/* Copyright (c) 2012-2015, 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 "hfi_packetization.h" #include "msm_vidc_debug.h" /* Set up look-up tables to convert HAL_* to HFI_*. * * The tables below mostly take advantage of the fact that most * HAL_* types are defined bitwise. So if we index them normally * when declaring the tables, we end up with huge arrays with wasted * space. So before indexing them, we apply log2 to use a more * sensible index. */ static int profile_table[] = { [ilog2(HAL_H264_PROFILE_BASELINE)] = HFI_H264_PROFILE_BASELINE, [ilog2(HAL_H264_PROFILE_MAIN)] = HFI_H264_PROFILE_MAIN, [ilog2(HAL_H264_PROFILE_HIGH)] = HFI_H264_PROFILE_HIGH, [ilog2(HAL_H264_PROFILE_CONSTRAINED_BASE)] = HFI_H264_PROFILE_CONSTRAINED_BASE, [ilog2(HAL_H264_PROFILE_CONSTRAINED_HIGH)] = HFI_H264_PROFILE_CONSTRAINED_HIGH, [ilog2(HAL_VPX_PROFILE_VERSION_1)] = HFI_VPX_PROFILE_VERSION_1, [ilog2(HAL_MVC_PROFILE_STEREO_HIGH)] = HFI_H264_PROFILE_STEREO_HIGH, }; static int entropy_mode[] = { [ilog2(HAL_H264_ENTROPY_CAVLC)] = HFI_H264_ENTROPY_CAVLC, [ilog2(HAL_H264_ENTROPY_CABAC)] = HFI_H264_ENTROPY_CABAC, }; static int cabac_model[] = { [ilog2(HAL_H264_CABAC_MODEL_0)] = HFI_H264_CABAC_MODEL_0, [ilog2(HAL_H264_CABAC_MODEL_1)] = HFI_H264_CABAC_MODEL_1, [ilog2(HAL_H264_CABAC_MODEL_2)] = HFI_H264_CABAC_MODEL_2, }; static int statistics_mode[] = { [ilog2(HAL_STATISTICS_MODE_DEFAULT)] = HFI_STATISTICS_MODE_DEFAULT, [ilog2(HAL_STATISTICS_MODE_1)] = HFI_STATISTICS_MODE_1, [ilog2(HAL_STATISTICS_MODE_2)] = HFI_STATISTICS_MODE_2, [ilog2(HAL_STATISTICS_MODE_3)] = HFI_STATISTICS_MODE_3, }; static int color_format[] = { [ilog2(HAL_COLOR_FORMAT_MONOCHROME)] = HFI_COLOR_FORMAT_MONOCHROME, [ilog2(HAL_COLOR_FORMAT_NV12)] = HFI_COLOR_FORMAT_NV12, [ilog2(HAL_COLOR_FORMAT_NV21)] = HFI_COLOR_FORMAT_NV21, [ilog2(HAL_COLOR_FORMAT_NV12_4x4TILE)] = HFI_COLOR_FORMAT_NV12_4x4TILE, [ilog2(HAL_COLOR_FORMAT_NV21_4x4TILE)] = HFI_COLOR_FORMAT_NV21_4x4TILE, [ilog2(HAL_COLOR_FORMAT_YUYV)] = HFI_COLOR_FORMAT_YUYV, [ilog2(HAL_COLOR_FORMAT_YVYU)] = HFI_COLOR_FORMAT_YVYU, [ilog2(HAL_COLOR_FORMAT_UYVY)] = HFI_COLOR_FORMAT_UYVY, [ilog2(HAL_COLOR_FORMAT_VYUY)] = HFI_COLOR_FORMAT_VYUY, [ilog2(HAL_COLOR_FORMAT_RGB565)] = HFI_COLOR_FORMAT_RGB565, [ilog2(HAL_COLOR_FORMAT_BGR565)] = HFI_COLOR_FORMAT_BGR565, [ilog2(HAL_COLOR_FORMAT_RGB888)] = HFI_COLOR_FORMAT_RGB888, [ilog2(HAL_COLOR_FORMAT_BGR888)] = HFI_COLOR_FORMAT_BGR888, [ilog2(HAL_COLOR_FORMAT_RGBA8888)] = HFI_COLOR_FORMAT_RGBA8888, /* UBWC Color formats*/ [ilog2(HAL_COLOR_FORMAT_NV12_UBWC)] = HFI_COLOR_FORMAT_NV12_UBWC, [ilog2(HAL_COLOR_FORMAT_NV12_TP10_UBWC)] = HFI_COLOR_FORMAT_YUV420_TP10_UBWC, [ilog2(HAL_COLOR_FORMAT_RGBA8888_UBWC)] = HFI_COLOR_FORMAT_RGBA8888_UBWC, }; static int nal_type[] = { [ilog2(HAL_NAL_FORMAT_STARTCODES)] = HFI_NAL_FORMAT_STARTCODES, [ilog2(HAL_NAL_FORMAT_ONE_NAL_PER_BUFFER)] = HFI_NAL_FORMAT_ONE_NAL_PER_BUFFER, [ilog2(HAL_NAL_FORMAT_ONE_BYTE_LENGTH)] = HFI_NAL_FORMAT_ONE_BYTE_LENGTH, [ilog2(HAL_NAL_FORMAT_TWO_BYTE_LENGTH)] = HFI_NAL_FORMAT_TWO_BYTE_LENGTH, [ilog2(HAL_NAL_FORMAT_FOUR_BYTE_LENGTH)] = HFI_NAL_FORMAT_FOUR_BYTE_LENGTH, }; static inline int hal_to_hfi_type(int property, int hal_type) { if (hal_type && roundup_pow_of_two(hal_type) != hal_type) { /* Not a power of 2, it's not going * to be in any of the tables anyway */ return -EINVAL; } if (hal_type) hal_type = ilog2(hal_type); switch (property) { case HAL_PARAM_PROFILE_LEVEL_CURRENT: return (hal_type >= ARRAY_SIZE(profile_table)) ? -ENOTSUPP : profile_table[hal_type]; case HAL_PARAM_VENC_H264_ENTROPY_CONTROL: return (hal_type >= ARRAY_SIZE(entropy_mode)) ? -ENOTSUPP : entropy_mode[hal_type]; case HAL_PARAM_VENC_H264_ENTROPY_CABAC_MODEL: return (hal_type >= ARRAY_SIZE(cabac_model)) ? -ENOTSUPP : cabac_model[hal_type]; case HAL_PARAM_UNCOMPRESSED_FORMAT_SELECT: return (hal_type >= ARRAY_SIZE(color_format)) ? -ENOTSUPP : color_format[hal_type]; case HAL_PARAM_NAL_STREAM_FORMAT_SELECT: return (hal_type >= ARRAY_SIZE(nal_type)) ? -ENOTSUPP : nal_type[hal_type]; case HAL_PARAM_VENC_MBI_STATISTICS_MODE: return (hal_type >= ARRAY_SIZE(statistics_mode)) ? -ENOTSUPP : statistics_mode[hal_type]; default: return -ENOTSUPP; } } u32 get_hfi_layout(enum hal_buffer_layout_type hal_buf_layout) { u32 hfi_layout; switch (hal_buf_layout) { case HAL_BUFFER_LAYOUT_TOP_BOTTOM: hfi_layout = HFI_MVC_BUFFER_LAYOUT_TOP_BOTTOM; break; case HAL_BUFFER_LAYOUT_SEQ: hfi_layout = HFI_MVC_BUFFER_LAYOUT_SEQ; break; default: dprintk(VIDC_ERR, "Invalid buffer layout: %#x\n", hal_buf_layout); hfi_layout = HFI_MVC_BUFFER_LAYOUT_SEQ; break; } return hfi_layout; } enum hal_domain vidc_get_hal_domain(u32 hfi_domain) { enum hal_domain hal_domain = 0; switch (hfi_domain) { case HFI_VIDEO_DOMAIN_VPE: hal_domain = HAL_VIDEO_DOMAIN_VPE; break; case HFI_VIDEO_DOMAIN_ENCODER: hal_domain = HAL_VIDEO_DOMAIN_ENCODER; break; case HFI_VIDEO_DOMAIN_DECODER: hal_domain = HAL_VIDEO_DOMAIN_DECODER; break; default: dprintk(VIDC_ERR, "%s: invalid domain %x\n", __func__, hfi_domain); hal_domain = 0; break; } return hal_domain; } enum hal_video_codec vidc_get_hal_codec(u32 hfi_codec) { enum hal_video_codec hal_codec = 0; switch (hfi_codec) { case HFI_VIDEO_CODEC_H264: hal_codec = HAL_VIDEO_CODEC_H264; break; case HFI_VIDEO_CODEC_H263: hal_codec = HAL_VIDEO_CODEC_H263; break; case HFI_VIDEO_CODEC_MPEG1: hal_codec = HAL_VIDEO_CODEC_MPEG1; break; case HFI_VIDEO_CODEC_MPEG2: hal_codec = HAL_VIDEO_CODEC_MPEG2; break; case HFI_VIDEO_CODEC_MPEG4: hal_codec = HAL_VIDEO_CODEC_MPEG4; break; case HFI_VIDEO_CODEC_DIVX_311: hal_codec = HAL_VIDEO_CODEC_DIVX_311; break; case HFI_VIDEO_CODEC_DIVX: hal_codec = HAL_VIDEO_CODEC_DIVX; break; case HFI_VIDEO_CODEC_VC1: hal_codec = HAL_VIDEO_CODEC_VC1; break; case HFI_VIDEO_CODEC_SPARK: hal_codec = HAL_VIDEO_CODEC_SPARK; break; case HFI_VIDEO_CODEC_VP8: hal_codec = HAL_VIDEO_CODEC_VP8; break; case HFI_VIDEO_CODEC_HEVC: hal_codec = HAL_VIDEO_CODEC_HEVC; break; case HFI_VIDEO_CODEC_VP9: hal_codec = HAL_VIDEO_CODEC_VP9; break; case HFI_VIDEO_CODEC_HEVC_HYBRID: hal_codec = HAL_VIDEO_CODEC_HEVC_HYBRID; break; default: dprintk(VIDC_INFO, "%s: invalid codec 0x%x\n", __func__, hfi_codec); hal_codec = 0; break; } return hal_codec; } u32 vidc_get_hfi_domain(enum hal_domain hal_domain) { u32 hfi_domain; switch (hal_domain) { case HAL_VIDEO_DOMAIN_VPE: hfi_domain = HFI_VIDEO_DOMAIN_VPE; break; case HAL_VIDEO_DOMAIN_ENCODER: hfi_domain = HFI_VIDEO_DOMAIN_ENCODER; break; case HAL_VIDEO_DOMAIN_DECODER: hfi_domain = HFI_VIDEO_DOMAIN_DECODER; break; default: dprintk(VIDC_ERR, "%s: invalid domain 0x%x\n", __func__, hal_domain); hfi_domain = 0; break; } return hfi_domain; } u32 vidc_get_hfi_codec(enum hal_video_codec hal_codec) { u32 hfi_codec = 0; switch (hal_codec) { case HAL_VIDEO_CODEC_MVC: case HAL_VIDEO_CODEC_H264: hfi_codec = HFI_VIDEO_CODEC_H264; break; case HAL_VIDEO_CODEC_H263: hfi_codec = HFI_VIDEO_CODEC_H263; break; case HAL_VIDEO_CODEC_MPEG1: hfi_codec = HFI_VIDEO_CODEC_MPEG1; break; case HAL_VIDEO_CODEC_MPEG2: hfi_codec = HFI_VIDEO_CODEC_MPEG2; break; case HAL_VIDEO_CODEC_MPEG4: hfi_codec = HFI_VIDEO_CODEC_MPEG4; break; case HAL_VIDEO_CODEC_DIVX_311: hfi_codec = HFI_VIDEO_CODEC_DIVX_311; break; case HAL_VIDEO_CODEC_DIVX: hfi_codec = HFI_VIDEO_CODEC_DIVX; break; case HAL_VIDEO_CODEC_VC1: hfi_codec = HFI_VIDEO_CODEC_VC1; break; case HAL_VIDEO_CODEC_SPARK: hfi_codec = HFI_VIDEO_CODEC_SPARK; break; case HAL_VIDEO_CODEC_VP8: hfi_codec = HFI_VIDEO_CODEC_VP8; break; case HAL_VIDEO_CODEC_HEVC: hfi_codec = HFI_VIDEO_CODEC_HEVC; break; case HAL_VIDEO_CODEC_VP9: hfi_codec = HFI_VIDEO_CODEC_VP9; break; case HAL_VIDEO_CODEC_HEVC_HYBRID: hfi_codec = HFI_VIDEO_CODEC_HEVC_HYBRID; break; default: dprintk(VIDC_INFO, "%s: invalid codec 0x%x\n", __func__, hal_codec); hfi_codec = 0; break; } return hfi_codec; } static void create_pkt_enable(void *pkt, u32 type, bool enable) { u32 *pkt_header = pkt; u32 *pkt_type = &pkt_header[0]; struct hfi_enable *hfi_enable = (struct hfi_enable *)&pkt_header[1]; *pkt_type = type; hfi_enable->enable = enable; } int create_pkt_cmd_sys_init(struct hfi_cmd_sys_init_packet *pkt, u32 arch_type) { int rc = 0; if (!pkt) return -EINVAL; pkt->packet_type = HFI_CMD_SYS_INIT; pkt->size = sizeof(struct hfi_cmd_sys_init_packet); pkt->arch_type = arch_type; return rc; } int create_pkt_cmd_sys_pc_prep(struct hfi_cmd_sys_pc_prep_packet *pkt) { int rc = 0; if (!pkt) return -EINVAL; pkt->packet_type = HFI_CMD_SYS_PC_PREP; pkt->size = sizeof(struct hfi_cmd_sys_pc_prep_packet); return rc; } int create_pkt_cmd_sys_idle_indicator( struct hfi_cmd_sys_set_property_packet *pkt, u32 enable) { struct hfi_enable *hfi; if (!pkt) return -EINVAL; pkt->size = sizeof(struct hfi_cmd_sys_set_property_packet) + sizeof(struct hfi_enable) + sizeof(u32); pkt->packet_type = HFI_CMD_SYS_SET_PROPERTY; pkt->num_properties = 1; pkt->rg_property_data[0] = HFI_PROPERTY_SYS_IDLE_INDICATOR; hfi = (struct hfi_enable *) &pkt->rg_property_data[1]; hfi->enable = enable; return 0; } int create_pkt_cmd_sys_debug_config( struct hfi_cmd_sys_set_property_packet *pkt, u32 mode) { struct hfi_debug_config *hfi; if (!pkt) return -EINVAL; pkt->size = sizeof(struct hfi_cmd_sys_set_property_packet) + sizeof(struct hfi_debug_config) + sizeof(u32); pkt->packet_type = HFI_CMD_SYS_SET_PROPERTY; pkt->num_properties = 1; pkt->rg_property_data[0] = HFI_PROPERTY_SYS_DEBUG_CONFIG; hfi = (struct hfi_debug_config *) &pkt->rg_property_data[1]; hfi->debug_config = mode; hfi->debug_mode = HFI_DEBUG_MODE_QUEUE; if (msm_vidc_fw_debug_mode <= (HFI_DEBUG_MODE_QUEUE | HFI_DEBUG_MODE_QDSS)) hfi->debug_mode = msm_vidc_fw_debug_mode; return 0; } int create_pkt_cmd_sys_coverage_config( struct hfi_cmd_sys_set_property_packet *pkt, u32 mode) { if (!pkt) { dprintk(VIDC_ERR, "In %s(), No input packet\n", __func__); return -EINVAL; } pkt->size = sizeof(struct hfi_cmd_sys_set_property_packet) + sizeof(u32); pkt->packet_type = HFI_CMD_SYS_SET_PROPERTY; pkt->num_properties = 1; pkt->rg_property_data[0] = HFI_PROPERTY_SYS_CONFIG_COVERAGE; pkt->rg_property_data[1] = mode; dprintk(VIDC_DBG, "Firmware coverage mode %d\n", pkt->rg_property_data[1]); return 0; } int create_pkt_cmd_sys_set_resource( struct hfi_cmd_sys_set_resource_packet *pkt, struct vidc_resource_hdr *resource_hdr, void *resource_value) { int rc = 0; if (!pkt || !resource_hdr || !resource_value) return -EINVAL; pkt->packet_type = HFI_CMD_SYS_SET_RESOURCE; pkt->size = sizeof(struct hfi_cmd_sys_set_resource_packet); pkt->resource_handle = hash32_ptr(resource_hdr->resource_handle); switch (resource_hdr->resource_id) { case VIDC_RESOURCE_OCMEM: case VIDC_RESOURCE_VMEM: { struct hfi_resource_ocmem *hfioc_mem = (struct hfi_resource_ocmem *) &pkt->rg_resource_data[0]; phys_addr_t imem_addr = (phys_addr_t)resource_value; pkt->resource_type = HFI_RESOURCE_OCMEM; pkt->size += sizeof(struct hfi_resource_ocmem) - sizeof(u32); hfioc_mem->size = (u32)resource_hdr->size; hfioc_mem->mem = imem_addr; break; } default: dprintk(VIDC_ERR, "Invalid resource_id %d\n", resource_hdr->resource_id); rc = -ENOTSUPP; } return rc; } int create_pkt_cmd_sys_release_resource( struct hfi_cmd_sys_release_resource_packet *pkt, struct vidc_resource_hdr *resource_hdr) { int rc = 0; if (!pkt) return -EINVAL; pkt->size = sizeof(struct hfi_cmd_sys_release_resource_packet); pkt->packet_type = HFI_CMD_SYS_RELEASE_RESOURCE; pkt->resource_handle = hash32_ptr(resource_hdr->resource_handle); switch (resource_hdr->resource_id) { case VIDC_RESOURCE_OCMEM: case VIDC_RESOURCE_VMEM: pkt->resource_type = HFI_RESOURCE_OCMEM; break; default: dprintk(VIDC_ERR, "Invalid resource_id %d\n", resource_hdr->resource_id); rc = -ENOTSUPP; } return rc; } int create_pkt_cmd_sys_ping(struct hfi_cmd_sys_ping_packet *pkt) { int rc = 0; if (!pkt) return -EINVAL; pkt->size = sizeof(struct hfi_cmd_sys_ping_packet); pkt->packet_type = HFI_CMD_SYS_PING; return rc; } inline int create_pkt_cmd_sys_session_init( struct hfi_cmd_sys_session_init_packet *pkt, struct hal_session *session, u32 session_domain, u32 session_codec) { int rc = 0; if (!pkt) return -EINVAL; pkt->size = sizeof(struct hfi_cmd_sys_session_init_packet); pkt->packet_type = HFI_CMD_SYS_SESSION_INIT; pkt->session_id = hash32_ptr(session); pkt->session_domain = vidc_get_hfi_domain(session_domain); pkt->session_codec = vidc_get_hfi_codec(session_codec); if (!pkt->session_codec) return -EINVAL; return rc; } int create_pkt_cmd_session_cmd(struct vidc_hal_session_cmd_pkt *pkt, int pkt_type, struct hal_session *session) { int rc = 0; if (!pkt) return -EINVAL; /* * Legacy packetization should skip sending any 3xx specific session * cmds. Add 3xx specific packetization to the switch case below. */ switch (pkt_type) { case HFI_CMD_SESSION_CONTINUE: dprintk(VIDC_INFO, "%s - skip sending %x for legacy hfi\n", __func__, pkt_type); return -EPERM; default: break; } pkt->size = sizeof(struct vidc_hal_session_cmd_pkt); pkt->packet_type = pkt_type; pkt->session_id = hash32_ptr(session); return rc; } int create_3x_pkt_cmd_session_cmd(struct vidc_hal_session_cmd_pkt *pkt, int pkt_type, struct hal_session *session) { int rc = 0; if (!pkt) return -EINVAL; pkt->size = sizeof(struct vidc_hal_session_cmd_pkt); pkt->packet_type = pkt_type; pkt->session_id = hash32_ptr(session); return rc; } int create_pkt_cmd_sys_power_control( struct hfi_cmd_sys_set_property_packet *pkt, u32 enable) { struct hfi_enable *hfi; if (!pkt) { dprintk(VIDC_ERR, "No input packet\n"); return -EINVAL; } pkt->size = sizeof(struct hfi_cmd_sys_set_property_packet) + sizeof(struct hfi_enable) + sizeof(u32); pkt->packet_type = HFI_CMD_SYS_SET_PROPERTY; pkt->num_properties = 1; pkt->rg_property_data[0] = HFI_PROPERTY_SYS_CODEC_POWER_PLANE_CTRL; hfi = (struct hfi_enable *) &pkt->rg_property_data[1]; hfi->enable = enable; return 0; } static u32 get_hfi_buffer(int hal_buffer) { u32 buffer; switch (hal_buffer) { case HAL_BUFFER_INPUT: buffer = HFI_BUFFER_INPUT; break; case HAL_BUFFER_OUTPUT: buffer = HFI_BUFFER_OUTPUT; break; case HAL_BUFFER_OUTPUT2: buffer = HFI_BUFFER_OUTPUT2; break; case HAL_BUFFER_EXTRADATA_INPUT: buffer = HFI_BUFFER_EXTRADATA_INPUT; break; case HAL_BUFFER_EXTRADATA_OUTPUT: buffer = HFI_BUFFER_EXTRADATA_OUTPUT; break; case HAL_BUFFER_EXTRADATA_OUTPUT2: buffer = HFI_BUFFER_EXTRADATA_OUTPUT2; break; case HAL_BUFFER_INTERNAL_SCRATCH: buffer = HFI_BUFFER_INTERNAL_SCRATCH; break; case HAL_BUFFER_INTERNAL_SCRATCH_1: buffer = HFI_BUFFER_INTERNAL_SCRATCH_1; break; case HAL_BUFFER_INTERNAL_SCRATCH_2: buffer = HFI_BUFFER_INTERNAL_SCRATCH_2; break; case HAL_BUFFER_INTERNAL_PERSIST: buffer = HFI_BUFFER_INTERNAL_PERSIST; break; case HAL_BUFFER_INTERNAL_PERSIST_1: buffer = HFI_BUFFER_INTERNAL_PERSIST_1; break; default: dprintk(VIDC_ERR, "Invalid buffer: %#x\n", hal_buffer); buffer = 0; break; } return buffer; } static int get_hfi_extradata_index(enum hal_extradata_id index) { int ret = 0; switch (index) { case HAL_EXTRADATA_MB_QUANTIZATION: ret = HFI_PROPERTY_PARAM_VDEC_MB_QUANTIZATION; break; case HAL_EXTRADATA_INTERLACE_VIDEO: ret = HFI_PROPERTY_PARAM_VDEC_INTERLACE_VIDEO_EXTRADATA; break; case HAL_EXTRADATA_VC1_FRAMEDISP: ret = HFI_PROPERTY_PARAM_VDEC_VC1_FRAMEDISP_EXTRADATA; break; case HAL_EXTRADATA_VC1_SEQDISP: ret = HFI_PROPERTY_PARAM_VDEC_VC1_SEQDISP_EXTRADATA; break; case HAL_EXTRADATA_TIMESTAMP: ret = HFI_PROPERTY_PARAM_VDEC_TIMESTAMP_EXTRADATA; break; case HAL_EXTRADATA_S3D_FRAME_PACKING: ret = HFI_PROPERTY_PARAM_S3D_FRAME_PACKING_EXTRADATA; break; case HAL_EXTRADATA_FRAME_RATE: ret = HFI_PROPERTY_PARAM_VDEC_FRAME_RATE_EXTRADATA; break; case HAL_EXTRADATA_PANSCAN_WINDOW: ret = HFI_PROPERTY_PARAM_VDEC_PANSCAN_WNDW_EXTRADATA; break; case HAL_EXTRADATA_RECOVERY_POINT_SEI: ret = HFI_PROPERTY_PARAM_VDEC_RECOVERY_POINT_SEI_EXTRADATA; break; case HAL_EXTRADATA_MULTISLICE_INFO: ret = HFI_PROPERTY_PARAM_VENC_MULTI_SLICE_INFO; break; case HAL_EXTRADATA_NUM_CONCEALED_MB: ret = HFI_PROPERTY_PARAM_VDEC_NUM_CONCEALED_MB; break; case HAL_EXTRADATA_ASPECT_RATIO: case HAL_EXTRADATA_INPUT_CROP: case HAL_EXTRADATA_DIGITAL_ZOOM: ret = HFI_PROPERTY_PARAM_INDEX_EXTRADATA; break; case HAL_EXTRADATA_MPEG2_SEQDISP: ret = HFI_PROPERTY_PARAM_VDEC_MPEG2_SEQDISP_EXTRADATA; break; case HAL_EXTRADATA_STREAM_USERDATA: ret = HFI_PROPERTY_PARAM_VDEC_STREAM_USERDATA_EXTRADATA; break; case HAL_EXTRADATA_FRAME_QP: ret = HFI_PROPERTY_PARAM_VDEC_FRAME_QP_EXTRADATA; break; case HAL_EXTRADATA_FRAME_BITS_INFO: ret = HFI_PROPERTY_PARAM_VDEC_FRAME_BITS_INFO_EXTRADATA; break; case HAL_EXTRADATA_LTR_INFO: ret = HFI_PROPERTY_PARAM_VENC_LTR_INFO; break; case HAL_EXTRADATA_METADATA_MBI: ret = HFI_PROPERTY_PARAM_VENC_MBI_DUMPING; break; case HAL_EXTRADATA_VQZIP_SEI: ret = HFI_PROPERTY_PARAM_VDEC_VQZIP_SEI_EXTRADATA; break; case HAL_EXTRADATA_YUV_STATS: ret = HFI_PROPERTY_PARAM_VENC_YUVSTAT_INFO_EXTRADATA; break; case HAL_EXTRADATA_ROI_QP: ret = HFI_PROPERTY_PARAM_VENC_ROI_QP_EXTRADATA; break; default: dprintk(VIDC_WARN, "Extradata index not found: %d\n", index); break; } return ret; } static int get_hfi_extradata_id(enum hal_extradata_id index) { int ret = 0; switch (index) { case HAL_EXTRADATA_ASPECT_RATIO: ret = MSM_VIDC_EXTRADATA_ASPECT_RATIO; break; case HAL_EXTRADATA_INPUT_CROP: ret = MSM_VIDC_EXTRADATA_INPUT_CROP; break; case HAL_EXTRADATA_DIGITAL_ZOOM: ret = MSM_VIDC_EXTRADATA_DIGITAL_ZOOM; break; default: ret = get_hfi_extradata_index(index); break; } return ret; } static u32 get_hfi_buf_mode(enum buffer_mode_type hal_buf_mode) { u32 buf_mode; switch (hal_buf_mode) { case HAL_BUFFER_MODE_STATIC: buf_mode = HFI_BUFFER_MODE_STATIC; break; case HAL_BUFFER_MODE_RING: buf_mode = HFI_BUFFER_MODE_RING; break; case HAL_BUFFER_MODE_DYNAMIC: buf_mode = HFI_BUFFER_MODE_DYNAMIC; break; default: dprintk(VIDC_ERR, "Invalid buffer mode: %#x\n", hal_buf_mode); buf_mode = 0; break; } return buf_mode; } static u32 get_hfi_ltr_mode(enum ltr_mode ltr_mode_type) { u32 ltrmode; switch (ltr_mode_type) { case HAL_LTR_MODE_DISABLE: ltrmode = HFI_LTR_MODE_DISABLE; break; case HAL_LTR_MODE_MANUAL: ltrmode = HFI_LTR_MODE_MANUAL; break; case HAL_LTR_MODE_PERIODIC: ltrmode = HFI_LTR_MODE_PERIODIC; break; default: dprintk(VIDC_ERR, "Invalid ltr mode: %#x\n", ltr_mode_type); ltrmode = HFI_LTR_MODE_DISABLE; break; } return ltrmode; } int create_pkt_cmd_session_set_buffers( struct hfi_cmd_session_set_buffers_packet *pkt, struct hal_session *session, struct vidc_buffer_addr_info *buffer_info) { int rc = 0; int i = 0; if (!pkt || !session) return -EINVAL; pkt->packet_type = HFI_CMD_SESSION_SET_BUFFERS; pkt->session_id = hash32_ptr(session); pkt->buffer_size = buffer_info->buffer_size; pkt->min_buffer_size = buffer_info->buffer_size; pkt->num_buffers = buffer_info->num_buffers; if (buffer_info->buffer_type == HAL_BUFFER_OUTPUT || buffer_info->buffer_type == HAL_BUFFER_OUTPUT2) { struct hfi_buffer_info *buff; pkt->extra_data_size = buffer_info->extradata_size; pkt->size = sizeof(struct hfi_cmd_session_set_buffers_packet) - sizeof(u32) + (buffer_info->num_buffers * sizeof(struct hfi_buffer_info)); buff = (struct hfi_buffer_info *) pkt->rg_buffer_info; for (i = 0; i < pkt->num_buffers; i++) { buff->buffer_addr = (u32)buffer_info->align_device_addr; buff->extra_data_addr = (u32)buffer_info->extradata_addr; } } else { pkt->extra_data_size = 0; pkt->size = sizeof(struct hfi_cmd_session_set_buffers_packet) + ((buffer_info->num_buffers - 1) * sizeof(u32)); for (i = 0; i < pkt->num_buffers; i++) { pkt->rg_buffer_info[i] = (u32)buffer_info->align_device_addr; } } pkt->buffer_type = get_hfi_buffer(buffer_info->buffer_type); if (!pkt->buffer_type) return -EINVAL; return rc; } int create_pkt_cmd_session_release_buffers( struct hfi_cmd_session_release_buffer_packet *pkt, struct hal_session *session, struct vidc_buffer_addr_info *buffer_info) { int rc = 0; int i = 0; if (!pkt || !session) return -EINVAL; pkt->packet_type = HFI_CMD_SESSION_RELEASE_BUFFERS; pkt->session_id = hash32_ptr(session); pkt->buffer_size = buffer_info->buffer_size; pkt->num_buffers = buffer_info->num_buffers; if (buffer_info->buffer_type == HAL_BUFFER_OUTPUT || buffer_info->buffer_type == HAL_BUFFER_OUTPUT2) { struct hfi_buffer_info *buff; buff = (struct hfi_buffer_info *) pkt->rg_buffer_info; for (i = 0; i < pkt->num_buffers; i++) { buff->buffer_addr = (u32)buffer_info->align_device_addr; buff->extra_data_addr = (u32)buffer_info->extradata_addr; } pkt->size = sizeof(struct hfi_cmd_session_set_buffers_packet) - sizeof(u32) + (buffer_info->num_buffers * sizeof(struct hfi_buffer_info)); } else { for (i = 0; i < pkt->num_buffers; i++) { pkt->rg_buffer_info[i] = (u32)buffer_info->align_device_addr; } pkt->extra_data_size = 0; pkt->size = sizeof(struct hfi_cmd_session_set_buffers_packet) + ((buffer_info->num_buffers - 1) * sizeof(u32)); } pkt->response_req = buffer_info->response_required; pkt->buffer_type = get_hfi_buffer(buffer_info->buffer_type); if (!pkt->buffer_type) return -EINVAL; return rc; } int create_pkt_cmd_session_etb_decoder( struct hfi_cmd_session_empty_buffer_compressed_packet *pkt, struct hal_session *session, struct vidc_frame_data *input_frame) { int rc = 0; if (!pkt || !session) return -EINVAL; pkt->size = sizeof(struct hfi_cmd_session_empty_buffer_compressed_packet); pkt->packet_type = HFI_CMD_SESSION_EMPTY_BUFFER; pkt->session_id = hash32_ptr(session); pkt->time_stamp_hi = upper_32_bits(input_frame->timestamp); pkt->time_stamp_lo = lower_32_bits(input_frame->timestamp); pkt->flags = input_frame->flags; pkt->mark_target = input_frame->mark_target; pkt->mark_data = input_frame->mark_data; pkt->offset = input_frame->offset; pkt->alloc_len = input_frame->alloc_len; pkt->filled_len = input_frame->filled_len; pkt->input_tag = input_frame->clnt_data; pkt->packet_buffer = (u32)input_frame->device_addr; trace_msm_v4l2_vidc_buffer_event_start("ETB", input_frame->device_addr, input_frame->timestamp, input_frame->alloc_len, input_frame->filled_len, input_frame->offset); if (!pkt->packet_buffer) rc = -EINVAL; return rc; } int create_pkt_cmd_session_etb_encoder( struct hfi_cmd_session_empty_buffer_uncompressed_plane0_packet *pkt, struct hal_session *session, struct vidc_frame_data *input_frame) { int rc = 0; if (!pkt || !session) return -EINVAL; pkt->size = sizeof(struct hfi_cmd_session_empty_buffer_uncompressed_plane0_packet); pkt->packet_type = HFI_CMD_SESSION_EMPTY_BUFFER; pkt->session_id = hash32_ptr(session); pkt->view_id = 0; pkt->time_stamp_hi = upper_32_bits(input_frame->timestamp); pkt->time_stamp_lo = lower_32_bits(input_frame->timestamp); pkt->flags = input_frame->flags; pkt->mark_target = input_frame->mark_target; pkt->mark_data = input_frame->mark_data; pkt->offset = input_frame->offset; pkt->alloc_len = input_frame->alloc_len; pkt->filled_len = input_frame->filled_len; pkt->input_tag = input_frame->clnt_data; pkt->packet_buffer = (u32)input_frame->device_addr; pkt->extra_data_buffer = (u32)input_frame->extradata_addr; trace_msm_v4l2_vidc_buffer_event_start("ETB", input_frame->device_addr, input_frame->timestamp, input_frame->alloc_len, input_frame->filled_len, input_frame->offset); if (!pkt->packet_buffer) rc = -EINVAL; return rc; } int create_pkt_cmd_session_ftb(struct hfi_cmd_session_fill_buffer_packet *pkt, struct hal_session *session, struct vidc_frame_data *output_frame) { int rc = 0; if (!pkt || !session || !output_frame) return -EINVAL; pkt->size = sizeof(struct hfi_cmd_session_fill_buffer_packet); pkt->packet_type = HFI_CMD_SESSION_FILL_BUFFER; pkt->session_id = hash32_ptr(session); if (output_frame->buffer_type == HAL_BUFFER_OUTPUT) pkt->stream_id = 0; else if (output_frame->buffer_type == HAL_BUFFER_OUTPUT2) pkt->stream_id = 1; if (!output_frame->device_addr) return -EINVAL; pkt->packet_buffer = (u32)output_frame->device_addr; pkt->extra_data_buffer = (u32)output_frame->extradata_addr; pkt->alloc_len = output_frame->alloc_len; pkt->filled_len = output_frame->filled_len; pkt->offset = output_frame->offset; pkt->rgData[0] = output_frame->extradata_size; trace_msm_v4l2_vidc_buffer_event_start("FTB", output_frame->device_addr, output_frame->timestamp, output_frame->alloc_len, output_frame->filled_len, output_frame->offset); dprintk(VIDC_DBG, "### Q OUTPUT BUFFER ###: %d, %d, %d\n", pkt->alloc_len, pkt->filled_len, pkt->offset); return rc; } int create_pkt_cmd_session_parse_seq_header( struct hfi_cmd_session_parse_sequence_header_packet *pkt, struct hal_session *session, struct vidc_seq_hdr *seq_hdr) { int rc = 0; if (!pkt || !session || !seq_hdr) return -EINVAL; pkt->size = sizeof(struct hfi_cmd_session_parse_sequence_header_packet); pkt->packet_type = HFI_CMD_SESSION_PARSE_SEQUENCE_HEADER; pkt->session_id = hash32_ptr(session); pkt->header_len = seq_hdr->seq_hdr_len; if (!seq_hdr->seq_hdr) return -EINVAL; pkt->packet_buffer = (u32)seq_hdr->seq_hdr; return rc; } int create_pkt_cmd_session_get_seq_hdr( struct hfi_cmd_session_get_sequence_header_packet *pkt, struct hal_session *session, struct vidc_seq_hdr *seq_hdr) { int rc = 0; if (!pkt || !session || !seq_hdr) return -EINVAL; pkt->size = sizeof(struct hfi_cmd_session_get_sequence_header_packet); pkt->packet_type = HFI_CMD_SESSION_GET_SEQUENCE_HEADER; pkt->session_id = hash32_ptr(session); pkt->buffer_len = seq_hdr->seq_hdr_len; if (!seq_hdr->seq_hdr) return -EINVAL; pkt->packet_buffer = (u32)seq_hdr->seq_hdr; return rc; } int create_pkt_cmd_session_get_buf_req( struct hfi_cmd_session_get_property_packet *pkt, struct hal_session *session) { int rc = 0; if (!pkt || !session) return -EINVAL; pkt->size = sizeof(struct hfi_cmd_session_get_property_packet); pkt->packet_type = HFI_CMD_SESSION_GET_PROPERTY; pkt->session_id = hash32_ptr(session); pkt->num_properties = 1; pkt->rg_property_data[0] = HFI_PROPERTY_CONFIG_BUFFER_REQUIREMENTS; return rc; } int create_pkt_cmd_session_flush(struct hfi_cmd_session_flush_packet *pkt, struct hal_session *session, enum hal_flush flush_mode) { int rc = 0; if (!pkt || !session) return -EINVAL; pkt->size = sizeof(struct hfi_cmd_session_flush_packet); pkt->packet_type = HFI_CMD_SESSION_FLUSH; pkt->session_id = hash32_ptr(session); switch (flush_mode) { case HAL_FLUSH_INPUT: pkt->flush_type = HFI_FLUSH_INPUT; break; case HAL_FLUSH_OUTPUT: pkt->flush_type = HFI_FLUSH_OUTPUT; break; case HAL_FLUSH_ALL: pkt->flush_type = HFI_FLUSH_ALL; break; default: dprintk(VIDC_ERR, "Invalid flush mode: %#x\n", flush_mode); return -EINVAL; } return rc; } int create_pkt_cmd_session_get_property( struct hfi_cmd_session_get_property_packet *pkt, struct hal_session *session, enum hal_property ptype) { int rc = 0; if (!pkt || !session) { dprintk(VIDC_ERR, "%s Invalid parameters\n", __func__); return -EINVAL; } pkt->size = sizeof(struct hfi_cmd_session_get_property_packet); pkt->packet_type = HFI_CMD_SESSION_GET_PROPERTY; pkt->session_id = hash32_ptr(session); pkt->num_properties = 1; switch (ptype) { case HAL_PARAM_PROFILE_LEVEL_CURRENT: pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_PROFILE_LEVEL_CURRENT; break; default: dprintk(VIDC_ERR, "%s cmd:%#x not supported\n", __func__, ptype); rc = -EINVAL; break; } return rc; } int create_3x_pkt_cmd_session_get_property( struct hfi_cmd_session_get_property_packet *pkt, struct hal_session *session, enum hal_property ptype) { int rc = 0; if (!pkt || !session) { dprintk(VIDC_ERR, "%s Invalid parameters\n", __func__); return -EINVAL; } pkt->size = sizeof(struct hfi_cmd_session_get_property_packet); pkt->packet_type = HFI_CMD_SESSION_GET_PROPERTY; pkt->session_id = hash32_ptr(session); pkt->num_properties = 1; switch (ptype) { case HAL_CONFIG_VDEC_ENTROPY: pkt->rg_property_data[0] = HFI_PROPERTY_CONFIG_VDEC_ENTROPY; break; default: rc = create_pkt_cmd_session_get_property(pkt, session, ptype); } return rc; } int create_pkt_cmd_session_set_property( struct hfi_cmd_session_set_property_packet *pkt, struct hal_session *session, enum hal_property ptype, void *pdata) { int rc = 0; if (!pkt || !session) return -EINVAL; pkt->size = sizeof(struct hfi_cmd_session_set_property_packet); pkt->packet_type = HFI_CMD_SESSION_SET_PROPERTY; pkt->session_id = hash32_ptr(session); pkt->num_properties = 1; switch (ptype) { case HAL_CONFIG_FRAME_RATE: { u32 buffer_type; struct hfi_frame_rate *hfi; struct hal_frame_rate *prop = (struct hal_frame_rate *) pdata; pkt->rg_property_data[0] = HFI_PROPERTY_CONFIG_FRAME_RATE; hfi = (struct hfi_frame_rate *) &pkt->rg_property_data[1]; buffer_type = get_hfi_buffer(prop->buffer_type); if (buffer_type) hfi->buffer_type = buffer_type; else return -EINVAL; hfi->frame_rate = prop->frame_rate; pkt->size += sizeof(u32) + sizeof(struct hfi_frame_rate); break; } case HAL_PARAM_UNCOMPRESSED_FORMAT_SELECT: { u32 buffer_type; struct hfi_uncompressed_format_select *hfi; struct hal_uncompressed_format_select *prop = (struct hal_uncompressed_format_select *) pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_UNCOMPRESSED_FORMAT_SELECT; hfi = (struct hfi_uncompressed_format_select *) &pkt->rg_property_data[1]; buffer_type = get_hfi_buffer(prop->buffer_type); if (buffer_type) hfi->buffer_type = buffer_type; else return -EINVAL; hfi->format = hal_to_hfi_type( HAL_PARAM_UNCOMPRESSED_FORMAT_SELECT, prop->format); pkt->size += sizeof(u32) + sizeof(struct hfi_uncompressed_format_select); break; } case HAL_PARAM_UNCOMPRESSED_PLANE_ACTUAL_CONSTRAINTS_INFO: break; case HAL_PARAM_UNCOMPRESSED_PLANE_ACTUAL_INFO: break; case HAL_PARAM_EXTRA_DATA_HEADER_CONFIG: break; case HAL_PARAM_FRAME_SIZE: { struct hfi_frame_size *hfi; struct hal_frame_size *prop = (struct hal_frame_size *) pdata; u32 buffer_type; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_FRAME_SIZE; hfi = (struct hfi_frame_size *) &pkt->rg_property_data[1]; buffer_type = get_hfi_buffer(prop->buffer_type); if (buffer_type) hfi->buffer_type = buffer_type; else return -EINVAL; hfi->height = prop->height; hfi->width = prop->width; pkt->size += sizeof(u32) + sizeof(struct hfi_frame_size); break; } case HAL_CONFIG_REALTIME: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_CONFIG_REALTIME, (((struct hal_enable *) pdata)->enable)); pkt->size += sizeof(u32) * 2; break; } case HAL_PARAM_BUFFER_COUNT_ACTUAL: { struct hfi_buffer_count_actual *hfi; struct hal_buffer_count_actual *prop = (struct hal_buffer_count_actual *) pdata; u32 buffer_type; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_BUFFER_COUNT_ACTUAL; hfi = (struct hfi_buffer_count_actual *) &pkt->rg_property_data[1]; hfi->buffer_count_actual = prop->buffer_count_actual; buffer_type = get_hfi_buffer(prop->buffer_type); if (buffer_type) hfi->buffer_type = buffer_type; else return -EINVAL; pkt->size += sizeof(u32) + sizeof(struct hfi_buffer_count_actual); break; } case HAL_PARAM_NAL_STREAM_FORMAT_SELECT: { struct hfi_nal_stream_format_select *hfi; struct hal_nal_stream_format_select *prop = (struct hal_nal_stream_format_select *)pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_NAL_STREAM_FORMAT_SELECT; hfi = (struct hfi_nal_stream_format_select *) &pkt->rg_property_data[1]; dprintk(VIDC_DBG, "data is :%d\n", prop->nal_stream_format_select); hfi->nal_stream_format_select = hal_to_hfi_type( HAL_PARAM_NAL_STREAM_FORMAT_SELECT, prop->nal_stream_format_select); pkt->size += sizeof(u32) + sizeof(struct hfi_nal_stream_format_select); break; } case HAL_PARAM_VDEC_OUTPUT_ORDER: { int *data = (int *) pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VDEC_OUTPUT_ORDER; switch (*data) { case HAL_OUTPUT_ORDER_DECODE: pkt->rg_property_data[1] = HFI_OUTPUT_ORDER_DECODE; break; case HAL_OUTPUT_ORDER_DISPLAY: pkt->rg_property_data[1] = HFI_OUTPUT_ORDER_DISPLAY; break; default: dprintk(VIDC_ERR, "invalid output order: %#x\n", *data); break; } pkt->size += sizeof(u32) * 2; break; } case HAL_PARAM_VDEC_PICTURE_TYPE_DECODE: { struct hfi_enable_picture *hfi; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VDEC_PICTURE_TYPE_DECODE; hfi = (struct hfi_enable_picture *) &pkt->rg_property_data[1]; hfi->picture_type = ((struct hfi_enable_picture *)pdata)->picture_type; pkt->size += sizeof(u32) * 2; break; } case HAL_PARAM_VDEC_OUTPUT2_KEEP_ASPECT_RATIO: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_PARAM_VDEC_OUTPUT2_KEEP_ASPECT_RATIO, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) * 2; break; } case HAL_CONFIG_VDEC_POST_LOOP_DEBLOCKER: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_CONFIG_VDEC_POST_LOOP_DEBLOCKER, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) * 2; break; } case HAL_PARAM_VDEC_MULTI_STREAM: { struct hfi_multi_stream *hfi; struct hal_multi_stream *prop = (struct hal_multi_stream *) pdata; u32 buffer_type; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VDEC_MULTI_STREAM; hfi = (struct hfi_multi_stream *) &pkt->rg_property_data[1]; buffer_type = get_hfi_buffer(prop->buffer_type); if (buffer_type) hfi->buffer_type = buffer_type; else return -EINVAL; hfi->enable = prop->enable; hfi->width = prop->width; hfi->height = prop->height; pkt->size += sizeof(u32) + sizeof(struct hfi_multi_stream); break; } case HAL_PARAM_VDEC_DISPLAY_PICTURE_BUFFER_COUNT: { struct hfi_display_picture_buffer_count *hfi; struct hal_display_picture_buffer_count *prop = (struct hal_display_picture_buffer_count *) pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VDEC_DISPLAY_PICTURE_BUFFER_COUNT; hfi = (struct hfi_display_picture_buffer_count *) &pkt->rg_property_data[1]; hfi->count = prop->count; hfi->enable = prop->enable; pkt->size += sizeof(u32) + sizeof(struct hfi_display_picture_buffer_count); break; } case HAL_PARAM_DIVX_FORMAT: { int *data = pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_DIVX_FORMAT; switch (*data) { case HAL_DIVX_FORMAT_4: pkt->rg_property_data[1] = HFI_DIVX_FORMAT_4; break; case HAL_DIVX_FORMAT_5: pkt->rg_property_data[1] = HFI_DIVX_FORMAT_5; break; case HAL_DIVX_FORMAT_6: pkt->rg_property_data[1] = HFI_DIVX_FORMAT_6; break; default: dprintk(VIDC_ERR, "Invalid divx format: %#x\n", *data); break; } pkt->size += sizeof(u32) * 2; break; } case HAL_CONFIG_VDEC_MB_ERROR_MAP_REPORTING: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_CONFIG_VDEC_MB_ERROR_MAP_REPORTING, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) * 2; break; } case HAL_PARAM_VDEC_CONTINUE_DATA_TRANSFER: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_PARAM_VDEC_CONTINUE_DATA_TRANSFER, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) * 2; break; } case HAL_PARAM_VDEC_SYNC_FRAME_DECODE: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_PARAM_VDEC_THUMBNAIL_MODE, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) * 2; break; } case HAL_PARAM_VENC_SYNC_FRAME_SEQUENCE_HEADER: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_CONFIG_VENC_SYNC_FRAME_SEQUENCE_HEADER, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) * 2; break; } case HAL_CONFIG_VENC_REQUEST_IFRAME: pkt->rg_property_data[0] = HFI_PROPERTY_CONFIG_VENC_REQUEST_SYNC_FRAME; pkt->size += sizeof(u32); break; case HAL_PARAM_VENC_MPEG4_SHORT_HEADER: break; case HAL_PARAM_VENC_MPEG4_AC_PREDICTION: break; case HAL_CONFIG_VENC_TARGET_BITRATE: { struct hfi_bitrate *hfi; pkt->rg_property_data[0] = HFI_PROPERTY_CONFIG_VENC_TARGET_BITRATE; hfi = (struct hfi_bitrate *) &pkt->rg_property_data[1]; hfi->bit_rate = ((struct hal_bitrate *)pdata)->bit_rate; hfi->layer_id = ((struct hal_bitrate *)pdata)->layer_id; pkt->size += sizeof(u32) + sizeof(struct hfi_bitrate); break; } case HAL_CONFIG_VENC_MAX_BITRATE: { struct hfi_bitrate *hfi; pkt->rg_property_data[0] = HFI_PROPERTY_CONFIG_VENC_MAX_BITRATE; hfi = (struct hfi_bitrate *) &pkt->rg_property_data[1]; hfi->bit_rate = ((struct hal_bitrate *)pdata)->bit_rate; hfi->layer_id = ((struct hal_bitrate *)pdata)->layer_id; pkt->size += sizeof(u32) + sizeof(struct hfi_bitrate); break; } case HAL_PARAM_PROFILE_LEVEL_CURRENT: { struct hfi_profile_level *hfi; struct hal_profile_level *prop = (struct hal_profile_level *) pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_PROFILE_LEVEL_CURRENT; hfi = (struct hfi_profile_level *) &pkt->rg_property_data[1]; hfi->level = prop->level; hfi->profile = hal_to_hfi_type(HAL_PARAM_PROFILE_LEVEL_CURRENT, prop->profile); if (hfi->profile <= 0) { hfi->profile = HFI_H264_PROFILE_HIGH; dprintk(VIDC_WARN, "Profile %d not supported, falling back to high\n", prop->profile); } if (!hfi->level) { hfi->level = 1; dprintk(VIDC_WARN, "Level %d not supported, falling back to high\n", prop->level); } pkt->size += sizeof(u32) + sizeof(struct hfi_profile_level); break; } case HAL_PARAM_VENC_H264_ENTROPY_CONTROL: { struct hfi_h264_entropy_control *hfi; struct hal_h264_entropy_control *prop = (struct hal_h264_entropy_control *) pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_H264_ENTROPY_CONTROL; hfi = (struct hfi_h264_entropy_control *) &pkt->rg_property_data[1]; hfi->entropy_mode = hal_to_hfi_type( HAL_PARAM_VENC_H264_ENTROPY_CONTROL, prop->entropy_mode); if (hfi->entropy_mode == HAL_H264_ENTROPY_CABAC) hfi->cabac_model = hal_to_hfi_type( HAL_PARAM_VENC_H264_ENTROPY_CABAC_MODEL, prop->cabac_model); pkt->size += sizeof(u32) + sizeof( struct hfi_h264_entropy_control); break; } case HAL_PARAM_VENC_RATE_CONTROL: { u32 *rc; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_RATE_CONTROL; rc = (u32 *)pdata; switch ((enum hal_rate_control) *rc) { case HAL_RATE_CONTROL_OFF: pkt->rg_property_data[1] = HFI_RATE_CONTROL_OFF; break; case HAL_RATE_CONTROL_CBR_CFR: pkt->rg_property_data[1] = HFI_RATE_CONTROL_CBR_CFR; break; case HAL_RATE_CONTROL_CBR_VFR: pkt->rg_property_data[1] = HFI_RATE_CONTROL_CBR_VFR; break; case HAL_RATE_CONTROL_VBR_CFR: pkt->rg_property_data[1] = HFI_RATE_CONTROL_VBR_CFR; break; case HAL_RATE_CONTROL_VBR_VFR: pkt->rg_property_data[1] = HFI_RATE_CONTROL_VBR_VFR; break; default: dprintk(VIDC_ERR, "Invalid Rate control setting: %p\n", pdata); break; } pkt->size += sizeof(u32) * 2; break; } case HAL_PARAM_VENC_MPEG4_TIME_RESOLUTION: { struct hfi_mpeg4_time_resolution *hfi; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_MPEG4_TIME_RESOLUTION; hfi = (struct hfi_mpeg4_time_resolution *) &pkt->rg_property_data[1]; hfi->time_increment_resolution = ((struct hal_mpeg4_time_resolution *)pdata)-> time_increment_resolution; pkt->size += sizeof(u32) * 2; break; } case HAL_PARAM_VENC_MPEG4_HEADER_EXTENSION: { struct hfi_mpeg4_header_extension *hfi; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_MPEG4_HEADER_EXTENSION; hfi = (struct hfi_mpeg4_header_extension *) &pkt->rg_property_data[1]; hfi->header_extension = (u32)(unsigned long) pdata; pkt->size += sizeof(u32) * 2; break; } case HAL_PARAM_VENC_H264_DEBLOCK_CONTROL: { struct hfi_h264_db_control *hfi; struct hal_h264_db_control *prop = (struct hal_h264_db_control *) pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_H264_DEBLOCK_CONTROL; hfi = (struct hfi_h264_db_control *) &pkt->rg_property_data[1]; switch (prop->mode) { case HAL_H264_DB_MODE_DISABLE: hfi->mode = HFI_H264_DB_MODE_DISABLE; break; case HAL_H264_DB_MODE_SKIP_SLICE_BOUNDARY: hfi->mode = HFI_H264_DB_MODE_SKIP_SLICE_BOUNDARY; break; case HAL_H264_DB_MODE_ALL_BOUNDARY: hfi->mode = HFI_H264_DB_MODE_ALL_BOUNDARY; break; default: dprintk(VIDC_ERR, "Invalid deblocking mode: %#x\n", prop->mode); break; } hfi->slice_alpha_offset = prop->slice_alpha_offset; hfi->slice_beta_offset = prop->slice_beta_offset; pkt->size += sizeof(u32) + sizeof(struct hfi_h264_db_control); break; } case HAL_PARAM_VENC_SESSION_QP: { struct hfi_quantization *hfi; struct hal_quantization *hal_quant = (struct hal_quantization *) pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_SESSION_QP; hfi = (struct hfi_quantization *) &pkt->rg_property_data[1]; hfi->qp_i = hal_quant->qpi; hfi->qp_p = hal_quant->qpp; hfi->qp_b = hal_quant->qpb; hfi->layer_id = hal_quant->layer_id; pkt->size += sizeof(u32) + sizeof(struct hfi_quantization); break; } case HAL_PARAM_VENC_SESSION_QP_RANGE: { struct hfi_quantization_range *hfi; struct hfi_quantization_range *hal_range = (struct hfi_quantization_range *) pdata; u32 min_qp, max_qp; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_SESSION_QP_RANGE; hfi = (struct hfi_quantization_range *) &pkt->rg_property_data[1]; min_qp = hal_range->min_qp; max_qp = hal_range->max_qp; /* We'll be packing in the qp, so make sure we * won't be losing data when masking */ if (min_qp > 0xff || max_qp > 0xff) { dprintk(VIDC_ERR, "qp value out of range\n"); rc = -ERANGE; break; } /* When creating the packet, pack the qp value as * 0xiippbb, where ii = qp range for I-frames, * pp = qp range for P-frames, etc. */ hfi->min_qp = min_qp | min_qp << 8 | min_qp << 16; hfi->max_qp = max_qp | max_qp << 8 | max_qp << 16; hfi->layer_id = hal_range->layer_id; pkt->size += sizeof(u32) + sizeof(struct hfi_quantization_range); break; } case HAL_PARAM_VENC_SEARCH_RANGE: { struct hfi_vc1e_perf_cfg_type *hfi; struct hal_vc1e_perf_cfg_type *hal_mv_searchrange = (struct hal_vc1e_perf_cfg_type *) pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_VC1_PERF_CFG; hfi = (struct hfi_vc1e_perf_cfg_type *) &pkt->rg_property_data[1]; hfi->search_range_x_subsampled[0] = hal_mv_searchrange->i_frame.x_subsampled; hfi->search_range_x_subsampled[1] = hal_mv_searchrange->p_frame.x_subsampled; hfi->search_range_x_subsampled[2] = hal_mv_searchrange->b_frame.x_subsampled; hfi->search_range_y_subsampled[0] = hal_mv_searchrange->i_frame.y_subsampled; hfi->search_range_y_subsampled[1] = hal_mv_searchrange->p_frame.y_subsampled; hfi->search_range_y_subsampled[2] = hal_mv_searchrange->b_frame.y_subsampled; pkt->size += sizeof(u32) + sizeof(struct hfi_vc1e_perf_cfg_type); break; } case HAL_PARAM_VENC_MAX_NUM_B_FRAMES: { struct hfi_max_num_b_frames *hfi; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_MAX_NUM_B_FRAMES; hfi = (struct hfi_max_num_b_frames *) &pkt->rg_property_data[1]; memcpy(hfi, (struct hfi_max_num_b_frames *) pdata, sizeof(struct hfi_max_num_b_frames)); pkt->size += sizeof(u32) + sizeof(struct hfi_max_num_b_frames); break; } case HAL_CONFIG_VENC_INTRA_PERIOD: { struct hfi_intra_period *hfi; pkt->rg_property_data[0] = HFI_PROPERTY_CONFIG_VENC_INTRA_PERIOD; hfi = (struct hfi_intra_period *) &pkt->rg_property_data[1]; memcpy(hfi, (struct hfi_intra_period *) pdata, sizeof(struct hfi_intra_period)); pkt->size += sizeof(u32) + sizeof(struct hfi_intra_period); break; } case HAL_CONFIG_VENC_IDR_PERIOD: { struct hfi_idr_period *hfi; pkt->rg_property_data[0] = HFI_PROPERTY_CONFIG_VENC_IDR_PERIOD; hfi = (struct hfi_idr_period *) &pkt->rg_property_data[1]; hfi->idr_period = ((struct hfi_idr_period *) pdata)->idr_period; pkt->size += sizeof(u32) * 2; break; } case HAL_PARAM_VDEC_CONCEAL_COLOR: { struct hfi_conceal_color *hfi; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VDEC_CONCEAL_COLOR; hfi = (struct hfi_conceal_color *) &pkt->rg_property_data[1]; if (hfi) hfi->conceal_color = ((struct hfi_conceal_color *) pdata)-> conceal_color; pkt->size += sizeof(u32) * 2; break; } case HAL_CONFIG_VPE_OPERATIONS: { struct hfi_operations_type *hfi; struct hal_operations *prop = (struct hal_operations *) pdata; pkt->rg_property_data[0] = HFI_PROPERTY_CONFIG_VPE_OPERATIONS; hfi = (struct hfi_operations_type *) &pkt->rg_property_data[1]; switch (prop->rotate) { case HAL_ROTATE_NONE: hfi->rotation = HFI_ROTATE_NONE; break; case HAL_ROTATE_90: hfi->rotation = HFI_ROTATE_90; break; case HAL_ROTATE_180: hfi->rotation = HFI_ROTATE_180; break; case HAL_ROTATE_270: hfi->rotation = HFI_ROTATE_270; break; default: dprintk(VIDC_ERR, "Invalid rotation setting: %#x\n", prop->rotate); rc = -EINVAL; break; } switch (prop->flip) { case HAL_FLIP_NONE: hfi->flip = HFI_FLIP_NONE; break; case HAL_FLIP_HORIZONTAL: hfi->flip = HFI_FLIP_HORIZONTAL; break; case HAL_FLIP_VERTICAL: hfi->flip = HFI_FLIP_VERTICAL; break; default: dprintk(VIDC_ERR, "Invalid flip setting: %#x\n", prop->flip); rc = -EINVAL; break; } pkt->size += sizeof(u32) + sizeof(struct hfi_operations_type); break; } case HAL_PARAM_VENC_INTRA_REFRESH: { struct hfi_intra_refresh *hfi; struct hal_intra_refresh *prop = (struct hal_intra_refresh *) pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_INTRA_REFRESH; hfi = (struct hfi_intra_refresh *) &pkt->rg_property_data[1]; switch (prop->mode) { case HAL_INTRA_REFRESH_NONE: hfi->mode = HFI_INTRA_REFRESH_NONE; break; case HAL_INTRA_REFRESH_ADAPTIVE: hfi->mode = HFI_INTRA_REFRESH_ADAPTIVE; break; case HAL_INTRA_REFRESH_CYCLIC: hfi->mode = HFI_INTRA_REFRESH_CYCLIC; break; case HAL_INTRA_REFRESH_CYCLIC_ADAPTIVE: hfi->mode = HFI_INTRA_REFRESH_CYCLIC_ADAPTIVE; break; case HAL_INTRA_REFRESH_RANDOM: hfi->mode = HFI_INTRA_REFRESH_RANDOM; break; default: dprintk(VIDC_ERR, "Invalid intra refresh setting: %#x\n", prop->mode); break; } hfi->air_mbs = prop->air_mbs; hfi->air_ref = prop->air_ref; hfi->cir_mbs = prop->cir_mbs; pkt->size += sizeof(u32) + sizeof(struct hfi_intra_refresh); break; } case HAL_PARAM_VENC_MULTI_SLICE_CONTROL: { struct hfi_multi_slice_control *hfi; struct hal_multi_slice_control *prop = (struct hal_multi_slice_control *) pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_MULTI_SLICE_CONTROL; hfi = (struct hfi_multi_slice_control *) &pkt->rg_property_data[1]; switch (prop->multi_slice) { case HAL_MULTI_SLICE_OFF: hfi->multi_slice = HFI_MULTI_SLICE_OFF; break; case HAL_MULTI_SLICE_GOB: hfi->multi_slice = HFI_MULTI_SLICE_GOB; break; case HAL_MULTI_SLICE_BY_MB_COUNT: hfi->multi_slice = HFI_MULTI_SLICE_BY_MB_COUNT; break; case HAL_MULTI_SLICE_BY_BYTE_COUNT: hfi->multi_slice = HFI_MULTI_SLICE_BY_BYTE_COUNT; break; default: dprintk(VIDC_ERR, "Invalid slice settings: %#x\n", prop->multi_slice); break; } hfi->slice_size = prop->slice_size; pkt->size += sizeof(u32) + sizeof(struct hfi_multi_slice_control); break; } case HAL_PARAM_INDEX_EXTRADATA: { struct hfi_index_extradata_config *hfi; struct hal_extradata_enable *extra = pdata; int id = 0; pkt->rg_property_data[0] = get_hfi_extradata_index(extra->index); hfi = (struct hfi_index_extradata_config *) &pkt->rg_property_data[1]; hfi->enable = extra->enable; id = get_hfi_extradata_id(extra->index); if (id) hfi->index_extra_data_id = id; else { dprintk(VIDC_WARN, "Failed to find extradata id: %d\n", id); rc = -EINVAL; } pkt->size += sizeof(u32) + sizeof(struct hfi_index_extradata_config); break; } case HAL_PARAM_VENC_SLICE_DELIVERY_MODE: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_PARAM_VENC_SLICE_DELIVERY_MODE, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) + sizeof(struct hfi_enable); break; } case HAL_PARAM_VENC_H264_VUI_TIMING_INFO: { struct hfi_h264_vui_timing_info *hfi; struct hal_h264_vui_timing_info *timing_info = pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_H264_VUI_TIMING_INFO; hfi = (struct hfi_h264_vui_timing_info *)&pkt-> rg_property_data[1]; hfi->enable = timing_info->enable; hfi->fixed_frame_rate = timing_info->fixed_frame_rate; hfi->time_scale = timing_info->time_scale; pkt->size += sizeof(u32) + sizeof(struct hfi_h264_vui_timing_info); break; } case HAL_CONFIG_VPE_DEINTERLACE: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_CONFIG_VPE_DEINTERLACE, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) + sizeof(struct hfi_enable); break; } case HAL_PARAM_VENC_H264_GENERATE_AUDNAL: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_PARAM_VENC_H264_GENERATE_AUDNAL, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) + sizeof(struct hfi_enable); break; } case HAL_PARAM_BUFFER_ALLOC_MODE: { u32 buffer_type; u32 buffer_mode; struct hfi_buffer_alloc_mode *hfi; struct hal_buffer_alloc_mode *alloc_info = pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_BUFFER_ALLOC_MODE; hfi = (struct hfi_buffer_alloc_mode *) &pkt->rg_property_data[1]; buffer_type = get_hfi_buffer(alloc_info->buffer_type); if (buffer_type) hfi->buffer_type = buffer_type; else return -EINVAL; buffer_mode = get_hfi_buf_mode(alloc_info->buffer_mode); if (buffer_mode) hfi->buffer_mode = buffer_mode; else return -EINVAL; pkt->size += sizeof(u32) + sizeof(struct hfi_buffer_alloc_mode); break; } case HAL_PARAM_VDEC_FRAME_ASSEMBLY: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_PARAM_VDEC_FRAME_ASSEMBLY, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) + sizeof(struct hfi_enable); break; } case HAL_PARAM_VENC_H264_VUI_BITSTREAM_RESTRC: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_PARAM_VENC_H264_VUI_BITSTREAM_RESTRC, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) + sizeof(struct hfi_enable); break; } case HAL_PARAM_VENC_PRESERVE_TEXT_QUALITY: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_PARAM_VENC_PRESERVE_TEXT_QUALITY, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) + sizeof(struct hfi_enable); break; } case HAL_PARAM_VDEC_SCS_THRESHOLD: { struct hfi_scs_threshold *hfi; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VDEC_SCS_THRESHOLD; hfi = (struct hfi_scs_threshold *) &pkt->rg_property_data[1]; hfi->threshold_value = ((struct hal_scs_threshold *) pdata)->threshold_value; pkt->size += sizeof(u32) + sizeof(struct hfi_scs_threshold); break; } case HAL_PARAM_MVC_BUFFER_LAYOUT: { struct hfi_mvc_buffer_layout_descp_type *hfi; struct hal_mvc_buffer_layout *layout_info = pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_MVC_BUFFER_LAYOUT; hfi = (struct hfi_mvc_buffer_layout_descp_type *) &pkt->rg_property_data[1]; hfi->layout_type = get_hfi_layout(layout_info->layout_type); hfi->bright_view_first = layout_info->bright_view_first; hfi->ngap = layout_info->ngap; pkt->size += sizeof(u32) + sizeof(struct hfi_mvc_buffer_layout_descp_type); break; } case HAL_PARAM_VENC_LTRMODE: { struct hfi_ltr_mode *hfi; struct hal_ltr_mode *hal = pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_LTRMODE; hfi = (struct hfi_ltr_mode *) &pkt->rg_property_data[1]; hfi->ltr_mode = get_hfi_ltr_mode(hal->mode); hfi->ltr_count = hal->count; hfi->trust_mode = hal->trust_mode; pkt->size += sizeof(u32) + sizeof(struct hfi_ltr_mode); break; } case HAL_CONFIG_VENC_USELTRFRAME: { struct hfi_ltr_use *hfi; struct hal_ltr_use *hal = pdata; pkt->rg_property_data[0] = HFI_PROPERTY_CONFIG_VENC_USELTRFRAME; hfi = (struct hfi_ltr_use *) &pkt->rg_property_data[1]; hfi->frames = hal->frames; hfi->ref_ltr = hal->ref_ltr; hfi->use_constrnt = hal->use_constraint; pkt->size += sizeof(u32) + sizeof(struct hfi_ltr_use); break; } case HAL_CONFIG_VENC_MARKLTRFRAME: { struct hfi_ltr_mark *hfi; struct hal_ltr_mark *hal = pdata; pkt->rg_property_data[0] = HFI_PROPERTY_CONFIG_VENC_MARKLTRFRAME; hfi = (struct hfi_ltr_mark *) &pkt->rg_property_data[1]; hfi->mark_frame = hal->mark_frame; pkt->size += sizeof(u32) + sizeof(struct hfi_ltr_mark); break; } case HAL_PARAM_VENC_HIER_P_MAX_ENH_LAYERS: { pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_HIER_P_MAX_NUM_ENH_LAYER; pkt->rg_property_data[1] = *(u32 *)pdata; pkt->size += sizeof(u32) * 2; break; } case HAL_CONFIG_VENC_HIER_P_NUM_FRAMES: { pkt->rg_property_data[0] = HFI_PROPERTY_CONFIG_VENC_HIER_P_ENH_LAYER; pkt->rg_property_data[1] = *(u32 *)pdata; pkt->size += sizeof(u32) * 2; break; } case HAL_PARAM_VENC_DISABLE_RC_TIMESTAMP: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_PARAM_VENC_DISABLE_RC_TIMESTAMP, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) + sizeof(struct hfi_enable); break; } case HAL_PARAM_VENC_ENABLE_INITIAL_QP: { struct hfi_initial_quantization *hfi; struct hal_initial_quantization *quant = pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_INITIAL_QP; hfi = (struct hfi_initial_quantization *) &pkt->rg_property_data[1]; hfi->init_qp_enable = quant->init_qp_enable; hfi->qp_i = quant->qpi; hfi->qp_p = quant->qpp; hfi->qp_b = quant->qpb; pkt->size += sizeof(u32) + sizeof(struct hfi_initial_quantization); break; } case HAL_PARAM_VPE_COLOR_SPACE_CONVERSION: { struct hfi_vpe_color_space_conversion *hfi = NULL; struct hal_vpe_color_space_conversion *hal = pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VPE_COLOR_SPACE_CONVERSION; hfi = (struct hfi_vpe_color_space_conversion *) &pkt->rg_property_data[1]; memcpy(hfi->csc_matrix, hal->csc_matrix, sizeof(hfi->csc_matrix)); memcpy(hfi->csc_bias, hal->csc_bias, sizeof(hfi->csc_bias)); memcpy(hfi->csc_limit, hal->csc_limit, sizeof(hfi->csc_limit)); pkt->size += sizeof(u32) + sizeof(struct hfi_vpe_color_space_conversion); break; } case HAL_PARAM_VENC_VPX_ERROR_RESILIENCE_MODE: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_PARAM_VENC_VPX_ERROR_RESILIENCE_MODE, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) + sizeof(struct hfi_enable); break; } case HAL_PARAM_VENC_H264_NAL_SVC_EXT: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_PARAM_VENC_H264_NAL_SVC_EXT, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) + sizeof(struct hfi_enable); break; } case HAL_CONFIG_VENC_PERF_MODE: { u32 hfi_perf_mode = 0; enum hal_perf_mode hal_perf_mode = *(enum hal_perf_mode *)pdata; switch (hal_perf_mode) { case HAL_PERF_MODE_POWER_SAVE: hfi_perf_mode = HFI_VENC_PERFMODE_POWER_SAVE; break; case HAL_PERF_MODE_POWER_MAX_QUALITY: hfi_perf_mode = HFI_VENC_PERFMODE_MAX_QUALITY; break; default: return -ENOTSUPP; } pkt->rg_property_data[0] = HFI_PROPERTY_CONFIG_VENC_PERF_MODE; pkt->rg_property_data[1] = hfi_perf_mode; pkt->size += sizeof(u32) * 2; break; } case HAL_PARAM_VENC_HIER_B_MAX_ENH_LAYERS: { pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_HIER_B_MAX_NUM_ENH_LAYER; pkt->rg_property_data[1] = *(u32 *)pdata; pkt->size += sizeof(u32) * 2; break; } case HAL_PARAM_VDEC_NON_SECURE_OUTPUT2: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_PARAM_VDEC_NONCP_OUTPUT2, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) + sizeof(struct hfi_enable); break; } case HAL_PARAM_VENC_HIER_P_HYBRID_MODE: { pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_HIER_P_HYBRID_MODE; pkt->rg_property_data[1] = ((struct hfi_hybrid_hierp *)pdata)->layers; pkt->size += sizeof(u32) + sizeof(struct hfi_hybrid_hierp); break; } case HAL_PARAM_VENC_MBI_STATISTICS_MODE: { pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_MBI_DUMPING; pkt->rg_property_data[1] = hal_to_hfi_type( HAL_PARAM_VENC_MBI_STATISTICS_MODE, *(u32 *)pdata); pkt->size += sizeof(u32) * 2; break; } case HAL_CONFIG_VENC_FRAME_QP: { pkt->rg_property_data[0] = HFI_PROPERTY_CONFIG_VENC_FRAME_QP; pkt->rg_property_data[1] = *(u32 *)pdata; pkt->size += sizeof(u32) * 2; break; } case HAL_CONFIG_VENC_BASELAYER_PRIORITYID: { pkt->rg_property_data[0] = HFI_PROPERTY_CONFIG_VENC_BASELAYER_PRIORITYID; pkt->rg_property_data[1] = *(u32 *)pdata; pkt->size += sizeof(u32) * 2; break; } case HAL_PROPERTY_PARAM_VENC_ASPECT_RATIO: { struct hfi_aspect_ratio *hfi = NULL; struct hal_aspect_ratio *hal = pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_ASPECT_RATIO; hfi = (struct hfi_aspect_ratio *) &pkt->rg_property_data[1]; memcpy(hfi, hal, sizeof(struct hfi_aspect_ratio)); pkt->size += sizeof(u32) + sizeof(struct hfi_aspect_ratio); break; } case HAL_PARAM_VENC_BITRATE_TYPE: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_PARAM_VENC_BITRATE_TYPE, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) + sizeof(struct hfi_enable); break; } /* FOLLOWING PROPERTIES ARE NOT IMPLEMENTED IN CORE YET */ case HAL_CONFIG_BUFFER_REQUIREMENTS: case HAL_CONFIG_PRIORITY: case HAL_CONFIG_BATCH_INFO: case HAL_PARAM_METADATA_PASS_THROUGH: case HAL_SYS_IDLE_INDICATOR: case HAL_PARAM_UNCOMPRESSED_FORMAT_SUPPORTED: case HAL_PARAM_INTERLACE_FORMAT_SUPPORTED: case HAL_PARAM_CHROMA_SITE: case HAL_PARAM_PROPERTIES_SUPPORTED: case HAL_PARAM_PROFILE_LEVEL_SUPPORTED: case HAL_PARAM_CAPABILITY_SUPPORTED: case HAL_PARAM_NAL_STREAM_FORMAT_SUPPORTED: case HAL_PARAM_MULTI_VIEW_FORMAT: case HAL_PARAM_MAX_SEQUENCE_HEADER_SIZE: case HAL_PARAM_CODEC_SUPPORTED: case HAL_PARAM_VDEC_MULTI_VIEW_SELECT: case HAL_PARAM_VDEC_MB_QUANTIZATION: case HAL_PARAM_VDEC_NUM_CONCEALED_MB: case HAL_PARAM_VDEC_H264_ENTROPY_SWITCHING: case HAL_PARAM_VENC_MPEG4_DATA_PARTITIONING: case HAL_CONFIG_BUFFER_COUNT_ACTUAL: case HAL_CONFIG_VDEC_MULTI_STREAM: case HAL_PARAM_VENC_MULTI_SLICE_INFO: case HAL_CONFIG_VENC_TIMESTAMP_SCALE: case HAL_PARAM_BUFFER_SIZE_MINIMUM: default: dprintk(VIDC_ERR, "DEFAULT: Calling %#x\n", ptype); rc = -ENOTSUPP; break; } return rc; } static int get_hfi_ssr_type(enum hal_ssr_trigger_type type) { int rc = HFI_TEST_SSR_HW_WDOG_IRQ; switch (type) { case SSR_ERR_FATAL: rc = HFI_TEST_SSR_SW_ERR_FATAL; break; case SSR_SW_DIV_BY_ZERO: rc = HFI_TEST_SSR_SW_DIV_BY_ZERO; break; case SSR_HW_WDOG_IRQ: rc = HFI_TEST_SSR_HW_WDOG_IRQ; break; default: dprintk(VIDC_WARN, "SSR trigger type not recognized, using WDOG.\n"); } return rc; } int create_pkt_ssr_cmd(enum hal_ssr_trigger_type type, struct hfi_cmd_sys_test_ssr_packet *pkt) { if (!pkt) { dprintk(VIDC_ERR, "Invalid params, device: %p\n", pkt); return -EINVAL; } pkt->size = sizeof(struct hfi_cmd_sys_test_ssr_packet); pkt->packet_type = HFI_CMD_SYS_TEST_SSR; pkt->trigger_type = get_hfi_ssr_type(type); return 0; } int create_pkt_cmd_sys_image_version( struct hfi_cmd_sys_get_property_packet *pkt) { if (!pkt) { dprintk(VIDC_ERR, "%s invalid param :%p\n", __func__, pkt); return -EINVAL; } pkt->size = sizeof(struct hfi_cmd_sys_get_property_packet); pkt->packet_type = HFI_CMD_SYS_GET_PROPERTY; pkt->num_properties = 1; pkt->rg_property_data[0] = HFI_PROPERTY_SYS_IMAGE_VERSION; return 0; } static int create_3x_pkt_cmd_session_set_property( struct hfi_cmd_session_set_property_packet *pkt, struct hal_session *session, enum hal_property ptype, void *pdata) { int rc = 0; if (!pkt || !session || !pdata) return -EINVAL; pkt->size = sizeof(struct hfi_cmd_session_set_property_packet); pkt->packet_type = HFI_CMD_SESSION_SET_PROPERTY; pkt->session_id = hash32_ptr(session); pkt->num_properties = 1; /* * Any session set property which is different in 3XX packetization * should be added as a new case below. All unchanged session set * properties will be handled in the default case. */ switch (ptype) { case HAL_PARAM_VDEC_MULTI_STREAM: { u32 buffer_type; struct hfi_3x_multi_stream *hfi; struct hal_multi_stream *prop = (struct hal_multi_stream *) pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VDEC_MULTI_STREAM; hfi = (struct hfi_3x_multi_stream *) &pkt->rg_property_data[1]; buffer_type = get_hfi_buffer(prop->buffer_type); if (buffer_type) hfi->buffer_type = buffer_type; else return -EINVAL; hfi->enable = prop->enable; pkt->size += sizeof(u32) + sizeof(struct hfi_3x_multi_stream); break; } case HAL_PARAM_VENC_INTRA_REFRESH: { struct hfi_3x_intra_refresh *hfi; struct hal_intra_refresh *prop = (struct hal_intra_refresh *) pdata; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_INTRA_REFRESH; hfi = (struct hfi_3x_intra_refresh *) &pkt->rg_property_data[1]; switch (prop->mode) { case HAL_INTRA_REFRESH_NONE: hfi->mode = HFI_INTRA_REFRESH_NONE; break; case HAL_INTRA_REFRESH_ADAPTIVE: hfi->mode = HFI_INTRA_REFRESH_ADAPTIVE; break; case HAL_INTRA_REFRESH_CYCLIC: hfi->mode = HFI_INTRA_REFRESH_CYCLIC; break; case HAL_INTRA_REFRESH_CYCLIC_ADAPTIVE: hfi->mode = HFI_INTRA_REFRESH_CYCLIC_ADAPTIVE; break; case HAL_INTRA_REFRESH_RANDOM: hfi->mode = HFI_INTRA_REFRESH_RANDOM; break; default: dprintk(VIDC_ERR, "Invalid intra refresh setting: %d\n", prop->mode); break; } hfi->mbs = prop->cir_mbs; pkt->size += sizeof(u32) + sizeof(struct hfi_3x_intra_refresh); break; } case HAL_PARAM_SYNC_BASED_INTERRUPT: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_PARAM_SYNC_BASED_INTERRUPT, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) + sizeof(struct hfi_enable); break; } case HAL_PARAM_VENC_VQZIP_SEI: { create_pkt_enable(pkt->rg_property_data, HFI_PROPERTY_PARAM_VENC_VQZIP_SEI_TYPE, ((struct hal_enable *)pdata)->enable); pkt->size += sizeof(u32) + sizeof(struct hfi_enable); break; } /* Deprecated param on Venus 3xx */ case HAL_PARAM_VDEC_CONTINUE_DATA_TRANSFER: { rc = -ENOTSUPP; break; } case HAL_PARAM_BUFFER_SIZE_MINIMUM: { struct hfi_buffer_size_minimum *hfi; struct hal_buffer_size_minimum *prop = (struct hal_buffer_size_minimum *) pdata; u32 buffer_type; pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_BUFFER_SIZE_MINIMUM; hfi = (struct hfi_buffer_size_minimum *) &pkt->rg_property_data[1]; hfi->buffer_size = prop->buffer_size; buffer_type = get_hfi_buffer(prop->buffer_type); if (buffer_type) hfi->buffer_type = buffer_type; else return -EINVAL; pkt->size += sizeof(u32) + sizeof(struct hfi_buffer_count_actual); break; } case HAL_PARAM_VENC_H264_PIC_ORDER_CNT: { pkt->rg_property_data[0] = HFI_PROPERTY_PARAM_VENC_H264_PICORDER_CNT_TYPE; pkt->rg_property_data[1] = *(u32 *)pdata; pkt->size += sizeof(u32) * 2; break; } default: rc = create_pkt_cmd_session_set_property(pkt, session, ptype, pdata); } return rc; } int create_pkt_cmd_session_sync_process( struct hfi_cmd_session_sync_process_packet *pkt, struct hal_session *session) { if (!pkt || !session) return -EINVAL; *pkt = (struct hfi_cmd_session_sync_process_packet) {0}; pkt->size = sizeof(*pkt); pkt->packet_type = HFI_CMD_SESSION_SYNC; pkt->session_id = hash32_ptr(session); pkt->sync_id = 0; return 0; } static struct hfi_packetization_ops hfi_default = { .sys_init = create_pkt_cmd_sys_init, .sys_pc_prep = create_pkt_cmd_sys_pc_prep, .sys_idle_indicator = create_pkt_cmd_sys_idle_indicator, .sys_power_control = create_pkt_cmd_sys_power_control, .sys_set_resource = create_pkt_cmd_sys_set_resource, .sys_debug_config = create_pkt_cmd_sys_debug_config, .sys_coverage_config = create_pkt_cmd_sys_coverage_config, .sys_release_resource = create_pkt_cmd_sys_release_resource, .sys_ping = create_pkt_cmd_sys_ping, .sys_image_version = create_pkt_cmd_sys_image_version, .ssr_cmd = create_pkt_ssr_cmd, .session_init = create_pkt_cmd_sys_session_init, .session_cmd = create_pkt_cmd_session_cmd, .session_set_buffers = create_pkt_cmd_session_set_buffers, .session_release_buffers = create_pkt_cmd_session_release_buffers, .session_etb_decoder = create_pkt_cmd_session_etb_decoder, .session_etb_encoder = create_pkt_cmd_session_etb_encoder, .session_ftb = create_pkt_cmd_session_ftb, .session_parse_seq_header = create_pkt_cmd_session_parse_seq_header, .session_get_seq_hdr = create_pkt_cmd_session_get_seq_hdr, .session_get_buf_req = create_pkt_cmd_session_get_buf_req, .session_flush = create_pkt_cmd_session_flush, .session_get_property = create_pkt_cmd_session_get_property, .session_set_property = create_pkt_cmd_session_set_property, }; struct hfi_packetization_ops *get_venus_3x_ops(void) { static struct hfi_packetization_ops hfi_venus_3x; hfi_venus_3x = hfi_default; /* Override new HFI functions for HFI_PACKETIZATION_3XX here. */ hfi_venus_3x.session_set_property = create_3x_pkt_cmd_session_set_property; hfi_venus_3x.session_get_property = create_3x_pkt_cmd_session_get_property; hfi_venus_3x.session_cmd = create_3x_pkt_cmd_session_cmd; hfi_venus_3x.session_sync_process = create_pkt_cmd_session_sync_process; return &hfi_venus_3x; } struct hfi_packetization_ops *hfi_get_pkt_ops_handle( enum hfi_packetization_type type) { dprintk(VIDC_DBG, "%s selected\n", type == HFI_PACKETIZATION_LEGACY ? "legacy packetization" : type == HFI_PACKETIZATION_3XX ? "3xx packetization" : "Unknown hfi"); switch (type) { case HFI_PACKETIZATION_LEGACY: return &hfi_default; case HFI_PACKETIZATION_3XX: return get_venus_3x_ops(); } return NULL; }