Commit f25709c4 authored by Andrzej Pietrasiewicz's avatar Andrzej Pietrasiewicz Committed by Mauro Carvalho Chehab

media: rkvdec: Add the VP9 backend

The Rockchip VDEC supports VP9 profile 0 up to 4096x2304@30fps. Add
a backend for this new format.
Signed-off-by: default avatarBoris Brezillon <boris.brezillon@collabora.com>
Signed-off-by: default avatarEzequiel Garcia <ezequiel@collabora.com>
Signed-off-by: default avatarAdrian Ratiu <adrian.ratiu@collabora.com>
Co-developed-by: default avatarAndrzej Pietrasiewicz <andrzej.p@collabora.com>
Signed-off-by: default avatarAndrzej Pietrasiewicz <andrzej.p@collabora.com>
Signed-off-by: default avatarHans Verkuil <hverkuil-cisco@xs4all.nl>
Signed-off-by: default avatarMauro Carvalho Chehab <mchehab+huawei@kernel.org>
parent 3e3b1fb0
...@@ -9,6 +9,7 @@ config VIDEO_ROCKCHIP_VDEC ...@@ -9,6 +9,7 @@ config VIDEO_ROCKCHIP_VDEC
select VIDEOBUF2_VMALLOC select VIDEOBUF2_VMALLOC
select V4L2_MEM2MEM_DEV select V4L2_MEM2MEM_DEV
select V4L2_H264 select V4L2_H264
select V4L2_VP9
help help
Support for the Rockchip Video Decoder IP present on Rockchip SoCs, Support for the Rockchip Video Decoder IP present on Rockchip SoCs,
which accelerates video decoding. which accelerates video decoding.
......
obj-$(CONFIG_VIDEO_ROCKCHIP_VDEC) += rockchip-vdec.o obj-$(CONFIG_VIDEO_ROCKCHIP_VDEC) += rockchip-vdec.o
rockchip-vdec-y += rkvdec.o rkvdec-h264.o rockchip-vdec-y += rkvdec.o rkvdec-h264.o rkvdec-vp9.o
// SPDX-License-Identifier: GPL-2.0
/*
* Rockchip Video Decoder VP9 backend
*
* Copyright (C) 2019 Collabora, Ltd.
* Boris Brezillon <boris.brezillon@collabora.com>
* Copyright (C) 2021 Collabora, Ltd.
* Andrzej Pietrasiewicz <andrzej.p@collabora.com>
*
* Copyright (C) 2016 Rockchip Electronics Co., Ltd.
* Alpha Lin <Alpha.Lin@rock-chips.com>
*/
/*
* For following the vp9 spec please start reading this driver
* code from rkvdec_vp9_run() followed by rkvdec_vp9_done().
*/
#include <linux/kernel.h>
#include <linux/vmalloc.h>
#include <media/v4l2-mem2mem.h>
#include <media/v4l2-vp9.h>
#include "rkvdec.h"
#include "rkvdec-regs.h"
#define RKVDEC_VP9_PROBE_SIZE 4864
#define RKVDEC_VP9_COUNT_SIZE 13232
#define RKVDEC_VP9_MAX_SEGMAP_SIZE 73728
struct rkvdec_vp9_intra_mode_probs {
u8 y_mode[105];
u8 uv_mode[23];
};
struct rkvdec_vp9_intra_only_frame_probs {
u8 coef_intra[4][2][128];
struct rkvdec_vp9_intra_mode_probs intra_mode[10];
};
struct rkvdec_vp9_inter_frame_probs {
u8 y_mode[4][9];
u8 comp_mode[5];
u8 comp_ref[5];
u8 single_ref[5][2];
u8 inter_mode[7][3];
u8 interp_filter[4][2];
u8 padding0[11];
u8 coef[2][4][2][128];
u8 uv_mode_0_2[3][9];
u8 padding1[5];
u8 uv_mode_3_5[3][9];
u8 padding2[5];
u8 uv_mode_6_8[3][9];
u8 padding3[5];
u8 uv_mode_9[9];
u8 padding4[7];
u8 padding5[16];
struct {
u8 joint[3];
u8 sign[2];
u8 classes[2][10];
u8 class0_bit[2];
u8 bits[2][10];
u8 class0_fr[2][2][3];
u8 fr[2][3];
u8 class0_hp[2];
u8 hp[2];
} mv;
};
struct rkvdec_vp9_probs {
u8 partition[16][3];
u8 pred[3];
u8 tree[7];
u8 skip[3];
u8 tx32[2][3];
u8 tx16[2][2];
u8 tx8[2][1];
u8 is_inter[4];
/* 128 bit alignment */
u8 padding0[3];
union {
struct rkvdec_vp9_inter_frame_probs inter;
struct rkvdec_vp9_intra_only_frame_probs intra_only;
};
};
/* Data structure describing auxiliary buffer format. */
struct rkvdec_vp9_priv_tbl {
struct rkvdec_vp9_probs probs;
u8 segmap[2][RKVDEC_VP9_MAX_SEGMAP_SIZE];
};
struct rkvdec_vp9_refs_counts {
u32 eob[2];
u32 coeff[3];
};
struct rkvdec_vp9_inter_frame_symbol_counts {
u32 partition[16][4];
u32 skip[3][2];
u32 inter[4][2];
u32 tx32p[2][4];
u32 tx16p[2][4];
u32 tx8p[2][2];
u32 y_mode[4][10];
u32 uv_mode[10][10];
u32 comp[5][2];
u32 comp_ref[5][2];
u32 single_ref[5][2][2];
u32 mv_mode[7][4];
u32 filter[4][3];
u32 mv_joint[4];
u32 sign[2][2];
/* add 1 element for align */
u32 classes[2][11 + 1];
u32 class0[2][2];
u32 bits[2][10][2];
u32 class0_fp[2][2][4];
u32 fp[2][4];
u32 class0_hp[2][2];
u32 hp[2][2];
struct rkvdec_vp9_refs_counts ref_cnt[2][4][2][6][6];
};
struct rkvdec_vp9_intra_frame_symbol_counts {
u32 partition[4][4][4];
u32 skip[3][2];
u32 intra[4][2];
u32 tx32p[2][4];
u32 tx16p[2][4];
u32 tx8p[2][2];
struct rkvdec_vp9_refs_counts ref_cnt[2][4][2][6][6];
};
struct rkvdec_vp9_run {
struct rkvdec_run base;
const struct v4l2_ctrl_vp9_frame *decode_params;
};
struct rkvdec_vp9_frame_info {
u32 valid : 1;
u32 segmapid : 1;
u32 frame_context_idx : 2;
u32 reference_mode : 2;
u32 tx_mode : 3;
u32 interpolation_filter : 3;
u32 flags;
u64 timestamp;
struct v4l2_vp9_segmentation seg;
struct v4l2_vp9_loop_filter lf;
};
struct rkvdec_vp9_ctx {
struct rkvdec_aux_buf priv_tbl;
struct rkvdec_aux_buf count_tbl;
struct v4l2_vp9_frame_symbol_counts inter_cnts;
struct v4l2_vp9_frame_symbol_counts intra_cnts;
struct v4l2_vp9_frame_context probability_tables;
struct v4l2_vp9_frame_context frame_context[4];
struct rkvdec_vp9_frame_info cur;
struct rkvdec_vp9_frame_info last;
};
static void write_coeff_plane(const u8 coef[6][6][3], u8 *coeff_plane)
{
unsigned int idx = 0, byte_count = 0;
int k, m, n;
u8 p;
for (k = 0; k < 6; k++) {
for (m = 0; m < 6; m++) {
for (n = 0; n < 3; n++) {
p = coef[k][m][n];
coeff_plane[idx++] = p;
byte_count++;
if (byte_count == 27) {
idx += 5;
byte_count = 0;
}
}
}
}
}
static void init_intra_only_probs(struct rkvdec_ctx *ctx,
const struct rkvdec_vp9_run *run)
{
struct rkvdec_vp9_ctx *vp9_ctx = ctx->priv;
struct rkvdec_vp9_priv_tbl *tbl = vp9_ctx->priv_tbl.cpu;
struct rkvdec_vp9_intra_only_frame_probs *rkprobs;
const struct v4l2_vp9_frame_context *probs;
unsigned int i, j, k;
rkprobs = &tbl->probs.intra_only;
probs = &vp9_ctx->probability_tables;
/*
* intra only 149 x 128 bits ,aligned to 152 x 128 bits coeff related
* prob 64 x 128 bits
*/
for (i = 0; i < ARRAY_SIZE(probs->coef); i++) {
for (j = 0; j < ARRAY_SIZE(probs->coef[0]); j++)
write_coeff_plane(probs->coef[i][j][0],
rkprobs->coef_intra[i][j]);
}
/* intra mode prob 80 x 128 bits */
for (i = 0; i < ARRAY_SIZE(v4l2_vp9_kf_y_mode_prob); i++) {
unsigned int byte_count = 0;
int idx = 0;
/* vp9_kf_y_mode_prob */
for (j = 0; j < ARRAY_SIZE(v4l2_vp9_kf_y_mode_prob[0]); j++) {
for (k = 0; k < ARRAY_SIZE(v4l2_vp9_kf_y_mode_prob[0][0]);
k++) {
u8 val = v4l2_vp9_kf_y_mode_prob[i][j][k];
rkprobs->intra_mode[i].y_mode[idx++] = val;
byte_count++;
if (byte_count == 27) {
byte_count = 0;
idx += 5;
}
}
}
}
for (i = 0; i < sizeof(v4l2_vp9_kf_uv_mode_prob); ++i) {
const u8 *ptr = (const u8 *)v4l2_vp9_kf_uv_mode_prob;
rkprobs->intra_mode[i / 23].uv_mode[i % 23] = ptr[i];
}
}
static void init_inter_probs(struct rkvdec_ctx *ctx,
const struct rkvdec_vp9_run *run)
{
struct rkvdec_vp9_ctx *vp9_ctx = ctx->priv;
struct rkvdec_vp9_priv_tbl *tbl = vp9_ctx->priv_tbl.cpu;
struct rkvdec_vp9_inter_frame_probs *rkprobs;
const struct v4l2_vp9_frame_context *probs;
unsigned int i, j, k;
rkprobs = &tbl->probs.inter;
probs = &vp9_ctx->probability_tables;
/*
* inter probs
* 151 x 128 bits, aligned to 152 x 128 bits
* inter only
* intra_y_mode & inter_block info 6 x 128 bits
*/
memcpy(rkprobs->y_mode, probs->y_mode, sizeof(rkprobs->y_mode));
memcpy(rkprobs->comp_mode, probs->comp_mode,
sizeof(rkprobs->comp_mode));
memcpy(rkprobs->comp_ref, probs->comp_ref,
sizeof(rkprobs->comp_ref));
memcpy(rkprobs->single_ref, probs->single_ref,
sizeof(rkprobs->single_ref));
memcpy(rkprobs->inter_mode, probs->inter_mode,
sizeof(rkprobs->inter_mode));
memcpy(rkprobs->interp_filter, probs->interp_filter,
sizeof(rkprobs->interp_filter));
/* 128 x 128 bits coeff related */
for (i = 0; i < ARRAY_SIZE(probs->coef); i++) {
for (j = 0; j < ARRAY_SIZE(probs->coef[0]); j++) {
for (k = 0; k < ARRAY_SIZE(probs->coef[0][0]); k++)
write_coeff_plane(probs->coef[i][j][k],
rkprobs->coef[k][i][j]);
}
}
/* intra uv mode 6 x 128 */
memcpy(rkprobs->uv_mode_0_2, &probs->uv_mode[0],
sizeof(rkprobs->uv_mode_0_2));
memcpy(rkprobs->uv_mode_3_5, &probs->uv_mode[3],
sizeof(rkprobs->uv_mode_3_5));
memcpy(rkprobs->uv_mode_6_8, &probs->uv_mode[6],
sizeof(rkprobs->uv_mode_6_8));
memcpy(rkprobs->uv_mode_9, &probs->uv_mode[9],
sizeof(rkprobs->uv_mode_9));
/* mv related 6 x 128 */
memcpy(rkprobs->mv.joint, probs->mv.joint,
sizeof(rkprobs->mv.joint));
memcpy(rkprobs->mv.sign, probs->mv.sign,
sizeof(rkprobs->mv.sign));
memcpy(rkprobs->mv.classes, probs->mv.classes,
sizeof(rkprobs->mv.classes));
memcpy(rkprobs->mv.class0_bit, probs->mv.class0_bit,
sizeof(rkprobs->mv.class0_bit));
memcpy(rkprobs->mv.bits, probs->mv.bits,
sizeof(rkprobs->mv.bits));
memcpy(rkprobs->mv.class0_fr, probs->mv.class0_fr,
sizeof(rkprobs->mv.class0_fr));
memcpy(rkprobs->mv.fr, probs->mv.fr,
sizeof(rkprobs->mv.fr));
memcpy(rkprobs->mv.class0_hp, probs->mv.class0_hp,
sizeof(rkprobs->mv.class0_hp));
memcpy(rkprobs->mv.hp, probs->mv.hp,
sizeof(rkprobs->mv.hp));
}
static void init_probs(struct rkvdec_ctx *ctx,
const struct rkvdec_vp9_run *run)
{
const struct v4l2_ctrl_vp9_frame *dec_params;
struct rkvdec_vp9_ctx *vp9_ctx = ctx->priv;
struct rkvdec_vp9_priv_tbl *tbl = vp9_ctx->priv_tbl.cpu;
struct rkvdec_vp9_probs *rkprobs = &tbl->probs;
const struct v4l2_vp9_segmentation *seg;
const struct v4l2_vp9_frame_context *probs;
bool intra_only;
dec_params = run->decode_params;
probs = &vp9_ctx->probability_tables;
seg = &dec_params->seg;
memset(rkprobs, 0, sizeof(*rkprobs));
intra_only = !!(dec_params->flags &
(V4L2_VP9_FRAME_FLAG_KEY_FRAME |
V4L2_VP9_FRAME_FLAG_INTRA_ONLY));
/* sb info 5 x 128 bit */
memcpy(rkprobs->partition,
intra_only ? v4l2_vp9_kf_partition_probs : probs->partition,
sizeof(rkprobs->partition));
memcpy(rkprobs->pred, seg->pred_probs, sizeof(rkprobs->pred));
memcpy(rkprobs->tree, seg->tree_probs, sizeof(rkprobs->tree));
memcpy(rkprobs->skip, probs->skip, sizeof(rkprobs->skip));
memcpy(rkprobs->tx32, probs->tx32, sizeof(rkprobs->tx32));
memcpy(rkprobs->tx16, probs->tx16, sizeof(rkprobs->tx16));
memcpy(rkprobs->tx8, probs->tx8, sizeof(rkprobs->tx8));
memcpy(rkprobs->is_inter, probs->is_inter, sizeof(rkprobs->is_inter));
if (intra_only)
init_intra_only_probs(ctx, run);
else
init_inter_probs(ctx, run);
}
struct rkvdec_vp9_ref_reg {
u32 reg_frm_size;
u32 reg_hor_stride;
u32 reg_y_stride;
u32 reg_yuv_stride;
u32 reg_ref_base;
};
static struct rkvdec_vp9_ref_reg ref_regs[] = {
{
.reg_frm_size = RKVDEC_REG_VP9_FRAME_SIZE(0),
.reg_hor_stride = RKVDEC_VP9_HOR_VIRSTRIDE(0),
.reg_y_stride = RKVDEC_VP9_LAST_FRAME_YSTRIDE,
.reg_yuv_stride = RKVDEC_VP9_LAST_FRAME_YUVSTRIDE,
.reg_ref_base = RKVDEC_REG_VP9_LAST_FRAME_BASE,
},
{
.reg_frm_size = RKVDEC_REG_VP9_FRAME_SIZE(1),
.reg_hor_stride = RKVDEC_VP9_HOR_VIRSTRIDE(1),
.reg_y_stride = RKVDEC_VP9_GOLDEN_FRAME_YSTRIDE,
.reg_yuv_stride = 0,
.reg_ref_base = RKVDEC_REG_VP9_GOLDEN_FRAME_BASE,
},
{
.reg_frm_size = RKVDEC_REG_VP9_FRAME_SIZE(2),
.reg_hor_stride = RKVDEC_VP9_HOR_VIRSTRIDE(2),
.reg_y_stride = RKVDEC_VP9_ALTREF_FRAME_YSTRIDE,
.reg_yuv_stride = 0,
.reg_ref_base = RKVDEC_REG_VP9_ALTREF_FRAME_BASE,
}
};
static struct rkvdec_decoded_buffer *
get_ref_buf(struct rkvdec_ctx *ctx, struct vb2_v4l2_buffer *dst, u64 timestamp)
{
struct v4l2_m2m_ctx *m2m_ctx = ctx->fh.m2m_ctx;
struct vb2_queue *cap_q = &m2m_ctx->cap_q_ctx.q;
int buf_idx;
/*
* If a ref is unused or invalid, address of current destination
* buffer is returned.
*/
buf_idx = vb2_find_timestamp(cap_q, timestamp, 0);
if (buf_idx < 0)
return vb2_to_rkvdec_decoded_buf(&dst->vb2_buf);
return vb2_to_rkvdec_decoded_buf(vb2_get_buffer(cap_q, buf_idx));
}
static dma_addr_t get_mv_base_addr(struct rkvdec_decoded_buffer *buf)
{
unsigned int aligned_pitch, aligned_height, yuv_len;
aligned_height = round_up(buf->vp9.height, 64);
aligned_pitch = round_up(buf->vp9.width * buf->vp9.bit_depth, 512) / 8;
yuv_len = (aligned_height * aligned_pitch * 3) / 2;
return vb2_dma_contig_plane_dma_addr(&buf->base.vb.vb2_buf, 0) +
yuv_len;
}
static void config_ref_registers(struct rkvdec_ctx *ctx,
const struct rkvdec_vp9_run *run,
struct rkvdec_decoded_buffer *ref_buf,
struct rkvdec_vp9_ref_reg *ref_reg)
{
unsigned int aligned_pitch, aligned_height, y_len, yuv_len;
struct rkvdec_dev *rkvdec = ctx->dev;
aligned_height = round_up(ref_buf->vp9.height, 64);
writel_relaxed(RKVDEC_VP9_FRAMEWIDTH(ref_buf->vp9.width) |
RKVDEC_VP9_FRAMEHEIGHT(ref_buf->vp9.height),
rkvdec->regs + ref_reg->reg_frm_size);
writel_relaxed(vb2_dma_contig_plane_dma_addr(&ref_buf->base.vb.vb2_buf, 0),
rkvdec->regs + ref_reg->reg_ref_base);
if (&ref_buf->base.vb == run->base.bufs.dst)
return;
aligned_pitch = round_up(ref_buf->vp9.width * ref_buf->vp9.bit_depth, 512) / 8;
y_len = aligned_height * aligned_pitch;
yuv_len = (y_len * 3) / 2;
writel_relaxed(RKVDEC_HOR_Y_VIRSTRIDE(aligned_pitch / 16) |
RKVDEC_HOR_UV_VIRSTRIDE(aligned_pitch / 16),
rkvdec->regs + ref_reg->reg_hor_stride);
writel_relaxed(RKVDEC_VP9_REF_YSTRIDE(y_len / 16),
rkvdec->regs + ref_reg->reg_y_stride);
if (!ref_reg->reg_yuv_stride)
return;
writel_relaxed(RKVDEC_VP9_REF_YUVSTRIDE(yuv_len / 16),
rkvdec->regs + ref_reg->reg_yuv_stride);
}
static void config_seg_registers(struct rkvdec_ctx *ctx, unsigned int segid)
{
struct rkvdec_vp9_ctx *vp9_ctx = ctx->priv;
const struct v4l2_vp9_segmentation *seg;
struct rkvdec_dev *rkvdec = ctx->dev;
s16 feature_val;
int feature_id;
u32 val = 0;
seg = vp9_ctx->last.valid ? &vp9_ctx->last.seg : &vp9_ctx->cur.seg;
feature_id = V4L2_VP9_SEG_LVL_ALT_Q;
if (v4l2_vp9_seg_feat_enabled(seg->feature_enabled, feature_id, segid)) {
feature_val = seg->feature_data[segid][feature_id];
val |= RKVDEC_SEGID_FRAME_QP_DELTA_EN(1) |
RKVDEC_SEGID_FRAME_QP_DELTA(feature_val);
}
feature_id = V4L2_VP9_SEG_LVL_ALT_L;
if (v4l2_vp9_seg_feat_enabled(seg->feature_enabled, feature_id, segid)) {
feature_val = seg->feature_data[segid][feature_id];
val |= RKVDEC_SEGID_FRAME_LOOPFILTER_VALUE_EN(1) |
RKVDEC_SEGID_FRAME_LOOPFILTER_VALUE(feature_val);
}
feature_id = V4L2_VP9_SEG_LVL_REF_FRAME;
if (v4l2_vp9_seg_feat_enabled(seg->feature_enabled, feature_id, segid)) {
feature_val = seg->feature_data[segid][feature_id];
val |= RKVDEC_SEGID_REFERINFO_EN(1) |
RKVDEC_SEGID_REFERINFO(feature_val);
}
feature_id = V4L2_VP9_SEG_LVL_SKIP;
if (v4l2_vp9_seg_feat_enabled(seg->feature_enabled, feature_id, segid))
val |= RKVDEC_SEGID_FRAME_SKIP_EN(1);
if (!segid &&
(seg->flags & V4L2_VP9_SEGMENTATION_FLAG_ABS_OR_DELTA_UPDATE))
val |= RKVDEC_SEGID_ABS_DELTA(1);
writel_relaxed(val, rkvdec->regs + RKVDEC_VP9_SEGID_GRP(segid));
}
static void update_dec_buf_info(struct rkvdec_decoded_buffer *buf,
const struct v4l2_ctrl_vp9_frame *dec_params)
{
buf->vp9.width = dec_params->frame_width_minus_1 + 1;
buf->vp9.height = dec_params->frame_height_minus_1 + 1;
buf->vp9.bit_depth = dec_params->bit_depth;
}
static void update_ctx_cur_info(struct rkvdec_vp9_ctx *vp9_ctx,
struct rkvdec_decoded_buffer *buf,
const struct v4l2_ctrl_vp9_frame *dec_params)
{
vp9_ctx->cur.valid = true;
vp9_ctx->cur.reference_mode = dec_params->reference_mode;
vp9_ctx->cur.interpolation_filter = dec_params->interpolation_filter;
vp9_ctx->cur.flags = dec_params->flags;
vp9_ctx->cur.timestamp = buf->base.vb.vb2_buf.timestamp;
vp9_ctx->cur.seg = dec_params->seg;
vp9_ctx->cur.lf = dec_params->lf;
}
static void update_ctx_last_info(struct rkvdec_vp9_ctx *vp9_ctx)
{
vp9_ctx->last = vp9_ctx->cur;
}
static void config_registers(struct rkvdec_ctx *ctx,
const struct rkvdec_vp9_run *run)
{
unsigned int y_len, uv_len, yuv_len, bit_depth, aligned_height, aligned_pitch, stream_len;
const struct v4l2_ctrl_vp9_frame *dec_params;
struct rkvdec_decoded_buffer *ref_bufs[3];
struct rkvdec_decoded_buffer *dst, *last, *mv_ref;
struct rkvdec_vp9_ctx *vp9_ctx = ctx->priv;
u32 val, last_frame_info = 0;
const struct v4l2_vp9_segmentation *seg;
struct rkvdec_dev *rkvdec = ctx->dev;
dma_addr_t addr;
bool intra_only;
unsigned int i;
dec_params = run->decode_params;
dst = vb2_to_rkvdec_decoded_buf(&run->base.bufs.dst->vb2_buf);
ref_bufs[0] = get_ref_buf(ctx, &dst->base.vb, dec_params->last_frame_ts);
ref_bufs[1] = get_ref_buf(ctx, &dst->base.vb, dec_params->golden_frame_ts);
ref_bufs[2] = get_ref_buf(ctx, &dst->base.vb, dec_params->alt_frame_ts);
if (vp9_ctx->last.valid)
last = get_ref_buf(ctx, &dst->base.vb, vp9_ctx->last.timestamp);
else
last = dst;
update_dec_buf_info(dst, dec_params);
update_ctx_cur_info(vp9_ctx, dst, dec_params);
seg = &dec_params->seg;
intra_only = !!(dec_params->flags &
(V4L2_VP9_FRAME_FLAG_KEY_FRAME |
V4L2_VP9_FRAME_FLAG_INTRA_ONLY));
writel_relaxed(RKVDEC_MODE(RKVDEC_MODE_VP9),
rkvdec->regs + RKVDEC_REG_SYSCTRL);
bit_depth = dec_params->bit_depth;
aligned_height = round_up(ctx->decoded_fmt.fmt.pix_mp.height, 64);
aligned_pitch = round_up(ctx->decoded_fmt.fmt.pix_mp.width *
bit_depth,
512) / 8;
y_len = aligned_height * aligned_pitch;
uv_len = y_len / 2;
yuv_len = y_len + uv_len;
writel_relaxed(RKVDEC_Y_HOR_VIRSTRIDE(aligned_pitch / 16) |
RKVDEC_UV_HOR_VIRSTRIDE(aligned_pitch / 16),
rkvdec->regs + RKVDEC_REG_PICPAR);
writel_relaxed(RKVDEC_Y_VIRSTRIDE(y_len / 16),
rkvdec->regs + RKVDEC_REG_Y_VIRSTRIDE);
writel_relaxed(RKVDEC_YUV_VIRSTRIDE(yuv_len / 16),
rkvdec->regs + RKVDEC_REG_YUV_VIRSTRIDE);
stream_len = vb2_get_plane_payload(&run->base.bufs.src->vb2_buf, 0);
writel_relaxed(RKVDEC_STRM_LEN(stream_len),
rkvdec->regs + RKVDEC_REG_STRM_LEN);
/*
* Reset count buffer, because decoder only output intra related syntax
* counts when decoding intra frame, but update entropy need to update
* all the probabilities.
*/
if (intra_only)
memset(vp9_ctx->count_tbl.cpu, 0, vp9_ctx->count_tbl.size);
vp9_ctx->cur.segmapid = vp9_ctx->last.segmapid;
if (!intra_only &&
!(dec_params->flags & V4L2_VP9_FRAME_FLAG_ERROR_RESILIENT) &&
(!(seg->flags & V4L2_VP9_SEGMENTATION_FLAG_ENABLED) ||
(seg->flags & V4L2_VP9_SEGMENTATION_FLAG_UPDATE_MAP)))
vp9_ctx->cur.segmapid++;
for (i = 0; i < ARRAY_SIZE(ref_bufs); i++)
config_ref_registers(ctx, run, ref_bufs[i], &ref_regs[i]);
for (i = 0; i < 8; i++)
config_seg_registers(ctx, i);
writel_relaxed(RKVDEC_VP9_TX_MODE(vp9_ctx->cur.tx_mode) |
RKVDEC_VP9_FRAME_REF_MODE(dec_params->reference_mode),
rkvdec->regs + RKVDEC_VP9_CPRHEADER_CONFIG);
if (!intra_only) {
const struct v4l2_vp9_loop_filter *lf;
s8 delta;
if (vp9_ctx->last.valid)
lf = &vp9_ctx->last.lf;
else
lf = &vp9_ctx->cur.lf;
val = 0;
for (i = 0; i < ARRAY_SIZE(lf->ref_deltas); i++) {
delta = lf->ref_deltas[i];
val |= RKVDEC_REF_DELTAS_LASTFRAME(i, delta);
}
writel_relaxed(val,
rkvdec->regs + RKVDEC_VP9_REF_DELTAS_LASTFRAME);
for (i = 0; i < ARRAY_SIZE(lf->mode_deltas); i++) {
delta = lf->mode_deltas[i];
last_frame_info |= RKVDEC_MODE_DELTAS_LASTFRAME(i,
delta);
}
}
if (vp9_ctx->last.valid && !intra_only &&
vp9_ctx->last.seg.flags & V4L2_VP9_SEGMENTATION_FLAG_ENABLED)
last_frame_info |= RKVDEC_SEG_EN_LASTFRAME;
if (vp9_ctx->last.valid &&
vp9_ctx->last.flags & V4L2_VP9_FRAME_FLAG_SHOW_FRAME)
last_frame_info |= RKVDEC_LAST_SHOW_FRAME;
if (vp9_ctx->last.valid &&
vp9_ctx->last.flags &
(V4L2_VP9_FRAME_FLAG_KEY_FRAME | V4L2_VP9_FRAME_FLAG_INTRA_ONLY))
last_frame_info |= RKVDEC_LAST_INTRA_ONLY;
if (vp9_ctx->last.valid &&
last->vp9.width == dst->vp9.width &&
last->vp9.height == dst->vp9.height)
last_frame_info |= RKVDEC_LAST_WIDHHEIGHT_EQCUR;
writel_relaxed(last_frame_info,
rkvdec->regs + RKVDEC_VP9_INFO_LASTFRAME);
writel_relaxed(stream_len - dec_params->compressed_header_size -
dec_params->uncompressed_header_size,
rkvdec->regs + RKVDEC_VP9_LASTTILE_SIZE);
for (i = 0; !intra_only && i < ARRAY_SIZE(ref_bufs); i++) {
unsigned int refw = ref_bufs[i]->vp9.width;
unsigned int refh = ref_bufs[i]->vp9.height;
u32 hscale, vscale;
hscale = (refw << 14) / dst->vp9.width;
vscale = (refh << 14) / dst->vp9.height;
writel_relaxed(RKVDEC_VP9_REF_HOR_SCALE(hscale) |
RKVDEC_VP9_REF_VER_SCALE(vscale),
rkvdec->regs + RKVDEC_VP9_REF_SCALE(i));
}
addr = vb2_dma_contig_plane_dma_addr(&dst->base.vb.vb2_buf, 0);
writel_relaxed(addr, rkvdec->regs + RKVDEC_REG_DECOUT_BASE);
addr = vb2_dma_contig_plane_dma_addr(&run->base.bufs.src->vb2_buf, 0);
writel_relaxed(addr, rkvdec->regs + RKVDEC_REG_STRM_RLC_BASE);
writel_relaxed(vp9_ctx->priv_tbl.dma +
offsetof(struct rkvdec_vp9_priv_tbl, probs),
rkvdec->regs + RKVDEC_REG_CABACTBL_PROB_BASE);
writel_relaxed(vp9_ctx->count_tbl.dma,
rkvdec->regs + RKVDEC_REG_VP9COUNT_BASE);
writel_relaxed(vp9_ctx->priv_tbl.dma +
offsetof(struct rkvdec_vp9_priv_tbl, segmap) +
(RKVDEC_VP9_MAX_SEGMAP_SIZE * vp9_ctx->cur.segmapid),
rkvdec->regs + RKVDEC_REG_VP9_SEGIDCUR_BASE);
writel_relaxed(vp9_ctx->priv_tbl.dma +
offsetof(struct rkvdec_vp9_priv_tbl, segmap) +
(RKVDEC_VP9_MAX_SEGMAP_SIZE * (!vp9_ctx->cur.segmapid)),
rkvdec->regs + RKVDEC_REG_VP9_SEGIDLAST_BASE);
if (!intra_only &&
!(dec_params->flags & V4L2_VP9_FRAME_FLAG_ERROR_RESILIENT) &&
vp9_ctx->last.valid)
mv_ref = last;
else
mv_ref = dst;
writel_relaxed(get_mv_base_addr(mv_ref),
rkvdec->regs + RKVDEC_VP9_REF_COLMV_BASE);
writel_relaxed(ctx->decoded_fmt.fmt.pix_mp.width |
(ctx->decoded_fmt.fmt.pix_mp.height << 16),
rkvdec->regs + RKVDEC_REG_PERFORMANCE_CYCLE);
}
static int validate_dec_params(struct rkvdec_ctx *ctx,
const struct v4l2_ctrl_vp9_frame *dec_params)
{
unsigned int aligned_width, aligned_height;
/* We only support profile 0. */
if (dec_params->profile != 0) {
dev_err(ctx->dev->dev, "unsupported profile %d\n",
dec_params->profile);
return -EINVAL;
}
aligned_width = round_up(dec_params->frame_width_minus_1 + 1, 64);
aligned_height = round_up(dec_params->frame_height_minus_1 + 1, 64);
/*
* Userspace should update the capture/decoded format when the
* resolution changes.
*/
if (aligned_width != ctx->decoded_fmt.fmt.pix_mp.width ||
aligned_height != ctx->decoded_fmt.fmt.pix_mp.height) {
dev_err(ctx->dev->dev,
"unexpected bitstream resolution %dx%d\n",
dec_params->frame_width_minus_1 + 1,
dec_params->frame_height_minus_1 + 1);
return -EINVAL;
}
return 0;
}
static int rkvdec_vp9_run_preamble(struct rkvdec_ctx *ctx,
struct rkvdec_vp9_run *run)
{
const struct v4l2_ctrl_vp9_frame *dec_params;
const struct v4l2_ctrl_vp9_compressed_hdr *prob_updates;
struct rkvdec_vp9_ctx *vp9_ctx = ctx->priv;
struct v4l2_ctrl *ctrl;
unsigned int fctx_idx;
int ret;
/* v4l2-specific stuff */
rkvdec_run_preamble(ctx, &run->base);
ctrl = v4l2_ctrl_find(&ctx->ctrl_hdl,
V4L2_CID_STATELESS_VP9_FRAME);
if (WARN_ON(!ctrl))
return -EINVAL;
dec_params = ctrl->p_cur.p;
ret = validate_dec_params(ctx, dec_params);
if (ret)
return ret;
run->decode_params = dec_params;
ctrl = v4l2_ctrl_find(&ctx->ctrl_hdl, V4L2_CID_STATELESS_VP9_COMPRESSED_HDR);
if (WARN_ON(!ctrl))
return -EINVAL;
prob_updates = ctrl->p_cur.p;
vp9_ctx->cur.tx_mode = prob_updates->tx_mode;
/*
* vp9 stuff
*
* by this point the userspace has done all parts of 6.2 uncompressed_header()
* except this fragment:
* if ( FrameIsIntra || error_resilient_mode ) {
* setup_past_independence ( )
* if ( frame_type == KEY_FRAME || error_resilient_mode == 1 ||
* reset_frame_context == 3 ) {
* for ( i = 0; i < 4; i ++ ) {
* save_probs( i )
* }
* } else if ( reset_frame_context == 2 ) {
* save_probs( frame_context_idx )
* }
* frame_context_idx = 0
* }
*/
fctx_idx = v4l2_vp9_reset_frame_ctx(dec_params, vp9_ctx->frame_context);
vp9_ctx->cur.frame_context_idx = fctx_idx;
/* 6.1 frame(sz): load_probs() and load_probs2() */
vp9_ctx->probability_tables = vp9_ctx->frame_context[fctx_idx];
/*
* The userspace has also performed 6.3 compressed_header(), but handling the
* probs in a special way. All probs which need updating, except MV-related,
* have been read from the bitstream and translated through inv_map_table[],
* but no 6.3.6 inv_recenter_nonneg(v, m) has been performed. The values passed
* by userspace are either translated values (there are no 0 values in
* inv_map_table[]), or zero to indicate no update. All MV-related probs which need
* updating have been read from the bitstream and (mv_prob << 1) | 1 has been
* performed. The values passed by userspace are either new values
* to replace old ones (the above mentioned shift and bitwise or never result in
* a zero) or zero to indicate no update.
* fw_update_probs() performs actual probs updates or leaves probs as-is
* for values for which a zero was passed from userspace.
*/
v4l2_vp9_fw_update_probs(&vp9_ctx->probability_tables, prob_updates, dec_params);
return 0;
}
static int rkvdec_vp9_run(struct rkvdec_ctx *ctx)
{
struct rkvdec_dev *rkvdec = ctx->dev;
struct rkvdec_vp9_run run = { };
int ret;
ret = rkvdec_vp9_run_preamble(ctx, &run);
if (ret) {
rkvdec_run_postamble(ctx, &run.base);
return ret;
}
/* Prepare probs. */
init_probs(ctx, &run);
/* Configure hardware registers. */
config_registers(ctx, &run);
rkvdec_run_postamble(ctx, &run.base);
schedule_delayed_work(&rkvdec->watchdog_work, msecs_to_jiffies(2000));
writel(1, rkvdec->regs + RKVDEC_REG_PREF_LUMA_CACHE_COMMAND);
writel(1, rkvdec->regs + RKVDEC_REG_PREF_CHR_CACHE_COMMAND);
writel(0xe, rkvdec->regs + RKVDEC_REG_STRMD_ERR_EN);
/* Start decoding! */
writel(RKVDEC_INTERRUPT_DEC_E | RKVDEC_CONFIG_DEC_CLK_GATE_E |
RKVDEC_TIMEOUT_E | RKVDEC_BUF_EMPTY_E,
rkvdec->regs + RKVDEC_REG_INTERRUPT);
return 0;
}
#define copy_tx_and_skip(p1, p2) \
do { \
memcpy((p1)->tx8, (p2)->tx8, sizeof((p1)->tx8)); \
memcpy((p1)->tx16, (p2)->tx16, sizeof((p1)->tx16)); \
memcpy((p1)->tx32, (p2)->tx32, sizeof((p1)->tx32)); \
memcpy((p1)->skip, (p2)->skip, sizeof((p1)->skip)); \
} while (0)
static void rkvdec_vp9_done(struct rkvdec_ctx *ctx,
struct vb2_v4l2_buffer *src_buf,
struct vb2_v4l2_buffer *dst_buf,
enum vb2_buffer_state result)
{
struct rkvdec_vp9_ctx *vp9_ctx = ctx->priv;
unsigned int fctx_idx;
/* v4l2-specific stuff */
if (result == VB2_BUF_STATE_ERROR)
goto out_update_last;
/*
* vp9 stuff
*
* 6.1.2 refresh_probs()
*
* In the spec a complementary condition goes last in 6.1.2 refresh_probs(),
* but it makes no sense to perform all the activities from the first "if"
* there if we actually are not refreshing the frame context. On top of that,
* because of 6.2 uncompressed_header() whenever error_resilient_mode == 1,
* refresh_frame_context == 0. Consequently, if we don't jump to out_update_last
* it means error_resilient_mode must be 0.
*/
if (!(vp9_ctx->cur.flags & V4L2_VP9_FRAME_FLAG_REFRESH_FRAME_CTX))
goto out_update_last;
fctx_idx = vp9_ctx->cur.frame_context_idx;
if (!(vp9_ctx->cur.flags & V4L2_VP9_FRAME_FLAG_PARALLEL_DEC_MODE)) {
/* error_resilient_mode == 0 && frame_parallel_decoding_mode == 0 */
struct v4l2_vp9_frame_context *probs = &vp9_ctx->probability_tables;
bool frame_is_intra = vp9_ctx->cur.flags &
(V4L2_VP9_FRAME_FLAG_KEY_FRAME | V4L2_VP9_FRAME_FLAG_INTRA_ONLY);
struct tx_and_skip {
u8 tx8[2][1];
u8 tx16[2][2];
u8 tx32[2][3];
u8 skip[3];
} _tx_skip, *tx_skip = &_tx_skip;
struct v4l2_vp9_frame_symbol_counts *counts;
/* buffer the forward-updated TX and skip probs */
if (frame_is_intra)
copy_tx_and_skip(tx_skip, probs);
/* 6.1.2 refresh_probs(): load_probs() and load_probs2() */
*probs = vp9_ctx->frame_context[fctx_idx];
/* if FrameIsIntra then undo the effect of load_probs2() */
if (frame_is_intra)
copy_tx_and_skip(probs, tx_skip);
counts = frame_is_intra ? &vp9_ctx->intra_cnts : &vp9_ctx->inter_cnts;
v4l2_vp9_adapt_coef_probs(probs, counts,
!vp9_ctx->last.valid ||
vp9_ctx->last.flags & V4L2_VP9_FRAME_FLAG_KEY_FRAME,
frame_is_intra);
if (!frame_is_intra) {
const struct rkvdec_vp9_inter_frame_symbol_counts *inter_cnts;
u32 classes[2][11];
int i;
inter_cnts = vp9_ctx->count_tbl.cpu;
for (i = 0; i < ARRAY_SIZE(classes); ++i)
memcpy(classes[i], inter_cnts->classes[i], sizeof(classes[0]));
counts->classes = &classes;
/* load_probs2() already done */
v4l2_vp9_adapt_noncoef_probs(&vp9_ctx->probability_tables, counts,
vp9_ctx->cur.reference_mode,
vp9_ctx->cur.interpolation_filter,
vp9_ctx->cur.tx_mode, vp9_ctx->cur.flags);
}
}
/* 6.1.2 refresh_probs(): save_probs(fctx_idx) */
vp9_ctx->frame_context[fctx_idx] = vp9_ctx->probability_tables;
out_update_last:
update_ctx_last_info(vp9_ctx);
}
static void rkvdec_init_v4l2_vp9_count_tbl(struct rkvdec_ctx *ctx)
{
struct rkvdec_vp9_ctx *vp9_ctx = ctx->priv;
struct rkvdec_vp9_intra_frame_symbol_counts *intra_cnts = vp9_ctx->count_tbl.cpu;
struct rkvdec_vp9_inter_frame_symbol_counts *inter_cnts = vp9_ctx->count_tbl.cpu;
int i, j, k, l, m;
vp9_ctx->inter_cnts.partition = &inter_cnts->partition;
vp9_ctx->inter_cnts.skip = &inter_cnts->skip;
vp9_ctx->inter_cnts.intra_inter = &inter_cnts->inter;
vp9_ctx->inter_cnts.tx32p = &inter_cnts->tx32p;
vp9_ctx->inter_cnts.tx16p = &inter_cnts->tx16p;
vp9_ctx->inter_cnts.tx8p = &inter_cnts->tx8p;
vp9_ctx->intra_cnts.partition = (u32 (*)[16][4])(&intra_cnts->partition);
vp9_ctx->intra_cnts.skip = &intra_cnts->skip;
vp9_ctx->intra_cnts.intra_inter = &intra_cnts->intra;
vp9_ctx->intra_cnts.tx32p = &intra_cnts->tx32p;
vp9_ctx->intra_cnts.tx16p = &intra_cnts->tx16p;
vp9_ctx->intra_cnts.tx8p = &intra_cnts->tx8p;
vp9_ctx->inter_cnts.y_mode = &inter_cnts->y_mode;
vp9_ctx->inter_cnts.uv_mode = &inter_cnts->uv_mode;
vp9_ctx->inter_cnts.comp = &inter_cnts->comp;
vp9_ctx->inter_cnts.comp_ref = &inter_cnts->comp_ref;
vp9_ctx->inter_cnts.single_ref = &inter_cnts->single_ref;
vp9_ctx->inter_cnts.mv_mode = &inter_cnts->mv_mode;
vp9_ctx->inter_cnts.filter = &inter_cnts->filter;
vp9_ctx->inter_cnts.mv_joint = &inter_cnts->mv_joint;
vp9_ctx->inter_cnts.sign = &inter_cnts->sign;
/*
* rk hardware actually uses "u32 classes[2][11 + 1];"
* instead of "u32 classes[2][11];", so this must be explicitly
* copied into vp9_ctx->classes when passing the data to the
* vp9 library function
*/
vp9_ctx->inter_cnts.class0 = &inter_cnts->class0;
vp9_ctx->inter_cnts.bits = &inter_cnts->bits;
vp9_ctx->inter_cnts.class0_fp = &inter_cnts->class0_fp;
vp9_ctx->inter_cnts.fp = &inter_cnts->fp;
vp9_ctx->inter_cnts.class0_hp = &inter_cnts->class0_hp;
vp9_ctx->inter_cnts.hp = &inter_cnts->hp;
#define INNERMOST_LOOP \
do { \
for (m = 0; m < ARRAY_SIZE(vp9_ctx->inter_cnts.coeff[0][0][0][0]); ++m) {\
vp9_ctx->inter_cnts.coeff[i][j][k][l][m] = \
&inter_cnts->ref_cnt[k][i][j][l][m].coeff; \
vp9_ctx->inter_cnts.eob[i][j][k][l][m][0] = \
&inter_cnts->ref_cnt[k][i][j][l][m].eob[0]; \
vp9_ctx->inter_cnts.eob[i][j][k][l][m][1] = \
&inter_cnts->ref_cnt[k][i][j][l][m].eob[1]; \
\
vp9_ctx->intra_cnts.coeff[i][j][k][l][m] = \
&intra_cnts->ref_cnt[k][i][j][l][m].coeff; \
vp9_ctx->intra_cnts.eob[i][j][k][l][m][0] = \
&intra_cnts->ref_cnt[k][i][j][l][m].eob[0]; \
vp9_ctx->intra_cnts.eob[i][j][k][l][m][1] = \
&intra_cnts->ref_cnt[k][i][j][l][m].eob[1]; \
} \
} while (0)
for (i = 0; i < ARRAY_SIZE(vp9_ctx->inter_cnts.coeff); ++i)
for (j = 0; j < ARRAY_SIZE(vp9_ctx->inter_cnts.coeff[0]); ++j)
for (k = 0; k < ARRAY_SIZE(vp9_ctx->inter_cnts.coeff[0][0]); ++k)
for (l = 0; l < ARRAY_SIZE(vp9_ctx->inter_cnts.coeff[0][0][0]); ++l)
INNERMOST_LOOP;
#undef INNERMOST_LOOP
}
static int rkvdec_vp9_start(struct rkvdec_ctx *ctx)
{
struct rkvdec_dev *rkvdec = ctx->dev;
struct rkvdec_vp9_priv_tbl *priv_tbl;
struct rkvdec_vp9_ctx *vp9_ctx;
unsigned char *count_tbl;
int ret;
vp9_ctx = kzalloc(sizeof(*vp9_ctx), GFP_KERNEL);
if (!vp9_ctx)
return -ENOMEM;
ctx->priv = vp9_ctx;
priv_tbl = dma_alloc_coherent(rkvdec->dev, sizeof(*priv_tbl),
&vp9_ctx->priv_tbl.dma, GFP_KERNEL);
if (!priv_tbl) {
ret = -ENOMEM;
goto err_free_ctx;
}
vp9_ctx->priv_tbl.size = sizeof(*priv_tbl);
vp9_ctx->priv_tbl.cpu = priv_tbl;
memset(priv_tbl, 0, sizeof(*priv_tbl));
count_tbl = dma_alloc_coherent(rkvdec->dev, RKVDEC_VP9_COUNT_SIZE,
&vp9_ctx->count_tbl.dma, GFP_KERNEL);
if (!count_tbl) {
ret = -ENOMEM;
goto err_free_priv_tbl;
}
vp9_ctx->count_tbl.size = RKVDEC_VP9_COUNT_SIZE;
vp9_ctx->count_tbl.cpu = count_tbl;
memset(count_tbl, 0, sizeof(*count_tbl));
rkvdec_init_v4l2_vp9_count_tbl(ctx);
return 0;
err_free_priv_tbl:
dma_free_coherent(rkvdec->dev, vp9_ctx->priv_tbl.size,
vp9_ctx->priv_tbl.cpu, vp9_ctx->priv_tbl.dma);
err_free_ctx:
kfree(vp9_ctx);
return ret;
}
static void rkvdec_vp9_stop(struct rkvdec_ctx *ctx)
{
struct rkvdec_vp9_ctx *vp9_ctx = ctx->priv;
struct rkvdec_dev *rkvdec = ctx->dev;
dma_free_coherent(rkvdec->dev, vp9_ctx->count_tbl.size,
vp9_ctx->count_tbl.cpu, vp9_ctx->count_tbl.dma);
dma_free_coherent(rkvdec->dev, vp9_ctx->priv_tbl.size,
vp9_ctx->priv_tbl.cpu, vp9_ctx->priv_tbl.dma);
kfree(vp9_ctx);
}
static int rkvdec_vp9_adjust_fmt(struct rkvdec_ctx *ctx,
struct v4l2_format *f)
{
struct v4l2_pix_format_mplane *fmt = &f->fmt.pix_mp;
fmt->num_planes = 1;
if (!fmt->plane_fmt[0].sizeimage)
fmt->plane_fmt[0].sizeimage = fmt->width * fmt->height * 2;
return 0;
}
const struct rkvdec_coded_fmt_ops rkvdec_vp9_fmt_ops = {
.adjust_fmt = rkvdec_vp9_adjust_fmt,
.start = rkvdec_vp9_start,
.stop = rkvdec_vp9_stop,
.run = rkvdec_vp9_run,
.done = rkvdec_vp9_done,
};
...@@ -99,10 +99,30 @@ static const struct rkvdec_ctrls rkvdec_h264_ctrls = { ...@@ -99,10 +99,30 @@ static const struct rkvdec_ctrls rkvdec_h264_ctrls = {
.num_ctrls = ARRAY_SIZE(rkvdec_h264_ctrl_descs), .num_ctrls = ARRAY_SIZE(rkvdec_h264_ctrl_descs),
}; };
static const u32 rkvdec_h264_decoded_fmts[] = { static const u32 rkvdec_h264_vp9_decoded_fmts[] = {
V4L2_PIX_FMT_NV12, V4L2_PIX_FMT_NV12,
}; };
static const struct rkvdec_ctrl_desc rkvdec_vp9_ctrl_descs[] = {
{
.cfg.id = V4L2_CID_STATELESS_VP9_FRAME,
},
{
.cfg.id = V4L2_CID_STATELESS_VP9_COMPRESSED_HDR,
},
{
.cfg.id = V4L2_CID_MPEG_VIDEO_VP9_PROFILE,
.cfg.min = V4L2_MPEG_VIDEO_VP9_PROFILE_0,
.cfg.max = V4L2_MPEG_VIDEO_VP9_PROFILE_0,
.cfg.def = V4L2_MPEG_VIDEO_VP9_PROFILE_0,
},
};
static const struct rkvdec_ctrls rkvdec_vp9_ctrls = {
.ctrls = rkvdec_vp9_ctrl_descs,
.num_ctrls = ARRAY_SIZE(rkvdec_vp9_ctrl_descs),
};
static const struct rkvdec_coded_fmt_desc rkvdec_coded_fmts[] = { static const struct rkvdec_coded_fmt_desc rkvdec_coded_fmts[] = {
{ {
.fourcc = V4L2_PIX_FMT_H264_SLICE, .fourcc = V4L2_PIX_FMT_H264_SLICE,
...@@ -116,8 +136,23 @@ static const struct rkvdec_coded_fmt_desc rkvdec_coded_fmts[] = { ...@@ -116,8 +136,23 @@ static const struct rkvdec_coded_fmt_desc rkvdec_coded_fmts[] = {
}, },
.ctrls = &rkvdec_h264_ctrls, .ctrls = &rkvdec_h264_ctrls,
.ops = &rkvdec_h264_fmt_ops, .ops = &rkvdec_h264_fmt_ops,
.num_decoded_fmts = ARRAY_SIZE(rkvdec_h264_decoded_fmts), .num_decoded_fmts = ARRAY_SIZE(rkvdec_h264_vp9_decoded_fmts),
.decoded_fmts = rkvdec_h264_decoded_fmts, .decoded_fmts = rkvdec_h264_vp9_decoded_fmts,
},
{
.fourcc = V4L2_PIX_FMT_VP9_FRAME,
.frmsize = {
.min_width = 64,
.max_width = 4096,
.step_width = 64,
.min_height = 64,
.max_height = 2304,
.step_height = 64,
},
.ctrls = &rkvdec_vp9_ctrls,
.ops = &rkvdec_vp9_fmt_ops,
.num_decoded_fmts = ARRAY_SIZE(rkvdec_h264_vp9_decoded_fmts),
.decoded_fmts = rkvdec_h264_vp9_decoded_fmts,
} }
}; };
......
...@@ -42,14 +42,18 @@ struct rkvdec_run { ...@@ -42,14 +42,18 @@ struct rkvdec_run {
struct rkvdec_vp9_decoded_buffer_info { struct rkvdec_vp9_decoded_buffer_info {
/* Info needed when the decoded frame serves as a reference frame. */ /* Info needed when the decoded frame serves as a reference frame. */
u16 width; unsigned short width;
u16 height; unsigned short height;
u32 bit_depth : 4; unsigned int bit_depth : 4;
}; };
struct rkvdec_decoded_buffer { struct rkvdec_decoded_buffer {
/* Must be the first field in this struct. */ /* Must be the first field in this struct. */
struct v4l2_m2m_buffer base; struct v4l2_m2m_buffer base;
union {
struct rkvdec_vp9_decoded_buffer_info vp9;
};
}; };
static inline struct rkvdec_decoded_buffer * static inline struct rkvdec_decoded_buffer *
...@@ -116,4 +120,6 @@ void rkvdec_run_preamble(struct rkvdec_ctx *ctx, struct rkvdec_run *run); ...@@ -116,4 +120,6 @@ void rkvdec_run_preamble(struct rkvdec_ctx *ctx, struct rkvdec_run *run);
void rkvdec_run_postamble(struct rkvdec_ctx *ctx, struct rkvdec_run *run); void rkvdec_run_postamble(struct rkvdec_ctx *ctx, struct rkvdec_run *run);
extern const struct rkvdec_coded_fmt_ops rkvdec_h264_fmt_ops; extern const struct rkvdec_coded_fmt_ops rkvdec_h264_fmt_ops;
extern const struct rkvdec_coded_fmt_ops rkvdec_vp9_fmt_ops;
#endif /* RKVDEC_H_ */ #endif /* RKVDEC_H_ */
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