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|
/*
* Copyright © 2012 Intel Corporation
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the
* "Software"), to deal in the Software without restriction, including
* without limitation the rights to use, copy, modify, merge, publish,
* distribute, sub license, and/or sell copies of the Software, and to
* permit persons to whom the Software is furnished to do so, subject to
* the following conditions:
*
* The above copyright notice and this permission notice (including the
* next paragraph) shall be included in all copies or substantial portions
* of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
* OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT.
* IN NO EVENT SHALL PRECISION INSIGHT AND/OR ITS SUPPLIERS BE LIABLE FOR
* ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*
* Authors:
* Zhao Yakui <yakui.zhao@intel.com>
* Xiang Haihao <haihao.xiang@intel.com>
*
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>
#include <assert.h>
#include "intel_batchbuffer.h"
#include "i965_defines.h"
#include "i965_structs.h"
#include "i965_drv_video.h"
#include "i965_encoder.h"
#include "i965_encoder_api.h"
#include "i965_encoder_utils.h"
#include "gen6_mfc.h"
#include "gen6_vme.h"
#include "intel_media.h"
#include <va/va_enc_jpeg.h>
#include "vp8_probs.h"
#define SURFACE_STATE_PADDED_SIZE SURFACE_STATE_PADDED_SIZE_GEN8
#define SURFACE_STATE_OFFSET(index) (SURFACE_STATE_PADDED_SIZE * index)
#define BINDING_TABLE_OFFSET(index) (SURFACE_STATE_OFFSET(MAX_MEDIA_SURFACES_GEN6) + sizeof(unsigned int) * index)
#define MFC_SOFTWARE_BATCH 0
#define B0_STEP_REV 2
#define IS_STEPPING_BPLUS(i965) ((i965->intel.revision) >= B0_STEP_REV)
//Zigzag scan order of the the Luma and Chroma components
//Note: Jpeg Spec ISO/IEC 10918-1, Figure A.6 shows the zigzag order differently.
//The Spec is trying to show the zigzag pattern with number positions. The below
//table will use the pattern shown by A.6 and map the position of the elements in the array
static const uint32_t zigzag_direct[64] = {
0, 1, 8, 16, 9, 2, 3, 10,
17, 24, 32, 25, 18, 11, 4, 5,
12, 19, 26, 33, 40, 48, 41, 34,
27, 20, 13, 6, 7, 14, 21, 28,
35, 42, 49, 56, 57, 50, 43, 36,
29, 22, 15, 23, 30, 37, 44, 51,
58, 59, 52, 45, 38, 31, 39, 46,
53, 60, 61, 54, 47, 55, 62, 63
};
//Default Luminance quantization table
//Source: Jpeg Spec ISO/IEC 10918-1, Annex K, Table K.1
static const uint8_t jpeg_luma_quant[64] = {
16, 11, 10, 16, 24, 40, 51, 61,
12, 12, 14, 19, 26, 58, 60, 55,
14, 13, 16, 24, 40, 57, 69, 56,
14, 17, 22, 29, 51, 87, 80, 62,
18, 22, 37, 56, 68, 109, 103, 77,
24, 35, 55, 64, 81, 104, 113, 92,
49, 64, 78, 87, 103, 121, 120, 101,
72, 92, 95, 98, 112, 100, 103, 99
};
//Default Chroma quantization table
//Source: Jpeg Spec ISO/IEC 10918-1, Annex K, Table K.2
static const uint8_t jpeg_chroma_quant[64] = {
17, 18, 24, 47, 99, 99, 99, 99,
18, 21, 26, 66, 99, 99, 99, 99,
24, 26, 56, 99, 99, 99, 99, 99,
47, 66, 99, 99, 99, 99, 99, 99,
99, 99, 99, 99, 99, 99, 99, 99,
99, 99, 99, 99, 99, 99, 99, 99,
99, 99, 99, 99, 99, 99, 99, 99,
99, 99, 99, 99, 99, 99, 99, 99
};
static const int va_to_gen7_jpeg_hufftable[2] = {
MFX_HUFFTABLE_ID_Y,
MFX_HUFFTABLE_ID_UV
};
static const uint32_t gen8_mfc_batchbuffer_avc[][4] = {
#include "shaders/utils/mfc_batchbuffer_hsw.g8b"
};
static const uint32_t gen9_mfc_batchbuffer_avc[][4] = {
#include "shaders/utils/mfc_batchbuffer_hsw.g9b"
};
static struct i965_kernel gen8_mfc_kernels[] = {
{
"MFC AVC INTRA BATCHBUFFER ",
MFC_BATCHBUFFER_AVC_INTRA,
gen8_mfc_batchbuffer_avc,
sizeof(gen8_mfc_batchbuffer_avc),
NULL
},
};
static struct i965_kernel gen9_mfc_kernels[] = {
{
"MFC AVC INTRA BATCHBUFFER ",
MFC_BATCHBUFFER_AVC_INTRA,
gen9_mfc_batchbuffer_avc,
sizeof(gen9_mfc_batchbuffer_avc),
NULL
},
};
static const uint32_t qm_flat[16] = {
0x10101010, 0x10101010, 0x10101010, 0x10101010,
0x10101010, 0x10101010, 0x10101010, 0x10101010,
0x10101010, 0x10101010, 0x10101010, 0x10101010,
0x10101010, 0x10101010, 0x10101010, 0x10101010
};
static const uint32_t fqm_flat[32] = {
0x10001000, 0x10001000, 0x10001000, 0x10001000,
0x10001000, 0x10001000, 0x10001000, 0x10001000,
0x10001000, 0x10001000, 0x10001000, 0x10001000,
0x10001000, 0x10001000, 0x10001000, 0x10001000,
0x10001000, 0x10001000, 0x10001000, 0x10001000,
0x10001000, 0x10001000, 0x10001000, 0x10001000,
0x10001000, 0x10001000, 0x10001000, 0x10001000,
0x10001000, 0x10001000, 0x10001000, 0x10001000
};
#define INTER_MODE_MASK 0x03
#define INTER_8X8 0x03
#define INTER_16X8 0x01
#define INTER_8X16 0x02
#define SUBMB_SHAPE_MASK 0x00FF00
#define INTER_16X16 0x00
#define INTER_MV8 (4 << 20)
#define INTER_MV32 (6 << 20)
static void
gen8_mfc_pipe_mode_select(VADriverContextP ctx,
int standard_select,
struct intel_encoder_context *encoder_context)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
assert(standard_select == MFX_FORMAT_MPEG2 ||
standard_select == MFX_FORMAT_AVC ||
standard_select == MFX_FORMAT_JPEG ||
standard_select == MFX_FORMAT_VP8);
BEGIN_BCS_BATCH(batch, 5);
OUT_BCS_BATCH(batch, MFX_PIPE_MODE_SELECT | (5 - 2));
OUT_BCS_BATCH(batch,
(MFX_LONG_MODE << 17) | /* Must be long format for encoder */
(MFD_MODE_VLD << 15) | /* VLD mode */
(0 << 10) | /* Stream-Out Enable */
((!!mfc_context->post_deblocking_output.bo) << 9) | /* Post Deblocking Output */
((!!mfc_context->pre_deblocking_output.bo) << 8) | /* Pre Deblocking Output */
(0 << 6) | /* frame statistics stream-out enable*/
(0 << 5) | /* not in stitch mode */
(1 << 4) | /* encoding mode */
(standard_select << 0)); /* standard select: avc or mpeg2 or jpeg*/
OUT_BCS_BATCH(batch,
(0 << 7) | /* expand NOA bus flag */
(0 << 6) | /* disable slice-level clock gating */
(0 << 5) | /* disable clock gating for NOA */
(0 << 4) | /* terminate if AVC motion and POC table error occurs */
(0 << 3) | /* terminate if AVC mbdata error occurs */
(0 << 2) | /* terminate if AVC CABAC/CAVLC decode error occurs */
(0 << 1) |
(0 << 0));
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
ADVANCE_BCS_BATCH(batch);
}
static void
gen8_mfc_surface_state(VADriverContextP ctx, struct intel_encoder_context *encoder_context)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
BEGIN_BCS_BATCH(batch, 6);
OUT_BCS_BATCH(batch, MFX_SURFACE_STATE | (6 - 2));
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch,
((mfc_context->surface_state.height - 1) << 18) |
((mfc_context->surface_state.width - 1) << 4));
OUT_BCS_BATCH(batch,
(MFX_SURFACE_PLANAR_420_8 << 28) | /* 420 planar YUV surface */
(1 << 27) | /* must be 1 for interleave U/V, hardware requirement */
(0 << 22) | /* surface object control state, FIXME??? */
((mfc_context->surface_state.w_pitch - 1) << 3) | /* pitch */
(0 << 2) | /* must be 0 for interleave U/V */
(1 << 1) | /* must be tiled */
(I965_TILEWALK_YMAJOR << 0)); /* tile walk, TILEWALK_YMAJOR */
OUT_BCS_BATCH(batch,
(0 << 16) | /* must be 0 for interleave U/V */
(mfc_context->surface_state.h_pitch)); /* y offset for U(cb) */
OUT_BCS_BATCH(batch, 0);
ADVANCE_BCS_BATCH(batch);
}
static void
gen8_mfc_ind_obj_base_addr_state(VADriverContextP ctx,
struct intel_encoder_context *encoder_context)
{
struct i965_driver_data *i965 = i965_driver_data(ctx);
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
struct gen6_vme_context *vme_context = encoder_context->vme_context;
int vme_size;
unsigned int bse_offset;
BEGIN_BCS_BATCH(batch, 26);
OUT_BCS_BATCH(batch, MFX_IND_OBJ_BASE_ADDR_STATE | (26 - 2));
/* the DW1-3 is for the MFX indirect bistream offset */
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
/* the DW4-5 is the MFX upper bound */
if (encoder_context->codec == CODEC_VP8) {
OUT_BCS_RELOC64(batch,
mfc_context->mfc_indirect_pak_bse_object.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
mfc_context->mfc_indirect_pak_bse_object.end_offset);
} else {
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
}
if (encoder_context->codec != CODEC_JPEG) {
vme_size = vme_context->vme_output.size_block * vme_context->vme_output.num_blocks;
/* the DW6-10 is for MFX Indirect MV Object Base Address */
OUT_BCS_RELOC64(batch, vme_context->vme_output.bo, I915_GEM_DOMAIN_INSTRUCTION, 0, 0);
OUT_BCS_BATCH(batch, i965->intel.mocs_state);
OUT_BCS_RELOC64(batch, vme_context->vme_output.bo, I915_GEM_DOMAIN_INSTRUCTION, 0, vme_size);
} else {
/* No VME for JPEG */
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
}
/* the DW11-15 is for MFX IT-COFF. Not used on encoder */
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
/* the DW16-20 is for MFX indirect DBLK. Not used on encoder */
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
/* the DW21-25 is for MFC Indirect PAK-BSE Object Base Address for Encoder*/
bse_offset = (encoder_context->codec == CODEC_JPEG) ? (mfc_context->mfc_indirect_pak_bse_object.offset) : 0;
OUT_BCS_RELOC64(batch,
mfc_context->mfc_indirect_pak_bse_object.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
bse_offset);
OUT_BCS_BATCH(batch, i965->intel.mocs_state);
OUT_BCS_RELOC64(batch,
mfc_context->mfc_indirect_pak_bse_object.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
mfc_context->mfc_indirect_pak_bse_object.end_offset);
ADVANCE_BCS_BATCH(batch);
}
static void
gen8_mfc_avc_img_state(VADriverContextP ctx, struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
VAEncPictureParameterBufferH264 *pPicParameter = (VAEncPictureParameterBufferH264 *)encode_state->pic_param_ext->buffer;
int width_in_mbs = (mfc_context->surface_state.width + 15) / 16;
int height_in_mbs = (mfc_context->surface_state.height + 15) / 16;
BEGIN_BCS_BATCH(batch, 16);
OUT_BCS_BATCH(batch, MFX_AVC_IMG_STATE | (16 - 2));
/*DW1. MB setting of frame */
OUT_BCS_BATCH(batch,
((width_in_mbs * height_in_mbs - 1) & 0xFFFF));
OUT_BCS_BATCH(batch,
((height_in_mbs - 1) << 16) |
((width_in_mbs - 1) << 0));
/* DW3 QP setting */
OUT_BCS_BATCH(batch,
(0 << 24) | /* Second Chroma QP Offset */
(0 << 16) | /* Chroma QP Offset */
(0 << 14) | /* Max-bit conformance Intra flag */
(0 << 13) | /* Max Macroblock size conformance Inter flag */
(pPicParameter->pic_fields.bits.weighted_pred_flag << 12) | /*Weighted_Pred_Flag */
(pPicParameter->pic_fields.bits.weighted_bipred_idc << 10) | /* Weighted_BiPred_Idc */
(0 << 8) | /* FIXME: Image Structure */
(0 << 0)); /* Current Decoed Image Frame Store ID, reserved in Encode mode */
OUT_BCS_BATCH(batch,
(0 << 16) | /* Mininum Frame size */
(0 << 15) | /* Disable reading of Macroblock Status Buffer */
(0 << 14) | /* Load BitStream Pointer only once, 1 slic 1 frame */
(0 << 13) | /* CABAC 0 word insertion test enable */
(1 << 12) | /* MVUnpackedEnable,compliant to DXVA */
(1 << 10) | /* Chroma Format IDC, 4:2:0 */
(0 << 8) | /* FIXME: MbMvFormatFlag */
(pPicParameter->pic_fields.bits.entropy_coding_mode_flag << 7) | /*0:CAVLC encoding mode,1:CABAC*/
(0 << 6) | /* Only valid for VLD decoding mode */
(0 << 5) | /* Constrained Intra Predition Flag, from PPS */
(0 << 4) | /* Direct 8x8 inference flag */
(pPicParameter->pic_fields.bits.transform_8x8_mode_flag << 3) | /*8x8 or 4x4 IDCT Transform Mode Flag*/
(1 << 2) | /* Frame MB only flag */
(0 << 1) | /* MBAFF mode is in active */
(0 << 0)); /* Field picture flag */
/* DW5 Trellis quantization */
OUT_BCS_BATCH(batch, 0); /* Mainly about MB rate control and debug, just ignoring */
OUT_BCS_BATCH(batch, /* Inter and Intra Conformance Max size limit */
(0xBB8 << 16) | /* InterMbMaxSz */
(0xEE8)); /* IntraMbMaxSz */
OUT_BCS_BATCH(batch, 0); /* Reserved */
/* DW8. QP delta */
OUT_BCS_BATCH(batch, 0); /* Slice QP Delta for bitrate control */
OUT_BCS_BATCH(batch, 0); /* Slice QP Delta for bitrate control */
/* DW10. Bit setting for MB */
OUT_BCS_BATCH(batch, 0x8C000000);
OUT_BCS_BATCH(batch, 0x00010000);
/* DW12. */
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0x02010100);
/* DW14. For short format */
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
ADVANCE_BCS_BATCH(batch);
}
static void
gen8_mfc_qm_state(VADriverContextP ctx,
int qm_type,
const uint32_t *qm,
int qm_length,
struct intel_encoder_context *encoder_context)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
unsigned int qm_buffer[16];
assert(qm_length <= 16);
assert(sizeof(*qm) == 4);
memcpy(qm_buffer, qm, qm_length * 4);
BEGIN_BCS_BATCH(batch, 18);
OUT_BCS_BATCH(batch, MFX_QM_STATE | (18 - 2));
OUT_BCS_BATCH(batch, qm_type << 0);
intel_batchbuffer_data(batch, qm_buffer, 16 * 4);
ADVANCE_BCS_BATCH(batch);
}
static void
gen8_mfc_avc_qm_state(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
const unsigned int *qm_4x4_intra;
const unsigned int *qm_4x4_inter;
const unsigned int *qm_8x8_intra;
const unsigned int *qm_8x8_inter;
VAEncSequenceParameterBufferH264 *pSeqParameter =
(VAEncSequenceParameterBufferH264 *)encode_state->seq_param_ext->buffer;
VAEncPictureParameterBufferH264 *pPicParameter =
(VAEncPictureParameterBufferH264 *)encode_state->pic_param_ext->buffer;
if (!pSeqParameter->seq_fields.bits.seq_scaling_matrix_present_flag
&& !pPicParameter->pic_fields.bits.pic_scaling_matrix_present_flag) {
qm_4x4_intra = qm_4x4_inter = qm_8x8_intra = qm_8x8_inter = qm_flat;
} else {
VAIQMatrixBufferH264 *qm;
assert(encode_state->q_matrix && encode_state->q_matrix->buffer);
qm = (VAIQMatrixBufferH264 *)encode_state->q_matrix->buffer;
qm_4x4_intra = (unsigned int *)qm->ScalingList4x4[0];
qm_4x4_inter = (unsigned int *)qm->ScalingList4x4[3];
qm_8x8_intra = (unsigned int *)qm->ScalingList8x8[0];
qm_8x8_inter = (unsigned int *)qm->ScalingList8x8[1];
}
gen8_mfc_qm_state(ctx, MFX_QM_AVC_4X4_INTRA_MATRIX, qm_4x4_intra, 12, encoder_context);
gen8_mfc_qm_state(ctx, MFX_QM_AVC_4X4_INTER_MATRIX, qm_4x4_inter, 12, encoder_context);
gen8_mfc_qm_state(ctx, MFX_QM_AVC_8x8_INTRA_MATRIX, qm_8x8_intra, 16, encoder_context);
gen8_mfc_qm_state(ctx, MFX_QM_AVC_8x8_INTER_MATRIX, qm_8x8_inter, 16, encoder_context);
}
static void
gen8_mfc_fqm_state(VADriverContextP ctx,
int fqm_type,
const uint32_t *fqm,
int fqm_length,
struct intel_encoder_context *encoder_context)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
unsigned int fqm_buffer[32];
assert(fqm_length <= 32);
assert(sizeof(*fqm) == 4);
memcpy(fqm_buffer, fqm, fqm_length * 4);
BEGIN_BCS_BATCH(batch, 34);
OUT_BCS_BATCH(batch, MFX_FQM_STATE | (34 - 2));
OUT_BCS_BATCH(batch, fqm_type << 0);
intel_batchbuffer_data(batch, fqm_buffer, 32 * 4);
ADVANCE_BCS_BATCH(batch);
}
static void
gen8_mfc_avc_fill_fqm(uint8_t *qm, uint16_t *fqm, int len)
{
int i, j;
for (i = 0; i < len; i++)
for (j = 0; j < len; j++)
fqm[i * len + j] = (1 << 16) / qm[j * len + i];
}
static void
gen8_mfc_avc_fqm_state(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
VAEncSequenceParameterBufferH264 *pSeqParameter =
(VAEncSequenceParameterBufferH264 *)encode_state->seq_param_ext->buffer;
VAEncPictureParameterBufferH264 *pPicParameter =
(VAEncPictureParameterBufferH264 *)encode_state->pic_param_ext->buffer;
if (!pSeqParameter->seq_fields.bits.seq_scaling_matrix_present_flag
&& !pPicParameter->pic_fields.bits.pic_scaling_matrix_present_flag) {
gen8_mfc_fqm_state(ctx, MFX_QM_AVC_4X4_INTRA_MATRIX, fqm_flat, 24, encoder_context);
gen8_mfc_fqm_state(ctx, MFX_QM_AVC_4X4_INTER_MATRIX, fqm_flat, 24, encoder_context);
gen8_mfc_fqm_state(ctx, MFX_QM_AVC_8x8_INTRA_MATRIX, fqm_flat, 32, encoder_context);
gen8_mfc_fqm_state(ctx, MFX_QM_AVC_8x8_INTER_MATRIX, fqm_flat, 32, encoder_context);
} else {
int i;
uint32_t fqm[32];
VAIQMatrixBufferH264 *qm;
assert(encode_state->q_matrix && encode_state->q_matrix->buffer);
qm = (VAIQMatrixBufferH264 *)encode_state->q_matrix->buffer;
for (i = 0; i < 3; i++)
gen8_mfc_avc_fill_fqm(qm->ScalingList4x4[i], (uint16_t *)fqm + 16 * i, 4);
gen8_mfc_fqm_state(ctx, MFX_QM_AVC_4X4_INTRA_MATRIX, fqm, 24, encoder_context);
for (i = 3; i < 6; i++)
gen8_mfc_avc_fill_fqm(qm->ScalingList4x4[i], (uint16_t *)fqm + 16 * (i - 3), 4);
gen8_mfc_fqm_state(ctx, MFX_QM_AVC_4X4_INTER_MATRIX, fqm, 24, encoder_context);
gen8_mfc_avc_fill_fqm(qm->ScalingList8x8[0], (uint16_t *)fqm, 8);
gen8_mfc_fqm_state(ctx, MFX_QM_AVC_8x8_INTRA_MATRIX, fqm, 32, encoder_context);
gen8_mfc_avc_fill_fqm(qm->ScalingList8x8[1], (uint16_t *)fqm, 8);
gen8_mfc_fqm_state(ctx, MFX_QM_AVC_8x8_INTER_MATRIX, fqm, 32, encoder_context);
}
}
static void
gen8_mfc_avc_insert_object(VADriverContextP ctx, struct intel_encoder_context *encoder_context,
unsigned int *insert_data, int lenght_in_dws, int data_bits_in_last_dw,
int skip_emul_byte_count, int is_last_header, int is_end_of_slice, int emulation_flag,
struct intel_batchbuffer *batch)
{
if (batch == NULL)
batch = encoder_context->base.batch;
if (data_bits_in_last_dw == 0)
data_bits_in_last_dw = 32;
BEGIN_BCS_BATCH(batch, lenght_in_dws + 2);
OUT_BCS_BATCH(batch, MFX_INSERT_OBJECT | (lenght_in_dws + 2 - 2));
OUT_BCS_BATCH(batch,
(0 << 16) | /* always start at offset 0 */
(data_bits_in_last_dw << 8) |
(skip_emul_byte_count << 4) |
(!!emulation_flag << 3) |
((!!is_last_header) << 2) |
((!!is_end_of_slice) << 1) |
(0 << 0)); /* FIXME: ??? */
intel_batchbuffer_data(batch, insert_data, lenght_in_dws * 4);
ADVANCE_BCS_BATCH(batch);
}
static void gen8_mfc_init(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct i965_driver_data *i965 = i965_driver_data(ctx);
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
dri_bo *bo;
int i;
int width_in_mbs = 0;
int height_in_mbs = 0;
int slice_batchbuffer_size;
if (encoder_context->codec == CODEC_H264 ||
encoder_context->codec == CODEC_H264_MVC) {
VAEncSequenceParameterBufferH264 *pSequenceParameter = (VAEncSequenceParameterBufferH264 *)encode_state->seq_param_ext->buffer;
width_in_mbs = pSequenceParameter->picture_width_in_mbs;
height_in_mbs = pSequenceParameter->picture_height_in_mbs;
} else if (encoder_context->codec == CODEC_MPEG2) {
VAEncSequenceParameterBufferMPEG2 *pSequenceParameter = (VAEncSequenceParameterBufferMPEG2 *)encode_state->seq_param_ext->buffer;
assert(encoder_context->codec == CODEC_MPEG2);
width_in_mbs = ALIGN(pSequenceParameter->picture_width, 16) / 16;
height_in_mbs = ALIGN(pSequenceParameter->picture_height, 16) / 16;
} else {
assert(encoder_context->codec == CODEC_JPEG);
VAEncPictureParameterBufferJPEG *pic_param = (VAEncPictureParameterBufferJPEG *)encode_state->pic_param_ext->buffer;
width_in_mbs = ALIGN(pic_param->picture_width, 16) / 16;
height_in_mbs = ALIGN(pic_param->picture_height, 16) / 16;
}
slice_batchbuffer_size = 64 * width_in_mbs * height_in_mbs + 4096 +
(SLICE_HEADER + SLICE_TAIL) * encode_state->num_slice_params_ext;
/*Encode common setup for MFC*/
dri_bo_unreference(mfc_context->post_deblocking_output.bo);
mfc_context->post_deblocking_output.bo = NULL;
dri_bo_unreference(mfc_context->pre_deblocking_output.bo);
mfc_context->pre_deblocking_output.bo = NULL;
dri_bo_unreference(mfc_context->uncompressed_picture_source.bo);
mfc_context->uncompressed_picture_source.bo = NULL;
dri_bo_unreference(mfc_context->mfc_indirect_pak_bse_object.bo);
mfc_context->mfc_indirect_pak_bse_object.bo = NULL;
for (i = 0; i < NUM_MFC_DMV_BUFFERS; i++) {
if (mfc_context->direct_mv_buffers[i].bo != NULL)
dri_bo_unreference(mfc_context->direct_mv_buffers[i].bo);
mfc_context->direct_mv_buffers[i].bo = NULL;
}
for (i = 0; i < MAX_MFC_REFERENCE_SURFACES; i++) {
if (mfc_context->reference_surfaces[i].bo != NULL)
dri_bo_unreference(mfc_context->reference_surfaces[i].bo);
mfc_context->reference_surfaces[i].bo = NULL;
}
dri_bo_unreference(mfc_context->intra_row_store_scratch_buffer.bo);
bo = dri_bo_alloc(i965->intel.bufmgr,
"Buffer",
width_in_mbs * 64,
64);
assert(bo);
mfc_context->intra_row_store_scratch_buffer.bo = bo;
dri_bo_unreference(mfc_context->macroblock_status_buffer.bo);
bo = dri_bo_alloc(i965->intel.bufmgr,
"Buffer",
width_in_mbs * height_in_mbs * 16,
64);
assert(bo);
mfc_context->macroblock_status_buffer.bo = bo;
dri_bo_unreference(mfc_context->deblocking_filter_row_store_scratch_buffer.bo);
bo = dri_bo_alloc(i965->intel.bufmgr,
"Buffer",
4 * width_in_mbs * 64, /* 4 * width_in_mbs * 64 */
64);
assert(bo);
mfc_context->deblocking_filter_row_store_scratch_buffer.bo = bo;
dri_bo_unreference(mfc_context->bsd_mpc_row_store_scratch_buffer.bo);
bo = dri_bo_alloc(i965->intel.bufmgr,
"Buffer",
2 * width_in_mbs * 64, /* 2 * width_in_mbs * 64 */
0x1000);
assert(bo);
mfc_context->bsd_mpc_row_store_scratch_buffer.bo = bo;
dri_bo_unreference(mfc_context->mfc_batchbuffer_surface.bo);
mfc_context->mfc_batchbuffer_surface.bo = NULL;
dri_bo_unreference(mfc_context->aux_batchbuffer_surface.bo);
mfc_context->aux_batchbuffer_surface.bo = NULL;
if (mfc_context->aux_batchbuffer)
intel_batchbuffer_free(mfc_context->aux_batchbuffer);
mfc_context->aux_batchbuffer = intel_batchbuffer_new(&i965->intel, I915_EXEC_BSD, slice_batchbuffer_size);
mfc_context->aux_batchbuffer_surface.bo = mfc_context->aux_batchbuffer->buffer;
dri_bo_reference(mfc_context->aux_batchbuffer_surface.bo);
mfc_context->aux_batchbuffer_surface.pitch = 16;
mfc_context->aux_batchbuffer_surface.num_blocks = mfc_context->aux_batchbuffer->size / 16;
mfc_context->aux_batchbuffer_surface.size_block = 16;
gen8_gpe_context_init(ctx, &mfc_context->gpe_context);
}
static void
gen8_mfc_pipe_buf_addr_state(VADriverContextP ctx,
struct intel_encoder_context *encoder_context)
{
struct i965_driver_data *i965 = i965_driver_data(ctx);
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
int i;
BEGIN_BCS_BATCH(batch, 61);
OUT_BCS_BATCH(batch, MFX_PIPE_BUF_ADDR_STATE | (61 - 2));
/* the DW1-3 is for pre_deblocking */
if (mfc_context->pre_deblocking_output.bo)
OUT_BCS_RELOC64(batch, mfc_context->pre_deblocking_output.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0);
else {
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0); /* pre output addr */
}
OUT_BCS_BATCH(batch, i965->intel.mocs_state);
/* the DW4-6 is for the post_deblocking */
if (mfc_context->post_deblocking_output.bo)
OUT_BCS_RELOC64(batch, mfc_context->post_deblocking_output.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0); /* post output addr */
else {
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
}
OUT_BCS_BATCH(batch, i965->intel.mocs_state);
/* the DW7-9 is for the uncompressed_picture */
OUT_BCS_RELOC64(batch, mfc_context->uncompressed_picture_source.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0); /* uncompressed data */
OUT_BCS_BATCH(batch, i965->intel.mocs_state);
/* the DW10-12 is for the mb status */
OUT_BCS_RELOC64(batch, mfc_context->macroblock_status_buffer.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0); /* StreamOut data*/
OUT_BCS_BATCH(batch, i965->intel.mocs_state);
/* the DW13-15 is for the intra_row_store_scratch */
OUT_BCS_RELOC64(batch, mfc_context->intra_row_store_scratch_buffer.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0);
OUT_BCS_BATCH(batch, i965->intel.mocs_state);
/* the DW16-18 is for the deblocking filter */
OUT_BCS_RELOC64(batch, mfc_context->deblocking_filter_row_store_scratch_buffer.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0);
OUT_BCS_BATCH(batch, i965->intel.mocs_state);
/* the DW 19-50 is for Reference pictures*/
for (i = 0; i < ARRAY_ELEMS(mfc_context->reference_surfaces); i++) {
if (mfc_context->reference_surfaces[i].bo != NULL) {
OUT_BCS_RELOC64(batch, mfc_context->reference_surfaces[i].bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0);
} else {
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
}
}
OUT_BCS_BATCH(batch, i965->intel.mocs_state);
/* The DW 52-54 is for the MB status buffer */
OUT_BCS_RELOC64(batch, mfc_context->macroblock_status_buffer.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0); /* Macroblock status buffer*/
OUT_BCS_BATCH(batch, i965->intel.mocs_state);
/* the DW 55-57 is the ILDB buffer */
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
/* the DW 58-60 is the second ILDB buffer */
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
ADVANCE_BCS_BATCH(batch);
}
static void
gen10_mfc_pipe_buf_addr_state(VADriverContextP ctx,
struct intel_encoder_context *encoder_context)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
int i;
BEGIN_BCS_BATCH(batch, 68);
OUT_BCS_BATCH(batch, MFX_PIPE_BUF_ADDR_STATE | (68 - 2));
/* the DW1-3 is for pre_deblocking */
if (mfc_context->pre_deblocking_output.bo)
OUT_BCS_RELOC64(batch, mfc_context->pre_deblocking_output.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0);
else {
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
}
OUT_BCS_BATCH(batch, 0);
/* the DW4-6 is for the post_deblocking */
if (mfc_context->post_deblocking_output.bo)
OUT_BCS_RELOC64(batch, mfc_context->post_deblocking_output.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0);
else {
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
}
OUT_BCS_BATCH(batch, 0);
/* the DW7-9 is for the uncompressed_picture */
OUT_BCS_RELOC64(batch, mfc_context->uncompressed_picture_source.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0); /* uncompressed data */
OUT_BCS_BATCH(batch, 0);
/* the DW10-12 is for the mb status */
OUT_BCS_RELOC64(batch, mfc_context->macroblock_status_buffer.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0); /* StreamOut data*/
OUT_BCS_BATCH(batch, 0);
/* the DW13-15 is for the intra_row_store_scratch */
OUT_BCS_RELOC64(batch, mfc_context->intra_row_store_scratch_buffer.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0);
OUT_BCS_BATCH(batch, 0);
/* the DW16-18 is for the deblocking filter */
OUT_BCS_RELOC64(batch, mfc_context->deblocking_filter_row_store_scratch_buffer.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0);
OUT_BCS_BATCH(batch, 0);
/* the DW 19-50 is for Reference pictures*/
for (i = 0; i < ARRAY_ELEMS(mfc_context->reference_surfaces); i++) {
if (mfc_context->reference_surfaces[i].bo != NULL) {
OUT_BCS_RELOC64(batch, mfc_context->reference_surfaces[i].bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0);
} else {
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
}
}
OUT_BCS_BATCH(batch, 0);
/* The DW 52-54 is for the MB status buffer */
OUT_BCS_RELOC64(batch, mfc_context->macroblock_status_buffer.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0);
OUT_BCS_BATCH(batch, 0);
/* the DW 55-57 is the ILDB buffer */
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
/* the DW 58-60 is the second ILDB buffer */
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
/* DW 61. Determine whether the compressed mode is used for Reference. */
OUT_BCS_BATCH(batch, 0);
/* DW 62..64. Scaled surface */
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
/* DW 65..67. Slice size streamout data */
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
ADVANCE_BCS_BATCH(batch);
}
static void
gen8_mfc_avc_directmode_state(VADriverContextP ctx,
struct intel_encoder_context *encoder_context)
{
struct i965_driver_data *i965 = i965_driver_data(ctx);
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
int i;
BEGIN_BCS_BATCH(batch, 71);
OUT_BCS_BATCH(batch, MFX_AVC_DIRECTMODE_STATE | (71 - 2));
/* Reference frames and Current frames */
/* the DW1-32 is for the direct MV for reference */
for (i = 0; i < NUM_MFC_DMV_BUFFERS - 2; i += 2) {
if (mfc_context->direct_mv_buffers[i].bo != NULL) {
OUT_BCS_RELOC64(batch, mfc_context->direct_mv_buffers[i].bo,
I915_GEM_DOMAIN_INSTRUCTION, 0,
0);
} else {
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
}
}
OUT_BCS_BATCH(batch, i965->intel.mocs_state);
/* the DW34-36 is the MV for the current reference */
OUT_BCS_RELOC64(batch, mfc_context->direct_mv_buffers[NUM_MFC_DMV_BUFFERS - 2].bo,
I915_GEM_DOMAIN_INSTRUCTION, 0,
0);
OUT_BCS_BATCH(batch, i965->intel.mocs_state);
/* POL list */
for (i = 0; i < 32; i++) {
OUT_BCS_BATCH(batch, i / 2);
}
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
ADVANCE_BCS_BATCH(batch);
}
static void
gen8_mfc_bsp_buf_base_addr_state(VADriverContextP ctx,
struct intel_encoder_context *encoder_context)
{
struct i965_driver_data *i965 = i965_driver_data(ctx);
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
BEGIN_BCS_BATCH(batch, 10);
OUT_BCS_BATCH(batch, MFX_BSP_BUF_BASE_ADDR_STATE | (10 - 2));
OUT_BCS_RELOC64(batch, mfc_context->bsd_mpc_row_store_scratch_buffer.bo,
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION,
0);
OUT_BCS_BATCH(batch, i965->intel.mocs_state);
/* the DW4-6 is for MPR Row Store Scratch Buffer Base Address */
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
/* the DW7-9 is for Bitplane Read Buffer Base Address */
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
ADVANCE_BCS_BATCH(batch);
}
static void gen8_mfc_avc_pipeline_picture_programing(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
mfc_context->pipe_mode_select(ctx, MFX_FORMAT_AVC, encoder_context);
mfc_context->set_surface_state(ctx, encoder_context);
mfc_context->ind_obj_base_addr_state(ctx, encoder_context);
gen8_mfc_pipe_buf_addr_state(ctx, encoder_context);
gen8_mfc_bsp_buf_base_addr_state(ctx, encoder_context);
mfc_context->avc_img_state(ctx, encode_state, encoder_context);
mfc_context->avc_qm_state(ctx, encode_state, encoder_context);
mfc_context->avc_fqm_state(ctx, encode_state, encoder_context);
gen8_mfc_avc_directmode_state(ctx, encoder_context);
intel_mfc_avc_ref_idx_state(ctx, encode_state, encoder_context);
}
static VAStatus gen8_mfc_run(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
intel_batchbuffer_flush(batch); //run the pipeline
return VA_STATUS_SUCCESS;
}
static VAStatus
gen8_mfc_stop(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context,
int *encoded_bits_size)
{
VAStatus vaStatus = VA_STATUS_ERROR_UNKNOWN;
VAEncPictureParameterBufferH264 *pPicParameter = (VAEncPictureParameterBufferH264 *)encode_state->pic_param_ext->buffer;
VACodedBufferSegment *coded_buffer_segment;
vaStatus = i965_MapBuffer(ctx, pPicParameter->coded_buf, (void **)&coded_buffer_segment);
assert(vaStatus == VA_STATUS_SUCCESS);
*encoded_bits_size = coded_buffer_segment->size * 8;
i965_UnmapBuffer(ctx, pPicParameter->coded_buf);
return VA_STATUS_SUCCESS;
}
static void
gen8_mfc_avc_slice_state(VADriverContextP ctx,
VAEncPictureParameterBufferH264 *pic_param,
VAEncSliceParameterBufferH264 *slice_param,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context,
int rate_control_enable,
int qp,
struct intel_batchbuffer *batch)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
int width_in_mbs = (mfc_context->surface_state.width + 15) / 16;
int height_in_mbs = (mfc_context->surface_state.height + 15) / 16;
int beginmb = slice_param->macroblock_address;
int endmb = beginmb + slice_param->num_macroblocks;
int beginx = beginmb % width_in_mbs;
int beginy = beginmb / width_in_mbs;
int nextx = endmb % width_in_mbs;
int nexty = endmb / width_in_mbs;
int slice_type = intel_avc_enc_slice_type_fixup(slice_param->slice_type);
int last_slice = (endmb == (width_in_mbs * height_in_mbs));
int maxQpN, maxQpP;
unsigned char correct[6], grow, shrink;
int i;
int weighted_pred_idc = 0;
unsigned int luma_log2_weight_denom = slice_param->luma_log2_weight_denom;
unsigned int chroma_log2_weight_denom = slice_param->chroma_log2_weight_denom;
int num_ref_l0 = 0, num_ref_l1 = 0;
if (batch == NULL)
batch = encoder_context->base.batch;
if (slice_type == SLICE_TYPE_I) {
luma_log2_weight_denom = 0;
chroma_log2_weight_denom = 0;
} else if (slice_type == SLICE_TYPE_P) {
weighted_pred_idc = pic_param->pic_fields.bits.weighted_pred_flag;
num_ref_l0 = pic_param->num_ref_idx_l0_active_minus1 + 1;
if (slice_param->num_ref_idx_active_override_flag)
num_ref_l0 = slice_param->num_ref_idx_l0_active_minus1 + 1;
} else if (slice_type == SLICE_TYPE_B) {
weighted_pred_idc = pic_param->pic_fields.bits.weighted_bipred_idc;
num_ref_l0 = pic_param->num_ref_idx_l0_active_minus1 + 1;
num_ref_l1 = pic_param->num_ref_idx_l1_active_minus1 + 1;
if (slice_param->num_ref_idx_active_override_flag) {
num_ref_l0 = slice_param->num_ref_idx_l0_active_minus1 + 1;
num_ref_l1 = slice_param->num_ref_idx_l1_active_minus1 + 1;
}
if (weighted_pred_idc == 2) {
/* 8.4.3 - Derivation process for prediction weights (8-279) */
luma_log2_weight_denom = 5;
chroma_log2_weight_denom = 5;
}
}
maxQpN = mfc_context->bit_rate_control_context[slice_type].MaxQpNegModifier;
maxQpP = mfc_context->bit_rate_control_context[slice_type].MaxQpPosModifier;
for (i = 0; i < 6; i++)
correct[i] = mfc_context->bit_rate_control_context[slice_type].Correct[i];
grow = mfc_context->bit_rate_control_context[slice_type].GrowInit +
(mfc_context->bit_rate_control_context[slice_type].GrowResistance << 4);
shrink = mfc_context->bit_rate_control_context[slice_type].ShrinkInit +
(mfc_context->bit_rate_control_context[slice_type].ShrinkResistance << 4);
BEGIN_BCS_BATCH(batch, 11);;
OUT_BCS_BATCH(batch, MFX_AVC_SLICE_STATE | (11 - 2));
OUT_BCS_BATCH(batch, slice_type); /*Slice Type: I:P:B Slice*/
OUT_BCS_BATCH(batch,
(num_ref_l0 << 16) |
(num_ref_l1 << 24) |
(chroma_log2_weight_denom << 8) |
(luma_log2_weight_denom << 0));
OUT_BCS_BATCH(batch,
(weighted_pred_idc << 30) |
(slice_param->direct_spatial_mv_pred_flag << 29) | /*Direct Prediction Type*/
(slice_param->disable_deblocking_filter_idc << 27) |
(slice_param->cabac_init_idc << 24) |
(qp << 16) | /*Slice Quantization Parameter*/
((slice_param->slice_beta_offset_div2 & 0xf) << 8) |
((slice_param->slice_alpha_c0_offset_div2 & 0xf) << 0));
OUT_BCS_BATCH(batch,
(beginy << 24) | /*First MB X&Y , the begin postion of current slice*/
(beginx << 16) |
slice_param->macroblock_address);
OUT_BCS_BATCH(batch, (nexty << 16) | nextx); /*Next slice first MB X&Y*/
OUT_BCS_BATCH(batch,
(0/*rate_control_enable*/ << 31) | /*in CBR mode RateControlCounterEnable = enable*/
(1 << 30) | /*ResetRateControlCounter*/
(0 << 28) | /*RC Triggle Mode = Always Rate Control*/
(4 << 24) | /*RC Stable Tolerance, middle level*/
(0/*rate_control_enable*/ << 23) | /*RC Panic Enable*/
(0 << 22) | /*QP mode, don't modfiy CBP*/
(0 << 21) | /*MB Type Direct Conversion Enabled*/
(0 << 20) | /*MB Type Skip Conversion Enabled*/
(last_slice << 19) | /*IsLastSlice*/
(0 << 18) | /*BitstreamOutputFlag Compressed BitStream Output Disable Flag 0:enable 1:disable*/
(1 << 17) | /*HeaderPresentFlag*/
(1 << 16) | /*SliceData PresentFlag*/
(1 << 15) | /*TailPresentFlag*/
(1 << 13) | /*RBSP NAL TYPE*/
(0 << 12)); /*CabacZeroWordInsertionEnable*/
OUT_BCS_BATCH(batch, mfc_context->mfc_indirect_pak_bse_object.offset);
OUT_BCS_BATCH(batch,
(maxQpN << 24) | /*Target QP - 24 is lowest QP*/
(maxQpP << 16) | /*Target QP + 20 is highest QP*/
(shrink << 8) |
(grow << 0));
OUT_BCS_BATCH(batch,
(correct[5] << 20) |
(correct[4] << 16) |
(correct[3] << 12) |
(correct[2] << 8) |
(correct[1] << 4) |
(correct[0] << 0));
OUT_BCS_BATCH(batch, 0);
ADVANCE_BCS_BATCH(batch);
}
#define AVC_INTRA_RDO_OFFSET 4
#define AVC_INTER_RDO_OFFSET 10
#define AVC_INTER_MSG_OFFSET 8
#define AVC_INTER_MV_OFFSET 48
#define AVC_RDO_MASK 0xFFFF
static int
gen8_mfc_avc_pak_object_intra(VADriverContextP ctx, int x, int y, int end_mb,
int qp, unsigned int *msg,
struct intel_encoder_context *encoder_context,
unsigned char target_mb_size, unsigned char max_mb_size,
struct intel_batchbuffer *batch)
{
int len_in_dwords = 12;
unsigned int intra_msg;
#define INTRA_MSG_FLAG (1 << 13)
#define INTRA_MBTYPE_MASK (0x1F0000)
if (batch == NULL)
batch = encoder_context->base.batch;
BEGIN_BCS_BATCH(batch, len_in_dwords);
intra_msg = msg[0] & 0xC0FF;
intra_msg |= INTRA_MSG_FLAG;
intra_msg |= ((msg[0] & INTRA_MBTYPE_MASK) >> 8);
OUT_BCS_BATCH(batch, MFC_AVC_PAK_OBJECT | (len_in_dwords - 2));
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch,
(0 << 24) | /* PackedMvNum, Debug*/
(0 << 20) | /* No motion vector */
(1 << 19) | /* CbpDcY */
(1 << 18) | /* CbpDcU */
(1 << 17) | /* CbpDcV */
intra_msg);
OUT_BCS_BATCH(batch, (0xFFFF << 16) | (y << 8) | x); /* Code Block Pattern for Y*/
OUT_BCS_BATCH(batch, 0x000F000F); /* Code Block Pattern */
OUT_BCS_BATCH(batch, (0 << 27) | (end_mb << 26) | qp); /* Last MB */
/*Stuff for Intra MB*/
OUT_BCS_BATCH(batch, msg[1]); /* We using Intra16x16 no 4x4 predmode*/
OUT_BCS_BATCH(batch, msg[2]);
OUT_BCS_BATCH(batch, msg[3] & 0xFF);
/*MaxSizeInWord and TargetSzieInWord*/
OUT_BCS_BATCH(batch, (max_mb_size << 24) |
(target_mb_size << 16));
OUT_BCS_BATCH(batch, 0);
ADVANCE_BCS_BATCH(batch);
return len_in_dwords;
}
static int
gen8_mfc_avc_pak_object_inter(VADriverContextP ctx, int x, int y, int end_mb, int qp,
unsigned int *msg, unsigned int offset,
struct intel_encoder_context *encoder_context,
unsigned char target_mb_size, unsigned char max_mb_size, int slice_type,
struct intel_batchbuffer *batch)
{
struct gen6_vme_context *vme_context = encoder_context->vme_context;
int len_in_dwords = 12;
unsigned int inter_msg = 0;
if (batch == NULL)
batch = encoder_context->base.batch;
{
#define MSG_MV_OFFSET 4
unsigned int *mv_ptr;
mv_ptr = msg + MSG_MV_OFFSET;
/* MV of VME output is based on 16 sub-blocks. So it is necessary
* to convert them to be compatible with the format of AVC_PAK
* command.
*/
if ((msg[0] & INTER_MODE_MASK) == INTER_8X16) {
/* MV[0] and MV[2] are replicated */
mv_ptr[4] = mv_ptr[0];
mv_ptr[5] = mv_ptr[1];
mv_ptr[2] = mv_ptr[8];
mv_ptr[3] = mv_ptr[9];
mv_ptr[6] = mv_ptr[8];
mv_ptr[7] = mv_ptr[9];
} else if ((msg[0] & INTER_MODE_MASK) == INTER_16X8) {
/* MV[0] and MV[1] are replicated */
mv_ptr[2] = mv_ptr[0];
mv_ptr[3] = mv_ptr[1];
mv_ptr[4] = mv_ptr[16];
mv_ptr[5] = mv_ptr[17];
mv_ptr[6] = mv_ptr[24];
mv_ptr[7] = mv_ptr[25];
} else if (((msg[0] & INTER_MODE_MASK) == INTER_8X8) &&
!(msg[1] & SUBMB_SHAPE_MASK)) {
/* Don't touch MV[0] or MV[1] */
mv_ptr[2] = mv_ptr[8];
mv_ptr[3] = mv_ptr[9];
mv_ptr[4] = mv_ptr[16];
mv_ptr[5] = mv_ptr[17];
mv_ptr[6] = mv_ptr[24];
mv_ptr[7] = mv_ptr[25];
}
}
BEGIN_BCS_BATCH(batch, len_in_dwords);
OUT_BCS_BATCH(batch, MFC_AVC_PAK_OBJECT | (len_in_dwords - 2));
inter_msg = 32;
/* MV quantity */
if ((msg[0] & INTER_MODE_MASK) == INTER_8X8) {
if (msg[1] & SUBMB_SHAPE_MASK)
inter_msg = 128;
}
OUT_BCS_BATCH(batch, inter_msg); /* 32 MV*/
OUT_BCS_BATCH(batch, offset);
inter_msg = msg[0] & (0x1F00FFFF);
inter_msg |= INTER_MV8;
inter_msg |= ((1 << 19) | (1 << 18) | (1 << 17));
if (((msg[0] & INTER_MODE_MASK) == INTER_8X8) &&
(msg[1] & SUBMB_SHAPE_MASK)) {
inter_msg |= INTER_MV32;
}
OUT_BCS_BATCH(batch, inter_msg);
OUT_BCS_BATCH(batch, (0xFFFF << 16) | (y << 8) | x); /* Code Block Pattern for Y*/
OUT_BCS_BATCH(batch, 0x000F000F); /* Code Block Pattern */
#if 0
if (slice_type == SLICE_TYPE_B) {
OUT_BCS_BATCH(batch, (0xF << 28) | (end_mb << 26) | qp); /* Last MB */
} else {
OUT_BCS_BATCH(batch, (end_mb << 26) | qp); /* Last MB */
}
#else
OUT_BCS_BATCH(batch, (end_mb << 26) | qp); /* Last MB */
#endif
inter_msg = msg[1] >> 8;
/*Stuff for Inter MB*/
OUT_BCS_BATCH(batch, inter_msg);
OUT_BCS_BATCH(batch, vme_context->ref_index_in_mb[0]);
OUT_BCS_BATCH(batch, vme_context->ref_index_in_mb[1]);
/*MaxSizeInWord and TargetSzieInWord*/
OUT_BCS_BATCH(batch, (max_mb_size << 24) |
(target_mb_size << 16));
OUT_BCS_BATCH(batch, 0x0);
ADVANCE_BCS_BATCH(batch);
return len_in_dwords;
}
static void
gen8_mfc_avc_pipeline_slice_programing(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context,
int slice_index,
struct intel_batchbuffer *slice_batch)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
struct gen6_vme_context *vme_context = encoder_context->vme_context;
VAEncSequenceParameterBufferH264 *pSequenceParameter = (VAEncSequenceParameterBufferH264 *)encode_state->seq_param_ext->buffer;
VAEncPictureParameterBufferH264 *pPicParameter = (VAEncPictureParameterBufferH264 *)encode_state->pic_param_ext->buffer;
VAEncSliceParameterBufferH264 *pSliceParameter = (VAEncSliceParameterBufferH264 *)encode_state->slice_params_ext[slice_index]->buffer;
unsigned int *msg = NULL, offset = 0;
unsigned char *msg_ptr = NULL;
int width_in_mbs = (mfc_context->surface_state.width + 15) / 16;
int height_in_mbs = (mfc_context->surface_state.height + 15) / 16;
int last_slice = (pSliceParameter->macroblock_address + pSliceParameter->num_macroblocks) == (width_in_mbs * height_in_mbs);
int i, x, y;
int qp = pPicParameter->pic_init_qp + pSliceParameter->slice_qp_delta;
unsigned int rate_control_mode = encoder_context->rate_control_mode;
unsigned int tail_data[] = { 0x0, 0x0 };
int slice_type = intel_avc_enc_slice_type_fixup(pSliceParameter->slice_type);
int is_intra = slice_type == SLICE_TYPE_I;
int qp_slice;
int qp_mb;
qp_slice = qp;
if (rate_control_mode != VA_RC_CQP) {
qp = mfc_context->brc.qp_prime_y[encoder_context->layer.curr_frame_layer_id][slice_type];
if (encode_state->slice_header_index[slice_index] == 0) {
pSliceParameter->slice_qp_delta = qp - pPicParameter->pic_init_qp;
qp_slice = qp;
}
}
/* only support for 8-bit pixel bit-depth */
assert(pSequenceParameter->bit_depth_luma_minus8 == 0);
assert(pSequenceParameter->bit_depth_chroma_minus8 == 0);
assert(pPicParameter->pic_init_qp < 52);
assert(qp >= 0 && qp < 52);
gen8_mfc_avc_slice_state(ctx,
pPicParameter,
pSliceParameter,
encode_state, encoder_context,
(rate_control_mode != VA_RC_CQP), qp_slice, slice_batch);
if (slice_index == 0) {
intel_avc_insert_aud_packed_data(ctx, encode_state, encoder_context, slice_batch);
intel_mfc_avc_pipeline_header_programing(ctx, encode_state, encoder_context, slice_batch);
}
intel_avc_slice_insert_packed_data(ctx, encode_state, encoder_context, slice_index, slice_batch);
dri_bo_map(vme_context->vme_output.bo, 1);
msg_ptr = (unsigned char *)vme_context->vme_output.bo->virtual;
msg = (unsigned int *)(msg_ptr + pSliceParameter->macroblock_address * vme_context->vme_output.size_block);
for (i = pSliceParameter->macroblock_address;
i < pSliceParameter->macroblock_address + pSliceParameter->num_macroblocks; i++) {
int last_mb = (i == (pSliceParameter->macroblock_address + pSliceParameter->num_macroblocks - 1));
x = i % width_in_mbs;
y = i / width_in_mbs;
msg = (unsigned int *)(msg_ptr + i * vme_context->vme_output.size_block);
if (vme_context->roi_enabled) {
qp_mb = *(vme_context->qp_per_mb + i);
} else
qp_mb = qp;
if (is_intra) {
assert(msg);
gen8_mfc_avc_pak_object_intra(ctx, x, y, last_mb, qp_mb, msg, encoder_context, 0, 0, slice_batch);
} else {
int inter_rdo, intra_rdo;
inter_rdo = msg[AVC_INTER_RDO_OFFSET] & AVC_RDO_MASK;
intra_rdo = msg[AVC_INTRA_RDO_OFFSET] & AVC_RDO_MASK;
offset = i * vme_context->vme_output.size_block + AVC_INTER_MV_OFFSET;
if (intra_rdo < inter_rdo) {
gen8_mfc_avc_pak_object_intra(ctx, x, y, last_mb, qp_mb, msg, encoder_context, 0, 0, slice_batch);
} else {
msg += AVC_INTER_MSG_OFFSET;
gen8_mfc_avc_pak_object_inter(ctx, x, y, last_mb, qp_mb, msg, offset, encoder_context, 0, 0, pSliceParameter->slice_type, slice_batch);
}
}
}
dri_bo_unmap(vme_context->vme_output.bo);
if (last_slice) {
mfc_context->insert_object(ctx, encoder_context,
tail_data, 2, 8,
2, 1, 1, 0, slice_batch);
} else {
mfc_context->insert_object(ctx, encoder_context,
tail_data, 1, 8,
1, 1, 1, 0, slice_batch);
}
}
static dri_bo *
gen8_mfc_avc_software_batchbuffer(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
struct intel_batchbuffer *batch;
dri_bo *batch_bo;
int i;
batch = mfc_context->aux_batchbuffer;
batch_bo = batch->buffer;
for (i = 0; i < encode_state->num_slice_params_ext; i++) {
gen8_mfc_avc_pipeline_slice_programing(ctx, encode_state, encoder_context, i, batch);
}
intel_batchbuffer_align(batch, 8);
BEGIN_BCS_BATCH(batch, 2);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, MI_BATCH_BUFFER_END);
ADVANCE_BCS_BATCH(batch);
dri_bo_reference(batch_bo);
intel_batchbuffer_free(batch);
mfc_context->aux_batchbuffer = NULL;
return batch_bo;
}
static void
gen8_mfc_batchbuffer_surfaces_input(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_vme_context *vme_context = encoder_context->vme_context;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
assert(vme_context->vme_output.bo);
mfc_context->buffer_suface_setup(ctx,
&mfc_context->gpe_context,
&vme_context->vme_output,
BINDING_TABLE_OFFSET(BIND_IDX_VME_OUTPUT),
SURFACE_STATE_OFFSET(BIND_IDX_VME_OUTPUT));
}
static void
gen8_mfc_batchbuffer_surfaces_output(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
assert(mfc_context->aux_batchbuffer_surface.bo);
mfc_context->buffer_suface_setup(ctx,
&mfc_context->gpe_context,
&mfc_context->aux_batchbuffer_surface,
BINDING_TABLE_OFFSET(BIND_IDX_MFC_BATCHBUFFER),
SURFACE_STATE_OFFSET(BIND_IDX_MFC_BATCHBUFFER));
}
static void
gen8_mfc_batchbuffer_surfaces_setup(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
gen8_mfc_batchbuffer_surfaces_input(ctx, encode_state, encoder_context);
gen8_mfc_batchbuffer_surfaces_output(ctx, encode_state, encoder_context);
}
static void
gen8_mfc_batchbuffer_idrt_setup(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
struct gen8_interface_descriptor_data *desc;
int i;
dri_bo *bo;
unsigned char *desc_ptr;
bo = mfc_context->gpe_context.idrt.bo;
dri_bo_map(bo, 1);
assert(bo->virtual);
desc_ptr = (unsigned char *)bo->virtual + mfc_context->gpe_context.idrt.offset;
desc = (struct gen8_interface_descriptor_data *)desc_ptr;
for (i = 0; i < mfc_context->gpe_context.num_kernels; i++) {
struct i965_kernel *kernel;
kernel = &mfc_context->gpe_context.kernels[i];
assert(sizeof(*desc) == 32);
/*Setup the descritor table*/
memset(desc, 0, sizeof(*desc));
desc->desc0.kernel_start_pointer = kernel->kernel_offset >> 6;
desc->desc3.sampler_count = 0;
desc->desc3.sampler_state_pointer = 0;
desc->desc4.binding_table_entry_count = 1;
desc->desc4.binding_table_pointer = (BINDING_TABLE_OFFSET(0) >> 5);
desc->desc5.constant_urb_entry_read_offset = 0;
desc->desc5.constant_urb_entry_read_length = 4;
desc++;
}
dri_bo_unmap(bo);
return;
}
static void
gen8_mfc_batchbuffer_constant_setup(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
(void)mfc_context;
}
#define AVC_PAK_LEN_IN_BYTE 48
#define AVC_PAK_LEN_IN_OWORD 3
static void
gen8_mfc_batchbuffer_emit_object_command(struct intel_batchbuffer *batch,
uint32_t intra_flag,
int head_offset,
int number_mb_cmds,
int slice_end_x,
int slice_end_y,
int mb_x,
int mb_y,
int width_in_mbs,
int qp,
uint32_t fwd_ref,
uint32_t bwd_ref)
{
uint32_t temp_value;
BEGIN_BATCH(batch, 14);
OUT_BATCH(batch, CMD_MEDIA_OBJECT | (14 - 2));
OUT_BATCH(batch, 0);
OUT_BATCH(batch, 0);
OUT_BATCH(batch, 0);
OUT_BATCH(batch, 0);
OUT_BATCH(batch, 0);
/*inline data */
OUT_BATCH(batch, head_offset / 16);
OUT_BATCH(batch, (intra_flag) | (qp << 16));
temp_value = (mb_x | (mb_y << 8) | (width_in_mbs << 16));
OUT_BATCH(batch, temp_value);
OUT_BATCH(batch, number_mb_cmds);
OUT_BATCH(batch,
((slice_end_y << 8) | (slice_end_x)));
OUT_BATCH(batch, fwd_ref);
OUT_BATCH(batch, bwd_ref);
OUT_BATCH(batch, MI_NOOP);
ADVANCE_BATCH(batch);
}
static void
gen8_mfc_avc_batchbuffer_slice_command(VADriverContextP ctx,
struct intel_encoder_context *encoder_context,
VAEncSliceParameterBufferH264 *slice_param,
int head_offset,
int qp,
int last_slice)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct gen6_vme_context *vme_context = encoder_context->vme_context;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
int width_in_mbs = (mfc_context->surface_state.width + 15) / 16;
int total_mbs = slice_param->num_macroblocks;
int slice_type = intel_avc_enc_slice_type_fixup(slice_param->slice_type);
int number_mb_cmds = 128;
int starting_offset = 0;
int mb_x, mb_y;
int last_mb, slice_end_x, slice_end_y;
int remaining_mb = total_mbs;
uint32_t fwd_ref, bwd_ref, mb_flag;
char tmp_qp;
int number_roi_mbs, max_mb_cmds, i;
last_mb = slice_param->macroblock_address + total_mbs - 1;
slice_end_x = last_mb % width_in_mbs;
slice_end_y = last_mb / width_in_mbs;
if (slice_type == SLICE_TYPE_I) {
fwd_ref = 0;
bwd_ref = 0;
mb_flag = 1;
} else {
fwd_ref = vme_context->ref_index_in_mb[0];
bwd_ref = vme_context->ref_index_in_mb[1];
mb_flag = 0;
}
if (width_in_mbs >= 100) {
number_mb_cmds = width_in_mbs / 5;
} else if (width_in_mbs >= 80) {
number_mb_cmds = width_in_mbs / 4;
} else if (width_in_mbs >= 60) {
number_mb_cmds = width_in_mbs / 3;
} else if (width_in_mbs >= 40) {
number_mb_cmds = width_in_mbs / 2;
} else {
number_mb_cmds = width_in_mbs;
}
max_mb_cmds = number_mb_cmds;
do {
mb_x = (slice_param->macroblock_address + starting_offset) % width_in_mbs;
mb_y = (slice_param->macroblock_address + starting_offset) / width_in_mbs;
number_mb_cmds = max_mb_cmds;
if (vme_context->roi_enabled) {
number_roi_mbs = 1;
tmp_qp = *(vme_context->qp_per_mb + starting_offset);
for (i = 1; i < max_mb_cmds; i++) {
if (tmp_qp != *(vme_context->qp_per_mb + starting_offset + i))
break;
number_roi_mbs++;
}
number_mb_cmds = number_roi_mbs;
qp = tmp_qp;
}
if (number_mb_cmds >= remaining_mb) {
number_mb_cmds = remaining_mb;
}
gen8_mfc_batchbuffer_emit_object_command(batch,
mb_flag,
head_offset,
number_mb_cmds,
slice_end_x,
slice_end_y,
mb_x,
mb_y,
width_in_mbs,
qp,
fwd_ref,
bwd_ref);
head_offset += (number_mb_cmds * AVC_PAK_LEN_IN_BYTE);
remaining_mb -= number_mb_cmds;
starting_offset += number_mb_cmds;
} while (remaining_mb > 0);
}
static void
gen8_mfc_avc_batchbuffer_slice(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context,
int slice_index)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
struct intel_batchbuffer *slice_batch = mfc_context->aux_batchbuffer;
VAEncSequenceParameterBufferH264 *pSequenceParameter = (VAEncSequenceParameterBufferH264 *)encode_state->seq_param_ext->buffer;
VAEncPictureParameterBufferH264 *pPicParameter = (VAEncPictureParameterBufferH264 *)encode_state->pic_param_ext->buffer;
VAEncSliceParameterBufferH264 *pSliceParameter = (VAEncSliceParameterBufferH264 *)encode_state->slice_params_ext[slice_index]->buffer;
int width_in_mbs = (mfc_context->surface_state.width + 15) / 16;
int height_in_mbs = (mfc_context->surface_state.height + 15) / 16;
int last_slice = (pSliceParameter->macroblock_address + pSliceParameter->num_macroblocks) == (width_in_mbs * height_in_mbs);
int qp = pPicParameter->pic_init_qp + pSliceParameter->slice_qp_delta;
unsigned int rate_control_mode = encoder_context->rate_control_mode;
unsigned int tail_data[] = { 0x0, 0x0 };
long head_offset;
int slice_type = intel_avc_enc_slice_type_fixup(pSliceParameter->slice_type);
int qp_slice;
qp_slice = qp;
if (rate_control_mode != VA_RC_CQP) {
qp = mfc_context->brc.qp_prime_y[encoder_context->layer.curr_frame_layer_id][slice_type];
if (encode_state->slice_header_index[slice_index] == 0) {
pSliceParameter->slice_qp_delta = qp - pPicParameter->pic_init_qp;
qp_slice = qp;
}
}
/* only support for 8-bit pixel bit-depth */
assert(pSequenceParameter->bit_depth_luma_minus8 == 0);
assert(pSequenceParameter->bit_depth_chroma_minus8 == 0);
assert(pPicParameter->pic_init_qp >= 0 && pPicParameter->pic_init_qp < 52);
assert(qp >= 0 && qp < 52);
gen8_mfc_avc_slice_state(ctx,
pPicParameter,
pSliceParameter,
encode_state,
encoder_context,
(rate_control_mode != VA_RC_CQP),
qp_slice,
slice_batch);
if (slice_index == 0) {
intel_avc_insert_aud_packed_data(ctx, encode_state, encoder_context, slice_batch);
intel_mfc_avc_pipeline_header_programing(ctx, encode_state, encoder_context, slice_batch);
}
intel_avc_slice_insert_packed_data(ctx, encode_state, encoder_context, slice_index, slice_batch);
intel_batchbuffer_align(slice_batch, 64); /* aligned by an Cache-line */
head_offset = intel_batchbuffer_used_size(slice_batch);
slice_batch->ptr += pSliceParameter->num_macroblocks * AVC_PAK_LEN_IN_BYTE;
gen8_mfc_avc_batchbuffer_slice_command(ctx,
encoder_context,
pSliceParameter,
head_offset,
qp,
last_slice);
/* Aligned for tail */
intel_batchbuffer_align(slice_batch, 64); /* aligned by Cache-line */
if (last_slice) {
mfc_context->insert_object(ctx,
encoder_context,
tail_data,
2,
8,
2,
1,
1,
0,
slice_batch);
} else {
mfc_context->insert_object(ctx,
encoder_context,
tail_data,
1,
8,
1,
1,
1,
0,
slice_batch);
}
return;
}
static void
gen8_mfc_avc_batchbuffer_pipeline(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct i965_driver_data *i965 = i965_driver_data(ctx);
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
struct intel_batchbuffer *batch = encoder_context->base.batch;
int i;
intel_batchbuffer_start_atomic(batch, 0x4000);
if (IS_GEN9(i965->intel.device_info) ||
IS_GEN10(i965->intel.device_info))
gen9_gpe_pipeline_setup(ctx, &mfc_context->gpe_context, batch);
else
gen8_gpe_pipeline_setup(ctx, &mfc_context->gpe_context, batch);
for (i = 0; i < encode_state->num_slice_params_ext; i++) {
gen8_mfc_avc_batchbuffer_slice(ctx, encode_state, encoder_context, i);
}
{
struct intel_batchbuffer *slice_batch = mfc_context->aux_batchbuffer;
intel_batchbuffer_align(slice_batch, 8);
BEGIN_BCS_BATCH(slice_batch, 2);
OUT_BCS_BATCH(slice_batch, 0);
OUT_BCS_BATCH(slice_batch, MI_BATCH_BUFFER_END);
ADVANCE_BCS_BATCH(slice_batch);
BEGIN_BATCH(batch, 2);
OUT_BATCH(batch, CMD_MEDIA_STATE_FLUSH);
OUT_BATCH(batch, 0);
ADVANCE_BATCH(batch);
intel_batchbuffer_free(slice_batch);
mfc_context->aux_batchbuffer = NULL;
}
if (IS_GEN9(i965->intel.device_info) ||
IS_GEN10(i965->intel.device_info))
gen9_gpe_pipeline_end(ctx, &mfc_context->gpe_context, batch);
intel_batchbuffer_end_atomic(batch);
intel_batchbuffer_flush(batch);
}
static void
gen8_mfc_build_avc_batchbuffer(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
gen8_mfc_batchbuffer_surfaces_setup(ctx, encode_state, encoder_context);
gen8_mfc_batchbuffer_idrt_setup(ctx, encode_state, encoder_context);
gen8_mfc_batchbuffer_constant_setup(ctx, encode_state, encoder_context);
gen8_mfc_avc_batchbuffer_pipeline(ctx, encode_state, encoder_context);
}
static dri_bo *
gen8_mfc_avc_hardware_batchbuffer(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
dri_bo_reference(mfc_context->aux_batchbuffer_surface.bo);
gen8_mfc_build_avc_batchbuffer(ctx, encode_state, encoder_context);
return mfc_context->aux_batchbuffer_surface.bo;
}
static void
gen8_mfc_avc_pipeline_programing(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
dri_bo *slice_batch_bo;
if (intel_mfc_interlace_check(ctx, encode_state, encoder_context)) {
fprintf(stderr, "Current VA driver don't support interlace mode!\n");
assert(0);
return;
}
if (encoder_context->soft_batch_force)
slice_batch_bo = gen8_mfc_avc_software_batchbuffer(ctx, encode_state, encoder_context);
else
slice_batch_bo = gen8_mfc_avc_hardware_batchbuffer(ctx, encode_state, encoder_context);
// begin programing
intel_batchbuffer_start_atomic_bcs(batch, 0x4000);
intel_batchbuffer_emit_mi_flush(batch);
// picture level programing
gen8_mfc_avc_pipeline_picture_programing(ctx, encode_state, encoder_context);
BEGIN_BCS_BATCH(batch, 3);
OUT_BCS_BATCH(batch, MI_BATCH_BUFFER_START | (1 << 8) | (1 << 0));
OUT_BCS_RELOC64(batch,
slice_batch_bo,
I915_GEM_DOMAIN_COMMAND, 0,
0);
ADVANCE_BCS_BATCH(batch);
// end programing
intel_batchbuffer_end_atomic(batch);
dri_bo_unreference(slice_batch_bo);
}
static VAStatus
gen8_mfc_avc_encode_picture(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
unsigned int rate_control_mode = encoder_context->rate_control_mode;
int current_frame_bits_size;
int sts;
for (;;) {
gen8_mfc_init(ctx, encode_state, encoder_context);
intel_mfc_avc_prepare(ctx, encode_state, encoder_context);
/*Programing bcs pipeline*/
gen8_mfc_avc_pipeline_programing(ctx, encode_state, encoder_context); //filling the pipeline
gen8_mfc_run(ctx, encode_state, encoder_context);
if (rate_control_mode == VA_RC_CBR || rate_control_mode == VA_RC_VBR) {
gen8_mfc_stop(ctx, encode_state, encoder_context, ¤t_frame_bits_size);
sts = intel_mfc_brc_postpack(encode_state, encoder_context, current_frame_bits_size);
if (sts == BRC_NO_HRD_VIOLATION) {
intel_mfc_hrd_context_update(encode_state, mfc_context);
break;
} else if (sts == BRC_OVERFLOW_WITH_MIN_QP || sts == BRC_UNDERFLOW_WITH_MAX_QP) {
if (!mfc_context->hrd.violation_noted) {
fprintf(stderr, "Unrepairable %s!\n", (sts == BRC_OVERFLOW_WITH_MIN_QP) ? "overflow" : "underflow");
mfc_context->hrd.violation_noted = 1;
}
return VA_STATUS_SUCCESS;
}
} else {
break;
}
}
return VA_STATUS_SUCCESS;
}
/*
* MPEG-2
*/
static const int
va_to_gen8_mpeg2_picture_type[3] = {
1, /* I */
2, /* P */
3 /* B */
};
static void
gen8_mfc_mpeg2_pic_state(VADriverContextP ctx,
struct intel_encoder_context *encoder_context,
struct encode_state *encode_state)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
VAEncPictureParameterBufferMPEG2 *pic_param;
int width_in_mbs = (mfc_context->surface_state.width + 15) / 16;
int height_in_mbs = (mfc_context->surface_state.height + 15) / 16;
VAEncSliceParameterBufferMPEG2 *slice_param = NULL;
assert(encode_state->pic_param_ext && encode_state->pic_param_ext->buffer);
pic_param = (VAEncPictureParameterBufferMPEG2 *)encode_state->pic_param_ext->buffer;
slice_param = (VAEncSliceParameterBufferMPEG2 *)encode_state->slice_params_ext[0]->buffer;
BEGIN_BCS_BATCH(batch, 13);
OUT_BCS_BATCH(batch, MFX_MPEG2_PIC_STATE | (13 - 2));
OUT_BCS_BATCH(batch,
(pic_param->f_code[1][1] & 0xf) << 28 | /* f_code[1][1] */
(pic_param->f_code[1][0] & 0xf) << 24 | /* f_code[1][0] */
(pic_param->f_code[0][1] & 0xf) << 20 | /* f_code[0][1] */
(pic_param->f_code[0][0] & 0xf) << 16 | /* f_code[0][0] */
pic_param->picture_coding_extension.bits.intra_dc_precision << 14 |
pic_param->picture_coding_extension.bits.picture_structure << 12 |
pic_param->picture_coding_extension.bits.top_field_first << 11 |
pic_param->picture_coding_extension.bits.frame_pred_frame_dct << 10 |
pic_param->picture_coding_extension.bits.concealment_motion_vectors << 9 |
pic_param->picture_coding_extension.bits.q_scale_type << 8 |
pic_param->picture_coding_extension.bits.intra_vlc_format << 7 |
pic_param->picture_coding_extension.bits.alternate_scan << 6);
OUT_BCS_BATCH(batch,
0 << 14 | /* LoadSlicePointerFlag, 0 means only loading bitstream pointer once */
va_to_gen8_mpeg2_picture_type[pic_param->picture_type] << 9 |
0);
OUT_BCS_BATCH(batch,
1 << 31 | /* slice concealment */
(height_in_mbs - 1) << 16 |
(width_in_mbs - 1));
if (slice_param && slice_param->quantiser_scale_code >= 14)
OUT_BCS_BATCH(batch, (3 << 1) | (1 << 4) | (5 << 8) | (1 << 12));
else
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch,
0xFFF << 16 | /* InterMBMaxSize */
0xFFF << 0 | /* IntraMBMaxSize */
0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
ADVANCE_BCS_BATCH(batch);
}
static void
gen8_mfc_mpeg2_qm_state(VADriverContextP ctx, struct intel_encoder_context *encoder_context)
{
unsigned char intra_qm[64] = {
8, 16, 19, 22, 26, 27, 29, 34,
16, 16, 22, 24, 27, 29, 34, 37,
19, 22, 26, 27, 29, 34, 34, 38,
22, 22, 26, 27, 29, 34, 37, 40,
22, 26, 27, 29, 32, 35, 40, 48,
26, 27, 29, 32, 35, 40, 48, 58,
26, 27, 29, 34, 38, 46, 56, 69,
27, 29, 35, 38, 46, 56, 69, 83
};
unsigned char non_intra_qm[64] = {
16, 16, 16, 16, 16, 16, 16, 16,
16, 16, 16, 16, 16, 16, 16, 16,
16, 16, 16, 16, 16, 16, 16, 16,
16, 16, 16, 16, 16, 16, 16, 16,
16, 16, 16, 16, 16, 16, 16, 16,
16, 16, 16, 16, 16, 16, 16, 16,
16, 16, 16, 16, 16, 16, 16, 16,
16, 16, 16, 16, 16, 16, 16, 16
};
gen8_mfc_qm_state(ctx, MFX_QM_MPEG_INTRA_QUANTIZER_MATRIX, (unsigned int *)intra_qm, 16, encoder_context);
gen8_mfc_qm_state(ctx, MFX_QM_MPEG_NON_INTRA_QUANTIZER_MATRIX, (unsigned int *)non_intra_qm, 16, encoder_context);
}
static void
gen8_mfc_mpeg2_fqm_state(VADriverContextP ctx, struct intel_encoder_context *encoder_context)
{
unsigned short intra_fqm[64] = {
65536 / 0x8, 65536 / 0x10, 65536 / 0x13, 65536 / 0x16, 65536 / 0x16, 65536 / 0x1a, 65536 / 0x1a, 65536 / 0x1b,
65536 / 0x10, 65536 / 0x10, 65536 / 0x16, 65536 / 0x16, 65536 / 0x1a, 65536 / 0x1b, 65536 / 0x1b, 65536 / 0x1d,
65536 / 0x13, 65536 / 0x16, 65536 / 0x1a, 65536 / 0x1a, 65536 / 0x1b, 65536 / 0x1d, 65536 / 0x1d, 65536 / 0x23,
65536 / 0x16, 65536 / 0x18, 65536 / 0x1b, 65536 / 0x1b, 65536 / 0x13, 65536 / 0x20, 65536 / 0x22, 65536 / 0x26,
65536 / 0x1a, 65536 / 0x1b, 65536 / 0x13, 65536 / 0x13, 65536 / 0x20, 65536 / 0x23, 65536 / 0x26, 65536 / 0x2e,
65536 / 0x1b, 65536 / 0x1d, 65536 / 0x22, 65536 / 0x22, 65536 / 0x23, 65536 / 0x28, 65536 / 0x2e, 65536 / 0x38,
65536 / 0x1d, 65536 / 0x22, 65536 / 0x22, 65536 / 0x25, 65536 / 0x28, 65536 / 0x30, 65536 / 0x38, 65536 / 0x45,
65536 / 0x22, 65536 / 0x25, 65536 / 0x26, 65536 / 0x28, 65536 / 0x30, 65536 / 0x3a, 65536 / 0x45, 65536 / 0x53,
};
unsigned short non_intra_fqm[64] = {
0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000,
0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000,
0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000,
0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000,
0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000,
0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000,
0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000,
0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000, 0x1000,
};
gen8_mfc_fqm_state(ctx, MFX_QM_MPEG_INTRA_QUANTIZER_MATRIX, (unsigned int *)intra_fqm, 32, encoder_context);
gen8_mfc_fqm_state(ctx, MFX_QM_MPEG_NON_INTRA_QUANTIZER_MATRIX, (unsigned int *)non_intra_fqm, 32, encoder_context);
}
static void
gen8_mfc_mpeg2_slicegroup_state(VADriverContextP ctx,
struct intel_encoder_context *encoder_context,
int x, int y,
int next_x, int next_y,
int is_fisrt_slice_group,
int is_last_slice_group,
int intra_slice,
int qp,
struct intel_batchbuffer *batch)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
if (batch == NULL)
batch = encoder_context->base.batch;
BEGIN_BCS_BATCH(batch, 8);
OUT_BCS_BATCH(batch, MFC_MPEG2_SLICEGROUP_STATE | (8 - 2));
OUT_BCS_BATCH(batch,
0 << 31 | /* MbRateCtrlFlag */
!!is_last_slice_group << 19 | /* IsLastSliceGrp */
1 << 17 | /* Insert Header before the first slice group data */
1 << 16 | /* SliceData PresentFlag: always 1 */
1 << 15 | /* TailPresentFlag: always 1 */
0 << 14 | /* FirstSliceHdrDisabled: slice header for each slice */
!!intra_slice << 13 | /* IntraSlice */
!!intra_slice << 12 | /* IntraSliceFlag */
0);
OUT_BCS_BATCH(batch,
next_y << 24 |
next_x << 16 |
y << 8 |
x << 0 |
0);
OUT_BCS_BATCH(batch, qp); /* FIXME: SliceGroupQp */
/* bitstream pointer is only loaded once for the first slice of a frame when
* LoadSlicePointerFlag is 0
*/
OUT_BCS_BATCH(batch, mfc_context->mfc_indirect_pak_bse_object.offset);
OUT_BCS_BATCH(batch, 0); /* FIXME: */
OUT_BCS_BATCH(batch, 0); /* FIXME: CorrectPoints */
OUT_BCS_BATCH(batch, 0); /* FIXME: CVxxx */
ADVANCE_BCS_BATCH(batch);
}
static int
gen8_mfc_mpeg2_pak_object_intra(VADriverContextP ctx,
struct intel_encoder_context *encoder_context,
int x, int y,
int first_mb_in_slice,
int last_mb_in_slice,
int first_mb_in_slice_group,
int last_mb_in_slice_group,
int mb_type,
int qp_scale_code,
int coded_block_pattern,
unsigned char target_size_in_word,
unsigned char max_size_in_word,
struct intel_batchbuffer *batch)
{
int len_in_dwords = 9;
if (batch == NULL)
batch = encoder_context->base.batch;
BEGIN_BCS_BATCH(batch, len_in_dwords);
OUT_BCS_BATCH(batch, MFC_MPEG2_PAK_OBJECT | (len_in_dwords - 2));
OUT_BCS_BATCH(batch,
0 << 24 | /* PackedMvNum */
0 << 20 | /* MvFormat */
7 << 17 | /* CbpDcY/CbpDcU/CbpDcV */
0 << 15 | /* TransformFlag: frame DCT */
0 << 14 | /* FieldMbFlag */
1 << 13 | /* IntraMbFlag */
mb_type << 8 | /* MbType: Intra */
0 << 2 | /* SkipMbFlag */
0 << 0 | /* InterMbMode */
0);
OUT_BCS_BATCH(batch, y << 16 | x);
OUT_BCS_BATCH(batch,
max_size_in_word << 24 |
target_size_in_word << 16 |
coded_block_pattern << 6 | /* CBP */
0);
OUT_BCS_BATCH(batch,
last_mb_in_slice << 31 |
first_mb_in_slice << 30 |
0 << 27 | /* EnableCoeffClamp */
last_mb_in_slice_group << 26 |
0 << 25 | /* MbSkipConvDisable */
first_mb_in_slice_group << 24 |
0 << 16 | /* MvFieldSelect */
qp_scale_code << 0 |
0);
OUT_BCS_BATCH(batch, 0); /* MV[0][0] */
OUT_BCS_BATCH(batch, 0); /* MV[1][0] */
OUT_BCS_BATCH(batch, 0); /* MV[0][1] */
OUT_BCS_BATCH(batch, 0); /* MV[1][1] */
ADVANCE_BCS_BATCH(batch);
return len_in_dwords;
}
/* Byte offset */
#define MPEG2_INTER_MV_OFFSET 48
static struct _mv_ranges {
int low; /* in the unit of 1/2 pixel */
int high; /* in the unit of 1/2 pixel */
} mv_ranges[] = {
{0, 0},
{ -16, 15},
{ -32, 31},
{ -64, 63},
{ -128, 127},
{ -256, 255},
{ -512, 511},
{ -1024, 1023},
{ -2048, 2047},
{ -4096, 4095}
};
static int
mpeg2_motion_vector(int mv, int pos, int display_max, int f_code)
{
if (mv + pos * 16 * 2 < 0 ||
mv + (pos + 1) * 16 * 2 > display_max * 2)
mv = 0;
if (f_code > 0 && f_code < 10) {
if (mv < mv_ranges[f_code].low)
mv = mv_ranges[f_code].low;
if (mv > mv_ranges[f_code].high)
mv = mv_ranges[f_code].high;
}
return mv;
}
static int
gen8_mfc_mpeg2_pak_object_inter(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context,
unsigned int *msg,
int width_in_mbs, int height_in_mbs,
int x, int y,
int first_mb_in_slice,
int last_mb_in_slice,
int first_mb_in_slice_group,
int last_mb_in_slice_group,
int qp_scale_code,
unsigned char target_size_in_word,
unsigned char max_size_in_word,
struct intel_batchbuffer *batch)
{
VAEncPictureParameterBufferMPEG2 *pic_param = (VAEncPictureParameterBufferMPEG2 *)encode_state->pic_param_ext->buffer;
int len_in_dwords = 9;
short *mvptr, mvx0, mvy0, mvx1, mvy1;
if (batch == NULL)
batch = encoder_context->base.batch;
mvptr = (short *)((unsigned char *)msg + MPEG2_INTER_MV_OFFSET);;
mvx0 = mpeg2_motion_vector(mvptr[0] / 2, x, width_in_mbs * 16, pic_param->f_code[0][0]);
mvy0 = mpeg2_motion_vector(mvptr[1] / 2, y, height_in_mbs * 16, pic_param->f_code[0][0]);
mvx1 = mpeg2_motion_vector(mvptr[2] / 2, x, width_in_mbs * 16, pic_param->f_code[1][0]);
mvy1 = mpeg2_motion_vector(mvptr[3] / 2, y, height_in_mbs * 16, pic_param->f_code[1][0]);
BEGIN_BCS_BATCH(batch, len_in_dwords);
OUT_BCS_BATCH(batch, MFC_MPEG2_PAK_OBJECT | (len_in_dwords - 2));
OUT_BCS_BATCH(batch,
2 << 24 | /* PackedMvNum */
7 << 20 | /* MvFormat */
7 << 17 | /* CbpDcY/CbpDcU/CbpDcV */
0 << 15 | /* TransformFlag: frame DCT */
0 << 14 | /* FieldMbFlag */
0 << 13 | /* IntraMbFlag */
1 << 8 | /* MbType: Frame-based */
0 << 2 | /* SkipMbFlag */
0 << 0 | /* InterMbMode */
0);
OUT_BCS_BATCH(batch, y << 16 | x);
OUT_BCS_BATCH(batch,
max_size_in_word << 24 |
target_size_in_word << 16 |
0x3f << 6 | /* CBP */
0);
OUT_BCS_BATCH(batch,
last_mb_in_slice << 31 |
first_mb_in_slice << 30 |
0 << 27 | /* EnableCoeffClamp */
last_mb_in_slice_group << 26 |
0 << 25 | /* MbSkipConvDisable */
first_mb_in_slice_group << 24 |
0 << 16 | /* MvFieldSelect */
qp_scale_code << 0 |
0);
OUT_BCS_BATCH(batch, (mvx0 & 0xFFFF) | mvy0 << 16); /* MV[0][0] */
OUT_BCS_BATCH(batch, (mvx1 & 0xFFFF) | mvy1 << 16); /* MV[1][0] */
OUT_BCS_BATCH(batch, 0); /* MV[0][1] */
OUT_BCS_BATCH(batch, 0); /* MV[1][1] */
ADVANCE_BCS_BATCH(batch);
return len_in_dwords;
}
static void
intel_mfc_mpeg2_pipeline_header_programing(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context,
struct intel_batchbuffer *slice_batch)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
int idx = va_enc_packed_type_to_idx(VAEncPackedHeaderMPEG2_SPS);
if (encode_state->packed_header_data[idx]) {
VAEncPackedHeaderParameterBuffer *param = NULL;
unsigned int *header_data = (unsigned int *)encode_state->packed_header_data[idx]->buffer;
unsigned int length_in_bits;
assert(encode_state->packed_header_param[idx]);
param = (VAEncPackedHeaderParameterBuffer *)encode_state->packed_header_param[idx]->buffer;
length_in_bits = param->bit_length;
mfc_context->insert_object(ctx,
encoder_context,
header_data,
ALIGN(length_in_bits, 32) >> 5,
length_in_bits & 0x1f,
5, /* FIXME: check it */
0,
0,
0, /* Needn't insert emulation bytes for MPEG-2 */
slice_batch);
}
idx = va_enc_packed_type_to_idx(VAEncPackedHeaderMPEG2_PPS);
if (encode_state->packed_header_data[idx]) {
VAEncPackedHeaderParameterBuffer *param = NULL;
unsigned int *header_data = (unsigned int *)encode_state->packed_header_data[idx]->buffer;
unsigned int length_in_bits;
assert(encode_state->packed_header_param[idx]);
param = (VAEncPackedHeaderParameterBuffer *)encode_state->packed_header_param[idx]->buffer;
length_in_bits = param->bit_length;
mfc_context->insert_object(ctx,
encoder_context,
header_data,
ALIGN(length_in_bits, 32) >> 5,
length_in_bits & 0x1f,
5, /* FIXME: check it */
0,
0,
0, /* Needn't insert emulation bytes for MPEG-2 */
slice_batch);
}
}
static void
gen8_mfc_mpeg2_pipeline_slice_group(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context,
int slice_index,
VAEncSliceParameterBufferMPEG2 *next_slice_group_param,
struct intel_batchbuffer *slice_batch)
{
struct gen6_vme_context *vme_context = encoder_context->vme_context;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
VAEncSequenceParameterBufferMPEG2 *seq_param = (VAEncSequenceParameterBufferMPEG2 *)encode_state->seq_param_ext->buffer;
VAEncSliceParameterBufferMPEG2 *slice_param = NULL;
unsigned char tail_delimiter[] = {MPEG2_DELIMITER0, MPEG2_DELIMITER1, MPEG2_DELIMITER2, MPEG2_DELIMITER3, MPEG2_DELIMITER4, 0, 0, 0};
unsigned char section_delimiter[] = {0x0, 0x0, 0x0, 0x0};
int width_in_mbs = ALIGN(seq_param->picture_width, 16) / 16;
int height_in_mbs = ALIGN(seq_param->picture_height, 16) / 16;
int i, j;
int h_start_pos, v_start_pos, h_next_start_pos, v_next_start_pos;
unsigned int *msg = NULL;
unsigned char *msg_ptr = NULL;
slice_param = (VAEncSliceParameterBufferMPEG2 *)encode_state->slice_params_ext[slice_index]->buffer;
h_start_pos = slice_param->macroblock_address % width_in_mbs;
v_start_pos = slice_param->macroblock_address / width_in_mbs;
assert(h_start_pos + slice_param->num_macroblocks <= width_in_mbs);
dri_bo_map(vme_context->vme_output.bo, 0);
msg_ptr = (unsigned char *)vme_context->vme_output.bo->virtual;
if (next_slice_group_param) {
h_next_start_pos = next_slice_group_param->macroblock_address % width_in_mbs;
v_next_start_pos = next_slice_group_param->macroblock_address / width_in_mbs;
} else {
h_next_start_pos = 0;
v_next_start_pos = height_in_mbs;
}
gen8_mfc_mpeg2_slicegroup_state(ctx,
encoder_context,
h_start_pos,
v_start_pos,
h_next_start_pos,
v_next_start_pos,
slice_index == 0,
next_slice_group_param == NULL,
slice_param->is_intra_slice,
slice_param->quantiser_scale_code,
slice_batch);
if (slice_index == 0)
intel_mfc_mpeg2_pipeline_header_programing(ctx, encode_state, encoder_context, slice_batch);
/* Insert '00' to make sure the header is valid */
mfc_context->insert_object(ctx,
encoder_context,
(unsigned int*)section_delimiter,
1,
8, /* 8bits in the last DWORD */
1, /* 1 byte */
1,
0,
0,
slice_batch);
for (i = 0; i < encode_state->slice_params_ext[slice_index]->num_elements; i++) {
/* PAK for each macroblocks */
for (j = 0; j < slice_param->num_macroblocks; j++) {
int h_pos = (slice_param->macroblock_address + j) % width_in_mbs;
int v_pos = (slice_param->macroblock_address + j) / width_in_mbs;
int first_mb_in_slice = (j == 0);
int last_mb_in_slice = (j == slice_param->num_macroblocks - 1);
int first_mb_in_slice_group = (i == 0 && j == 0);
int last_mb_in_slice_group = (i == encode_state->slice_params_ext[slice_index]->num_elements - 1 &&
j == slice_param->num_macroblocks - 1);
msg = (unsigned int *)(msg_ptr + (slice_param->macroblock_address + j) * vme_context->vme_output.size_block);
if (slice_param->is_intra_slice) {
gen8_mfc_mpeg2_pak_object_intra(ctx,
encoder_context,
h_pos, v_pos,
first_mb_in_slice,
last_mb_in_slice,
first_mb_in_slice_group,
last_mb_in_slice_group,
0x1a,
slice_param->quantiser_scale_code,
0x3f,
0,
0xff,
slice_batch);
} else {
int inter_rdo, intra_rdo;
inter_rdo = msg[AVC_INTER_RDO_OFFSET] & AVC_RDO_MASK;
intra_rdo = msg[AVC_INTRA_RDO_OFFSET] & AVC_RDO_MASK;
if (intra_rdo < inter_rdo)
gen8_mfc_mpeg2_pak_object_intra(ctx,
encoder_context,
h_pos, v_pos,
first_mb_in_slice,
last_mb_in_slice,
first_mb_in_slice_group,
last_mb_in_slice_group,
0x1a,
slice_param->quantiser_scale_code,
0x3f,
0,
0xff,
slice_batch);
else
gen8_mfc_mpeg2_pak_object_inter(ctx,
encode_state,
encoder_context,
msg,
width_in_mbs, height_in_mbs,
h_pos, v_pos,
first_mb_in_slice,
last_mb_in_slice,
first_mb_in_slice_group,
last_mb_in_slice_group,
slice_param->quantiser_scale_code,
0,
0xff,
slice_batch);
}
}
slice_param++;
}
dri_bo_unmap(vme_context->vme_output.bo);
/* tail data */
if (next_slice_group_param == NULL) { /* end of a picture */
mfc_context->insert_object(ctx,
encoder_context,
(unsigned int *)tail_delimiter,
2,
8, /* 8bits in the last DWORD */
5, /* 5 bytes */
1,
1,
0,
slice_batch);
} else { /* end of a lsice group */
mfc_context->insert_object(ctx,
encoder_context,
(unsigned int *)section_delimiter,
1,
8, /* 8bits in the last DWORD */
1, /* 1 byte */
1,
1,
0,
slice_batch);
}
}
/*
* A batch buffer for all slices, including slice state,
* slice insert object and slice pak object commands
*
*/
static dri_bo *
gen8_mfc_mpeg2_software_slice_batchbuffer(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
struct intel_batchbuffer *batch;
VAEncSliceParameterBufferMPEG2 *next_slice_group_param = NULL;
dri_bo *batch_bo;
int i;
batch = mfc_context->aux_batchbuffer;
batch_bo = batch->buffer;
for (i = 0; i < encode_state->num_slice_params_ext; i++) {
if (i == encode_state->num_slice_params_ext - 1)
next_slice_group_param = NULL;
else
next_slice_group_param = (VAEncSliceParameterBufferMPEG2 *)encode_state->slice_params_ext[i + 1]->buffer;
gen8_mfc_mpeg2_pipeline_slice_group(ctx, encode_state, encoder_context, i, next_slice_group_param, batch);
}
intel_batchbuffer_align(batch, 8);
BEGIN_BCS_BATCH(batch, 2);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, MI_BATCH_BUFFER_END);
ADVANCE_BCS_BATCH(batch);
dri_bo_reference(batch_bo);
intel_batchbuffer_free(batch);
mfc_context->aux_batchbuffer = NULL;
return batch_bo;
}
static void
gen8_mfc_mpeg2_pipeline_picture_programing(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
mfc_context->pipe_mode_select(ctx, MFX_FORMAT_MPEG2, encoder_context);
mfc_context->set_surface_state(ctx, encoder_context);
mfc_context->ind_obj_base_addr_state(ctx, encoder_context);
gen8_mfc_pipe_buf_addr_state(ctx, encoder_context);
gen8_mfc_bsp_buf_base_addr_state(ctx, encoder_context);
gen8_mfc_mpeg2_pic_state(ctx, encoder_context, encode_state);
gen8_mfc_mpeg2_qm_state(ctx, encoder_context);
gen8_mfc_mpeg2_fqm_state(ctx, encoder_context);
}
static void
gen8_mfc_mpeg2_pipeline_programing(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
dri_bo *slice_batch_bo;
slice_batch_bo = gen8_mfc_mpeg2_software_slice_batchbuffer(ctx, encode_state, encoder_context);
// begin programing
intel_batchbuffer_start_atomic_bcs(batch, 0x4000);
intel_batchbuffer_emit_mi_flush(batch);
// picture level programing
gen8_mfc_mpeg2_pipeline_picture_programing(ctx, encode_state, encoder_context);
BEGIN_BCS_BATCH(batch, 4);
OUT_BCS_BATCH(batch, MI_BATCH_BUFFER_START | (1 << 8) | (1 << 0));
OUT_BCS_RELOC64(batch,
slice_batch_bo,
I915_GEM_DOMAIN_COMMAND, 0,
0);
OUT_BCS_BATCH(batch, 0);
ADVANCE_BCS_BATCH(batch);
// end programing
intel_batchbuffer_end_atomic(batch);
dri_bo_unreference(slice_batch_bo);
}
static VAStatus
intel_mfc_mpeg2_prepare(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
struct object_surface *obj_surface;
struct object_buffer *obj_buffer;
struct i965_coded_buffer_segment *coded_buffer_segment;
VAStatus vaStatus = VA_STATUS_SUCCESS;
dri_bo *bo;
int i;
/* reconstructed surface */
obj_surface = encode_state->reconstructed_object;
i965_check_alloc_surface_bo(ctx, obj_surface, 1, VA_FOURCC_NV12, SUBSAMPLE_YUV420);
mfc_context->pre_deblocking_output.bo = obj_surface->bo;
dri_bo_reference(mfc_context->pre_deblocking_output.bo);
mfc_context->surface_state.width = obj_surface->orig_width;
mfc_context->surface_state.height = obj_surface->orig_height;
mfc_context->surface_state.w_pitch = obj_surface->width;
mfc_context->surface_state.h_pitch = obj_surface->height;
/* forward reference */
obj_surface = encode_state->reference_objects[0];
if (obj_surface && obj_surface->bo) {
mfc_context->reference_surfaces[0].bo = obj_surface->bo;
dri_bo_reference(mfc_context->reference_surfaces[0].bo);
} else
mfc_context->reference_surfaces[0].bo = NULL;
/* backward reference */
obj_surface = encode_state->reference_objects[1];
if (obj_surface && obj_surface->bo) {
mfc_context->reference_surfaces[1].bo = obj_surface->bo;
dri_bo_reference(mfc_context->reference_surfaces[1].bo);
} else {
mfc_context->reference_surfaces[1].bo = mfc_context->reference_surfaces[0].bo;
if (mfc_context->reference_surfaces[1].bo)
dri_bo_reference(mfc_context->reference_surfaces[1].bo);
}
for (i = 2; i < ARRAY_ELEMS(mfc_context->reference_surfaces); i++) {
mfc_context->reference_surfaces[i].bo = mfc_context->reference_surfaces[i & 1].bo;
if (mfc_context->reference_surfaces[i].bo)
dri_bo_reference(mfc_context->reference_surfaces[i].bo);
}
/* input YUV surface */
obj_surface = encode_state->input_yuv_object;
mfc_context->uncompressed_picture_source.bo = obj_surface->bo;
dri_bo_reference(mfc_context->uncompressed_picture_source.bo);
/* coded buffer */
obj_buffer = encode_state->coded_buf_object;
bo = obj_buffer->buffer_store->bo;
mfc_context->mfc_indirect_pak_bse_object.bo = bo;
mfc_context->mfc_indirect_pak_bse_object.offset = I965_CODEDBUFFER_HEADER_SIZE;
mfc_context->mfc_indirect_pak_bse_object.end_offset = ALIGN(obj_buffer->size_element - 0x1000, 0x1000);
dri_bo_reference(mfc_context->mfc_indirect_pak_bse_object.bo);
/* set the internal flag to 0 to indicate the coded size is unknown */
dri_bo_map(bo, 1);
coded_buffer_segment = (struct i965_coded_buffer_segment *)bo->virtual;
coded_buffer_segment->mapped = 0;
coded_buffer_segment->codec = encoder_context->codec;
dri_bo_unmap(bo);
return vaStatus;
}
static VAStatus
gen8_mfc_mpeg2_encode_picture(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
gen8_mfc_init(ctx, encode_state, encoder_context);
intel_mfc_mpeg2_prepare(ctx, encode_state, encoder_context);
/*Programing bcs pipeline*/
gen8_mfc_mpeg2_pipeline_programing(ctx, encode_state, encoder_context);
gen8_mfc_run(ctx, encode_state, encoder_context);
return VA_STATUS_SUCCESS;
}
/* JPEG encode methods */
static VAStatus
intel_mfc_jpeg_prepare(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
struct object_surface *obj_surface;
struct object_buffer *obj_buffer;
struct i965_coded_buffer_segment *coded_buffer_segment;
VAStatus vaStatus = VA_STATUS_SUCCESS;
dri_bo *bo;
/* input YUV surface */
obj_surface = encode_state->input_yuv_object;
mfc_context->uncompressed_picture_source.bo = obj_surface->bo;
dri_bo_reference(mfc_context->uncompressed_picture_source.bo);
/* coded buffer */
obj_buffer = encode_state->coded_buf_object;
bo = obj_buffer->buffer_store->bo;
mfc_context->mfc_indirect_pak_bse_object.bo = bo;
mfc_context->mfc_indirect_pak_bse_object.offset = I965_CODEDBUFFER_HEADER_SIZE;
mfc_context->mfc_indirect_pak_bse_object.end_offset = ALIGN(obj_buffer->size_element - 0x1000, 0x1000);
dri_bo_reference(mfc_context->mfc_indirect_pak_bse_object.bo);
/* set the internal flag to 0 to indicate the coded size is unknown */
dri_bo_map(bo, 1);
coded_buffer_segment = (struct i965_coded_buffer_segment *)bo->virtual;
coded_buffer_segment->mapped = 0;
coded_buffer_segment->codec = encoder_context->codec;
dri_bo_unmap(bo);
return vaStatus;
}
static void
gen8_mfc_jpeg_set_surface_state(VADriverContextP ctx,
struct intel_encoder_context *encoder_context,
struct encode_state *encode_state)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct object_surface *obj_surface = encode_state->input_yuv_object;
unsigned int input_fourcc;
unsigned int y_cb_offset;
unsigned int y_cr_offset;
unsigned int surface_format;
assert(obj_surface);
y_cb_offset = obj_surface->y_cb_offset;
y_cr_offset = obj_surface->y_cr_offset;
input_fourcc = obj_surface->fourcc;
surface_format = (obj_surface->fourcc == VA_FOURCC_Y800) ?
MFX_SURFACE_MONOCHROME : MFX_SURFACE_PLANAR_420_8;
switch (input_fourcc) {
case VA_FOURCC_Y800: {
surface_format = MFX_SURFACE_MONOCHROME;
break;
}
case VA_FOURCC_NV12: {
surface_format = MFX_SURFACE_PLANAR_420_8;
break;
}
case VA_FOURCC_UYVY: {
surface_format = MFX_SURFACE_YCRCB_SWAPY;
break;
}
case VA_FOURCC_YUY2: {
surface_format = MFX_SURFACE_YCRCB_NORMAL;
break;
}
case VA_FOURCC_RGBA:
case VA_FOURCC_444P: {
surface_format = MFX_SURFACE_R8G8B8A8_UNORM;
break;
}
}
BEGIN_BCS_BATCH(batch, 6);
OUT_BCS_BATCH(batch, MFX_SURFACE_STATE | (6 - 2));
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch,
((obj_surface->orig_height - 1) << 18) |
((obj_surface->orig_width - 1) << 4));
OUT_BCS_BATCH(batch,
(surface_format << 28) | /* Surface Format */
(0 << 27) | /* must be 1 for interleave U/V, hardware requirement for AVC/VC1/MPEG and 0 for JPEG */
(0 << 22) | /* surface object control state, FIXME??? */
((obj_surface->width - 1) << 3) | /* pitch */
(0 << 2) | /* must be 0 for interleave U/V */
(1 << 1) | /* must be tiled */
(I965_TILEWALK_YMAJOR << 0)); /* tile walk, TILEWALK_YMAJOR */
OUT_BCS_BATCH(batch,
(0 << 16) | /* X offset for U(Cb), must be 0 */
(y_cb_offset << 0)); /* Y offset for U(Cb) */
OUT_BCS_BATCH(batch,
(0 << 16) | /* X offset for V(Cr), must be 0 */
(y_cr_offset << 0)); /* Y offset for V(Cr), must be 0 for video codec, non-zoeo for JPEG */
ADVANCE_BCS_BATCH(batch);
}
static void
gen8_mfc_jpeg_pic_state(VADriverContextP ctx,
struct intel_encoder_context *encoder_context,
struct encode_state *encode_state)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct object_surface *obj_surface = encode_state->input_yuv_object;
VAEncPictureParameterBufferJPEG *pic_param;
unsigned int surface_format;
unsigned int frame_width_in_blks;
unsigned int frame_height_in_blks;
unsigned int pixels_in_horizontal_lastMCU;
unsigned int pixels_in_vertical_lastMCU;
unsigned int input_surface_format;
unsigned int output_mcu_format;
unsigned int picture_width;
unsigned int picture_height;
assert(encode_state->pic_param_ext && encode_state->pic_param_ext->buffer);
assert(obj_surface);
pic_param = (VAEncPictureParameterBufferJPEG *)encode_state->pic_param_ext->buffer;
surface_format = obj_surface->fourcc;
picture_width = pic_param->picture_width;
picture_height = pic_param->picture_height;
switch (surface_format) {
case VA_FOURCC_Y800: {
input_surface_format = JPEG_ENC_SURFACE_Y8;
output_mcu_format = JPEG_ENC_MCU_YUV400;
break;
}
case VA_FOURCC_NV12: {
input_surface_format = JPEG_ENC_SURFACE_NV12;
output_mcu_format = JPEG_ENC_MCU_YUV420;
break;
}
case VA_FOURCC_UYVY: {
input_surface_format = JPEG_ENC_SURFACE_UYVY;
output_mcu_format = JPEG_ENC_MCU_YUV422H_2Y;
break;
}
case VA_FOURCC_YUY2: {
input_surface_format = JPEG_ENC_SURFACE_YUY2;
output_mcu_format = JPEG_ENC_MCU_YUV422H_2Y;
break;
}
case VA_FOURCC_RGBA:
case VA_FOURCC_444P: {
input_surface_format = JPEG_ENC_SURFACE_RGB;
output_mcu_format = JPEG_ENC_MCU_RGB;
break;
}
default : {
input_surface_format = JPEG_ENC_SURFACE_NV12;
output_mcu_format = JPEG_ENC_MCU_YUV420;
break;
}
}
switch (output_mcu_format) {
case JPEG_ENC_MCU_YUV400:
case JPEG_ENC_MCU_RGB: {
pixels_in_horizontal_lastMCU = (picture_width % 8);
pixels_in_vertical_lastMCU = (picture_height % 8);
//H1=1,V1=1 for YUV400 and YUV444. So, compute these values accordingly
frame_width_in_blks = ((picture_width + 7) / 8);
frame_height_in_blks = ((picture_height + 7) / 8);
break;
}
case JPEG_ENC_MCU_YUV420: {
if ((picture_width % 2) == 0)
pixels_in_horizontal_lastMCU = picture_width % 16;
else
pixels_in_horizontal_lastMCU = ((picture_width % 16) + 1) % 16;
if ((picture_height % 2) == 0)
pixels_in_vertical_lastMCU = picture_height % 16;
else
pixels_in_vertical_lastMCU = ((picture_height % 16) + 1) % 16;
//H1=2,V1=2 for YUV420. So, compute these values accordingly
frame_width_in_blks = ((picture_width + 15) / 16) * 2;
frame_height_in_blks = ((picture_height + 15) / 16) * 2;
break;
}
case JPEG_ENC_MCU_YUV422H_2Y: {
if (picture_width % 2 == 0)
pixels_in_horizontal_lastMCU = picture_width % 16;
else
pixels_in_horizontal_lastMCU = ((picture_width % 16) + 1) % 16;
pixels_in_vertical_lastMCU = picture_height % 8;
//H1=2,V1=1 for YUV422H_2Y. So, compute these values accordingly
frame_width_in_blks = ((picture_width + 15) / 16) * 2;
frame_height_in_blks = ((picture_height + 7) / 8);
break;
}
} //end of switch
BEGIN_BCS_BATCH(batch, 3);
/* DWORD 0 */
OUT_BCS_BATCH(batch, MFX_JPEG_PIC_STATE | (3 - 2));
/* DWORD 1 */
OUT_BCS_BATCH(batch,
(pixels_in_horizontal_lastMCU << 26) | /* Pixels In Horizontal Last MCU */
(pixels_in_vertical_lastMCU << 21) | /* Pixels In Vertical Last MCU */
(input_surface_format << 8) | /* Input Surface format */
(output_mcu_format << 0)); /* Output MCU Structure */
/* DWORD 2 */
OUT_BCS_BATCH(batch,
((frame_height_in_blks - 1) << 16) | /* Frame Height In Blks Minus 1 */
(JPEG_ENC_ROUND_QUANT_DEFAULT << 13) | /* Rounding Quant set to default value 0 */
((frame_width_in_blks - 1) << 0)); /* Frame Width In Blks Minus 1 */
ADVANCE_BCS_BATCH(batch);
}
static void
get_reciprocal_dword_qm(unsigned char *raster_qm, uint32_t *dword_qm)
{
int i = 0, j = 0;
short hdw, ldw;
for (i = 0, j = 0; i < 64; i += 2, j++) {
ldw = 65535 / (raster_qm[i]);
hdw = 65535 / (raster_qm[i + 1]);
dword_qm[j] = (hdw << 16) | ldw;
}
}
static void
gen8_mfc_jpeg_fqm_state(VADriverContextP ctx,
struct intel_encoder_context *encoder_context,
struct encode_state *encode_state)
{
unsigned int quality = 0;
uint32_t temp, i = 0, j = 0, dword_qm[32];
VAEncPictureParameterBufferJPEG *pic_param;
VAQMatrixBufferJPEG *qmatrix;
unsigned char raster_qm[64], column_raster_qm[64];
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
assert(encode_state->pic_param_ext && encode_state->pic_param_ext->buffer);
pic_param = (VAEncPictureParameterBufferJPEG *)encode_state->pic_param_ext->buffer;
quality = pic_param->quality;
//If the app sends the qmatrix, use it, buffer it for using it with the next frames
//The app can send qmatrix for the first frame and not send for the subsequent frames
if (encode_state->q_matrix && encode_state->q_matrix->buffer) {
qmatrix = (VAQMatrixBufferJPEG *)encode_state->q_matrix->buffer;
mfc_context->buffered_qmatrix.load_lum_quantiser_matrix = 1;
memcpy(mfc_context->buffered_qmatrix.lum_quantiser_matrix, qmatrix->lum_quantiser_matrix, 64 * (sizeof(unsigned char)));
if (pic_param->num_components > 1) {
mfc_context->buffered_qmatrix.load_chroma_quantiser_matrix = 1;
memcpy(mfc_context->buffered_qmatrix.chroma_quantiser_matrix, qmatrix->chroma_quantiser_matrix, 64 * (sizeof(unsigned char)));
} else {
mfc_context->buffered_qmatrix.load_chroma_quantiser_matrix = 0;
}
} else {
//If the app doesnt send the qmatrix, use the buffered/default qmatrix
qmatrix = &mfc_context->buffered_qmatrix;
qmatrix->load_lum_quantiser_matrix = 1;
qmatrix->load_chroma_quantiser_matrix = (pic_param->num_components > 1) ? 1 : 0;
}
//As per the design, normalization of the quality factor and scaling of the Quantization tables
//based on the quality factor needs to be done in the driver before sending the values to the HW.
//But note, the driver expects the scaled quantization tables (as per below logic) to be sent as
//packed header information. The packed header is written as the header of the jpeg file. This
//header information is used to decode the jpeg file. So, it is the app's responsibility to send
//the correct header information (See build_packed_jpeg_header_buffer() in jpegenc.c in LibVa on
//how to do this). QTables can be different for different applications. If no tables are provided,
//the default tables in the driver are used.
//Normalization of the quality factor
if (quality > 100) quality = 100;
if (quality == 0) quality = 1;
quality = (quality < 50) ? (5000 / quality) : (200 - (quality * 2));
//Step 1. Apply Quality factor and clip to range [1, 255] for luma and chroma Quantization matrices
//Step 2. HW expects the 1/Q[i] values in the qm sent, so get reciprocals
//Step 3. HW also expects 32 dwords, hence combine 2 (1/Q) values into 1 dword
//Step 4. Send the Quantization matrix to the HW, use gen8_mfc_fqm_state
//For luma (Y or R)
if (qmatrix->load_lum_quantiser_matrix) {
//apply quality to lum_quantiser_matrix
for (i = 0; i < 64; i++) {
temp = (qmatrix->lum_quantiser_matrix[i] * quality) / 100;
//clamp to range [1,255]
temp = (temp > 255) ? 255 : temp;
temp = (temp < 1) ? 1 : temp;
qmatrix->lum_quantiser_matrix[i] = (unsigned char)temp;
}
//For VAAPI, the VAQMatrixBuffer needs to be in zigzag order.
//The App should send it in zigzag. Now, the driver has to extract the raster from it.
for (j = 0; j < 64; j++)
raster_qm[zigzag_direct[j]] = qmatrix->lum_quantiser_matrix[j];
//Convert the raster order(row-ordered) to the column-raster (column by column).
//To be consistent with the other encoders, send it in column order.
//Need to double check if our HW expects col or row raster.
for (j = 0; j < 64; j++) {
int row = j / 8, col = j % 8;
column_raster_qm[col * 8 + row] = raster_qm[j];
}
//Convert to raster QM to reciprocal. HW expects values in reciprocal.
get_reciprocal_dword_qm(column_raster_qm, dword_qm);
//send the luma qm to the command buffer
gen8_mfc_fqm_state(ctx, MFX_QM_JPEG_LUMA_Y_QUANTIZER_MATRIX, dword_qm, 32, encoder_context);
}
//For Chroma, if chroma exists (Cb, Cr or G, B)
if (qmatrix->load_chroma_quantiser_matrix) {
//apply quality to chroma_quantiser_matrix
for (i = 0; i < 64; i++) {
temp = (qmatrix->chroma_quantiser_matrix[i] * quality) / 100;
//clamp to range [1,255]
temp = (temp > 255) ? 255 : temp;
temp = (temp < 1) ? 1 : temp;
qmatrix->chroma_quantiser_matrix[i] = (unsigned char)temp;
}
//For VAAPI, the VAQMatrixBuffer needs to be in zigzag order.
//The App should send it in zigzag. Now, the driver has to extract the raster from it.
for (j = 0; j < 64; j++)
raster_qm[zigzag_direct[j]] = qmatrix->chroma_quantiser_matrix[j];
//Convert the raster order(row-ordered) to the column-raster (column by column).
//To be consistent with the other encoders, send it in column order.
//Need to double check if our HW expects col or row raster.
for (j = 0; j < 64; j++) {
int row = j / 8, col = j % 8;
column_raster_qm[col * 8 + row] = raster_qm[j];
}
//Convert to raster QM to reciprocal. HW expects values in reciprocal.
get_reciprocal_dword_qm(column_raster_qm, dword_qm);
//send the same chroma qm to the command buffer (for both U,V or G,B)
gen8_mfc_fqm_state(ctx, MFX_QM_JPEG_CHROMA_CB_QUANTIZER_MATRIX, dword_qm, 32, encoder_context);
gen8_mfc_fqm_state(ctx, MFX_QM_JPEG_CHROMA_CR_QUANTIZER_MATRIX, dword_qm, 32, encoder_context);
}
}
//Translation of Table K.5 into code: This method takes the huffval from the
//Huffmantable buffer and converts into index for the coefficients and size tables
uint8_t map_huffval_to_index(uint8_t huff_val)
{
uint8_t index = 0;
if (huff_val < 0xF0) {
index = (((huff_val >> 4) & 0x0F) * 0xA) + (huff_val & 0x0F);
} else {
index = 1 + (((huff_val >> 4) & 0x0F) * 0xA) + (huff_val & 0x0F);
}
return index;
}
//Implementation of Flow chart Annex C - Figure C.1
static void
generate_huffman_codesizes_table(uint8_t *bits, uint8_t *huff_size_table, uint8_t *lastK)
{
uint8_t i = 1, j = 1, k = 0;
while (i <= 16) {
while (j <= (uint8_t)bits[i - 1]) {
huff_size_table[k] = i;
k = k + 1;
j = j + 1;
}
i = i + 1;
j = 1;
}
huff_size_table[k] = 0;
(*lastK) = k;
}
//Implementation of Flow chart Annex C - Figure C.2
static void
generate_huffman_codes_table(uint8_t *huff_size_table, uint16_t *huff_code_table)
{
uint8_t k = 0;
uint16_t code = 0;
uint8_t si = huff_size_table[k];
while (huff_size_table[k] != 0) {
while (huff_size_table[k] == si) {
// An huffman code can never be 0xFFFF. Replace it with 0 if 0xFFFF
if (code == 0xFFFF) {
code = 0x0000;
}
huff_code_table[k] = code;
code = code + 1;
k = k + 1;
}
code <<= 1;
si = si + 1;
}
}
//Implementation of Flow chat Annex C - Figure C.3
static void
generate_ordered_codes_table(uint8_t *huff_vals, uint8_t *huff_size_table, uint16_t *huff_code_table, uint8_t type, uint8_t lastK)
{
uint8_t huff_val_size = 0, i = 0, k = 0;
huff_val_size = (type == 0) ? 12 : 162;
uint8_t huff_si_table[huff_val_size];
uint16_t huff_co_table[huff_val_size];
memset(huff_si_table, 0, sizeof(huff_si_table));
memset(huff_co_table, 0, sizeof(huff_co_table));
do {
i = map_huffval_to_index(huff_vals[k]);
huff_co_table[i] = huff_code_table[k];
huff_si_table[i] = huff_size_table[k];
k++;
} while (k < lastK);
memcpy(huff_size_table, huff_si_table, sizeof(uint8_t)*huff_val_size);
memcpy(huff_code_table, huff_co_table, sizeof(uint16_t)*huff_val_size);
}
//This method converts the huffman table to code words which is needed by the HW
//Flowcharts from Jpeg Spec Annex C - Figure C.1, Figure C.2, Figure C.3 are used here
static void
convert_hufftable_to_codes(VAHuffmanTableBufferJPEGBaseline *huff_buffer, uint32_t *table, uint8_t type, uint8_t index)
{
uint8_t lastK = 0, i = 0;
uint8_t huff_val_size = 0;
uint8_t *huff_bits, *huff_vals;
huff_val_size = (type == 0) ? 12 : 162;
uint8_t huff_size_table[huff_val_size + 1]; //The +1 for adding 0 at the end of huff_val_size
uint16_t huff_code_table[huff_val_size];
memset(huff_size_table, 0, sizeof(huff_size_table));
memset(huff_code_table, 0, sizeof(huff_code_table));
huff_bits = (type == 0) ? (huff_buffer->huffman_table[index].num_dc_codes) : (huff_buffer->huffman_table[index].num_ac_codes);
huff_vals = (type == 0) ? (huff_buffer->huffman_table[index].dc_values) : (huff_buffer->huffman_table[index].ac_values);
//Generation of table of Huffman code sizes
generate_huffman_codesizes_table(huff_bits, huff_size_table, &lastK);
//Generation of table of Huffman codes
generate_huffman_codes_table(huff_size_table, huff_code_table);
//Ordering procedure for encoding procedure code tables
generate_ordered_codes_table(huff_vals, huff_size_table, huff_code_table, type, lastK);
//HW expects Byte0: Code length; Byte1,Byte2: Code Word, Byte3: Dummy
//Since IA is littlended, &, | and << accordingly to store the values in the DWord.
for (i = 0; i < huff_val_size; i++) {
table[i] = 0;
table[i] = ((huff_size_table[i] & 0xFF) | ((huff_code_table[i] & 0xFFFF) << 8));
}
}
//send the huffman table using MFC_JPEG_HUFF_TABLE_STATE
static void
gen8_mfc_jpeg_huff_table_state(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context,
int num_tables)
{
VAHuffmanTableBufferJPEGBaseline *huff_buffer;
struct intel_batchbuffer *batch = encoder_context->base.batch;
uint8_t index;
uint32_t dc_table[12], ac_table[162];
assert(encode_state->huffman_table && encode_state->huffman_table->buffer);
huff_buffer = (VAHuffmanTableBufferJPEGBaseline *)encode_state->huffman_table->buffer;
memset(dc_table, 0, sizeof(dc_table));
memset(ac_table, 0, sizeof(ac_table));
for (index = 0; index < num_tables; index++) {
int id = va_to_gen7_jpeg_hufftable[index];
if (!huff_buffer->load_huffman_table[index])
continue;
//load DC table with 12 DWords
convert_hufftable_to_codes(huff_buffer, dc_table, 0, index); //0 for Dc
//load AC table with 162 DWords
convert_hufftable_to_codes(huff_buffer, ac_table, 1, index); //1 for AC
BEGIN_BCS_BATCH(batch, 176);
OUT_BCS_BATCH(batch, MFC_JPEG_HUFF_TABLE_STATE | (176 - 2));
OUT_BCS_BATCH(batch, id); //Huff table id
//DWord 2 - 13 has DC_TABLE
intel_batchbuffer_data(batch, dc_table, 12 * 4);
//Dword 14 -175 has AC_TABLE
intel_batchbuffer_data(batch, ac_table, 162 * 4);
ADVANCE_BCS_BATCH(batch);
}
}
//This method is used to compute the MCU count used for setting MFC_JPEG_SCAN_OBJECT
static void get_Y_sampling_factors(uint32_t surface_format, uint8_t *h_factor, uint8_t *v_factor)
{
switch (surface_format) {
case VA_FOURCC_Y800: {
(* h_factor) = 1;
(* v_factor) = 1;
break;
}
case VA_FOURCC_NV12: {
(* h_factor) = 2;
(* v_factor) = 2;
break;
}
case VA_FOURCC_UYVY: {
(* h_factor) = 2;
(* v_factor) = 1;
break;
}
case VA_FOURCC_YUY2: {
(* h_factor) = 2;
(* v_factor) = 1;
break;
}
case VA_FOURCC_RGBA:
case VA_FOURCC_444P: {
(* h_factor) = 1;
(* v_factor) = 1;
break;
}
default : { //May be have to insert error handling here. For now just use as below
(* h_factor) = 1;
(* v_factor) = 1;
break;
}
}
}
//set MFC_JPEG_SCAN_OBJECT
static void
gen8_mfc_jpeg_scan_object(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
uint32_t mcu_count, surface_format, Mx, My;
uint8_t i, horizontal_sampling_factor, vertical_sampling_factor, huff_ac_table = 0, huff_dc_table = 0;
uint8_t is_last_scan = 1; //Jpeg has only 1 scan per frame. When last scan, HW inserts EOI code.
uint8_t head_present_flag = 1; //Header has tables and app data
uint16_t num_components, restart_interval; //Specifies number of MCUs in an ECS.
VAEncSliceParameterBufferJPEG *slice_param;
VAEncPictureParameterBufferJPEG *pic_param;
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct object_surface *obj_surface = encode_state->input_yuv_object;
assert(encode_state->slice_params_ext[0] && encode_state->slice_params_ext[0]->buffer);
assert(encode_state->pic_param_ext && encode_state->pic_param_ext->buffer);
assert(obj_surface);
pic_param = (VAEncPictureParameterBufferJPEG *)encode_state->pic_param_ext->buffer;
slice_param = (VAEncSliceParameterBufferJPEG *)encode_state->slice_params_ext[0]->buffer;
surface_format = obj_surface->fourcc;
get_Y_sampling_factors(surface_format, &horizontal_sampling_factor, &vertical_sampling_factor);
// Mx = #MCUs in a row, My = #MCUs in a column
Mx = (pic_param->picture_width + (horizontal_sampling_factor * 8 - 1)) / (horizontal_sampling_factor * 8);
My = (pic_param->picture_height + (vertical_sampling_factor * 8 - 1)) / (vertical_sampling_factor * 8);
mcu_count = (Mx * My);
num_components = pic_param->num_components;
restart_interval = slice_param->restart_interval;
//Depending on number of components and values set for table selectors,
//only those bits are set in 24:22 for AC table, 20:18 for DC table
for (i = 0; i < num_components; i++) {
huff_ac_table |= ((slice_param->components[i].ac_table_selector) << i);
huff_dc_table |= ((slice_param->components[i].dc_table_selector) << i);
}
BEGIN_BCS_BATCH(batch, 3);
/* DWORD 0 */
OUT_BCS_BATCH(batch, MFC_JPEG_SCAN_OBJECT | (3 - 2));
/* DWORD 1 */
OUT_BCS_BATCH(batch, mcu_count << 0); //MCU Count
/* DWORD 2 */
OUT_BCS_BATCH(batch,
(huff_ac_table << 22) | //Huffman AC Table
(huff_dc_table << 18) | //Huffman DC Table
(head_present_flag << 17) | //Head present flag
(is_last_scan << 16) | //Is last scan
(restart_interval << 0)); //Restart Interval
ADVANCE_BCS_BATCH(batch);
}
static void
gen8_mfc_jpeg_pak_insert_object(struct intel_encoder_context *encoder_context, unsigned int *insert_data,
int length_in_dws, int data_bits_in_last_dw, int is_last_header,
int is_end_of_slice)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
assert(batch);
if (data_bits_in_last_dw == 0)
data_bits_in_last_dw = 32;
BEGIN_BCS_BATCH(batch, length_in_dws + 2);
OUT_BCS_BATCH(batch, MFX_INSERT_OBJECT | (length_in_dws + 2 - 2));
//DWord 1
OUT_BCS_BATCH(batch,
(0 << 16) | //DataByteOffset 0 for JPEG Encoder
(0 << 15) | //HeaderLengthExcludeFrmSize 0 for JPEG Encoder
(data_bits_in_last_dw << 8) | //DataBitsInLastDW
(0 << 4) | //SkipEmulByteCount 0 for JPEG Encoder
(0 << 3) | //EmulationFlag 0 for JPEG Encoder
((!!is_last_header) << 2) | //LastHeaderFlag
((!!is_end_of_slice) << 1) | //EndOfSliceFlag
(1 << 0)); //BitstreamStartReset 1 for JPEG Encoder
//Data Paylaod
intel_batchbuffer_data(batch, insert_data, length_in_dws * 4);
ADVANCE_BCS_BATCH(batch);
}
//send the jpeg headers to HW using MFX_PAK_INSERT_OBJECT
static void
gen8_mfc_jpeg_add_headers(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
if (encode_state->packed_header_data_ext) {
VAEncPackedHeaderParameterBuffer *param = NULL;
unsigned int *header_data = (unsigned int *)(*encode_state->packed_header_data_ext)->buffer;
unsigned int length_in_bits;
param = (VAEncPackedHeaderParameterBuffer *)(*encode_state->packed_header_params_ext)->buffer;
length_in_bits = param->bit_length;
gen8_mfc_jpeg_pak_insert_object(encoder_context,
header_data,
ALIGN(length_in_bits, 32) >> 5,
length_in_bits & 0x1f,
1,
1);
}
}
//Initialize the buffered_qmatrix with the default qmatrix in the driver.
//If the app sends the qmatrix, this will be replaced with the one app sends.
static void
jpeg_init_default_qmatrix(VADriverContextP ctx, struct intel_encoder_context *encoder_context)
{
int i = 0;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
//Load the the QM in zigzag order. If app sends QM, it is always in zigzag order.
for (i = 0; i < 64; i++)
mfc_context->buffered_qmatrix.lum_quantiser_matrix[i] = jpeg_luma_quant[zigzag_direct[i]];
for (i = 0; i < 64; i++)
mfc_context->buffered_qmatrix.chroma_quantiser_matrix[i] = jpeg_chroma_quant[zigzag_direct[i]];
}
/* This is at the picture level */
static void
gen8_mfc_jpeg_pipeline_picture_programing(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
int i, j, component, max_selector = 0;
VAEncSliceParameterBufferJPEG *slice_param;
gen8_mfc_pipe_mode_select(ctx, MFX_FORMAT_JPEG, encoder_context);
gen8_mfc_jpeg_set_surface_state(ctx, encoder_context, encode_state);
gen8_mfc_pipe_buf_addr_state(ctx, encoder_context);
gen8_mfc_ind_obj_base_addr_state(ctx, encoder_context);
gen8_mfc_bsp_buf_base_addr_state(ctx, encoder_context);
gen8_mfc_jpeg_pic_state(ctx, encoder_context, encode_state);
//do the slice level encoding here
gen8_mfc_jpeg_fqm_state(ctx, encoder_context, encode_state);
//I dont think I need this for loop. Just to be consistent with other encoding logic...
for (i = 0; i < encode_state->num_slice_params_ext; i++) {
assert(encode_state->slice_params_ext && encode_state->slice_params_ext[i]->buffer);
slice_param = (VAEncSliceParameterBufferJPEG *)encode_state->slice_params_ext[i]->buffer;
for (j = 0; j < encode_state->slice_params_ext[i]->num_elements; j++) {
for (component = 0; component < slice_param->num_components; component++) {
if (max_selector < slice_param->components[component].dc_table_selector)
max_selector = slice_param->components[component].dc_table_selector;
if (max_selector < slice_param->components[component].ac_table_selector)
max_selector = slice_param->components[component].ac_table_selector;
}
slice_param++;
}
}
assert(max_selector < 2);
//send the huffman table using MFC_JPEG_HUFF_TABLE
gen8_mfc_jpeg_huff_table_state(ctx, encode_state, encoder_context, max_selector + 1);
//set MFC_JPEG_SCAN_OBJECT
gen8_mfc_jpeg_scan_object(ctx, encode_state, encoder_context);
//add headers using MFX_PAK_INSERT_OBJECT (it is refered as MFX_INSERT_OBJECT in this driver code)
gen8_mfc_jpeg_add_headers(ctx, encode_state, encoder_context);
}
static void
gen8_mfc_jpeg_pipeline_programing(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
// begin programing
intel_batchbuffer_start_atomic_bcs(batch, 0x4000);
intel_batchbuffer_emit_mi_flush(batch);
// picture level programing
gen8_mfc_jpeg_pipeline_picture_programing(ctx, encode_state, encoder_context);
// end programing
intel_batchbuffer_end_atomic(batch);
}
static VAStatus
gen8_mfc_jpeg_encode_picture(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
gen8_mfc_init(ctx, encode_state, encoder_context);
intel_mfc_jpeg_prepare(ctx, encode_state, encoder_context);
/*Programing bcs pipeline*/
gen8_mfc_jpeg_pipeline_programing(ctx, encode_state, encoder_context);
gen8_mfc_run(ctx, encode_state, encoder_context);
return VA_STATUS_SUCCESS;
}
static int gen8_mfc_vp8_qindex_estimate(struct encode_state *encode_state,
struct gen6_mfc_context *mfc_context,
int target_frame_size,
int is_key_frame)
{
VAEncSequenceParameterBufferVP8 *seq_param = (VAEncSequenceParameterBufferVP8 *)encode_state->seq_param_ext->buffer;
VAEncPictureParameterBufferVP8 *pic_param = (VAEncPictureParameterBufferVP8 *)encode_state->pic_param_ext->buffer;
unsigned int max_qindex = pic_param->clamp_qindex_high;
unsigned int min_qindex = pic_param->clamp_qindex_low;
int width_in_mbs = ALIGN(seq_param->frame_width, 16) / 16;
int height_in_mbs = ALIGN(seq_param->frame_height, 16) / 16;
int target_mb_size;
int last_size_gap = -1;
int per_mb_size_at_qindex;
int target_qindex = min_qindex, i;
/* make sure would not overflow*/
if (target_frame_size >= (0x7fffffff >> 9))
target_mb_size = (target_frame_size / width_in_mbs / height_in_mbs) << 9;
else
target_mb_size = (target_frame_size << 9) / width_in_mbs / height_in_mbs;
for (i = min_qindex; i <= max_qindex; i++) {
per_mb_size_at_qindex = vp8_bits_per_mb[!is_key_frame][i];
target_qindex = i;
if (per_mb_size_at_qindex <= target_mb_size) {
if (target_mb_size - per_mb_size_at_qindex < last_size_gap)
target_qindex--;
break;
} else
last_size_gap = per_mb_size_at_qindex - target_mb_size;
}
return target_qindex;
}
static void gen8_mfc_vp8_brc_init(struct encode_state *encode_state,
struct intel_encoder_context* encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
VAEncSequenceParameterBufferVP8 *seq_param = (VAEncSequenceParameterBufferVP8 *)encode_state->seq_param_ext->buffer;
double bitrate = encoder_context->brc.bits_per_second[0];
double framerate = (double)encoder_context->brc.framerate[0].num / (double)encoder_context->brc.framerate[0].den;
int inum = 1, pnum = 0;
int intra_period = seq_param->intra_period;
int width_in_mbs = ALIGN(seq_param->frame_width, 16) / 16;
int height_in_mbs = ALIGN(seq_param->frame_height, 16) / 16;
int max_frame_size = (vp8_bits_per_mb[0][0] >> 9) * width_in_mbs * height_in_mbs; /* vp8_bits_per_mb table mutilpled 512 */
pnum = intra_period - 1;
mfc_context->brc.mode = encoder_context->rate_control_mode;
mfc_context->brc.target_frame_size[0][SLICE_TYPE_I] = (int)((double)((bitrate * intra_period) / framerate) /
(double)(inum + BRC_PWEIGHT * pnum));
mfc_context->brc.target_frame_size[0][SLICE_TYPE_P] = BRC_PWEIGHT * mfc_context->brc.target_frame_size[0][SLICE_TYPE_I];
mfc_context->brc.gop_nums[0][SLICE_TYPE_I] = inum;
mfc_context->brc.gop_nums[0][SLICE_TYPE_P] = pnum;
mfc_context->brc.bits_per_frame[0] = bitrate / framerate;
mfc_context->brc.qp_prime_y[0][SLICE_TYPE_I] = gen8_mfc_vp8_qindex_estimate(encode_state,
mfc_context,
mfc_context->brc.target_frame_size[0][SLICE_TYPE_I],
1);
mfc_context->brc.qp_prime_y[0][SLICE_TYPE_P] = gen8_mfc_vp8_qindex_estimate(encode_state,
mfc_context,
mfc_context->brc.target_frame_size[0][SLICE_TYPE_P],
0);
if (encoder_context->brc.hrd_buffer_size)
mfc_context->hrd.buffer_size[0] = (double)encoder_context->brc.hrd_buffer_size;
else
mfc_context->hrd.buffer_size[0] = bitrate;
if (encoder_context->brc.hrd_initial_buffer_fullness &&
encoder_context->brc.hrd_initial_buffer_fullness < mfc_context->hrd.buffer_size[0])
mfc_context->hrd.current_buffer_fullness[0] = (double)encoder_context->brc.hrd_initial_buffer_fullness;
else
mfc_context->hrd.current_buffer_fullness[0] = mfc_context->hrd.buffer_size[0] / 2.0;
mfc_context->hrd.target_buffer_fullness[0] = (double)mfc_context->hrd.buffer_size[0] / 2.0;
mfc_context->hrd.buffer_capacity[0] = (double)mfc_context->hrd.buffer_size[0] / max_frame_size;
mfc_context->hrd.violation_noted = 0;
}
static int gen8_mfc_vp8_brc_postpack(struct encode_state *encode_state,
struct intel_encoder_context *encoder_context,
int frame_bits)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
gen6_brc_status sts = BRC_NO_HRD_VIOLATION;
VAEncPictureParameterBufferVP8 *pic_param = (VAEncPictureParameterBufferVP8 *)encode_state->pic_param_ext->buffer;
int is_key_frame = !pic_param->pic_flags.bits.frame_type;
int slicetype = (is_key_frame ? SLICE_TYPE_I : SLICE_TYPE_P);
int qpi = mfc_context->brc.qp_prime_y[0][SLICE_TYPE_I];
int qpp = mfc_context->brc.qp_prime_y[0][SLICE_TYPE_P];
int qp; // quantizer of previously encoded slice of current type
int qpn; // predicted quantizer for next frame of current type in integer format
double qpf; // predicted quantizer for next frame of current type in float format
double delta_qp; // QP correction
int target_frame_size, frame_size_next;
/* Notes:
* x - how far we are from HRD buffer borders
* y - how far we are from target HRD buffer fullness
*/
double x, y;
double frame_size_alpha;
unsigned int max_qindex = pic_param->clamp_qindex_high;
unsigned int min_qindex = pic_param->clamp_qindex_low;
qp = mfc_context->brc.qp_prime_y[0][slicetype];
target_frame_size = mfc_context->brc.target_frame_size[0][slicetype];
if (mfc_context->hrd.buffer_capacity[0] < 5)
frame_size_alpha = 0;
else
frame_size_alpha = (double)mfc_context->brc.gop_nums[0][slicetype];
if (frame_size_alpha > 30) frame_size_alpha = 30;
frame_size_next = target_frame_size + (double)(target_frame_size - frame_bits) /
(double)(frame_size_alpha + 1.);
/* frame_size_next: avoiding negative number and too small value */
if ((double)frame_size_next < (double)(target_frame_size * 0.25))
frame_size_next = (int)((double)target_frame_size * 0.25);
qpf = (double)qp * target_frame_size / frame_size_next;
qpn = (int)(qpf + 0.5);
if (qpn == qp) {
/* setting qpn we round qpf making mistakes: now we are trying to compensate this */
mfc_context->brc.qpf_rounding_accumulator[0] += qpf - qpn;
if (mfc_context->brc.qpf_rounding_accumulator[0] > 1.0) {
qpn++;
mfc_context->brc.qpf_rounding_accumulator[0] = 0.;
} else if (mfc_context->brc.qpf_rounding_accumulator[0] < -1.0) {
qpn--;
mfc_context->brc.qpf_rounding_accumulator[0] = 0.;
}
}
/* making sure that QP is not changing too fast */
if ((qpn - qp) > BRC_QP_MAX_CHANGE) qpn = qp + BRC_QP_MAX_CHANGE;
else if ((qpn - qp) < -BRC_QP_MAX_CHANGE) qpn = qp - BRC_QP_MAX_CHANGE;
/* making sure that with QP predictions we did do not leave QPs range */
BRC_CLIP(qpn, min_qindex, max_qindex);
/* checking wthether HRD compliance is still met */
sts = intel_mfc_update_hrd(encode_state, encoder_context, frame_bits);
/* calculating QP delta as some function*/
x = mfc_context->hrd.target_buffer_fullness[0] - mfc_context->hrd.current_buffer_fullness[0];
if (x > 0) {
x /= mfc_context->hrd.target_buffer_fullness[0];
y = mfc_context->hrd.current_buffer_fullness[0];
} else {
x /= (mfc_context->hrd.buffer_size[0] - mfc_context->hrd.target_buffer_fullness[0]);
y = mfc_context->hrd.buffer_size[0] - mfc_context->hrd.current_buffer_fullness[0];
}
if (y < 0.01) y = 0.01;
if (x > 1) x = 1;
else if (x < -1) x = -1;
delta_qp = BRC_QP_MAX_CHANGE * exp(-1 / y) * sin(BRC_PI_0_5 * x);
qpn = (int)(qpn + delta_qp + 0.5);
/* making sure that with QP predictions we did do not leave QPs range */
BRC_CLIP(qpn, min_qindex, max_qindex);
if (sts == BRC_NO_HRD_VIOLATION) { // no HRD violation
/* correcting QPs of slices of other types */
if (!is_key_frame) {
if (abs(qpn - BRC_I_P_QP_DIFF - qpi) > 4)
mfc_context->brc.qp_prime_y[0][SLICE_TYPE_I] += (qpn - BRC_I_P_QP_DIFF - qpi) >> 2;
} else {
if (abs(qpn + BRC_I_P_QP_DIFF - qpp) > 4)
mfc_context->brc.qp_prime_y[0][SLICE_TYPE_P] += (qpn + BRC_I_P_QP_DIFF - qpp) >> 2;
}
BRC_CLIP(mfc_context->brc.qp_prime_y[0][SLICE_TYPE_I], min_qindex, max_qindex);
BRC_CLIP(mfc_context->brc.qp_prime_y[0][SLICE_TYPE_P], min_qindex, max_qindex);
} else if (sts == BRC_UNDERFLOW) { // underflow
if (qpn <= qp) qpn = qp + 2;
if (qpn > max_qindex) {
qpn = max_qindex;
sts = BRC_UNDERFLOW_WITH_MAX_QP; //underflow with maxQP
}
} else if (sts == BRC_OVERFLOW) {
if (qpn >= qp) qpn = qp - 2;
if (qpn < min_qindex) { // < 0 (?) overflow with minQP
qpn = min_qindex;
sts = BRC_OVERFLOW_WITH_MIN_QP; // bit stuffing to be done
}
}
mfc_context->brc.qp_prime_y[0][slicetype] = qpn;
return sts;
}
static void gen8_mfc_vp8_hrd_context_init(struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
unsigned int rate_control_mode = encoder_context->rate_control_mode;
int target_bit_rate = encoder_context->brc.bits_per_second[0];
// current we only support CBR mode.
if (rate_control_mode == VA_RC_CBR) {
mfc_context->vui_hrd.i_bit_rate_value = target_bit_rate >> 10;
mfc_context->vui_hrd.i_initial_cpb_removal_delay = ((target_bit_rate * 8) >> 10) * 0.5 * 1024 / target_bit_rate * 90000;
mfc_context->vui_hrd.i_cpb_removal_delay = 2;
mfc_context->vui_hrd.i_frame_number = 0;
mfc_context->vui_hrd.i_initial_cpb_removal_delay_length = 24;
mfc_context->vui_hrd.i_cpb_removal_delay_length = 24;
mfc_context->vui_hrd.i_dpb_output_delay_length = 24;
}
}
static void gen8_mfc_vp8_hrd_context_update(struct encode_state *encode_state,
struct gen6_mfc_context *mfc_context)
{
mfc_context->vui_hrd.i_frame_number++;
}
static void gen8_mfc_vp8_brc_prepare(struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
unsigned int rate_control_mode = encoder_context->rate_control_mode;
if (rate_control_mode == VA_RC_CBR) {
bool brc_updated;
assert(encoder_context->codec != CODEC_MPEG2);
brc_updated = encoder_context->brc.need_reset;
/*Programing bit rate control */
if (brc_updated) {
gen8_mfc_vp8_brc_init(encode_state, encoder_context);
}
/*Programing HRD control */
if (brc_updated)
gen8_mfc_vp8_hrd_context_init(encode_state, encoder_context);
}
}
static void vp8_enc_state_init(struct gen6_mfc_context *mfc_context,
VAEncPictureParameterBufferVP8 *pic_param,
VAQMatrixBufferVP8 *q_matrix)
{
int is_key_frame = !pic_param->pic_flags.bits.frame_type;
unsigned char *coeff_probs_stream_in_buffer;
mfc_context->vp8_state.frame_header_lf_update_pos = 0;
mfc_context->vp8_state.frame_header_qindex_update_pos = 0;
mfc_context->vp8_state.frame_header_token_update_pos = 0;
mfc_context->vp8_state.frame_header_bin_mv_upate_pos = 0;
mfc_context->vp8_state.prob_skip_false = 255;
memset(mfc_context->vp8_state.mb_segment_tree_probs, 0, sizeof(mfc_context->vp8_state.mb_segment_tree_probs));
memcpy(mfc_context->vp8_state.mv_probs, vp8_default_mv_context, sizeof(mfc_context->vp8_state.mv_probs));
if (is_key_frame) {
memcpy(mfc_context->vp8_state.y_mode_probs, vp8_kf_ymode_prob, sizeof(mfc_context->vp8_state.y_mode_probs));
memcpy(mfc_context->vp8_state.uv_mode_probs, vp8_kf_uv_mode_prob, sizeof(mfc_context->vp8_state.uv_mode_probs));
mfc_context->vp8_state.prob_intra = 255;
mfc_context->vp8_state.prob_last = 128;
mfc_context->vp8_state.prob_gf = 128;
} else {
memcpy(mfc_context->vp8_state.y_mode_probs, vp8_ymode_prob, sizeof(mfc_context->vp8_state.y_mode_probs));
memcpy(mfc_context->vp8_state.uv_mode_probs, vp8_uv_mode_prob, sizeof(mfc_context->vp8_state.uv_mode_probs));
mfc_context->vp8_state.prob_intra = 63;
mfc_context->vp8_state.prob_last = 128;
mfc_context->vp8_state.prob_gf = 128;
}
mfc_context->vp8_state.prob_skip_false = vp8_base_skip_false_prob[q_matrix->quantization_index[0]];
dri_bo_map(mfc_context->vp8_state.coeff_probs_stream_in_bo, 1);
coeff_probs_stream_in_buffer = (unsigned char *)mfc_context->vp8_state.coeff_probs_stream_in_bo->virtual;
assert(coeff_probs_stream_in_buffer);
memcpy(coeff_probs_stream_in_buffer, vp8_default_coef_probs, sizeof(vp8_default_coef_probs));
dri_bo_unmap(mfc_context->vp8_state.coeff_probs_stream_in_bo);
}
static void vp8_enc_state_update(struct gen6_mfc_context *mfc_context,
VAQMatrixBufferVP8 *q_matrix)
{
/*some other probabilities need to be updated*/
}
extern void binarize_vp8_frame_header(VAEncSequenceParameterBufferVP8 *seq_param,
VAEncPictureParameterBufferVP8 *pic_param,
VAQMatrixBufferVP8 *q_matrix,
struct gen6_mfc_context *mfc_context,
struct intel_encoder_context *encoder_context);
static void vp8_enc_frame_header_binarize(struct encode_state *encode_state,
struct intel_encoder_context *encoder_context,
struct gen6_mfc_context *mfc_context)
{
VAEncSequenceParameterBufferVP8 *seq_param = (VAEncSequenceParameterBufferVP8 *)encode_state->seq_param_ext->buffer;
VAEncPictureParameterBufferVP8 *pic_param = (VAEncPictureParameterBufferVP8 *)encode_state->pic_param_ext->buffer;
VAQMatrixBufferVP8 *q_matrix = (VAQMatrixBufferVP8 *)encode_state->q_matrix->buffer;
unsigned char *frame_header_buffer;
binarize_vp8_frame_header(seq_param, pic_param, q_matrix, mfc_context, encoder_context);
dri_bo_map(mfc_context->vp8_state.frame_header_bo, 1);
frame_header_buffer = (unsigned char *)mfc_context->vp8_state.frame_header_bo->virtual;
assert(frame_header_buffer);
memcpy(frame_header_buffer, mfc_context->vp8_state.vp8_frame_header, (mfc_context->vp8_state.frame_header_bit_count + 7) / 8);
free(mfc_context->vp8_state.vp8_frame_header);
dri_bo_unmap(mfc_context->vp8_state.frame_header_bo);
}
#define MAX_VP8_FRAME_HEADER_SIZE 0x2000
#define VP8_TOKEN_STATISTICS_BUFFER_SIZE 0x2000
static void gen8_mfc_vp8_init(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct i965_driver_data *i965 = i965_driver_data(ctx);
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
dri_bo *bo;
int i;
int width_in_mbs = 0;
int height_in_mbs = 0;
int slice_batchbuffer_size;
int is_key_frame, slice_type, rate_control_mode;
VAEncSequenceParameterBufferVP8 *pSequenceParameter = (VAEncSequenceParameterBufferVP8 *)encode_state->seq_param_ext->buffer;
VAEncPictureParameterBufferVP8 *pic_param = (VAEncPictureParameterBufferVP8 *)encode_state->pic_param_ext->buffer;
VAQMatrixBufferVP8 *q_matrix = (VAQMatrixBufferVP8 *)encode_state->q_matrix->buffer;
width_in_mbs = ALIGN(pSequenceParameter->frame_height, 16) / 16;
height_in_mbs = ALIGN(pSequenceParameter->frame_height, 16) / 16;
is_key_frame = !pic_param->pic_flags.bits.frame_type;
slice_type = (is_key_frame ? SLICE_TYPE_I : SLICE_TYPE_P);
rate_control_mode = encoder_context->rate_control_mode;
if (rate_control_mode == VA_RC_CBR) {
q_matrix->quantization_index[0] = mfc_context->brc.qp_prime_y[0][slice_type];
for (i = 1; i < 4; i++)
q_matrix->quantization_index[i] = q_matrix->quantization_index[0];
for (i = 0; i < 5; i++)
q_matrix->quantization_index_delta[i] = 0;
}
slice_batchbuffer_size = 64 * width_in_mbs * height_in_mbs + 4096 +
(SLICE_HEADER + SLICE_TAIL);
/*Encode common setup for MFC*/
dri_bo_unreference(mfc_context->post_deblocking_output.bo);
mfc_context->post_deblocking_output.bo = NULL;
dri_bo_unreference(mfc_context->pre_deblocking_output.bo);
mfc_context->pre_deblocking_output.bo = NULL;
dri_bo_unreference(mfc_context->uncompressed_picture_source.bo);
mfc_context->uncompressed_picture_source.bo = NULL;
dri_bo_unreference(mfc_context->mfc_indirect_pak_bse_object.bo);
mfc_context->mfc_indirect_pak_bse_object.bo = NULL;
for (i = 0; i < NUM_MFC_DMV_BUFFERS; i++) {
if (mfc_context->direct_mv_buffers[i].bo != NULL)
dri_bo_unreference(mfc_context->direct_mv_buffers[i].bo);
mfc_context->direct_mv_buffers[i].bo = NULL;
}
for (i = 0; i < MAX_MFC_REFERENCE_SURFACES; i++) {
if (mfc_context->reference_surfaces[i].bo != NULL)
dri_bo_unreference(mfc_context->reference_surfaces[i].bo);
mfc_context->reference_surfaces[i].bo = NULL;
}
dri_bo_unreference(mfc_context->intra_row_store_scratch_buffer.bo);
bo = dri_bo_alloc(i965->intel.bufmgr,
"Buffer",
width_in_mbs * 64 * 16,
64);
assert(bo);
mfc_context->intra_row_store_scratch_buffer.bo = bo;
dri_bo_unreference(mfc_context->macroblock_status_buffer.bo);
bo = dri_bo_alloc(i965->intel.bufmgr,
"Buffer",
width_in_mbs * height_in_mbs * 16,
64);
assert(bo);
mfc_context->macroblock_status_buffer.bo = bo;
dri_bo_unreference(mfc_context->deblocking_filter_row_store_scratch_buffer.bo);
bo = dri_bo_alloc(i965->intel.bufmgr,
"Buffer",
16 * width_in_mbs * 64, /* 16 * width_in_mbs * 64 */
64);
assert(bo);
mfc_context->deblocking_filter_row_store_scratch_buffer.bo = bo;
dri_bo_unreference(mfc_context->bsd_mpc_row_store_scratch_buffer.bo);
bo = dri_bo_alloc(i965->intel.bufmgr,
"Buffer",
16 * width_in_mbs * 64, /* 16 * width_in_mbs * 64 */
0x1000);
assert(bo);
mfc_context->bsd_mpc_row_store_scratch_buffer.bo = bo;
dri_bo_unreference(mfc_context->mfc_batchbuffer_surface.bo);
mfc_context->mfc_batchbuffer_surface.bo = NULL;
dri_bo_unreference(mfc_context->aux_batchbuffer_surface.bo);
mfc_context->aux_batchbuffer_surface.bo = NULL;
if (mfc_context->aux_batchbuffer) {
intel_batchbuffer_free(mfc_context->aux_batchbuffer);
mfc_context->aux_batchbuffer = NULL;
}
mfc_context->aux_batchbuffer = intel_batchbuffer_new(&i965->intel, I915_EXEC_BSD, slice_batchbuffer_size);
mfc_context->aux_batchbuffer_surface.bo = mfc_context->aux_batchbuffer->buffer;
dri_bo_reference(mfc_context->aux_batchbuffer_surface.bo);
mfc_context->aux_batchbuffer_surface.pitch = 16;
mfc_context->aux_batchbuffer_surface.num_blocks = mfc_context->aux_batchbuffer->size / 16;
mfc_context->aux_batchbuffer_surface.size_block = 16;
gen8_gpe_context_init(ctx, &mfc_context->gpe_context);
/* alloc vp8 encoding buffers*/
dri_bo_unreference(mfc_context->vp8_state.frame_header_bo);
bo = dri_bo_alloc(i965->intel.bufmgr,
"Buffer",
MAX_VP8_FRAME_HEADER_SIZE,
0x1000);
assert(bo);
mfc_context->vp8_state.frame_header_bo = bo;
mfc_context->vp8_state.intermediate_buffer_max_size = width_in_mbs * height_in_mbs * 384 * 9;
for (i = 0; i < 8; i++) {
mfc_context->vp8_state.intermediate_partition_offset[i] = width_in_mbs * height_in_mbs * 384 * (i + 1);
}
dri_bo_unreference(mfc_context->vp8_state.intermediate_bo);
bo = dri_bo_alloc(i965->intel.bufmgr,
"Buffer",
mfc_context->vp8_state.intermediate_buffer_max_size,
0x1000);
assert(bo);
mfc_context->vp8_state.intermediate_bo = bo;
dri_bo_unreference(mfc_context->vp8_state.stream_out_bo);
bo = dri_bo_alloc(i965->intel.bufmgr,
"Buffer",
width_in_mbs * height_in_mbs * 16,
0x1000);
assert(bo);
mfc_context->vp8_state.stream_out_bo = bo;
dri_bo_unreference(mfc_context->vp8_state.coeff_probs_stream_in_bo);
bo = dri_bo_alloc(i965->intel.bufmgr,
"Buffer",
sizeof(vp8_default_coef_probs),
0x1000);
assert(bo);
mfc_context->vp8_state.coeff_probs_stream_in_bo = bo;
dri_bo_unreference(mfc_context->vp8_state.token_statistics_bo);
bo = dri_bo_alloc(i965->intel.bufmgr,
"Buffer",
VP8_TOKEN_STATISTICS_BUFFER_SIZE,
0x1000);
assert(bo);
mfc_context->vp8_state.token_statistics_bo = bo;
dri_bo_unreference(mfc_context->vp8_state.mpc_row_store_bo);
bo = dri_bo_alloc(i965->intel.bufmgr,
"Buffer",
width_in_mbs * 16 * 64,
0x1000);
assert(bo);
mfc_context->vp8_state.mpc_row_store_bo = bo;
vp8_enc_state_init(mfc_context, pic_param, q_matrix);
vp8_enc_frame_header_binarize(encode_state, encoder_context, mfc_context);
}
static VAStatus
intel_mfc_vp8_prepare(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
struct object_surface *obj_surface;
struct object_buffer *obj_buffer;
struct i965_coded_buffer_segment *coded_buffer_segment;
VAEncPictureParameterBufferVP8 *pic_param = (VAEncPictureParameterBufferVP8 *)encode_state->pic_param_ext->buffer;
VAStatus vaStatus = VA_STATUS_SUCCESS;
dri_bo *bo;
int i;
/* reconstructed surface */
obj_surface = encode_state->reconstructed_object;
i965_check_alloc_surface_bo(ctx, obj_surface, 1, VA_FOURCC('N', 'V', '1', '2'), SUBSAMPLE_YUV420);
if (pic_param->loop_filter_level[0] == 0) {
mfc_context->pre_deblocking_output.bo = obj_surface->bo;
dri_bo_reference(mfc_context->pre_deblocking_output.bo);
} else {
mfc_context->post_deblocking_output.bo = obj_surface->bo;
dri_bo_reference(mfc_context->post_deblocking_output.bo);
}
mfc_context->surface_state.width = obj_surface->orig_width;
mfc_context->surface_state.height = obj_surface->orig_height;
mfc_context->surface_state.w_pitch = obj_surface->width;
mfc_context->surface_state.h_pitch = obj_surface->height;
/* set vp8 reference frames */
for (i = 0; i < ARRAY_ELEMS(mfc_context->reference_surfaces); i++) {
obj_surface = encode_state->reference_objects[i];
if (obj_surface && obj_surface->bo) {
mfc_context->reference_surfaces[i].bo = obj_surface->bo;
dri_bo_reference(mfc_context->reference_surfaces[i].bo);
} else {
mfc_context->reference_surfaces[i].bo = NULL;
}
}
/* input YUV surface */
obj_surface = encode_state->input_yuv_object;
mfc_context->uncompressed_picture_source.bo = obj_surface->bo;
dri_bo_reference(mfc_context->uncompressed_picture_source.bo);
/* coded buffer */
obj_buffer = encode_state->coded_buf_object;
bo = obj_buffer->buffer_store->bo;
mfc_context->mfc_indirect_pak_bse_object.bo = bo;
mfc_context->mfc_indirect_pak_bse_object.offset = I965_CODEDBUFFER_HEADER_SIZE;
mfc_context->mfc_indirect_pak_bse_object.end_offset = ALIGN(obj_buffer->size_element - 0x1000, 0x1000);
dri_bo_reference(mfc_context->mfc_indirect_pak_bse_object.bo);
dri_bo_unreference(mfc_context->vp8_state.final_frame_bo);
mfc_context->vp8_state.final_frame_bo = mfc_context->mfc_indirect_pak_bse_object.bo;
mfc_context->vp8_state.final_frame_byte_offset = I965_CODEDBUFFER_HEADER_SIZE;
dri_bo_reference(mfc_context->vp8_state.final_frame_bo);
/* set the internal flag to 0 to indicate the coded size is unknown */
dri_bo_map(bo, 1);
coded_buffer_segment = (struct i965_coded_buffer_segment *)bo->virtual;
coded_buffer_segment->mapped = 0;
coded_buffer_segment->codec = encoder_context->codec;
dri_bo_unmap(bo);
return vaStatus;
}
static void
gen8_mfc_vp8_encoder_cfg(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
VAEncSequenceParameterBufferVP8 *seq_param = (VAEncSequenceParameterBufferVP8 *)encode_state->seq_param_ext->buffer;
VAEncPictureParameterBufferVP8 *pic_param = (VAEncPictureParameterBufferVP8 *)encode_state->pic_param_ext->buffer;
BEGIN_BCS_BATCH(batch, 30);
OUT_BCS_BATCH(batch, MFX_VP8_ENCODER_CFG | (30 - 2)); /* SKL should be 31-2 ? */
OUT_BCS_BATCH(batch,
0 << 9 | /* compressed bitstream output disable */
1 << 7 | /* disable per-segment delta qindex and loop filter in RC */
1 << 6 | /* RC initial pass */
0 << 4 | /* upate segment feature date flag */
1 << 3 | /* bitstream statistics output enable */
1 << 2 | /* token statistics output enable */
0 << 1 | /* final bitstream output disable */
0 << 0); /*DW1*/
OUT_BCS_BATCH(batch, 0); /*DW2*/
OUT_BCS_BATCH(batch,
0xfff << 16 | /* max intra mb bit count limit */
0xfff << 0 /* max inter mb bit count limit */
); /*DW3*/
OUT_BCS_BATCH(batch, 0); /*DW4*/
OUT_BCS_BATCH(batch, 0); /*DW5*/
OUT_BCS_BATCH(batch, 0); /*DW6*/
OUT_BCS_BATCH(batch, 0); /*DW7*/
OUT_BCS_BATCH(batch, 0); /*DW8*/
OUT_BCS_BATCH(batch, 0); /*DW9*/
OUT_BCS_BATCH(batch, 0); /*DW10*/
OUT_BCS_BATCH(batch, 0); /*DW11*/
OUT_BCS_BATCH(batch, 0); /*DW12*/
OUT_BCS_BATCH(batch, 0); /*DW13*/
OUT_BCS_BATCH(batch, 0); /*DW14*/
OUT_BCS_BATCH(batch, 0); /*DW15*/
OUT_BCS_BATCH(batch, 0); /*DW16*/
OUT_BCS_BATCH(batch, 0); /*DW17*/
OUT_BCS_BATCH(batch, 0); /*DW18*/
OUT_BCS_BATCH(batch, 0); /*DW19*/
OUT_BCS_BATCH(batch, 0); /*DW20*/
OUT_BCS_BATCH(batch, 0); /*DW21*/
OUT_BCS_BATCH(batch,
pic_param->pic_flags.bits.show_frame << 23 |
pic_param->pic_flags.bits.version << 20
); /*DW22*/
OUT_BCS_BATCH(batch,
(seq_param->frame_height_scale << 14 | seq_param->frame_height) << 16 |
(seq_param->frame_width_scale << 14 | seq_param->frame_width) << 0
);
/*DW24*/
OUT_BCS_BATCH(batch, mfc_context->vp8_state.frame_header_bit_count); /* frame header bit count */
/*DW25*/
OUT_BCS_BATCH(batch, mfc_context->vp8_state.frame_header_qindex_update_pos); /* frame header bin buffer qindex update pointer */
/*DW26*/
OUT_BCS_BATCH(batch, mfc_context->vp8_state.frame_header_lf_update_pos); /* frame header bin buffer loop filter update pointer*/
/*DW27*/
OUT_BCS_BATCH(batch, mfc_context->vp8_state.frame_header_token_update_pos); /* frame header bin buffer token update pointer */
/*DW28*/
OUT_BCS_BATCH(batch, mfc_context->vp8_state.frame_header_bin_mv_upate_pos); /*frame header bin buffer mv update pointer */
/*DW29*/
OUT_BCS_BATCH(batch, 0);
ADVANCE_BCS_BATCH(batch);
}
static void
gen8_mfc_vp8_pic_state(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
VAEncSequenceParameterBufferVP8 *seq_param = (VAEncSequenceParameterBufferVP8 *)encode_state->seq_param_ext->buffer;
VAEncPictureParameterBufferVP8 *pic_param = (VAEncPictureParameterBufferVP8 *)encode_state->pic_param_ext->buffer;
VAQMatrixBufferVP8 *q_matrix = (VAQMatrixBufferVP8 *)encode_state->q_matrix->buffer;
int i, j, log2num;
log2num = pic_param->pic_flags.bits.num_token_partitions;
/*update mode and token probs*/
vp8_enc_state_update(mfc_context, q_matrix);
BEGIN_BCS_BATCH(batch, 38);
OUT_BCS_BATCH(batch, MFX_VP8_PIC_STATE | (38 - 2));
OUT_BCS_BATCH(batch,
(ALIGN(seq_param->frame_height, 16) / 16 - 1) << 16 |
(ALIGN(seq_param->frame_width, 16) / 16 - 1) << 0);
OUT_BCS_BATCH(batch,
log2num << 24 |
pic_param->sharpness_level << 16 |
pic_param->pic_flags.bits.sign_bias_alternate << 13 |
pic_param->pic_flags.bits.sign_bias_golden << 12 |
pic_param->pic_flags.bits.loop_filter_adj_enable << 11 |
pic_param->pic_flags.bits.mb_no_coeff_skip << 10 |
pic_param->pic_flags.bits.update_mb_segmentation_map << 9 |
pic_param->pic_flags.bits.segmentation_enabled << 8 |
!pic_param->pic_flags.bits.frame_type << 5 | /* 0 indicate an intra frame in VP8 stream/spec($9.1)*/
(pic_param->pic_flags.bits.version / 2) << 4 |
(pic_param->pic_flags.bits.version == 3) << 1 | /* full pixel mode for version 3 */
!!pic_param->pic_flags.bits.version << 0); /* version 0: 6 tap */
OUT_BCS_BATCH(batch,
pic_param->loop_filter_level[3] << 24 |
pic_param->loop_filter_level[2] << 16 |
pic_param->loop_filter_level[1] << 8 |
pic_param->loop_filter_level[0] << 0);
OUT_BCS_BATCH(batch,
q_matrix->quantization_index[3] << 24 |
q_matrix->quantization_index[2] << 16 |
q_matrix->quantization_index[1] << 8 |
q_matrix->quantization_index[0] << 0);
OUT_BCS_BATCH(batch,
((unsigned short)(q_matrix->quantization_index_delta[4]) >> 15) << 28 |
abs(q_matrix->quantization_index_delta[4]) << 24 |
((unsigned short)(q_matrix->quantization_index_delta[3]) >> 15) << 20 |
abs(q_matrix->quantization_index_delta[3]) << 16 |
((unsigned short)(q_matrix->quantization_index_delta[2]) >> 15) << 12 |
abs(q_matrix->quantization_index_delta[2]) << 8 |
((unsigned short)(q_matrix->quantization_index_delta[1]) >> 15) << 4 |
abs(q_matrix->quantization_index_delta[1]) << 0);
OUT_BCS_BATCH(batch,
((unsigned short)(q_matrix->quantization_index_delta[0]) >> 15) << 4 |
abs(q_matrix->quantization_index_delta[0]) << 0);
OUT_BCS_BATCH(batch,
pic_param->clamp_qindex_high << 8 |
pic_param->clamp_qindex_low << 0);
for (i = 8; i < 19; i++) {
//OUT_BCS_BATCH(batch, 0xffffffff);
OUT_BCS_BATCH(batch, 0);
}
OUT_BCS_BATCH(batch,
mfc_context->vp8_state.mb_segment_tree_probs[2] << 16 |
mfc_context->vp8_state.mb_segment_tree_probs[1] << 8 |
mfc_context->vp8_state.mb_segment_tree_probs[0] << 0);
OUT_BCS_BATCH(batch,
mfc_context->vp8_state.prob_skip_false << 24 |
mfc_context->vp8_state.prob_intra << 16 |
mfc_context->vp8_state.prob_last << 8 |
mfc_context->vp8_state.prob_gf << 0);
OUT_BCS_BATCH(batch,
mfc_context->vp8_state.y_mode_probs[3] << 24 |
mfc_context->vp8_state.y_mode_probs[2] << 16 |
mfc_context->vp8_state.y_mode_probs[1] << 8 |
mfc_context->vp8_state.y_mode_probs[0] << 0);
OUT_BCS_BATCH(batch,
mfc_context->vp8_state.uv_mode_probs[2] << 16 |
mfc_context->vp8_state.uv_mode_probs[1] << 8 |
mfc_context->vp8_state.uv_mode_probs[0] << 0);
/* MV update value, DW23-DW32 */
for (i = 0; i < 2; i++) {
for (j = 0; j < 20; j += 4) {
OUT_BCS_BATCH(batch,
(j + 3 == 19 ? 0 : mfc_context->vp8_state.mv_probs[i][j + 3]) << 24 |
mfc_context->vp8_state.mv_probs[i][j + 2] << 16 |
mfc_context->vp8_state.mv_probs[i][j + 1] << 8 |
mfc_context->vp8_state.mv_probs[i][j + 0] << 0);
}
}
OUT_BCS_BATCH(batch,
(pic_param->ref_lf_delta[3] & 0x7f) << 24 |
(pic_param->ref_lf_delta[2] & 0x7f) << 16 |
(pic_param->ref_lf_delta[1] & 0x7f) << 8 |
(pic_param->ref_lf_delta[0] & 0x7f) << 0);
OUT_BCS_BATCH(batch,
(pic_param->mode_lf_delta[3] & 0x7f) << 24 |
(pic_param->mode_lf_delta[2] & 0x7f) << 16 |
(pic_param->mode_lf_delta[1] & 0x7f) << 8 |
(pic_param->mode_lf_delta[0] & 0x7f) << 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
ADVANCE_BCS_BATCH(batch);
}
#define OUT_VP8_BUFFER(bo, offset) \
if (bo) \
OUT_BCS_RELOC64(batch, \
bo, \
I915_GEM_DOMAIN_INSTRUCTION, I915_GEM_DOMAIN_INSTRUCTION, \
offset); \
else { \
OUT_BCS_BATCH(batch, 0); \
OUT_BCS_BATCH(batch, 0); \
} \
OUT_BCS_BATCH(batch, i965->intel.mocs_state);
static void
gen8_mfc_vp8_bsp_buf_base_addr_state(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct i965_driver_data *i965 = i965_driver_data(ctx);
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
BEGIN_BCS_BATCH(batch, 32);
OUT_BCS_BATCH(batch, MFX_VP8_BSP_BUF_BASE_ADDR_STATE | (32 - 2));
OUT_VP8_BUFFER(mfc_context->vp8_state.frame_header_bo, 0);
OUT_VP8_BUFFER(mfc_context->vp8_state.intermediate_bo, 0);
OUT_BCS_BATCH(batch, mfc_context->vp8_state.intermediate_partition_offset[0]);
OUT_BCS_BATCH(batch, mfc_context->vp8_state.intermediate_partition_offset[1]);
OUT_BCS_BATCH(batch, mfc_context->vp8_state.intermediate_partition_offset[2]);
OUT_BCS_BATCH(batch, mfc_context->vp8_state.intermediate_partition_offset[3]);
OUT_BCS_BATCH(batch, mfc_context->vp8_state.intermediate_partition_offset[4]);
OUT_BCS_BATCH(batch, mfc_context->vp8_state.intermediate_partition_offset[5]);
OUT_BCS_BATCH(batch, mfc_context->vp8_state.intermediate_partition_offset[6]);
OUT_BCS_BATCH(batch, mfc_context->vp8_state.intermediate_partition_offset[7]);
OUT_BCS_BATCH(batch, mfc_context->vp8_state.intermediate_buffer_max_size);
OUT_VP8_BUFFER(mfc_context->vp8_state.final_frame_bo, I965_CODEDBUFFER_HEADER_SIZE);
OUT_BCS_BATCH(batch, 0);
OUT_VP8_BUFFER(mfc_context->vp8_state.stream_out_bo, 0);
OUT_VP8_BUFFER(mfc_context->vp8_state.coeff_probs_stream_in_bo, 0);
OUT_VP8_BUFFER(mfc_context->vp8_state.token_statistics_bo, 0);
OUT_VP8_BUFFER(mfc_context->vp8_state.mpc_row_store_bo, 0);
ADVANCE_BCS_BATCH(batch);
}
#define ENCODE_INPUT_SOURCE 4
static void
gen10_vp8_mfc_input_surface(VADriverContextP ctx, struct intel_encoder_context *encoder_context)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
BEGIN_BCS_BATCH(batch, 6);
OUT_BCS_BATCH(batch, MFX_SURFACE_STATE | (6 - 2));
OUT_BCS_BATCH(batch, ENCODE_INPUT_SOURCE);
OUT_BCS_BATCH(batch,
((mfc_context->surface_state.height - 1) << 18) |
((mfc_context->surface_state.width - 1) << 4));
OUT_BCS_BATCH(batch,
(MFX_SURFACE_PLANAR_420_8 << 28) | /* 420 planar YUV surface */
(1 << 27) | /* must be 1 for interleave U/V, hardware requirement */
(0 << 20) |
((mfc_context->surface_state.w_pitch - 1) << 3) | /* pitch */
(0 << 2) | /* must be 0 for interleave U/V */
(1 << 1) | /* must be tiled */
(I965_TILEWALK_YMAJOR << 0)); /* tile walk, TILEWALK_YMAJOR */
OUT_BCS_BATCH(batch,
(0 << 16) | /* must be 0 for interleave U/V */
(mfc_context->surface_state.h_pitch)); /* y offset for U(cb) */
OUT_BCS_BATCH(batch, 0);
ADVANCE_BCS_BATCH(batch);
}
static void
gen8_mfc_vp8_pipeline_picture_programing(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
struct i965_driver_data *i965 = i965_driver_data(ctx);
mfc_context->pipe_mode_select(ctx, MFX_FORMAT_VP8, encoder_context);
mfc_context->set_surface_state(ctx, encoder_context);
if (IS_GEN10(i965->intel.device_info))
gen10_vp8_mfc_input_surface(ctx, encoder_context);
mfc_context->ind_obj_base_addr_state(ctx, encoder_context);
if (IS_GEN10(i965->intel.device_info))
gen10_mfc_pipe_buf_addr_state(ctx, encoder_context);
else
gen8_mfc_pipe_buf_addr_state(ctx, encoder_context);
gen8_mfc_bsp_buf_base_addr_state(ctx, encoder_context);
gen8_mfc_vp8_bsp_buf_base_addr_state(ctx, encode_state, encoder_context);
gen8_mfc_vp8_pic_state(ctx, encode_state, encoder_context);
gen8_mfc_vp8_encoder_cfg(ctx, encode_state, encoder_context);
}
static const unsigned char
vp8_intra_mb_mode_map[VME_MB_INTRA_MODE_COUNT] = {
PAK_V_PRED,
PAK_H_PRED,
PAK_DC_PRED,
PAK_TM_PRED
};
static const unsigned char
vp8_intra_block_mode_map[VME_B_INTRA_MODE_COUNT] = {
PAK_B_VE_PRED,
PAK_B_HE_PRED,
PAK_B_DC_PRED,
PAK_B_LD_PRED,
PAK_B_RD_PRED,
PAK_B_VR_PRED,
PAK_B_HD_PRED,
PAK_B_VL_PRED,
PAK_B_HU_PRED
};
static int inline gen8_mfc_vp8_intra_mb_mode_map(unsigned int vme_pred_mode, int is_luma_4x4)
{
unsigned int i, pak_pred_mode = 0;
unsigned int vme_sub_blocks_pred_mode[8], pak_sub_blocks_pred_mode[8]; /* 8 blocks's intra mode */
if (!is_luma_4x4) {
pak_pred_mode = vp8_intra_mb_mode_map[vme_pred_mode & 0x3];
} else {
for (i = 0; i < 8; i++) {
vme_sub_blocks_pred_mode[i] = ((vme_pred_mode >> (4 * i)) & 0xf);
assert(vme_sub_blocks_pred_mode[i] < VME_B_INTRA_MODE_COUNT);
pak_sub_blocks_pred_mode[i] = vp8_intra_block_mode_map[vme_sub_blocks_pred_mode[i]];
pak_pred_mode |= (pak_sub_blocks_pred_mode[i] << (4 * i));
}
}
return pak_pred_mode;
}
static void
gen8_mfc_vp8_pak_object_intra(VADriverContextP ctx,
struct intel_encoder_context *encoder_context,
unsigned int *msg,
int x, int y,
struct intel_batchbuffer *batch)
{
unsigned int vme_intra_mb_mode, vme_chroma_pred_mode;
unsigned int pak_intra_mb_mode, pak_chroma_pred_mode;
unsigned int vme_luma_pred_mode[2], pak_luma_pred_mode[2];
if (batch == NULL)
batch = encoder_context->base.batch;
vme_intra_mb_mode = ((msg[0] & 0x30) >> 4);
assert((vme_intra_mb_mode == 0) || (vme_intra_mb_mode == 2)); //vp8 only support intra_16x16 and intra_4x4
pak_intra_mb_mode = (vme_intra_mb_mode >> 1);
vme_luma_pred_mode[0] = msg[1];
vme_luma_pred_mode[1] = msg[2];
vme_chroma_pred_mode = msg[3] & 0x3;
pak_luma_pred_mode[0] = gen8_mfc_vp8_intra_mb_mode_map(vme_luma_pred_mode[0], pak_intra_mb_mode);
pak_luma_pred_mode[1] = gen8_mfc_vp8_intra_mb_mode_map(vme_luma_pred_mode[1], pak_intra_mb_mode);
pak_chroma_pred_mode = gen8_mfc_vp8_intra_mb_mode_map(vme_chroma_pred_mode, 0);
BEGIN_BCS_BATCH(batch, 7);
OUT_BCS_BATCH(batch, MFX_VP8_PAK_OBJECT | (7 - 2));
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch,
(0 << 20) | /* mv format: intra mb */
(0 << 18) | /* Segment ID */
(0 << 17) | /* disable coeff clamp */
(1 << 13) | /* intra mb flag */
(0 << 11) | /* refer picture select: last frame */
(pak_intra_mb_mode << 8) | /* mb type */
(pak_chroma_pred_mode << 4) | /* mb uv mode */
(0 << 2) | /* skip mb flag: disable */
0);
OUT_BCS_BATCH(batch, (y << 16) | x);
OUT_BCS_BATCH(batch, pak_luma_pred_mode[0]);
OUT_BCS_BATCH(batch, pak_luma_pred_mode[1]);
ADVANCE_BCS_BATCH(batch);
}
static void
gen8_mfc_vp8_pak_object_inter(VADriverContextP ctx,
struct intel_encoder_context *encoder_context,
unsigned int *msg,
int offset,
int x, int y,
struct intel_batchbuffer *batch)
{
int i;
if (batch == NULL)
batch = encoder_context->base.batch;
/* only support inter_16x16 now */
assert((msg[AVC_INTER_MSG_OFFSET] & INTER_MODE_MASK) == INTER_16X16);
/* for inter_16x16, all 16 MVs should be same,
* and move mv to the vme mb start address to make sure offset is 64 bytes aligned
* as vp8 spec, all vp8 luma motion vectors are doulbled stored
*/
msg[0] = (((msg[AVC_INTER_MV_OFFSET / 4] & 0xffff0000) << 1) | ((msg[AVC_INTER_MV_OFFSET / 4] << 1) & 0xffff));
for (i = 1; i < 16; i++) {
msg[i] = msg[0];
}
BEGIN_BCS_BATCH(batch, 7);
OUT_BCS_BATCH(batch, MFX_VP8_PAK_OBJECT | (7 - 2));
OUT_BCS_BATCH(batch,
(0 << 29) | /* enable inline mv data: disable */
64);
OUT_BCS_BATCH(batch,
offset);
OUT_BCS_BATCH(batch,
(4 << 20) | /* mv format: inter */
(0 << 18) | /* Segment ID */
(0 << 17) | /* coeff clamp: disable */
(0 << 13) | /* intra mb flag: inter mb */
(0 << 11) | /* refer picture select: last frame */
(0 << 8) | /* mb type: 16x16 */
(0 << 4) | /* mb uv mode: dc_pred */
(0 << 2) | /* skip mb flag: disable */
0);
OUT_BCS_BATCH(batch, (y << 16) | x);
/*new mv*/
OUT_BCS_BATCH(batch, 0x8);
OUT_BCS_BATCH(batch, 0x8);
ADVANCE_BCS_BATCH(batch);
}
static void
gen8_mfc_vp8_pak_pipeline(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context,
struct intel_batchbuffer *slice_batch)
{
struct gen6_vme_context *vme_context = encoder_context->vme_context;
VAEncSequenceParameterBufferVP8 *seq_param = (VAEncSequenceParameterBufferVP8 *)encode_state->seq_param_ext->buffer;
VAEncPictureParameterBufferVP8 *pic_param = (VAEncPictureParameterBufferVP8 *)encode_state->pic_param_ext->buffer;
int width_in_mbs = ALIGN(seq_param->frame_width, 16) / 16;
int height_in_mbs = ALIGN(seq_param->frame_height, 16) / 16;
unsigned int *msg = NULL;
unsigned char *msg_ptr = NULL;
unsigned int i, offset, is_intra_frame;
is_intra_frame = !pic_param->pic_flags.bits.frame_type;
dri_bo_map(vme_context->vme_output.bo, 1);
msg_ptr = (unsigned char *)vme_context->vme_output.bo->virtual;
for (i = 0; i < width_in_mbs * height_in_mbs; i++) {
int h_pos = i % width_in_mbs;
int v_pos = i / width_in_mbs;
msg = (unsigned int *)(msg_ptr + i * vme_context->vme_output.size_block);
if (is_intra_frame) {
gen8_mfc_vp8_pak_object_intra(ctx,
encoder_context,
msg,
h_pos, v_pos,
slice_batch);
} else {
int inter_rdo, intra_rdo;
inter_rdo = msg[AVC_INTER_RDO_OFFSET] & AVC_RDO_MASK;
intra_rdo = msg[AVC_INTRA_RDO_OFFSET] & AVC_RDO_MASK;
if (intra_rdo < inter_rdo) {
gen8_mfc_vp8_pak_object_intra(ctx,
encoder_context,
msg,
h_pos, v_pos,
slice_batch);
} else {
offset = i * vme_context->vme_output.size_block;
gen8_mfc_vp8_pak_object_inter(ctx,
encoder_context,
msg,
offset,
h_pos, v_pos,
slice_batch);
}
}
}
dri_bo_unmap(vme_context->vme_output.bo);
}
/*
* A batch buffer for vp8 pak object commands
*/
static dri_bo *
gen8_mfc_vp8_software_batchbuffer(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
struct intel_batchbuffer *batch;
dri_bo *batch_bo;
batch = mfc_context->aux_batchbuffer;
batch_bo = batch->buffer;
gen8_mfc_vp8_pak_pipeline(ctx, encode_state, encoder_context, batch);
intel_batchbuffer_align(batch, 8);
BEGIN_BCS_BATCH(batch, 2);
OUT_BCS_BATCH(batch, 0);
OUT_BCS_BATCH(batch, MI_BATCH_BUFFER_END);
ADVANCE_BCS_BATCH(batch);
dri_bo_reference(batch_bo);
intel_batchbuffer_free(batch);
mfc_context->aux_batchbuffer = NULL;
return batch_bo;
}
static void
gen8_mfc_vp8_pipeline_programing(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct intel_batchbuffer *batch = encoder_context->base.batch;
dri_bo *slice_batch_bo;
slice_batch_bo = gen8_mfc_vp8_software_batchbuffer(ctx, encode_state, encoder_context);
// begin programing
intel_batchbuffer_start_atomic_bcs(batch, 0x4000);
intel_batchbuffer_emit_mi_flush(batch);
// picture level programing
gen8_mfc_vp8_pipeline_picture_programing(ctx, encode_state, encoder_context);
BEGIN_BCS_BATCH(batch, 4);
OUT_BCS_BATCH(batch, MI_BATCH_BUFFER_START | (1 << 8) | (1 << 0));
OUT_BCS_RELOC64(batch,
slice_batch_bo,
I915_GEM_DOMAIN_COMMAND, 0,
0);
OUT_BCS_BATCH(batch, 0);
ADVANCE_BCS_BATCH(batch);
// end programing
intel_batchbuffer_end_atomic(batch);
dri_bo_unreference(slice_batch_bo);
}
static int gen8_mfc_calc_vp8_coded_buffer_size(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
VAEncPictureParameterBufferVP8 *pic_param = (VAEncPictureParameterBufferVP8 *)encode_state->pic_param_ext->buffer;
unsigned char is_intra_frame = !pic_param->pic_flags.bits.frame_type;
unsigned int *vp8_encoding_status, i, first_partition_bytes, token_partition_bytes, vp8_coded_bytes;
int partition_num = 1 << pic_param->pic_flags.bits.num_token_partitions;
first_partition_bytes = token_partition_bytes = vp8_coded_bytes = 0;
dri_bo_map(mfc_context->vp8_state.token_statistics_bo, 0);
vp8_encoding_status = (unsigned int *)mfc_context->vp8_state.token_statistics_bo->virtual;
first_partition_bytes = (vp8_encoding_status[0] + 7) / 8;
for (i = 1; i <= partition_num; i++)
token_partition_bytes += (vp8_encoding_status[i] + 7) / 8;
/*coded_bytes includes P0~P8 partitions bytes + uncompresse date bytes + partion_size bytes in bitstream + 3 extra bytes */
/*it seems the last partition size in vp8 status buffer is smaller than reality. so add 3 extra bytes */
vp8_coded_bytes = first_partition_bytes + token_partition_bytes + (3 + 7 * !!is_intra_frame) + (partition_num - 1) * 3 + 3;
dri_bo_unmap(mfc_context->vp8_state.token_statistics_bo);
dri_bo_map(mfc_context->vp8_state.final_frame_bo, 0);
struct i965_coded_buffer_segment *coded_buffer_segment = (struct i965_coded_buffer_segment *)(mfc_context->vp8_state.final_frame_bo->virtual);
coded_buffer_segment->base.size = vp8_coded_bytes;
dri_bo_unmap(mfc_context->vp8_state.final_frame_bo);
return vp8_coded_bytes;
}
static VAStatus
gen8_mfc_vp8_encode_picture(VADriverContextP ctx,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
struct gen6_mfc_context *mfc_context = encoder_context->mfc_context;
unsigned int rate_control_mode = encoder_context->rate_control_mode;
int current_frame_bits_size;
int sts;
gen8_mfc_vp8_init(ctx, encode_state, encoder_context);
intel_mfc_vp8_prepare(ctx, encode_state, encoder_context);
/*Programing bcs pipeline*/
gen8_mfc_vp8_pipeline_programing(ctx, encode_state, encoder_context);
gen8_mfc_run(ctx, encode_state, encoder_context);
current_frame_bits_size = 8 * gen8_mfc_calc_vp8_coded_buffer_size(ctx, encode_state, encoder_context);
if (rate_control_mode == VA_RC_CBR /*|| rate_control_mode == VA_RC_VBR*/) {
sts = gen8_mfc_vp8_brc_postpack(encode_state, encoder_context, current_frame_bits_size);
if (sts == BRC_NO_HRD_VIOLATION) {
gen8_mfc_vp8_hrd_context_update(encode_state, mfc_context);
} else if (sts == BRC_OVERFLOW_WITH_MIN_QP || sts == BRC_UNDERFLOW_WITH_MAX_QP) {
if (!mfc_context->hrd.violation_noted) {
fprintf(stderr, "Unrepairable %s!\n", (sts == BRC_OVERFLOW_WITH_MIN_QP) ? "overflow" : "underflow");
mfc_context->hrd.violation_noted = 1;
}
return VA_STATUS_SUCCESS;
}
}
return VA_STATUS_SUCCESS;
}
static void
gen8_mfc_context_destroy(void *context)
{
struct gen6_mfc_context *mfc_context = context;
int i;
dri_bo_unreference(mfc_context->post_deblocking_output.bo);
mfc_context->post_deblocking_output.bo = NULL;
dri_bo_unreference(mfc_context->pre_deblocking_output.bo);
mfc_context->pre_deblocking_output.bo = NULL;
dri_bo_unreference(mfc_context->uncompressed_picture_source.bo);
mfc_context->uncompressed_picture_source.bo = NULL;
dri_bo_unreference(mfc_context->mfc_indirect_pak_bse_object.bo);
mfc_context->mfc_indirect_pak_bse_object.bo = NULL;
for (i = 0; i < NUM_MFC_DMV_BUFFERS; i++) {
dri_bo_unreference(mfc_context->direct_mv_buffers[i].bo);
mfc_context->direct_mv_buffers[i].bo = NULL;
}
dri_bo_unreference(mfc_context->intra_row_store_scratch_buffer.bo);
mfc_context->intra_row_store_scratch_buffer.bo = NULL;
dri_bo_unreference(mfc_context->macroblock_status_buffer.bo);
mfc_context->macroblock_status_buffer.bo = NULL;
dri_bo_unreference(mfc_context->deblocking_filter_row_store_scratch_buffer.bo);
mfc_context->deblocking_filter_row_store_scratch_buffer.bo = NULL;
dri_bo_unreference(mfc_context->bsd_mpc_row_store_scratch_buffer.bo);
mfc_context->bsd_mpc_row_store_scratch_buffer.bo = NULL;
for (i = 0; i < MAX_MFC_REFERENCE_SURFACES; i++) {
dri_bo_unreference(mfc_context->reference_surfaces[i].bo);
mfc_context->reference_surfaces[i].bo = NULL;
}
gen8_gpe_context_destroy(&mfc_context->gpe_context);
dri_bo_unreference(mfc_context->mfc_batchbuffer_surface.bo);
mfc_context->mfc_batchbuffer_surface.bo = NULL;
dri_bo_unreference(mfc_context->aux_batchbuffer_surface.bo);
mfc_context->aux_batchbuffer_surface.bo = NULL;
if (mfc_context->aux_batchbuffer)
intel_batchbuffer_free(mfc_context->aux_batchbuffer);
mfc_context->aux_batchbuffer = NULL;
dri_bo_unreference(mfc_context->vp8_state.coeff_probs_stream_in_bo);
mfc_context->vp8_state.coeff_probs_stream_in_bo = NULL;
dri_bo_unreference(mfc_context->vp8_state.final_frame_bo);
mfc_context->vp8_state.final_frame_bo = NULL;
dri_bo_unreference(mfc_context->vp8_state.frame_header_bo);
mfc_context->vp8_state.frame_header_bo = NULL;
dri_bo_unreference(mfc_context->vp8_state.intermediate_bo);
mfc_context->vp8_state.intermediate_bo = NULL;
dri_bo_unreference(mfc_context->vp8_state.mpc_row_store_bo);
mfc_context->vp8_state.mpc_row_store_bo = NULL;
dri_bo_unreference(mfc_context->vp8_state.stream_out_bo);
mfc_context->vp8_state.stream_out_bo = NULL;
dri_bo_unreference(mfc_context->vp8_state.token_statistics_bo);
mfc_context->vp8_state.token_statistics_bo = NULL;
free(mfc_context);
}
static VAStatus gen8_mfc_pipeline(VADriverContextP ctx,
VAProfile profile,
struct encode_state *encode_state,
struct intel_encoder_context *encoder_context)
{
VAStatus vaStatus;
switch (profile) {
case VAProfileH264ConstrainedBaseline:
case VAProfileH264Main:
case VAProfileH264High:
case VAProfileH264MultiviewHigh:
case VAProfileH264StereoHigh:
vaStatus = gen8_mfc_avc_encode_picture(ctx, encode_state, encoder_context);
break;
case VAProfileMPEG2Simple:
case VAProfileMPEG2Main:
vaStatus = gen8_mfc_mpeg2_encode_picture(ctx, encode_state, encoder_context);
break;
case VAProfileJPEGBaseline:
jpeg_init_default_qmatrix(ctx, encoder_context);
vaStatus = gen8_mfc_jpeg_encode_picture(ctx, encode_state, encoder_context);
break;
case VAProfileVP8Version0_3:
vaStatus = gen8_mfc_vp8_encode_picture(ctx, encode_state, encoder_context);
break;
default:
vaStatus = VA_STATUS_ERROR_UNSUPPORTED_PROFILE;
break;
}
return vaStatus;
}
extern Bool i965_encoder_vp8_pak_context_init(VADriverContextP ctx, struct intel_encoder_context *encoder_context);
Bool gen8_mfc_context_init(VADriverContextP ctx, struct intel_encoder_context *encoder_context)
{
struct i965_driver_data *i965 = i965_driver_data(ctx);
struct gen6_mfc_context *mfc_context;
if (IS_CHERRYVIEW(i965->intel.device_info) && encoder_context->codec == CODEC_VP8)
return i965_encoder_vp8_pak_context_init(ctx, encoder_context);
if (IS_GEN8(i965->intel.device_info) && (encoder_context->codec == CODEC_H264 ||
encoder_context->codec == CODEC_H264_MVC)) {
return gen9_avc_pak_context_init(ctx, encoder_context);
}
mfc_context = calloc(1, sizeof(struct gen6_mfc_context));
assert(mfc_context);
mfc_context->gpe_context.surface_state_binding_table.length = (SURFACE_STATE_PADDED_SIZE + sizeof(unsigned int)) * MAX_MEDIA_SURFACES_GEN6;
mfc_context->gpe_context.idrt.entry_size = ALIGN(sizeof(struct gen8_interface_descriptor_data), 64);
mfc_context->gpe_context.idrt.max_entries = MAX_INTERFACE_DESC_GEN6;
mfc_context->gpe_context.curbe.length = 32 * 4;
mfc_context->gpe_context.sampler.entry_size = 0;
mfc_context->gpe_context.sampler.max_entries = 0;
if (i965->intel.eu_total > 0)
mfc_context->gpe_context.vfe_state.max_num_threads = 6 * i965->intel.eu_total;
else
mfc_context->gpe_context.vfe_state.max_num_threads = 60 - 1;
mfc_context->gpe_context.vfe_state.num_urb_entries = 16;
mfc_context->gpe_context.vfe_state.gpgpu_mode = 0;
mfc_context->gpe_context.vfe_state.urb_entry_size = 59 - 1;
mfc_context->gpe_context.vfe_state.curbe_allocation_size = 37 - 1;
if (IS_GEN9(i965->intel.device_info) ||
IS_GEN10(i965->intel.device_info)) {
gen8_gpe_load_kernels(ctx,
&mfc_context->gpe_context,
gen9_mfc_kernels,
1);
} else {
gen8_gpe_load_kernels(ctx,
&mfc_context->gpe_context,
gen8_mfc_kernels,
1);
}
mfc_context->pipe_mode_select = gen8_mfc_pipe_mode_select;
mfc_context->set_surface_state = gen8_mfc_surface_state;
mfc_context->ind_obj_base_addr_state = gen8_mfc_ind_obj_base_addr_state;
mfc_context->avc_img_state = gen8_mfc_avc_img_state;
mfc_context->avc_qm_state = gen8_mfc_avc_qm_state;
mfc_context->avc_fqm_state = gen8_mfc_avc_fqm_state;
mfc_context->insert_object = gen8_mfc_avc_insert_object;
mfc_context->buffer_suface_setup = gen8_gpe_buffer_suface_setup;
encoder_context->mfc_context = mfc_context;
encoder_context->mfc_context_destroy = gen8_mfc_context_destroy;
encoder_context->mfc_pipeline = gen8_mfc_pipeline;
if (encoder_context->codec == CODEC_VP8)
encoder_context->mfc_brc_prepare = gen8_mfc_vp8_brc_prepare;
else
encoder_context->mfc_brc_prepare = intel_mfc_brc_prepare;
return True;
}
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