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android / platform / external / libavc / 2ee0c1bced131ffb06d1b430b08a202cd3a52005 / . / encoder / ih264e_api.c
blob: c46134d6da3f99f9800cbcef6634b3cb45ae77fb [file] [log] [blame]
/******************************************************************************
*
* Copyright (C) 2015 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at:
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
*****************************************************************************
* Originally developed and contributed by Ittiam Systems Pvt. Ltd, Bangalore
*/
/**
*******************************************************************************
* @file
* ih264e_api.c
*
* @brief
* Contains api function definitions for H264 encoder
*
* @author
* ittiam
*
* @par List of Functions:
* - api_check_struct_sanity()
* - ih264e_codec_update_config()
* - ih264e_set_default_params()
* - ih264e_init()
* - ih264e_get_num_rec()
* - ih264e_fill_num_mem_rec()
* - ih264e_init_mem_rec()
* - ih264e_retrieve_memrec()
* - ih264e_set_flush_mode()
* - ih264e_get_buf_info()
* - ih264e_set_dimensions()
* - ih264e_set_frame_rate()
* - ih264e_set_bit_rate()
* - ih264e_set_frame_type()
* - ih264e_set_qp()
* - ih264e_set_enc_mode()
* - ih264e_set_vbv_params()
* - ih264_set_air_params()
* - ih264_set_me_params()
* - ih264_set_ipe_params()
* - ih264_set_gop_params()
* - ih264_set_profile_params()
* - ih264_set_deblock_params()
* - ih264e_set_num_cores()
* - ih264e_reset()
* - ih264e_ctl()
* - ih264e_api_function()
*
* @remarks
* None
*
*******************************************************************************
*/
/*****************************************************************************/
/* File Includes */
/*****************************************************************************/
/* System Include Files */
#include <stdio.h>
#include <stddef.h>
#include <stdlib.h>
#include <string.h>
#include <assert.h>
/* User Include Files */
#include "ih264e_config.h"
#include "ih264_typedefs.h"
#include "ih264_size_defs.h"
#include "iv2.h"
#include "ive2.h"
#include "ih264e.h"
#include "ithread.h"
#include "ih264_debug.h"
#include "ih264_defs.h"
#include "ih264_error.h"
#include "ih264_structs.h"
#include "ih264_trans_quant_itrans_iquant.h"
#include "ih264_inter_pred_filters.h"
#include "ih264_mem_fns.h"
#include "ih264_padding.h"
#include "ih264_intra_pred_filters.h"
#include "ih264_deblk_edge_filters.h"
#include "ih264_cabac_tables.h"
#include "ih264_macros.h"
#include "ih264e_defs.h"
#include "ih264e_globals.h"
#include "ih264_buf_mgr.h"
#include "irc_mem_req_and_acq.h"
#include "irc_cntrl_param.h"
#include "irc_frame_info_collector.h"
#include "irc_rate_control_api.h"
#include "ih264e_time_stamp.h"
#include "ih264e_modify_frm_rate.h"
#include "ih264e_rate_control.h"
#include "ih264e_error.h"
#include "ih264e_bitstream.h"
#include "ime_defs.h"
#include "ime_distortion_metrics.h"
#include "ime_structs.h"
#include "ih264e_cabac_structs.h"
#include "ih264e_structs.h"
#include "ih264e_utils.h"
#include "ih264e_core_coding.h"
#include "ih264_platform_macros.h"
#include "ih264e_platform_macros.h"
#include "ih264_list.h"
#include "ih264_dpb_mgr.h"
#include "ih264_cavlc_tables.h"
#include "ih264e_cavlc.h"
#include "ih264_common_tables.h"
#include "ih264e_master.h"
#include "ih264e_fmt_conv.h"
#include "ih264e_version.h"
/*****************************************************************************/
/* Function Declarations */
/*****************************************************************************/
WORD32 ih264e_get_rate_control_mem_tab(void *pv_rate_control,
iv_mem_rec_t *ps_mem,
ITT_FUNC_TYPE_E e_func_type);
/*****************************************************************************/
/* Function Definitions */
/*****************************************************************************/
/**
*******************************************************************************
*
* @brief
* Used to test arguments for corresponding API call
*
* @par Description:
* For each command the arguments are validated
*
* @param[in] ps_handle
* Codec handle at API level
*
* @param[in] pv_api_ip
* Pointer to input structure
*
* @param[out] pv_api_op
* Pointer to output structure
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static IV_STATUS_T api_check_struct_sanity(iv_obj_t *ps_handle,
void *pv_api_ip,
void *pv_api_op)
{
/* api call */
WORD32 command = IV_CMD_NA;
/* input structure expected by the api call */
UWORD32 *pu4_api_ip = pv_api_ip;
/* output structure expected by the api call */
UWORD32 *pu4_api_op = pv_api_op;
/* temp var */
WORD32 i, j;
if (NULL == pv_api_op || NULL == pv_api_ip)
{
return (IV_FAIL);
}
/* get command */
command = pu4_api_ip[1];
/* set error code */
pu4_api_op[1] = 0;
/* error checks on handle */
switch (command)
{
case IV_CMD_GET_NUM_MEM_REC:
case IV_CMD_FILL_NUM_MEM_REC:
break;
case IV_CMD_INIT:
if (ps_handle == NULL)
{
*(pu4_api_op + 1) |= 1 << IVE_UNSUPPORTEDPARAM;
*(pu4_api_op + 1) |= IVE_ERR_HANDLE_NULL;
return IV_FAIL;
}
if (ps_handle->u4_size != sizeof(iv_obj_t))
{
*(pu4_api_op + 1) |= 1 << IVE_UNSUPPORTEDPARAM;
*(pu4_api_op + 1) |= IVE_ERR_HANDLE_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
break;
case IVE_CMD_QUEUE_INPUT:
case IVE_CMD_QUEUE_OUTPUT:
case IVE_CMD_DEQUEUE_OUTPUT:
case IVE_CMD_GET_RECON:
case IV_CMD_RETRIEVE_MEMREC:
case IVE_CMD_VIDEO_CTL:
case IVE_CMD_VIDEO_ENCODE:
if (ps_handle == NULL)
{
*(pu4_api_op + 1) |= 1 << IVE_UNSUPPORTEDPARAM;
*(pu4_api_op + 1) |= IVE_ERR_HANDLE_NULL;
return IV_FAIL;
}
if (ps_handle->u4_size != sizeof(iv_obj_t))
{
*(pu4_api_op + 1) |= 1 << IVE_UNSUPPORTEDPARAM;
*(pu4_api_op + 1) |= IVE_ERR_HANDLE_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_handle->pv_fxns != ih264e_api_function)
{
*(pu4_api_op + 1) |= 1 << IVE_UNSUPPORTEDPARAM;
*(pu4_api_op + 1) |= IVE_ERR_API_FUNCTION_PTR_NULL;
return IV_FAIL;
}
if (ps_handle->pv_codec_handle == NULL)
{
*(pu4_api_op + 1) |= 1 << IVE_UNSUPPORTEDPARAM;
*(pu4_api_op + 1) |= IVE_ERR_INVALID_CODEC_HANDLE;
return IV_FAIL;
}
break;
default:
*(pu4_api_op + 1) |= 1 << IVE_UNSUPPORTEDPARAM;
*(pu4_api_op + 1) |= IVE_ERR_INVALID_API_CMD;
return IV_FAIL;
}
/* error checks on input output structures */
switch (command)
{
case IV_CMD_GET_NUM_MEM_REC:
{
ih264e_num_mem_rec_ip_t *ps_ip = pv_api_ip;
ih264e_num_mem_rec_op_t *ps_op = pv_api_op;
ps_op->s_ive_op.u4_error_code = 0;
if (ps_ip->s_ive_ip.u4_size != sizeof(ih264e_num_mem_rec_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_GET_MEM_REC_API_STRUCT_SIZE_INCORRECT;
return (IV_FAIL);
}
if (ps_op->s_ive_op.u4_size != sizeof(ih264e_num_mem_rec_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_GET_MEM_REC_API_STRUCT_SIZE_INCORRECT;
return (IV_FAIL);
}
break;
}
case IV_CMD_FILL_NUM_MEM_REC:
{
ih264e_fill_mem_rec_ip_t *ps_ip = pv_api_ip;
ih264e_fill_mem_rec_op_t *ps_op = pv_api_op;
iv_mem_rec_t *ps_mem_rec = NULL;
WORD32 max_wd = ALIGN16(ps_ip->s_ive_ip.u4_max_wd);
WORD32 max_ht = ALIGN16(ps_ip->s_ive_ip.u4_max_ht);
ps_op->s_ive_op.u4_error_code = 0;
if (ps_ip->s_ive_ip.u4_size != sizeof(ih264e_fill_mem_rec_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_FILL_MEM_REC_API_STRUCT_SIZE_INCORRECT;
return (IV_FAIL);
}
if (ps_op->s_ive_op.u4_size != sizeof(ih264e_fill_mem_rec_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_FILL_MEM_REC_API_STRUCT_SIZE_INCORRECT;
return (IV_FAIL);
}
if (max_wd < MIN_WD || max_wd > MAX_WD)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |= IH264E_WIDTH_NOT_SUPPORTED;
return (IV_FAIL);
}
if (max_ht < MIN_HT || max_ht > MAX_HT)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |= IH264E_HEIGHT_NOT_SUPPORTED;
return (IV_FAIL);
}
/* verify number of mem rec ptr */
if (NULL == ps_ip->s_ive_ip.ps_mem_rec)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_FILL_NUM_MEM_RECS_POINTER_NULL;
return (IV_FAIL);
}
/* verify number of mem records */
if (ps_ip->s_ive_ip.u4_num_mem_rec != MEM_REC_CNT)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_NUM_MEM_REC_NOT_SUFFICIENT;
return IV_FAIL;
}
/* check mem records sizes are correct */
ps_mem_rec = ps_ip->s_ive_ip.ps_mem_rec;
for (i = 0; i < MEM_REC_CNT; i++)
{
if (ps_mem_rec[i].u4_size != sizeof(iv_mem_rec_t))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_MEM_REC_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
}
break;
}
case IV_CMD_INIT:
{
ih264e_init_ip_t *ps_ip = pv_api_ip;
ih264e_init_op_t *ps_op = pv_api_op;
iv_mem_rec_t *ps_mem_rec = NULL;
WORD32 max_wd = ALIGN16(ps_ip->s_ive_ip.u4_max_wd);
WORD32 max_ht = ALIGN16(ps_ip->s_ive_ip.u4_max_ht);
ps_op->s_ive_op.u4_error_code = 0;
if (ps_ip->s_ive_ip.u4_size != sizeof(ih264e_init_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_INIT_API_STRUCT_SIZE_INCORRECT;
return (IV_FAIL);
}
if (ps_op->s_ive_op.u4_size != sizeof(ih264e_init_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_INIT_API_STRUCT_SIZE_INCORRECT;
return (IV_FAIL);
}
if (max_wd < MIN_WD || max_wd > MAX_WD)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |= IH264E_WIDTH_NOT_SUPPORTED;
return (IV_FAIL);
}
if (max_ht < MIN_HT || max_ht > MAX_HT)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |= IH264E_HEIGHT_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_max_ref_cnt > MAX_REF_PIC_CNT ||
ps_ip->s_ive_ip.u4_max_ref_cnt < MIN_REF_PIC_CNT)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |= IH264E_NUM_REF_UNSUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_max_reorder_cnt != 0)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |= IH264E_NUM_REORDER_UNSUPPORTED;
return (IV_FAIL);
}
if ((ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_10)
&& (ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_1B)
&& (ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_11)
&& (ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_12)
&& (ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_13)
&& (ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_20)
&& (ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_21)
&& (ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_22)
&& (ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_30)
&& (ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_31)
&& (ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_32)
&& (ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_40)
&& (ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_41)
&& (ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_42)
&& (ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_50)
&& (ps_ip->s_ive_ip.u4_max_level != IH264_LEVEL_51))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_CODEC_LEVEL_NOT_SUPPORTED;
return (IV_FAIL);
}
if ((ps_ip->s_ive_ip.e_inp_color_fmt != IV_YUV_420P)
&& (ps_ip->s_ive_ip.e_inp_color_fmt != IV_YUV_422ILE)
&& (ps_ip->s_ive_ip.e_inp_color_fmt != IV_YUV_420SP_UV)
&& (ps_ip->s_ive_ip.e_inp_color_fmt != IV_YUV_420SP_VU))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INPUT_CHROMA_FORMAT_NOT_SUPPORTED;
return (IV_FAIL);
}
if ((ps_ip->s_ive_ip.e_recon_color_fmt != IV_YUV_420P)
&& (ps_ip->s_ive_ip.e_recon_color_fmt != IV_YUV_420SP_UV)
&& (ps_ip->s_ive_ip.e_recon_color_fmt != IV_YUV_420SP_VU))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_RECON_CHROMA_FORMAT_NOT_SUPPORTED;
return (IV_FAIL);
}
if ((ps_ip->s_ive_ip.e_rc_mode != IVE_RC_NONE)
&& (ps_ip->s_ive_ip.e_rc_mode != IVE_RC_STORAGE)
&& (ps_ip->s_ive_ip.e_rc_mode != IVE_RC_CBR_NON_LOW_DELAY))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_RATE_CONTROL_MODE_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_max_framerate > DEFAULT_MAX_FRAMERATE)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_FRAME_RATE_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_max_bitrate > DEFAULT_MAX_BITRATE)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |= IH264E_BITRATE_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_num_bframes > MAX_NUM_BFRAMES)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |= IH264E_BFRAMES_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_num_bframes
&& (ps_ip->s_ive_ip.u4_max_ref_cnt < 2))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |= IH264E_BFRAMES_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.e_content_type != IV_PROGRESSIVE)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_CONTENT_TYPE_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_max_srch_rng_x > DEFAULT_MAX_SRCH_RANGE_X)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_HORIZONTAL_SEARCH_RANGE_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_max_srch_rng_y > DEFAULT_MAX_SRCH_RANGE_Y)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_VERTICAL_SEARCH_RANGE_NOT_SUPPORTED;
return (IV_FAIL);
}
if ((ps_ip->s_ive_ip.e_slice_mode != IVE_SLICE_MODE_NONE)
&& (ps_ip->s_ive_ip.e_slice_mode != IVE_SLICE_MODE_BLOCKS))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_SLICE_TYPE_INPUT_INVALID;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.e_slice_mode == IVE_SLICE_MODE_BLOCKS)
{
if (ps_ip->s_ive_ip.u4_slice_param == 0
|| ps_ip->s_ive_ip.u4_slice_param > ((UWORD32)max_ht >> 4))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_SLICE_PARAM_INPUT_INVALID;
return (IV_FAIL);
}
}
if (NULL == ps_ip->s_ive_ip.ps_mem_rec)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_FILL_NUM_MEM_RECS_POINTER_NULL;
return (IV_FAIL);
}
/* verify number of mem records */
if (ps_ip->s_ive_ip.u4_num_mem_rec != MEM_REC_CNT)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_NUM_MEM_REC_NOT_SUFFICIENT;
return (IV_FAIL);
}
ps_mem_rec = ps_ip->s_ive_ip.ps_mem_rec;
/* check memrecords sizes are correct */
for (i = 0; i <((WORD32)ps_ip->s_ive_ip.u4_num_mem_rec); i++)
{
if (ps_mem_rec[i].u4_size != sizeof(iv_mem_rec_t))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_MEM_REC_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
/* check memrecords pointers are not NULL */
if (ps_mem_rec[i].pv_base == NULL)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_MEM_REC_BASE_POINTER_NULL;
return IV_FAIL;
}
}
/* verify memtabs for overlapping regions */
{
void *start[MEM_REC_CNT];
void *end[MEM_REC_CNT];
start[0] = (ps_mem_rec[0].pv_base);
end[0] = ((UWORD8 *) ps_mem_rec[0].pv_base)
+ ps_mem_rec[0].u4_mem_size - 1;
for (i = 1; i < MEM_REC_CNT; i++)
{
/* This array is populated to check memtab overlap */
start[i] = (ps_mem_rec[i].pv_base);
end[i] = ((UWORD8 *) ps_mem_rec[i].pv_base)
+ ps_mem_rec[i].u4_mem_size - 1;
for (j = 0; j < i; j++)
{
if ((start[i] >= start[j]) && (start[i] <= end[j]))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_MEM_REC_OVERLAP_ERR;
return IV_FAIL;
}
if ((end[i] >= start[j]) && (end[i] <= end[j]))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_MEM_REC_OVERLAP_ERR;
return IV_FAIL;
}
if ((start[i] < start[j]) && (end[i] > end[j]))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_MEM_REC_OVERLAP_ERR;
return IV_FAIL;
}
}
}
}
/* re-validate mem records with init config */
{
/* mem records */
iv_mem_rec_t s_mem_rec_ittiam_api[MEM_REC_CNT];
/* api interface structs */
ih264e_fill_mem_rec_ip_t s_ip;
ih264e_fill_mem_rec_op_t s_op;
/* error status */
IV_STATUS_T e_status;
/* temp var */
WORD32 i;
s_ip.s_ive_ip.u4_size = sizeof(ih264e_fill_mem_rec_ip_t);
s_op.s_ive_op.u4_size = sizeof(ih264e_fill_mem_rec_op_t);
s_ip.s_ive_ip.e_cmd = IV_CMD_FILL_NUM_MEM_REC;
s_ip.s_ive_ip.ps_mem_rec = s_mem_rec_ittiam_api;
s_ip.s_ive_ip.u4_max_wd = max_wd;
s_ip.s_ive_ip.u4_max_ht = max_ht;
s_ip.s_ive_ip.u4_num_mem_rec = ps_ip->s_ive_ip.u4_num_mem_rec;
s_ip.s_ive_ip.u4_max_level = ps_ip->s_ive_ip.u4_max_level;
s_ip.s_ive_ip.u4_max_ref_cnt = ps_ip->s_ive_ip.u4_max_ref_cnt;
s_ip.s_ive_ip.u4_max_reorder_cnt =
ps_ip->s_ive_ip.u4_max_reorder_cnt;
s_ip.s_ive_ip.e_color_format = ps_ip->s_ive_ip.e_inp_color_fmt;
s_ip.s_ive_ip.u4_max_srch_rng_x =
ps_ip->s_ive_ip.u4_max_srch_rng_x;
s_ip.s_ive_ip.u4_max_srch_rng_y =
ps_ip->s_ive_ip.u4_max_srch_rng_y;
for (i = 0; i < MEM_REC_CNT; i++)
{
s_mem_rec_ittiam_api[i].u4_size = sizeof(iv_mem_rec_t);
}
/* fill mem records */
e_status = ih264e_api_function(NULL, (void *) &s_ip,
(void *) &s_op);
if (IV_FAIL == e_status)
{
ps_op->s_ive_op.u4_error_code = s_op.s_ive_op.u4_error_code;
return (IV_FAIL);
}
/* verify mem records */
for (i = 0; i < MEM_REC_CNT; i++)
{
if (ps_mem_rec[i].u4_mem_size
< s_mem_rec_ittiam_api[i].u4_mem_size)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_MEM_REC_INSUFFICIENT_SIZE;
return IV_FAIL;
}
if (ps_mem_rec[i].u4_mem_alignment
!= s_mem_rec_ittiam_api[i].u4_mem_alignment)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_MEM_REC_ALIGNMENT_ERR;
return IV_FAIL;
}
if (ps_mem_rec[i].e_mem_type
!= s_mem_rec_ittiam_api[i].e_mem_type)
{
UWORD32 check = IV_SUCCESS;
UWORD32 diff = s_mem_rec_ittiam_api[i].e_mem_type
- ps_mem_rec[i].e_mem_type;
if ((ps_mem_rec[i].e_mem_type
<= IV_EXTERNAL_CACHEABLE_SCRATCH_MEM)
&& (s_mem_rec_ittiam_api[i].e_mem_type
>= IV_INTERNAL_NONCACHEABLE_PERSISTENT_MEM))
{
check = IV_FAIL;
}
if (3 != (s_mem_rec_ittiam_api[i].e_mem_type % 4))
{
/* It is not IV_EXTERNAL_NONCACHEABLE_PERSISTENT_MEM or
* IV_EXTERNAL_CACHEABLE_PERSISTENT_MEM */
if ((diff < 1) || (diff > 3))
{
/* Difference between 1 and 3 is okay for all cases other than the
* two filtered with the MOD condition above */
check = IV_FAIL;
}
}
else
{
if (diff == 1)
{
/* This particular case is when codec asked for External Persistent,
* but got Internal Scratch */
check = IV_FAIL;
}
if ((diff != 2) && (diff != 3))
{
check = IV_FAIL;
}
}
if (check == IV_FAIL)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_MEM_REC_INCORRECT_TYPE;
return IV_FAIL;
}
}
}
}
break;
}
case IVE_CMD_QUEUE_INPUT:
case IVE_CMD_QUEUE_OUTPUT:
case IVE_CMD_DEQUEUE_OUTPUT:
case IVE_CMD_GET_RECON:
break;
case IV_CMD_RETRIEVE_MEMREC:
{
ih264e_retrieve_mem_rec_ip_t *ps_ip = pv_api_ip;
ih264e_retrieve_mem_rec_op_t *ps_op = pv_api_op;
iv_mem_rec_t *ps_mem_rec = NULL;
ps_op->s_ive_op.u4_error_code = 0;
if (ps_ip->s_ive_ip.u4_size != sizeof(ih264e_retrieve_mem_rec_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_RETRIEVE_MEM_REC_API_STRUCT_SIZE_INCORRECT;
return (IV_FAIL);
}
if (ps_op->s_ive_op.u4_size != sizeof(ih264e_retrieve_mem_rec_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_RETRIEVE_MEM_REC_API_STRUCT_SIZE_INCORRECT;
return (IV_FAIL);
}
if (NULL == ps_ip->s_ive_ip.ps_mem_rec)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_FILL_NUM_MEM_RECS_POINTER_NULL;
return (IV_FAIL);
}
ps_mem_rec = ps_ip->s_ive_ip.ps_mem_rec;
/* check memrecords sizes are correct */
for (i = 0; i < MEM_REC_CNT; i++)
{
if (ps_mem_rec[i].u4_size != sizeof(iv_mem_rec_t))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_MEM_REC_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
}
break;
}
case IVE_CMD_VIDEO_ENCODE:
{
ih264e_video_encode_ip_t *ps_ip = pv_api_ip;
ih264e_video_encode_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size != sizeof(ih264e_video_encode_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_ENCODE_API_STRUCT_SIZE_INCORRECT;
return (IV_FAIL);
}
if (ps_op->s_ive_op.u4_size != sizeof(ih264e_video_encode_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_ENCODE_API_STRUCT_SIZE_INCORRECT;
return (IV_FAIL);
}
break;
}
case IVE_CMD_VIDEO_CTL:
{
/* ptr to input structure */
WORD32 *pu4_ptr_cmd = pv_api_ip;
/* sub command */
WORD32 sub_command = pu4_ptr_cmd[2];
switch (sub_command)
{
case IVE_CMD_CTL_SETDEFAULT:
{
ih264e_ctl_setdefault_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_setdefault_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_setdefault_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_SETDEF_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_setdefault_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_SETDEF_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
break;
}
case IVE_CMD_CTL_GETBUFINFO:
{
codec_t *ps_codec = (codec_t *) (ps_handle->pv_codec_handle);
ih264e_ctl_getbufinfo_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_getbufinfo_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_getbufinfo_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_GETBUFINFO_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_getbufinfo_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_GETBUFINFO_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_ip->s_ive_ip.u4_max_wd < MIN_WD)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_WIDTH_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_max_wd > ps_codec->s_cfg.u4_max_wd)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_WIDTH_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_max_ht < MIN_HT)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_HEIGHT_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_max_ht > ps_codec->s_cfg.u4_max_ht)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_HEIGHT_NOT_SUPPORTED;
return (IV_FAIL);
}
if ((ps_ip->s_ive_ip.e_inp_color_fmt != IV_YUV_420P)
&& (ps_ip->s_ive_ip.e_inp_color_fmt != IV_YUV_422ILE)
&& (ps_ip->s_ive_ip.e_inp_color_fmt != IV_YUV_420SP_UV)
&& (ps_ip->s_ive_ip.e_inp_color_fmt != IV_YUV_420SP_VU))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INPUT_CHROMA_FORMAT_NOT_SUPPORTED;
return (IV_FAIL);
}
break;
}
case IVE_CMD_CTL_GETVERSION:
{
ih264e_ctl_getversioninfo_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_getversioninfo_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_getversioninfo_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_GETVERSION_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_getversioninfo_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_GETVERSION_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_ip->s_ive_ip.pu1_version == NULL)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_CTL_GET_VERSION_BUFFER_IS_NULL;
return IV_FAIL;
}
break;
}
case IVE_CMD_CTL_FLUSH:
{
ih264e_ctl_flush_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_flush_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_flush_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_FLUSH_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_flush_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_FLUSH_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
break;
}
case IVE_CMD_CTL_RESET:
{
ih264e_ctl_reset_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_reset_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_reset_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_RESET_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_reset_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_RESET_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
break;
}
case IVE_CMD_CTL_SET_NUM_CORES:
{
ih264e_ctl_set_num_cores_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_num_cores_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_set_num_cores_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_SETCORES_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_set_num_cores_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_SETCORES_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.u4_num_cores < 1)
|| (ps_ip->s_ive_ip.u4_num_cores > MAX_NUM_CORES))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_NUM_CORES;
return IV_FAIL;
}
break;
}
case IVE_CMD_CTL_SET_DIMENSIONS:
{
codec_t *ps_codec = (codec_t *) (ps_handle->pv_codec_handle);
ih264e_ctl_set_dimensions_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_dimensions_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_set_dimensions_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_SETDIM_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_set_dimensions_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_SETDIM_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_ip->s_ive_ip.u4_wd < MIN_WD)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_WIDTH_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_wd > ps_codec->s_cfg.u4_max_wd)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_WIDTH_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_ht < MIN_HT)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_HEIGHT_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_ht > ps_codec->s_cfg.u4_max_ht)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_HEIGHT_NOT_SUPPORTED;
return (IV_FAIL);
}
break;
}
case IVE_CMD_CTL_SET_FRAMERATE:
{
ih264e_ctl_set_frame_rate_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_frame_rate_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_set_frame_rate_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_SETFRAMERATE_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_set_frame_rate_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_SETFRAMERATE_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (((ps_ip->s_ive_ip.u4_src_frame_rate * 1000) > DEFAULT_MAX_FRAMERATE)
|| ((ps_ip->s_ive_ip.u4_tgt_frame_rate * 1000) > DEFAULT_MAX_FRAMERATE))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_FRAME_RATE_NOT_SUPPORTED;
return (IV_FAIL);
}
if ((ps_ip->s_ive_ip.u4_src_frame_rate == 0)
|| (ps_ip->s_ive_ip.u4_tgt_frame_rate == 0))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_FRAME_RATE_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_tgt_frame_rate
> ps_ip->s_ive_ip.u4_src_frame_rate)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_TGT_FRAME_RATE_EXCEEDS_SRC_FRAME_RATE;
return (IV_FAIL);
}
break;
}
case IVE_CMD_CTL_SET_BITRATE:
{
ih264e_ctl_set_bitrate_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_bitrate_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_set_bitrate_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_SETBITRATE_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_set_bitrate_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_SETBITRATE_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.u4_target_bitrate > DEFAULT_MAX_BITRATE)
|| (ps_ip->s_ive_ip.u4_target_bitrate == 0))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_BITRATE_NOT_SUPPORTED;
return (IV_FAIL);
}
break;
}
case IVE_CMD_CTL_SET_FRAMETYPE:
{
ih264e_ctl_set_frame_type_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_frame_type_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_set_frame_type_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_SETFRAMETYPE_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_set_frame_type_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_SETFRAMETYPE_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.e_frame_type != IV_NA_FRAME)
&& (ps_ip->s_ive_ip.e_frame_type != IV_I_FRAME)
&& (ps_ip->s_ive_ip.e_frame_type != IV_P_FRAME)
&& (ps_ip->s_ive_ip.e_frame_type != IV_IDR_FRAME))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_FORCE_FRAME_INPUT;
return IV_FAIL;
}
break;
}
case IVE_CMD_CTL_SET_ME_PARAMS:
{
codec_t *ps_codec = (codec_t *) (ps_handle->pv_codec_handle);
ih264e_ctl_set_me_params_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_me_params_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_set_me_params_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_SETMEPARAMS_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_set_me_params_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_SETMEPARAMS_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.u4_me_speed_preset != FULL_SRCH)
&& (ps_ip->s_ive_ip.u4_me_speed_preset != DMND_SRCH)
&& (ps_ip->s_ive_ip.u4_me_speed_preset != HEX_SRCH))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_ME_SPEED_PRESET;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.u4_enable_hpel != 0)
&& (ps_ip->s_ive_ip.u4_enable_hpel != 1))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_HALFPEL_OPTION;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.u4_enable_qpel != 0)
&& (ps_ip->s_ive_ip.u4_enable_qpel != 1))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_QPEL_OPTION;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.u4_enable_fast_sad != 0)
&& (ps_ip->s_ive_ip.u4_enable_fast_sad != 1))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_FAST_SAD_OPTION;
return IV_FAIL;
}
if (ps_ip->s_ive_ip.u4_enable_alt_ref > 255)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_ALT_REF_OPTION;
return IV_FAIL;
}
if (ps_ip->s_ive_ip.u4_srch_rng_x
> ps_codec->s_cfg.u4_max_srch_rng_x)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_HORIZONTAL_SEARCH_RANGE_NOT_SUPPORTED;
return (IV_FAIL);
}
if (ps_ip->s_ive_ip.u4_srch_rng_y
> ps_codec->s_cfg.u4_max_srch_rng_y)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_VERTICAL_SEARCH_RANGE_NOT_SUPPORTED;
return (IV_FAIL);
}
break;
}
case IVE_CMD_CTL_SET_IPE_PARAMS:
{
ih264e_ctl_set_ipe_params_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_ipe_params_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_set_ipe_params_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_SETIPEPARAMS_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_set_ipe_params_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_SETIPEPARAMS_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.u4_enable_intra_4x4 != 0)
&& (ps_ip->s_ive_ip.u4_enable_intra_4x4 != 1))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_INTRA4x4_OPTION;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.u4_enc_speed_preset != IVE_CONFIG)
&& (ps_ip->s_ive_ip.u4_enc_speed_preset != IVE_SLOWEST)
&& (ps_ip->s_ive_ip.u4_enc_speed_preset != IVE_NORMAL)
&& (ps_ip->s_ive_ip.u4_enc_speed_preset != IVE_FAST)
&& (ps_ip->s_ive_ip.u4_enc_speed_preset != IVE_HIGH_SPEED)
&& (ps_ip->s_ive_ip.u4_enc_speed_preset != IVE_FASTEST))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_ENC_SPEED_PRESET;
return IV_FAIL;
}
break;
}
case IVE_CMD_CTL_SET_GOP_PARAMS:
{
ih264e_ctl_set_gop_params_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_gop_params_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_set_gop_params_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_SETGOPPARAMS_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_set_gop_params_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_SETGOPPARAMS_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.u4_i_frm_interval < DEFAULT_MIN_INTRA_FRAME_RATE)
|| (ps_ip->s_ive_ip.u4_i_frm_interval > DEFAULT_MAX_INTRA_FRAME_RATE))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_INTRA_FRAME_INTERVAL;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.u4_idr_frm_interval < DEFAULT_MIN_INTRA_FRAME_RATE)
|| (ps_ip->s_ive_ip.u4_idr_frm_interval > DEFAULT_MAX_INTRA_FRAME_RATE))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_IDR_FRAME_INTERVAL;
return IV_FAIL;
}
break;
}
case IVE_CMD_CTL_SET_DEBLOCK_PARAMS:
{
ih264e_ctl_set_deblock_params_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_deblock_params_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_set_deblock_params_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_SETDEBLKPARAMS_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_set_deblock_params_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_SETDEBLKPARAMS_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.u4_disable_deblock_level != DISABLE_DEBLK_LEVEL_0)
&& (ps_ip->s_ive_ip.u4_disable_deblock_level != DISABLE_DEBLK_LEVEL_2)
&& (ps_ip->s_ive_ip.u4_disable_deblock_level != DISABLE_DEBLK_LEVEL_3)
&& (ps_ip->s_ive_ip.u4_disable_deblock_level != DISABLE_DEBLK_LEVEL_4))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_DEBLOCKING_TYPE_INPUT;
return IV_FAIL;
}
break;
}
case IVE_CMD_CTL_SET_QP:
{
ih264e_ctl_set_qp_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_qp_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_set_qp_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_SETQPPARAMS_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_set_qp_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_SETQPPARAMS_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.u4_i_qp_max > MAX_H264_QP)
|| (ps_ip->s_ive_ip.u4_p_qp_max > MAX_H264_QP)
|| (ps_ip->s_ive_ip.u4_b_qp_max > MAX_H264_QP))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_MAX_FRAME_QP;
return IV_FAIL;
}
/* We donot support QP < 4 */
if ((ps_ip->s_ive_ip.u4_i_qp_min < 4)
|| (ps_ip->s_ive_ip.u4_p_qp_min < 4)
|| (ps_ip->s_ive_ip.u4_b_qp_min < 4)
|| (ps_ip->s_ive_ip.u4_i_qp_min > ps_ip->s_ive_ip.u4_i_qp_max)
|| (ps_ip->s_ive_ip.u4_p_qp_min > ps_ip->s_ive_ip.u4_p_qp_max)
|| (ps_ip->s_ive_ip.u4_b_qp_min > ps_ip->s_ive_ip.u4_b_qp_max))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_MIN_FRAME_QP;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.u4_i_qp > ps_ip->s_ive_ip.u4_i_qp_max)
|| (ps_ip->s_ive_ip.u4_p_qp > ps_ip->s_ive_ip.u4_p_qp_max)
|| (ps_ip->s_ive_ip.u4_b_qp > ps_ip->s_ive_ip.u4_b_qp_max))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |= IH264E_INVALID_INIT_QP;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.u4_i_qp < ps_ip->s_ive_ip.u4_i_qp_min)
|| (ps_ip->s_ive_ip.u4_p_qp < ps_ip->s_ive_ip.u4_p_qp_min)
|| (ps_ip->s_ive_ip.u4_b_qp < ps_ip->s_ive_ip.u4_b_qp_min))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |= IH264E_INVALID_INIT_QP;
return IV_FAIL;
}
break;
}
case IVE_CMD_CTL_SET_ENC_MODE:
{
ih264e_ctl_set_enc_mode_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_enc_mode_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_set_enc_mode_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_SETENCMODE_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_set_enc_mode_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_SETENCMODE_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.e_enc_mode != IVE_ENC_MODE_HEADER)
&& (ps_ip->s_ive_ip.e_enc_mode != IVE_ENC_MODE_PICTURE))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_ENC_OPERATION_MODE;
return IV_FAIL;
}
break;
}
case IVE_CMD_CTL_SET_VBV_PARAMS:
{
ih264e_ctl_set_vbv_params_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_vbv_params_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_set_vbv_params_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_SETVBVPARAMS_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_set_vbv_params_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_SETVBVPARAMS_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.u4_vbv_buffer_delay < DEFAULT_MIN_BUFFER_DELAY)
|| (ps_ip->s_ive_ip.u4_vbv_buffer_delay > DEFAULT_MAX_BUFFER_DELAY))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_BUFFER_DELAY;
return IV_FAIL;
}
break;
}
case IVE_CMD_CTL_SET_AIR_PARAMS:
{
ih264e_ctl_set_air_params_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_air_params_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_set_air_params_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_SETAIRPARAMS_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_set_air_params_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_SETAIRPARAMS_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if ((ps_ip->s_ive_ip.e_air_mode != IVE_AIR_MODE_NONE)
&& (ps_ip->s_ive_ip.e_air_mode != IVE_AIR_MODE_CYCLIC)
&& (ps_ip->s_ive_ip.e_air_mode != IVE_AIR_MODE_RANDOM))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_AIR_MODE;
return IV_FAIL;
}
if (ps_ip->s_ive_ip.u4_air_refresh_period == 0)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_AIR_REFRESH_PERIOD;
return IV_FAIL;
}
break;
}
case IVE_CMD_CTL_SET_PROFILE_PARAMS:
{
ih264e_ctl_set_profile_params_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_profile_params_op_t *ps_op = pv_api_op;
if (ps_ip->s_ive_ip.u4_size
!= sizeof(ih264e_ctl_set_profile_params_ip_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_IP_CTL_SETPROFILE_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_op->s_ive_op.u4_size
!= sizeof(ih264e_ctl_set_profile_params_op_t))
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IVE_ERR_OP_CTL_SETPROFILE_API_STRUCT_SIZE_INCORRECT;
return IV_FAIL;
}
if (ps_ip->s_ive_ip.e_profile != IV_PROFILE_BASE &&
ps_ip->s_ive_ip.e_profile != IV_PROFILE_MAIN)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_PROFILE_NOT_SUPPORTED;
return IV_FAIL;
}
if (ps_ip->s_ive_ip.u4_entropy_coding_mode > 1)
{
ps_op->s_ive_op.u4_error_code |= 1
<< IVE_UNSUPPORTEDPARAM;
ps_op->s_ive_op.u4_error_code |=
IH264E_INVALID_ENTROPY_CODING_MODE;
return IV_FAIL;
}
break;
}
default:
*(pu4_api_op + 1) |= 1 << IVE_UNSUPPORTEDPARAM;
*(pu4_api_op + 1) |= IVE_ERR_INVALID_API_SUB_CMD;
return IV_FAIL;
}
break;
}
default:
*(pu4_api_op + 1) |= 1 << IVE_UNSUPPORTEDPARAM;
*(pu4_api_op + 1) |= IVE_ERR_INVALID_API_CMD;
return IV_FAIL;
}
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief update encoder configuration parameters
*
* @par Description:
* updates encoder configuration parameters from the given config set.
* Initialize/reinitialize codec parameters according to new configurations.
*
* @param[in] ps_codec
* Pointer to codec context
*
* @param[in] ps_cfg
* Pointer to config param set
*
* @remarks none
*
*******************************************************************************
*/
IH264E_ERROR_T ih264e_codec_update_config(codec_t *ps_codec,
cfg_params_t *ps_cfg)
{
/* config params */
cfg_params_t *ps_curr_cfg = &ps_codec->s_cfg;
/* error status */
IH264E_ERROR_T err = IH264E_SUCCESS;
/* temp var */
UWORD32 u4_init_rc = 0;
/***********************/
/* UPDATE CODEC CONFIG */
/***********************/
if (ps_cfg->e_cmd == IVE_CMD_CTL_SET_DIMENSIONS)
{
UWORD32 wd_aln = ALIGN16(ps_cfg->u4_wd);
UWORD32 ht_aln = ALIGN16(ps_cfg->u4_ht);
if (ps_curr_cfg->u4_wd != wd_aln || ps_curr_cfg->u4_ht != ht_aln
|| ps_curr_cfg->u4_disp_wd != ps_cfg->u4_disp_wd
|| ps_curr_cfg->u4_disp_ht != ps_cfg->u4_disp_ht)
{
ps_curr_cfg->u4_wd = wd_aln;
ps_curr_cfg->u4_ht = ht_aln;
ps_curr_cfg->u4_disp_wd = ps_cfg->u4_disp_wd;
ps_curr_cfg->u4_disp_ht = ps_cfg->u4_disp_ht;
ps_curr_cfg->i4_wd_mbs = ps_curr_cfg->u4_wd >> 4;
ps_curr_cfg->i4_ht_mbs = ps_curr_cfg->u4_ht >> 4;
ps_codec->i4_rec_strd = ALIGN16(ps_cfg->u4_wd) + PAD_WD;
/* If number of MBs in a frame changes the air map also changes.
* Hence recompute air map also reset air pic cnt */
if (ps_codec->s_cfg.e_air_mode != IVE_AIR_MODE_NONE)
{
/* re-init the air map */
ih264e_init_air_map(ps_codec);
/* reset air counter */
ps_codec->i4_air_pic_cnt = -1;
}
/* initialize mv bank buffer manager */
err = ih264e_mv_buf_mgr_add_bufs(ps_codec);
if (err != IH264E_SUCCESS)
return err;
/* initialize ref bank buffer manager */
err = ih264e_pic_buf_mgr_add_bufs(ps_codec);
if (err != IH264E_SUCCESS)
return err;
/* since dimension changed, start new sequence by forcing IDR */
ps_codec->force_curr_frame_type = IV_IDR_FRAME;
/* in case dimension changes, we need to reinitialize RC as the
* old model shall not fit further */
u4_init_rc = 1;
/* when the dimension changes, the header needs to be regenerated */
ps_codec->i4_gen_header = 1;
}
}
else if (ps_cfg->e_cmd == IVE_CMD_CTL_SET_FRAMERATE)
{
/* temp var */
UWORD32 u4_src_ticks, u4_tgt_ticks;
u4_src_ticks = ih264e_frame_time_get_src_ticks(
ps_codec->s_rate_control.pps_frame_time);
u4_tgt_ticks = ih264e_frame_time_get_tgt_ticks(
ps_codec->s_rate_control.pps_frame_time);
/* Change frame rate */
if (ps_codec->s_cfg.u4_src_frame_rate
!= ps_cfg->u4_src_frame_rate * 1000)
{
ps_codec->s_cfg.u4_src_frame_rate = ps_cfg->u4_src_frame_rate
* 1000;
ih264e_frame_time_update_src_frame_rate(
ps_codec->s_rate_control.pps_frame_time,
ps_codec->s_cfg.u4_src_frame_rate);
ih264_time_stamp_update_frame_rate(
ps_codec->s_rate_control.pps_time_stamp,
ps_codec->s_cfg.u4_src_frame_rate);
irc_change_frame_rate(ps_codec->s_rate_control.pps_rate_control_api,
ps_codec->s_cfg.u4_src_frame_rate,
u4_src_ticks, u4_tgt_ticks);
}
if (ps_codec->s_cfg.u4_tgt_frame_rate
!= ps_cfg->u4_tgt_frame_rate * 1000)
{
ps_codec->s_cfg.u4_tgt_frame_rate = ps_cfg->u4_tgt_frame_rate
* 1000;
ih264e_frame_time_update_tgt_frame_rate(
ps_codec->s_rate_control.pps_frame_time,
ps_codec->s_cfg.u4_tgt_frame_rate);
irc_change_frame_rate(ps_codec->s_rate_control.pps_rate_control_api,
ps_codec->s_cfg.u4_src_frame_rate,
u4_src_ticks, u4_tgt_ticks);
irc_change_frm_rate_for_bit_alloc(
ps_codec->s_rate_control.pps_rate_control_api,
ps_codec->s_cfg.u4_tgt_frame_rate);
}
}
else if (ps_cfg->e_cmd == IVE_CMD_CTL_SET_BITRATE)
{
if (ps_curr_cfg->u4_target_bitrate != ps_cfg->u4_target_bitrate)
{
if (IVE_RC_NONE != ps_curr_cfg->e_rc_mode)
irc_change_avg_bit_rate(
ps_codec->s_rate_control.pps_rate_control_api,
ps_cfg->u4_target_bitrate);
ps_curr_cfg->u4_target_bitrate = ps_cfg->u4_target_bitrate;
}
}
else if (ps_cfg->e_cmd == IVE_CMD_CTL_SET_FRAMETYPE)
{
switch (ps_cfg->e_frame_type)
{
case IV_I_FRAME:
ps_codec->force_curr_frame_type = IV_I_FRAME;
break;
case IV_IDR_FRAME:
ps_codec->force_curr_frame_type = IV_IDR_FRAME;
break;
case IV_P_FRAME:
default:
break;
}
}
else if (ps_cfg->e_cmd == IVE_CMD_CTL_SET_ME_PARAMS)
{
if (ps_curr_cfg->u4_enc_speed_preset == IVE_CONFIG)
{
ps_codec->s_cfg.u4_enable_hpel = ps_cfg->u4_enable_hpel;
ps_codec->s_cfg.u4_enable_fast_sad = ps_cfg->u4_enable_fast_sad;
ps_codec->s_cfg.u4_me_speed_preset = ps_cfg->u4_me_speed_preset;
ps_codec->s_cfg.u4_enable_qpel = ps_cfg->u4_enable_qpel;
}
else if (ps_curr_cfg->u4_enc_speed_preset == IVE_FASTEST)
{
ps_codec->s_cfg.u4_enable_fast_sad = ps_cfg->u4_enable_fast_sad;
}
ps_codec->s_cfg.u4_srch_rng_x = ps_cfg->u4_srch_rng_x;
ps_codec->s_cfg.u4_srch_rng_y = ps_cfg->u4_srch_rng_y;
if (ps_codec->s_cfg.u4_enable_alt_ref != ps_cfg->u4_enable_alt_ref)
{
ps_codec->s_cfg.u4_enable_alt_ref = ps_cfg->u4_enable_alt_ref;
ps_codec->u4_is_curr_frm_ref = 1;
}
}
else if (ps_cfg->e_cmd == IVE_CMD_CTL_SET_IPE_PARAMS)
{
ps_curr_cfg->u4_enc_speed_preset = ps_cfg->u4_enc_speed_preset;
if (ps_curr_cfg->u4_enc_speed_preset == IVE_SLOWEST)
{/* high quality */
/* enable diamond search */
ps_curr_cfg->u4_me_speed_preset = DMND_SRCH;
ps_curr_cfg->u4_enable_fast_sad = 0;
/* disable intra 4x4 */
ps_curr_cfg->u4_enable_intra_4x4 = 1;
ps_codec->luma_energy_compaction[1] =
ih264e_code_luma_intra_macroblock_4x4_rdopt_on;
/* sub pel off */
ps_curr_cfg->u4_enable_hpel = 1;
/* deblocking off */
ps_curr_cfg->u4_disable_deblock_level = DISABLE_DEBLK_LEVEL_0;
/* disabled intra inter gating in Inter slices */
ps_codec->u4_inter_gate = 0;
}
else if (ps_curr_cfg->u4_enc_speed_preset == IVE_NORMAL)
{/* normal */
/* enable diamond search */
ps_curr_cfg->u4_me_speed_preset = DMND_SRCH;
ps_curr_cfg->u4_enable_fast_sad = 0;
/* disable intra 4x4 */
ps_curr_cfg->u4_enable_intra_4x4 = 1;
/* sub pel off */
ps_curr_cfg->u4_enable_hpel = 1;
/* deblocking off */
ps_curr_cfg->u4_disable_deblock_level = DISABLE_DEBLK_LEVEL_0;
/* disabled intra inter gating in Inter slices */
ps_codec->u4_inter_gate = 0;
}
else if (ps_curr_cfg->u4_enc_speed_preset == IVE_FAST)
{/* normal */
/* enable diamond search */
ps_curr_cfg->u4_me_speed_preset = DMND_SRCH;
ps_curr_cfg->u4_enable_fast_sad = 0;
/* disable intra 4x4 */
ps_curr_cfg->u4_enable_intra_4x4 = 0;
/* sub pel off */
ps_curr_cfg->u4_enable_hpel = 1;
/* deblocking off */
ps_curr_cfg->u4_disable_deblock_level = DISABLE_DEBLK_LEVEL_0;
/* disabled intra inter gating in Inter slices */
ps_codec->u4_inter_gate = 1;
}
else if (ps_curr_cfg->u4_enc_speed_preset == IVE_HIGH_SPEED)
{/* fast */
/* enable diamond search */
ps_curr_cfg->u4_me_speed_preset = DMND_SRCH;
ps_curr_cfg->u4_enable_fast_sad = 0;
/* disable intra 4x4 */
ps_curr_cfg->u4_enable_intra_4x4 = 0;
/* sub pel off */
ps_curr_cfg->u4_enable_hpel = 0;
/* deblocking off */
ps_curr_cfg->u4_disable_deblock_level = DISABLE_DEBLK_LEVEL_4;
/* disabled intra inter gating in Inter slices */
ps_codec->u4_inter_gate = 0;
}
else if (ps_curr_cfg->u4_enc_speed_preset == IVE_FASTEST)
{/* fastest */
/* enable diamond search */
ps_curr_cfg->u4_me_speed_preset = DMND_SRCH;
//u4_num_layers = 4;
/* disable intra 4x4 */
ps_curr_cfg->u4_enable_intra_4x4 = 0;
/* sub pel off */
ps_curr_cfg->u4_enable_hpel = 0;
/* deblocking off */
ps_curr_cfg->u4_disable_deblock_level = DISABLE_DEBLK_LEVEL_4;
/* disabled intra inter gating in Inter slices */
ps_codec->u4_inter_gate = 1;
}
else if (ps_curr_cfg->u4_enc_speed_preset == IVE_CONFIG)
{
ps_curr_cfg->u4_enable_intra_4x4 = ps_cfg->u4_enable_intra_4x4;
}
}
else if (ps_cfg->e_cmd == IVE_CMD_CTL_SET_GOP_PARAMS)
{
if (ps_curr_cfg->u4_i_frm_interval != ps_cfg->u4_i_frm_interval)
{
ps_curr_cfg->u4_i_frm_interval = ps_cfg->u4_i_frm_interval;
/* reset air counter */
ps_codec->i4_air_pic_cnt = -1;
/* re-init air map */
ih264e_init_air_map(ps_codec);
/*Effect intra frame interval change*/
irc_change_intra_frm_int_call(
ps_codec->s_rate_control.pps_rate_control_api,
ps_curr_cfg->u4_i_frm_interval);
}
ps_curr_cfg->u4_idr_frm_interval = ps_cfg->u4_idr_frm_interval;
}
else if (ps_cfg->e_cmd == IVE_CMD_CTL_SET_DEBLOCK_PARAMS)
{
if (ps_curr_cfg->u4_enc_speed_preset == IVE_CONFIG)
{
ps_curr_cfg->u4_disable_deblock_level =
ps_cfg->u4_disable_deblock_level;
}
}
else if (ps_cfg->e_cmd == IVE_CMD_CTL_SET_QP)
{
UWORD8 au1_init_qp[MAX_PIC_TYPE];
UWORD8 au1_min_max_qp[2 * MAX_PIC_TYPE];
ps_codec->s_cfg.u4_i_qp_max = ps_cfg->u4_i_qp_max;
ps_codec->s_cfg.u4_i_qp_min = ps_cfg->u4_i_qp_min;
ps_codec->s_cfg.u4_i_qp = ps_cfg->u4_i_qp;
ps_codec->s_cfg.u4_p_qp_max = ps_cfg->u4_p_qp_max;
ps_codec->s_cfg.u4_p_qp_min = ps_cfg->u4_p_qp_min;
ps_codec->s_cfg.u4_p_qp = ps_cfg->u4_p_qp;
ps_codec->s_cfg.u4_b_qp_max = ps_cfg->u4_b_qp_max;
ps_codec->s_cfg.u4_b_qp_min = ps_cfg->u4_b_qp_min;
ps_codec->s_cfg.u4_b_qp = ps_cfg->u4_b_qp;
/* update rc lib with modified qp */
au1_init_qp[0] = gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_i_qp];
au1_init_qp[1] = gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_p_qp];
au1_init_qp[2] = gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_b_qp];
irc_change_init_qp(ps_codec->s_rate_control.pps_rate_control_api,
au1_init_qp);
au1_min_max_qp[2 * I_PIC] =
gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_i_qp_min];
au1_min_max_qp[2 * I_PIC + 1] =
gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_i_qp_max];
au1_min_max_qp[2 * P_PIC] =
gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_p_qp_min];
au1_min_max_qp[2 * P_PIC + 1] =
gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_p_qp_max];
au1_min_max_qp[2 * B_PIC] =
gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_b_qp_min];
au1_min_max_qp[2 * B_PIC + 1] =
gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_b_qp_max];
irc_change_min_max_qp(ps_codec->s_rate_control.pps_rate_control_api,
au1_min_max_qp);
}
else if (ps_cfg->e_cmd == IVE_CMD_CTL_SET_ENC_MODE)
{
ps_codec->s_cfg.e_enc_mode = ps_cfg->e_enc_mode;
if (ps_codec->s_cfg.e_enc_mode == IVE_ENC_MODE_HEADER)
{
ps_codec->i4_header_mode = 1;
ps_codec->s_cfg.e_enc_mode = IVE_ENC_MODE_PICTURE;
}
else
{
ps_codec->i4_header_mode = 0;
}
}
else if (ps_cfg->e_cmd == IVE_CMD_CTL_SET_VBV_PARAMS
&& IVE_RC_NONE != ps_codec->s_cfg.e_rc_mode)
{
ps_codec->s_cfg.u4_vbv_buf_size = ps_cfg->u4_vbv_buf_size;
ps_codec->s_cfg.u4_vbv_buffer_delay = ps_cfg->u4_vbv_buffer_delay;
// irc_change_buffer_delay(ps_codec->s_rate_control.pps_rate_control_api, ps_codec->s_cfg.u4_vbv_buffer_delay);
// TODO: remove this when the support for changing buffer dynamically
// is yet to be added.
u4_init_rc = 1;
}
else if (ps_cfg->e_cmd == IVE_CMD_CTL_SET_AIR_PARAMS)
{
if (ps_curr_cfg->e_air_mode != ps_cfg->e_air_mode
|| ps_curr_cfg->u4_air_refresh_period
!= ps_cfg->u4_air_refresh_period)
{
ps_curr_cfg->e_air_mode = ps_cfg->e_air_mode;
ps_curr_cfg->u4_air_refresh_period = ps_cfg->u4_air_refresh_period;
ih264e_init_air_map(ps_codec);
/* reset air counter */
ps_codec->i4_air_pic_cnt = -1;
}
}
else if (ps_cfg->e_cmd == IVE_CMD_CTL_SET_PROFILE_PARAMS)
{
ps_codec->s_cfg.e_profile = ps_cfg->e_profile;
ps_codec->s_cfg.u4_entropy_coding_mode = ps_cfg->u4_entropy_coding_mode;
}
else if (ps_cfg->e_cmd == IVE_CMD_CTL_SET_NUM_CORES)
{
ps_codec->s_cfg.u4_num_cores = ps_cfg->u4_num_cores;
}
/* reset RC model */
if (u4_init_rc)
{
/* init qp */
UWORD8 au1_init_qp[MAX_PIC_TYPE];
/* min max qp */
UWORD8 au1_min_max_qp[2 * MAX_PIC_TYPE];
/* init i,p,b qp */
au1_init_qp[0] = gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_i_qp];
au1_init_qp[1] = gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_p_qp];
au1_init_qp[2] = gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_b_qp];
/* init min max qp */
au1_min_max_qp[2 * I_PIC] =
gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_i_qp_min];
au1_min_max_qp[2 * I_PIC + 1] =
gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_i_qp_max];
au1_min_max_qp[2 * P_PIC] =
gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_p_qp_min];
au1_min_max_qp[2 * P_PIC + 1] =
gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_p_qp_max];
au1_min_max_qp[2 * B_PIC] =
gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_b_qp_min];
au1_min_max_qp[2 * B_PIC + 1] =
gau1_h264_to_mpeg2_qmap[ps_codec->s_cfg.u4_b_qp_max];
/* get rc mode */
switch (ps_codec->s_cfg.e_rc_mode)
{
case IVE_RC_STORAGE:
ps_codec->s_rate_control.e_rc_type = VBR_STORAGE;
break;
case IVE_RC_CBR_NON_LOW_DELAY:
ps_codec->s_rate_control.e_rc_type = CBR_NLDRC;
break;
case IVE_RC_CBR_LOW_DELAY:
ps_codec->s_rate_control.e_rc_type = CBR_LDRC;
break;
case IVE_RC_NONE:
ps_codec->s_rate_control.e_rc_type = CONST_QP;
break;
default:
break;
}
/* init rate control */
ih264e_rc_init(ps_codec->s_rate_control.pps_rate_control_api,
ps_codec->s_rate_control.pps_frame_time,
ps_codec->s_rate_control.pps_time_stamp,
ps_codec->s_rate_control.pps_pd_frm_rate,
ps_codec->s_cfg.u4_max_framerate,
ps_codec->s_cfg.u4_src_frame_rate,
ps_codec->s_cfg.u4_tgt_frame_rate,
ps_codec->s_rate_control.e_rc_type,
ps_codec->s_cfg.u4_target_bitrate,
ps_codec->s_cfg.u4_max_bitrate,
ps_codec->s_cfg.u4_vbv_buffer_delay,
ps_codec->s_cfg.u4_i_frm_interval,
ps_codec->s_cfg.u4_num_bframes + 1, au1_init_qp,
ps_codec->s_cfg.u4_num_bframes + 2, au1_min_max_qp,
ps_codec->s_cfg.u4_max_level);
}
return err;
}
/**
*******************************************************************************
*
* @brief
* Sets default encoder config parameters
*
* @par Description:
* Sets default dynamic parameters. Will be called in ih264e_init() to ensure
* that even if set_params is not called, codec continues to work
*
* @param[in] ps_cfg
* Pointer to encoder config params
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static WORD32 ih264e_set_default_params(cfg_params_t *ps_cfg)
{
WORD32 ret = IV_SUCCESS;
ps_cfg->u4_max_wd = MAX_WD;
ps_cfg->u4_max_ht = MAX_HT;
ps_cfg->u4_max_ref_cnt = MAX_REF_CNT;
ps_cfg->u4_max_reorder_cnt = MAX_REF_CNT;
ps_cfg->u4_max_level = DEFAULT_MAX_LEVEL;
ps_cfg->e_inp_color_fmt = IV_YUV_420SP_UV;
ps_cfg->u4_enable_recon = DEFAULT_RECON_ENABLE;
ps_cfg->e_recon_color_fmt = IV_YUV_420P;
ps_cfg->u4_enc_speed_preset = IVE_FASTEST;
ps_cfg->e_rc_mode = DEFAULT_RC;
ps_cfg->u4_max_framerate = DEFAULT_MAX_FRAMERATE;
ps_cfg->u4_max_bitrate = DEFAULT_MAX_BITRATE;
ps_cfg->u4_num_bframes = DEFAULT_MAX_NUM_BFRAMES;
ps_cfg->e_content_type = IV_PROGRESSIVE;
ps_cfg->u4_max_srch_rng_x = DEFAULT_MAX_SRCH_RANGE_X;
ps_cfg->u4_max_srch_rng_y = DEFAULT_MAX_SRCH_RANGE_Y;
ps_cfg->e_slice_mode = IVE_SLICE_MODE_NONE;
ps_cfg->u4_slice_param = DEFAULT_SLICE_PARAM;
ps_cfg->e_arch = ih264e_default_arch();
ps_cfg->e_soc = SOC_GENERIC;
ps_cfg->u4_disp_wd = MAX_WD;
ps_cfg->u4_disp_ht = MAX_HT;
ps_cfg->u4_wd = MAX_WD;
ps_cfg->u4_ht = MAX_HT;
ps_cfg->u4_src_frame_rate = DEFAULT_SRC_FRAME_RATE;
ps_cfg->u4_tgt_frame_rate = DEFAULT_TGT_FRAME_RATE;
ps_cfg->u4_target_bitrate = DEFAULT_BITRATE;
ps_cfg->e_frame_type = IV_NA_FRAME;
ps_cfg->e_enc_mode = IVE_ENC_MODE_DEFAULT;
ps_cfg->u4_i_qp = DEFAULT_I_QP;
ps_cfg->u4_p_qp = DEFAULT_P_QP;
ps_cfg->u4_b_qp = DEFAULT_B_QP;
ps_cfg->u4_i_qp_min = DEFAULT_QP_MIN;
ps_cfg->u4_i_qp_max = DEFAULT_QP_MAX;
ps_cfg->u4_p_qp_min = DEFAULT_QP_MIN;
ps_cfg->u4_p_qp_max = DEFAULT_QP_MAX;
ps_cfg->u4_b_qp_min = DEFAULT_QP_MIN;
ps_cfg->u4_b_qp_max = DEFAULT_QP_MAX;
ps_cfg->e_air_mode = DEFAULT_AIR_MODE;
ps_cfg->u4_air_refresh_period = DEFAULT_AIR_REFRESH_PERIOD;
ps_cfg->u4_vbv_buffer_delay = DEFAULT_VBV_DELAY;
ps_cfg->u4_vbv_buf_size = DEFAULT_VBV_SIZE;
ps_cfg->u4_num_cores = DEFAULT_NUM_CORES;
ps_cfg->u4_me_speed_preset = DEFAULT_ME_SPEED_PRESET;
ps_cfg->u4_enable_hpel = DEFAULT_HPEL;
ps_cfg->u4_enable_qpel = DEFAULT_QPEL;
ps_cfg->u4_enable_intra_4x4 = DEFAULT_I4;
ps_cfg->u4_enable_intra_8x8 = DEFAULT_I8;
ps_cfg->u4_enable_intra_16x16 = DEFAULT_I16;
ps_cfg->u4_enable_fast_sad = DEFAULT_ENABLE_FAST_SAD;
ps_cfg->u4_enable_satqd = DEFAULT_ENABLE_SATQD;
ps_cfg->i4_min_sad =
(ps_cfg->u4_enable_satqd == DEFAULT_ENABLE_SATQD) ?
DEFAULT_MIN_SAD_ENABLE :
DEFAULT_MIN_SAD_DISABLE;
ps_cfg->u4_srch_rng_x = DEFAULT_SRCH_RNG_X;
ps_cfg->u4_srch_rng_y = DEFAULT_SRCH_RNG_Y;
ps_cfg->u4_i_frm_interval = DEFAULT_I_INTERVAL;
ps_cfg->u4_idr_frm_interval = DEFAULT_IDR_INTERVAL;
ps_cfg->u4_disable_deblock_level = DEFAULT_DISABLE_DEBLK_LEVEL;
ps_cfg->e_profile = DEFAULT_PROFILE;
ps_cfg->u4_timestamp_low = 0;
ps_cfg->u4_timestamp_high = 0;
ps_cfg->u4_is_valid = 1;
ps_cfg->e_cmd = IVE_CMD_CT_NA;
ps_cfg->i4_wd_mbs = ps_cfg->u4_max_wd >> 4;
ps_cfg->i4_ht_mbs = ps_cfg->u4_max_ht >> 4;
ps_cfg->u4_entropy_coding_mode = CAVLC;
ps_cfg->u4_weighted_prediction = 0;
ps_cfg->u4_constrained_intra_pred = 0;
ps_cfg->u4_pic_info_type = 0;
ps_cfg->u4_mb_info_type = 0;
return ret;
}
/**
*******************************************************************************
*
* @brief
* Initialize encoder context. This will be called by init_mem_rec and during
* codec reset
*
* @par Description:
* Initializes the context
*
* @param[in] ps_codec
* Codec context pointer
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static WORD32 ih264e_init(codec_t *ps_codec)
{
/* enc config param set */
cfg_params_t *ps_cfg = &(ps_codec->s_cfg);
/* temp var */
WORD32 i;
/* coded pic count */
ps_codec->i4_poc = 0;
/* Number of API calls to encode are made */
ps_codec->i4_encode_api_call_cnt = -1;
/* Indicates no header has been generated yet */
ps_codec->u4_header_generated = 0;
/* Number of pictures encoded */
ps_codec->i4_pic_cnt = -1;
/* Number of threads created */
ps_codec->i4_proc_thread_cnt = 0;
/* ctl mutex init */
ithread_mutex_init(ps_codec->pv_ctl_mutex);
/* Set encoder chroma format */
ps_codec->e_codec_color_format =
(ps_cfg->e_inp_color_fmt == IV_YUV_420SP_VU) ?
IV_YUV_420SP_VU : IV_YUV_420SP_UV;
/* Number of continuous frames where deblocking was disabled */
ps_codec->i4_disable_deblk_pic_cnt = 0;
/* frame num */
ps_codec->i4_frame_num = 0;
/* set the current frame type to I frame, since we are going to start encoding*/
ps_codec->force_curr_frame_type = IV_NA_FRAME;
/* idr_pic_id */
ps_codec->i4_idr_pic_id = -1;
/* Flush mode */
ps_codec->i4_flush_mode = 0;
/* Encode header mode */
ps_codec->i4_header_mode = 0;
/* Encode generate header */
ps_codec->i4_gen_header = 0;
/* To signal successful completion of init */
ps_codec->i4_init_done = 1;
/* To signal that at least one picture was decoded */
ps_codec->i4_first_pic_done = 0;
/* Reset Codec */
ps_codec->i4_reset_flag = 0;
/* Current error code */
ps_codec->i4_error_code = IH264E_SUCCESS;
/* threshold residue */
ps_codec->u4_thres_resi = 1;
/* inter gating enable */
ps_codec->u4_inter_gate = 0;
/* entropy mutex init */
ithread_mutex_init(ps_codec->pv_entropy_mutex);
/* sps id */
ps_codec->i4_sps_id = 0;
/* sps id */
ps_codec->i4_pps_id = 0;
/* Process thread created status */
memset(ps_codec->ai4_process_thread_created, 0, MAX_PROCESS_THREADS);
/* Number of MBs processed together */
ps_codec->i4_proc_nmb = 8;
/* Previous POC msb */
ps_codec->i4_prev_poc_msb = 0;
/* Previous POC lsb */
ps_codec->i4_prev_poc_lsb = -1;
/* max Previous POC lsb */
ps_codec->i4_max_prev_poc_lsb = -1;
/* sps, pps status */
{
sps_t *ps_sps = ps_codec->ps_sps_base;
pps_t *ps_pps = ps_codec->ps_pps_base;
for (i = 0; i < MAX_SPS_CNT; i++)
{
ps_sps->i1_sps_valid = 0;
ps_sps++;
}
for (i = 0; i < MAX_PPS_CNT; i++)
{
ps_pps->i1_pps_valid = 0;
ps_pps++;
}
}
{
WORD32 max_mb_rows = ps_cfg->i4_ht_mbs;
WORD32 num_jobs = max_mb_rows * MAX_CTXT_SETS;
WORD32 clz;
/* Use next power of two number of entries*/
clz = CLZ(num_jobs);
num_jobs = 1 << (32 - clz);
/* init process jobq */
ps_codec->pv_proc_jobq = ih264_list_init(
ps_codec->pv_proc_jobq_buf,
ps_codec->i4_proc_jobq_buf_size, num_jobs,
sizeof(job_t), 10);
RETURN_IF((ps_codec->pv_proc_jobq == NULL), IV_FAIL);
ih264_list_reset(ps_codec->pv_proc_jobq);
/* init entropy jobq */
ps_codec->pv_entropy_jobq = ih264_list_init(
ps_codec->pv_entropy_jobq_buf,
ps_codec->i4_entropy_jobq_buf_size, num_jobs,
sizeof(job_t), 10);
RETURN_IF((ps_codec->pv_entropy_jobq == NULL), IV_FAIL);
ih264_list_reset(ps_codec->pv_entropy_jobq);
}
/* Update the jobq context to all the threads */
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
ps_codec->as_process[i].pv_proc_jobq = ps_codec->pv_proc_jobq;
ps_codec->as_process[i].pv_entropy_jobq = ps_codec->pv_entropy_jobq;
/* i4_id always stays between 0 and MAX_PROCESS_THREADS */
ps_codec->as_process[i].i4_id =
(i >= MAX_PROCESS_THREADS) ?
(i - MAX_PROCESS_THREADS) : i;
ps_codec->as_process[i].ps_codec = ps_codec;
ps_codec->as_process[i].s_entropy.pv_proc_jobq = ps_codec->pv_proc_jobq;
ps_codec->as_process[i].s_entropy.pv_entropy_jobq =
ps_codec->pv_entropy_jobq;
ps_codec->as_process[i].s_entropy.i4_abs_pic_order_cnt = -1;
}
/* Initialize MV Bank buffer manager */
ps_codec->pv_mv_buf_mgr = ih264_buf_mgr_init(ps_codec->pv_mv_buf_mgr_base);
/* Initialize Picture buffer manager for reference buffers*/
ps_codec->pv_ref_buf_mgr = ih264_buf_mgr_init(
ps_codec->pv_ref_buf_mgr_base);
/* Initialize Picture buffer manager for input buffers*/
ps_codec->pv_inp_buf_mgr = ih264_buf_mgr_init(
ps_codec->pv_inp_buf_mgr_base);
/* Initialize buffer manager for output buffers*/
ps_codec->pv_out_buf_mgr = ih264_buf_mgr_init(
ps_codec->pv_out_buf_mgr_base);
/* buffer cnt in buffer manager */
ps_codec->i4_inp_buf_cnt = 0;
ps_codec->i4_out_buf_cnt = 0;
ps_codec->i4_ref_buf_cnt = 0;
ps_codec->ps_pic_buf = (pic_buf_t *) ps_codec->pv_pic_buf_base;
memset(ps_codec->ps_pic_buf, 0, BUF_MGR_MAX_CNT * sizeof(pic_buf_t));
/* Initialize dpb manager */
ih264_dpb_mgr_init((dpb_mgr_t*) ps_codec->pv_dpb_mgr);
memset(ps_codec->as_ref_set, 0,
sizeof(ref_set_t) * (MAX_DPB_SIZE + MAX_CTXT_SETS));
for (i = 0; i < (MAX_DPB_SIZE + MAX_CTXT_SETS); i++)
{
ps_codec->as_ref_set[i].i4_pic_cnt = -1;
}
/* fn ptr init */
ih264e_init_function_ptr(ps_codec);
/* reset status flags */
for (i = 0; i < MAX_CTXT_SETS; i++)
{
ps_codec->au4_entropy_thread_active[i] = 0;
ps_codec->ai4_pic_cnt[i] = -1;
ps_codec->s_rate_control.pre_encode_skip[i] = 0;
ps_codec->s_rate_control.post_encode_skip[i] = 0;
}
ps_codec->s_rate_control.num_intra_in_prev_frame = 0;
ps_codec->s_rate_control.i4_avg_activity = 0;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Gets number of memory records required by the codec
*
* @par Description:
* Gets codec memory requirements
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @returns status
*
* @remarks
*
*******************************************************************************
*/
static WORD32 ih264e_get_num_rec(void *pv_api_ip, void *pv_api_op)
{
/* api call I/O structures */
ih264e_num_mem_rec_op_t *ps_op = pv_api_op;
UNUSED(pv_api_ip);
ps_op->s_ive_op.u4_num_mem_rec = MEM_REC_CNT;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Fills memory records of the codec
*
* @par Description:
* Fills codec memory requirements
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static WORD32 ih264e_fill_num_mem_rec(void *pv_api_ip, void *pv_api_op)
{
/* api call I/O structures */
ih264e_fill_mem_rec_ip_t *ps_ip = pv_api_ip;
ih264e_fill_mem_rec_op_t *ps_op = pv_api_op;
/* profile / level info */
WORD32 level;
WORD32 num_reorder_frames;
WORD32 num_ref_frames;
/* mem records */
WORD32 no_of_mem_rec;
iv_mem_rec_t *ps_mem_rec_base, *ps_mem_rec;
/* frame dimensions */
WORD32 max_wd_luma, max_ht_luma;
WORD32 max_mb_rows, max_mb_cols, max_mb_cnt;
/* temp var */
WORD32 i;
/* error status */
IV_STATUS_T status = IV_SUCCESS;
num_reorder_frames = ps_ip->s_ive_ip.u4_max_reorder_cnt;
num_ref_frames = ps_ip->s_ive_ip.u4_max_ref_cnt;
/* mem records */
ps_mem_rec_base = ps_ip->s_ive_ip.ps_mem_rec;
no_of_mem_rec = ps_ip->s_ive_ip.u4_num_mem_rec;
/* frame dimensions */
max_ht_luma = ps_ip->s_ive_ip.u4_max_ht;
max_wd_luma = ps_ip->s_ive_ip.u4_max_wd;
max_ht_luma = ALIGN16(max_ht_luma);
max_wd_luma = ALIGN16(max_wd_luma);
max_mb_rows = max_ht_luma / MB_SIZE;
max_mb_cols = max_wd_luma / MB_SIZE;
max_mb_cnt = max_mb_rows * max_mb_cols;
/* profile / level info */
level = ih264e_get_min_level(max_ht_luma, max_wd_luma);
/* validate params */
if ((level < MIN_LEVEL) || (level > MAX_LEVEL))
{
ps_op->s_ive_op.u4_error_code |= IH264E_CODEC_LEVEL_NOT_SUPPORTED;
level = MAX_LEVEL;
}
if (num_ref_frames > MAX_REF_CNT)
{
ps_op->s_ive_op.u4_error_code |= IH264E_NUM_REF_UNSUPPORTED;
num_ref_frames = MAX_REF_CNT;
}
if (num_reorder_frames > MAX_REF_CNT)
{
ps_op->s_ive_op.u4_error_code |= IH264E_NUM_REORDER_UNSUPPORTED;
num_reorder_frames = MAX_REF_CNT;
}
/* Set all memory records as persistent and alignment as 128 by default */
ps_mem_rec = ps_mem_rec_base;
for (i = 0; i < no_of_mem_rec; i++)
{
ps_mem_rec->u4_mem_alignment = 128;
ps_mem_rec->e_mem_type = IV_EXTERNAL_CACHEABLE_PERSISTENT_MEM;
ps_mem_rec++;
}
/************************************************************************
* Request memory for h264 encoder handle *
***********************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_IV_OBJ];
{
ps_mem_rec->u4_mem_size = sizeof(iv_obj_t);
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_IV_OBJ, ps_mem_rec->u4_mem_size);
/************************************************************************
* Request memory for h264 encoder context *
***********************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_CODEC];
{
ps_mem_rec->u4_mem_size = sizeof(codec_t);
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_CODEC, ps_mem_rec->u4_mem_size);
/************************************************************************
* Request memory for CABAC context *
***********************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_CABAC];
{
ps_mem_rec->u4_mem_size = sizeof(cabac_ctxt_t);
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_CABAC, ps_mem_rec->u4_mem_size);
/************************************************************************
* Request memory for CABAC MB info *
***********************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_CABAC_MB_INFO];
{
ps_mem_rec->u4_mem_size = ((max_mb_cols + 1) + 1)
* sizeof(mb_info_ctxt_t);
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_CABAC_MB_INFO, ps_mem_rec->u4_mem_size);
/************************************************************************
* Request memory for entropy context *
* In multi core encoding, each row is assumed to be launched on a *
* thread. The rows below can only start after its neighbors are coded *
* The status of an mb coded/uncoded is signaled via entropy map. *
* 1. One word32 to store skip run cnt *
* 2. mb entropy map (mb status entropy coded/uncoded). The size*
* of the entropy map is max mb cols. Further allocate one *
* more additional row to evade checking for row -1. *
* 3. size of bit stream buffer to store bit stream ctxt. *
* 4. Entropy coding is dependent on nnz coefficient count for *
* the neighbor blocks. It is sufficient to maintain one row *
* worth of nnz as entropy for lower row waits on entropy map*
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_ENTROPY];
{
/* total size of the mem record */
WORD32 total_size = 0;
/* size of skip mb run */
total_size += sizeof(WORD32);
total_size = ALIGN8(total_size);
/* size in bytes to store entropy status of an entire frame */
total_size += (max_mb_cols * max_mb_rows);
/* add an additional 1 row of bytes to evade the special case of row 0 */
total_size += max_mb_cols;
total_size = ALIGN128(total_size);
/* size of bit stream buffer */
total_size += sizeof(bitstrm_t);
total_size = ALIGN128(total_size);
/* top nnz luma */
total_size += (max_mb_cols * 4 * sizeof(UWORD8));
total_size = ALIGN128(total_size);
/* top nnz cbcr */
total_size += (max_mb_cols * 4 * sizeof(UWORD8));
total_size = ALIGN128(total_size);
/* total size per each proc ctxt */
total_size *= MAX_CTXT_SETS;
ps_mem_rec->u4_mem_size = total_size;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_ENTROPY, ps_mem_rec->u4_mem_size);
/************************************************************************
* The residue coefficients that needs to be entropy coded are packed *
* at a buffer space by the proc threads. The entropy thread shall *
* read from the buffer space, unpack them and encode the same. The *
* buffer space required to pack a row of mbs are as follows. *
* Assuming transform_8x8_flag is disabled, *
* In the worst case, 1 mb contains 1 dc 4x4 luma sub block, followed *
* by 16 ac 4x4 luma sub blocks, 2 dc chroma 2x2 sub blocks, followed *
* by 8 ac 4x4 chroma sub blocks. *
* For the sake of simplicity we assume that all sub blocks are of *
* type 4x4. The packing of each 4x4 is depicted by the structure *
* tu_sblk_coeff_data_t *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_MB_COEFF_DATA];
{
/* temp var */
WORD32 size = 0;
/* size of coeff data of 1 mb */
size += sizeof(tu_sblk_coeff_data_t) * MAX_4x4_SUBBLKS;
/* size of coeff data of 1 row of mb's */
size *= max_mb_cols;
/* align to avoid any false sharing across threads */
size = ALIGN64(size);
/* size for one full frame */
size *= max_mb_rows;
/* size of each proc buffer set (ping, pong) */
size *= MAX_CTXT_SETS;
ps_mem_rec->u4_mem_size = size;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_MB_COEFF_DATA, ps_mem_rec->u4_mem_size);
/************************************************************************
* while encoding an mb, the mb header data is signaled to the entropy*
* thread by writing to a buffer space. the size of header data per mb *
* is assumed to be 40 bytes *
* TODO: revisit this inference *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_MB_HEADER_DATA];
{
/* temp var */
WORD32 size;
/* size per MB */
size = 40;
/* size for 1 row of mbs */
size = size * max_mb_cols;
/* align to avoid any false sharing across threads */
size = ALIGN64(size);
/* size for one full frame */
size *= max_mb_rows;
/* size of each proc buffer set (ping, pong) */
size *= MAX_CTXT_SETS;
ps_mem_rec->u4_mem_size = size;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_MB_HEADER_DATA, ps_mem_rec->u4_mem_size);
/************************************************************************
* Size for holding mv_buf_t for each MV Bank. *
* Note this allocation is done for BUF_MGR_MAX_CNT instead of *
* MAX_DPB_SIZE or max_dpb_size for following reasons *
* max_dpb_size will be based on max_wd and max_ht *
* For higher max_wd and max_ht this number will be smaller than *
* MAX_DPB_SIZE But during actual initialization number of buffers *
* allocated can be more. *
* *
* One extra MV Bank is needed to hold current pics MV bank. *
* Since this is only a structure allocation and not actual buffer *
* allocation, it is allocated for BUF_MGR_MAX_CNT entries *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_MVBANK];
{
/* max luma samples */
WORD32 max_luma_samples = 0;
/* determine max luma samples */
for (i = 0; i < 16; i++)
if (level ==(WORD32)gas_ih264_lvl_tbl[i].u4_level_idc)
max_luma_samples = gas_ih264_lvl_tbl[i].u4_max_fs
<< (BLK_SIZE + BLK_SIZE);
ps_mem_rec->u4_mem_size = ih264_buf_mgr_size();
/************************************************************************
* Allocate for pu_map, enc_pu_t and pic_pu_idx for each MV bank *
* Note: Number of luma samples is not max_wd * max_ht here, instead it *
* is set to maximum number of luma samples allowed at the given level. *
* This is done to ensure that any stream with width and height lesser *
* than max_wd and max_ht is supported. Number of buffers required can *
* be greater for lower width and heights at a given level and this *
* increased number of buffers might require more memory than what *
* max_wd and max_ht buffer would have required Also note one extra *
* buffer is allocated to store current pictures MV bank. *
***********************************************************************/
ps_mem_rec->u4_mem_size += BUF_MGR_MAX_CNT * sizeof(mv_buf_t);
ps_mem_rec->u4_mem_size += (num_ref_frames + num_reorder_frames
+ MAX_CTXT_SETS)
* ih264e_get_pic_mv_bank_size(max_luma_samples);
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_MVBANK, ps_mem_rec->u4_mem_size);
/************************************************************************
* While encoding inter slices, to compute the cost of encoding an mb *
* with the mv's at hand, we employ the expression cost = sad + lambda *
* x mv_bits. Here mv_bits is the total number of bits taken to represe*
* nt the mv in the stream. The mv bits for all the possible mv are *
* stored in the look up table. The mem record for this look up table *
* is given below. *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_MVBITS];
{
/* max srch range x */
UWORD32 u4_srch_range_x = ps_ip->s_ive_ip.u4_max_srch_rng_x;
/* max srch range y */
UWORD32 u4_srch_range_y = ps_ip->s_ive_ip.u4_max_srch_rng_y;
/* max srch range */
UWORD32 u4_max_srch_range = MAX(u4_srch_range_x, u4_srch_range_y);
/* due to subpel */
u4_max_srch_range <<= 2;
/* due to mv on either direction */
u4_max_srch_range = (u4_max_srch_range << 1);
/* due to pred mv + zero */
u4_max_srch_range = (u4_max_srch_range << 1) + 1;
u4_max_srch_range = ALIGN128(u4_max_srch_range);
ps_mem_rec->u4_mem_size = u4_max_srch_range;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_MVBITS, ps_mem_rec->u4_mem_size);
/************************************************************************
* Request memory for SPS *
***********************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_SPS];
{
ps_mem_rec->u4_mem_size = MAX_SPS_CNT * sizeof(sps_t);
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_SPS, ps_mem_rec->u4_mem_size);
/************************************************************************
* Request memory for PPS *
***********************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_PPS];
{
ps_mem_rec->u4_mem_size = MAX_PPS_CNT * sizeof(pps_t);
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_PPS, ps_mem_rec->u4_mem_size);
/************************************************************************
* Request memory for Slice Header *
***********************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_SLICE_HDR];
{
ps_mem_rec->u4_mem_size = MAX_CTXT_SETS * MAX_SLICE_HDR_CNT
* sizeof(slice_header_t);
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_SLICE_HDR, ps_mem_rec->u4_mem_size);
/************************************************************************
* Request memory for Adaptive Intra Refresh *
***********************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_AIR_MAP];
{
/* total size of the mem record */
WORD32 total_size = 0;
/* intra coded map */
total_size += max_mb_cnt;
total_size *= MAX_CTXT_SETS;
/* mb refresh map */
total_size += sizeof(UWORD16) * max_mb_cnt;
/* alignment */
total_size = ALIGN128(total_size);
ps_mem_rec->u4_mem_size = total_size;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_AIR_MAP, ps_mem_rec->u4_mem_size);
/************************************************************************
* In multi slice encoding, this memory record helps tracking the start*
* of slice with reference to mb. *
* MEM RECORD for holding *
* 1. mb slice map *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_SLICE_MAP];
{
/* total size of the mem record */
WORD32 total_size = 0;
/* size in bytes to slice index of all mbs of a frame */
total_size = ALIGN64(max_mb_cnt);
/* ih264e_update_proc_ctxt can overread by 1 at the end */
total_size += 1;
/* total size per each proc ctxt */
total_size *= MAX_CTXT_SETS;
ps_mem_rec->u4_mem_size = total_size;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_SLICE_MAP, ps_mem_rec->u4_mem_size);
/************************************************************************
* Request memory to hold thread handles for each processing thread *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_THREAD_HANDLE];
{
WORD32 handle_size = ithread_get_handle_size();
ps_mem_rec->u4_mem_size = MAX_PROCESS_THREADS * handle_size;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_THREAD_HANDLE, ps_mem_rec->u4_mem_size);
/************************************************************************
* Request memory to hold mutex for control calls *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_CTL_MUTEX];
{
ps_mem_rec->u4_mem_size = ithread_get_mutex_lock_size();
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_CTL_MUTEX, ps_mem_rec->u4_mem_size);
/************************************************************************
* Request memory to hold mutex for entropy calls *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_ENTROPY_MUTEX];
{
ps_mem_rec->u4_mem_size = ithread_get_mutex_lock_size();
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_ENTROPY_MUTEX, ps_mem_rec->u4_mem_size);
/************************************************************************
* Request memory to hold process jobs *
***********************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_PROC_JOBQ];
{
/* One process job per row of MBs */
/* Allocate for two pictures, so that wrap around can be handled easily */
WORD32 num_jobs = max_mb_rows * MAX_CTXT_SETS;
WORD32 job_queue_size = ih264_list_size(num_jobs, sizeof(job_t));
ps_mem_rec->u4_mem_size = job_queue_size;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_PROC_JOBQ, ps_mem_rec->u4_mem_size);
/************************************************************************
* Request memory to hold entropy jobs *
***********************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_ENTROPY_JOBQ];
{
/* One process job per row of MBs */
/* Allocate for two pictures, so that wrap around can be handled easily */
WORD32 num_jobs = max_mb_rows * MAX_CTXT_SETS;
WORD32 job_queue_size = ih264_list_size(num_jobs, sizeof(job_t));
ps_mem_rec->u4_mem_size = job_queue_size;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_ENTROPY_JOBQ, ps_mem_rec->u4_mem_size);
/************************************************************************
* In multi core encoding, each row is assumed to be launched on a *
* thread. The rows below can only start after its neighbors are coded *
* The status of an mb coded/uncoded is signaled via proc map. *
* MEM RECORD for holding *
* 1. mb proc map (mb status core coded/uncoded) *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_PROC_MAP];
{
/* total size of the mem record */
WORD32 total_size = 0;
/* size in bytes to mb core coding status of an entire frame */
total_size = max_mb_cnt;
/* add an additional 1 row of bytes to evade the special case of row 0 */
total_size += max_mb_cols;
/* total size per each proc ctxt */
total_size *= MAX_CTXT_SETS;
ps_mem_rec->u4_mem_size = total_size;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_PROC_MAP, ps_mem_rec->u4_mem_size);
/************************************************************************
* mem record for holding a particular MB is deblocked or not *
* 1. mb deblk map (mb status deblocked/not deblocked) *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_DBLK_MAP];
{
/* total size of the mem record */
WORD32 total_size = 0;
/* size in bytes to mb core coding status of an entire frame */
total_size = max_mb_cnt;
/* add an additional 1 row of bytes to evade the special case of row 0 */
total_size += max_mb_cols;
total_size = ALIGN64(total_size);
/* total size per each proc ctxt */
total_size *= MAX_CTXT_SETS;
ps_mem_rec->u4_mem_size = total_size;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_DBLK_MAP, ps_mem_rec->u4_mem_size);
/************************************************************************
* mem record for holding a particular MB's me is done or not *
* 1. mb me map *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_ME_MAP];
{
/* total size of the mem record */
WORD32 total_size = 0;
/* size in bytes to mb core coding status of an entire frame */
total_size = max_mb_cnt;
/* add an additional 1 row of bytes to evade the special case of row 0 */
total_size += max_mb_cols;
/* total size per each proc ctxt */
total_size *= MAX_CTXT_SETS;
ps_mem_rec->u4_mem_size = total_size;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_ME_MAP, ps_mem_rec->u4_mem_size);
/************************************************************************
* size for holding dpb manager context *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_DPB_MGR];
{
ps_mem_rec->u4_mem_size = sizeof(dpb_mgr_t);
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_DPB_MGR, ps_mem_rec->u4_mem_size);
/************************************************************************
* luma or chroma core coding involves mb estimation, error computation*
* between the estimated singnal and the actual signal, transform the *
* error, quantize the error, then inverse transform and inverse quant *
* ize the residue and add the result back to estimated signal. *
* To perform all these, a set of temporary buffers are needed. *
* MEM RECORD for holding scratch buffers *
* 1. prediction buffer used during mb mode analysis *
* 2 temp. reference buffer when intra 4x4 with rdopt on is *
* enabled *
* - when intra 4x4 is enabled, rdopt is on, to store the *
* reconstructed values and use them later this temp. buffer *
* is used. *
* 3. prediction buffer used during intra mode analysis *
* 4. prediction buffer used during intra 16x16 plane mode *
* analysis
* 5. prediction buffer used during intra chroma mode analysis *
* 6. prediction buffer used during intra chroma 16x16 plane *
* mode analysis
* 7. forward transform output buffer *
* - to store the error between estimated and the actual inp *
* ut and to store the fwd transformed quantized output *
* 8. forward transform output buffer *
* - when intra 4x4 is enabled, rdopt is on, to store the *
* fwd transform values and use them later this temp. buffer *
* is used. *
* 9. temporary buffer for inverse transform *
* - temporary buffer used in inverse transform and inverse *
* quantization *
* A. Buffers for holding half_x , half_y and half_xy planes *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_PROC_SCRATCH];
{
WORD32 total_size = 0;
WORD32 i4_tmp_size;
/* size to hold prediction buffer */
total_size += sizeof(UWORD8) * 16 * 16;
total_size = ALIGN64(total_size);
/* size to hold recon for intra 4x4 buffer */
total_size += sizeof(UWORD8) * 16 * 16;
total_size = ALIGN64(total_size);
/* prediction buffer intra 16x16 */
total_size += sizeof(UWORD8) * 16 * 16;
total_size = ALIGN64(total_size);
/* prediction buffer intra 16x16 plane*/
total_size += sizeof(UWORD8) * 16 * 16;
total_size = ALIGN64(total_size);
/* prediction buffer intra chroma*/
total_size += sizeof(UWORD8) * 16 * 8;
total_size = ALIGN64(total_size);
/* prediction buffer intra chroma plane*/
total_size += sizeof(UWORD8) * 16 * 8;
total_size = ALIGN64(total_size);
/* size to hold fwd transform output */
total_size += sizeof(WORD16) * SIZE_TRANS_BUFF;
total_size = ALIGN64(total_size);
/* size to hold fwd transform output */
total_size += sizeof(WORD16) * SIZE_TRANS_BUFF;
total_size = ALIGN64(total_size);
/* size to hold temporary data during inverse transform */
total_size += sizeof(WORD32) * SIZE_TMP_BUFF_ITRANS;
total_size = ALIGN64(total_size);
/* Buffers for holding half_x , half_y and half_xy planes */
i4_tmp_size = sizeof(UWORD8) * (HP_BUFF_WD * HP_BUFF_HT);
total_size += (ALIGN64(i4_tmp_size) * SUBPEL_BUFF_CNT);
/* Allocate for each process thread */
total_size *= MAX_PROCESS_CTXT;
ps_mem_rec->u4_mem_size = total_size;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_PROC_SCRATCH, ps_mem_rec->u4_mem_size);
/************************************************************************
* When transform_8x8_flag is disabled, the size of a sub block is *
* 4x4 and when the transform_8x8_flag is enabled the size of the sub *
* block is 8x8. The threshold matrix and the forward scaling list *
* is of the size of the sub block. *
* MEM RECORD for holding *
* 1. quantization parameters for plane y, cb, cr *
* - threshold matrix for quantization *
* - forward weight matrix *
* - satqd threshold matrix *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_QUANT_PARAM];
{
/* total size of the mem record */
WORD32 total_size = 0;
/* quantization parameter list for planes y,cb and cr */
total_size += ALIGN64(sizeof(quant_params_t)) * 3;
/* size of threshold matrix for quantization
* (assuming the transform_8x8_flag is disabled).
* for all 3 planes */
total_size += ALIGN64(sizeof(WORD16) * 4 * 4) * 3;
/* size of forward weight matrix for quantization
* (assuming the transform_8x8_flag is disabled).
* for all 3 planes */
total_size += ALIGN64(sizeof(WORD16) * 4 * 4) * 3;
/* Size for SATDQ threshold matrix for palnes y, cb and cr */
total_size += ALIGN64(sizeof(UWORD16) * 9) * 3;
/* total size per each proc thread */
total_size *= MAX_PROCESS_CTXT;
ps_mem_rec->u4_mem_size = total_size;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_QUANT_PARAM, ps_mem_rec->u4_mem_size);
/************************************************************************
* While computing blocking strength for the current mb, the csbp, mb *
* type for the neighboring mbs are necessary. memtab for storing top *
* row mbtype and csbp is evaluated here. *
* *
* when encoding intra 4x4 or intra 8x8 the submb types are estimated *
* and sent. The estimation is dependent on neighbor mbs. For this *
* store the top row sub mb types for intra mbs *
* *
* During motion vector prediction, the curr mb mv is predicted from *
* neigbors left, top, top right and sometimes top left depending on *
* the availability. The top and top right content is accessed from *
* the memtab specified below. *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_TOP_ROW_SYN_INFO];
{
/* total size of the mem record */
WORD32 total_size = 0;
/* size in bytes to store 1 row of mb_info_t */
/* one additional mb, to avoid checking end of row condition */
total_size += (max_mb_cols + 1) * sizeof(mb_info_t);
/* size in bytes to store 1 row of intra macroblock sub modes */
total_size += max_mb_cols * sizeof(UWORD8) * 16;
/* size in bytes to store 1 row + 1 of enc_pu_t */
/* one additional mb, to avoid checking end of row condition */
total_size += (max_mb_cols + 1) * sizeof(enc_pu_t);
/* total size per proc ctxt */
total_size = ALIGN128(total_size);
/* total size per each proc ctxt */
total_size *= MAX_CTXT_SETS;
ps_mem_rec->u4_mem_size = total_size;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_TOP_ROW_SYN_INFO, ps_mem_rec->u4_mem_size);
/************************************************************************
* When transform_8x8_flag is disabled, the mb is partitioned into *
* 4 sub blocks. This corresponds to 1 vertical left edge and 1 *
* vertical inner edge, 1 horizontal top edge and 1 horizontal *
* inner edge per mb. Further, When transform_8x8_flag is enabled, *
* the mb is partitioned in to 16 sub blocks. This corresponds to *
* 1 vertical left edge and 3 vertical inner edges, 1 horizontal top *
* edge and 3 horizontal inner edges per mb. *
* MEM RECORD for holding *
* 1. vertical edge blocking strength *
* 2. horizontal edge blocking strength *
* 3. mb qp *
* all are frame level *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_BS_QP];
{
/* total size of the mem record */
WORD32 total_size = 0;
/* size in bytes to store vertical edge bs, horizontal edge bs and qp of every mb*/
WORD32 vert_bs_size, horz_bs_size, qp_size;
/* vertical edge bs = total number of vertical edges * number of bytes per each edge */
/* total num of v edges = total mb * 4 (assuming transform_8x8_flag = 0),
* each edge is formed by 4 pairs of subblks, requiring 4 bytes to storing bs */
vert_bs_size = ALIGN64(max_mb_cnt * 4 * 4);
/* horizontal edge bs = total number of horizontal edges * number of bytes per each edge */
/* total num of h edges = total mb * 4 (assuming transform_8x8_flag = 0),
* each edge is formed by 4 pairs of subblks, requiring 4 bytes to storing bs */
horz_bs_size = ALIGN64(max_mb_cnt * 4 * 4);
/* qp of each mb requires 1 byte */
qp_size = ALIGN64(max_mb_cnt);
/* total size */
total_size = vert_bs_size + horz_bs_size + qp_size;
/* total size per each proc ctxt */
total_size *= MAX_CTXT_SETS;
ps_mem_rec->u4_mem_size = total_size;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_BS_QP, ps_mem_rec->u4_mem_size);
/************************************************************************
* size for holding dpb manager context *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_INP_PIC];
{
ps_mem_rec->u4_mem_size = ih264_buf_mgr_size();
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_INP_PIC, ps_mem_rec->u4_mem_size);
/************************************************************************
* size for holding dpb manager context *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_OUT];
{
ps_mem_rec->u4_mem_size = ih264_buf_mgr_size();
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_OUT, ps_mem_rec->u4_mem_size);
/************************************************************************
* Size for color space conversion *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_CSC];
{
/* We need a total a memory for a single frame of 420 sp, ie
* (wd * ht) for luma and (wd * ht / 2) for chroma*/
ps_mem_rec->u4_mem_size = MAX_CTXT_SETS
* ((3 * max_ht_luma * max_wd_luma) >> 1);
/* Allocate an extra row, since inverse transform functions for
* chroma access(only read, not used) few extra bytes due to
* interleaved input
*/
ps_mem_rec->u4_mem_size += max_wd_luma;
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_CSC, ps_mem_rec->u4_mem_size);
/************************************************************************
* Size for holding pic_buf_t for each reference picture *
* Note this allocation is done for BUF_MGR_MAX_CNT instead of *
* MAX_DPB_SIZE or max_dpb_size for following reasons *
* max_dpb_size will be based on max_wd and max_ht *
* For higher max_wd and max_ht this number will be smaller than *
* MAX_DPB_SIZE But during actual initialization number of buffers *
* allocated can be more. *
* *
* Also to handle display depth application can allocate more than *
* what codec asks for in case of non-shared mode *
* Since this is only a structure allocation and not actual buffer *
* allocation, it is allocated for BUF_MGR_MAX_CNT entries *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_REF_PIC];
{
ps_mem_rec->u4_mem_size = ih264_buf_mgr_size();
ps_mem_rec->u4_mem_size += BUF_MGR_MAX_CNT * sizeof(pic_buf_t);
/************************************************************************
* Note: Number of luma samples is not max_wd * max_ht here, instead it *
* is set to maximum number of luma samples allowed at the given level. *
* This is done to ensure that any stream with width and height lesser *
* than max_wd and max_ht is supported. Number of buffers required can *
* be greater for lower width and heights at a given level and this *
* increased number of buffers might require more memory than what *
* max_wd and max_ht buffer would have required. Number of buffers is *
* doubled in order to return one frame at a time instead of sending *
* multiple outputs during dpb full case. Also note one extra buffer is *
* allocted to store current picture. *
* *
* Half-pel planes for each reference buffer are allocated along with *
* the reference buffer. So each reference buffer is 4 times the *
* required size. This way buffer management for the half-pel planes is *
* easier and while using the half-pel planes in MC, an offset can be *
* used from a single pointer *
***********************************************************************/
ps_mem_rec->u4_mem_size += HPEL_PLANES_CNT
* ih264e_get_total_pic_buf_size(
max_wd_luma * max_ht_luma, level,
PAD_WD, PAD_HT, num_ref_frames,
num_reorder_frames);
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_REF_PIC, ps_mem_rec->u4_mem_size);
/************************************************************************
* Request memory to hold mem recs to be returned during retrieve call *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_BACKUP];
{
ps_mem_rec->u4_mem_size = MEM_REC_CNT * sizeof(iv_mem_rec_t);
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_BACKUP, ps_mem_rec->u4_mem_size);
/************************************************************************
* size for memory required by NMB info structs and buffer for storing *
* half pel plane *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_MB_INFO_NMB];
{
ps_mem_rec->u4_mem_size = MAX_PROCESS_CTXT * max_mb_cols *
(sizeof(mb_info_nmb_t) + MB_SIZE * MB_SIZE
* sizeof(UWORD8));
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_MB_INFO_NMB, ps_mem_rec->u4_mem_size);
/************************************************************************
* RC mem records *
************************************************************************/
ps_mem_rec = &ps_mem_rec_base[MEM_REC_RC];
{
ih264e_get_rate_control_mem_tab(NULL, ps_mem_rec, FILL_MEMTAB);
}
DEBUG("\nMemory record Id %d = %d \n", MEM_REC_RC, ps_mem_rec->u4_mem_size);
/* Each memtab size is aligned to next multiple of 128 bytes */
/* This is to ensure all the memtabs start at different cache lines */
ps_mem_rec = ps_mem_rec_base;
for (i = 0; i < MEM_REC_CNT; i++)
{
ps_mem_rec->u4_mem_size = ALIGN128(ps_mem_rec->u4_mem_size);
ps_mem_rec++;
}
ps_op->s_ive_op.u4_num_mem_rec = MEM_REC_CNT;
DEBUG("Num mem recs in fill call : %d\n", ps_op->s_ive_op.u4_num_mem_rec);
return (status);
}
/**
*******************************************************************************
*
* @brief
* Initializes from mem records passed to the codec
*
* @par Description:
* Initializes pointers based on mem records passed
*
* @param[in] ps_codec_obj
* Pointer to codec object at API level
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static WORD32 ih264e_init_mem_rec(iv_obj_t *ps_codec_obj,
void *pv_api_ip,
void *pv_api_op)
{
/* api call I/O structures */
ih264e_init_ip_t *ps_ip = pv_api_ip;
ih264e_init_op_t *ps_op = pv_api_op;
/* mem records */
iv_mem_rec_t *ps_mem_rec_base, *ps_mem_rec;
/* codec variables */
codec_t * ps_codec;
cabac_ctxt_t *ps_cabac;
mb_info_ctxt_t *ps_mb_map_ctxt_inc;
cfg_params_t *ps_cfg;
/* frame dimensions */
WORD32 max_wd_luma, max_ht_luma;
WORD32 max_mb_rows, max_mb_cols, max_mb_cnt;
/* temp var */
WORD32 i, j;
WORD32 status = IV_SUCCESS;
/* frame dimensions */
max_ht_luma = ALIGN16(ps_ip->s_ive_ip.u4_max_ht);
max_wd_luma = ALIGN16(ps_ip->s_ive_ip.u4_max_wd);
max_mb_rows = max_ht_luma / MB_SIZE;
max_mb_cols = max_wd_luma / MB_SIZE;
max_mb_cnt = max_mb_rows * max_mb_cols;
/* mem records */
ps_mem_rec_base = ps_ip->s_ive_ip.ps_mem_rec;
/* Init mem records */
ps_mem_rec = &ps_mem_rec_base[MEM_REC_CODEC];
{
ps_codec_obj->pv_codec_handle = ps_mem_rec->pv_base;
ps_codec = (codec_t *) (ps_codec_obj->pv_codec_handle);
}
/* Init mem records_cabac ctxt */
ps_mem_rec = &ps_mem_rec_base[MEM_REC_CABAC];
{
ps_cabac = (cabac_ctxt_t *)(ps_mem_rec->pv_base);
}
/* Init mem records mb info array for CABAC */
ps_mem_rec = &ps_mem_rec_base[MEM_REC_CABAC_MB_INFO];
{
ps_mb_map_ctxt_inc = (mb_info_ctxt_t *)(ps_mem_rec->pv_base);
}
/* Note this memset can not be done in init() call, since init will called
during reset as well. And calling this during reset will mean all pointers
need to reinitialized */
memset(ps_codec, 0, sizeof(codec_t));
memset(ps_cabac, 0, sizeof(cabac_ctxt_t));
/* Set default Config Params */
ps_cfg = &ps_codec->s_cfg;
ih264e_set_default_params(ps_cfg);
/* Update config params as per input */
ps_cfg->u4_max_wd = ALIGN16(ps_ip->s_ive_ip.u4_max_wd);
ps_cfg->u4_max_ht = ALIGN16(ps_ip->s_ive_ip.u4_max_ht);
ps_cfg->i4_wd_mbs = ps_cfg->u4_max_wd >> 4;
ps_cfg->i4_ht_mbs = ps_cfg->u4_max_ht >> 4;
ps_cfg->u4_max_ref_cnt = ps_ip->s_ive_ip.u4_max_ref_cnt;
ps_cfg->u4_max_reorder_cnt = ps_ip->s_ive_ip.u4_max_reorder_cnt;
ps_cfg->u4_max_level = ps_ip->s_ive_ip.u4_max_level;
ps_cfg->e_inp_color_fmt = ps_ip->s_ive_ip.e_inp_color_fmt;
ps_cfg->e_recon_color_fmt = ps_ip->s_ive_ip.e_recon_color_fmt;
ps_cfg->u4_max_framerate = ps_ip->s_ive_ip.u4_max_framerate;
ps_cfg->u4_max_bitrate = ps_ip->s_ive_ip.u4_max_bitrate;
ps_cfg->u4_num_bframes = ps_ip->s_ive_ip.u4_num_bframes;
ps_cfg->e_content_type = ps_ip->s_ive_ip.e_content_type;
ps_cfg->u4_max_srch_rng_x = ps_ip->s_ive_ip.u4_max_srch_rng_x;
ps_cfg->u4_max_srch_rng_y = ps_ip->s_ive_ip.u4_max_srch_rng_y;
ps_cfg->e_slice_mode = ps_ip->s_ive_ip.e_slice_mode;
ps_cfg->u4_slice_param = ps_ip->s_ive_ip.u4_slice_param;
ps_cfg->e_arch = ps_ip->s_ive_ip.e_arch;
ps_cfg->e_soc = ps_ip->s_ive_ip.e_soc;
ps_cfg->u4_enable_recon = ps_ip->s_ive_ip.u4_enable_recon;
ps_cfg->e_rc_mode = ps_ip->s_ive_ip.e_rc_mode;
/* Validate params */
if ((ps_ip->s_ive_ip.u4_max_level < MIN_LEVEL)
|| (ps_ip->s_ive_ip.u4_max_level > MAX_LEVEL))
{
ps_op->s_ive_op.u4_error_code |= IH264E_CODEC_LEVEL_NOT_SUPPORTED;
ps_cfg->u4_max_level = DEFAULT_MAX_LEVEL;
}
if (ps_ip->s_ive_ip.u4_max_ref_cnt > MAX_REF_CNT)
{
ps_op->s_ive_op.u4_error_code |= IH264E_NUM_REF_UNSUPPORTED;
ps_cfg->u4_max_ref_cnt = MAX_REF_CNT;
}
if (ps_ip->s_ive_ip.u4_max_reorder_cnt > MAX_REF_CNT)
{
ps_op->s_ive_op.u4_error_code |= IH264E_NUM_REORDER_UNSUPPORTED;
ps_cfg->u4_max_reorder_cnt = MAX_REF_CNT;
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_BACKUP];
{
ps_codec->ps_mem_rec_backup = (iv_mem_rec_t *) ps_mem_rec->pv_base;
memcpy(ps_codec->ps_mem_rec_backup, ps_mem_rec_base,
MEM_REC_CNT * sizeof(iv_mem_rec_t));
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_ENTROPY];
{
/* temp var */
WORD32 size = 0, offset;
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
if (i < MAX_PROCESS_CTXT / MAX_CTXT_SETS)
{
/* base ptr */
UWORD8 *pu1_buf = ps_mem_rec->pv_base;
/* reset size */
size = 0;
/* skip mb run */
ps_codec->as_process[i].s_entropy.pi4_mb_skip_run =
(void *) (pu1_buf + size);
size += sizeof(WORD32);
size = ALIGN8(size);
/* entropy map */
ps_codec->as_process[i].s_entropy.pu1_entropy_map =
(void *) (pu1_buf + size + max_mb_cols);
/* size in bytes to store entropy status of an entire frame */
size += (max_mb_cols * max_mb_rows);
/* add an additional 1 row of bytes to evade the special case of row 0 */
size += max_mb_cols;
size = ALIGN128(size);
/* bit stream ptr */
ps_codec->as_process[i].s_entropy.ps_bitstrm = (void *) (pu1_buf
+ size);
size += sizeof(bitstrm_t);
size = ALIGN128(size);
/* nnz luma */
ps_codec->as_process[i].s_entropy.pu1_top_nnz_luma =
(void *) (pu1_buf + size);
size += (max_mb_cols * 4 * sizeof(UWORD8));
size = ALIGN128(size);
/* nnz chroma */
ps_codec->as_process[i].s_entropy.pu1_top_nnz_cbcr =
(void *) (pu1_buf + size);
size += (max_mb_cols * 4 * sizeof(UWORD8));
size = ALIGN128(size);
offset = size;
/* cabac Context */
ps_codec->as_process[i].s_entropy.ps_cabac = ps_cabac;
}
else
{
/* base ptr */
UWORD8 *pu1_buf = ps_mem_rec->pv_base;
/* reset size */
size = offset;
/* skip mb run */
ps_codec->as_process[i].s_entropy.pi4_mb_skip_run =
(void *) (pu1_buf + size);
size += sizeof(WORD32);
size = ALIGN8(size);
/* entropy map */
ps_codec->as_process[i].s_entropy.pu1_entropy_map =
(void *) (pu1_buf + size + max_mb_cols);
/* size in bytes to store entropy status of an entire frame */
size += (max_mb_cols * max_mb_rows);
/* add an additional 1 row of bytes to evade the special case of row 0 */
size += max_mb_cols;
size = ALIGN128(size);
/* bit stream ptr */
ps_codec->as_process[i].s_entropy.ps_bitstrm = (void *) (pu1_buf
+ size);
size += sizeof(bitstrm_t);
size = ALIGN128(size);
/* nnz luma */
ps_codec->as_process[i].s_entropy.pu1_top_nnz_luma =
(void *) (pu1_buf + size);
size += (max_mb_cols * 4 * sizeof(UWORD8));
size = ALIGN128(size);
/* nnz chroma */
ps_codec->as_process[i].s_entropy.pu1_top_nnz_cbcr =
(void *) (pu1_buf + size);
size += (max_mb_cols * 4 * sizeof(UWORD8));
size = ALIGN128(size);
/* cabac Context */
ps_codec->as_process[i].s_entropy.ps_cabac = ps_cabac;
}
}
ps_codec->as_process[0].s_entropy.ps_cabac->ps_mb_map_ctxt_inc_base =
ps_mb_map_ctxt_inc;
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_MB_COEFF_DATA];
{
/* temp var */
WORD32 size = 0, size_of_row;
UWORD8 *pu1_buf = ps_mem_rec->pv_base;
/* size of coeff data of 1 mb */
size += sizeof(tu_sblk_coeff_data_t) * MAX_4x4_SUBBLKS;
/* size of coeff data of 1 row of mb's */
size *= max_mb_cols;
/* align to avoid false sharing */
size = ALIGN64(size);
size_of_row = size;
/* size for one full frame */
size *= max_mb_rows;
ps_codec->u4_size_coeff_data = size_of_row;
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
if (i < MAX_PROCESS_CTXT / MAX_CTXT_SETS)
{
ps_codec->as_process[i].pv_pic_mb_coeff_data = pu1_buf;
ps_codec->as_process[i].s_entropy.pv_pic_mb_coeff_data =
pu1_buf;
}
else
{
ps_codec->as_process[i].pv_pic_mb_coeff_data = pu1_buf + size;
ps_codec->as_process[i].s_entropy.pv_pic_mb_coeff_data = pu1_buf
+ size;
}
}
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_MB_HEADER_DATA];
{
/* temp var */
WORD32 size, size_of_row;
UWORD8 *pu1_buf = ps_mem_rec->pv_base;
/* size of header data of 1 mb */
size = 40;
/* size for 1 row of mbs */
size = size * max_mb_cols;
/* align to avoid any false sharing across threads */
size = ALIGN64(size);
size_of_row = size;
/* size for one full frame */
size *= max_mb_rows;
ps_codec->u4_size_header_data = size_of_row;
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
if (i < MAX_PROCESS_CTXT / MAX_CTXT_SETS)
{
ps_codec->as_process[i].pv_pic_mb_header_data = pu1_buf;
ps_codec->as_process[i].s_entropy.pv_pic_mb_header_data =
pu1_buf;
}
else
{
ps_codec->as_process[i].pv_pic_mb_header_data = pu1_buf + size;
ps_codec->as_process[i].s_entropy.pv_pic_mb_header_data =
pu1_buf + size;
}
}
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_MVBANK];
{
/* size of buf mgr struct */
WORD32 size = ih264_buf_mgr_size();
/* temp var */
UWORD8 *pu1_buf = ps_mem_rec->pv_base;
/* mv buffer mgr */
ps_codec->pv_mv_buf_mgr_base = pu1_buf;
/* mv bank */
ps_codec->pv_mv_bank_buf_base = pu1_buf + size;
ps_codec->i4_total_mv_bank_size = ps_mem_rec->u4_mem_size - size;
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_MVBITS];
{
/* max srch range x */
UWORD32 u4_srch_range_x = ps_ip->s_ive_ip.u4_max_srch_rng_x;
/* max srch range y */
UWORD32 u4_srch_range_y = ps_ip->s_ive_ip.u4_max_srch_rng_y;
/* max srch range */
UWORD32 u4_max_srch_range = MAX(u4_srch_range_x, u4_srch_range_y);
/* temp var */
UWORD8 *pu1_buf = ps_mem_rec->pv_base;
/* due to subpel */
u4_max_srch_range <<= 2;
// /* due to mv on either direction */
// u4_max_srch_range = (u4_max_srch_range << 1);
/* due to pred mv + zero */
u4_max_srch_range = (u4_max_srch_range << 1) + 1;
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
/* me ctxt */
me_ctxt_t *ps_mem_ctxt = &(ps_codec->as_process[i].s_me_ctxt);
/* init at zero mv */
ps_mem_ctxt->pu1_mv_bits = pu1_buf + u4_max_srch_range;
}
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_SPS];
{
ps_codec->ps_sps_base = (sps_t *) ps_mem_rec->pv_base;
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_PPS];
{
ps_codec->ps_pps_base = (pps_t *) ps_mem_rec->pv_base;
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_SLICE_HDR];
{
ps_codec->ps_slice_hdr_base = ps_mem_rec->pv_base;
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
if (i < MAX_PROCESS_CTXT / MAX_CTXT_SETS)
{
ps_codec->as_process[i].ps_slice_hdr_base = ps_mem_rec->pv_base;
}
else
{
/* temp var */
WORD32 size = MAX_SLICE_HDR_CNT * sizeof(slice_header_t);
void *pv_buf = (UWORD8 *) ps_mem_rec->pv_base + size;
ps_codec->as_process[i].ps_slice_hdr_base = pv_buf;
}
}
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_AIR_MAP];
{
/* temp var */
UWORD8 *pu1_buf = ps_mem_rec->pv_base;
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
if (i < MAX_PROCESS_CTXT / MAX_CTXT_SETS)
{
ps_codec->as_process[i].pu1_is_intra_coded = pu1_buf;
}
else
{
ps_codec->as_process[i].pu1_is_intra_coded = pu1_buf
+ max_mb_cnt;
}
}
ps_codec->pu2_intr_rfrsh_map = (UWORD16 *) (pu1_buf + max_mb_cnt * 2);
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_SLICE_MAP];
{
/* pointer to storage space */
UWORD8 *pu1_buf_ping, *pu1_buf_pong;
/* init pointer */
pu1_buf_ping = ps_mem_rec->pv_base;
pu1_buf_pong = pu1_buf_ping + ALIGN64(max_mb_cnt);
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
if (i < MAX_PROCESS_CTXT / MAX_CTXT_SETS)
{
ps_codec->as_process[i].pu1_slice_idx = pu1_buf_ping;
}
else
{
ps_codec->as_process[i].pu1_slice_idx = pu1_buf_pong;
}
}
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_THREAD_HANDLE];
{
WORD32 handle_size = ithread_get_handle_size();
for (i = 0; i < MAX_PROCESS_THREADS; i++)
{
ps_codec->apv_proc_thread_handle[i] = (UWORD8 *) ps_mem_rec->pv_base
+ (i * handle_size);
}
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_CTL_MUTEX];
{
ps_codec->pv_ctl_mutex = ps_mem_rec->pv_base;
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_ENTROPY_MUTEX];
{
ps_codec->pv_entropy_mutex = ps_mem_rec->pv_base;
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_PROC_JOBQ];
{
ps_codec->pv_proc_jobq_buf = ps_mem_rec->pv_base;
ps_codec->i4_proc_jobq_buf_size = ps_mem_rec->u4_mem_size;
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_ENTROPY_JOBQ];
{
ps_codec->pv_entropy_jobq_buf = ps_mem_rec->pv_base;
ps_codec->i4_entropy_jobq_buf_size = ps_mem_rec->u4_mem_size;
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_PROC_MAP];
{
/* pointer to storage space */
UWORD8 *pu1_buf = ps_mem_rec->pv_base;
/* total size of the mem record */
WORD32 total_size = 0;
/* size in bytes to mb core coding status of an entire frame */
total_size = max_mb_cnt;
/* add an additional 1 row of bytes to evade the special case of row 0 */
total_size += max_mb_cols;
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
if (i < MAX_PROCESS_CTXT / MAX_CTXT_SETS)
{
ps_codec->as_process[i].pu1_proc_map = pu1_buf + max_mb_cols;
}
else
{
ps_codec->as_process[i].pu1_proc_map = pu1_buf + total_size
+ max_mb_cols;
}
}
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_DBLK_MAP];
{
/* pointer to storage space */
UWORD8 *pu1_buf = ps_mem_rec->pv_base;
/* total size of the mem record */
WORD32 total_size = 0;
/* size in bytes to mb core coding status of an entire frame */
total_size = max_mb_cnt;
/* add an additional 1 row of bytes to evade the special case of row 0 */
total_size += max_mb_cols;
/*Align the memory offsets*/
total_size = ALIGN64(total_size);
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
if (i < MAX_PROCESS_CTXT / MAX_CTXT_SETS)
{
ps_codec->as_process[i].pu1_deblk_map = pu1_buf + max_mb_cols;
}
else
{
ps_codec->as_process[i].pu1_deblk_map = pu1_buf + total_size
+ max_mb_cols;
}
}
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_ME_MAP];
{
/* pointer to storage space */
UWORD8 *pu1_buf = (UWORD8 *) ps_mem_rec->pv_base;
/* total size of the mem record */
WORD32 total_size = 0;
/* size in bytes to mb core coding status of an entire frame */
total_size = max_mb_cnt;
/* add an additional 1 row of bytes to evade the special case of row 0 */
total_size += max_mb_cols;
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
if (i < MAX_PROCESS_CTXT / MAX_CTXT_SETS)
{
ps_codec->as_process[i].pu1_me_map = pu1_buf + max_mb_cols;
}
else
{
ps_codec->as_process[i].pu1_me_map = pu1_buf + total_size
+ max_mb_cols;
}
}
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_DPB_MGR];
{
ps_codec->pv_dpb_mgr = ps_mem_rec->pv_base;
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_PROC_SCRATCH];
{
/* pointer to storage space */
UWORD8 *pu1_buf = (UWORD8 *) ps_mem_rec->pv_base;
/* size of pred buffer, fwd transform output, temp buffer for inv tra */
WORD32 size_pred_luma, size_pred_chroma, size_fwd, size_inv, size_hp;
/* temp var */
WORD32 size = 0;
/* size to hold intra/inter prediction buffer */
size_pred_luma = sizeof(UWORD8) * 16 * 16;
size_pred_chroma = sizeof(UWORD8) * 8 * 16;
/* size to hold fwd transform output */
size_fwd = sizeof(WORD16) * SIZE_TRANS_BUFF;
/* size to hold temporary data during inverse transform */
size_inv = sizeof(WORD32) * SIZE_TMP_BUFF_ITRANS;
/* size to hold half pel plane buffers */
size_hp = sizeof(UWORD8) * (HP_BUFF_WD * HP_BUFF_HT);
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
/* prediction buffer */
ps_codec->as_process[i].pu1_pred_mb = (void *) (pu1_buf + size);
ps_codec->as_process[i].i4_pred_strd = 16;
size += size_pred_luma;
size = ALIGN64(size);
/* prediction buffer */
ps_codec->as_process[i].pu1_ref_mb_intra_4x4 = (void *) (pu1_buf
+ size);
size += size_pred_luma;
size = ALIGN64(size);
/* prediction buffer intra 16x16 */
ps_codec->as_process[i].pu1_pred_mb_intra_16x16 = (void *) (pu1_buf
+ size);
size += size_pred_luma;
size = ALIGN64(size);
/* prediction buffer intra 16x16 plane*/
ps_codec->as_process[i].pu1_pred_mb_intra_16x16_plane =
(void *) (pu1_buf + size);
size += size_pred_luma;
size = ALIGN64(size);
/* prediction buffer intra chroma*/
ps_codec->as_process[i].pu1_pred_mb_intra_chroma = (void *) (pu1_buf
+ size);
size += size_pred_chroma;
size = ALIGN64(size);
/* prediction buffer intra chroma plane*/
ps_codec->as_process[i].pu1_pred_mb_intra_chroma_plane =
(void *) (pu1_buf + size);
size += size_pred_chroma;
size = ALIGN64(size);
/* Fwd transform output */
ps_codec->as_process[i].pi2_res_buf = (void *) (pu1_buf + size);
ps_codec->as_process[i].i4_res_strd = 16;
size += size_fwd;
size = ALIGN64(size);
/* Fwd transform output */
ps_codec->as_process[i].pi2_res_buf_intra_4x4 = (void *) (pu1_buf
+ size);
size += size_fwd;
size = ALIGN64(size);
/* scratch buffer used during inverse transform */
ps_codec->as_process[i].pv_scratch_buff = (void *) (pu1_buf + size);
size += size_inv;
size = ALIGN64(size);
for (j = 0; j < SUBPEL_BUFF_CNT; j++)
{
ps_codec->as_process[i].apu1_subpel_buffs[j] = (pu1_buf + size);
size += ALIGN64(size_hp);
}
}
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_QUANT_PARAM];
{
/* pointer to storage space */
UWORD8 *pu1_buf = (UWORD8 *) ps_mem_rec->pv_base;
/* size of qp, threshold matrix, fwd scaling list for one plane */
WORD32 size_quant_param, size_thres_mat, size_fwd_weight_mat,
size_satqd_weight_mat;
/* temp var */
WORD32 total_size = 0;
/* size of quantization parameter list of 1 plane */
size_quant_param = ALIGN64(sizeof(quant_params_t));
/* size of threshold matrix for quantization
* (assuming the transform_8x8_flag is disabled).
* for 1 plane */
size_thres_mat = ALIGN64(sizeof(WORD16) * 4 * 4);
/* size of forward weight matrix for quantization
* (assuming the transform_8x8_flag is disabled).
* for 1 plane */
size_fwd_weight_mat = ALIGN64(sizeof(WORD16) * 4 * 4);
/* size of SATQD matrix*/
size_satqd_weight_mat = ALIGN64(sizeof(UWORD16) * 9);
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
quant_params_t **ps_qp_params = ps_codec->as_process[i].ps_qp_params;
/* quantization param structure */
ps_qp_params[0] = (quant_params_t *) (pu1_buf + total_size);
total_size = total_size + size_quant_param;
ps_qp_params[1] = (quant_params_t *) (pu1_buf + total_size);
total_size = total_size + size_quant_param;
ps_qp_params[2] = (quant_params_t *) (pu1_buf + total_size);
total_size = total_size + size_quant_param;
/* threshold matrix for quantization */
ps_qp_params[0]->pu2_thres_mat = (void *) (pu1_buf + total_size);
total_size = total_size + size_thres_mat;
ps_qp_params[1]->pu2_thres_mat = (void *) (pu1_buf + total_size);
total_size = total_size + size_thres_mat;
ps_qp_params[2]->pu2_thres_mat = (void *) (pu1_buf + total_size);
total_size = total_size + size_thres_mat;
/* fwd weight matrix */
ps_qp_params[0]->pu2_weigh_mat = (void *) (pu1_buf + total_size);
total_size = total_size + size_fwd_weight_mat;
ps_qp_params[1]->pu2_weigh_mat = (void *) (pu1_buf + total_size);
total_size = total_size + size_fwd_weight_mat;
ps_qp_params[2]->pu2_weigh_mat = (void *) (pu1_buf + total_size);
total_size = total_size + size_fwd_weight_mat;
/* threshold matrix for SATQD */
ps_qp_params[0]->pu2_sad_thrsh = (void *) (pu1_buf + total_size);
total_size = total_size + size_satqd_weight_mat;
ps_qp_params[1]->pu2_sad_thrsh = (void *) (pu1_buf + total_size);
total_size = total_size + size_satqd_weight_mat;
ps_qp_params[2]->pu2_sad_thrsh = (void *) (pu1_buf + total_size);
total_size = total_size + size_satqd_weight_mat;
total_size = ALIGN128(total_size);
}
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_TOP_ROW_SYN_INFO];
{
/* total size of the mem record */
WORD32 total_size = 0, size_csbp, size_intra_modes, size_mv;
/* pointer to buffer */
UWORD8 *pu1_buf = ps_mem_rec->pv_base;
/* size in bytes to store 1 row of mb_info_t */
/* one additional mb, to avoid checking end of row condition */
size_csbp = (max_mb_cols + 1) * sizeof(mb_info_t);
/* size in bytes to store 1 row of intra macroblock sub modes */
size_intra_modes = max_mb_cols * sizeof(UWORD8) * 16;
/* size in bytes to store 1 row + 1 of enc_pu_t */
/* one additional mb, to avoid checking end of row condition */
size_mv = (max_mb_cols + 1) * sizeof(enc_pu_t);
/* total size per proc ctxt */
total_size = size_csbp + size_intra_modes + size_mv;
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
if (i < MAX_PROCESS_CTXT / MAX_CTXT_SETS)
{
ps_codec->as_process[i].ps_top_row_mb_syntax_ele_base =
(mb_info_t *) pu1_buf;
ps_codec->as_process[i].pu1_top_mb_intra_modes_base = pu1_buf
+ size_csbp;
ps_codec->as_process[i].ps_top_row_pu_base =
(enc_pu_t *) (pu1_buf + size_csbp
+ size_intra_modes);
}
else
{
ps_codec->as_process[i].ps_top_row_mb_syntax_ele_base =
(mb_info_t *) (pu1_buf + total_size);
ps_codec->as_process[i].pu1_top_mb_intra_modes_base = pu1_buf
+ total_size + size_csbp;
ps_codec->as_process[i].ps_top_row_pu_base =
(enc_pu_t *) (pu1_buf + total_size + size_csbp
+ size_intra_modes);
}
}
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_BS_QP];
{
UWORD8 *pu1_buf_ping, *pu1_buf_pong;
/* total size of the mem record */
WORD32 total_size = 0;
/* size in bytes to store vertical edge bs, horizontal edge bs and qp of every mb*/
WORD32 vert_bs_size, horz_bs_size, qp_size;
/* vertical edge bs = total number of vertical edges * number of bytes per each edge */
/* total num of v edges = total mb * 4 (assuming transform_8x8_flag = 0),
* each edge is formed by 4 pairs of subblks, requiring 4 bytes to storing bs */
vert_bs_size = ALIGN64(max_mb_cnt * 4 * 4);
/* horizontal edge bs = total number of horizontal edges * number of bytes per each edge */
/* total num of h edges = total mb * 4 (assuming transform_8x8_flag = 0),
* each edge is formed by 4 pairs of subblks, requiring 4 bytes to storing bs */
horz_bs_size = ALIGN64(max_mb_cnt * 4 * 4);
/* qp of each mb requires 1 byte */
qp_size = ALIGN64(max_mb_cnt);
/* total size */
total_size = vert_bs_size + horz_bs_size + qp_size;
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
if (i < MAX_PROCESS_CTXT / MAX_CTXT_SETS)
{
pu1_buf_ping = (UWORD8 *) ps_mem_rec->pv_base;
/* vertical edge bs storage space */
ps_codec->as_process[i].s_deblk_ctxt.s_bs_ctxt.pu4_pic_vert_bs =
(UWORD32 *) pu1_buf_ping;
pu1_buf_ping += vert_bs_size;
/* horizontal edge bs storage space */
ps_codec->as_process[i].s_deblk_ctxt.s_bs_ctxt.pu4_pic_horz_bs =
(UWORD32 *) pu1_buf_ping;
pu1_buf_ping += horz_bs_size;
/* qp */
ps_codec->as_process[i].s_deblk_ctxt.s_bs_ctxt.pu1_pic_qp =
(UWORD8 *) pu1_buf_ping;
pu1_buf_ping += qp_size;
}
else
{
pu1_buf_pong = (UWORD8 *) ps_mem_rec->pv_base;
pu1_buf_pong += total_size;
/* vertical edge bs storage space */
ps_codec->as_process[i].s_deblk_ctxt.s_bs_ctxt.pu4_pic_vert_bs =
(UWORD32 *) pu1_buf_pong;
pu1_buf_pong += vert_bs_size;
/* horizontal edge bs storage space */
ps_codec->as_process[i].s_deblk_ctxt.s_bs_ctxt.pu4_pic_horz_bs =
(UWORD32 *) pu1_buf_pong;
pu1_buf_pong += horz_bs_size;
/* qp */
ps_codec->as_process[i].s_deblk_ctxt.s_bs_ctxt.pu1_pic_qp =
(UWORD8 *) pu1_buf_pong;
pu1_buf_pong += qp_size;
}
}
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_INP_PIC];
{
ps_codec->pv_inp_buf_mgr_base = ps_mem_rec->pv_base;
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_OUT];
{
ps_codec->pv_out_buf_mgr_base = ps_mem_rec->pv_base;
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_CSC];
{
ps_codec->pu1_y_csc_buf_base = ps_mem_rec->pv_base;
ps_codec->pu1_uv_csc_buf_base = (UWORD8 *) ps_mem_rec->pv_base
+ (max_ht_luma * max_wd_luma);
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_REF_PIC];
{
/* size of buf mgr struct */
WORD32 size = ih264_buf_mgr_size();
/* temp var */
UWORD8 *pu1_buf = ps_mem_rec->pv_base;
/* pic buffer mgr */
ps_codec->pv_ref_buf_mgr_base = pu1_buf;
/* picture bank */
ps_codec->pv_pic_buf_base = pu1_buf + size;
ps_codec->i4_total_pic_buf_size = ps_mem_rec->u4_mem_size - size;
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_MB_INFO_NMB];
{
/* temp var */
UWORD8 *pu1_buf = ps_mem_rec->pv_base;
/* size of nmb ctxt */
WORD32 size = max_mb_cols * sizeof(mb_info_nmb_t);
WORD32 nmb_cntr, subpel_buf_size;
/* init nmb info structure pointer in all proc ctxts */
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
ps_codec->as_process[i].ps_nmb_info = (mb_info_nmb_t *) (pu1_buf);
pu1_buf += size;
}
subpel_buf_size = MB_SIZE * MB_SIZE * sizeof(UWORD8);
/* adjusting pointers for nmb halfpel buffer */
for (i = 0; i < MAX_PROCESS_CTXT; i++)
{
mb_info_nmb_t* ps_mb_info_nmb =
&ps_codec->as_process[i].ps_nmb_info[0];
for (nmb_cntr = 0; nmb_cntr < max_mb_cols; nmb_cntr++)
{
ps_mb_info_nmb[nmb_cntr].pu1_best_sub_pel_buf = pu1_buf;
pu1_buf = pu1_buf + subpel_buf_size;
ps_mb_info_nmb[nmb_cntr].u4_bst_spel_buf_strd = MB_SIZE;
}
}
}
ps_mem_rec = &ps_mem_rec_base[MEM_REC_RC];
{
ih264e_get_rate_control_mem_tab(&ps_codec->s_rate_control, ps_mem_rec,
USE_BASE);
}
/* init codec ctxt */
status = ih264e_init(ps_codec);
return status;
}
/**
*******************************************************************************
*
* @brief
* Retrieves mem records passed to the codec
*
* @par Description:
* Retrieves mem recs passed during init
*
* @param[in] ps_codec_obj
* Pointer to codec object at API level
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static WORD32 ih264e_retrieve_memrec(iv_obj_t *ps_codec_obj,
void *pv_api_ip,
void *pv_api_op)
{
/* codec ctxt */
codec_t *ps_codec = (codec_t *) ps_codec_obj->pv_codec_handle;
/* ctrl call I/O structures */
ih264e_retrieve_mem_rec_ip_t *ps_ip = pv_api_ip;
ih264e_retrieve_mem_rec_op_t *ps_op = pv_api_op;
if (ps_codec->i4_init_done != 1)
{
ps_op->s_ive_op.u4_error_code |= 1 << IVE_FATALERROR;
ps_op->s_ive_op.u4_error_code |= IH264E_INIT_NOT_DONE;
return IV_FAIL;
}
/* join threads upon at end of sequence */
ih264e_join_threads(ps_codec);
/* collect list of memory records used by the encoder library */
memcpy(ps_ip->s_ive_ip.ps_mem_rec, ps_codec->ps_mem_rec_backup,
MEM_REC_CNT * (sizeof(iv_mem_rec_t)));
ps_op->s_ive_op.u4_num_mem_rec_filled = MEM_REC_CNT;
/* clean up mutex memory */
ih264_list_free(ps_codec->pv_entropy_jobq);
ih264_list_free(ps_codec->pv_proc_jobq);
ithread_mutex_destroy(ps_codec->pv_ctl_mutex);
ithread_mutex_destroy(ps_codec->pv_entropy_mutex);
ih264_buf_mgr_free((buf_mgr_t *)ps_codec->pv_mv_buf_mgr);
ih264_buf_mgr_free((buf_mgr_t *)ps_codec->pv_ref_buf_mgr);
ih264_buf_mgr_free((buf_mgr_t *)ps_codec->pv_inp_buf_mgr);
ih264_buf_mgr_free((buf_mgr_t *)ps_codec->pv_out_buf_mgr);
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Sets the encoder in flush mode.
*
* @par Description:
* Sets the encoder in flush mode
*
* @param[in] ps_codec_obj
* Pointer to codec object at API level
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @returns error status
*
* @remarks This call has no real effect on encoder
*
*******************************************************************************
*/
static WORD32 ih264e_set_flush_mode(iv_obj_t *ps_codec_obj,
void *pv_api_ip,
void *pv_api_op)
{
/* codec ctxt */
codec_t *ps_codec = (codec_t *) ps_codec_obj->pv_codec_handle;
/* ctrl call I/O structures */
ih264e_ctl_flush_op_t *ps_ctl_op = pv_api_op;
UNUSED(pv_api_ip);
ps_ctl_op->s_ive_op.u4_error_code = 0;
/* signal flush frame control call */
ps_codec->i4_flush_mode = 1;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Gets encoder buffer requirements
*
* @par Description:
* Gets the encoder buffer requirements. Basing on max width and max height
* configuration settings, this routine, computes the sizes of necessary input,
* output buffers returns this info to callee.
*
* @param[in] ps_codec_obj
* Pointer to codec object at API level
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static WORD32 ih264e_get_buf_info(iv_obj_t *ps_codec_obj,
void *pv_api_ip,
void *pv_api_op)
{
/* ctrl call I/O structures */
ih264e_ctl_getbufinfo_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_getbufinfo_op_t *ps_op = pv_api_op;
/* temp var */
WORD32 wd = ALIGN16(ps_ip->s_ive_ip.u4_max_wd);
WORD32 ht = ALIGN16(ps_ip->s_ive_ip.u4_max_ht);
WORD32 i;
UNUSED(ps_codec_obj);
ps_op->s_ive_op.u4_error_code = 0;
/* Number of components in input buffers required for codec &
* Minimum sizes of each component in input buffer required */
if (ps_ip->s_ive_ip.e_inp_color_fmt == IV_YUV_420P)
{
ps_op->s_ive_op.u4_inp_comp_cnt = MIN_RAW_BUFS_420_COMP;
ps_op->s_ive_op.au4_min_in_buf_size[0] = wd * ht;
ps_op->s_ive_op.au4_min_in_buf_size[1] = (wd >> 1) * (ht >> 1);
ps_op->s_ive_op.au4_min_in_buf_size[2] = (wd >> 1) * (ht >> 1);
}
else if (ps_ip->s_ive_ip.e_inp_color_fmt == IV_YUV_422ILE)
{
ps_op->s_ive_op.u4_inp_comp_cnt = MIN_RAW_BUFS_422ILE_COMP;
ps_op->s_ive_op.au4_min_in_buf_size[0] = wd * ht * 2;
ps_op->s_ive_op.au4_min_in_buf_size[1] =
ps_op->s_ive_op.au4_min_in_buf_size[2] = 0;
}
else if (ps_ip->s_ive_ip.e_inp_color_fmt == IV_RGB_565)
{
ps_op->s_ive_op.u4_inp_comp_cnt = MIN_RAW_BUFS_RGB565_COMP;
ps_op->s_ive_op.au4_min_in_buf_size[0] = wd * ht * 2;
ps_op->s_ive_op.au4_min_in_buf_size[1] =
ps_op->s_ive_op.au4_min_in_buf_size[2] = 0;
}
else if (ps_ip->s_ive_ip.e_inp_color_fmt == IV_RGBA_8888)
{
ps_op->s_ive_op.u4_inp_comp_cnt = MIN_RAW_BUFS_RGBA8888_COMP;
ps_op->s_ive_op.au4_min_in_buf_size[0] = wd * ht * 4;
ps_op->s_ive_op.au4_min_in_buf_size[1] =
ps_op->s_ive_op.au4_min_in_buf_size[2] = 0;
}
else if ((ps_ip->s_ive_ip.e_inp_color_fmt == IV_YUV_420SP_UV)
|| (ps_ip->s_ive_ip.e_inp_color_fmt == IV_YUV_420SP_VU))
{
ps_op->s_ive_op.u4_inp_comp_cnt = MIN_RAW_BUFS_420SP_COMP;
ps_op->s_ive_op.au4_min_in_buf_size[0] = wd * ht;
ps_op->s_ive_op.au4_min_in_buf_size[1] = wd * (ht >> 1);
ps_op->s_ive_op.au4_min_in_buf_size[2] = 0;
}
/* Number of components in output buffers required for codec &
* Minimum sizes of each component in output buffer required */
ps_op->s_ive_op.u4_out_comp_cnt = MIN_BITS_BUFS_COMP;
for (i = 0; i < (WORD32) ps_op->s_ive_op.u4_out_comp_cnt; i++)
{
ps_op->s_ive_op.au4_min_out_buf_size[i] = MAX(((wd * ht * 3) >> 1), MIN_STREAM_SIZE);
}
ps_op->s_ive_op.u4_min_inp_bufs = MIN_INP_BUFS;
ps_op->s_ive_op.u4_min_out_bufs = MIN_OUT_BUFS;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Sets the picture dimensions
*
* @par Description:
* Sets width, height, display width, display height and strides
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @param[out] ps_cfg
* Pointer to config structure to be updated
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static IV_STATUS_T ih264e_set_dimensions(void *pv_api_ip,
void *pv_api_op,
cfg_params_t *ps_cfg)
{
/* ctrl call I/O structures */
ih264e_ctl_set_dimensions_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_dimensions_op_t *ps_op = pv_api_op;
ps_op->s_ive_op.u4_error_code = 0;
ps_cfg->u4_wd = ALIGN16(ps_ip->s_ive_ip.u4_wd);
ps_cfg->u4_ht = ALIGN16(ps_ip->s_ive_ip.u4_ht);
ps_cfg->i4_wd_mbs = ps_cfg->u4_wd >> 4;
ps_cfg->i4_ht_mbs = ps_cfg->u4_ht >> 4;
ps_cfg->u4_disp_wd = ps_ip->s_ive_ip.u4_wd;
ps_cfg->u4_disp_ht = ps_ip->s_ive_ip.u4_ht;
ps_cfg->u4_timestamp_high = ps_ip->s_ive_ip.u4_timestamp_high;
ps_cfg->u4_timestamp_low = ps_ip->s_ive_ip.u4_timestamp_low;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Sets source and target frame rates
*
* @par Description:
* Sets source and target frame rates
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @param[out] ps_cfg
* Pointer to config structure to be updated
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static IV_STATUS_T ih264e_set_frame_rate(void *pv_api_ip,
void *pv_api_op,
cfg_params_t *ps_cfg)
{
/* ctrl call I/O structures */
ih264e_ctl_set_frame_rate_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_frame_rate_op_t *ps_op = pv_api_op;
ps_op->s_ive_op.u4_error_code = 0;
ps_cfg->u4_src_frame_rate = ps_ip->s_ive_ip.u4_src_frame_rate;
ps_cfg->u4_tgt_frame_rate = ps_ip->s_ive_ip.u4_tgt_frame_rate;
ps_cfg->u4_timestamp_high = ps_ip->s_ive_ip.u4_timestamp_high;
ps_cfg->u4_timestamp_low = ps_ip->s_ive_ip.u4_timestamp_low;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Sets target bit rate
*
* @par Description:
* Sets target bit rate
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @param[out] ps_cfg
* Pointer to config structure to be updated
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static IV_STATUS_T ih264e_set_bit_rate(void *pv_api_ip,
void *pv_api_op,
cfg_params_t *ps_cfg)
{
/* ctrl call I/O structures */
ih264e_ctl_set_bitrate_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_bitrate_op_t *ps_op = pv_api_op;
ps_op->s_ive_op.u4_error_code = 0;
ps_cfg->u4_target_bitrate = ps_ip->s_ive_ip.u4_target_bitrate;
ps_cfg->u4_timestamp_high = ps_ip->s_ive_ip.u4_timestamp_high;
ps_cfg->u4_timestamp_low = ps_ip->s_ive_ip.u4_timestamp_low;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Sets frame type
*
* @par Description:
* Sets frame type
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @param[out] ps_cfg
* Pointer to config structure to be updated
*
* @returns error status
*
* @remarks not a sticky tag
*
*******************************************************************************
*/
static IV_STATUS_T ih264e_set_frame_type(void *pv_api_ip,
void *pv_api_op,
cfg_params_t *ps_cfg)
{
/* ctrl call I/O structures */
ih264e_ctl_set_frame_type_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_frame_type_op_t *ps_op = pv_api_op;
ps_op->s_ive_op.u4_error_code = 0;
ps_cfg->e_frame_type = ps_ip->s_ive_ip.e_frame_type;
ps_cfg->u4_timestamp_high = ps_ip->s_ive_ip.u4_timestamp_high;
ps_cfg->u4_timestamp_low = ps_ip->s_ive_ip.u4_timestamp_low;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Sets quantization params
*
* @par Description:
* Sets the max, min and default qp for I frame, P frame and B frame
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @param[out] ps_cfg
* Pointer to config structure to be updated
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static IV_STATUS_T ih264e_set_qp(void *pv_api_ip,
void *pv_api_op,
cfg_params_t *ps_cfg)
{
/* ctrl call I/O structures */
ih264e_ctl_set_qp_ip_t *ps_set_qp_ip = pv_api_ip;
ih264e_ctl_set_qp_op_t *ps_set_qp_op = pv_api_op;
ps_set_qp_op->s_ive_op.u4_error_code = 0;
ps_cfg->u4_i_qp_max = ps_set_qp_ip->s_ive_ip.u4_i_qp_max;
ps_cfg->u4_i_qp_min = ps_set_qp_ip->s_ive_ip.u4_i_qp_min;
ps_cfg->u4_i_qp = ps_set_qp_ip->s_ive_ip.u4_i_qp;
ps_cfg->u4_p_qp_max = ps_set_qp_ip->s_ive_ip.u4_p_qp_max;
ps_cfg->u4_p_qp_min = ps_set_qp_ip->s_ive_ip.u4_p_qp_min;
ps_cfg->u4_p_qp = ps_set_qp_ip->s_ive_ip.u4_p_qp;
ps_cfg->u4_b_qp_max = ps_set_qp_ip->s_ive_ip.u4_b_qp_max;
ps_cfg->u4_b_qp_min = ps_set_qp_ip->s_ive_ip.u4_b_qp_min;
ps_cfg->u4_b_qp = ps_set_qp_ip->s_ive_ip.u4_b_qp;
ps_cfg->u4_timestamp_high = ps_set_qp_ip->s_ive_ip.u4_timestamp_high;
ps_cfg->u4_timestamp_low = ps_set_qp_ip->s_ive_ip.u4_timestamp_low;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Sets encoding mode
*
* @par Description:
* Sets encoding mode
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @param[out] ps_cfg
* Pointer to config structure to be updated
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static IV_STATUS_T ih264e_set_enc_mode(void *pv_api_ip,
void *pv_api_op,
cfg_params_t *ps_cfg)
{
/* ctrl call I/O structures */
ih264e_ctl_set_enc_mode_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_enc_mode_op_t *ps_op = pv_api_op;
ps_op->s_ive_op.u4_error_code = 0;
ps_cfg->e_enc_mode = ps_ip->s_ive_ip.e_enc_mode;
ps_cfg->u4_timestamp_high = ps_ip->s_ive_ip.u4_timestamp_high;
ps_cfg->u4_timestamp_low = ps_ip->s_ive_ip.u4_timestamp_low;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Sets vbv parameters
*
* @par Description:
* Sets vbv parameters
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @param[out] ps_cfg
* Pointer to config structure to be updated
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static IV_STATUS_T ih264e_set_vbv_params(void *pv_api_ip,
void *pv_api_op,
cfg_params_t *ps_cfg)
{
/* ctrl call I/O structures */
ih264e_ctl_set_vbv_params_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_vbv_params_op_t *ps_op = pv_api_op;
ps_op->s_ive_op.u4_error_code = 0;
ps_cfg->u4_vbv_buf_size = ps_ip->s_ive_ip.u4_vbv_buf_size;
ps_cfg->u4_vbv_buffer_delay = ps_ip->s_ive_ip.u4_vbv_buffer_delay;
ps_cfg->u4_timestamp_high = ps_ip->s_ive_ip.u4_timestamp_high;
ps_cfg->u4_timestamp_low = ps_ip->s_ive_ip.u4_timestamp_low;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Sets AIR parameters
*
* @par Description:
* Sets AIR parameters
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @param[out] ps_cfg
* Pointer to config structure to be updated
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static IV_STATUS_T ih264_set_air_params(void *pv_api_ip,
void *pv_api_op,
cfg_params_t *ps_cfg)
{
/* ctrl call I/O structures */
ih264e_ctl_set_air_params_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_air_params_op_t *ps_op = pv_api_op;
ps_op->s_ive_op.u4_error_code = 0;
ps_cfg->e_air_mode = ps_ip->s_ive_ip.e_air_mode;
ps_cfg->u4_air_refresh_period = ps_ip->s_ive_ip.u4_air_refresh_period;
ps_cfg->u4_timestamp_high = ps_ip->s_ive_ip.u4_timestamp_high;
ps_cfg->u4_timestamp_low = ps_ip->s_ive_ip.u4_timestamp_low;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Sets motion estimation parameters
*
* @par Description:
* Sets motion estimation parameters
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @param[out] ps_cfg
* Pointer to config structure to be updated
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static IV_STATUS_T ih264_set_me_params(void *pv_api_ip,
void *pv_api_op,
cfg_params_t *ps_cfg)
{
/* ctrl call I/O structures */
ih264e_ctl_set_me_params_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_me_params_op_t *ps_op = pv_api_op;
ps_op->s_ive_op.u4_error_code = 0;
ps_cfg->u4_enable_hpel = ps_ip->s_ive_ip.u4_enable_hpel;
ps_cfg->u4_enable_qpel = ps_ip->s_ive_ip.u4_enable_qpel;
ps_cfg->u4_enable_fast_sad = ps_ip->s_ive_ip.u4_enable_fast_sad;
ps_cfg->u4_enable_alt_ref = ps_ip->s_ive_ip.u4_enable_alt_ref;
ps_cfg->u4_srch_rng_x = ps_ip->s_ive_ip.u4_srch_rng_x;
ps_cfg->u4_srch_rng_y = ps_ip->s_ive_ip.u4_srch_rng_y;
ps_cfg->u4_me_speed_preset = ps_ip->s_ive_ip.u4_me_speed_preset;
ps_cfg->u4_timestamp_high = ps_ip->s_ive_ip.u4_timestamp_high;
ps_cfg->u4_timestamp_low = ps_ip->s_ive_ip.u4_timestamp_low;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Sets Intra/Inter Prediction estimation parameters
*
* @par Description:
* Sets Intra/Inter Prediction estimation parameters
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @param[out] ps_cfg
* Pointer to config structure to be updated
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static IV_STATUS_T ih264_set_ipe_params(void *pv_api_ip,
void *pv_api_op,
cfg_params_t *ps_cfg)
{
/* ctrl call I/O structures */
ih264e_ctl_set_ipe_params_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_ipe_params_op_t *ps_op = pv_api_op;
ps_op->s_ive_op.u4_error_code = 0;
ps_cfg->u4_enable_intra_4x4 = ps_ip->s_ive_ip.u4_enable_intra_4x4;
ps_cfg->u4_enc_speed_preset = ps_ip->s_ive_ip.u4_enc_speed_preset;
ps_cfg->u4_timestamp_high = ps_ip->s_ive_ip.u4_timestamp_high;
ps_cfg->u4_timestamp_low = ps_ip->s_ive_ip.u4_timestamp_low;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Sets GOP parameters
*
* @par Description:
* Sets GOP parameters
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @param[out] ps_cfg
* Pointer to config structure to be updated
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static IV_STATUS_T ih264_set_gop_params(void *pv_api_ip,
void *pv_api_op,
cfg_params_t *ps_cfg)
{
/* ctrl call I/O structures */
ih264e_ctl_set_gop_params_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_gop_params_op_t *ps_op = pv_api_op;
ps_op->s_ive_op.u4_error_code = 0;
ps_cfg->u4_i_frm_interval = ps_ip->s_ive_ip.u4_i_frm_interval;
ps_cfg->u4_idr_frm_interval = ps_ip->s_ive_ip.u4_idr_frm_interval;
ps_cfg->u4_timestamp_high = ps_ip->s_ive_ip.u4_timestamp_high;
ps_cfg->u4_timestamp_low = ps_ip->s_ive_ip.u4_timestamp_low;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Sets profile parameters
*
* @par Description:
* Sets profile parameters
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @param[out] ps_cfg
* Pointer to config structure to be updated
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static IV_STATUS_T ih264_set_profile_params(void *pv_api_ip,
void *pv_api_op,
cfg_params_t *ps_cfg)
{
/* ctrl call I/O structures */
ih264e_ctl_set_profile_params_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_profile_params_op_t *ps_op = pv_api_op;
ps_op->s_ive_op.u4_error_code = 0;
ps_cfg->e_profile = ps_ip->s_ive_ip.e_profile;
ps_cfg->u4_entropy_coding_mode = ps_ip->s_ive_ip.u4_entropy_coding_mode;
ps_cfg->u4_timestamp_high = ps_ip->s_ive_ip.u4_timestamp_high;
ps_cfg->u4_timestamp_low = ps_ip->s_ive_ip.u4_timestamp_low;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Sets disable deblock level
*
* @par Description:
* Sets disable deblock level. Level 0 means no disabling and level 4 means
* disable completely. 1, 2, 3 are intermediate levels that control amount
* of deblocking done.
*
* @param[in] ps_codec_obj
* Pointer to codec object at API level
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static WORD32 ih264_set_deblock_params(void *pv_api_ip,
void *pv_api_op,
cfg_params_t *ps_cfg)
{
/* ctrl call I/O structures */
ih264e_ctl_set_deblock_params_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_deblock_params_op_t *ps_op = pv_api_op;
ps_op->s_ive_op.u4_error_code = 0;
ps_cfg->u4_disable_deblock_level = ps_ip->s_ive_ip.u4_disable_deblock_level;
ps_cfg->u4_timestamp_high = ps_ip->s_ive_ip.u4_timestamp_high;
ps_cfg->u4_timestamp_low = ps_ip->s_ive_ip.u4_timestamp_low;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Sets number of cores
*
* @par Description:
* Sets number of cores
*
* @param[in] ps_codec_obj
* Pointer to codec object at API level
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @returns error status
*
* @remarks The number of encoder threads is limited to MAX_PROCESS_THREADS
*
*******************************************************************************
*/
static WORD32 ih264e_set_num_cores(void *pv_api_ip,
void *pv_api_op,
cfg_params_t *ps_cfg)
{
/* ctrl call I/O structures */
ih264e_ctl_set_num_cores_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_set_num_cores_op_t *ps_op = pv_api_op;
ps_op->s_ive_op.u4_error_code = 0;
ps_cfg->u4_num_cores = MIN(ps_ip->s_ive_ip.u4_num_cores, MAX_PROCESS_THREADS);
ps_cfg->u4_timestamp_high = ps_ip->s_ive_ip.u4_timestamp_high;
ps_cfg->u4_timestamp_low = ps_ip->s_ive_ip.u4_timestamp_low;
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Resets encoder state
*
* @par Description:
* Resets encoder state by calling ih264e_init()
*
* @param[in] ps_codec_obj
* Pointer to codec object at API level
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static WORD32 ih264e_reset(iv_obj_t *ps_codec_obj,
void *pv_api_ip,
void *pv_api_op)
{
/* codec ctxt */
codec_t * ps_codec = (codec_t *) (ps_codec_obj->pv_codec_handle);
/* ctrl call I/O structures */
ih264e_ctl_reset_op_t *ps_op = pv_api_op;
UNUSED(pv_api_ip);
ps_op->s_ive_op.u4_error_code = 0;
if (ps_codec != NULL)
{
ih264e_init(ps_codec);
}
else
{
ps_op->s_ive_op.u4_error_code = IH264E_INIT_NOT_DONE;
}
return IV_SUCCESS;
}
/**
*******************************************************************************
*
* @brief
* Codec control call
*
* @par Description:
* Codec control call which in turn calls appropriate calls based on sub-command
*
* @param[in] ps_codec_obj
* Pointer to codec object at API level
*
* @param[in] pv_api_ip
* Pointer to input argument structure
*
* @param[out] pv_api_op
* Pointer to output argument structure
*
* @returns error status
*
* @remarks none
*
*******************************************************************************
*/
static WORD32 ih264e_ctl(iv_obj_t *ps_codec_obj,
void *pv_api_ip,
void *pv_api_op)
{
/* codec ctxt */
codec_t *ps_codec = (codec_t *) ps_codec_obj->pv_codec_handle;
/* ctrl call I/O structures */
ih264e_ctl_setdefault_ip_t *ps_ctl_ip = pv_api_ip;
ih264e_ctl_setdefault_op_t *ps_ctl_op = pv_api_op;
/* ctrl call sub cmd */
IVE_CONTROL_API_COMMAND_TYPE_T sub_cmd = ps_ctl_ip->s_ive_ip.e_sub_cmd;
/* error status */
IV_STATUS_T ret = IV_SUCCESS;
/* temp var */
WORD32 i;
cfg_params_t *ps_cfg = NULL;
/* control call is for configuring encoding params, this is not to be called
* before a successful init call */
if (ps_codec->i4_init_done != 1)
{
ps_ctl_op->s_ive_op.u4_error_code |= 1 << IVE_FATALERROR;
ps_ctl_op->s_ive_op.u4_error_code |= IH264E_INIT_NOT_DONE;
return IV_FAIL;
}
/* make it thread safe */
ithread_mutex_lock(ps_codec->pv_ctl_mutex);
/* find a free config param set to hold current parameters */
for (i = 0; i < MAX_ACTIVE_CONFIG_PARAMS; i++)
{
if (0 == ps_codec->as_cfg[i].u4_is_valid)
{
ps_cfg = &ps_codec->as_cfg[i];
break;
}
}
/* If all are invalid, then start overwriting from the head config params */
if (NULL == ps_cfg)
{
ps_cfg = &ps_codec->as_cfg[0];
}
ps_cfg->u4_is_valid = 1;
ps_cfg->e_cmd = sub_cmd;
switch (sub_cmd)
{
case IVE_CMD_CTL_SET_DIMENSIONS:
ret = ih264e_set_dimensions(pv_api_ip, pv_api_op, ps_cfg);
break;
case IVE_CMD_CTL_SET_FRAMERATE:
ret = ih264e_set_frame_rate(pv_api_ip, pv_api_op, ps_cfg);
break;
case IVE_CMD_CTL_SET_BITRATE:
ret = ih264e_set_bit_rate(pv_api_ip, pv_api_op, ps_cfg);
break;
case IVE_CMD_CTL_SET_FRAMETYPE:
ret = ih264e_set_frame_type(pv_api_ip, pv_api_op, ps_cfg);
break;
case IVE_CMD_CTL_SET_QP:
ret = ih264e_set_qp(pv_api_ip, pv_api_op, ps_cfg);
break;
case IVE_CMD_CTL_SET_ENC_MODE:
ret = ih264e_set_enc_mode(pv_api_ip, pv_api_op, ps_cfg);
break;
case IVE_CMD_CTL_SET_VBV_PARAMS:
ret = ih264e_set_vbv_params(pv_api_ip, pv_api_op, ps_cfg);
break;
case IVE_CMD_CTL_SET_AIR_PARAMS:
ret = ih264_set_air_params(pv_api_ip, pv_api_op, ps_cfg);
break;
case IVE_CMD_CTL_SET_ME_PARAMS:
ret = ih264_set_me_params(pv_api_ip, pv_api_op, ps_cfg);
break;
case IVE_CMD_CTL_SET_IPE_PARAMS:
ret = ih264_set_ipe_params(pv_api_ip, pv_api_op, ps_cfg);
break;
case IVE_CMD_CTL_SET_GOP_PARAMS:
ret = ih264_set_gop_params(pv_api_ip, pv_api_op, ps_cfg);
break;
case IVE_CMD_CTL_SET_PROFILE_PARAMS:
ret = ih264_set_profile_params(pv_api_ip, pv_api_op, ps_cfg);
break;
case IVE_CMD_CTL_SET_DEBLOCK_PARAMS:
ret = ih264_set_deblock_params(pv_api_ip, pv_api_op, ps_cfg);
break;
case IVE_CMD_CTL_RESET:
/* invalidate config param struct as it is being served right away */
ps_codec->as_cfg[i].u4_is_valid = 0;
ret = ih264e_reset(ps_codec_obj, pv_api_ip, pv_api_op);
break;
case IVE_CMD_CTL_SETDEFAULT:
{
/* ctrl call I/O structures */
ih264e_ctl_setdefault_op_t *ps_op = pv_api_op;
/* invalidate config param struct as it is being served right away */
ps_codec->as_cfg[i].u4_is_valid = 0;
/* error status */
ret = ih264e_set_default_params(ps_cfg);
ps_op->s_ive_op.u4_error_code = ret;
break;
}
case IVE_CMD_CTL_FLUSH:
/* invalidate config param struct as it is being served right away */
ps_codec->as_cfg[i].u4_is_valid = 0;
ret = ih264e_set_flush_mode(ps_codec_obj, pv_api_ip, pv_api_op);
break;
case IVE_CMD_CTL_GETBUFINFO:
/* invalidate config param struct as it is being served right away */
ps_codec->as_cfg[i].u4_is_valid = 0;
ret = ih264e_get_buf_info(ps_codec_obj, pv_api_ip, pv_api_op);
break;
case IVE_CMD_CTL_GETVERSION:
{
/* ctrl call I/O structures */
ih264e_ctl_getversioninfo_ip_t *ps_ip = pv_api_ip;
ih264e_ctl_getversioninfo_op_t *ps_op = pv_api_op;
/* invalidate config param struct as it is being served right away */
ps_codec->as_cfg[i].u4_is_valid = 0;
/* error status */
ps_op->s_ive_op.u4_error_code = IV_SUCCESS;
if (ps_ip->s_ive_ip.u4_version_bufsize <= 0)
{
ps_op->s_ive_op.u4_error_code =
IH264E_CXA_VERS_BUF_INSUFFICIENT;
ret = IV_FAIL;
}
else
{
ret = ih264e_get_version((CHAR *) ps_ip->s_ive_ip.pu1_version,
ps_ip->s_ive_ip.u4_version_bufsize);
if (ret != IV_SUCCESS)
{
ps_op->s_ive_op.u4_error_code =
IH264E_CXA_VERS_BUF_INSUFFICIENT;
ret = IV_FAIL;
}
}
break;
}
case IVE_CMD_CTL_SET_NUM_CORES:
ret = ih264e_set_num_cores(pv_api_ip, pv_api_op, ps_cfg);
break;
default:
/* invalidate config param struct as it is being served right away */
ps_codec->as_cfg[i].u4_is_valid = 0;
DEBUG("Warning !! unrecognized control api command \n");
break;
}
ithread_mutex_unlock(ps_codec->pv_ctl_mutex);
return ret;
}
/**
*******************************************************************************
*
* @brief
* Codec entry point function. All the function calls to the codec are done
* using this function with different values specified in command
*
* @par Description:
* Arguments are tested for validity and then based on the command
* appropriate function is called
*
* @param[in] ps_handle
* API level handle for codec
*
* @param[in] pv_api_ip
* Input argument structure
*
* @param[out] pv_api_op
* Output argument structure
*
* @returns error_status
*
* @remarks
*
*******************************************************************************
*/
IV_STATUS_T ih264e_api_function(iv_obj_t *ps_handle,
void *pv_api_ip,
void *pv_api_op)
{
/* api command */
WORD32 command = IV_CMD_NA;
/* error status */
IV_STATUS_T e_status;
WORD32 ret;
/* tmp var */
WORD32 *pu4_ptr_cmd = (WORD32 *) pv_api_ip;
/* validate input / output structures */
e_status = api_check_struct_sanity(ps_handle, pv_api_ip, pv_api_op);
if (e_status != IV_SUCCESS)
{
DEBUG("error code = %d\n", *((UWORD32 *)pv_api_op + 1));
return IV_FAIL;
}
pu4_ptr_cmd++;
command = *pu4_ptr_cmd;
switch (command)
{
case IV_CMD_GET_NUM_MEM_REC:
ret = ih264e_get_num_rec(pv_api_ip, pv_api_op);
break;
case IV_CMD_FILL_NUM_MEM_REC:
ret = ih264e_fill_num_mem_rec(pv_api_ip, pv_api_op);
break;
case IV_CMD_INIT:
ret = ih264e_init_mem_rec(ps_handle, pv_api_ip, pv_api_op);
break;
case IV_CMD_RETRIEVE_MEMREC:
ret = ih264e_retrieve_memrec(ps_handle, pv_api_ip, pv_api_op);
break;
case IVE_CMD_VIDEO_CTL:
ret = ih264e_ctl(ps_handle, pv_api_ip, pv_api_op);
break;
case IVE_CMD_VIDEO_ENCODE:
ret = ih264e_encode(ps_handle, pv_api_ip, pv_api_op);
break;
default:
ret = IV_FAIL;
break;
}
return (IV_STATUS_T) ret;
}