Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Jeffy Chen | 2940 | 93.01% | 1 | 5.26% |
Ezequiel García | 147 | 4.65% | 11 | 57.89% |
Jonas Karlman | 32 | 1.01% | 2 | 10.53% |
ZhiChao Yu | 18 | 0.57% | 1 | 5.26% |
Philipp Zabel | 14 | 0.44% | 1 | 5.26% |
Benjamin Gaignard | 8 | 0.25% | 1 | 5.26% |
Alex Bee | 1 | 0.03% | 1 | 5.26% |
Mauro Carvalho Chehab | 1 | 0.03% | 1 | 5.26% |
Total | 3161 | 19 |
// SPDX-License-Identifier: GPL-2.0 /* * Rockchip VPU codec vp8 decode driver * * Copyright (C) 2014 Rockchip Electronics Co., Ltd. * ZhiChao Yu <zhichao.yu@rock-chips.com> * * Copyright (C) 2014 Google LLC. * Tomasz Figa <tfiga@chromium.org> * * Copyright (C) 2015 Rockchip Electronics Co., Ltd. * Alpha Lin <alpha.lin@rock-chips.com> */ #include <media/v4l2-mem2mem.h> #include "hantro_hw.h" #include "hantro.h" #include "hantro_g1_regs.h" #define VDPU_REG_DEC_CTRL0 0x0c8 #define VDPU_REG_STREAM_LEN 0x0cc #define VDPU_REG_DEC_FORMAT 0x0d4 #define VDPU_REG_DEC_CTRL0_DEC_MODE(x) (((x) & 0xf) << 0) #define VDPU_REG_DATA_ENDIAN 0x0d8 #define VDPU_REG_CONFIG_DEC_STRENDIAN_E BIT(5) #define VDPU_REG_CONFIG_DEC_STRSWAP32_E BIT(4) #define VDPU_REG_CONFIG_DEC_OUTSWAP32_E BIT(3) #define VDPU_REG_CONFIG_DEC_INSWAP32_E BIT(2) #define VDPU_REG_CONFIG_DEC_OUT_ENDIAN BIT(1) #define VDPU_REG_CONFIG_DEC_IN_ENDIAN BIT(0) #define VDPU_REG_AXI_CTRL 0x0e0 #define VDPU_REG_CONFIG_DEC_MAX_BURST(x) (((x) & 0x1f) << 16) #define VDPU_REG_EN_FLAGS 0x0e4 #define VDPU_REG_DEC_CTRL0_PIC_INTER_E BIT(14) #define VDPU_REG_CONFIG_DEC_TIMEOUT_E BIT(5) #define VDPU_REG_CONFIG_DEC_CLK_GATE_E BIT(4) #define VDPU_REG_PRED_FLT 0x0ec #define VDPU_REG_ADDR_QTABLE 0x0f4 #define VDPU_REG_ADDR_DST 0x0fc #define VDPU_REG_ADDR_STR 0x100 #define VDPU_REG_VP8_PIC_MB_SIZE 0x1e0 #define VDPU_REG_VP8_DCT_START_BIT 0x1e4 #define VDPU_REG_DEC_CTRL4_VC1_HEIGHT_EXT BIT(13) #define VDPU_REG_DEC_CTRL4_BILIN_MC_E BIT(12) #define VDPU_REG_VP8_CTRL0 0x1e8 #define VDPU_REG_VP8_DATA_VAL 0x1f0 #define VDPU_REG_PRED_FLT7 0x1f4 #define VDPU_REG_PRED_FLT8 0x1f8 #define VDPU_REG_PRED_FLT9 0x1fc #define VDPU_REG_PRED_FLT10 0x200 #define VDPU_REG_FILTER_LEVEL 0x204 #define VDPU_REG_VP8_QUANTER0 0x208 #define VDPU_REG_VP8_ADDR_REF0 0x20c #define VDPU_REG_FILTER_MB_ADJ 0x210 #define VDPU_REG_REF_PIC_FILT_TYPE_E BIT(31) #define VDPU_REG_REF_PIC_FILT_SHARPNESS(x) (((x) & 0x7) << 28) #define VDPU_REG_FILTER_REF_ADJ 0x214 #define VDPU_REG_VP8_ADDR_REF2_5(i) (0x218 + ((i) * 0x4)) #define VDPU_REG_VP8_GREF_SIGN_BIAS BIT(0) #define VDPU_REG_VP8_AREF_SIGN_BIAS BIT(0) #define VDPU_REG_VP8_DCT_BASE(i) \ (0x230 + ((((i) < 5) ? (i) : ((i) + 1)) * 0x4)) #define VDPU_REG_VP8_ADDR_CTRL_PART 0x244 #define VDPU_REG_VP8_SEGMENT_VAL 0x254 #define VDPU_REG_FWD_PIC1_SEGMENT_BASE(x) ((x) << 0) #define VDPU_REG_FWD_PIC1_SEGMENT_UPD_E BIT(1) #define VDPU_REG_FWD_PIC1_SEGMENT_E BIT(0) #define VDPU_REG_VP8_DCT_START_BIT2 0x258 #define VDPU_REG_VP8_QUANTER1 0x25c #define VDPU_REG_VP8_QUANTER2 0x260 #define VDPU_REG_PRED_FLT1 0x264 #define VDPU_REG_PRED_FLT2 0x268 #define VDPU_REG_PRED_FLT3 0x26c #define VDPU_REG_PRED_FLT4 0x270 #define VDPU_REG_PRED_FLT5 0x274 #define VDPU_REG_PRED_FLT6 0x278 static const struct hantro_reg vp8_dec_dct_base[8] = { { VDPU_REG_ADDR_STR, 0, 0xffffffff }, { VDPU_REG_VP8_DCT_BASE(0), 0, 0xffffffff }, { VDPU_REG_VP8_DCT_BASE(1), 0, 0xffffffff }, { VDPU_REG_VP8_DCT_BASE(2), 0, 0xffffffff }, { VDPU_REG_VP8_DCT_BASE(3), 0, 0xffffffff }, { VDPU_REG_VP8_DCT_BASE(4), 0, 0xffffffff }, { VDPU_REG_VP8_DCT_BASE(5), 0, 0xffffffff }, { VDPU_REG_VP8_DCT_BASE(6), 0, 0xffffffff }, }; static const struct hantro_reg vp8_dec_lf_level[4] = { { VDPU_REG_FILTER_LEVEL, 18, 0x3f }, { VDPU_REG_FILTER_LEVEL, 12, 0x3f }, { VDPU_REG_FILTER_LEVEL, 6, 0x3f }, { VDPU_REG_FILTER_LEVEL, 0, 0x3f }, }; static const struct hantro_reg vp8_dec_mb_adj[4] = { { VDPU_REG_FILTER_MB_ADJ, 21, 0x7f }, { VDPU_REG_FILTER_MB_ADJ, 14, 0x7f }, { VDPU_REG_FILTER_MB_ADJ, 7, 0x7f }, { VDPU_REG_FILTER_MB_ADJ, 0, 0x7f }, }; static const struct hantro_reg vp8_dec_ref_adj[4] = { { VDPU_REG_FILTER_REF_ADJ, 21, 0x7f }, { VDPU_REG_FILTER_REF_ADJ, 14, 0x7f }, { VDPU_REG_FILTER_REF_ADJ, 7, 0x7f }, { VDPU_REG_FILTER_REF_ADJ, 0, 0x7f }, }; static const struct hantro_reg vp8_dec_quant[4] = { { VDPU_REG_VP8_QUANTER0, 11, 0x7ff }, { VDPU_REG_VP8_QUANTER0, 0, 0x7ff }, { VDPU_REG_VP8_QUANTER1, 11, 0x7ff }, { VDPU_REG_VP8_QUANTER1, 0, 0x7ff }, }; static const struct hantro_reg vp8_dec_quant_delta[5] = { { VDPU_REG_VP8_QUANTER0, 27, 0x1f }, { VDPU_REG_VP8_QUANTER0, 22, 0x1f }, { VDPU_REG_VP8_QUANTER1, 27, 0x1f }, { VDPU_REG_VP8_QUANTER1, 22, 0x1f }, { VDPU_REG_VP8_QUANTER2, 27, 0x1f }, }; static const struct hantro_reg vp8_dec_dct_start_bits[8] = { { VDPU_REG_VP8_CTRL0, 26, 0x3f }, { VDPU_REG_VP8_DCT_START_BIT, 26, 0x3f }, { VDPU_REG_VP8_DCT_START_BIT, 20, 0x3f }, { VDPU_REG_VP8_DCT_START_BIT2, 24, 0x3f }, { VDPU_REG_VP8_DCT_START_BIT2, 18, 0x3f }, { VDPU_REG_VP8_DCT_START_BIT2, 12, 0x3f }, { VDPU_REG_VP8_DCT_START_BIT2, 6, 0x3f }, { VDPU_REG_VP8_DCT_START_BIT2, 0, 0x3f }, }; static const struct hantro_reg vp8_dec_pred_bc_tap[8][6] = { { { 0, 0, 0}, { VDPU_REG_PRED_FLT, 22, 0x3ff }, { VDPU_REG_PRED_FLT, 12, 0x3ff }, { VDPU_REG_PRED_FLT, 2, 0x3ff }, { VDPU_REG_PRED_FLT1, 22, 0x3ff }, { 0, 0, 0}, }, { { 0, 0, 0}, { VDPU_REG_PRED_FLT1, 12, 0x3ff }, { VDPU_REG_PRED_FLT1, 2, 0x3ff }, { VDPU_REG_PRED_FLT2, 22, 0x3ff }, { VDPU_REG_PRED_FLT2, 12, 0x3ff }, { 0, 0, 0}, }, { { VDPU_REG_PRED_FLT10, 10, 0x3 }, { VDPU_REG_PRED_FLT2, 2, 0x3ff }, { VDPU_REG_PRED_FLT3, 22, 0x3ff }, { VDPU_REG_PRED_FLT3, 12, 0x3ff }, { VDPU_REG_PRED_FLT3, 2, 0x3ff }, { VDPU_REG_PRED_FLT10, 8, 0x3}, }, { { 0, 0, 0}, { VDPU_REG_PRED_FLT4, 22, 0x3ff }, { VDPU_REG_PRED_FLT4, 12, 0x3ff }, { VDPU_REG_PRED_FLT4, 2, 0x3ff }, { VDPU_REG_PRED_FLT5, 22, 0x3ff }, { 0, 0, 0}, }, { { VDPU_REG_PRED_FLT10, 6, 0x3 }, { VDPU_REG_PRED_FLT5, 12, 0x3ff }, { VDPU_REG_PRED_FLT5, 2, 0x3ff }, { VDPU_REG_PRED_FLT6, 22, 0x3ff }, { VDPU_REG_PRED_FLT6, 12, 0x3ff }, { VDPU_REG_PRED_FLT10, 4, 0x3 }, }, { { 0, 0, 0}, { VDPU_REG_PRED_FLT6, 2, 0x3ff }, { VDPU_REG_PRED_FLT7, 22, 0x3ff }, { VDPU_REG_PRED_FLT7, 12, 0x3ff }, { VDPU_REG_PRED_FLT7, 2, 0x3ff }, { 0, 0, 0}, }, { { VDPU_REG_PRED_FLT10, 2, 0x3 }, { VDPU_REG_PRED_FLT8, 22, 0x3ff }, { VDPU_REG_PRED_FLT8, 12, 0x3ff }, { VDPU_REG_PRED_FLT8, 2, 0x3ff }, { VDPU_REG_PRED_FLT9, 22, 0x3ff }, { VDPU_REG_PRED_FLT10, 0, 0x3 }, }, { { 0, 0, 0}, { VDPU_REG_PRED_FLT9, 12, 0x3ff }, { VDPU_REG_PRED_FLT9, 2, 0x3ff }, { VDPU_REG_PRED_FLT10, 22, 0x3ff }, { VDPU_REG_PRED_FLT10, 12, 0x3ff }, { 0, 0, 0}, }, }; static const struct hantro_reg vp8_dec_mb_start_bit = { .base = VDPU_REG_VP8_CTRL0, .shift = 18, .mask = 0x3f }; static const struct hantro_reg vp8_dec_mb_aligned_data_len = { .base = VDPU_REG_VP8_DATA_VAL, .shift = 0, .mask = 0x3fffff }; static const struct hantro_reg vp8_dec_num_dct_partitions = { .base = VDPU_REG_VP8_DATA_VAL, .shift = 24, .mask = 0xf }; static const struct hantro_reg vp8_dec_stream_len = { .base = VDPU_REG_STREAM_LEN, .shift = 0, .mask = 0xffffff }; static const struct hantro_reg vp8_dec_mb_width = { .base = VDPU_REG_VP8_PIC_MB_SIZE, .shift = 23, .mask = 0x1ff }; static const struct hantro_reg vp8_dec_mb_height = { .base = VDPU_REG_VP8_PIC_MB_SIZE, .shift = 11, .mask = 0xff }; static const struct hantro_reg vp8_dec_mb_width_ext = { .base = VDPU_REG_VP8_PIC_MB_SIZE, .shift = 3, .mask = 0x7 }; static const struct hantro_reg vp8_dec_mb_height_ext = { .base = VDPU_REG_VP8_PIC_MB_SIZE, .shift = 0, .mask = 0x7 }; static const struct hantro_reg vp8_dec_bool_range = { .base = VDPU_REG_VP8_CTRL0, .shift = 0, .mask = 0xff }; static const struct hantro_reg vp8_dec_bool_value = { .base = VDPU_REG_VP8_CTRL0, .shift = 8, .mask = 0xff }; static const struct hantro_reg vp8_dec_filter_disable = { .base = VDPU_REG_DEC_CTRL0, .shift = 8, .mask = 1 }; static const struct hantro_reg vp8_dec_skip_mode = { .base = VDPU_REG_DEC_CTRL0, .shift = 9, .mask = 1 }; static const struct hantro_reg vp8_dec_start_dec = { .base = VDPU_REG_EN_FLAGS, .shift = 0, .mask = 1 }; static void cfg_lf(struct hantro_ctx *ctx, const struct v4l2_ctrl_vp8_frame *hdr) { const struct v4l2_vp8_segment *seg = &hdr->segment; const struct v4l2_vp8_loop_filter *lf = &hdr->lf; struct hantro_dev *vpu = ctx->dev; unsigned int i; u32 reg; if (!(seg->flags & V4L2_VP8_SEGMENT_FLAG_ENABLED)) { hantro_reg_write(vpu, &vp8_dec_lf_level[0], lf->level); } else if (seg->flags & V4L2_VP8_SEGMENT_FLAG_DELTA_VALUE_MODE) { for (i = 0; i < 4; i++) { u32 lf_level = clamp(lf->level + seg->lf_update[i], 0, 63); hantro_reg_write(vpu, &vp8_dec_lf_level[i], lf_level); } } else { for (i = 0; i < 4; i++) hantro_reg_write(vpu, &vp8_dec_lf_level[i], seg->lf_update[i]); } reg = VDPU_REG_REF_PIC_FILT_SHARPNESS(lf->sharpness_level); if (lf->flags & V4L2_VP8_LF_FILTER_TYPE_SIMPLE) reg |= VDPU_REG_REF_PIC_FILT_TYPE_E; vdpu_write_relaxed(vpu, reg, VDPU_REG_FILTER_MB_ADJ); if (lf->flags & V4L2_VP8_LF_ADJ_ENABLE) { for (i = 0; i < 4; i++) { hantro_reg_write(vpu, &vp8_dec_mb_adj[i], lf->mb_mode_delta[i]); hantro_reg_write(vpu, &vp8_dec_ref_adj[i], lf->ref_frm_delta[i]); } } } static void cfg_qp(struct hantro_ctx *ctx, const struct v4l2_ctrl_vp8_frame *hdr) { const struct v4l2_vp8_quantization *q = &hdr->quant; const struct v4l2_vp8_segment *seg = &hdr->segment; struct hantro_dev *vpu = ctx->dev; unsigned int i; if (!(seg->flags & V4L2_VP8_SEGMENT_FLAG_ENABLED)) { hantro_reg_write(vpu, &vp8_dec_quant[0], q->y_ac_qi); } else if (seg->flags & V4L2_VP8_SEGMENT_FLAG_DELTA_VALUE_MODE) { for (i = 0; i < 4; i++) { u32 quant = clamp(q->y_ac_qi + seg->quant_update[i], 0, 127); hantro_reg_write(vpu, &vp8_dec_quant[i], quant); } } else { for (i = 0; i < 4; i++) hantro_reg_write(vpu, &vp8_dec_quant[i], seg->quant_update[i]); } hantro_reg_write(vpu, &vp8_dec_quant_delta[0], q->y_dc_delta); hantro_reg_write(vpu, &vp8_dec_quant_delta[1], q->y2_dc_delta); hantro_reg_write(vpu, &vp8_dec_quant_delta[2], q->y2_ac_delta); hantro_reg_write(vpu, &vp8_dec_quant_delta[3], q->uv_dc_delta); hantro_reg_write(vpu, &vp8_dec_quant_delta[4], q->uv_ac_delta); } static void cfg_parts(struct hantro_ctx *ctx, const struct v4l2_ctrl_vp8_frame *hdr) { struct hantro_dev *vpu = ctx->dev; struct vb2_v4l2_buffer *vb2_src; u32 first_part_offset = V4L2_VP8_FRAME_IS_KEY_FRAME(hdr) ? 10 : 3; u32 mb_size, mb_offset_bytes, mb_offset_bits, mb_start_bits; u32 dct_size_part_size, dct_part_offset; dma_addr_t src_dma; u32 dct_part_total_len = 0; u32 count = 0; unsigned int i; vb2_src = hantro_get_src_buf(ctx); src_dma = vb2_dma_contig_plane_dma_addr(&vb2_src->vb2_buf, 0); /* * Calculate control partition mb data info * @first_part_header_bits: bits offset of mb data from first * part start pos * @mb_offset_bits: bits offset of mb data from src_dma * base addr * @mb_offset_byte: bytes offset of mb data from src_dma * base addr * @mb_start_bits: bits offset of mb data from mb data * 64bits alignment addr */ mb_offset_bits = first_part_offset * 8 + hdr->first_part_header_bits + 8; mb_offset_bytes = mb_offset_bits / 8; mb_start_bits = mb_offset_bits - (mb_offset_bytes & (~DEC_8190_ALIGN_MASK)) * 8; mb_size = hdr->first_part_size - (mb_offset_bytes - first_part_offset) + (mb_offset_bytes & DEC_8190_ALIGN_MASK); /* Macroblock data aligned base addr */ vdpu_write_relaxed(vpu, (mb_offset_bytes & (~DEC_8190_ALIGN_MASK)) + src_dma, VDPU_REG_VP8_ADDR_CTRL_PART); hantro_reg_write(vpu, &vp8_dec_mb_start_bit, mb_start_bits); hantro_reg_write(vpu, &vp8_dec_mb_aligned_data_len, mb_size); /* * Calculate DCT partition info * @dct_size_part_size: Containing sizes of DCT part, every DCT part * has 3 bytes to store its size, except the last * DCT part * @dct_part_offset: bytes offset of DCT parts from src_dma base addr * @dct_part_total_len: total size of all DCT parts */ dct_size_part_size = (hdr->num_dct_parts - 1) * 3; dct_part_offset = first_part_offset + hdr->first_part_size; for (i = 0; i < hdr->num_dct_parts; i++) dct_part_total_len += hdr->dct_part_sizes[i]; dct_part_total_len += dct_size_part_size; dct_part_total_len += (dct_part_offset & DEC_8190_ALIGN_MASK); /* Number of DCT partitions */ hantro_reg_write(vpu, &vp8_dec_num_dct_partitions, hdr->num_dct_parts - 1); /* DCT partition length */ hantro_reg_write(vpu, &vp8_dec_stream_len, dct_part_total_len); /* DCT partitions base address */ for (i = 0; i < hdr->num_dct_parts; i++) { u32 byte_offset = dct_part_offset + dct_size_part_size + count; u32 base_addr = byte_offset + src_dma; hantro_reg_write(vpu, &vp8_dec_dct_base[i], base_addr & (~DEC_8190_ALIGN_MASK)); hantro_reg_write(vpu, &vp8_dec_dct_start_bits[i], (byte_offset & DEC_8190_ALIGN_MASK) * 8); count += hdr->dct_part_sizes[i]; } } /* * prediction filter taps * normal 6-tap filters */ static void cfg_tap(struct hantro_ctx *ctx, const struct v4l2_ctrl_vp8_frame *hdr) { struct hantro_dev *vpu = ctx->dev; int i, j; if ((hdr->version & 0x03) != 0) return; /* Tap filter not used. */ for (i = 0; i < 8; i++) { for (j = 0; j < 6; j++) { if (vp8_dec_pred_bc_tap[i][j].base != 0) hantro_reg_write(vpu, &vp8_dec_pred_bc_tap[i][j], hantro_vp8_dec_mc_filter[i][j]); } } } static void cfg_ref(struct hantro_ctx *ctx, const struct v4l2_ctrl_vp8_frame *hdr, struct vb2_v4l2_buffer *vb2_dst) { struct hantro_dev *vpu = ctx->dev; dma_addr_t ref; ref = hantro_get_ref(ctx, hdr->last_frame_ts); if (!ref) { vpu_debug(0, "failed to find last frame ts=%llu\n", hdr->last_frame_ts); ref = vb2_dma_contig_plane_dma_addr(&vb2_dst->vb2_buf, 0); } vdpu_write_relaxed(vpu, ref, VDPU_REG_VP8_ADDR_REF0); ref = hantro_get_ref(ctx, hdr->golden_frame_ts); if (!ref && hdr->golden_frame_ts) vpu_debug(0, "failed to find golden frame ts=%llu\n", hdr->golden_frame_ts); if (!ref) ref = vb2_dma_contig_plane_dma_addr(&vb2_dst->vb2_buf, 0); if (hdr->flags & V4L2_VP8_FRAME_FLAG_SIGN_BIAS_GOLDEN) ref |= VDPU_REG_VP8_GREF_SIGN_BIAS; vdpu_write_relaxed(vpu, ref, VDPU_REG_VP8_ADDR_REF2_5(2)); ref = hantro_get_ref(ctx, hdr->alt_frame_ts); if (!ref && hdr->alt_frame_ts) vpu_debug(0, "failed to find alt frame ts=%llu\n", hdr->alt_frame_ts); if (!ref) ref = vb2_dma_contig_plane_dma_addr(&vb2_dst->vb2_buf, 0); if (hdr->flags & V4L2_VP8_FRAME_FLAG_SIGN_BIAS_ALT) ref |= VDPU_REG_VP8_AREF_SIGN_BIAS; vdpu_write_relaxed(vpu, ref, VDPU_REG_VP8_ADDR_REF2_5(3)); } static void cfg_buffers(struct hantro_ctx *ctx, const struct v4l2_ctrl_vp8_frame *hdr, struct vb2_v4l2_buffer *vb2_dst) { const struct v4l2_vp8_segment *seg = &hdr->segment; struct hantro_dev *vpu = ctx->dev; dma_addr_t dst_dma; u32 reg; /* Set probability table buffer address */ vdpu_write_relaxed(vpu, ctx->vp8_dec.prob_tbl.dma, VDPU_REG_ADDR_QTABLE); /* Set segment map address */ reg = VDPU_REG_FWD_PIC1_SEGMENT_BASE(ctx->vp8_dec.segment_map.dma); if (seg->flags & V4L2_VP8_SEGMENT_FLAG_ENABLED) { reg |= VDPU_REG_FWD_PIC1_SEGMENT_E; if (seg->flags & V4L2_VP8_SEGMENT_FLAG_UPDATE_MAP) reg |= VDPU_REG_FWD_PIC1_SEGMENT_UPD_E; } vdpu_write_relaxed(vpu, reg, VDPU_REG_VP8_SEGMENT_VAL); /* set output frame buffer address */ dst_dma = vb2_dma_contig_plane_dma_addr(&vb2_dst->vb2_buf, 0); vdpu_write_relaxed(vpu, dst_dma, VDPU_REG_ADDR_DST); } int rockchip_vpu2_vp8_dec_run(struct hantro_ctx *ctx) { const struct v4l2_ctrl_vp8_frame *hdr; struct hantro_dev *vpu = ctx->dev; struct vb2_v4l2_buffer *vb2_dst; size_t height = ctx->dst_fmt.height; size_t width = ctx->dst_fmt.width; u32 mb_width, mb_height; u32 reg; hantro_start_prepare_run(ctx); hdr = hantro_get_ctrl(ctx, V4L2_CID_STATELESS_VP8_FRAME); if (WARN_ON(!hdr)) return -EINVAL; /* Reset segment_map buffer in keyframe */ if (V4L2_VP8_FRAME_IS_KEY_FRAME(hdr) && ctx->vp8_dec.segment_map.cpu) memset(ctx->vp8_dec.segment_map.cpu, 0, ctx->vp8_dec.segment_map.size); hantro_vp8_prob_update(ctx, hdr); /* * Extensive testing shows that the hardware does not properly * clear the internal state from previous a decoding run. This * causes corruption in decoded frames for multi-instance use cases. * A soft reset before programming the registers has been found * to resolve those problems. */ ctx->codec_ops->reset(ctx); reg = VDPU_REG_CONFIG_DEC_TIMEOUT_E | VDPU_REG_CONFIG_DEC_CLK_GATE_E; if (!V4L2_VP8_FRAME_IS_KEY_FRAME(hdr)) reg |= VDPU_REG_DEC_CTRL0_PIC_INTER_E; vdpu_write_relaxed(vpu, reg, VDPU_REG_EN_FLAGS); reg = VDPU_REG_CONFIG_DEC_STRENDIAN_E | VDPU_REG_CONFIG_DEC_INSWAP32_E | VDPU_REG_CONFIG_DEC_STRSWAP32_E | VDPU_REG_CONFIG_DEC_OUTSWAP32_E | VDPU_REG_CONFIG_DEC_IN_ENDIAN | VDPU_REG_CONFIG_DEC_OUT_ENDIAN; vdpu_write_relaxed(vpu, reg, VDPU_REG_DATA_ENDIAN); reg = VDPU_REG_CONFIG_DEC_MAX_BURST(16); vdpu_write_relaxed(vpu, reg, VDPU_REG_AXI_CTRL); reg = VDPU_REG_DEC_CTRL0_DEC_MODE(10); vdpu_write_relaxed(vpu, reg, VDPU_REG_DEC_FORMAT); if (!(hdr->flags & V4L2_VP8_FRAME_FLAG_MB_NO_SKIP_COEFF)) hantro_reg_write(vpu, &vp8_dec_skip_mode, 1); if (hdr->lf.level == 0) hantro_reg_write(vpu, &vp8_dec_filter_disable, 1); /* Frame dimensions */ mb_width = MB_WIDTH(width); mb_height = MB_HEIGHT(height); hantro_reg_write(vpu, &vp8_dec_mb_width, mb_width); hantro_reg_write(vpu, &vp8_dec_mb_height, mb_height); hantro_reg_write(vpu, &vp8_dec_mb_width_ext, mb_width >> 9); hantro_reg_write(vpu, &vp8_dec_mb_height_ext, mb_height >> 8); /* Boolean decoder */ hantro_reg_write(vpu, &vp8_dec_bool_range, hdr->coder_state.range); hantro_reg_write(vpu, &vp8_dec_bool_value, hdr->coder_state.value); reg = vdpu_read(vpu, VDPU_REG_VP8_DCT_START_BIT); if (hdr->version != 3) reg |= VDPU_REG_DEC_CTRL4_VC1_HEIGHT_EXT; if (hdr->version & 0x3) reg |= VDPU_REG_DEC_CTRL4_BILIN_MC_E; vdpu_write_relaxed(vpu, reg, VDPU_REG_VP8_DCT_START_BIT); cfg_lf(ctx, hdr); cfg_qp(ctx, hdr); cfg_parts(ctx, hdr); cfg_tap(ctx, hdr); vb2_dst = hantro_get_dst_buf(ctx); cfg_ref(ctx, hdr, vb2_dst); cfg_buffers(ctx, hdr, vb2_dst); hantro_end_prepare_run(ctx); hantro_reg_write(vpu, &vp8_dec_start_dec, 1); return 0; }
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