// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (c) 2020-2021, The Linux Foundation. All rights reserved. */ #include "msm_vidc_control.h" #include "msm_vidc_debug.h" #include "hfi_packet.h" #include "hfi_property.h" #include "venus_hfi.h" #include "msm_vidc_internal.h" #include "msm_vidc_driver.h" #define CAP_TO_8BIT_QP(a) { \ if ((a) < 0) \ (a) = 0; \ } static bool is_priv_ctrl(u32 id) { bool private = false; if (IS_PRIV_CTRL(id)) return true; /* * Treat below standard controls as private because * we have added custom values to the controls */ switch (id) { /* * TODO: V4L2_CID_MPEG_VIDEO_H264_HIERARCHICAL_CODING_TYPE is * std ctrl. But needs some fixes in v4l2-ctrls.c. Hence, * make this as private ctrl for time being */ case V4L2_CID_MPEG_VIDEO_H264_HIERARCHICAL_CODING_TYPE: private = true; break; default: private = false; break; } return private; } static bool is_meta_ctrl(u32 id) { return (id == V4L2_CID_MPEG_VIDC_METADATA_LTR_MARK_USE_DETAILS || id == V4L2_CID_MPEG_VIDC_METADATA_SEQ_HEADER_NAL || id == V4L2_CID_MPEG_VIDC_METADATA_DPB_LUMA_CHROMA_MISR || id == V4L2_CID_MPEG_VIDC_METADATA_OPB_LUMA_CHROMA_MISR || id == V4L2_CID_MPEG_VIDC_METADATA_INTERLACE || id == V4L2_CID_MPEG_VIDC_METADATA_CONCEALED_MB_COUNT || id == V4L2_CID_MPEG_VIDC_METADATA_HISTOGRAM_INFO || id == V4L2_CID_MPEG_VIDC_METADATA_SEI_MASTERING_DISPLAY_COLOUR || id == V4L2_CID_MPEG_VIDC_METADATA_SEI_CONTENT_LIGHT_LEVEL || id == V4L2_CID_MPEG_VIDC_METADATA_HDR10PLUS || id == V4L2_CID_MPEG_VIDC_METADATA_EVA_STATS || id == V4L2_CID_MPEG_VIDC_METADATA_BUFFER_TAG || id == V4L2_CID_MPEG_VIDC_METADATA_DPB_TAG_LIST || id == V4L2_CID_MPEG_VIDC_METADATA_SUBFRAME_OUTPUT || id == V4L2_CID_MPEG_VIDC_METADATA_ROI_INFO || id == V4L2_CID_MPEG_VIDC_METADATA_TIMESTAMP || id == V4L2_CID_MPEG_VIDC_METADATA_ENC_QP_METADATA); } static const char *const mpeg_video_rate_control[] = { "VBR", "CBR", "CBR VFR", "MBR", "MBR VFR", "CQ", NULL, }; static const char *const mpeg_video_stream_format[] = { "NAL Format Start Codes", "NAL Format One NAL Per Buffer", "NAL Format One Byte Length", "NAL Format Two Byte Length", "NAL Format Four Byte Length", NULL, }; static const char *const mpeg_video_blur_types[] = { "Blur None", "Blur External", "Blur Adaptive", NULL, }; static const char *const mpeg_video_avc_coding_layer[] = { "B", "P", NULL, }; static const char *const roi_map_type[] = { "None", "2-bit", "2-bit", NULL, }; static u32 msm_vidc_get_port_info(struct msm_vidc_inst *inst, enum msm_vidc_inst_capability_type cap_id) { struct msm_vidc_inst_capability *capability = inst->capabilities; if (capability->cap[cap_id].flags & CAP_FLAG_INPUT_PORT && capability->cap[cap_id].flags & CAP_FLAG_OUTPUT_PORT) { if (inst->vb2q[OUTPUT_PORT].streaming) return get_hfi_port(inst, INPUT_PORT); else return get_hfi_port(inst, OUTPUT_PORT); } if (capability->cap[cap_id].flags & CAP_FLAG_INPUT_PORT) return get_hfi_port(inst, INPUT_PORT); else if (capability->cap[cap_id].flags & CAP_FLAG_OUTPUT_PORT) return get_hfi_port(inst, OUTPUT_PORT); else return HFI_PORT_NONE; } static const char * const * msm_vidc_get_qmenu_type( struct msm_vidc_inst *inst, u32 control_id) { switch (control_id) { case V4L2_CID_MPEG_VIDEO_BITRATE_MODE: return mpeg_video_rate_control; case V4L2_CID_MPEG_VIDEO_HEVC_SIZE_OF_LENGTH_FIELD: return mpeg_video_stream_format; case V4L2_CID_MPEG_VIDC_VIDEO_BLUR_TYPES: return mpeg_video_blur_types; case V4L2_CID_MPEG_VIDEO_H264_HIERARCHICAL_CODING_TYPE: return mpeg_video_avc_coding_layer; default: i_vpr_e(inst, "%s: No available qmenu for ctrl %#x\n", __func__, control_id); return NULL; } } static int msm_vidc_packetize_control(struct msm_vidc_inst *inst, enum msm_vidc_inst_capability_type cap_id, u32 payload_type, void *hfi_val, u32 payload_size, const char *func) { int rc = 0; i_vpr_h(inst, "set cap: name: %24s, cap value: %#10x, hfi: %#10x\n", cap_name(cap_id), inst->capabilities->cap[cap_id].value, *(s64 *)hfi_val); rc = venus_hfi_session_property(inst, inst->capabilities->cap[cap_id].hfi_id, HFI_HOST_FLAGS_NONE, msm_vidc_get_port_info(inst, cap_id), payload_type, hfi_val, sizeof(payload_size)); if (rc) i_vpr_e(inst, "%s: failed to set cap[%d] %s to fw\n", __func__, cap_id, cap_name(cap_id)); return rc; } static enum msm_vidc_inst_capability_type msm_vidc_get_cap_id( struct msm_vidc_inst *inst, u32 id) { enum msm_vidc_inst_capability_type i = INST_CAP_NONE + 1; struct msm_vidc_inst_capability *capability; enum msm_vidc_inst_capability_type cap_id = INST_CAP_NONE; capability = inst->capabilities; do { if (capability->cap[i].v4l2_id == id) { cap_id = capability->cap[i].cap; break; } i++; } while (i < INST_CAP_MAX); return cap_id; } static int msm_vidc_add_capid_to_list(struct msm_vidc_inst *inst, enum msm_vidc_inst_capability_type cap_id, enum msm_vidc_ctrl_list_type type) { struct msm_vidc_inst_cap_entry *entry = NULL, *curr_node = NULL; /* skip adding if cap_id already present in list */ if (type & FW_LIST) { list_for_each_entry(curr_node, &inst->firmware.list, list) { if (curr_node->cap_id == cap_id) { i_vpr_l(inst, "%s: cap[%d] %s already present in FW_LIST\n", __func__, cap_id, cap_name(cap_id)); return 0; } } } entry = kzalloc(sizeof(*entry), GFP_ATOMIC); if (!entry) { i_vpr_e(inst, "%s: alloc failed\n", __func__); return -ENOMEM; } entry->cap_id = cap_id; if (type & CHILD_LIST) list_add_tail(&entry->list, &inst->children.list); if (type & FW_LIST) list_add_tail(&entry->list, &inst->firmware.list); return 0; } static int msm_vidc_add_children(struct msm_vidc_inst *inst, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; int i = 0; struct msm_vidc_inst_capability *capability = inst->capabilities; while (i < MAX_CAP_CHILDREN && capability->cap[cap_id].children[i]) { rc = msm_vidc_add_capid_to_list(inst, capability->cap[cap_id].children[i], CHILD_LIST); if (rc) return rc; i++; } return rc; } static bool is_parent_available(struct msm_vidc_inst* inst, u32 cap, u32 check_parent) { int i = 0; u32 cap_parent; while (i < MAX_CAP_PARENTS && inst->capabilities->cap[cap].parents[i]) { cap_parent = inst->capabilities->cap[cap].parents[i]; if (cap_parent == check_parent) { return true; } i++; } return false; } int msm_vidc_update_cap_value(struct msm_vidc_inst *inst, u32 cap, s32 adjusted_val, const char *func) { if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } if (inst->capabilities->cap[cap].value != adjusted_val) i_vpr_h(inst, "%s: updated database: name: %s, value: %#x -> %#x\n", func, cap_name(cap), inst->capabilities->cap[cap].value, adjusted_val); inst->capabilities->cap[cap].value = adjusted_val; return 0; } static int msm_vidc_get_parent_value(struct msm_vidc_inst* inst, u32 cap, u32 parent, s32 *value, const char *func) { int rc = 0; if (is_parent_available(inst, cap, parent)) { switch (parent) { case BITRATE_MODE: *value = inst->hfi_rc_type; break; case LAYER_TYPE: *value = inst->hfi_layer_type; break; default: *value = inst->capabilities->cap[parent].value; break; } } else { i_vpr_e(inst, "%s: missing parent %d for cap[%d] %s, fix database\n", func, parent, cap, cap_name(cap)); rc = -EINVAL; } return rc; } static int msm_vidc_adjust_hevc_qp(struct msm_vidc_inst *inst, enum msm_vidc_inst_capability_type cap_id) { struct msm_vidc_inst_capability *capability; s32 pix_fmt = -1; capability = inst->capabilities; if (!(inst->codec == MSM_VIDC_HEVC || inst->codec == MSM_VIDC_HEIC)) { i_vpr_e(inst, "%s: incorrect cap[%d] %s entry in database, fix database\n", __func__, cap_id, cap_name(cap_id)); return -EINVAL; } if (msm_vidc_get_parent_value(inst, cap_id, PIX_FMTS, &pix_fmt, __func__)) return -EINVAL; if (pix_fmt == MSM_VIDC_FMT_P010 || pix_fmt == MSM_VIDC_FMT_TP10C) goto exit; CAP_TO_8BIT_QP(capability->cap[cap_id].value); if (cap_id == MIN_FRAME_QP) { CAP_TO_8BIT_QP(capability->cap[I_FRAME_MIN_QP].value); CAP_TO_8BIT_QP(capability->cap[P_FRAME_MIN_QP].value); CAP_TO_8BIT_QP(capability->cap[B_FRAME_MIN_QP].value); } else if (cap_id == MAX_FRAME_QP) { CAP_TO_8BIT_QP(capability->cap[I_FRAME_MAX_QP].value); CAP_TO_8BIT_QP(capability->cap[P_FRAME_MAX_QP].value); CAP_TO_8BIT_QP(capability->cap[B_FRAME_MAX_QP].value); } else if (cap_id == I_FRAME_QP) { CAP_TO_8BIT_QP(capability->cap[P_FRAME_QP].value); CAP_TO_8BIT_QP(capability->cap[B_FRAME_QP].value); } exit: return 0; } static int msm_vidc_adjust_property(struct msm_vidc_inst *inst, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst_capability *capability; capability = inst->capabilities; /* * skip for uninitialized cap properties. * Eg: Skip Tramform 8x8 cap that is uninitialized for HEVC codec */ if (!capability->cap[cap_id].cap) return 0; if (capability->cap[cap_id].adjust) { rc = capability->cap[cap_id].adjust(inst, NULL); if (rc) goto exit; } /* add children cap_id's to chidren list */ rc = msm_vidc_add_children(inst, cap_id); if (rc) goto exit; /* add cap_id to firmware list */ rc = msm_vidc_add_capid_to_list(inst, cap_id, FW_LIST); if (rc) goto exit; return 0; exit: return rc; } static int msm_vidc_adjust_dynamic_property(struct msm_vidc_inst *inst, enum msm_vidc_inst_capability_type cap_id, struct v4l2_ctrl *ctrl) { int rc = 0; struct msm_vidc_inst_capability *capability; s32 prev_value; capability = inst->capabilities; /* * ctrl is NULL for children adjustment calls * When a dynamic control having children is adjusted, check if dynamic * adjustment is allowed for its children. */ if (!(capability->cap[cap_id].flags & CAP_FLAG_DYNAMIC_ALLOWED)) { i_vpr_e(inst, "%s: dynamic setting of cap[%d] %s is not allowed\n", __func__, cap_id, cap_name(cap_id)); msm_vidc_change_inst_state(inst, MSM_VIDC_ERROR, __func__); return -EINVAL; } /* * if ctrl is NULL, it is children of some parent, and hence, * must have an adjust function defined */ if (!ctrl && !capability->cap[cap_id].adjust) { i_vpr_e(inst, "%s: child cap[%d] %s must have ajdust function\n", __func__, capability->cap[cap_id].cap, cap_name(capability->cap[cap_id].cap)); return -EINVAL; } prev_value = capability->cap[cap_id].value; if (capability->cap[cap_id].adjust) { rc = capability->cap[cap_id].adjust(inst, ctrl); if (rc) goto exit; } else if (ctrl) { msm_vidc_update_cap_value(inst, cap_id, ctrl->val, __func__); } /* add children if cap value modified */ if (capability->cap[cap_id].value != prev_value) { rc = msm_vidc_add_children(inst, cap_id); if (rc) goto exit; } /* add cap_id to firmware list always */ rc = msm_vidc_add_capid_to_list(inst, cap_id, FW_LIST); if (rc) goto exit; return 0; exit: return rc; } int msm_vidc_ctrl_deinit(struct msm_vidc_inst *inst) { if (!inst) { d_vpr_e("%s: invalid parameters\n", __func__); return -EINVAL; } i_vpr_h(inst, "%s(): num ctrls %d\n", __func__, inst->num_ctrls); v4l2_ctrl_handler_free(&inst->ctrl_handler); memset(&inst->ctrl_handler, 0, sizeof(struct v4l2_ctrl_handler)); kfree(inst->ctrls); inst->ctrls = NULL; return 0; } int msm_vidc_ctrl_init(struct msm_vidc_inst *inst) { int rc = 0; struct msm_vidc_inst_capability *capability; struct msm_vidc_core *core; int idx = 0; struct v4l2_ctrl_config ctrl_cfg = {0}; int num_ctrls = 0, ctrl_idx = 0; if (!inst || !inst->core || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } core = inst->core; capability = inst->capabilities; if (!core->v4l2_ctrl_ops) { i_vpr_e(inst, "%s: no control ops\n", __func__); return -EINVAL; } for (idx = 0; idx < INST_CAP_MAX; idx++) { if (capability->cap[idx].v4l2_id) num_ctrls++; } if (!num_ctrls) { i_vpr_e(inst, "%s: no ctrls available in cap database\n", __func__); return -EINVAL; } inst->ctrls = kcalloc(num_ctrls, sizeof(struct v4l2_ctrl *), GFP_KERNEL); if (!inst->ctrls) { i_vpr_e(inst, "%s: failed to allocate ctrl\n", __func__); return -ENOMEM; } rc = v4l2_ctrl_handler_init(&inst->ctrl_handler, num_ctrls); if (rc) { i_vpr_e(inst, "control handler init failed, %d\n", inst->ctrl_handler.error); goto error; } for (idx = 0; idx < INST_CAP_MAX; idx++) { struct v4l2_ctrl *ctrl; if (!capability->cap[idx].v4l2_id) continue; if (ctrl_idx >= num_ctrls) { i_vpr_e(inst, "%s: invalid ctrl %#x, max allowed %d\n", __func__, capability->cap[idx].v4l2_id, num_ctrls); rc = -EINVAL; goto error; } i_vpr_h(inst, "%s: cap[%d] %24s, value %d min %d max %d step_or_mask %#x flags %#x v4l2_id %#x hfi_id %#x\n", __func__, idx, cap_name(idx), capability->cap[idx].value, capability->cap[idx].min, capability->cap[idx].max, capability->cap[idx].step_or_mask, capability->cap[idx].flags, capability->cap[idx].v4l2_id, capability->cap[idx].hfi_id); memset(&ctrl_cfg, 0, sizeof(struct v4l2_ctrl_config)); if (is_priv_ctrl(capability->cap[idx].v4l2_id)) { /* add private control */ ctrl_cfg.def = capability->cap[idx].value; ctrl_cfg.flags = 0; ctrl_cfg.id = capability->cap[idx].v4l2_id; ctrl_cfg.max = capability->cap[idx].max; ctrl_cfg.min = capability->cap[idx].min; ctrl_cfg.ops = core->v4l2_ctrl_ops; ctrl_cfg.type = (capability->cap[idx].flags & CAP_FLAG_MENU) ? V4L2_CTRL_TYPE_MENU : V4L2_CTRL_TYPE_INTEGER; if (ctrl_cfg.type == V4L2_CTRL_TYPE_MENU) { ctrl_cfg.menu_skip_mask = ~(capability->cap[idx].step_or_mask); ctrl_cfg.qmenu = msm_vidc_get_qmenu_type(inst, capability->cap[idx].v4l2_id); } else { ctrl_cfg.step = capability->cap[idx].step_or_mask; } ctrl_cfg.name = cap_name(capability->cap[idx].cap); if (!ctrl_cfg.name) { i_vpr_e(inst, "%s: %#x ctrl name is null\n", __func__, ctrl_cfg.id); rc = -EINVAL; goto error; } ctrl = v4l2_ctrl_new_custom(&inst->ctrl_handler, &ctrl_cfg, NULL); } else { if (capability->cap[idx].flags & CAP_FLAG_MENU) { ctrl = v4l2_ctrl_new_std_menu( &inst->ctrl_handler, core->v4l2_ctrl_ops, capability->cap[idx].v4l2_id, capability->cap[idx].max, ~(capability->cap[idx].step_or_mask), capability->cap[idx].value); } else { ctrl = v4l2_ctrl_new_std(&inst->ctrl_handler, core->v4l2_ctrl_ops, capability->cap[idx].v4l2_id, capability->cap[idx].min, capability->cap[idx].max, capability->cap[idx].step_or_mask, capability->cap[idx].value); } } if (!ctrl) { i_vpr_e(inst, "%s: invalid ctrl %#x\n", __func__, capability->cap[idx].v4l2_id); rc = -EINVAL; goto error; } rc = inst->ctrl_handler.error; if (rc) { i_vpr_e(inst, "error adding ctrl (%#x) to ctrl handle, %d\n", capability->cap[idx].v4l2_id, inst->ctrl_handler.error); goto error; } /* * TODO(AS) * ctrl->flags |= capability->cap[idx].flags; */ ctrl->flags |= V4L2_CTRL_FLAG_EXECUTE_ON_WRITE; inst->ctrls[ctrl_idx] = ctrl; ctrl_idx++; } inst->num_ctrls = num_ctrls; i_vpr_h(inst, "%s(): num ctrls %d\n", __func__, inst->num_ctrls); return 0; error: msm_vidc_ctrl_deinit(inst); return rc; } int msm_v4l2_op_s_ctrl(struct v4l2_ctrl *ctrl) { int rc = 0; struct msm_vidc_inst *inst; enum msm_vidc_inst_capability_type cap_id; struct msm_vidc_inst_cap_entry *curr_node = NULL, *tmp_node = NULL; struct msm_vidc_inst_capability *capability; if (!ctrl) { d_vpr_e("%s: invalid ctrl parameter\n", __func__); return -EINVAL; } inst = container_of(ctrl->handler, struct msm_vidc_inst, ctrl_handler); if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid parameters for inst\n", __func__); return -EINVAL; } if (inst->state == MSM_VIDC_ERROR) { i_vpr_e(inst, "%s: set ctrl not allowed in error state\n"); /* (error name TBD); */ return -EINVAL; } capability = inst->capabilities; i_vpr_h(inst, "%s: state %d, name %s, id 0x%x value %d\n", __func__, inst->state, ctrl->name, ctrl->id, ctrl->val); cap_id = msm_vidc_get_cap_id(inst, ctrl->id); if (cap_id == INST_CAP_NONE) { i_vpr_e(inst, "%s: could not find cap_id for ctrl %s\n", __func__, ctrl->name); return -EINVAL; } capability->cap[cap_id].flags |= CAP_FLAG_CLIENT_SET; /* Static setting */ if (!inst->vb2q[OUTPUT_PORT].streaming) { msm_vidc_update_cap_value(inst, cap_id, ctrl->val, __func__); if (ctrl->id == V4L2_CID_MPEG_VIDC_MIN_BITSTREAM_SIZE_OVERWRITE) { rc = msm_vidc_update_bitstream_buffer_size(inst); if (rc) return rc; } if (ctrl->id == V4L2_CID_MPEG_VIDC_PRIORITY) { rc = msm_vidc_adjust_session_priority(inst, ctrl); if (rc) return rc; } if (ctrl->id == V4L2_CID_MPEG_VIDC_THUMBNAIL_MODE) { rc = msm_vidc_update_buffer_count(inst, INPUT_PORT); if (rc) return rc; } if (is_meta_ctrl(ctrl->id)) { if (cap_id == META_DPB_TAG_LIST) { /* * To subscribe HFI_PROP_DPB_TAG_LIST * data in FBD, HFI_PROP_BUFFER_TAG data * must be delivered via FTB. Hence, update * META_OUTPUT_BUF_TAG when META_DPB_TAG_LIST * is updated. */ msm_vidc_update_cap_value(inst, META_OUTPUT_BUF_TAG, ctrl->val, __func__); } rc = msm_vidc_update_meta_port_settings(inst); if (rc) return rc; } return 0; } /* check if dynamic adjustment is allowed */ if (inst->vb2q[OUTPUT_PORT].streaming && !(capability->cap[cap_id].flags & CAP_FLAG_DYNAMIC_ALLOWED)) { i_vpr_e(inst, "%s: dynamic setting of cap[%d] %s is not allowed\n", __func__, cap_id, cap_name(cap_id)); return -EBUSY; } rc = msm_vidc_adjust_dynamic_property(inst, cap_id, ctrl); if (rc) goto exit; /* adjust all children if any */ list_for_each_entry_safe(curr_node, tmp_node, &inst->children.list, list) { rc = msm_vidc_adjust_dynamic_property( inst, curr_node->cap_id, NULL); if (rc) goto exit; list_del(&curr_node->list); kfree(curr_node); } /* dynamic controls with request will be set along with qbuf */ if (inst->request) return 0; /* Dynamic set control ASAP */ rc = msm_vidc_set_v4l2_properties(inst); if (rc) { i_vpr_e(inst, "%s: setting %s failed\n", __func__, ctrl->name); goto exit; } exit: return rc; } int msm_vidc_adjust_entropy_mode(void *instance, struct v4l2_ctrl *ctrl) { struct msm_vidc_inst_capability *capability; s32 adjusted_value; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; s32 profile = -1; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; /* ctrl is always NULL in streamon case */ adjusted_value = ctrl ? ctrl->val : capability->cap[ENTROPY_MODE].value; if (inst->codec != MSM_VIDC_H264) { i_vpr_e(inst, "%s: incorrect entry in database. fix the database\n", __func__); return 0; } if (msm_vidc_get_parent_value(inst, ENTROPY_MODE, PROFILE, &profile, __func__)) return -EINVAL; if (profile == V4L2_MPEG_VIDEO_H264_PROFILE_BASELINE || profile == V4L2_MPEG_VIDEO_H264_PROFILE_CONSTRAINED_BASELINE) adjusted_value = V4L2_MPEG_VIDEO_H264_ENTROPY_MODE_CAVLC; msm_vidc_update_cap_value(inst, ENTROPY_MODE, adjusted_value, __func__); return 0; } int msm_vidc_adjust_bitrate_mode(void *instance, struct v4l2_ctrl *ctrl) { struct msm_vidc_inst_capability *capability; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; int lossless, frame_rc, bitrate_mode, frame_skip; u32 hfi_value = 0; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; bitrate_mode = capability->cap[BITRATE_MODE].value; lossless = capability->cap[LOSSLESS].value; frame_rc = capability->cap[FRAME_RC_ENABLE].value; frame_skip = capability->cap[FRAME_SKIP_MODE].value; if (lossless) { hfi_value = HFI_RC_LOSSLESS; goto update; } if (!frame_rc && !is_image_session(inst)) { hfi_value = HFI_RC_OFF; goto update; } if (bitrate_mode == V4L2_MPEG_VIDEO_BITRATE_MODE_VBR) { hfi_value = HFI_RC_VBR_CFR; } else if (bitrate_mode == V4L2_MPEG_VIDEO_BITRATE_MODE_CBR) { if (frame_skip) hfi_value = HFI_RC_CBR_VFR; else hfi_value = HFI_RC_CBR_CFR; } else if (bitrate_mode == V4L2_MPEG_VIDEO_BITRATE_MODE_CQ) { hfi_value = HFI_RC_CQ; } update: inst->hfi_rc_type = hfi_value; i_vpr_h(inst, "%s: hfi rc type: %#x\n", __func__, inst->hfi_rc_type); return 0; } int msm_vidc_adjust_profile(void *instance, struct v4l2_ctrl *ctrl) { struct msm_vidc_inst_capability *capability; s32 adjusted_value; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; s32 pix_fmt = -1; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; adjusted_value = ctrl ? ctrl->val : capability->cap[PROFILE].value; /* PIX_FMTS dependency is common across all chipsets. * Hence, PIX_FMTS must be specified as Parent for HEVC profile. * Otherwise it would be a database error that should be fixed. */ if (msm_vidc_get_parent_value(inst, PROFILE, PIX_FMTS, &pix_fmt, __func__)) return -EINVAL; /* 10 bit profile for 10 bit color format */ if (pix_fmt == MSM_VIDC_FMT_TP10C || pix_fmt == MSM_VIDC_FMT_P010) { adjusted_value = V4L2_MPEG_VIDEO_HEVC_PROFILE_MAIN_10; } else { /* 8 bit profile for 8 bit color format */ if (adjusted_value == V4L2_MPEG_VIDEO_HEVC_PROFILE_MAIN_10) { if (is_image_session(inst)) adjusted_value = V4L2_MPEG_VIDEO_HEVC_PROFILE_MAIN_STILL_PICTURE; else adjusted_value = V4L2_MPEG_VIDEO_HEVC_PROFILE_MAIN; } } msm_vidc_update_cap_value(inst, PROFILE, adjusted_value, __func__); return 0; } int msm_vidc_adjust_ltr_count(void *instance, struct v4l2_ctrl *ctrl) { struct msm_vidc_inst_capability *capability; s32 adjusted_value; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; s32 rc_type = -1; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; adjusted_value = ctrl ? ctrl->val : capability->cap[LTR_COUNT].value; if (msm_vidc_get_parent_value(inst, LTR_COUNT, BITRATE_MODE, &rc_type, __func__)) return -EINVAL; if (rc_type != HFI_RC_OFF && rc_type != HFI_RC_CBR_CFR && rc_type != HFI_RC_CBR_VFR) adjusted_value = 0; msm_vidc_update_cap_value(inst, LTR_COUNT, adjusted_value, __func__); return 0; } int msm_vidc_adjust_use_ltr(void *instance, struct v4l2_ctrl *ctrl) { struct msm_vidc_inst_capability *capability; s32 adjusted_value; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; s32 ltr_count = -1; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; adjusted_value = ctrl ? ctrl->val : capability->cap[USE_LTR].value; if (msm_vidc_get_parent_value(inst, USE_LTR, LTR_COUNT, <r_count, __func__)) return -EINVAL; if (!ltr_count) { adjusted_value = 0; } else if (adjusted_value <= 0 || adjusted_value >= (1 << ltr_count)) { /* USE_LTR value should be > 0 and < (2 ^ LTR_COUNT) */ i_vpr_e(inst, "%s: invalid value %d\n", __func__, adjusted_value); return -EINVAL; } /* USE_LTR value is a bitmask value */ msm_vidc_update_cap_value(inst, USE_LTR, adjusted_value, __func__); return 0; } int msm_vidc_adjust_mark_ltr(void *instance, struct v4l2_ctrl *ctrl) { struct msm_vidc_inst_capability *capability; s32 adjusted_value; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; s32 ltr_count = -1; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; adjusted_value = ctrl ? ctrl->val : capability->cap[MARK_LTR].value; if (msm_vidc_get_parent_value(inst, MARK_LTR, LTR_COUNT, <r_count, __func__)) return -EINVAL; if (!ltr_count) { adjusted_value = 0; } else if (adjusted_value < 0 || adjusted_value > (ltr_count - 1)) { /* MARK_LTR value should be > 0 and <= (LTR_COUNT - 1) */ i_vpr_e(inst, "%s: invalid value %d\n", __func__, adjusted_value); return -EINVAL; } msm_vidc_update_cap_value(inst, MARK_LTR, adjusted_value, __func__); return 0; } int msm_vidc_adjust_ir_random(void *instance, struct v4l2_ctrl *ctrl) { struct msm_vidc_inst_capability *capability; s32 adjusted_value; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; adjusted_value = ctrl ? ctrl->val : capability->cap[IR_RANDOM].value; /* * BITRATE_MODE dependency is NOT common across all chipsets. * Hence, do not return error if not specified as one of the parent. */ if (is_parent_available(inst, IR_RANDOM, BITRATE_MODE) && inst->hfi_rc_type != HFI_RC_CBR_CFR && inst->hfi_rc_type != HFI_RC_CBR_VFR) adjusted_value = 0; msm_vidc_update_cap_value(inst, IR_RANDOM, adjusted_value, __func__); return 0; } int msm_vidc_adjust_delta_based_rc(void *instance, struct v4l2_ctrl *ctrl) { struct msm_vidc_inst_capability *capability; s32 adjusted_value; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; s32 rc_type = -1; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; adjusted_value = ctrl ? ctrl->val : capability->cap[TIME_DELTA_BASED_RC].value; if (msm_vidc_get_parent_value(inst, TIME_DELTA_BASED_RC, BITRATE_MODE, &rc_type, __func__)) return -EINVAL; if (rc_type == HFI_RC_OFF || rc_type == HFI_RC_CQ) adjusted_value = 0; msm_vidc_update_cap_value(inst, TIME_DELTA_BASED_RC, adjusted_value, __func__); return 0; } int msm_vidc_adjust_transform_8x8(void *instance, struct v4l2_ctrl *ctrl) { struct msm_vidc_inst_capability *capability; s32 adjusted_value; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; s32 profile = -1; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; adjusted_value = ctrl ? ctrl->val : capability->cap[TRANSFORM_8X8].value; if (inst->codec != MSM_VIDC_H264) { i_vpr_e(inst, "%s: incorrect entry in database. fix the database\n", __func__); return 0; } if (msm_vidc_get_parent_value(inst, TRANSFORM_8X8, PROFILE, &profile, __func__)) return -EINVAL; if (profile != V4L2_MPEG_VIDEO_H264_PROFILE_HIGH && profile != V4L2_MPEG_VIDEO_H264_PROFILE_CONSTRAINED_HIGH) adjusted_value = V4L2_MPEG_MSM_VIDC_DISABLE; msm_vidc_update_cap_value(inst, TRANSFORM_8X8, adjusted_value, __func__); return 0; } static int msm_vidc_adjust_static_layer_count_and_type(struct msm_vidc_inst *inst, s32 layer_count) { bool hb_requested = false; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } if (!layer_count) { i_vpr_h(inst, "client not enabled layer encoding\n"); goto exit; } if (inst->hfi_rc_type == HFI_RC_CQ) { i_vpr_h(inst, "rc type is CQ, disabling layer encoding\n"); layer_count = 0; goto exit; } if (inst->codec == MSM_VIDC_H264) { if (!inst->capabilities->cap[LAYER_ENABLE].value) { layer_count = 0; goto exit; } hb_requested = (inst->capabilities->cap[LAYER_TYPE].value == V4L2_MPEG_VIDEO_H264_HIERARCHICAL_CODING_B) ? true : false; } else if (inst->codec == MSM_VIDC_HEVC) { hb_requested = (inst->capabilities->cap[LAYER_TYPE].value == V4L2_MPEG_VIDEO_HEVC_HIERARCHICAL_CODING_B) ? true : false; } if (hb_requested && inst->hfi_rc_type != HFI_RC_VBR_CFR) { i_vpr_h(inst, "%s: HB layer encoding is supported for VBR rc only\n", __func__); layer_count = 0; goto exit; } /* decide hfi layer type */ if (hb_requested) { inst->hfi_layer_type = HFI_HIER_B; } else { /* HP requested */ inst->hfi_layer_type = HFI_HIER_P_SLIDING_WINDOW; if (inst->codec == MSM_VIDC_H264 && inst->hfi_rc_type == HFI_RC_VBR_CFR) inst->hfi_layer_type = HFI_HIER_P_HYBRID_LTR; } /* sanitize layer count based on layer type and codec */ if (inst->hfi_layer_type == HFI_HIER_B) { if (layer_count > MAX_ENH_LAYER_HB) layer_count = MAX_ENH_LAYER_HB; } else if (inst->hfi_layer_type == HFI_HIER_P_HYBRID_LTR) { if (layer_count > MAX_AVC_ENH_LAYER_HYBRID_HP) layer_count = MAX_AVC_ENH_LAYER_HYBRID_HP; } else if (inst->hfi_layer_type == HFI_HIER_P_SLIDING_WINDOW) { if (inst->codec == MSM_VIDC_H264) { if (layer_count > MAX_AVC_ENH_LAYER_SLIDING_WINDOW) layer_count = MAX_AVC_ENH_LAYER_SLIDING_WINDOW; } else { if (layer_count > MAX_HEVC_ENH_LAYER_SLIDING_WINDOW) layer_count = MAX_HEVC_ENH_LAYER_SLIDING_WINDOW; } } exit: msm_vidc_update_cap_value(inst, ENH_LAYER_COUNT, layer_count, __func__); inst->capabilities->cap[ENH_LAYER_COUNT].max = layer_count; return 0; } int msm_vidc_adjust_layer_count(void *instance, struct v4l2_ctrl *ctrl) { int rc = 0; struct msm_vidc_inst_capability *capability; s32 client_layer_count; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; client_layer_count = ctrl ? ctrl->val : capability->cap[ENH_LAYER_COUNT].value; if (!is_parent_available(inst, ENH_LAYER_COUNT, BITRATE_MODE)) { i_vpr_e(inst, "%s: missing parent %d in database", __func__, BITRATE_MODE); return -EINVAL; } if (!inst->vb2q[OUTPUT_PORT].streaming) { rc = msm_vidc_adjust_static_layer_count_and_type(inst, client_layer_count); if (rc) goto exit; } else { if (inst->hfi_layer_type == HFI_HIER_P_HYBRID_LTR || inst->hfi_layer_type == HFI_HIER_P_SLIDING_WINDOW) { /* dynamic layer count change is only supported for HP */ if (client_layer_count > inst->capabilities->cap[ENH_LAYER_COUNT].max) client_layer_count = inst->capabilities->cap[ENH_LAYER_COUNT].max; msm_vidc_update_cap_value(inst, ENH_LAYER_COUNT, client_layer_count, __func__); } } exit: return rc; } /* * 1. GOP calibration is only done for HP layer encoding type. * 2. Dynamic GOP size should not exceed static GOP size * 3. For HB case, or when layer encoding is not enabled, * client set GOP size is directly set to FW. */ int msm_vidc_adjust_gop_size(void *instance, struct v4l2_ctrl *ctrl) { struct msm_vidc_inst_capability *capability; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; s32 adjusted_value, enh_layer_count = -1; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; adjusted_value = ctrl ? ctrl->val : capability->cap[GOP_SIZE].value; if (msm_vidc_get_parent_value(inst, GOP_SIZE, ENH_LAYER_COUNT, &enh_layer_count, __func__)) return -EINVAL; if (!enh_layer_count) goto exit; /* calibrate GOP size */ if (inst->hfi_layer_type == HFI_HIER_P_SLIDING_WINDOW || inst->hfi_layer_type == HFI_HIER_P_HYBRID_LTR) { /* * Layer encoding needs GOP size to be multiple of subgop size * And subgop size is 2 ^ number of enhancement layers. */ u32 min_gop_size; u32 num_subgops; /* v4l2 layer count is the number of enhancement layers */ min_gop_size = 1 << enh_layer_count; num_subgops = (adjusted_value + (min_gop_size >> 1)) / min_gop_size; if (num_subgops) adjusted_value = num_subgops * min_gop_size; else adjusted_value = min_gop_size; } exit: msm_vidc_update_cap_value(inst, GOP_SIZE, adjusted_value, __func__); return 0; } int msm_vidc_adjust_b_frame(void *instance, struct v4l2_ctrl *ctrl) { struct msm_vidc_inst_capability *capability; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; s32 adjusted_value, enh_layer_count = -1; const u32 max_bframe_size = 7; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; if (inst->vb2q[OUTPUT_PORT].streaming) return 0; adjusted_value = ctrl ? ctrl->val : capability->cap[B_FRAME].value; if (msm_vidc_get_parent_value(inst, B_FRAME, ENH_LAYER_COUNT, &enh_layer_count, __func__)) return -EINVAL; if (!enh_layer_count || inst->hfi_layer_type != HFI_HIER_B) { adjusted_value = 0; goto exit; } adjusted_value = (2 << enh_layer_count) - 1; /* Allowed Bframe values are 0, 1, 3, 7 */ if (adjusted_value > max_bframe_size) adjusted_value = max_bframe_size; exit: msm_vidc_update_cap_value(inst, B_FRAME, adjusted_value, __func__); return 0; } int msm_vidc_adjust_bitrate(void *instance, struct v4l2_ctrl *ctrl) { int i; struct msm_vidc_inst_capability *capability; s32 adjusted_value; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; s32 rc_type = -1, enh_layer_count = -1; u32 cap_id = 0, cumulative_bitrate = 0; bool layer_bitrate_set = false; u32 layer_br_caps[6] = {L0_BR, L1_BR, L2_BR, L3_BR, L4_BR, L5_BR}; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; adjusted_value = ctrl ? ctrl->val : capability->cap[BIT_RATE].value; /* ignore layer bitrate when total bitrate is set */ if (capability->cap[BIT_RATE].flags & CAP_FLAG_CLIENT_SET) goto exit; if (msm_vidc_get_parent_value(inst, BIT_RATE, ENH_LAYER_COUNT, &enh_layer_count, __func__)) return -EINVAL; if (msm_vidc_get_parent_value(inst, BIT_RATE, BITRATE_MODE, &rc_type, __func__)) return -EINVAL; /* * ENH_LAYER_COUNT cap max is positive only if * layer encoding is enabled for static setting */ if (capability->cap[ENH_LAYER_COUNT].max) { layer_bitrate_set = true; for (i = 0; i <= enh_layer_count; i++) { if (i >= ARRAY_SIZE(layer_br_caps)) break; cap_id = layer_br_caps[i]; if (!(capability->cap[cap_id].flags & CAP_FLAG_CLIENT_SET)) { layer_bitrate_set = false; break; } cumulative_bitrate += capability->cap[cap_id].value; } /* layer bitrate supported only for CBR rc */ if (layer_bitrate_set && (rc_type == HFI_RC_CBR_CFR || rc_type == HFI_RC_CBR_VFR)) { if (cumulative_bitrate > capability->cap[BIT_RATE].max) cumulative_bitrate = capability->cap[BIT_RATE].max; adjusted_value = cumulative_bitrate; i_vpr_h(inst, "%s: update BIT_RATE with cumulative bitrate\n", __func__); } } else { for (i = 0; i < sizeof(layer_br_caps) / sizeof(u32); i++) { if (i >= ARRAY_SIZE(layer_br_caps)) break; cap_id = layer_br_caps[i]; /* * layer bitrate cannot be set * when layer encoding is disabled */ if (capability->cap[cap_id].flags & CAP_FLAG_CLIENT_SET) { i_vpr_e(inst, "%s: invalid layer bitrate set\n", __func__); return -EINVAL; } } } exit: msm_vidc_update_cap_value(inst, BIT_RATE, adjusted_value, __func__); return 0; } int msm_vidc_adjust_peak_bitrate(void *instance, struct v4l2_ctrl *ctrl) { struct msm_vidc_inst_capability *capability; s32 adjusted_value; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; s32 rc_type = -1, bitrate = -1; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; adjusted_value = ctrl ? ctrl->val : capability->cap[PEAK_BITRATE].value; if (msm_vidc_get_parent_value(inst, PEAK_BITRATE, BITRATE_MODE, &rc_type, __func__)) return -EINVAL; if (rc_type != HFI_RC_CBR_CFR && rc_type != HFI_RC_CBR_VFR) return 0; if (msm_vidc_get_parent_value(inst, PEAK_BITRATE, BIT_RATE, &bitrate, __func__)) return -EINVAL; /* Peak Bitrate should be larger than or equal to avg bitrate */ if (capability->cap[PEAK_BITRATE].flags & CAP_FLAG_CLIENT_SET) { if (adjusted_value < bitrate) adjusted_value = bitrate; } else { adjusted_value = capability->cap[BIT_RATE].value + (capability->cap[BIT_RATE].value / PERCENT_PEAK_BITRATE_INCREASED); } msm_vidc_update_cap_value(inst, PEAK_BITRATE, adjusted_value, __func__); return 0; } int msm_vidc_adjust_hevc_min_qp(void *instance, struct v4l2_ctrl *ctrl) { int rc = 0; struct msm_vidc_inst_capability *capability; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; if (ctrl) msm_vidc_update_cap_value(inst, MIN_FRAME_QP, ctrl->val, __func__); rc = msm_vidc_adjust_hevc_qp(inst, MIN_FRAME_QP); return rc; } int msm_vidc_adjust_hevc_max_qp(void *instance, struct v4l2_ctrl *ctrl) { int rc = 0; struct msm_vidc_inst_capability *capability; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; if (ctrl) msm_vidc_update_cap_value(inst, MAX_FRAME_QP, ctrl->val, __func__); rc = msm_vidc_adjust_hevc_qp(inst, MAX_FRAME_QP); return rc; } int msm_vidc_adjust_hevc_frame_qp(void *instance, struct v4l2_ctrl *ctrl) { int rc = 0; struct msm_vidc_inst_capability *capability; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; if (ctrl) msm_vidc_update_cap_value(inst, I_FRAME_QP, ctrl->val, __func__); rc = msm_vidc_adjust_hevc_qp(inst, I_FRAME_QP); return rc; } int msm_vidc_adjust_session_priority(void *instance, struct v4l2_ctrl *ctrl) { int rc = 0; int adjusted_value; bool rate_by_client = false; struct msm_vidc_inst_capability *capability; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; adjusted_value = ctrl ? ctrl->val : capability->cap[PRIORITY].value; if (capability->cap[FRAME_RATE].flags & CAP_FLAG_CLIENT_SET || capability->cap[OPERATING_RATE].flags & CAP_FLAG_CLIENT_SET) rate_by_client = true; /* * For RT, check for resource feasability if rate is set by client. * For RT, move to NRT, if rate is not set by client. * For NRT, sessions with rate set by client takes higher order * among NRT sessions. They are constraint RT or low priority RT. */ if (adjusted_value == 0 && rate_by_client) { rc = msm_vidc_check_mbps_supported(inst); if (rc) { d_vpr_e("%s: priority 0 not feasible due to resource\n", __func__); return rc; } } if (adjusted_value == 0 && !rate_by_client) { adjusted_value = 1; inst->priority_level = MSM_VIDC_PRIORITY_LOW; } if (adjusted_value > 0 && rate_by_client) inst->priority_level = MSM_VIDC_PRIORITY_HIGH; msm_vidc_update_cap_value(inst, PRIORITY, adjusted_value, __func__); return rc; } /* * Loop over instance capabilities with CAP_FLAG_ROOT * and call adjust function, where * - adjust current capability value * - update tail of instance children list with capability children * - update instance firmware list with current capability id * Now, loop over child list and call its adjust function */ int msm_vidc_adjust_v4l2_properties(struct msm_vidc_inst *inst) { int rc = 0; int i; struct msm_vidc_inst_cap_entry *curr_node = NULL, *tmp_node = NULL; struct msm_vidc_inst_capability *capability; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; i_vpr_h(inst, "%s()\n", __func__); for (i = 0; i < INST_CAP_MAX; i++) { if (capability->cap[i].flags & CAP_FLAG_ROOT) { rc = msm_vidc_adjust_property(inst, capability->cap[i].cap); if (rc) goto exit; } } /* * children of all root controls are already * added to inst->children list at this point */ list_for_each_entry_safe(curr_node, tmp_node, &inst->children.list, list) { /* * call adjust for each child. Each child adjust * will also update child list at the tail with * its own children list. * Also, if current control id value is updated, * its entry should be added to fw list. */ rc = msm_vidc_adjust_property(inst, curr_node->cap_id); if (rc) goto exit; list_del(&curr_node->list); kfree(curr_node); } exit: return rc; } int msm_vidc_set_header_mode(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; int header_mode, prepend_sps_pps, hdr_metadata; u32 hfi_value = 0; struct msm_vidc_inst_capability *capability; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; header_mode = capability->cap[cap_id].value; prepend_sps_pps = capability->cap[PREPEND_SPSPPS_TO_IDR].value; hdr_metadata = capability->cap[META_SEQ_HDR_NAL].value; /* prioritize PREPEND_SPSPPS_TO_IDR mode over other header modes */ if (prepend_sps_pps) hfi_value = HFI_SEQ_HEADER_PREFIX_WITH_SYNC_FRAME; else if (header_mode == V4L2_MPEG_VIDEO_HEADER_MODE_JOINED_WITH_1ST_FRAME) hfi_value = HFI_SEQ_HEADER_JOINED_WITH_1ST_FRAME; else hfi_value = HFI_SEQ_HEADER_SEPERATE_FRAME; if (hdr_metadata) hfi_value |= HFI_SEQ_HEADER_METADATA; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_U32_ENUM, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_deblock_mode(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *) instance; s32 alpha = 0, beta = 0; u32 lf_mode, hfi_value = 0, lf_offset = 6; struct msm_vidc_inst_capability *capability; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; rc = msm_vidc_v4l2_to_hfi_enum(inst, LF_MODE, &lf_mode); if (rc) return -EINVAL; beta = inst->capabilities->cap[LF_BETA].value + lf_offset; alpha = inst->capabilities->cap[LF_ALPHA].value + lf_offset; hfi_value = (alpha << 16) | (beta << 8) | lf_mode; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_32_PACKED, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_constant_quality(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; u32 hfi_value = 0; s32 rc_type = -1; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } if (msm_vidc_get_parent_value(inst, cap_id, BITRATE_MODE, &rc_type, __func__)) return -EINVAL; if (rc_type != HFI_RC_CQ) return 0; hfi_value = inst->capabilities->cap[cap_id].value; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_U32, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_vbr_related_properties(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; u32 hfi_value = 0; s32 rc_type = -1; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } if (msm_vidc_get_parent_value(inst, cap_id, BITRATE_MODE, &rc_type, __func__)) return -EINVAL; if (rc_type != HFI_RC_VBR_CFR) return 0; hfi_value = inst->capabilities->cap[cap_id].value; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_U32, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_cbr_related_properties(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; u32 hfi_value = 0; s32 rc_type = -1; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } if (msm_vidc_get_parent_value(inst, cap_id, BITRATE_MODE, &rc_type, __func__)) return -EINVAL; if (rc_type != HFI_RC_CBR_VFR && rc_type != HFI_RC_CBR_CFR) return 0; hfi_value = inst->capabilities->cap[cap_id].value; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_U32, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_use_and_mark_ltr(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; u32 hfi_value = 0; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } if (!inst->capabilities->cap[LTR_COUNT].value) { i_vpr_h(inst, "%s: ltr count is 0, cap %s is not set\n", __func__, cap_name(cap_id)); return 0; } hfi_value = inst->capabilities->cap[cap_id].value; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_U32, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_min_qp(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; struct msm_vidc_inst_capability *capability; s32 i_frame_qp = 0, p_frame_qp = 0, b_frame_qp = 0, min_qp_enable = 0; u32 i_qp_enable = 0, p_qp_enable = 0, b_qp_enable = 0; u32 client_qp_enable = 0, hfi_value = 0, offset = 0; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; min_qp_enable = capability->cap[MIN_FRAME_QP].flags & CAP_FLAG_CLIENT_SET; i_qp_enable = min_qp_enable || capability->cap[I_FRAME_MIN_QP].flags & CAP_FLAG_CLIENT_SET; p_qp_enable = min_qp_enable || capability->cap[P_FRAME_MIN_QP].flags & CAP_FLAG_CLIENT_SET; b_qp_enable = min_qp_enable || capability->cap[B_FRAME_MIN_QP].flags & CAP_FLAG_CLIENT_SET; client_qp_enable = i_qp_enable | p_qp_enable << 1 | b_qp_enable << 2; if (!client_qp_enable) { i_vpr_h(inst, "%s: client did not set min qp, cap %s is not set\n", __func__, cap_name(cap_id)); return 0; } if (is_10bit_colorformat(capability->cap[PIX_FMTS].value)) offset = 12; /* * I_FRAME_MIN_QP, P_FRAME_MIN_QP, B_FRAME_MIN_QP, * MIN_FRAME_QP caps have default value as MIN_QP_10BIT values. * Hence, if client sets either one among MIN_FRAME_QP * and (I_FRAME_MIN_QP or P_FRAME_MIN_QP or B_FRAME_MIN_QP), * max of both caps will result into client set value. */ i_frame_qp = max(capability->cap[I_FRAME_MIN_QP].value, capability->cap[MIN_FRAME_QP].value) + offset; p_frame_qp = max(capability->cap[P_FRAME_MIN_QP].value, capability->cap[MIN_FRAME_QP].value) + offset; b_frame_qp = max(capability->cap[B_FRAME_MIN_QP].value, capability->cap[MIN_FRAME_QP].value) + offset; hfi_value = i_frame_qp | p_frame_qp << 8 | b_frame_qp << 16 | client_qp_enable << 24; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_32_PACKED, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_max_qp(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; struct msm_vidc_inst_capability *capability; s32 i_frame_qp = 0, p_frame_qp = 0, b_frame_qp = 0, max_qp_enable = 0; u32 i_qp_enable = 0, p_qp_enable = 0, b_qp_enable = 0; u32 client_qp_enable = 0, hfi_value = 0, offset = 0; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capability = inst->capabilities; max_qp_enable = capability->cap[MAX_FRAME_QP].flags & CAP_FLAG_CLIENT_SET; i_qp_enable = max_qp_enable || capability->cap[I_FRAME_MAX_QP].flags & CAP_FLAG_CLIENT_SET; p_qp_enable = max_qp_enable || capability->cap[P_FRAME_MAX_QP].flags & CAP_FLAG_CLIENT_SET; b_qp_enable = max_qp_enable || capability->cap[B_FRAME_MAX_QP].flags & CAP_FLAG_CLIENT_SET; client_qp_enable = i_qp_enable | p_qp_enable << 1 | b_qp_enable << 2; if (!client_qp_enable) { i_vpr_h(inst, "%s: client did not set max qp, cap %s is not set\n", __func__, cap_name(cap_id)); return 0; } if (is_10bit_colorformat(capability->cap[PIX_FMTS].value)) offset = 12; /* * I_FRAME_MAX_QP, P_FRAME_MAX_QP, B_FRAME_MAX_QP, * MAX_FRAME_QP caps have default value as MAX_QP values. * Hence, if client sets either one among MAX_FRAME_QP * and (I_FRAME_MAX_QP or P_FRAME_MAX_QP or B_FRAME_MAX_QP), * min of both caps will result into client set value. */ i_frame_qp = min(capability->cap[I_FRAME_MAX_QP].value, capability->cap[MAX_FRAME_QP].value) + offset; p_frame_qp = min(capability->cap[P_FRAME_MAX_QP].value, capability->cap[MAX_FRAME_QP].value) + offset; b_frame_qp = min(capability->cap[B_FRAME_MAX_QP].value, capability->cap[MAX_FRAME_QP].value) + offset; hfi_value = i_frame_qp | p_frame_qp << 8 | b_frame_qp << 16 | client_qp_enable << 24; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_32_PACKED, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_frame_qp(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; struct msm_vidc_inst_capability *capab; s32 i_frame_qp = 0, p_frame_qp = 0, b_frame_qp = 0; u32 i_qp_enable = 0, p_qp_enable = 0, b_qp_enable = 0; u32 client_qp_enable = 0, hfi_value = 0, offset = 0; s32 rc_type = -1; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } capab = inst->capabilities; if (msm_vidc_get_parent_value(inst, I_FRAME_QP, BITRATE_MODE, &rc_type, __func__)) return -EINVAL; if (rc_type == HFI_RC_OFF) { /* Mandatorily set for rc off case */ i_qp_enable = p_qp_enable = b_qp_enable = 1; } else { /* Set only if client has set for NON rc off case */ i_qp_enable = capab->cap[I_FRAME_QP].flags & CAP_FLAG_CLIENT_SET; p_qp_enable = capab->cap[P_FRAME_QP].flags & CAP_FLAG_CLIENT_SET; b_qp_enable = capab->cap[B_FRAME_QP].flags & CAP_FLAG_CLIENT_SET; } client_qp_enable = i_qp_enable | p_qp_enable << 1 | b_qp_enable << 2; if (!client_qp_enable) { i_vpr_h(inst, "%s: client did not set frame qp, cap %s is not set\n", __func__, cap_name(cap_id)); return 0; } if (is_10bit_colorformat(capab->cap[PIX_FMTS].value)) offset = 12; i_frame_qp = capab->cap[I_FRAME_QP].value + offset; p_frame_qp = capab->cap[P_FRAME_QP].value + offset; b_frame_qp = capab->cap[B_FRAME_QP].value + offset; hfi_value = i_frame_qp | p_frame_qp << 8 | b_frame_qp << 16 | client_qp_enable << 24; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_32_PACKED, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_req_sync_frame(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; s32 prepend_spspps; u32 hfi_value = 0; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } prepend_spspps = inst->capabilities->cap[PREPEND_SPSPPS_TO_IDR].value; if (prepend_spspps) hfi_value = HFI_SYNC_FRAME_REQUEST_WITH_PREFIX_SEQ_HDR; else hfi_value = HFI_SYNC_FRAME_REQUEST_WITHOUT_SEQ_HDR; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_U32_ENUM, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_chroma_qp_index_offset(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; u32 hfi_value = 0, chroma_qp_offset_mode = 0, chroma_qp = 0; u32 offset = 12; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } if (inst->capabilities->cap[cap_id].flags & CAP_FLAG_CLIENT_SET) chroma_qp_offset_mode = HFI_FIXED_CHROMAQP_OFFSET; else chroma_qp_offset_mode = HFI_ADAPTIVE_CHROMAQP_OFFSET; chroma_qp = inst->capabilities->cap[cap_id].value + offset; hfi_value = chroma_qp_offset_mode | chroma_qp << 8 | chroma_qp << 16 ; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_32_PACKED, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_slice_count(void* instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst* inst = (struct msm_vidc_inst*)instance; s32 slice_mode = -1; u32 hfi_value = 0, set_cap_id = 0; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } slice_mode = inst->capabilities->cap[SLICE_MODE].value; if (slice_mode == V4L2_MPEG_VIDEO_MULTI_SLICE_MODE_SINGLE) { i_vpr_h(inst, "%s: slice mode is: %u, ignore setting to fw\n", __func__, slice_mode); return 0; } if (slice_mode == V4L2_MPEG_VIDEO_MULTI_SLICE_MODE_MAX_MB) { hfi_value = inst->capabilities->cap[SLICE_MAX_MB].value; set_cap_id = SLICE_MAX_MB; } else if (slice_mode == V4L2_MPEG_VIDEO_MULTI_SLICE_MODE_MAX_BYTES) { hfi_value = inst->capabilities->cap[SLICE_MAX_BYTES].value; set_cap_id = SLICE_MAX_BYTES; } rc = msm_vidc_packetize_control(inst, set_cap_id, HFI_PAYLOAD_U32, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_nal_length(void* instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; u32 hfi_value = HFI_NAL_LENGTH_STARTCODES; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } if (!inst->capabilities->cap[WITHOUT_STARTCODE].value) { hfi_value = HFI_NAL_LENGTH_STARTCODES; } else { rc = msm_vidc_v4l2_to_hfi_enum(inst, NAL_LENGTH_FIELD, &hfi_value); if (rc) return -EINVAL; } rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_U32_ENUM, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_layer_count_and_type(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; u32 hfi_layer_count, hfi_layer_type = 0; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } if (!inst->vb2q[OUTPUT_PORT].streaming) { /* set layer type */ hfi_layer_type = inst->hfi_layer_type; cap_id = LAYER_TYPE; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_U32_ENUM, &hfi_layer_type, sizeof(u32), __func__); if (rc) goto exit; } else { if (inst->hfi_layer_type == HFI_HIER_B) { i_vpr_l(inst, "%s: HB dyn layers change is not supported\n", __func__); return 0; } } /* set layer count */ cap_id = ENH_LAYER_COUNT; /* hfi baselayer starts from 1 */ hfi_layer_count = inst->capabilities->cap[ENH_LAYER_COUNT].value + 1; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_U32, &hfi_layer_count, sizeof(u32), __func__); if (rc) goto exit; exit: return rc; } int msm_vidc_set_gop_size(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; u32 hfi_value; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } if (inst->vb2q[OUTPUT_PORT].streaming) { if (inst->hfi_layer_type == HFI_HIER_B) { i_vpr_l(inst, "%s: HB dyn GOP setting is not supported\n", __func__); return 0; } } hfi_value = inst->capabilities->cap[GOP_SIZE].value; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_U32, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_bitrate(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0, i; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; u32 hfi_value = 0; s32 rc_type = -1, enh_layer_count = -1; u32 layer_br_caps[6] = {L0_BR, L1_BR, L2_BR, L3_BR, L4_BR, L5_BR}; bool layer_bitrate_set = false; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } /* set Total Bitrate */ if (inst->capabilities->cap[BIT_RATE].flags & CAP_FLAG_CLIENT_SET) goto set_total_bitrate; if (msm_vidc_get_parent_value(inst, BIT_RATE, ENH_LAYER_COUNT, &enh_layer_count, __func__)) return -EINVAL; if (msm_vidc_get_parent_value(inst, BIT_RATE, BITRATE_MODE, &rc_type, __func__)) return -EINVAL; if (inst->capabilities->cap[ENH_LAYER_COUNT].max && (rc_type == HFI_RC_CBR_CFR || rc_type == HFI_RC_CBR_VFR)) { layer_bitrate_set = true; for (i = 0; i <= enh_layer_count; i++) { if (i >= ARRAY_SIZE(layer_br_caps)) break; cap_id = layer_br_caps[i]; if (!(inst->capabilities->cap[cap_id].flags & CAP_FLAG_CLIENT_SET)) { layer_bitrate_set = false; break; } } if (layer_bitrate_set) { /* set Layer Bitrate */ for (i = 0; i <= enh_layer_count; i++) { if (i >= ARRAY_SIZE(layer_br_caps)) break; cap_id = layer_br_caps[i]; hfi_value = inst->capabilities->cap[cap_id].value; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_U32, &hfi_value, sizeof(u32), __func__); if (rc) return rc; } goto exit; } } set_total_bitrate: hfi_value = inst->capabilities->cap[BIT_RATE].value; rc = msm_vidc_packetize_control(inst, BIT_RATE, HFI_PAYLOAD_U32, &hfi_value, sizeof(u32), __func__); if (rc) return rc; exit: return rc; } int msm_vidc_set_session_priority(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; u32 hfi_value = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } hfi_value = (inst->capabilities->cap[cap_id].value * 2) + inst->priority_level; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_U32, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } /* TODO int msm_vidc_set_flip(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; u32 hflip, vflip, hfi_value = HFI_DISABLE_FLIP; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } hflip = inst->capabilities->cap[HFLIP].value; vflip = inst->capabilities->cap[VFLIP].value; if (hflip) hfi_value |= HFI_HORIZONTAL_FLIP; if (vflip) hfi_value |= HFI_VERTICAL_FLIP; i_vpr_h(inst, "set cap: name: %24s, value: %#10x, hfi: %#10x\n", cap_name(cap_id), inst->capabilities->cap[cap_id].value, hfi_value); rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_U32_ENUM, &hfi_value, sizeof(u32), __func__); return rc; } */ int msm_vidc_set_q16(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; u32 hfi_value = 0; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } hfi_value = inst->capabilities->cap[cap_id].value; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_Q16, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_u32(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; u32 hfi_value; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } if (inst->capabilities->cap[cap_id].flags & CAP_FLAG_MENU) { rc = msm_vidc_v4l2_menu_to_hfi(inst, cap_id, &hfi_value); if (rc) return -EINVAL; } else { hfi_value = inst->capabilities->cap[cap_id].value; } rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_U32, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_u32_enum(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; u32 hfi_value; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } rc = msm_vidc_v4l2_to_hfi_enum(inst, cap_id, &hfi_value); if (rc) return -EINVAL; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_U32_ENUM, &hfi_value, sizeof(u32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_s32(void *instance, enum msm_vidc_inst_capability_type cap_id) { int rc = 0; struct msm_vidc_inst *inst = (struct msm_vidc_inst *)instance; s32 hfi_value = 0; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } hfi_value = inst->capabilities->cap[cap_id].value; rc = msm_vidc_packetize_control(inst, cap_id, HFI_PAYLOAD_S32, &hfi_value, sizeof(s32), __func__); if (rc) return rc; return rc; } int msm_vidc_set_v4l2_properties(struct msm_vidc_inst *inst) { int rc = 0; struct msm_vidc_inst_capability *capability; struct msm_vidc_inst_cap_entry *curr_node = NULL, *tmp_node = NULL; if (!inst || !inst->capabilities) { d_vpr_e("%s: invalid params\n", __func__); return -EINVAL; } i_vpr_h(inst, "%s()\n", __func__); capability = inst->capabilities; list_for_each_entry_safe(curr_node, tmp_node, &inst->firmware.list, list) { /* cap_id's like PIX_FMT etc may not have set functions */ if (!capability->cap[curr_node->cap_id].set) continue; rc = capability->cap[curr_node->cap_id].set(inst, curr_node->cap_id); if (rc) goto exit; list_del(&curr_node->list); kfree(curr_node); } exit: return rc; } int msm_vidc_v4l2_menu_to_hfi(struct msm_vidc_inst *inst, enum msm_vidc_inst_capability_type cap_id, u32 *value) { struct msm_vidc_inst_capability *capability = inst->capabilities; switch (capability->cap[cap_id].v4l2_id) { case V4L2_CID_MPEG_VIDEO_H264_ENTROPY_MODE: switch (capability->cap[cap_id].value) { case V4L2_MPEG_VIDEO_H264_ENTROPY_MODE_CABAC: *value = 1; break; case V4L2_MPEG_VIDEO_H264_ENTROPY_MODE_CAVLC: *value = 0; break; default: *value = 1; goto set_default; } return 0; default: i_vpr_e(inst, "%s: mapping not specified for ctrl_id: %#x\n", __func__, capability->cap[cap_id].v4l2_id); return -EINVAL; } set_default: i_vpr_e(inst, "%s: invalid value %d for ctrl id: %#x. Set default: %u\n", __func__, capability->cap[cap_id].value, capability->cap[cap_id].v4l2_id, *value); return 0; } int msm_vidc_v4l2_to_hfi_enum(struct msm_vidc_inst *inst, enum msm_vidc_inst_capability_type cap_id, u32 *value) { struct msm_vidc_inst_capability *capability = inst->capabilities; switch (capability->cap[cap_id].v4l2_id) { case V4L2_CID_MPEG_VIDEO_BITRATE_MODE: *value = inst->hfi_rc_type; return 0; case V4L2_CID_MPEG_VIDEO_HEVC_PROFILE: case V4L2_CID_MPEG_VIDEO_H264_PROFILE: case V4L2_CID_MPEG_VIDEO_VP9_PROFILE: case V4L2_CID_MPEG_VIDEO_HEVC_LEVEL: case V4L2_CID_MPEG_VIDEO_H264_LEVEL: case V4L2_CID_MPEG_VIDEO_HEVC_TIER: case V4L2_CID_MPEG_VIDC_VIDEO_BLUR_TYPES: *value = capability->cap[cap_id].value; return 0; case V4L2_CID_MPEG_VIDEO_HEVC_HIER_CODING_TYPE: switch (capability->cap[cap_id].value) { case V4L2_MPEG_VIDEO_HEVC_HIERARCHICAL_CODING_B: *value = HFI_HIER_B; break; case V4L2_MPEG_VIDEO_HEVC_HIERARCHICAL_CODING_P: //TODO (AS): check if this is right mapping *value = HFI_HIER_P_SLIDING_WINDOW; break; default: *value = HFI_HIER_P_SLIDING_WINDOW; goto set_default; } return 0; case V4L2_CID_ROTATE: switch (capability->cap[cap_id].value) { case 0: *value = HFI_ROTATION_NONE; break; case 90: *value = HFI_ROTATION_90; break; case 180: *value = HFI_ROTATION_180; break; case 270: *value = HFI_ROTATION_270; break; default: *value = HFI_ROTATION_NONE; goto set_default; } return 0; case V4L2_CID_MPEG_VIDEO_HEVC_LOOP_FILTER_MODE: switch (capability->cap[cap_id].value) { case V4L2_MPEG_VIDEO_HEVC_LOOP_FILTER_MODE_ENABLED: *value = HFI_DEBLOCK_ALL_BOUNDARY; break; case V4L2_MPEG_VIDEO_HEVC_LOOP_FILTER_MODE_DISABLED: *value = HFI_DEBLOCK_DISABLE; break; case DB_HEVC_DISABLE_SLICE_BOUNDARY: *value = HFI_DEBLOCK_DISABLE_AT_SLICE_BOUNDARY; break; default: *value = HFI_DEBLOCK_ALL_BOUNDARY; goto set_default; } return 0; case V4L2_CID_MPEG_VIDEO_H264_LOOP_FILTER_MODE: switch (capability->cap[cap_id].value) { case V4L2_MPEG_VIDEO_H264_LOOP_FILTER_MODE_ENABLED: *value = HFI_DEBLOCK_ALL_BOUNDARY; break; case V4L2_MPEG_VIDEO_H264_LOOP_FILTER_MODE_DISABLED: *value = HFI_DEBLOCK_DISABLE; break; case DB_H264_DISABLE_SLICE_BOUNDARY: *value = HFI_DEBLOCK_DISABLE_AT_SLICE_BOUNDARY; break; default: *value = HFI_DEBLOCK_ALL_BOUNDARY; goto set_default; } return 0; case V4L2_CID_MPEG_VIDEO_HEVC_SIZE_OF_LENGTH_FIELD: switch (capability->cap[cap_id].value) { case V4L2_MPEG_VIDEO_HEVC_SIZE_4: *value = HFI_NAL_LENGTH_SIZE_4; break; default: *value = HFI_NAL_LENGTH_STARTCODES; goto set_default; } return 0; default: i_vpr_e(inst, "%s: mapping not specified for ctrl_id: %#x\n", __func__, capability->cap[cap_id].v4l2_id); return -EINVAL; } set_default: i_vpr_e(inst, "%s: invalid value %d for ctrl id: %#x. Set default: %u\n", __func__, capability->cap[cap_id].value, capability->cap[cap_id].v4l2_id, *value); return 0; }