler_bm[map_idx] |= blk_map[map_idx]; break; case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC2: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC3: shader_bm[map_idx] |= blk_map[map_idx]; break; case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_MEMSYS: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_MEMSYS2: mmu_l2_bm[map_idx] |= blk_map[map_idx]; break; default: WARN_ON(true); } } } else { WARN_ON(true); } } dst->fe_bm = kbase_hwcnt_backend_gpu_block_map_to_physical(fe_bm[EM_LO], fe_bm[EM_HI]); dst->shader_bm = kbase_hwcnt_backend_gpu_block_map_to_physical(shader_bm[EM_LO], shader_bm[EM_HI]); dst->tiler_bm = kbase_hwcnt_backend_gpu_block_map_to_physical(tiler_bm[EM_LO], tiler_bm[EM_HI]); dst->mmu_l2_bm = kbase_hwcnt_backend_gpu_block_map_to_physical(mmu_l2_bm[EM_LO], mmu_l2_bm[EM_HI]); } void kbase_hwcnt_gpu_set_to_physical(enum kbase_hwcnt_physical_set *dst, enum kbase_hwcnt_set src) { switch (src) { case KBASE_HWCNT_SET_PRIMARY: *dst = KBASE_HWCNT_PHYSICAL_SET_PRIMARY; break; case KBASE_HWCNT_SET_SECONDARY: *dst = KBASE_HWCNT_PHYSICAL_SET_SECONDARY; break; case KBASE_HWCNT_SET_TERTIARY: *dst = KBASE_HWCNT_PHYSICAL_SET_TERTIARY; break; default: WARN_ON(true); } } void kbase_hwcnt_gpu_enable_map_from_physical(struct kbase_hwcnt_enable_map *dst, const struct kbase_hwcnt_physical_enable_map *src) { const struct kbase_hwcnt_metadata *metadata; u64 fe_bm[EM_COUNT] = { 0 }; u64 shader_bm[EM_COUNT] = { 0 }; u64 tiler_bm[EM_COUNT] = { 0 }; u64 mmu_l2_bm[EM_COUNT] = { 0 }; size_t grp, blk, blk_inst; if (WARN_ON(!src) || WARN_ON(!dst)) return; metadata = dst->metadata; kbasep_hwcnt_backend_gpu_block_map_from_physical(src->fe_bm, &fe_bm[EM_LO], &fe_bm[EM_HI]); kbasep_hwcnt_backend_gpu_block_map_from_physical(src->shader_bm, &shader_bm[EM_LO], &shader_bm[EM_HI]); kbasep_hwcnt_backend_gpu_block_map_from_physical(src->tiler_bm, &tiler_bm[EM_LO], &tiler_bm[EM_HI]); kbasep_hwcnt_backend_gpu_block_map_from_physical(src->mmu_l2_bm, &mmu_l2_bm[EM_LO], &mmu_l2_bm[EM_HI]); kbase_hwcnt_metadata_for_each_block(metadata, grp, blk, blk_inst) { const u64 grp_type = kbase_hwcnt_metadata_group_type(metadata, grp); const u64 blk_type = kbase_hwcnt_metadata_block_type(metadata, grp, blk); u64 *blk_map = kbase_hwcnt_enable_map_block_instance(dst, grp, blk, blk_inst); if ((enum kbase_hwcnt_gpu_group_type)grp_type == KBASE_HWCNT_GPU_GROUP_TYPE_V5) { const size_t map_stride = kbase_hwcnt_metadata_block_enable_map_stride(metadata, grp, blk); size_t map_idx; for (map_idx = 0; map_idx < map_stride; ++map_idx) { if (WARN_ON(map_idx >= EM_COUNT)) break; switch ((enum kbase_hwcnt_gpu_v5_block_type)blk_type) { case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_FE_UNDEFINED: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC_UNDEFINED: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_TILER_UNDEFINED: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_MEMSYS_UNDEFINED: /* Nothing to do in this case. */ break; case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_FE: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_FE2: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_FE3: blk_map[map_idx] = fe_bm[map_idx]; break; case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_TILER: blk_map[map_idx] = tiler_bm[map_idx]; break; case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC2: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_SC3: blk_map[map_idx] = shader_bm[map_idx]; break; case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_MEMSYS: case KBASE_HWCNT_GPU_V5_BLOCK_TYPE_PERF_MEMSYS2: blk_map[map_idx] = mmu_l2_bm[map_idx]; break; default: WARN_ON(true); } } } else { WARN_ON(true); } } } void kbase_hwcnt_gpu_patch_dump_headers(struct kbase_hwcnt_dump_buffer *buf, const struct kbase_hwcnt_enable_map *enable_map) { const struct kbase_hwcnt_metadata *metadata; size_t grp, blk, blk_inst; if (WARN_ON(!buf) || WARN_ON(!enable_map) || WARN_ON(buf->metadata != enable_map->metadata)) return; metadata = buf->metadata; kbase_hwcnt_metadata_for_each_block(metadata, grp, blk, blk_inst) { const u64 grp_type = kbase_hwcnt_metadata_group_type(metadata, grp); u64 *buf_blk = kbase_hwcnt_dump_buffer_block_instance(buf, grp, blk, blk_inst); const u64 *blk_map = kbase_hwcnt_enable_map_block_instance(enable_map, grp, blk, blk_inst); if ((enum kbase_hwcnt_gpu_group_type)grp_type == KBASE_HWCNT_GPU_GROUP_TYPE_V5) { const size_t map_stride = kbase_hwcnt_metadata_block_enable_map_stride(metadata, grp, blk); u64 prfcnt_bm[EM_COUNT] = { 0 }; u32 prfcnt_en = 0; size_t map_idx; for (map_idx = 0; map_idx < map_stride; ++map_idx) { if (WARN_ON(map_idx >= EM_COUNT)) break; prfcnt_bm[map_idx] = blk_map[map_idx]; } prfcnt_en = kbase_hwcnt_backend_gpu_block_map_to_physical(prfcnt_bm[EM_LO], prfcnt_bm[EM_HI]); buf_blk[KBASE_HWCNT_V5_PRFCNT_EN_HEADER] = prfcnt_en; } else { WARN_ON(true); } } }