/* Copyright (c) 2012-2016, The Linux Foundation. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 and * only version 2 as published by the Free Software Foundation. * * 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. * */ #include #include #include #include "msm_vidc_internal.h" #include "msm_vidc_debug.h" #include "msm_vdec.h" #include "msm_venc.h" #include "msm_vidc_common.h" #include #include "vidc_hfi_api.h" #include "msm_vidc_dcvs.h" #define MAX_EVENTS 30 static int get_poll_flags(void *instance) { struct msm_vidc_inst *inst = instance; struct vb2_queue *outq = &inst->bufq[OUTPUT_PORT].vb2_bufq; struct vb2_queue *capq = &inst->bufq[CAPTURE_PORT].vb2_bufq; struct vb2_buffer *out_vb = NULL; struct vb2_buffer *cap_vb = NULL; unsigned long flags; int rc = 0; if (v4l2_event_pending(&inst->event_handler)) rc |= POLLPRI; spin_lock_irqsave(&capq->done_lock, flags); if (!list_empty(&capq->done_list)) cap_vb = list_first_entry(&capq->done_list, struct vb2_buffer, done_entry); if (cap_vb && (cap_vb->state == VB2_BUF_STATE_DONE || cap_vb->state == VB2_BUF_STATE_ERROR)) rc |= POLLIN | POLLRDNORM; spin_unlock_irqrestore(&capq->done_lock, flags); spin_lock_irqsave(&outq->done_lock, flags); if (!list_empty(&outq->done_list)) out_vb = list_first_entry(&outq->done_list, struct vb2_buffer, done_entry); if (out_vb && (out_vb->state == VB2_BUF_STATE_DONE || out_vb->state == VB2_BUF_STATE_ERROR)) rc |= POLLOUT | POLLWRNORM; spin_unlock_irqrestore(&outq->done_lock, flags); return rc; } int msm_vidc_poll(void *instance, struct file *filp, struct poll_table_struct *wait) { struct msm_vidc_inst *inst = instance; struct vb2_queue *outq = NULL; struct vb2_queue *capq = NULL; if (!inst) return -EINVAL; outq = &inst->bufq[OUTPUT_PORT].vb2_bufq; capq = &inst->bufq[CAPTURE_PORT].vb2_bufq; poll_wait(filp, &inst->event_handler.wait, wait); poll_wait(filp, &capq->done_wq, wait); poll_wait(filp, &outq->done_wq, wait); return get_poll_flags(inst); } EXPORT_SYMBOL(msm_vidc_poll); int msm_vidc_querycap(void *instance, struct v4l2_capability *cap) { struct msm_vidc_inst *inst = instance; if (!inst || !cap) return -EINVAL; if (inst->session_type == MSM_VIDC_DECODER) return msm_vdec_querycap(instance, cap); else if (inst->session_type == MSM_VIDC_ENCODER) return msm_venc_querycap(instance, cap); return -EINVAL; } EXPORT_SYMBOL(msm_vidc_querycap); int msm_vidc_enum_fmt(void *instance, struct v4l2_fmtdesc *f) { struct msm_vidc_inst *inst = instance; if (!inst || !f) return -EINVAL; if (inst->session_type == MSM_VIDC_DECODER) return msm_vdec_enum_fmt(instance, f); else if (inst->session_type == MSM_VIDC_ENCODER) return msm_venc_enum_fmt(instance, f); return -EINVAL; } EXPORT_SYMBOL(msm_vidc_enum_fmt); int msm_vidc_s_fmt(void *instance, struct v4l2_format *f) { struct msm_vidc_inst *inst = instance; if (!inst || !f) return -EINVAL; if (inst->session_type == MSM_VIDC_DECODER) return msm_vdec_s_fmt(instance, f); if (inst->session_type == MSM_VIDC_ENCODER) return msm_venc_s_fmt(instance, f); return -EINVAL; } EXPORT_SYMBOL(msm_vidc_s_fmt); int msm_vidc_g_fmt(void *instance, struct v4l2_format *f) { struct msm_vidc_inst *inst = instance; if (!inst || !f) return -EINVAL; if (inst->session_type == MSM_VIDC_DECODER) return msm_vdec_g_fmt(instance, f); else if (inst->session_type == MSM_VIDC_ENCODER) return msm_venc_g_fmt(instance, f); return -EINVAL; } EXPORT_SYMBOL(msm_vidc_g_fmt); int msm_vidc_s_ctrl(void *instance, struct v4l2_control *control) { struct msm_vidc_inst *inst = instance; if (!inst || !control) return -EINVAL; return msm_comm_s_ctrl(instance, control); } EXPORT_SYMBOL(msm_vidc_s_ctrl); int msm_vidc_g_ctrl(void *instance, struct v4l2_control *control) { struct msm_vidc_inst *inst = instance; if (!inst || !control) return -EINVAL; return msm_comm_g_ctrl(instance, control); } EXPORT_SYMBOL(msm_vidc_g_ctrl); int msm_vidc_s_ext_ctrl(void *instance, struct v4l2_ext_controls *control) { struct msm_vidc_inst *inst = instance; if (!inst || !control) return -EINVAL; if (inst->session_type == MSM_VIDC_DECODER) return msm_vdec_s_ext_ctrl(instance, control); if (inst->session_type == MSM_VIDC_ENCODER) return msm_venc_s_ext_ctrl(instance, control); return -EINVAL; } EXPORT_SYMBOL(msm_vidc_s_ext_ctrl); int msm_vidc_reqbufs(void *instance, struct v4l2_requestbuffers *b) { struct msm_vidc_inst *inst = instance; if (!inst || !b) return -EINVAL; if (inst->session_type == MSM_VIDC_DECODER) return msm_vdec_reqbufs(instance, b); if (inst->session_type == MSM_VIDC_ENCODER) return msm_venc_reqbufs(instance, b); return -EINVAL; } EXPORT_SYMBOL(msm_vidc_reqbufs); struct buffer_info *get_registered_buf(struct msm_vidc_inst *inst, struct v4l2_buffer *b, int idx, int *plane) { struct buffer_info *temp; struct buffer_info *ret = NULL; int i; int fd = b->m.planes[idx].reserved[0]; u32 buff_off = b->m.planes[idx].reserved[1]; u32 size = b->m.planes[idx].length; ion_phys_addr_t device_addr = b->m.planes[idx].m.userptr; if (fd < 0 || !plane) { dprintk(VIDC_ERR, "Invalid input\n"); goto err_invalid_input; } WARN(!mutex_is_locked(&inst->registeredbufs.lock), "Registered buf lock is not acquired for %s", __func__); *plane = 0; list_for_each_entry(temp, &inst->registeredbufs.list, list) { for (i = 0; i < min(temp->num_planes, VIDEO_MAX_PLANES); i++) { bool fd_matches = fd == temp->fd[i]; bool device_addr_matches = device_addr == temp->device_addr[i]; bool contains_within = CONTAINS(temp->buff_off[i], temp->size[i], buff_off) || CONTAINS(buff_off, size, temp->buff_off[i]); bool overlaps = OVERLAPS(buff_off, size, temp->buff_off[i], temp->size[i]); if (!temp->inactive && (fd_matches || device_addr_matches) && (contains_within || overlaps)) { dprintk(VIDC_DBG, "This memory region is already mapped\n"); ret = temp; *plane = i; break; } } if (ret) break; } err_invalid_input: return ret; } static struct msm_smem *get_same_fd_buffer(struct msm_vidc_list *buf_list, int fd) { struct buffer_info *temp; struct msm_smem *same_fd_handle = NULL; int i; if (!fd) return NULL; if (!buf_list || fd < 0) { dprintk(VIDC_ERR, "Invalid input\n"); goto err_invalid_input; } mutex_lock(&buf_list->lock); list_for_each_entry(temp, &buf_list->list, list) { for (i = 0; i < min(temp->num_planes, VIDEO_MAX_PLANES); i++) { if (temp->fd[i] == fd && temp->handle[i] && temp->mapped[i]) { temp->same_fd_ref[i]++; dprintk(VIDC_INFO, "Found same fd buffer\n"); same_fd_handle = temp->handle[i]; break; } } if (same_fd_handle) break; } mutex_unlock(&buf_list->lock); err_invalid_input: return same_fd_handle; } struct buffer_info *device_to_uvaddr(struct msm_vidc_list *buf_list, ion_phys_addr_t device_addr) { struct buffer_info *temp = NULL; bool found = false; int i; if (!buf_list || !device_addr) { dprintk(VIDC_ERR, "Invalid input- device_addr: %pa buf_list: %p\n", &device_addr, buf_list); goto err_invalid_input; } mutex_lock(&buf_list->lock); list_for_each_entry(temp, &buf_list->list, list) { for (i = 0; i < min(temp->num_planes, VIDEO_MAX_PLANES); i++) { if (!temp->inactive && temp->device_addr[i] == device_addr) { dprintk(VIDC_INFO, "Found same fd buffer\n"); found = true; break; } } if (found) break; } mutex_unlock(&buf_list->lock); err_invalid_input: return temp; } static inline void populate_buf_info(struct buffer_info *binfo, struct v4l2_buffer *b, u32 i) { binfo->type = b->type; binfo->fd[i] = b->m.planes[i].reserved[0]; binfo->buff_off[i] = b->m.planes[i].reserved[1]; binfo->size[i] = b->m.planes[i].length; binfo->uvaddr[i] = b->m.planes[i].m.userptr; binfo->num_planes = b->length; binfo->memory = b->memory; binfo->v4l2_index = b->index; binfo->timestamp.tv_sec = b->timestamp.tv_sec; binfo->timestamp.tv_usec = b->timestamp.tv_usec; dprintk(VIDC_DBG, "%s: fd[%d] = %d b->index = %d", __func__, i, binfo->fd[0], b->index); } static inline void repopulate_v4l2_buffer(struct v4l2_buffer *b, struct buffer_info *binfo) { int i = 0; b->type = binfo->type; b->length = binfo->num_planes; b->memory = binfo->memory; b->index = binfo->v4l2_index; b->timestamp.tv_sec = binfo->timestamp.tv_sec; b->timestamp.tv_usec = binfo->timestamp.tv_usec; binfo->dequeued = false; for (i = 0; i < binfo->num_planes; ++i) { b->m.planes[i].reserved[0] = binfo->fd[i]; b->m.planes[i].reserved[1] = binfo->buff_off[i]; b->m.planes[i].length = binfo->size[i]; b->m.planes[i].m.userptr = binfo->device_addr[i]; dprintk(VIDC_DBG, "%s %d %d %d %pa\n", __func__, binfo->fd[i], binfo->buff_off[i], binfo->size[i], &binfo->device_addr[i]); } } static struct msm_smem *map_buffer(struct msm_vidc_inst *inst, struct v4l2_plane *p, enum hal_buffer buffer_type) { struct msm_smem *handle = NULL; handle = msm_comm_smem_user_to_kernel(inst, p->reserved[0], p->reserved[1], buffer_type); if (!handle) { dprintk(VIDC_ERR, "%s: Failed to get device buffer address\n", __func__); return NULL; } return handle; } static inline enum hal_buffer get_hal_buffer_type( struct msm_vidc_inst *inst, struct v4l2_buffer *b) { if (b->type == V4L2_BUF_TYPE_VIDEO_OUTPUT_MPLANE) return HAL_BUFFER_INPUT; else if (b->type == V4L2_BUF_TYPE_VIDEO_CAPTURE_MPLANE) return HAL_BUFFER_OUTPUT; else return -EINVAL; } static inline bool is_dynamic_output_buffer_mode(struct v4l2_buffer *b, struct msm_vidc_inst *inst) { return b->type == V4L2_BUF_TYPE_VIDEO_CAPTURE_MPLANE && inst->buffer_mode_set[CAPTURE_PORT] == HAL_BUFFER_MODE_DYNAMIC; } static inline void save_v4l2_buffer(struct v4l2_buffer *b, struct buffer_info *binfo) { int i = 0; for (i = 0; i < b->length; ++i) { if (EXTRADATA_IDX(b->length) && (i == EXTRADATA_IDX(b->length)) && !b->m.planes[i].length) { continue; } populate_buf_info(binfo, b, i); } } int map_and_register_buf(struct msm_vidc_inst *inst, struct v4l2_buffer *b) { struct buffer_info *binfo = NULL; struct buffer_info *temp = NULL, *iterator = NULL; int plane = 0; int i = 0, rc = 0; struct msm_smem *same_fd_handle = NULL; if (!b || !inst) { dprintk(VIDC_ERR, "%s: invalid input\n", __func__); return -EINVAL; } binfo = kzalloc(sizeof(*binfo), GFP_KERNEL); if (!binfo) { dprintk(VIDC_ERR, "Out of memory\n"); rc = -ENOMEM; goto exit; } if (b->length > VIDEO_MAX_PLANES) { dprintk(VIDC_ERR, "Num planes exceeds max: %d, %d\n", b->length, VIDEO_MAX_PLANES); rc = -EINVAL; goto exit; } dprintk(VIDC_DBG, "[MAP] Create binfo = %p fd = %d type = %d\n", binfo, b->m.planes[0].reserved[0], b->type); for (i = 0; i < b->length; ++i) { rc = 0; if (EXTRADATA_IDX(b->length) && (i == EXTRADATA_IDX(b->length)) && !b->m.planes[i].length) { continue; } mutex_lock(&inst->registeredbufs.lock); temp = get_registered_buf(inst, b, i, &plane); if (temp && !is_dynamic_output_buffer_mode(b, inst)) { dprintk(VIDC_DBG, "This memory region has already been prepared\n"); rc = 0; mutex_unlock(&inst->registeredbufs.lock); goto exit; } if (temp && is_dynamic_output_buffer_mode(b, inst) && !i) { /* * Buffer is already present in registered list * increment ref_count, populate new values of v4l2 * buffer in existing buffer_info struct. * * We will use the saved buffer info and queue it when * we receive RELEASE_BUFFER_REFERENCE EVENT from f/w. */ dprintk(VIDC_DBG, "[MAP] Buffer already prepared\n"); temp->inactive = false; list_for_each_entry(iterator, &inst->registeredbufs.list, list) { if (iterator == temp) { rc = buf_ref_get(inst, temp); save_v4l2_buffer(b, temp); break; } } } mutex_unlock(&inst->registeredbufs.lock); /* * rc == 1, * buffer is mapped, fw has released all reference, so skip * mapping and queue it immediately. * * rc == 2, * buffer is mapped and fw is holding a reference, hold it in * the driver and queue it later when fw has released */ if (rc == 1) { rc = 0; goto exit; } else if (rc == 2) { rc = -EEXIST; goto exit; } same_fd_handle = get_same_fd_buffer( &inst->registeredbufs, b->m.planes[i].reserved[0]); populate_buf_info(binfo, b, i); if (same_fd_handle) { binfo->device_addr[i] = same_fd_handle->device_addr + binfo->buff_off[i]; b->m.planes[i].m.userptr = binfo->device_addr[i]; binfo->mapped[i] = false; binfo->handle[i] = same_fd_handle; } else { binfo->handle[i] = map_buffer(inst, &b->m.planes[i], get_hal_buffer_type(inst, b)); if (!binfo->handle[i]) { rc = -EINVAL; goto exit; } binfo->mapped[i] = true; binfo->device_addr[i] = binfo->handle[i]->device_addr + binfo->buff_off[i]; b->m.planes[i].m.userptr = binfo->device_addr[i]; } /* We maintain one ref count for all planes*/ if (!i && is_dynamic_output_buffer_mode(b, inst)) { rc = buf_ref_get(inst, binfo); if (rc < 0) goto exit; } dprintk(VIDC_DBG, "%s: [MAP] binfo = %p, handle[%d] = %p, device_addr = %pa, fd = %d, offset = %d, mapped = %d\n", __func__, binfo, i, binfo->handle[i], &binfo->device_addr[i], binfo->fd[i], binfo->buff_off[i], binfo->mapped[i]); } mutex_lock(&inst->registeredbufs.lock); list_add_tail(&binfo->list, &inst->registeredbufs.list); mutex_unlock(&inst->registeredbufs.lock); return 0; exit: kfree(binfo); return rc; } int unmap_and_deregister_buf(struct msm_vidc_inst *inst, struct buffer_info *binfo) { int i = 0; struct buffer_info *temp = NULL; bool found = false, keep_node = false; if (!inst || !binfo) { dprintk(VIDC_ERR, "%s invalid param: %p %p\n", __func__, inst, binfo); return -EINVAL; } WARN(!mutex_is_locked(&inst->registeredbufs.lock), "Registered buf lock is not acquired for %s", __func__); /* * Make sure the buffer to be unmapped and deleted * from the registered list is present in the list. */ list_for_each_entry(temp, &inst->registeredbufs.list, list) { if (temp == binfo) { found = true; break; } } /* * Free the buffer info only if * - buffer info has not been deleted from registered list * - vidc client has called dqbuf on the buffer * - no references are held on the buffer */ if (!found || !temp || !temp->pending_deletion || !temp->dequeued) goto exit; for (i = 0; i < temp->num_planes; i++) { dprintk(VIDC_DBG, "%s: [UNMAP] binfo = %p, handle[%d] = %p, device_addr = %pa, fd = %d, offset = %d, mapped = %d\n", __func__, temp, i, temp->handle[i], &temp->device_addr[i], temp->fd[i], temp->buff_off[i], temp->mapped[i]); /* * Unmap the handle only if the buffer has been mapped and no * other buffer has a reference to this buffer. * In case of buffers with same fd, we will map the buffer only * once and subsequent buffers will refer to the mapped buffer's * device address. * For buffers which share the same fd, do not unmap and keep * the buffer info in registered list. */ if (temp->handle[i] && temp->mapped[i] && !temp->same_fd_ref[i]) { msm_comm_smem_free(inst, temp->handle[i]); } if (temp->same_fd_ref[i]) keep_node = true; else { temp->fd[i] = 0; temp->handle[i] = 0; temp->device_addr[i] = 0; temp->uvaddr[i] = 0; } } if (!keep_node) { dprintk(VIDC_DBG, "[UNMAP] AND-FREED binfo: %p\n", temp); list_del(&temp->list); kfree(temp); } else { temp->inactive = true; dprintk(VIDC_DBG, "[UNMAP] NOT-FREED binfo: %p\n", temp); } exit: return 0; } int qbuf_dynamic_buf(struct msm_vidc_inst *inst, struct buffer_info *binfo) { struct v4l2_buffer b = {0}; struct v4l2_plane plane[VIDEO_MAX_PLANES] = { {0} }; if (!binfo) { dprintk(VIDC_ERR, "%s invalid param: %p\n", __func__, binfo); return -EINVAL; } dprintk(VIDC_DBG, "%s fd[0] = %d\n", __func__, binfo->fd[0]); b.m.planes = plane; repopulate_v4l2_buffer(&b, binfo); if (inst->session_type == MSM_VIDC_DECODER) return msm_vdec_qbuf(inst, &b); if (inst->session_type == MSM_VIDC_ENCODER) return msm_venc_qbuf(inst, &b); return -EINVAL; } int output_buffer_cache_invalidate(struct msm_vidc_inst *inst, struct buffer_info *binfo) { int i = 0; int rc = 0; if (!inst) { dprintk(VIDC_ERR, "%s: invalid inst: %p\n", __func__, inst); return -EINVAL; } if (!binfo) { dprintk(VIDC_ERR, "%s: invalid buffer info: %p\n", __func__, inst); return -EINVAL; } if (binfo->type != V4L2_BUF_TYPE_VIDEO_CAPTURE_MPLANE) return 0; for (i = 0; i < binfo->num_planes; i++) { if (binfo->handle[i]) { rc = msm_comm_smem_cache_operations(inst, binfo->handle[i], SMEM_CACHE_INVALIDATE); if (rc) { dprintk(VIDC_ERR, "%s: Failed to clean caches: %d\n", __func__, rc); return -EINVAL; } } else dprintk(VIDC_DBG, "%s: NULL handle for plane %d\n", __func__, i); } return 0; } static bool valid_v4l2_buffer(struct v4l2_buffer *b, struct msm_vidc_inst *inst) { enum vidc_ports port = !V4L2_TYPE_IS_MULTIPLANAR(b->type) ? MAX_PORT_NUM : b->type == V4L2_BUF_TYPE_VIDEO_CAPTURE_MPLANE ? CAPTURE_PORT : b->type == V4L2_BUF_TYPE_VIDEO_OUTPUT_MPLANE ? OUTPUT_PORT : MAX_PORT_NUM; return port != MAX_PORT_NUM && inst->fmts[port]->num_planes == b->length; } int msm_vidc_prepare_buf(void *instance, struct v4l2_buffer *b) { struct msm_vidc_inst *inst = instance; if (!inst || !b || !valid_v4l2_buffer(b, inst)) return -EINVAL; if (is_dynamic_output_buffer_mode(b, inst)) return 0; if (map_and_register_buf(inst, b)) return -EINVAL; if (inst->session_type == MSM_VIDC_DECODER) return msm_vdec_prepare_buf(instance, b); if (inst->session_type == MSM_VIDC_ENCODER) return msm_venc_prepare_buf(instance, b); return -EINVAL; } EXPORT_SYMBOL(msm_vidc_prepare_buf); int msm_vidc_release_buffers(void *instance, int buffer_type) { struct msm_vidc_inst *inst = instance; struct buffer_info *bi, *dummy; struct v4l2_buffer buffer_info; struct v4l2_plane plane[VIDEO_MAX_PLANES]; int i, rc = 0; if (!inst) return -EINVAL; if (!inst->in_reconfig && inst->state > MSM_VIDC_LOAD_RESOURCES && inst->state < MSM_VIDC_RELEASE_RESOURCES_DONE) { rc = msm_comm_try_state(inst, MSM_VIDC_RELEASE_RESOURCES_DONE); if (rc) { dprintk(VIDC_ERR, "Failed to move inst: %p to release res done\n", inst); } } /* * In dynamic buffer mode, driver needs to release resources, * but not call release buffers on firmware, as the buffers * were never registered with firmware. */ if (buffer_type == V4L2_BUF_TYPE_VIDEO_CAPTURE_MPLANE && inst->buffer_mode_set[CAPTURE_PORT] == HAL_BUFFER_MODE_DYNAMIC) { goto free_and_unmap; } mutex_lock(&inst->registeredbufs.lock); list_for_each_entry(bi, &inst->registeredbufs.list, list) { bool release_buf = false; if (bi->type == buffer_type) { buffer_info.type = bi->type; for (i = 0; i < min(bi->num_planes, VIDEO_MAX_PLANES); i++) { plane[i].reserved[0] = bi->fd[i]; plane[i].reserved[1] = bi->buff_off[i]; plane[i].length = bi->size[i]; plane[i].m.userptr = bi->device_addr[i]; buffer_info.m.planes = plane; dprintk(VIDC_DBG, "Releasing buffer: %d, %d, %d\n", buffer_info.m.planes[i].reserved[0], buffer_info.m.planes[i].reserved[1], buffer_info.m.planes[i].length); } buffer_info.length = bi->num_planes; release_buf = true; } if (!release_buf) continue; if (inst->session_type == MSM_VIDC_DECODER) rc = msm_vdec_release_buf(instance, &buffer_info); if (inst->session_type == MSM_VIDC_ENCODER) rc = msm_venc_release_buf(instance, &buffer_info); if (rc) dprintk(VIDC_ERR, "Failed Release buffer: %d, %d, %d\n", buffer_info.m.planes[0].reserved[0], buffer_info.m.planes[0].reserved[1], buffer_info.m.planes[0].length); } mutex_unlock(&inst->registeredbufs.lock); free_and_unmap: mutex_lock(&inst->registeredbufs.lock); list_for_each_entry_safe(bi, dummy, &inst->registeredbufs.list, list) { if (bi->type == buffer_type) { list_del(&bi->list); for (i = 0; i < bi->num_planes; i++) { if (bi->handle[i] && bi->mapped[i]) { dprintk(VIDC_DBG, "%s: [UNMAP] binfo = %p, handle[%d] = %p, device_addr = %pa, fd = %d, offset = %d, mapped = %d\n", __func__, bi, i, bi->handle[i], &bi->device_addr[i], bi->fd[i], bi->buff_off[i], bi->mapped[i]); msm_comm_smem_free(inst, bi->handle[i]); } } kfree(bi); } } mutex_unlock(&inst->registeredbufs.lock); return rc; } EXPORT_SYMBOL(msm_vidc_release_buffers); int msm_vidc_qbuf(void *instance, struct v4l2_buffer *b) { struct msm_vidc_inst *inst = instance; struct buffer_info *binfo; int plane = 0; int rc = 0; int i; if (!inst || !b || !valid_v4l2_buffer(b, inst)) return -EINVAL; rc = map_and_register_buf(inst, b); if (rc == -EEXIST) { if (atomic_read(&inst->in_flush) && is_dynamic_output_buffer_mode(b, inst)) { dprintk(VIDC_ERR, "Flush in progress, do not hold any buffers in driver\n"); msm_comm_flush_dynamic_buffers(inst); } return 0; } if (rc) return rc; for (i = 0; i < b->length; ++i) { if (EXTRADATA_IDX(b->length) && (i == EXTRADATA_IDX(b->length)) && !b->m.planes[i].length) { b->m.planes[i].m.userptr = 0; continue; } mutex_lock(&inst->registeredbufs.lock); binfo = get_registered_buf(inst, b, i, &plane); mutex_unlock(&inst->registeredbufs.lock); if (!binfo) { dprintk(VIDC_ERR, "This buffer is not registered: %d, %d, %d\n", b->m.planes[i].reserved[0], b->m.planes[i].reserved[1], b->m.planes[i].length); goto err_invalid_buff; } b->m.planes[i].m.userptr = binfo->device_addr[i]; dprintk(VIDC_DBG, "Queueing device address = %pa\n", &binfo->device_addr[i]); if (inst->fmts[OUTPUT_PORT]->fourcc == V4L2_PIX_FMT_HEVC_HYBRID && binfo->handle[i] && b->type == V4L2_BUF_TYPE_VIDEO_CAPTURE_MPLANE) { rc = msm_comm_smem_cache_operations(inst, binfo->handle[i], SMEM_CACHE_INVALIDATE); if (rc) { dprintk(VIDC_ERR, "Failed to inv caches: %d\n", rc); goto err_invalid_buff; } } if (binfo->handle[i] && (b->type == V4L2_BUF_TYPE_VIDEO_OUTPUT_MPLANE)) { rc = msm_comm_smem_cache_operations(inst, binfo->handle[i], SMEM_CACHE_CLEAN); if (rc) { dprintk(VIDC_ERR, "Failed to clean caches: %d\n", rc); goto err_invalid_buff; } } } if (inst->session_type == MSM_VIDC_DECODER) return msm_vdec_qbuf(instance, b); if (inst->session_type == MSM_VIDC_ENCODER) return msm_venc_qbuf(instance, b); err_invalid_buff: return -EINVAL; } EXPORT_SYMBOL(msm_vidc_qbuf); int msm_vidc_dqbuf(void *instance, struct v4l2_buffer *b) { struct msm_vidc_inst *inst = instance; struct buffer_info *buffer_info = NULL; int i = 0, rc = 0; if (!inst || !b || !valid_v4l2_buffer(b, inst)) return -EINVAL; if (inst->session_type == MSM_VIDC_DECODER) rc = msm_vdec_dqbuf(instance, b); if (inst->session_type == MSM_VIDC_ENCODER) rc = msm_venc_dqbuf(instance, b); if (rc) return rc; for (i = 0; i < b->length; i++) { if (EXTRADATA_IDX(b->length) && (i == EXTRADATA_IDX(b->length)) && !b->m.planes[i].m.userptr) { continue; } buffer_info = device_to_uvaddr(&inst->registeredbufs, b->m.planes[i].m.userptr); if (!buffer_info) { dprintk(VIDC_ERR, "%s no buffer info registered for buffer addr: %#lx\n", __func__, b->m.planes[i].m.userptr); return -EINVAL; } b->m.planes[i].m.userptr = buffer_info->uvaddr[i]; b->m.planes[i].reserved[0] = buffer_info->fd[i]; b->m.planes[i].reserved[1] = buffer_info->buff_off[i]; if (!b->m.planes[i].m.userptr) { dprintk(VIDC_ERR, "%s: Failed to find user virtual address, %#lx, %d, %d\n", __func__, b->m.planes[i].m.userptr, b->type, i); return -EINVAL; } } if (!buffer_info) { dprintk(VIDC_ERR, "%s: error - no buffer info found in registered list\n", __func__); return -EINVAL; } if (is_dynamic_output_buffer_mode(b, inst)) { if (!buffer_info) return -EINVAL; buffer_info->dequeued = true; dprintk(VIDC_DBG, "[DEQUEUED]: fd[0] = %d\n", buffer_info->fd[0]); mutex_lock(&inst->registeredbufs.lock); rc = unmap_and_deregister_buf(inst, buffer_info); mutex_unlock(&inst->registeredbufs.lock); } else rc = output_buffer_cache_invalidate(inst, buffer_info); return rc; } EXPORT_SYMBOL(msm_vidc_dqbuf); int msm_vidc_streamon(void *instance, enum v4l2_buf_type i) { struct msm_vidc_inst *inst = instance; if (!inst) return -EINVAL; if (inst->session_type == MSM_VIDC_DECODER) return msm_vdec_streamon(instance, i); if (inst->session_type == MSM_VIDC_ENCODER) return msm_venc_streamon(instance, i); return -EINVAL; } EXPORT_SYMBOL(msm_vidc_streamon); int msm_vidc_streamoff(void *instance, enum v4l2_buf_type i) { struct msm_vidc_inst *inst = instance; if (!inst) return -EINVAL; if (inst->session_type == MSM_VIDC_DECODER) return msm_vdec_streamoff(instance, i); if (inst->session_type == MSM_VIDC_ENCODER) return msm_venc_streamoff(instance, i); return -EINVAL; } EXPORT_SYMBOL(msm_vidc_streamoff); int msm_vidc_enum_framesizes(void *instance, struct v4l2_frmsizeenum *fsize) { struct msm_vidc_inst *inst = instance; struct msm_vidc_capability *capability = NULL; if (!inst || !fsize) { dprintk(VIDC_ERR, "%s: invalid parameter: %p %p\n", __func__, inst, fsize); return -EINVAL; } if (!inst->core) return -EINVAL; capability = &inst->capability; fsize->type = V4L2_FRMSIZE_TYPE_STEPWISE; fsize->stepwise.min_width = capability->width.min; fsize->stepwise.max_width = capability->width.max; fsize->stepwise.step_width = capability->width.step_size; fsize->stepwise.min_height = capability->height.min; fsize->stepwise.max_height = capability->height.max; fsize->stepwise.step_height = capability->height.step_size; return 0; } EXPORT_SYMBOL(msm_vidc_enum_framesizes); static void *vidc_get_userptr(void *alloc_ctx, unsigned long vaddr, unsigned long size, int write) { return (void *)0xdeadbeef; } static void vidc_put_userptr(void *buf_priv) { } static const struct vb2_mem_ops msm_vidc_vb2_mem_ops = { .get_userptr = vidc_get_userptr, .put_userptr = vidc_put_userptr, }; static inline int vb2_bufq_init(struct msm_vidc_inst *inst, enum v4l2_buf_type type, enum session_type sess) { struct vb2_queue *q = NULL; if (type == V4L2_BUF_TYPE_VIDEO_CAPTURE_MPLANE) { q = &inst->bufq[CAPTURE_PORT].vb2_bufq; } else if (type == V4L2_BUF_TYPE_VIDEO_OUTPUT_MPLANE) { q = &inst->bufq[OUTPUT_PORT].vb2_bufq; } else { dprintk(VIDC_ERR, "buf_type = %d not recognised\n", type); return -EINVAL; } q->type = type; q->io_modes = VB2_MMAP | VB2_USERPTR; q->io_flags = 0; q->timestamp_flags = V4L2_BUF_FLAG_TIMESTAMP_COPY; if (sess == MSM_VIDC_DECODER) q->ops = msm_vdec_get_vb2q_ops(); else if (sess == MSM_VIDC_ENCODER) q->ops = msm_venc_get_vb2q_ops(); q->mem_ops = &msm_vidc_vb2_mem_ops; q->drv_priv = inst; return vb2_queue_init(q); } static int setup_event_queue(void *inst, struct video_device *pvdev) { int rc = 0; struct msm_vidc_inst *vidc_inst = (struct msm_vidc_inst *)inst; v4l2_fh_init(&vidc_inst->event_handler, pvdev); v4l2_fh_add(&vidc_inst->event_handler); return rc; } int msm_vidc_subscribe_event(void *inst, const struct v4l2_event_subscription *sub) { int rc = 0; struct msm_vidc_inst *vidc_inst = (struct msm_vidc_inst *)inst; if (!inst || !sub) return -EINVAL; rc = v4l2_event_subscribe(&vidc_inst->event_handler, sub, MAX_EVENTS, NULL); return rc; } EXPORT_SYMBOL(msm_vidc_subscribe_event); int msm_vidc_unsubscribe_event(void *inst, const struct v4l2_event_subscription *sub) { int rc = 0; struct msm_vidc_inst *vidc_inst = (struct msm_vidc_inst *)inst; if (!inst || !sub) return -EINVAL; rc = v4l2_event_unsubscribe(&vidc_inst->event_handler, sub); return rc; } EXPORT_SYMBOL(msm_vidc_unsubscribe_event); int msm_vidc_dqevent(void *inst, struct v4l2_event *event) { int rc = 0; struct msm_vidc_inst *vidc_inst = (struct msm_vidc_inst *)inst; if (!inst || !event) return -EINVAL; rc = v4l2_event_dequeue(&vidc_inst->event_handler, event, false); return rc; } EXPORT_SYMBOL(msm_vidc_dqevent); static bool msm_vidc_check_for_inst_overload(struct msm_vidc_core *core) { u32 instance_count = 0; u32 secure_instance_count = 0; struct msm_vidc_inst *inst = NULL; bool overload = false; mutex_lock(&core->lock); list_for_each_entry(inst, &core->instances, list) { instance_count++; /* This flag is not updated yet for the current instance */ if (inst->flags & VIDC_SECURE) secure_instance_count++; } mutex_unlock(&core->lock); /* Instance count includes current instance as well. */ if ((instance_count > core->resources.max_inst_count) || (secure_instance_count > core->resources.max_secure_inst_count)) overload = true; return overload; } void *msm_vidc_open(int core_id, int session_type) { struct msm_vidc_inst *inst = NULL; struct msm_vidc_core *core = NULL; int rc = 0; int i = 0; if (core_id >= MSM_VIDC_CORES_MAX || session_type >= MSM_VIDC_MAX_DEVICES) { dprintk(VIDC_ERR, "Invalid input, core_id = %d, session = %d\n", core_id, session_type); goto err_invalid_core; } core = get_vidc_core(core_id); if (!core) { dprintk(VIDC_ERR, "Failed to find core for core_id = %d\n", core_id); goto err_invalid_core; } inst = kzalloc(sizeof(*inst), GFP_KERNEL); if (!inst) { dprintk(VIDC_ERR, "Failed to allocate memory\n"); rc = -ENOMEM; goto err_invalid_core; } pr_info(VIDC_DBG_TAG "Opening video instance: %p, %d\n", VIDC_MSG_PRIO2STRING(VIDC_INFO), inst, session_type); mutex_init(&inst->sync_lock); mutex_init(&inst->bufq[CAPTURE_PORT].lock); mutex_init(&inst->bufq[OUTPUT_PORT].lock); mutex_init(&inst->lock); INIT_MSM_VIDC_LIST(&inst->pendingq); INIT_MSM_VIDC_LIST(&inst->scratchbufs); INIT_MSM_VIDC_LIST(&inst->persistbufs); INIT_MSM_VIDC_LIST(&inst->pending_getpropq); INIT_MSM_VIDC_LIST(&inst->outputbufs); INIT_MSM_VIDC_LIST(&inst->registeredbufs); kref_init(&inst->kref); inst->session_type = session_type; inst->state = MSM_VIDC_CORE_UNINIT_DONE; inst->core = core; inst->bit_depth = MSM_VIDC_BIT_DEPTH_8; inst->instant_bitrate = 0; for (i = SESSION_MSG_INDEX(SESSION_MSG_START); i <= SESSION_MSG_INDEX(SESSION_MSG_END); i++) { init_completion(&inst->completions[i]); } inst->mem_client = msm_smem_new_client(SMEM_ION, &inst->core->resources, session_type); if (!inst->mem_client) { dprintk(VIDC_ERR, "Failed to create memory client\n"); goto fail_mem_client; } if (session_type == MSM_VIDC_DECODER) { msm_vdec_inst_init(inst); rc = msm_vdec_ctrl_init(inst); } else if (session_type == MSM_VIDC_ENCODER) { msm_venc_inst_init(inst); rc = msm_venc_ctrl_init(inst); } if (rc) goto fail_bufq_capture; msm_dcvs_init(inst); rc = vb2_bufq_init(inst, V4L2_BUF_TYPE_VIDEO_CAPTURE_MPLANE, session_type); if (rc) { dprintk(VIDC_ERR, "Failed to initialize vb2 queue on capture port\n"); goto fail_bufq_capture; } rc = vb2_bufq_init(inst, V4L2_BUF_TYPE_VIDEO_OUTPUT_MPLANE, session_type); if (rc) { dprintk(VIDC_ERR, "Failed to initialize vb2 queue on capture port\n"); goto fail_bufq_output; } setup_event_queue(inst, &core->vdev[session_type].vdev); mutex_lock(&core->lock); list_add_tail(&inst->list, &core->instances); mutex_unlock(&core->lock); rc = msm_comm_try_state(inst, MSM_VIDC_CORE_INIT_DONE); if (rc) { dprintk(VIDC_ERR, "Failed to move video instance to init state\n"); goto fail_init; } if (msm_vidc_check_for_inst_overload(core)) { dprintk(VIDC_ERR, "Instance count reached Max limit, rejecting session"); goto fail_init; } inst->debugfs_root = msm_vidc_debugfs_init_inst(inst, core->debugfs_root); return inst; fail_init: v4l2_fh_del(&inst->event_handler); v4l2_fh_exit(&inst->event_handler); vb2_queue_release(&inst->bufq[OUTPUT_PORT].vb2_bufq); mutex_lock(&core->lock); list_del(&inst->list); mutex_unlock(&core->lock); fail_bufq_output: vb2_queue_release(&inst->bufq[CAPTURE_PORT].vb2_bufq); fail_bufq_capture: msm_comm_ctrl_deinit(inst); msm_smem_delete_client(inst->mem_client); fail_mem_client: kfree(inst); inst = NULL; err_invalid_core: return inst; } EXPORT_SYMBOL(msm_vidc_open); static void cleanup_instance(struct msm_vidc_inst *inst) { struct vb2_buf_entry *entry, *dummy; if (inst) { mutex_lock(&inst->pendingq.lock); list_for_each_entry_safe(entry, dummy, &inst->pendingq.list, list) { list_del(&entry->list); kfree(entry); } mutex_unlock(&inst->pendingq.lock); if (msm_comm_release_scratch_buffers(inst, false)) { dprintk(VIDC_ERR, "Failed to release scratch buffers\n"); } if (msm_comm_release_persist_buffers(inst)) { dprintk(VIDC_ERR, "Failed to release persist buffers\n"); } if (msm_comm_release_output_buffers(inst)) { dprintk(VIDC_ERR, "Failed to release output buffers\n"); } if (inst->extradata_handle) msm_comm_smem_free(inst, inst->extradata_handle); debugfs_remove_recursive(inst->debugfs_root); mutex_lock(&inst->pending_getpropq.lock); WARN_ON(!list_empty(&inst->pending_getpropq.list)); mutex_unlock(&inst->pending_getpropq.lock); } } int msm_vidc_destroy(struct msm_vidc_inst *inst) { struct msm_vidc_core *core; int i = 0; if (!inst || !inst->core) return -EINVAL; core = inst->core; mutex_lock(&core->lock); /* inst->list lives in core->instances */ list_del(&inst->list); mutex_unlock(&core->lock); msm_comm_ctrl_deinit(inst); v4l2_fh_del(&inst->event_handler); v4l2_fh_exit(&inst->event_handler); for (i = 0; i < MAX_PORT_NUM; i++) vb2_queue_release(&inst->bufq[i].vb2_bufq); pr_info(VIDC_DBG_TAG "Closed video instance: %p\n", VIDC_MSG_PRIO2STRING(VIDC_INFO), inst); kfree(inst); return 0; } int msm_vidc_close(void *instance) { void close_helper(struct kref *kref) { struct msm_vidc_inst *inst = container_of(kref, struct msm_vidc_inst, kref); msm_vidc_destroy(inst); } struct msm_vidc_inst *inst = instance; struct buffer_info *bi, *dummy; int rc = 0; if (!inst || !inst->core) return -EINVAL; mutex_lock(&inst->registeredbufs.lock); list_for_each_entry_safe(bi, dummy, &inst->registeredbufs.list, list) { if (bi->type == V4L2_BUF_TYPE_VIDEO_OUTPUT_MPLANE) { int i = 0; list_del(&bi->list); for (i = 0; i < min(bi->num_planes, VIDEO_MAX_PLANES); i++) { if (bi->handle[i] && bi->mapped[i]) msm_comm_smem_free(inst, bi->handle[i]); } kfree(bi); } } mutex_unlock(&inst->registeredbufs.lock); cleanup_instance(inst); if (inst->state != MSM_VIDC_CORE_INVALID && inst->core->state != VIDC_CORE_INVALID) rc = msm_comm_try_state(inst, MSM_VIDC_CORE_UNINIT); else rc = msm_comm_force_cleanup(inst); if (rc) dprintk(VIDC_ERR, "Failed to move video instance to uninit state\n"); msm_comm_session_clean(inst); msm_smem_delete_client(inst->mem_client); kref_put(&inst->kref, close_helper); return 0; } EXPORT_SYMBOL(msm_vidc_close); int msm_vidc_suspend(int core_id) { return msm_comm_suspend(core_id); } EXPORT_SYMBOL(msm_vidc_suspend);