// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (c) 2016-2021, The Linux Foundation. All rights reserved. * Copyright (c) 2022-2024 Qualcomm Innovation Center, Inc. All rights reserved. */ #include #include #include #include #include #include #include #if IS_REACHABLE(CONFIG_DMABUF_HEAPS) #include #include #endif #include "cam_compat.h" #include "cam_req_mgr_util.h" #include "cam_mem_mgr.h" #include "cam_smmu_api.h" #include "cam_debug_util.h" #include "cam_trace.h" #include "cam_common_util.h" #include "cam_presil_hw_access.h" #define CAM_MEM_SHARED_BUFFER_PAD_4K (4 * 1024) static struct cam_mem_table tbl; static atomic_t cam_mem_mgr_state = ATOMIC_INIT(CAM_MEM_MGR_UNINITIALIZED); /* Number of words for dumping req state info */ #define CAM_MEM_MGR_DUMP_BUF_NUM_WORDS 29 /* cam_mem_mgr_debug - global struct to keep track of debug settings for mem mgr * * @dentry : Directory entry to the mem mgr root folder * @alloc_profile_enable : Whether to enable alloc profiling * @override_cpu_access_dir : Override cpu access direction to BIDIRECTIONAL */ static struct { struct dentry *dentry; bool alloc_profile_enable; bool override_cpu_access_dir; } g_cam_mem_mgr_debug; #if IS_REACHABLE(CONFIG_DMABUF_HEAPS) static void cam_mem_mgr_put_dma_heaps(void); static int cam_mem_mgr_get_dma_heaps(void); #endif #ifdef CONFIG_CAM_PRESIL static inline void cam_mem_mgr_reset_presil_params(int idx) { tbl.bufq[idx].presil_params.fd_for_umd_daemon = -1; tbl.bufq[idx].presil_params.refcount = 0; } #else static inline void cam_mem_mgr_reset_presil_params(int idx) { return; } #endif static unsigned long cam_mem_mgr_mini_dump_cb(void *dst, unsigned long len, void *priv_data) { struct cam_mem_table_mini_dump *md; if (!dst) { CAM_ERR(CAM_MEM, "Invalid params"); return 0; } if (len < sizeof(*md)) { CAM_ERR(CAM_MEM, "Insufficient length %u", len); return 0; } md = (struct cam_mem_table_mini_dump *)dst; memcpy(md->bufq, tbl.bufq, CAM_MEM_BUFQ_MAX * sizeof(struct cam_mem_buf_queue)); md->dbg_buf_idx = tbl.dbg_buf_idx; md->alloc_profile_enable = g_cam_mem_mgr_debug.alloc_profile_enable; md->force_cache_allocs = tbl.force_cache_allocs; md->need_shared_buffer_padding = tbl.need_shared_buffer_padding; return sizeof(*md); } static void cam_mem_mgr_print_tbl(void) { int i; uint64_t ms, hrs, min, sec; struct timespec64 current_ts; CAM_GET_TIMESTAMP(current_ts); CAM_CONVERT_TIMESTAMP_FORMAT(current_ts, hrs, min, sec, ms); CAM_INFO(CAM_MEM, "***%llu:%llu:%llu:%llu Mem mgr table dump***", hrs, min, sec, ms); for (i = 1; i < CAM_MEM_BUFQ_MAX; i++) { CAM_CONVERT_TIMESTAMP_FORMAT((tbl.bufq[i].timestamp), hrs, min, sec, ms); CAM_INFO(CAM_MEM, "%llu:%llu:%llu:%llu idx %d fd %d i_ino %lu size %llu active %d buf_handle %d krefCount %d urefCount %d buf_name %s", hrs, min, sec, ms, i, tbl.bufq[i].fd, tbl.bufq[i].i_ino, tbl.bufq[i].len, tbl.bufq[i].active, tbl.bufq[i].buf_handle, kref_read(&tbl.bufq[i].krefcount), kref_read(&tbl.bufq[i].urefcount), tbl.bufq[i].buf_name); } } /** * For faster lookups, maintaining same indexing as SMMU * for saving iova for a given buffer for a given context * bank * * Buffer X : [iova_1, 0x0, iova_3, ...] * Here iova_1 is for device_1, no iova available for device_2, * iova_3 for device_3 and so on */ static inline bool cam_mem_mgr_get_hwva_entry_idx( int32_t mem_handle, int32_t *entry_idx) { int entry; entry = GET_SMMU_TABLE_IDX(mem_handle); if (unlikely((entry < 0) || (entry >= tbl.max_hdls_supported))) { CAM_ERR(CAM_MEM, "Invalid mem_hdl: 0x%x, failed to lookup", mem_handle); return false; } *entry_idx = entry; return true; } static int cam_mem_util_get_dma_dir(uint32_t flags) { int rc = -EINVAL; if (flags & CAM_MEM_FLAG_HW_READ_ONLY) rc = DMA_TO_DEVICE; else if (flags & CAM_MEM_FLAG_HW_WRITE_ONLY) rc = DMA_FROM_DEVICE; else if (flags & CAM_MEM_FLAG_HW_READ_WRITE) rc = DMA_BIDIRECTIONAL; else if (flags & CAM_MEM_FLAG_PROTECTED_MODE) rc = DMA_BIDIRECTIONAL; return rc; } static int cam_mem_util_map_cpu_va(struct dma_buf *dmabuf, uintptr_t *vaddr, size_t *len) { int rc = 0; /* * dma_buf_begin_cpu_access() and dma_buf_end_cpu_access() * need to be called in pair to avoid stability issue. */ rc = dma_buf_begin_cpu_access(dmabuf, DMA_BIDIRECTIONAL); if (rc) { CAM_ERR(CAM_MEM, "dma begin access failed rc=%d", rc); return rc; } rc = cam_compat_util_get_dmabuf_va(dmabuf, vaddr); if (rc) { CAM_ERR(CAM_MEM, "kernel vmap failed: rc = %d", rc); *len = 0; dma_buf_end_cpu_access(dmabuf, DMA_BIDIRECTIONAL); } else { *len = dmabuf->size; CAM_DBG(CAM_MEM, "vaddr = %llu, len = %zu", *vaddr, *len); } return rc; } static int cam_mem_util_unmap_cpu_va(struct dma_buf *dmabuf, uint64_t vaddr) { int rc = 0; if (!dmabuf || !vaddr) { CAM_ERR(CAM_MEM, "Invalid input args %pK %llX", dmabuf, vaddr); return -EINVAL; } cam_compat_util_put_dmabuf_va(dmabuf, (void *)vaddr); /* * dma_buf_begin_cpu_access() and * dma_buf_end_cpu_access() need to be called in pair * to avoid stability issue. */ rc = dma_buf_end_cpu_access(dmabuf, DMA_BIDIRECTIONAL); if (rc) { CAM_ERR(CAM_MEM, "Failed in end cpu access, dmabuf=%pK", dmabuf); return rc; } return rc; } static int cam_mem_mgr_create_debug_fs(void) { int rc = 0; struct dentry *dbgfileptr = NULL; if (!cam_debugfs_available() || g_cam_mem_mgr_debug.dentry) return 0; rc = cam_debugfs_create_subdir("memmgr", &dbgfileptr); if (rc) { CAM_ERR(CAM_MEM, "DebugFS could not create directory!"); rc = -ENOENT; goto end; } g_cam_mem_mgr_debug.dentry = dbgfileptr; debugfs_create_bool("alloc_profile_enable", 0644, g_cam_mem_mgr_debug.dentry, &g_cam_mem_mgr_debug.alloc_profile_enable); debugfs_create_bool("override_cpu_access_dir", 0644, g_cam_mem_mgr_debug.dentry, &g_cam_mem_mgr_debug.override_cpu_access_dir); end: return rc; } int cam_mem_mgr_init(void) { int i; int bitmap_size; int rc = 0; if (atomic_read(&cam_mem_mgr_state)) return 0; memset(tbl.bufq, 0, sizeof(tbl.bufq)); if (cam_smmu_need_force_alloc_cached(&tbl.force_cache_allocs)) { CAM_ERR(CAM_MEM, "Error in getting force cache alloc flag"); return -EINVAL; } tbl.need_shared_buffer_padding = cam_smmu_need_shared_buffer_padding(); #if IS_REACHABLE(CONFIG_DMABUF_HEAPS) rc = cam_mem_mgr_get_dma_heaps(); if (rc) { CAM_ERR(CAM_MEM, "Failed in getting dma heaps rc=%d", rc); return rc; } #endif bitmap_size = BITS_TO_LONGS(CAM_MEM_BUFQ_MAX) * sizeof(long); tbl.bitmap = kzalloc(bitmap_size, GFP_KERNEL); if (!tbl.bitmap) { rc = -ENOMEM; goto put_heaps; } tbl.bits = bitmap_size * BITS_PER_BYTE; bitmap_zero(tbl.bitmap, tbl.bits); /* We need to reserve slot 0 because 0 is invalid */ set_bit(0, tbl.bitmap); for (i = 1; i < CAM_MEM_BUFQ_MAX; i++) { tbl.bufq[i].fd = -1; tbl.bufq[i].buf_handle = -1; cam_mem_mgr_reset_presil_params(i); } mutex_init(&tbl.m_lock); atomic_set(&cam_mem_mgr_state, CAM_MEM_MGR_INITIALIZED); cam_mem_mgr_create_debug_fs(); cam_common_register_mini_dump_cb(cam_mem_mgr_mini_dump_cb, "cam_mem", NULL); rc = cam_smmu_driver_init(&tbl.csf_version, &tbl.max_hdls_supported); if (rc) goto clean_bitmap_and_mutex; if (!tbl.max_hdls_supported) { CAM_ERR(CAM_MEM, "Invalid number of supported handles"); rc = -EINVAL; goto clean_bitmap_and_mutex; } tbl.max_hdls_info_size = sizeof(struct cam_mem_buf_hw_hdl_info) * tbl.max_hdls_supported; /* Index 0 is reserved as invalid slot */ for (i = 1; i < CAM_MEM_BUFQ_MAX; i++) { tbl.bufq[i].hdls_info = kzalloc(tbl.max_hdls_info_size, GFP_KERNEL); if (!tbl.bufq[i].hdls_info) { CAM_ERR(CAM_MEM, "Failed to allocate hdls array queue idx: %d", i); rc = -ENOMEM; goto free_hdls_info; } } return 0; free_hdls_info: for (--i; i > 0; i--) { kfree(tbl.bufq[i].hdls_info); tbl.bufq[i].hdls_info = NULL; } clean_bitmap_and_mutex: kfree(tbl.bitmap); tbl.bitmap = NULL; mutex_destroy(&tbl.m_lock); atomic_set(&cam_mem_mgr_state, CAM_MEM_MGR_UNINITIALIZED); put_heaps: #if IS_REACHABLE(CONFIG_DMABUF_HEAPS) cam_mem_mgr_put_dma_heaps(); #endif return rc; } static int32_t cam_mem_get_slot(void) { int32_t idx; mutex_lock(&tbl.m_lock); idx = find_first_zero_bit(tbl.bitmap, tbl.bits); if (idx >= CAM_MEM_BUFQ_MAX || idx <= 0) { mutex_unlock(&tbl.m_lock); return -ENOMEM; } set_bit(idx, tbl.bitmap); tbl.bufq[idx].active = true; tbl.bufq[idx].release_deferred = false; CAM_GET_TIMESTAMP((tbl.bufq[idx].timestamp)); mutex_init(&tbl.bufq[idx].q_lock); mutex_unlock(&tbl.m_lock); return idx; } static void cam_mem_put_slot(int32_t idx) { mutex_lock(&tbl.m_lock); mutex_lock(&tbl.bufq[idx].q_lock); tbl.bufq[idx].active = false; tbl.bufq[idx].release_deferred = false; tbl.bufq[idx].is_internal = false; memset(&tbl.bufq[idx].timestamp, 0, sizeof(struct timespec64)); kref_init(&tbl.bufq[idx].krefcount); kref_init(&tbl.bufq[idx].urefcount); mutex_unlock(&tbl.bufq[idx].q_lock); mutex_destroy(&tbl.bufq[idx].q_lock); clear_bit(idx, tbl.bitmap); mutex_unlock(&tbl.m_lock); } static bool cam_mem_mgr_is_iova_info_updated_locked( struct cam_mem_buf_hw_hdl_info *hw_vaddr_info_arr, int32_t iommu_hdl) { int entry; struct cam_mem_buf_hw_hdl_info *vaddr_entry; /* validate hdl for entry idx */ if (!cam_mem_mgr_get_hwva_entry_idx(iommu_hdl, &entry)) return false; vaddr_entry = &hw_vaddr_info_arr[entry]; if (vaddr_entry->valid_mapping && vaddr_entry->iommu_hdl == iommu_hdl) return true; return false; } static void cam_mem_mgr_update_iova_info_locked( struct cam_mem_buf_hw_hdl_info *hw_vaddr_info_arr, dma_addr_t vaddr, int32_t iommu_hdl, size_t len, bool valid_mapping, struct kref *ref_count) { int entry; struct cam_mem_buf_hw_hdl_info *vaddr_entry; /* validate hdl for entry idx */ if (!cam_mem_mgr_get_hwva_entry_idx(iommu_hdl, &entry)) return; vaddr_entry = &hw_vaddr_info_arr[entry]; vaddr_entry->vaddr = vaddr; vaddr_entry->iommu_hdl = iommu_hdl; vaddr_entry->addr_updated = true; vaddr_entry->valid_mapping = valid_mapping; vaddr_entry->len = len; vaddr_entry->ref_count = ref_count; } /* Utility to be invoked with bufq entry lock held */ static int cam_mem_mgr_try_retrieving_hwva_locked( int idx, int32_t mmu_handle, dma_addr_t *iova_ptr, size_t *len_ptr, struct list_head *buf_tracker) { int rc = -EINVAL, entry; struct cam_mem_buf_hw_hdl_info *hdl_info = NULL; /* Check for valid entry */ if (cam_mem_mgr_get_hwva_entry_idx(mmu_handle, &entry)) { hdl_info = &tbl.bufq[idx].hdls_info[entry]; /* Ensure we are picking a valid entry */ if ((hdl_info->iommu_hdl == mmu_handle) && (hdl_info->addr_updated)) { *iova_ptr = hdl_info->vaddr; *len_ptr = hdl_info->len; if (buf_tracker) cam_smmu_add_buf_to_track_list(tbl.bufq[idx].fd, tbl.bufq[idx].i_ino, &hdl_info->ref_count, buf_tracker, GET_SMMU_TABLE_IDX(mmu_handle)); rc = 0; } } return rc; } int cam_mem_get_io_buf(int32_t buf_handle, int32_t mmu_handle, dma_addr_t *iova_ptr, size_t *len_ptr, uint32_t *flags, struct list_head *buf_tracker) { int rc = 0, idx; bool retrieved_iova = false; struct kref *ref_count; *len_ptr = 0; if (!atomic_read(&cam_mem_mgr_state)) { CAM_ERR(CAM_MEM, "failed. mem_mgr not initialized"); return -EINVAL; } idx = CAM_MEM_MGR_GET_HDL_IDX(buf_handle); if (idx >= CAM_MEM_BUFQ_MAX || idx <= 0) return -ENOENT; if (!tbl.bufq[idx].active) { CAM_ERR(CAM_MEM, "Buffer at idx=%d is already unmapped,", idx); return -EAGAIN; } mutex_lock(&tbl.bufq[idx].q_lock); if (buf_handle != tbl.bufq[idx].buf_handle) { rc = -EINVAL; goto err; } if (flags) *flags = tbl.bufq[idx].flags; /* Try retrieving iova if saved previously */ rc = cam_mem_mgr_try_retrieving_hwva_locked(idx, mmu_handle, iova_ptr, len_ptr, buf_tracker); if (!rc) { retrieved_iova = true; goto end; } if (CAM_MEM_MGR_IS_SECURE_HDL(buf_handle)) rc = cam_smmu_get_stage2_iova(mmu_handle, tbl.bufq[idx].fd, tbl.bufq[idx].dma_buf, iova_ptr, len_ptr, buf_tracker, &ref_count); else rc = cam_smmu_get_iova(mmu_handle, tbl.bufq[idx].fd, tbl.bufq[idx].dma_buf, iova_ptr, len_ptr, buf_tracker, &ref_count); if (rc) { CAM_ERR(CAM_MEM, "failed to find buf_hdl:0x%x, mmu_hdl: 0x%x for fd:%d i_ino:%lu", buf_handle, mmu_handle, tbl.bufq[idx].fd, tbl.bufq[idx].i_ino); goto err; } /* Save iova in bufq for future use */ cam_mem_mgr_update_iova_info_locked(tbl.bufq[idx].hdls_info, *iova_ptr, mmu_handle, *len_ptr, false, ref_count); end: CAM_DBG(CAM_MEM, "handle:0x%x fd:%d i_ino:%lu iova_ptr:0x%lx len_ptr:%lu retrieved from bufq: %s", mmu_handle, tbl.bufq[idx].fd, tbl.bufq[idx].i_ino, *iova_ptr, *len_ptr, CAM_BOOL_TO_YESNO(retrieved_iova)); err: mutex_unlock(&tbl.bufq[idx].q_lock); return rc; } EXPORT_SYMBOL(cam_mem_get_io_buf); int cam_mem_get_cpu_buf(int32_t buf_handle, uintptr_t *vaddr_ptr, size_t *len) { int idx; if (!atomic_read(&cam_mem_mgr_state)) { CAM_ERR(CAM_MEM, "failed. mem_mgr not initialized"); return -EINVAL; } if (!buf_handle || !vaddr_ptr || !len) return -EINVAL; idx = CAM_MEM_MGR_GET_HDL_IDX(buf_handle); if (idx >= CAM_MEM_BUFQ_MAX || idx <= 0) return -EINVAL; if (!tbl.bufq[idx].active) { CAM_ERR(CAM_MEM, "Buffer at idx=%d is already unmapped,", idx); return -EPERM; } if (buf_handle != tbl.bufq[idx].buf_handle) { CAM_ERR(CAM_MEM, "idx: %d Invalid buf handle %d", idx, buf_handle); return -EINVAL; } if (!(tbl.bufq[idx].flags & CAM_MEM_FLAG_KMD_ACCESS)) { CAM_ERR(CAM_MEM, "idx: %d Invalid flag 0x%x", idx, tbl.bufq[idx].flags); return -EINVAL; } if (tbl.bufq[idx].kmdvaddr && kref_get_unless_zero(&tbl.bufq[idx].krefcount)) { *vaddr_ptr = tbl.bufq[idx].kmdvaddr; *len = tbl.bufq[idx].len; } else { CAM_ERR(CAM_MEM, "No KMD access requested, kmdvddr= %p, idx= %d, buf_handle= %d", tbl.bufq[idx].kmdvaddr, idx, buf_handle); return -EINVAL; } return 0; } EXPORT_SYMBOL(cam_mem_get_cpu_buf); int cam_mem_mgr_cache_ops(struct cam_mem_cache_ops_cmd *cmd) { int rc = 0, idx; uint32_t cache_dir; unsigned long dmabuf_flag = 0; if (!atomic_read(&cam_mem_mgr_state)) { CAM_ERR(CAM_MEM, "failed. mem_mgr not initialized"); return -EINVAL; } if (!cmd) return -EINVAL; idx = CAM_MEM_MGR_GET_HDL_IDX(cmd->buf_handle); if (idx >= CAM_MEM_BUFQ_MAX || idx <= 0) return -EINVAL; mutex_lock(&tbl.m_lock); if (!test_bit(idx, tbl.bitmap)) { CAM_ERR(CAM_MEM, "Buffer at idx=%d is already unmapped,", idx); mutex_unlock(&tbl.m_lock); return -EINVAL; } mutex_lock(&tbl.bufq[idx].q_lock); mutex_unlock(&tbl.m_lock); if (cmd->buf_handle != tbl.bufq[idx].buf_handle) { rc = -EINVAL; goto end; } rc = dma_buf_get_flags(tbl.bufq[idx].dma_buf, &dmabuf_flag); if (rc) { CAM_ERR(CAM_MEM, "cache get flags failed %d", rc); goto end; } #if IS_REACHABLE(CONFIG_DMABUF_HEAPS) CAM_DBG(CAM_MEM, "Calling dmap buf APIs for cache operations"); cache_dir = DMA_BIDIRECTIONAL; #else if (dmabuf_flag & ION_FLAG_CACHED) { switch (cmd->mem_cache_ops) { case CAM_MEM_CLEAN_CACHE: cache_dir = DMA_TO_DEVICE; break; case CAM_MEM_INV_CACHE: cache_dir = DMA_FROM_DEVICE; break; case CAM_MEM_CLEAN_INV_CACHE: cache_dir = DMA_BIDIRECTIONAL; break; default: CAM_ERR(CAM_MEM, "invalid cache ops :%d", cmd->mem_cache_ops); rc = -EINVAL; goto end; } } else { CAM_DBG(CAM_MEM, "BUF is not cached"); goto end; } #endif rc = dma_buf_begin_cpu_access(tbl.bufq[idx].dma_buf, (cmd->mem_cache_ops == CAM_MEM_CLEAN_INV_CACHE) ? DMA_BIDIRECTIONAL : DMA_TO_DEVICE); if (rc) { CAM_ERR(CAM_MEM, "dma begin access failed rc=%d", rc); goto end; } rc = dma_buf_end_cpu_access(tbl.bufq[idx].dma_buf, cache_dir); if (rc) { CAM_ERR(CAM_MEM, "dma end access failed rc=%d", rc); goto end; } end: mutex_unlock(&tbl.bufq[idx].q_lock); return rc; } EXPORT_SYMBOL(cam_mem_mgr_cache_ops); int cam_mem_mgr_cpu_access_op(struct cam_mem_cpu_access_op *cmd) { int rc = 0, idx; uint32_t direction; if (!atomic_read(&cam_mem_mgr_state)) { CAM_ERR(CAM_MEM, "failed. mem_mgr not initialized"); return -EINVAL; } if (!cmd) { CAM_ERR(CAM_MEM, "Invalid cmd"); return -EINVAL; } idx = CAM_MEM_MGR_GET_HDL_IDX(cmd->buf_handle); if (idx >= CAM_MEM_BUFQ_MAX || idx <= 0) { CAM_ERR(CAM_MEM, "Invalid idx=%d, buf_handle 0x%x, access=0x%x", idx, cmd->buf_handle, cmd->access); return -EINVAL; } mutex_lock(&tbl.m_lock); if (!test_bit(idx, tbl.bitmap)) { CAM_ERR(CAM_MEM, "Buffer at idx=%d is already freed/unmapped", idx); mutex_unlock(&tbl.m_lock); return -EINVAL; } mutex_lock(&tbl.bufq[idx].q_lock); mutex_unlock(&tbl.m_lock); if (cmd->buf_handle != tbl.bufq[idx].buf_handle) { CAM_ERR(CAM_MEM, "Buffer at idx=%d is different incoming handle 0x%x, actual handle 0x%x", idx, cmd->buf_handle, tbl.bufq[idx].buf_handle); rc = -EINVAL; goto end; } CAM_DBG(CAM_MEM, "buf_handle=0x%x, access=0x%x, access_type=0x%x, override_access=%d", cmd->buf_handle, cmd->access, cmd->access_type, g_cam_mem_mgr_debug.override_cpu_access_dir); if (cmd->access_type & CAM_MEM_CPU_ACCESS_READ && cmd->access_type & CAM_MEM_CPU_ACCESS_WRITE) { direction = DMA_BIDIRECTIONAL; } else if (cmd->access_type & CAM_MEM_CPU_ACCESS_READ) { direction = DMA_FROM_DEVICE; } else if (cmd->access_type & CAM_MEM_CPU_ACCESS_WRITE) { direction = DMA_TO_DEVICE; } else { direction = DMA_BIDIRECTIONAL; CAM_WARN(CAM_MEM, "Invalid access type buf_handle=0x%x, access=0x%x, access_type=0x%x", cmd->buf_handle, cmd->access, cmd->access_type); } if (g_cam_mem_mgr_debug.override_cpu_access_dir) direction = DMA_BIDIRECTIONAL; if (cmd->access & CAM_MEM_BEGIN_CPU_ACCESS) { rc = dma_buf_begin_cpu_access(tbl.bufq[idx].dma_buf, direction); if (rc) { CAM_ERR(CAM_MEM, "dma begin cpu access failed rc=%d, buf_handle=0x%x, access=0x%x, access_type=0x%x", rc, cmd->buf_handle, cmd->access, cmd->access_type); goto end; } } if (cmd->access & CAM_MEM_END_CPU_ACCESS) { rc = dma_buf_end_cpu_access(tbl.bufq[idx].dma_buf, direction); if (rc) { CAM_ERR(CAM_MEM, "dma end cpu access failed rc=%d, buf_handle=0x%x, access=0x%x, access_type=0x%x", rc, cmd->buf_handle, cmd->access, cmd->access_type); goto end; } } end: mutex_unlock(&tbl.bufq[idx].q_lock); return rc; } EXPORT_SYMBOL(cam_mem_mgr_cpu_access_op); #if IS_REACHABLE(CONFIG_DMABUF_HEAPS) #define CAM_MAX_VMIDS 4 static void cam_mem_mgr_put_dma_heaps(void) { CAM_DBG(CAM_MEM, "Releasing DMA Buf heaps usage"); } static int cam_mem_mgr_get_dma_heaps(void) { int rc = 0; tbl.system_heap = NULL; tbl.system_movable_heap = NULL; tbl.system_uncached_heap = NULL; tbl.camera_heap = NULL; tbl.camera_uncached_heap = NULL; tbl.secure_display_heap = NULL; tbl.ubwc_p_heap = NULL; tbl.ubwc_p_movable_heap = NULL; tbl.system_heap = dma_heap_find("qcom,system"); if (IS_ERR_OR_NULL(tbl.system_heap)) { rc = PTR_ERR(tbl.system_heap); CAM_ERR(CAM_MEM, "qcom system heap not found, rc=%d", rc); tbl.system_heap = NULL; goto put_heaps; } tbl.system_movable_heap = dma_heap_find("qcom,system-movable"); if (IS_ERR_OR_NULL(tbl.system_movable_heap)) { rc = PTR_ERR(tbl.system_movable_heap); CAM_DBG(CAM_MEM, "qcom system heap not found, rc=%d", rc); tbl.system_movable_heap = NULL; /* not fatal error, we can fallback to system heap */ } tbl.system_uncached_heap = dma_heap_find("qcom,system-uncached"); if (IS_ERR_OR_NULL(tbl.system_uncached_heap)) { if (tbl.force_cache_allocs) { /* optional, we anyway do not use uncached */ CAM_DBG(CAM_MEM, "qcom system-uncached heap not found, err=%d", PTR_ERR(tbl.system_uncached_heap)); tbl.system_uncached_heap = NULL; } else { /* fatal, must need uncached heaps */ rc = PTR_ERR(tbl.system_uncached_heap); CAM_ERR(CAM_MEM, "qcom system-uncached heap not found, rc=%d", rc); tbl.system_uncached_heap = NULL; goto put_heaps; } } tbl.ubwc_p_heap = dma_heap_find("qcom,ubwcp"); if (IS_ERR_OR_NULL(tbl.ubwc_p_heap)) { CAM_DBG(CAM_MEM, "qcom ubwcp heap not found, err=%d", PTR_ERR(tbl.ubwc_p_heap)); tbl.ubwc_p_heap = NULL; } tbl.ubwc_p_movable_heap = dma_heap_find("qcom,ubwcp-movable"); if (IS_ERR_OR_NULL(tbl.ubwc_p_movable_heap)) { CAM_DBG(CAM_MEM, "qcom ubwcp movable heap not found, err=%d", PTR_ERR(tbl.ubwc_p_movable_heap)); tbl.ubwc_p_movable_heap = NULL; } tbl.secure_display_heap = dma_heap_find("qcom,display"); if (IS_ERR_OR_NULL(tbl.secure_display_heap)) { rc = PTR_ERR(tbl.secure_display_heap); CAM_ERR(CAM_MEM, "qcom,display heap not found, rc=%d", rc); tbl.secure_display_heap = NULL; goto put_heaps; } tbl.camera_heap = dma_heap_find("qcom,camera"); if (IS_ERR_OR_NULL(tbl.camera_heap)) { /* optional heap, not a fatal error */ CAM_DBG(CAM_MEM, "qcom camera heap not found, err=%d", PTR_ERR(tbl.camera_heap)); tbl.camera_heap = NULL; } tbl.camera_uncached_heap = dma_heap_find("qcom,camera-uncached"); if (IS_ERR_OR_NULL(tbl.camera_uncached_heap)) { /* optional heap, not a fatal error */ CAM_DBG(CAM_MEM, "qcom camera heap not found, err=%d", PTR_ERR(tbl.camera_uncached_heap)); tbl.camera_uncached_heap = NULL; } CAM_INFO(CAM_MEM, "Heaps : system=%pK %pK, system_uncached=%pK, camera=%pK, camera-uncached=%pK, secure_display=%pK, ubwc_p=%pK %pK", tbl.system_heap, tbl.system_movable_heap, tbl.system_uncached_heap, tbl.camera_heap, tbl.camera_uncached_heap, tbl.secure_display_heap, tbl.ubwc_p_heap, tbl.ubwc_p_movable_heap); return 0; put_heaps: cam_mem_mgr_put_dma_heaps(); return rc; } int cam_mem_mgr_check_for_supported_heaps(uint64_t *heap_mask) { uint64_t heap_caps = 0; if (!heap_mask) return -EINVAL; if (tbl.ubwc_p_heap) heap_caps |= CAM_REQ_MGR_MEM_UBWC_P_HEAP_SUPPORTED; if ((tbl.camera_heap) || (tbl.camera_uncached_heap)) heap_caps |= CAM_REQ_MGR_MEM_CAMERA_HEAP_SUPPORTED; *heap_mask = heap_caps; return 0; } static int cam_mem_util_get_dma_buf(size_t len, unsigned int cam_flags, enum cam_mem_mgr_allocator alloc_type, struct dma_buf **buf, unsigned long *i_ino) { int rc = 0; struct dma_heap *heap = NULL, *try_heap = NULL; struct timespec64 ts1, ts2; long microsec = 0; bool use_cached_heap = false; struct mem_buf_lend_kernel_arg arg; int vmids[CAM_MAX_VMIDS]; int perms[CAM_MAX_VMIDS]; int num_vmids = 0; if (!buf) { CAM_ERR(CAM_MEM, "Invalid params"); return -EINVAL; } if (g_cam_mem_mgr_debug.alloc_profile_enable) CAM_GET_TIMESTAMP(ts1); if ((cam_flags & CAM_MEM_FLAG_CACHE) || (tbl.force_cache_allocs && (!(cam_flags & CAM_MEM_FLAG_PROTECTED_MODE)))) { CAM_DBG(CAM_MEM, "Using CACHED heap, cam_flags=0x%x, force_cache_allocs=%d", cam_flags, tbl.force_cache_allocs); use_cached_heap = true; } else if (cam_flags & CAM_MEM_FLAG_PROTECTED_MODE) { use_cached_heap = true; CAM_DBG(CAM_MEM, "Using CACHED heap for secure, cam_flags=0x%x, force_cache_allocs=%d", cam_flags, tbl.force_cache_allocs); } else { use_cached_heap = false; if (!tbl.system_uncached_heap && !tbl.camera_uncached_heap) { CAM_ERR(CAM_MEM, "Using UNCACHED heap not supported, cam_flags=0x%x, force_cache_allocs=%d", cam_flags, tbl.force_cache_allocs); return -EINVAL; } } if (cam_flags & CAM_MEM_FLAG_PROTECTED_MODE) { if (IS_CSF25(tbl.csf_version.arch_ver, tbl.csf_version.max_ver)) { heap = tbl.system_heap; len = cam_align_dma_buf_size(len); } else { heap = tbl.secure_display_heap; vmids[num_vmids] = VMID_CP_CAMERA; perms[num_vmids] = PERM_READ | PERM_WRITE; num_vmids++; } if (cam_flags & CAM_MEM_FLAG_CDSP_OUTPUT) { CAM_DBG(CAM_MEM, "Secure mode CDSP flags"); vmids[num_vmids] = VMID_CP_CDSP; perms[num_vmids] = PERM_READ | PERM_WRITE; num_vmids++; } } else if (cam_flags & CAM_MEM_FLAG_EVA_NOPIXEL) { heap = tbl.secure_display_heap; vmids[num_vmids] = VMID_CP_NON_PIXEL; perms[num_vmids] = PERM_READ | PERM_WRITE; num_vmids++; } else if (cam_flags & CAM_MEM_FLAG_UBWC_P_HEAP) { if (!tbl.ubwc_p_heap) { CAM_ERR(CAM_MEM, "ubwc-p heap is not available, can't allocate"); return -EINVAL; } if (tbl.ubwc_p_movable_heap && (alloc_type == CAM_MEMMGR_ALLOC_USER)) heap = tbl.ubwc_p_movable_heap; else heap = tbl.ubwc_p_heap; CAM_DBG(CAM_MEM, "Allocating from ubwc-p heap %pK, size=%d, flags=0x%x", heap, len, cam_flags); } else if (use_cached_heap) { /* * The default scheme is to try allocating from the camera heap * if available; if not, try for the system heap. Userland can also select * to pick a specific heap for allocation; this will deviate from the * default selection scheme. * */ if (!(cam_flags & CAM_MEM_FLAG_USE_SYS_HEAP_ONLY)) try_heap = tbl.camera_heap; if (!(cam_flags & CAM_MEM_FLAG_USE_CAMERA_HEAP_ONLY)) { if (tbl.system_movable_heap && (alloc_type == CAM_MEMMGR_ALLOC_USER)) heap = tbl.system_movable_heap; else heap = tbl.system_heap; } } else { if (!(cam_flags & CAM_MEM_FLAG_USE_SYS_HEAP_ONLY)) try_heap = tbl.camera_uncached_heap; if (!(cam_flags & CAM_MEM_FLAG_USE_CAMERA_HEAP_ONLY)) heap = tbl.system_uncached_heap; } CAM_DBG(CAM_MEM, "Using heaps : try=%pK, heap=%pK", try_heap, heap); *buf = NULL; if (!try_heap && !heap) { CAM_ERR(CAM_MEM, "No heap available for allocation, can't allocate flag: 0x%x", cam_flags); return -EINVAL; } if (try_heap) { *buf = dma_heap_buffer_alloc(try_heap, len, O_RDWR, 0); if (IS_ERR(*buf)) { CAM_WARN(CAM_MEM, "Failed in allocating from try heap, heap=%pK, len=%zu, err=%d", try_heap, len, PTR_ERR(*buf)); *buf = NULL; } } if (*buf == NULL) { *buf = dma_heap_buffer_alloc(heap, len, O_RDWR, 0); if (IS_ERR(*buf)) { rc = PTR_ERR(*buf); CAM_ERR(CAM_MEM, "Failed in allocating from heap, heap=%pK, len=%zu, err=%d", heap, len, rc); *buf = NULL; return rc; } } *i_ino = file_inode((*buf)->file)->i_ino; if (((cam_flags & CAM_MEM_FLAG_PROTECTED_MODE) && !IS_CSF25(tbl.csf_version.arch_ver, tbl.csf_version.max_ver)) || (cam_flags & CAM_MEM_FLAG_EVA_NOPIXEL)) { if (num_vmids >= CAM_MAX_VMIDS) { CAM_ERR(CAM_MEM, "Insufficient array size for vmids %d", num_vmids); rc = -EINVAL; goto end; } arg.nr_acl_entries = num_vmids; arg.vmids = vmids; arg.perms = perms; rc = mem_buf_lend(*buf, &arg); if (rc) { CAM_ERR(CAM_MEM, "Failed in buf lend rc=%d, buf=%pK, vmids [0]=0x%x, [1]=0x%x, [2]=0x%x", rc, *buf, vmids[0], vmids[1], vmids[2]); goto end; } } CAM_DBG(CAM_MEM, "Allocate success, len=%zu, *buf=%pK, i_ino=%lu", len, *buf, *i_ino); if (g_cam_mem_mgr_debug.alloc_profile_enable) { CAM_GET_TIMESTAMP(ts2); CAM_GET_TIMESTAMP_DIFF_IN_MICRO(ts1, ts2, microsec); trace_cam_log_event("IONAllocProfile", "size and time in micro", len, microsec); } return rc; end: dma_buf_put(*buf); return rc; } #else bool cam_mem_mgr_ubwc_p_heap_supported(void) { return false; } static int cam_mem_util_get_dma_buf(size_t len, unsigned int cam_flags, enum cam_mem_mgr_allocator alloc_type, struct dma_buf **buf, unsigned long *i_ino) { int rc = 0; unsigned int heap_id; int32_t ion_flag = 0; struct timespec64 ts1, ts2; long microsec = 0; if (!buf) { CAM_ERR(CAM_MEM, "Invalid params"); return -EINVAL; } if (cam_flags & CAM_MEM_FLAG_UBWC_P_HEAP) { CAM_ERR(CAM_MEM, "ubwcp heap not supported"); return -EINVAL; } if (g_cam_mem_mgr_debug.alloc_profile_enable) CAM_GET_TIMESTAMP(ts1); if ((cam_flags & CAM_MEM_FLAG_PROTECTED_MODE) && (cam_flags & CAM_MEM_FLAG_CDSP_OUTPUT)) { heap_id = ION_HEAP(ION_SECURE_DISPLAY_HEAP_ID); ion_flag |= ION_FLAG_SECURE | ION_FLAG_CP_CAMERA | ION_FLAG_CP_CDSP; } else if (cam_flags & CAM_MEM_FLAG_PROTECTED_MODE) { heap_id = ION_HEAP(ION_SECURE_DISPLAY_HEAP_ID); ion_flag |= ION_FLAG_SECURE | ION_FLAG_CP_CAMERA; } else { heap_id = ION_HEAP(ION_SYSTEM_HEAP_ID) | ION_HEAP(ION_CAMERA_HEAP_ID); } if (cam_flags & CAM_MEM_FLAG_CACHE) ion_flag |= ION_FLAG_CACHED; else ion_flag &= ~ION_FLAG_CACHED; if (tbl.force_cache_allocs && (!(ion_flag & ION_FLAG_SECURE))) ion_flag |= ION_FLAG_CACHED; *buf = ion_alloc(len, heap_id, ion_flag); if (IS_ERR_OR_NULL(*buf)) return -ENOMEM; *i_ino = file_inode((*buf)->file)->i_ino; if (g_cam_mem_mgr_debug.alloc_profile_enable) { CAM_GET_TIMESTAMP(ts2); CAM_GET_TIMESTAMP_DIFF_IN_MICRO(ts1, ts2, microsec); trace_cam_log_event("IONAllocProfile", "size and time in micro", len, microsec); } return rc; } #endif static int cam_mem_util_buffer_alloc(size_t len, uint32_t flags, struct dma_buf **dmabuf, int *fd, unsigned long *i_ino) { int rc; rc = cam_mem_util_get_dma_buf(len, flags, CAM_MEMMGR_ALLOC_USER, dmabuf, i_ino); if (rc) { CAM_ERR(CAM_MEM, "Error allocating dma buf : len=%llu, flags=0x%x", len, flags); return rc; } /* * increment the ref count so that ref count becomes 2 here * when we close fd, refcount becomes 1 and when we do * dmap_put_buf, ref count becomes 0 and memory will be freed. */ get_dma_buf(*dmabuf); *fd = dma_buf_fd(*dmabuf, O_CLOEXEC); if (*fd < 0) { CAM_ERR(CAM_MEM, "get fd fail, *fd=%d", *fd); rc = -EINVAL; goto put_buf; } CAM_DBG(CAM_MEM, "Alloc success : len=%zu, *dmabuf=%pK, fd=%d, i_ino=%lu", len, *dmabuf, *fd, *i_ino); return rc; put_buf: dma_buf_put(*dmabuf); return rc; } static int cam_mem_util_check_alloc_flags(struct cam_mem_mgr_alloc_cmd_v2 *cmd) { if (cmd->num_hdl > CAM_MEM_MMU_MAX_HANDLE) { CAM_ERR(CAM_MEM, "Num of mmu hdl exceeded maximum(%d)", CAM_MEM_MMU_MAX_HANDLE); return -EINVAL; } if (cmd->flags & CAM_MEM_FLAG_PROTECTED_MODE && cmd->flags & CAM_MEM_FLAG_KMD_ACCESS) { CAM_ERR(CAM_MEM, "Kernel mapping in secure mode not allowed"); return -EINVAL; } if ((cmd->flags & CAM_MEM_FLAG_EVA_NOPIXEL) && (cmd->flags & CAM_MEM_FLAG_PROTECTED_MODE || cmd->flags & CAM_MEM_FLAG_KMD_ACCESS)) { CAM_ERR(CAM_MEM, "Kernel mapping and secure mode not allowed in no pixel mode"); return -EINVAL; } if (cmd->flags & CAM_MEM_FLAG_UBWC_P_HEAP && (cmd->flags & CAM_MEM_FLAG_PROTECTED_MODE || cmd->flags & CAM_MEM_FLAG_EVA_NOPIXEL || cmd->flags & CAM_MEM_FLAG_KMD_ACCESS || cmd->flags & CAM_MEM_FLAG_CMD_BUF_TYPE || cmd->flags & CAM_MEM_FLAG_HW_SHARED_ACCESS || cmd->flags & CAM_MEM_FLAG_HW_AND_CDM_OR_SHARED)) { CAM_ERR(CAM_MEM, "UBWC-P buffer not supported with this combinatation of flags 0x%x", cmd->flags); return -EINVAL; } return 0; } static int cam_mem_util_check_map_flags(struct cam_mem_mgr_map_cmd_v2 *cmd) { if (!cmd->flags) { CAM_ERR(CAM_MEM, "Invalid flags"); return -EINVAL; } if (cmd->num_hdl > CAM_MEM_MMU_MAX_HANDLE) { CAM_ERR(CAM_MEM, "Num of mmu hdl %d exceeded maximum(%d)", cmd->num_hdl, CAM_MEM_MMU_MAX_HANDLE); return -EINVAL; } if (cmd->flags & CAM_MEM_FLAG_PROTECTED_MODE && cmd->flags & CAM_MEM_FLAG_KMD_ACCESS) { CAM_ERR(CAM_MEM, "Kernel mapping in secure mode not allowed, flags=0x%x", cmd->flags); return -EINVAL; } if (cmd->flags & CAM_MEM_FLAG_HW_SHARED_ACCESS) { CAM_ERR(CAM_MEM, "Shared memory buffers are not allowed to be mapped"); return -EINVAL; } return 0; } static int cam_mem_util_map_hw_va(uint32_t flags, int32_t *mmu_hdls, int32_t num_hdls, int fd, struct dma_buf *dmabuf, struct cam_mem_buf_hw_hdl_info *hw_vaddr_info_arr, size_t *len, enum cam_smmu_region_id region, bool is_internal) { int i; int rc = -1; int dir = cam_mem_util_get_dma_dir(flags); bool dis_delayed_unmap = false; dma_addr_t hw_vaddr; struct kref *ref_count; struct cam_mem_buf_hw_hdl_info *hdl_info = NULL; if (dir < 0) { CAM_ERR(CAM_MEM, "fail to map DMA direction, dir=%d", dir); return dir; } if (flags & CAM_MEM_FLAG_DISABLE_DELAYED_UNMAP) dis_delayed_unmap = true; CAM_DBG(CAM_MEM, "map_hw_va : fd = %d, flags = 0x%x, dir=%d, num_hdls=%d", fd, flags, dir, num_hdls); for (i = 0; i < num_hdls; i++) { if (cam_mem_mgr_is_iova_info_updated_locked(hw_vaddr_info_arr, mmu_hdls[i])) continue; /* If 36-bit enabled, check for ICP cmd buffers and map them within the shared region */ if (cam_smmu_is_expanded_memory() && cam_smmu_supports_shared_region(mmu_hdls[i]) && ((flags & CAM_MEM_FLAG_CMD_BUF_TYPE) || (flags & CAM_MEM_FLAG_HW_AND_CDM_OR_SHARED))) region = CAM_SMMU_REGION_SHARED; if (flags & CAM_MEM_FLAG_PROTECTED_MODE) rc = cam_smmu_map_stage2_iova(mmu_hdls[i], fd, dmabuf, dir, &hw_vaddr, len, &ref_count); else rc = cam_smmu_map_user_iova(mmu_hdls[i], fd, dmabuf, dis_delayed_unmap, dir, &hw_vaddr, len, region, is_internal, &ref_count); if (rc) { CAM_ERR(CAM_MEM, "Failed %s map to smmu, i=%d, fd=%d, dir=%d, mmu_hdl=%d, rc=%d", (flags & CAM_MEM_FLAG_PROTECTED_MODE) ? "" : "secured", i, fd, dir, mmu_hdls[i], rc); goto multi_map_fail; } /* cache hw va */ cam_mem_mgr_update_iova_info_locked(hw_vaddr_info_arr, hw_vaddr, mmu_hdls[i], *len, true, ref_count); } return rc; multi_map_fail: for (i = 0; i < tbl.max_hdls_supported; i++) { if (!hw_vaddr_info_arr[i].valid_mapping) continue; hdl_info = &hw_vaddr_info_arr[i]; if (flags & CAM_MEM_FLAG_PROTECTED_MODE) cam_smmu_unmap_stage2_iova(hdl_info->iommu_hdl, fd, dmabuf, false); else cam_smmu_unmap_user_iova(hdl_info->iommu_hdl, fd, dmabuf, CAM_SMMU_REGION_IO, false); } /* reset any updated entries */ memset(hw_vaddr_info_arr, 0x0, tbl.max_hdls_info_size); return rc; } int cam_mem_mgr_alloc_and_map(struct cam_mem_mgr_alloc_cmd_v2 *cmd) { int rc, idx; struct dma_buf *dmabuf = NULL; int fd = -1; size_t len; uintptr_t kvaddr = 0; size_t klen; unsigned long i_ino = 0; if (!atomic_read(&cam_mem_mgr_state)) { CAM_ERR(CAM_MEM, "failed. mem_mgr not initialized"); return -EINVAL; } if (!cmd) { CAM_ERR(CAM_MEM, " Invalid argument"); return -EINVAL; } if (cmd->num_hdl > tbl.max_hdls_supported) { CAM_ERR(CAM_MEM, "Num of mmu hdl %d exceeded maximum(%d)", cmd->num_hdl, tbl.max_hdls_supported); return -EINVAL; } len = cmd->len; if (tbl.need_shared_buffer_padding && (cmd->flags & CAM_MEM_FLAG_HW_SHARED_ACCESS)) { len += CAM_MEM_SHARED_BUFFER_PAD_4K; CAM_DBG(CAM_MEM, "Pad 4k size, actual %llu, allocating %zu", cmd->len, len); } rc = cam_mem_util_check_alloc_flags(cmd); if (rc) { CAM_ERR(CAM_MEM, "Invalid flags: flags = 0x%X, rc=%d", cmd->flags, rc); return rc; } rc = cam_mem_util_buffer_alloc(len, cmd->flags, &dmabuf, &fd, &i_ino); if (rc) { CAM_ERR(CAM_MEM, "Ion Alloc failed, len=%llu, align=%llu, flags=0x%x, num_hdl=%d", len, cmd->align, cmd->flags, cmd->num_hdl); cam_mem_mgr_print_tbl(); return rc; } if (!dmabuf) { CAM_ERR(CAM_MEM, "Ion Alloc return NULL dmabuf! fd=%d, i_ino=%lu, len=%d", fd, i_ino, len); cam_mem_mgr_print_tbl(); return rc; } idx = cam_mem_get_slot(); if (idx < 0) { CAM_ERR(CAM_MEM, "Failed in getting mem slot, idx=%d", idx); rc = -ENOMEM; cam_mem_mgr_print_tbl(); goto slot_fail; } if (cam_dma_buf_set_name(dmabuf, cmd->buf_name)) CAM_ERR(CAM_MEM, "set dma buffer name(%s) failed", cmd->buf_name); if ((cmd->flags & CAM_MEM_FLAG_HW_READ_WRITE) || (cmd->flags & CAM_MEM_FLAG_HW_SHARED_ACCESS) || (cmd->flags & CAM_MEM_FLAG_PROTECTED_MODE)) { enum cam_smmu_region_id region; if (cmd->flags & CAM_MEM_FLAG_HW_READ_WRITE) region = CAM_SMMU_REGION_IO; if (cmd->flags & CAM_MEM_FLAG_HW_SHARED_ACCESS) region = CAM_SMMU_REGION_SHARED; if (cmd->flags & CAM_MEM_FLAG_PROTECTED_MODE) region = CAM_SMMU_REGION_IO; rc = cam_mem_util_map_hw_va(cmd->flags, cmd->mmu_hdls, cmd->num_hdl, fd, dmabuf, tbl.bufq[idx].hdls_info, &len, region, true); if (rc) { CAM_ERR(CAM_MEM, "Failed in map_hw_va len=%llu, flags=0x%x, fd=%d, region=%d, num_hdl=%d, rc=%d", len, cmd->flags, fd, region, cmd->num_hdl, rc); if (rc == -EALREADY) { if ((size_t)dmabuf->size != len) rc = -EBADR; cam_mem_mgr_print_tbl(); } goto map_hw_fail; } } mutex_lock(&tbl.bufq[idx].q_lock); tbl.bufq[idx].fd = fd; tbl.bufq[idx].i_ino = i_ino; tbl.bufq[idx].dma_buf = NULL; tbl.bufq[idx].flags = cmd->flags; tbl.bufq[idx].buf_handle = GET_MEM_HANDLE(idx, fd); tbl.bufq[idx].is_internal = true; if (cmd->flags & CAM_MEM_FLAG_PROTECTED_MODE) CAM_MEM_MGR_SET_SECURE_HDL(tbl.bufq[idx].buf_handle, true); if (cmd->flags & CAM_MEM_FLAG_KMD_ACCESS) { rc = cam_mem_util_map_cpu_va(dmabuf, &kvaddr, &klen); if (rc) { CAM_ERR(CAM_MEM, "dmabuf: %pK mapping failed: %d", dmabuf, rc); goto map_kernel_fail; } } if (cmd->flags & CAM_MEM_FLAG_KMD_DEBUG_FLAG) tbl.dbg_buf_idx = idx; tbl.bufq[idx].kmdvaddr = kvaddr; tbl.bufq[idx].dma_buf = dmabuf; tbl.bufq[idx].len = len; tbl.bufq[idx].num_hdls = cmd->num_hdl; cam_mem_mgr_reset_presil_params(idx); tbl.bufq[idx].is_imported = false; if (cmd->flags & CAM_MEM_FLAG_KMD_ACCESS) kref_init(&tbl.bufq[idx].krefcount); kref_init(&tbl.bufq[idx].urefcount); tbl.bufq[idx].smmu_mapping_client = CAM_SMMU_MAPPING_USER; strscpy(tbl.bufq[idx].buf_name, cmd->buf_name, sizeof(tbl.bufq[idx].buf_name)); mutex_unlock(&tbl.bufq[idx].q_lock); cmd->out.buf_handle = tbl.bufq[idx].buf_handle; cmd->out.fd = tbl.bufq[idx].fd; cmd->out.vaddr = 0; CAM_DBG(CAM_MEM, "fd=%d, flags=0x%x, num_hdl=%d, idx=%d, buf handle=%x, len=%zu, i_ino=%lu, name:%s", cmd->out.fd, cmd->flags, cmd->num_hdl, idx, cmd->out.buf_handle, tbl.bufq[idx].len, tbl.bufq[idx].i_ino, cmd->buf_name); return rc; map_kernel_fail: mutex_unlock(&tbl.bufq[idx].q_lock); map_hw_fail: cam_mem_put_slot(idx); slot_fail: dma_buf_put(dmabuf); return rc; } static bool cam_mem_util_is_map_internal(int32_t fd, unsigned i_ino) { uint32_t i; bool is_internal = false; mutex_lock(&tbl.m_lock); for_each_set_bit(i, tbl.bitmap, tbl.bits) { if ((tbl.bufq[i].fd == fd) && (tbl.bufq[i].i_ino == i_ino)) { is_internal = tbl.bufq[i].is_internal; break; } } mutex_unlock(&tbl.m_lock); return is_internal; } int cam_mem_mgr_map(struct cam_mem_mgr_map_cmd_v2 *cmd) { int32_t idx; int rc; struct dma_buf *dmabuf; size_t len = 0; bool is_internal = false; unsigned long i_ino; if (!atomic_read(&cam_mem_mgr_state)) { CAM_ERR(CAM_MEM, "failed. mem_mgr not initialized"); return -EINVAL; } if (!cmd || (cmd->fd < 0)) { CAM_ERR(CAM_MEM, "Invalid argument"); return -EINVAL; } if (cmd->num_hdl > tbl.max_hdls_supported) { CAM_ERR(CAM_MEM, "Num of mmu hdl %d exceeded maximum(%d)", cmd->num_hdl, tbl.max_hdls_supported); return -EINVAL; } rc = cam_mem_util_check_map_flags(cmd); if (rc) { CAM_ERR(CAM_MEM, "Invalid flags: flags = %X", cmd->flags); return rc; } dmabuf = dma_buf_get(cmd->fd); if (IS_ERR_OR_NULL((void *)(dmabuf))) { CAM_ERR(CAM_MEM, "Failed to import dma_buf fd"); return -EINVAL; } i_ino = file_inode(dmabuf->file)->i_ino; is_internal = cam_mem_util_is_map_internal(cmd->fd, i_ino); idx = cam_mem_get_slot(); if (idx < 0) { CAM_ERR(CAM_MEM, "Failed in getting mem slot, idx=%d, fd=%d", idx, cmd->fd); rc = -ENOMEM; cam_mem_mgr_print_tbl(); goto slot_fail; } if (cam_dma_buf_set_name(dmabuf, cmd->buf_name)) CAM_DBG(CAM_MEM, "Dma buffer (%s) busy", cmd->buf_name); if ((cmd->flags & CAM_MEM_FLAG_HW_READ_WRITE) || (cmd->flags & CAM_MEM_FLAG_PROTECTED_MODE)) { rc = cam_mem_util_map_hw_va(cmd->flags, cmd->mmu_hdls, cmd->num_hdl, cmd->fd, dmabuf, tbl.bufq[idx].hdls_info, &len, CAM_SMMU_REGION_IO, is_internal); if (rc) { CAM_ERR(CAM_MEM, "Failed in map_hw_va, flags=0x%x, fd=%d, len=%llu, region=%d, num_hdl=%d, rc=%d", cmd->flags, cmd->fd, len, CAM_SMMU_REGION_IO, cmd->num_hdl, rc); if (rc == -EALREADY) { if ((size_t)dmabuf->size != len) { rc = -EBADR; cam_mem_mgr_print_tbl(); } } goto map_fail; } } mutex_lock(&tbl.bufq[idx].q_lock); tbl.bufq[idx].fd = cmd->fd; tbl.bufq[idx].i_ino = i_ino; tbl.bufq[idx].dma_buf = NULL; tbl.bufq[idx].flags = cmd->flags; tbl.bufq[idx].buf_handle = GET_MEM_HANDLE(idx, cmd->fd); if (cmd->flags & CAM_MEM_FLAG_PROTECTED_MODE) CAM_MEM_MGR_SET_SECURE_HDL(tbl.bufq[idx].buf_handle, true); tbl.bufq[idx].kmdvaddr = 0; tbl.bufq[idx].dma_buf = dmabuf; tbl.bufq[idx].len = len; tbl.bufq[idx].num_hdls = cmd->num_hdl; tbl.bufq[idx].is_imported = true; tbl.bufq[idx].is_internal = is_internal; if (cmd->flags & CAM_MEM_FLAG_KMD_ACCESS) kref_init(&tbl.bufq[idx].krefcount); kref_init(&tbl.bufq[idx].urefcount); tbl.bufq[idx].smmu_mapping_client = CAM_SMMU_MAPPING_USER; strscpy(tbl.bufq[idx].buf_name, cmd->buf_name, sizeof(tbl.bufq[idx].buf_name)); mutex_unlock(&tbl.bufq[idx].q_lock); cmd->out.buf_handle = tbl.bufq[idx].buf_handle; cmd->out.vaddr = 0; cmd->out.size = (uint32_t)len; CAM_DBG(CAM_MEM, "fd=%d, flags=0x%x, num_hdl=%d, idx=%d, buf handle=%x, len=%zu, i_ino=%lu, name:%s", cmd->fd, cmd->flags, cmd->num_hdl, idx, cmd->out.buf_handle, tbl.bufq[idx].len, tbl.bufq[idx].i_ino, cmd->buf_name); return rc; map_fail: cam_mem_put_slot(idx); slot_fail: dma_buf_put(dmabuf); return rc; } static int cam_mem_util_unmap_hw_va(int32_t idx, enum cam_smmu_region_id region, enum cam_smmu_mapping_client client, bool force_unmap) { int i, fd, num_hdls; uint32_t flags; struct cam_mem_buf_hw_hdl_info *hdl_info = NULL; struct dma_buf *dma_buf; unsigned long i_ino; int rc = 0; if (idx >= CAM_MEM_BUFQ_MAX || idx <= 0) { CAM_ERR(CAM_MEM, "Incorrect index"); return -EINVAL; } flags = tbl.bufq[idx].flags; num_hdls = tbl.bufq[idx].num_hdls; fd = tbl.bufq[idx].fd; dma_buf = tbl.bufq[idx].dma_buf; i_ino = tbl.bufq[idx].i_ino; if (unlikely(!num_hdls)) { CAM_DBG(CAM_MEM, "No valid handles to unmap"); return 0; } CAM_DBG(CAM_MEM, "unmap_hw_va : idx=%d, fd=%x, i_ino=%lu flags=0x%x, num_hdls=%d, client=%d", idx, fd, i_ino, flags, tbl.bufq[idx].num_hdls, client); for (i = 0; i < tbl.max_hdls_supported; i++) { if (!tbl.bufq[idx].hdls_info[i].valid_mapping) continue; hdl_info = &tbl.bufq[idx].hdls_info[i]; if (flags & CAM_MEM_FLAG_PROTECTED_MODE) rc = cam_smmu_unmap_stage2_iova(hdl_info->iommu_hdl, fd, dma_buf, force_unmap); else if (client == CAM_SMMU_MAPPING_USER) rc = cam_smmu_unmap_user_iova(hdl_info->iommu_hdl, fd, dma_buf, region, force_unmap); else if (client == CAM_SMMU_MAPPING_KERNEL) rc = cam_smmu_unmap_kernel_iova(hdl_info->iommu_hdl, tbl.bufq[idx].dma_buf, region); else { CAM_ERR(CAM_MEM, "invalid caller for unmapping : %d", client); rc = -EINVAL; goto end; } if (rc < 0) { CAM_ERR(CAM_MEM, "Failed in %s unmap, i=%d, fd=%d, i_ino=%lu, mmu_hdl=%d, rc=%d", ((flags & CAM_MEM_FLAG_PROTECTED_MODE) ? "secure" : "non-secure"), i, fd, i_ino, hdl_info->iommu_hdl, rc); goto end; } CAM_DBG(CAM_MEM, "i: %d unmap_hw_va : idx=%d, fd=%x, i_ino=%lu flags=0x%x, num_hdls=%d, client=%d hdl: %d", i, idx, fd, i_ino, flags, tbl.bufq[idx].num_hdls, client, hdl_info->iommu_hdl); /* exit loop if all handles for this buffer have been unmapped */ if (!(--num_hdls)) break; } end: return rc; } static void cam_mem_mgr_unmap_active_buf(int idx) { enum cam_smmu_region_id region = CAM_SMMU_REGION_SHARED; if (tbl.bufq[idx].flags & CAM_MEM_FLAG_HW_SHARED_ACCESS) region = CAM_SMMU_REGION_SHARED; else if (tbl.bufq[idx].flags & CAM_MEM_FLAG_HW_READ_WRITE) region = CAM_SMMU_REGION_IO; cam_mem_util_unmap_hw_va(idx, region, CAM_SMMU_MAPPING_USER, true); if (tbl.bufq[idx].flags & CAM_MEM_FLAG_KMD_ACCESS) cam_mem_util_unmap_cpu_va(tbl.bufq[idx].dma_buf, tbl.bufq[idx].kmdvaddr); } static int cam_mem_mgr_cleanup_table(void) { int i; mutex_lock(&tbl.m_lock); for (i = 1; i < CAM_MEM_BUFQ_MAX; i++) { if (!tbl.bufq[i].active) { CAM_DBG(CAM_MEM, "Buffer inactive at idx=%d, continuing", i); continue; } else { CAM_DBG(CAM_MEM, "Active buffer at idx=%d, possible leak needs unmapping", i); cam_mem_mgr_unmap_active_buf(i); } mutex_lock(&tbl.bufq[i].q_lock); if (tbl.bufq[i].dma_buf) { dma_buf_put(tbl.bufq[i].dma_buf); tbl.bufq[i].dma_buf = NULL; } tbl.bufq[i].fd = -1; tbl.bufq[i].i_ino = 0; tbl.bufq[i].flags = 0; tbl.bufq[i].buf_handle = -1; tbl.bufq[i].len = 0; tbl.bufq[i].num_hdls = 0; tbl.bufq[i].dma_buf = NULL; tbl.bufq[i].active = false; tbl.bufq[i].release_deferred = false; tbl.bufq[i].is_internal = false; memset(tbl.bufq[i].hdls_info, 0x0, tbl.max_hdls_info_size); cam_mem_mgr_reset_presil_params(i); kref_init(&tbl.bufq[i].krefcount); kref_init(&tbl.bufq[i].urefcount); mutex_unlock(&tbl.bufq[i].q_lock); mutex_destroy(&tbl.bufq[i].q_lock); } bitmap_zero(tbl.bitmap, tbl.bits); /* We need to reserve slot 0 because 0 is invalid */ set_bit(0, tbl.bitmap); mutex_unlock(&tbl.m_lock); return 0; } void cam_mem_mgr_deinit(void) { int i; if (!atomic_read(&cam_mem_mgr_state)) return; atomic_set(&cam_mem_mgr_state, CAM_MEM_MGR_UNINITIALIZED); cam_mem_mgr_cleanup_table(); cam_smmu_driver_deinit(); mutex_lock(&tbl.m_lock); bitmap_zero(tbl.bitmap, tbl.bits); kfree(tbl.bitmap); tbl.bitmap = NULL; tbl.dbg_buf_idx = -1; /* index 0 is reserved */ for (i = 1; i < CAM_MEM_BUFQ_MAX; i++) { kfree(tbl.bufq[i].hdls_info); tbl.bufq[i].hdls_info = NULL; } mutex_unlock(&tbl.m_lock); mutex_destroy(&tbl.m_lock); } static void cam_mem_util_unmap_dummy(struct kref *kref) { CAM_DBG(CAM_MEM, "Cam mem util unmap dummy"); } static void cam_mem_util_unmap(int32_t idx) { int rc = 0; enum cam_smmu_region_id region = CAM_SMMU_REGION_SHARED; enum cam_smmu_mapping_client client; if (idx >= CAM_MEM_BUFQ_MAX || idx <= 0) { CAM_ERR(CAM_MEM, "Incorrect index"); return; } client = tbl.bufq[idx].smmu_mapping_client; CAM_DBG(CAM_MEM, "Flags = %X idx %d", tbl.bufq[idx].flags, idx); mutex_lock(&tbl.m_lock); if (!tbl.bufq[idx].active) { CAM_WARN(CAM_MEM, "Buffer at idx=%d is already unmapped", idx); mutex_unlock(&tbl.m_lock); return; } /* Deactivate the buffer queue to prevent multiple unmap */ mutex_lock(&tbl.bufq[idx].q_lock); tbl.bufq[idx].active = false; tbl.bufq[idx].release_deferred = false; mutex_unlock(&tbl.bufq[idx].q_lock); mutex_unlock(&tbl.m_lock); if (tbl.bufq[idx].flags & CAM_MEM_FLAG_KMD_ACCESS) { if (tbl.bufq[idx].dma_buf && tbl.bufq[idx].kmdvaddr) { rc = cam_mem_util_unmap_cpu_va(tbl.bufq[idx].dma_buf, tbl.bufq[idx].kmdvaddr); if (rc) CAM_ERR(CAM_MEM, "Failed, dmabuf=%pK, kmdvaddr=%pK", tbl.bufq[idx].dma_buf, (void *) tbl.bufq[idx].kmdvaddr); } } /* SHARED flag gets precedence, all other flags after it */ if (tbl.bufq[idx].flags & CAM_MEM_FLAG_HW_SHARED_ACCESS) { region = CAM_SMMU_REGION_SHARED; } else { if (tbl.bufq[idx].flags & CAM_MEM_FLAG_HW_READ_WRITE) region = CAM_SMMU_REGION_IO; } if ((tbl.bufq[idx].flags & CAM_MEM_FLAG_HW_READ_WRITE) || (tbl.bufq[idx].flags & CAM_MEM_FLAG_HW_SHARED_ACCESS) || (tbl.bufq[idx].flags & CAM_MEM_FLAG_PROTECTED_MODE)) { rc = cam_mem_util_unmap_hw_va(idx, region, client, false); if (rc) CAM_ERR(CAM_MEM, "Failed, dmabuf=%pK", tbl.bufq[idx].dma_buf); } mutex_lock(&tbl.m_lock); mutex_lock(&tbl.bufq[idx].q_lock); tbl.bufq[idx].flags = 0; tbl.bufq[idx].buf_handle = -1; CAM_DBG(CAM_MEM, "Ion buf at idx = %d freeing fd = %d, imported %d, dma_buf %pK, i_ino %lu", idx, tbl.bufq[idx].fd, tbl.bufq[idx].is_imported, tbl.bufq[idx].dma_buf, tbl.bufq[idx].i_ino); if (tbl.bufq[idx].dma_buf) dma_buf_put(tbl.bufq[idx].dma_buf); tbl.bufq[idx].fd = -1; tbl.bufq[idx].i_ino = 0; tbl.bufq[idx].dma_buf = NULL; tbl.bufq[idx].is_imported = false; tbl.bufq[idx].is_internal = false; tbl.bufq[idx].len = 0; tbl.bufq[idx].num_hdls = 0; memset(tbl.bufq[idx].hdls_info, 0x0, tbl.max_hdls_info_size); cam_mem_mgr_reset_presil_params(idx); memset(&tbl.bufq[idx].timestamp, 0, sizeof(struct timespec64)); memset(&tbl.bufq[idx].krefcount, 0, sizeof(struct kref)); memset(&tbl.bufq[idx].urefcount, 0, sizeof(struct kref)); mutex_unlock(&tbl.bufq[idx].q_lock); mutex_destroy(&tbl.bufq[idx].q_lock); clear_bit(idx, tbl.bitmap); mutex_unlock(&tbl.m_lock); } static void cam_mem_util_unmap_wrapper(struct kref *kref) { int32_t idx; struct cam_mem_buf_queue *bufq = container_of(kref, typeof(*bufq), krefcount); idx = CAM_MEM_MGR_GET_HDL_IDX(bufq->buf_handle); if (idx >= CAM_MEM_BUFQ_MAX || idx <= 0) { CAM_ERR(CAM_MEM, "idx: %d not valid", idx); return; } cam_mem_util_unmap(idx); } void cam_mem_put_cpu_buf(int32_t buf_handle) { int idx; uint64_t ms, hrs, min, sec; struct timespec64 current_ts; uint32_t krefcount = 0, urefcount = 0; bool unmap = false; if (!buf_handle) { CAM_ERR(CAM_MEM, "Invalid buf_handle"); return; } idx = CAM_MEM_MGR_GET_HDL_IDX(buf_handle); if (idx >= CAM_MEM_BUFQ_MAX || idx <= 0) { CAM_ERR(CAM_MEM, "idx: %d not valid", idx); return; } if (!tbl.bufq[idx].active) { CAM_ERR(CAM_MEM, "idx: %d not active", idx); return; } if (buf_handle != tbl.bufq[idx].buf_handle) { CAM_ERR(CAM_MEM, "idx: %d Invalid buf handle %d", idx, buf_handle); return; } kref_put(&tbl.bufq[idx].krefcount, cam_mem_util_unmap_dummy); krefcount = kref_read(&tbl.bufq[idx].krefcount); urefcount = kref_read(&tbl.bufq[idx].urefcount); if ((krefcount == 1) && (urefcount == 0)) unmap = true; if (unmap) { cam_mem_util_unmap(idx); CAM_GET_TIMESTAMP(current_ts); CAM_CONVERT_TIMESTAMP_FORMAT(current_ts, hrs, min, sec, ms); CAM_DBG(CAM_MEM, "%llu:%llu:%llu:%llu Called unmap from here, buf_handle: %u, idx: %d", hrs, min, sec, ms, buf_handle, idx); } else if (tbl.bufq[idx].release_deferred) { CAM_CONVERT_TIMESTAMP_FORMAT((tbl.bufq[idx].timestamp), hrs, min, sec, ms); CAM_ERR(CAM_MEM, "%llu:%llu:%llu:%llu idx %d fd %d i_ino %lu size %llu active %d buf_handle %d krefCount %d urefCount %d buf_name %s", hrs, min, sec, ms, idx, tbl.bufq[idx].fd, tbl.bufq[idx].i_ino, tbl.bufq[idx].len, tbl.bufq[idx].active, tbl.bufq[idx].buf_handle, krefcount, urefcount, tbl.bufq[idx].buf_name); CAM_GET_TIMESTAMP(current_ts); CAM_CONVERT_TIMESTAMP_FORMAT(current_ts, hrs, min, sec, ms); CAM_ERR(CAM_MEM, "%llu:%llu:%llu:%llu Not unmapping even after defer, buf_handle: %u, idx: %d", hrs, min, sec, ms, buf_handle, idx); } else if (krefcount == 0) { CAM_ERR(CAM_MEM, "Unbalanced release Called buf_handle: %u, idx: %d", tbl.bufq[idx].buf_handle, idx); } } EXPORT_SYMBOL(cam_mem_put_cpu_buf); int cam_mem_mgr_release(struct cam_mem_mgr_release_cmd *cmd) { int idx; int rc = 0; uint64_t ms, hrs, min, sec; struct timespec64 current_ts; uint32_t krefcount = 0, urefcount = 0; bool unmap = false; if (!atomic_read(&cam_mem_mgr_state)) { CAM_ERR(CAM_MEM, "failed. mem_mgr not initialized"); return -EINVAL; } if (!cmd) { CAM_ERR(CAM_MEM, "Invalid argument"); return -EINVAL; } idx = CAM_MEM_MGR_GET_HDL_IDX(cmd->buf_handle); if (idx >= CAM_MEM_BUFQ_MAX || idx <= 0) { CAM_ERR(CAM_MEM, "Incorrect index %d extracted from mem handle", idx); return -EINVAL; } if (!tbl.bufq[idx].active) { CAM_ERR(CAM_MEM, "Released buffer state should be active"); return -EINVAL; } if (tbl.bufq[idx].buf_handle != cmd->buf_handle) { CAM_ERR(CAM_MEM, "Released buf handle %d not matching within table %d, idx=%d", cmd->buf_handle, tbl.bufq[idx].buf_handle, idx); return -EINVAL; } CAM_DBG(CAM_MEM, "Releasing hdl = %x, idx = %d", cmd->buf_handle, idx); kref_put(&tbl.bufq[idx].urefcount, cam_mem_util_unmap_dummy); urefcount = kref_read(&tbl.bufq[idx].urefcount); if (tbl.bufq[idx].flags & CAM_MEM_FLAG_KMD_ACCESS) { krefcount = kref_read(&tbl.bufq[idx].krefcount); if ((krefcount == 1) && (urefcount == 0)) unmap = true; } else { if (urefcount == 0) unmap = true; } if (unmap) { cam_mem_util_unmap(idx); CAM_DBG(CAM_MEM, "Called unmap from here, buf_handle: %u, idx: %d", cmd->buf_handle, idx); } else if (tbl.bufq[idx].flags & CAM_MEM_FLAG_KMD_ACCESS) { rc = -EINVAL; CAM_GET_TIMESTAMP(current_ts); CAM_CONVERT_TIMESTAMP_FORMAT(current_ts, hrs, min, sec, ms); CAM_CONVERT_TIMESTAMP_FORMAT((tbl.bufq[idx].timestamp), hrs, min, sec, ms); CAM_ERR(CAM_MEM, "%llu:%llu:%llu:%llu idx %d fd %d i_ino %lu size %llu active %d buf_handle %d krefCount %d urefCount %d buf_name %s", hrs, min, sec, ms, idx, tbl.bufq[idx].fd, tbl.bufq[idx].i_ino, tbl.bufq[idx].len, tbl.bufq[idx].active, tbl.bufq[idx].buf_handle, krefcount, urefcount, tbl.bufq[idx].buf_name); if (tbl.bufq[idx].release_deferred) CAM_ERR(CAM_MEM, "Unbalanced release Called buf_handle: %u, idx: %d", tbl.bufq[idx].buf_handle, idx); tbl.bufq[idx].release_deferred = true; } return rc; } int cam_mem_mgr_request_mem(struct cam_mem_mgr_request_desc *inp, struct cam_mem_mgr_memory_desc *out) { struct dma_buf *buf = NULL; int ion_fd = -1, rc = 0; uintptr_t kvaddr; dma_addr_t iova = 0; size_t request_len = 0; uint32_t mem_handle; int32_t idx; int32_t smmu_hdl = 0; unsigned long i_ino = 0; enum cam_smmu_region_id region = CAM_SMMU_REGION_SHARED; if (!atomic_read(&cam_mem_mgr_state)) { CAM_ERR(CAM_MEM, "failed. mem_mgr not initialized"); return -EINVAL; } if (!inp || !out) { CAM_ERR(CAM_MEM, "Invalid params"); return -EINVAL; } if (!(inp->flags & CAM_MEM_FLAG_HW_READ_WRITE || inp->flags & CAM_MEM_FLAG_HW_SHARED_ACCESS || inp->flags & CAM_MEM_FLAG_CACHE)) { CAM_ERR(CAM_MEM, "Invalid flags for request mem"); return -EINVAL; } rc = cam_mem_util_get_dma_buf(inp->size, inp->flags, CAM_MEMMGR_ALLOC_KERNEL, &buf, &i_ino); if (rc) { CAM_ERR(CAM_MEM, "ION alloc failed for shared buffer"); goto ion_fail; } else if (!buf) { CAM_ERR(CAM_MEM, "ION alloc returned NULL buffer"); goto ion_fail; } else { CAM_DBG(CAM_MEM, "Got dma_buf = %pK", buf); } /* * we are mapping kva always here, * update flags so that we do unmap properly */ inp->flags |= CAM_MEM_FLAG_KMD_ACCESS; rc = cam_mem_util_map_cpu_va(buf, &kvaddr, &request_len); if (rc) { CAM_ERR(CAM_MEM, "Failed to get kernel vaddr"); goto map_fail; } if (!inp->smmu_hdl) { CAM_ERR(CAM_MEM, "Invalid SMMU handle"); rc = -EINVAL; goto smmu_fail; } /* SHARED flag gets precedence, all other flags after it */ if (inp->flags & CAM_MEM_FLAG_HW_SHARED_ACCESS) { region = CAM_SMMU_REGION_SHARED; } else { if (inp->flags & CAM_MEM_FLAG_HW_READ_WRITE) region = CAM_SMMU_REGION_IO; } rc = cam_smmu_map_kernel_iova(inp->smmu_hdl, buf, CAM_SMMU_MAP_RW, &iova, &request_len, region); if (rc < 0) { CAM_ERR(CAM_MEM, "SMMU mapping failed"); goto smmu_fail; } smmu_hdl = inp->smmu_hdl; idx = cam_mem_get_slot(); if (idx < 0) { CAM_ERR(CAM_MEM, "Failed in getting mem slot, idx=%d", idx); rc = -ENOMEM; cam_mem_mgr_print_tbl(); goto slot_fail; } mutex_lock(&tbl.bufq[idx].q_lock); mem_handle = GET_MEM_HANDLE(idx, ion_fd); tbl.bufq[idx].dma_buf = buf; tbl.bufq[idx].fd = -1; tbl.bufq[idx].i_ino = i_ino; tbl.bufq[idx].flags = inp->flags; tbl.bufq[idx].buf_handle = mem_handle; tbl.bufq[idx].kmdvaddr = kvaddr; cam_mem_mgr_update_iova_info_locked(tbl.bufq[idx].hdls_info, iova, inp->smmu_hdl, inp->size, true, NULL); tbl.bufq[idx].len = inp->size; tbl.bufq[idx].num_hdls = 1; tbl.bufq[idx].is_imported = false; kref_init(&tbl.bufq[idx].krefcount); tbl.bufq[idx].smmu_mapping_client = CAM_SMMU_MAPPING_KERNEL; mutex_unlock(&tbl.bufq[idx].q_lock); out->kva = kvaddr; out->iova = (uint32_t)iova; out->smmu_hdl = smmu_hdl; out->mem_handle = mem_handle; out->len = inp->size; out->region = region; CAM_DBG(CAM_MEM, "idx=%d, dmabuf=%pK, i_ino=%lu, flags=0x%x, mem_handle=0x%x", idx, buf, i_ino, inp->flags, mem_handle); return rc; slot_fail: cam_smmu_unmap_kernel_iova(inp->smmu_hdl, buf, region); smmu_fail: cam_mem_util_unmap_cpu_va(buf, kvaddr); map_fail: dma_buf_put(buf); ion_fail: return rc; } EXPORT_SYMBOL(cam_mem_mgr_request_mem); int cam_mem_mgr_release_mem(struct cam_mem_mgr_memory_desc *inp) { int32_t idx; int rc = 0; if (!atomic_read(&cam_mem_mgr_state)) { CAM_ERR(CAM_MEM, "failed. mem_mgr not initialized"); return -EINVAL; } if (!inp) { CAM_ERR(CAM_MEM, "Invalid argument"); return -EINVAL; } idx = CAM_MEM_MGR_GET_HDL_IDX(inp->mem_handle); if (idx >= CAM_MEM_BUFQ_MAX || idx <= 0) { CAM_ERR(CAM_MEM, "Incorrect index extracted from mem handle"); return -EINVAL; } if (!tbl.bufq[idx].active) { CAM_ERR(CAM_MEM, "Released buffer state should be active"); return -EINVAL; } if (tbl.bufq[idx].buf_handle != inp->mem_handle) { CAM_ERR(CAM_MEM, "Released buf handle not matching within table"); return -EINVAL; } CAM_DBG(CAM_MEM, "Releasing hdl = %X", inp->mem_handle); if (kref_put(&tbl.bufq[idx].krefcount, cam_mem_util_unmap_wrapper)) CAM_DBG(CAM_MEM, "Called unmap from here, buf_handle: %u, idx: %d", tbl.bufq[idx].buf_handle, idx); else { CAM_ERR(CAM_MEM, "Unbalanced release Called buf_handle: %u, idx: %d", tbl.bufq[idx].buf_handle, idx); rc = -EINVAL; } return rc; } EXPORT_SYMBOL(cam_mem_mgr_release_mem); int cam_mem_mgr_reserve_memory_region(struct cam_mem_mgr_request_desc *inp, enum cam_smmu_region_id region, struct cam_mem_mgr_memory_desc *out) { struct dma_buf *buf = NULL; int rc = 0, ion_fd = -1; dma_addr_t iova = 0; size_t request_len = 0; uint32_t mem_handle; int32_t idx; int32_t smmu_hdl = 0; uintptr_t kvaddr = 0; unsigned long i_ino = 0; if (!atomic_read(&cam_mem_mgr_state)) { CAM_ERR(CAM_MEM, "failed. mem_mgr not initialized"); return -EINVAL; } if (!inp || !out) { CAM_ERR(CAM_MEM, "Invalid param(s)"); return -EINVAL; } if (!inp->smmu_hdl) { CAM_ERR(CAM_MEM, "Invalid SMMU handle"); return -EINVAL; } if ((region != CAM_SMMU_REGION_SECHEAP) && (region != CAM_SMMU_REGION_FWUNCACHED)) { CAM_ERR(CAM_MEM, "Only secondary heap supported"); return -EINVAL; } rc = cam_mem_util_get_dma_buf(inp->size, 0, CAM_MEMMGR_ALLOC_KERNEL, &buf, &i_ino); if (rc) { CAM_ERR(CAM_MEM, "ION alloc failed for sec heap buffer"); goto ion_fail; } else if (!buf) { CAM_ERR(CAM_MEM, "ION alloc returned NULL buffer"); goto ion_fail; } else { CAM_DBG(CAM_MEM, "Got dma_buf = %pK", buf); } if (inp->flags & CAM_MEM_FLAG_KMD_ACCESS) { rc = cam_mem_util_map_cpu_va(buf, &kvaddr, &request_len); if (rc) { CAM_ERR(CAM_MEM, "Failed to get kernel vaddr"); goto kmap_fail; } } rc = cam_smmu_reserve_buf_region(region, inp->smmu_hdl, buf, &iova, &request_len); if (rc) { CAM_ERR(CAM_MEM, "Reserving secondary heap failed"); goto smmu_fail; } smmu_hdl = inp->smmu_hdl; idx = cam_mem_get_slot(); if (idx < 0) { CAM_ERR(CAM_MEM, "Failed in getting mem slot, idx=%d", idx); rc = -ENOMEM; cam_mem_mgr_print_tbl(); goto slot_fail; } mutex_lock(&tbl.bufq[idx].q_lock); mem_handle = GET_MEM_HANDLE(idx, ion_fd); tbl.bufq[idx].fd = -1; tbl.bufq[idx].i_ino = i_ino; tbl.bufq[idx].dma_buf = buf; tbl.bufq[idx].flags = inp->flags; tbl.bufq[idx].buf_handle = mem_handle; tbl.bufq[idx].kmdvaddr = kvaddr; cam_mem_mgr_update_iova_info_locked(tbl.bufq[idx].hdls_info, iova, inp->smmu_hdl, request_len, true, NULL); tbl.bufq[idx].len = request_len; tbl.bufq[idx].num_hdls = 1; tbl.bufq[idx].is_imported = false; kref_init(&tbl.bufq[idx].krefcount); tbl.bufq[idx].smmu_mapping_client = CAM_SMMU_MAPPING_KERNEL; mutex_unlock(&tbl.bufq[idx].q_lock); out->kva = kvaddr; out->iova = (uint32_t)iova; out->smmu_hdl = smmu_hdl; out->mem_handle = mem_handle; out->len = request_len; out->region = region; return rc; slot_fail: cam_smmu_release_buf_region(region, smmu_hdl); smmu_fail: if (region == CAM_SMMU_REGION_FWUNCACHED) cam_mem_util_unmap_cpu_va(buf, kvaddr); kmap_fail: dma_buf_put(buf); ion_fail: return rc; } EXPORT_SYMBOL(cam_mem_mgr_reserve_memory_region); static void *cam_mem_mgr_user_dump_buf( void *dump_struct, uint8_t *addr_ptr) { struct cam_mem_buf_queue *buf = NULL; uint64_t *addr; int i = 0; buf = (struct cam_mem_buf_queue *)dump_struct; addr = (uint64_t *)addr_ptr; *addr++ = buf->timestamp.tv_sec; *addr++ = buf->timestamp.tv_nsec / NSEC_PER_USEC; *addr++ = buf->fd; *addr++ = buf->i_ino; *addr++ = buf->buf_handle; *addr++ = buf->len; *addr++ = buf->align; *addr++ = buf->flags; *addr++ = buf->kmdvaddr; *addr++ = buf->is_imported; *addr++ = buf->is_internal; *addr++ = buf->num_hdls; for (i = 0; i < tbl.max_hdls_supported; i++) { if (!buf->hdls_info[i].addr_updated) continue; *addr++ = buf->hdls_info[i].iommu_hdl; *addr++ = buf->hdls_info[i].vaddr; } return addr; } int cam_mem_mgr_dump_user(struct cam_dump_req_cmd *dump_req) { int rc = 0; int i; struct cam_common_hw_dump_args dump_args; size_t buf_len; size_t remain_len; uint32_t min_len; uintptr_t cpu_addr; rc = cam_mem_get_cpu_buf(dump_req->buf_handle, &cpu_addr, &buf_len); if (rc) { CAM_ERR(CAM_MEM, "Invalid handle %u rc %d", dump_req->buf_handle, rc); return rc; } if (buf_len <= dump_req->offset) { CAM_WARN(CAM_MEM, "Dump buffer overshoot len %zu offset %zu", buf_len, dump_req->offset); cam_mem_put_cpu_buf(dump_req->buf_handle); return -ENOSPC; } remain_len = buf_len - dump_req->offset; min_len = (CAM_MEM_BUFQ_MAX * (CAM_MEM_MGR_DUMP_BUF_NUM_WORDS * sizeof(uint64_t) + sizeof(struct cam_common_hw_dump_header))); if (remain_len < min_len) { CAM_WARN(CAM_MEM, "Dump buffer exhaust remain %zu min %u", remain_len, min_len); cam_mem_put_cpu_buf(dump_req->buf_handle); return -ENOSPC; } dump_args.req_id = dump_req->issue_req_id; dump_args.cpu_addr = cpu_addr; dump_args.buf_len = buf_len; dump_args.offset = dump_req->offset; dump_args.ctxt_to_hw_map = NULL; mutex_lock(&tbl.m_lock); for (i = 1; i < CAM_MEM_BUFQ_MAX; i++) { if (tbl.bufq[i].active) { mutex_lock(&tbl.bufq[i].q_lock); rc = cam_common_user_dump_helper(&dump_args, cam_mem_mgr_user_dump_buf, &tbl.bufq[i], sizeof(uint64_t), "MEM_MGR_BUF.%d:", i); if (rc) { CAM_ERR(CAM_CRM, "Dump state info failed, rc: %d", rc); return rc; } mutex_unlock(&tbl.bufq[i].q_lock); } } mutex_unlock(&tbl.m_lock); dump_req->offset = dump_args.offset; cam_mem_put_cpu_buf(dump_req->buf_handle); return rc; } int cam_mem_mgr_free_memory_region(struct cam_mem_mgr_memory_desc *inp) { int32_t rc = 0, idx, entry_idx; if (!atomic_read(&cam_mem_mgr_state)) { CAM_ERR(CAM_MEM, "failed. mem_mgr not initialized"); return -EINVAL; } if (!inp) { CAM_ERR(CAM_MEM, "Invalid argument"); return -EINVAL; } if ((inp->region != CAM_SMMU_REGION_SECHEAP) && (inp->region != CAM_SMMU_REGION_FWUNCACHED)) { CAM_ERR(CAM_MEM, "Only secondary heap supported"); return -EINVAL; } idx = CAM_MEM_MGR_GET_HDL_IDX(inp->mem_handle); if (idx >= CAM_MEM_BUFQ_MAX || idx <= 0) { CAM_ERR(CAM_MEM, "Incorrect index extracted from mem handle"); return -EINVAL; } if (!tbl.bufq[idx].active) { CAM_ERR(CAM_MEM, "Released buffer state should be active"); return -EINVAL; } if (tbl.bufq[idx].buf_handle != inp->mem_handle) { CAM_ERR(CAM_MEM, "Released buf handle not matching within table"); return -EINVAL; } if (tbl.bufq[idx].num_hdls != 1) { CAM_ERR(CAM_MEM, "Sec heap region should have only one smmu hdl"); return -ENODEV; } if (!cam_mem_mgr_get_hwva_entry_idx(inp->smmu_hdl, &entry_idx)) { CAM_ERR(CAM_MEM, "Passed SMMU handle not a valid handle"); return -ENODEV; } if (inp->smmu_hdl != tbl.bufq[idx].hdls_info[entry_idx].iommu_hdl) { CAM_ERR(CAM_MEM, "Passed SMMU handle doesn't match with internal hdl"); return -ENODEV; } rc = cam_smmu_release_buf_region(inp->region, inp->smmu_hdl); if (rc) { CAM_ERR(CAM_MEM, "Sec heap region release failed"); return -ENODEV; } CAM_DBG(CAM_MEM, "Releasing hdl = %X", inp->mem_handle); if (kref_put(&tbl.bufq[idx].krefcount, cam_mem_util_unmap_wrapper)) CAM_DBG(CAM_MEM, "Called unmap from here, buf_handle: %u, idx: %d", inp->mem_handle, idx); else { CAM_ERR(CAM_MEM, "Unbalanced release Called buf_handle: %u, idx: %d", inp->mem_handle, idx); rc = -EINVAL; } return rc; } EXPORT_SYMBOL(cam_mem_mgr_free_memory_region); #ifdef CONFIG_CAM_PRESIL struct dma_buf *cam_mem_mgr_get_dma_buf(int fd) { struct dma_buf *dmabuf = NULL; dmabuf = dma_buf_get(fd); if (IS_ERR_OR_NULL((void *)(dmabuf))) { CAM_ERR(CAM_MEM, "Failed to import dma_buf for fd"); return NULL; } CAM_INFO(CAM_PRESIL, "Received DMA Buf* %pK", dmabuf); return dmabuf; } int cam_mem_mgr_put_dmabuf_from_fd(uint64_t input_dmabuf) { struct dma_buf *dmabuf = (struct dma_buf *)(uint64_t)input_dmabuf; int idx = 0; CAM_INFO(CAM_PRESIL, "Received dma_buf :%pK", dmabuf); if (!dmabuf) { CAM_ERR(CAM_PRESIL, "NULL to import dma_buf fd"); return -EINVAL; } for (idx = 0; idx < CAM_MEM_BUFQ_MAX; idx++) { if ((tbl.bufq[idx].dma_buf != NULL) && (tbl.bufq[idx].dma_buf == dmabuf)) { if (tbl.bufq[idx].presil_params.refcount) tbl.bufq[idx].presil_params.refcount--; else CAM_ERR(CAM_PRESIL, "Unbalanced dmabuf put: %pK", dmabuf); if (!tbl.bufq[idx].presil_params.refcount) { dma_buf_put(dmabuf); cam_mem_mgr_reset_presil_params(idx); CAM_DBG(CAM_PRESIL, "Done dma_buf_put for %pK", dmabuf); } } } return 0; } int cam_mem_mgr_get_fd_from_dmabuf(uint64_t input_dmabuf) { int fd_for_dmabuf = -1; struct dma_buf *dmabuf = (struct dma_buf *)(uint64_t)input_dmabuf; int idx = 0; CAM_DBG(CAM_PRESIL, "Received dma_buf :%pK", dmabuf); if (!dmabuf) { CAM_ERR(CAM_PRESIL, "NULL to import dma_buf fd"); return -EINVAL; } for (idx = 0; idx < CAM_MEM_BUFQ_MAX; idx++) { if ((tbl.bufq[idx].dma_buf != NULL) && (tbl.bufq[idx].dma_buf == dmabuf)) { CAM_DBG(CAM_PRESIL, "Found entry for request from Presil UMD Daemon at %d, dmabuf %pK fd_for_umd_daemon %d refcount: %d", idx, tbl.bufq[idx].dma_buf, tbl.bufq[idx].presil_params.fd_for_umd_daemon, tbl.bufq[idx].presil_params.refcount); if (tbl.bufq[idx].presil_params.fd_for_umd_daemon < 0) { fd_for_dmabuf = dma_buf_fd(dmabuf, O_CLOEXEC); if (fd_for_dmabuf < 0) { CAM_ERR(CAM_PRESIL, "get fd fail, fd_for_dmabuf=%d", fd_for_dmabuf); return -EINVAL; } tbl.bufq[idx].presil_params.fd_for_umd_daemon = fd_for_dmabuf; CAM_INFO(CAM_PRESIL, "Received generated idx %d fd_for_dmabuf Buf* %lld", idx, fd_for_dmabuf); } else { fd_for_dmabuf = tbl.bufq[idx].presil_params.fd_for_umd_daemon; CAM_INFO(CAM_PRESIL, "Received existing at idx %d fd_for_dmabuf Buf* %lld", idx, fd_for_dmabuf); } tbl.bufq[idx].presil_params.refcount++; } else { CAM_DBG(CAM_MEM, "Not found dmabuf at idx=%d, dma_buf %pK handle 0x%0x active %d ", idx, tbl.bufq[idx].dma_buf, tbl.bufq[idx].buf_handle, tbl.bufq[idx].active); } } return (int)fd_for_dmabuf; } int cam_mem_mgr_send_buffer_to_presil(int32_t iommu_hdl, int32_t buf_handle) { int rc = 0; /* Sending Presil IO Buf to PC side ( as iova start address indicates) */ uint64_t io_buf_addr; size_t io_buf_size; int i, j, fd = -1, idx = 0; uint8_t *iova_ptr = NULL; uint64_t dmabuf = 0; bool is_mapped_in_cb = false; CAM_DBG(CAM_PRESIL, "buf handle 0x%0x", buf_handle); idx = CAM_MEM_MGR_GET_HDL_IDX(buf_handle); for (i = 0; i < tbl.bufq[idx].num_hdl; i++) { if (tbl.bufq[idx].hdls[i] == iommu_hdl) is_mapped_in_cb = true; } if (!is_mapped_in_cb) { for (j = 0; j < CAM_MEM_BUFQ_MAX; j++) { if (tbl.bufq[j].i_ino == tbl.bufq[idx].i_ino) { for (i = 0; i < tbl.bufq[j].num_hdl; i++) { if (tbl.bufq[j].hdls[i] == iommu_hdl) is_mapped_in_cb = true; } } } if (!is_mapped_in_cb) { CAM_DBG(CAM_PRESIL, "Still Could not find idx=%d, FD %d buf_handle 0x%0x", idx, GET_FD_FROM_HANDLE(buf_handle), buf_handle); /* * Okay to return 0, since this function also gets called for buffers that * are shared only between umd/kmd, these may not be mapped with smmu */ return 0; } } if ((tbl.bufq[idx].buf_handle != 0) && (tbl.bufq[idx].active) && (tbl.bufq[idx].buf_handle == buf_handle)) { CAM_DBG(CAM_PRESIL, "Found dmabuf in bufq idx %d, FD %d handle 0x%0x dmabuf %pK", idx, tbl.bufq[idx].fd, tbl.bufq[idx].buf_handle, tbl.bufq[idx].dma_buf); dmabuf = (uint64_t)tbl.bufq[idx].dma_buf; fd = tbl.bufq[idx].fd; } else { CAM_ERR(CAM_PRESIL, "Could not find dmabuf Invalid Mem idx=%d, FD %d handle 0x%0x active %d", idx, tbl.bufq[idx].fd, tbl.bufq[idx].buf_handle, tbl.bufq[idx].active); return -EINVAL; } rc = cam_mem_get_io_buf(buf_handle, iommu_hdl, &io_buf_addr, &io_buf_size, NULL, NULL); if (rc || NULL == (void *)io_buf_addr) { CAM_DBG(CAM_PRESIL, "Invalid ioaddr : 0x%x, fd = %d, dmabuf = %pK", io_buf_addr, fd, dmabuf); return -EINVAL; } iova_ptr = (uint8_t *)io_buf_addr; CAM_INFO(CAM_PRESIL, "Sending buffer with ioaddr : 0x%x, fd = %d, dmabuf = %pK", io_buf_addr, fd, dmabuf); rc = cam_presil_send_buffer(dmabuf, 0, 0, (uint32_t)io_buf_size, (uint64_t)iova_ptr); return rc; } int cam_mem_mgr_send_all_buffers_to_presil(int32_t iommu_hdl) { int idx = 0; int rc = 0; int32_t fd_already_sent[128]; int fd_already_sent_count = 0; int fd_already_index = 0; int fd_already_sent_found = 0; memset(&fd_already_sent, 0x0, sizeof(fd_already_sent)); for (idx = 0; idx < CAM_MEM_BUFQ_MAX; idx++) { if ((tbl.bufq[idx].buf_handle != 0) && (tbl.bufq[idx].active)) { CAM_DBG(CAM_PRESIL, "Sending %d, FD %d handle 0x%0x", idx, tbl.bufq[idx].fd, tbl.bufq[idx].buf_handle); fd_already_sent_found = 0; for (fd_already_index = 0; fd_already_index < fd_already_sent_count; fd_already_index++) { if (fd_already_sent[fd_already_index] == tbl.bufq[idx].fd) { fd_already_sent_found = 1; CAM_DBG(CAM_PRESIL, "fd_already_sent %d, FD %d handle 0x%0x flags=0x%0x", idx, tbl.bufq[idx].fd, tbl.bufq[idx].buf_handle, tbl.bufq[idx].flags); } } if (fd_already_sent_found) continue; CAM_DBG(CAM_PRESIL, "Sending %d, FD %d handle 0x%0x flags=0x%0x", idx, tbl.bufq[idx].fd, tbl.bufq[idx].buf_handle, tbl.bufq[idx].flags); rc = cam_mem_mgr_send_buffer_to_presil(iommu_hdl, tbl.bufq[idx].buf_handle); fd_already_sent[fd_already_sent_count++] = tbl.bufq[idx].fd; } else { CAM_DBG(CAM_PRESIL, "Invalid Mem idx=%d, FD %d handle 0x%0x active %d", idx, tbl.bufq[idx].fd, tbl.bufq[idx].buf_handle, tbl.bufq[idx].active); } } return rc; } EXPORT_SYMBOL(cam_mem_mgr_send_all_buffers_to_presil); int cam_mem_mgr_retrieve_buffer_from_presil(int32_t buf_handle, uint32_t buf_size, uint32_t offset, int32_t iommu_hdl) { int rc = 0; /* Receive output buffer from Presil IO Buf to PC side (as iova start address indicates) */ uint64_t io_buf_addr; size_t io_buf_size; uint64_t dmabuf = 0; int fd = 0; uint8_t *iova_ptr = NULL; int idx = 0; CAM_DBG(CAM_PRESIL, "buf handle 0x%0x ", buf_handle); rc = cam_mem_get_io_buf(buf_handle, iommu_hdl, &io_buf_addr, &io_buf_size, NULL, NULL); if (rc) { CAM_ERR(CAM_PRESIL, "Unable to get IOVA for buffer buf_hdl: 0x%0x iommu_hdl: 0x%0x", buf_handle, iommu_hdl); return -EINVAL; } iova_ptr = (uint8_t *)io_buf_addr; iova_ptr += offset; // correct target address to start writing buffer to. if (!buf_size) { buf_size = io_buf_size; CAM_DBG(CAM_PRESIL, "Updated buf_size from Zero to 0x%0x", buf_size); } fd = GET_FD_FROM_HANDLE(buf_handle); idx = CAM_MEM_MGR_GET_HDL_IDX(buf_handle); if ((tbl.bufq[idx].buf_handle != 0) && (tbl.bufq[idx].active) && (tbl.bufq[idx].buf_handle == buf_handle)) { CAM_DBG(CAM_PRESIL, "Found dmabuf in bufq idx %d, FD %d handle 0x%0x dmabuf %pK", idx, tbl.bufq[idx].fd, tbl.bufq[idx].buf_handle, tbl.bufq[idx].dma_buf); dmabuf = (uint64_t)tbl.bufq[idx].dma_buf; } else { CAM_ERR(CAM_PRESIL, "Could not find dmabuf Invalid Mem idx=%d, FD %d handle 0x%0x active %d ", idx, tbl.bufq[idx].fd, tbl.bufq[idx].buf_handle, tbl.bufq[idx].active); } CAM_DBG(CAM_PRESIL, "Retrieving buffer with ioaddr : 0x%x, offset = %d, size = %d, fd = %d, dmabuf = %pK", io_buf_addr, offset, buf_size, fd, dmabuf); rc = cam_presil_retrieve_buffer(dmabuf, 0, 0, (uint32_t)buf_size, (uint64_t)io_buf_addr); CAM_INFO(CAM_PRESIL, "Retrieved buffer with ioaddr : 0x%x, offset = %d, size = %d, fd = %d, dmabuf = %pK", io_buf_addr, 0, buf_size, fd, dmabuf); return rc; } #else /* ifdef CONFIG_CAM_PRESIL */ struct dma_buf * cam_mem_mgr_get_dma_buf(int fd) { return NULL; } int cam_mem_mgr_send_all_buffers_to_presil(int32_t iommu_hdl) { return 0; } int cam_mem_mgr_send_buffer_to_presil(int32_t iommu_hdl, int32_t buf_handle) { return 0; } int cam_mem_mgr_retrieve_buffer_from_presil(int32_t buf_handle, uint32_t buf_size, uint32_t offset, int32_t iommu_hdl) { return 0; } #endif /* ifdef CONFIG_CAM_PRESIL */