/************************************************************************** * * Copyright 2011 Advanced Micro Devices, Inc. * All Rights Reserved. * * 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 THE COPYRIGHT HOLDER(S) OR AUTHOR(S) 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. * **************************************************************************/ #include #include #include #include #include #include "pipe/p_video_codec.h" #include "util/u_memory.h" #include "util/u_video.h" #include "vl/vl_defines.h" #include "vl/vl_mpeg12_decoder.h" #include "radeonsi/si_pipe.h" #include "radeon_video.h" #include "radeon_uvd.h" #define NUM_BUFFERS 4 #define NUM_MPEG2_REFS 6 #define NUM_H264_REFS 17 #define NUM_VC1_REFS 5 #define FB_BUFFER_OFFSET 0x1000 #define FB_BUFFER_SIZE 2048 #define FB_BUFFER_SIZE_TONGA (2048 * 64) #define IT_SCALING_TABLE_SIZE 992 #define UVD_SESSION_CONTEXT_SIZE (128 * 1024) /* UVD decoder representation */ struct ruvd_decoder { struct pipe_video_codec base; ruvd_set_dtb set_dtb; unsigned stream_handle; unsigned stream_type; unsigned frame_number; struct pipe_screen *screen; struct radeon_winsys* ws; struct radeon_winsys_cs* cs; unsigned cur_buffer; struct rvid_buffer msg_fb_it_buffers[NUM_BUFFERS]; struct ruvd_msg *msg; uint32_t *fb; unsigned fb_size; uint8_t *it; struct rvid_buffer bs_buffers[NUM_BUFFERS]; void* bs_ptr; unsigned bs_size; struct rvid_buffer dpb; bool use_legacy; struct rvid_buffer ctx; struct rvid_buffer sessionctx; struct { unsigned data0; unsigned data1; unsigned cmd; unsigned cntl; } reg; }; /* flush IB to the hardware */ static int flush(struct ruvd_decoder *dec, unsigned flags) { return dec->ws->cs_flush(dec->cs, flags, NULL); } /* add a new set register command to the IB */ static void set_reg(struct ruvd_decoder *dec, unsigned reg, uint32_t val) { radeon_emit(dec->cs, RUVD_PKT0(reg >> 2, 0)); radeon_emit(dec->cs, val); } /* send a command to the VCPU through the GPCOM registers */ static void send_cmd(struct ruvd_decoder *dec, unsigned cmd, struct pb_buffer* buf, uint32_t off, enum radeon_bo_usage usage, enum radeon_bo_domain domain) { int reloc_idx; reloc_idx = dec->ws->cs_add_buffer(dec->cs, buf, usage | RADEON_USAGE_SYNCHRONIZED, domain, RADEON_PRIO_UVD); if (!dec->use_legacy) { uint64_t addr; addr = dec->ws->buffer_get_virtual_address(buf); addr = addr + off; set_reg(dec, dec->reg.data0, addr); set_reg(dec, dec->reg.data1, addr >> 32); } else { off += dec->ws->buffer_get_reloc_offset(buf); set_reg(dec, RUVD_GPCOM_VCPU_DATA0, off); set_reg(dec, RUVD_GPCOM_VCPU_DATA1, reloc_idx * 4); } set_reg(dec, dec->reg.cmd, cmd << 1); } /* do the codec needs an IT buffer ?*/ static bool have_it(struct ruvd_decoder *dec) { return dec->stream_type == RUVD_CODEC_H264_PERF || dec->stream_type == RUVD_CODEC_H265; } /* map the next available message/feedback/itscaling buffer */ static void map_msg_fb_it_buf(struct ruvd_decoder *dec) { struct rvid_buffer* buf; uint8_t *ptr; /* grab the current message/feedback buffer */ buf = &dec->msg_fb_it_buffers[dec->cur_buffer]; /* and map it for CPU access */ ptr = dec->ws->buffer_map(buf->res->buf, dec->cs, PIPE_TRANSFER_WRITE); /* calc buffer offsets */ dec->msg = (struct ruvd_msg *)ptr; memset(dec->msg, 0, sizeof(*dec->msg)); dec->fb = (uint32_t *)(ptr + FB_BUFFER_OFFSET); if (have_it(dec)) dec->it = (uint8_t *)(ptr + FB_BUFFER_OFFSET + dec->fb_size); } /* unmap and send a message command to the VCPU */ static void send_msg_buf(struct ruvd_decoder *dec) { struct rvid_buffer* buf; /* ignore the request if message/feedback buffer isn't mapped */ if (!dec->msg || !dec->fb) return; /* grab the current message buffer */ buf = &dec->msg_fb_it_buffers[dec->cur_buffer]; /* unmap the buffer */ dec->ws->buffer_unmap(buf->res->buf); dec->msg = NULL; dec->fb = NULL; dec->it = NULL; if (dec->sessionctx.res) send_cmd(dec, RUVD_CMD_SESSION_CONTEXT_BUFFER, dec->sessionctx.res->buf, 0, RADEON_USAGE_READWRITE, RADEON_DOMAIN_VRAM); /* and send it to the hardware */ send_cmd(dec, RUVD_CMD_MSG_BUFFER, buf->res->buf, 0, RADEON_USAGE_READ, RADEON_DOMAIN_GTT); } /* cycle to the next set of buffers */ static void next_buffer(struct ruvd_decoder *dec) { ++dec->cur_buffer; dec->cur_buffer %= NUM_BUFFERS; } /* convert the profile into something UVD understands */ static uint32_t profile2stream_type(struct ruvd_decoder *dec, unsigned family) { switch (u_reduce_video_profile(dec->base.profile)) { case PIPE_VIDEO_FORMAT_MPEG4_AVC: return (family >= CHIP_TONGA) ? RUVD_CODEC_H264_PERF : RUVD_CODEC_H264; case PIPE_VIDEO_FORMAT_VC1: return RUVD_CODEC_VC1; case PIPE_VIDEO_FORMAT_MPEG12: return RUVD_CODEC_MPEG2; case PIPE_VIDEO_FORMAT_MPEG4: return RUVD_CODEC_MPEG4; case PIPE_VIDEO_FORMAT_HEVC: return RUVD_CODEC_H265; case PIPE_VIDEO_FORMAT_JPEG: return RUVD_CODEC_MJPEG; default: assert(0); return 0; } } static unsigned calc_ctx_size_h264_perf(struct ruvd_decoder *dec) { unsigned width_in_mb, height_in_mb, ctx_size; unsigned width = align(dec->base.width, VL_MACROBLOCK_WIDTH); unsigned height = align(dec->base.height, VL_MACROBLOCK_HEIGHT); unsigned max_references = dec->base.max_references + 1; // picture width & height in 16 pixel units width_in_mb = width / VL_MACROBLOCK_WIDTH; height_in_mb = align(height / VL_MACROBLOCK_HEIGHT, 2); if (!dec->use_legacy) { unsigned fs_in_mb = width_in_mb * height_in_mb; unsigned num_dpb_buffer; switch(dec->base.level) { case 30: num_dpb_buffer = 8100 / fs_in_mb; break; case 31: num_dpb_buffer = 18000 / fs_in_mb; break; case 32: num_dpb_buffer = 20480 / fs_in_mb; break; case 41: num_dpb_buffer = 32768 / fs_in_mb; break; case 42: num_dpb_buffer = 34816 / fs_in_mb; break; case 50: num_dpb_buffer = 110400 / fs_in_mb; break; case 51: num_dpb_buffer = 184320 / fs_in_mb; break; default: num_dpb_buffer = 184320 / fs_in_mb; break; } num_dpb_buffer++; max_references = MAX2(MIN2(NUM_H264_REFS, num_dpb_buffer), max_references); ctx_size = max_references * align(width_in_mb * height_in_mb * 192, 256); } else { // the firmware seems to always assume a minimum of ref frames max_references = MAX2(NUM_H264_REFS, max_references); // macroblock context buffer ctx_size = align(width_in_mb * height_in_mb * max_references * 192, 256); } return ctx_size; } static unsigned calc_ctx_size_h265_main(struct ruvd_decoder *dec) { unsigned width = align(dec->base.width, VL_MACROBLOCK_WIDTH); unsigned height = align(dec->base.height, VL_MACROBLOCK_HEIGHT); unsigned max_references = dec->base.max_references + 1; if (dec->base.width * dec->base.height >= 4096*2000) max_references = MAX2(max_references, 8); else max_references = MAX2(max_references, 17); width = align (width, 16); height = align (height, 16); return ((width + 255) / 16) * ((height + 255) / 16) * 16 * max_references + 52 * 1024; } static unsigned calc_ctx_size_h265_main10(struct ruvd_decoder *dec, struct pipe_h265_picture_desc *pic) { unsigned block_size, log2_ctb_size, width_in_ctb, height_in_ctb, num_16x16_block_per_ctb; unsigned context_buffer_size_per_ctb_row, cm_buffer_size, max_mb_address, db_left_tile_pxl_size; unsigned db_left_tile_ctx_size = 4096 / 16 * (32 + 16 * 4); unsigned width = align(dec->base.width, VL_MACROBLOCK_WIDTH); unsigned height = align(dec->base.height, VL_MACROBLOCK_HEIGHT); unsigned coeff_10bit = (pic->pps->sps->bit_depth_luma_minus8 || pic->pps->sps->bit_depth_chroma_minus8) ? 2 : 1; unsigned max_references = dec->base.max_references + 1; if (dec->base.width * dec->base.height >= 4096*2000) max_references = MAX2(max_references, 8); else max_references = MAX2(max_references, 17); block_size = (1 << (pic->pps->sps->log2_min_luma_coding_block_size_minus3 + 3)); log2_ctb_size = block_size + pic->pps->sps->log2_diff_max_min_luma_coding_block_size; width_in_ctb = (width + ((1 << log2_ctb_size) - 1)) >> log2_ctb_size; height_in_ctb = (height + ((1 << log2_ctb_size) - 1)) >> log2_ctb_size; num_16x16_block_per_ctb = ((1 << log2_ctb_size) >> 4) * ((1 << log2_ctb_size) >> 4); context_buffer_size_per_ctb_row = align(width_in_ctb * num_16x16_block_per_ctb * 16, 256); max_mb_address = (unsigned) ceil(height * 8 / 2048.0); cm_buffer_size = max_references * context_buffer_size_per_ctb_row * height_in_ctb; db_left_tile_pxl_size = coeff_10bit * (max_mb_address * 2 * 2048 + 1024); return cm_buffer_size + db_left_tile_ctx_size + db_left_tile_pxl_size; } static unsigned get_db_pitch_alignment(struct ruvd_decoder *dec) { if (((struct si_screen*)dec->screen)->info.family < CHIP_VEGA10) return 16; else return 32; } /* calculate size of reference picture buffer */ static unsigned calc_dpb_size(struct ruvd_decoder *dec) { unsigned width_in_mb, height_in_mb, image_size, dpb_size; // always align them to MB size for dpb calculation unsigned width = align(dec->base.width, VL_MACROBLOCK_WIDTH); unsigned height = align(dec->base.height, VL_MACROBLOCK_HEIGHT); // always one more for currently decoded picture unsigned max_references = dec->base.max_references + 1; // aligned size of a single frame image_size = align(width, get_db_pitch_alignment(dec)) * height; image_size += image_size / 2; image_size = align(image_size, 1024); // picture width & height in 16 pixel units width_in_mb = width / VL_MACROBLOCK_WIDTH; height_in_mb = align(height / VL_MACROBLOCK_HEIGHT, 2); switch (u_reduce_video_profile(dec->base.profile)) { case PIPE_VIDEO_FORMAT_MPEG4_AVC: { if (!dec->use_legacy) { unsigned fs_in_mb = width_in_mb * height_in_mb; unsigned alignment = 64, num_dpb_buffer; if (dec->stream_type == RUVD_CODEC_H264_PERF) alignment = 256; switch(dec->base.level) { case 30: num_dpb_buffer = 8100 / fs_in_mb; break; case 31: num_dpb_buffer = 18000 / fs_in_mb; break; case 32: num_dpb_buffer = 20480 / fs_in_mb; break; case 41: num_dpb_buffer = 32768 / fs_in_mb; break; case 42: num_dpb_buffer = 34816 / fs_in_mb; break; case 50: num_dpb_buffer = 110400 / fs_in_mb; break; case 51: num_dpb_buffer = 184320 / fs_in_mb; break; default: num_dpb_buffer = 184320 / fs_in_mb; break; } num_dpb_buffer++; max_references = MAX2(MIN2(NUM_H264_REFS, num_dpb_buffer), max_references); dpb_size = image_size * max_references; if ((dec->stream_type != RUVD_CODEC_H264_PERF) || (((struct si_screen*)dec->screen)->info.family < CHIP_POLARIS10)) { dpb_size += max_references * align(width_in_mb * height_in_mb * 192, alignment); dpb_size += align(width_in_mb * height_in_mb * 32, alignment); } } else { // the firmware seems to allways assume a minimum of ref frames max_references = MAX2(NUM_H264_REFS, max_references); // reference picture buffer dpb_size = image_size * max_references; if ((dec->stream_type != RUVD_CODEC_H264_PERF) || (((struct si_screen*)dec->screen)->info.family < CHIP_POLARIS10)) { // macroblock context buffer dpb_size += width_in_mb * height_in_mb * max_references * 192; // IT surface buffer dpb_size += width_in_mb * height_in_mb * 32; } } break; } case PIPE_VIDEO_FORMAT_HEVC: if (dec->base.width * dec->base.height >= 4096*2000) max_references = MAX2(max_references, 8); else max_references = MAX2(max_references, 17); width = align (width, 16); height = align (height, 16); if (dec->base.profile == PIPE_VIDEO_PROFILE_HEVC_MAIN_10) dpb_size = align((align(width, get_db_pitch_alignment(dec)) * height * 9) / 4, 256) * max_references; else dpb_size = align((align(width, get_db_pitch_alignment(dec)) * height * 3) / 2, 256) * max_references; break; case PIPE_VIDEO_FORMAT_VC1: // the firmware seems to allways assume a minimum of ref frames max_references = MAX2(NUM_VC1_REFS, max_references); // reference picture buffer dpb_size = image_size * max_references; // CONTEXT_BUFFER dpb_size += width_in_mb * height_in_mb * 128; // IT surface buffer dpb_size += width_in_mb * 64; // DB surface buffer dpb_size += width_in_mb * 128; // BP dpb_size += align(MAX2(width_in_mb, height_in_mb) * 7 * 16, 64); break; case PIPE_VIDEO_FORMAT_MPEG12: // reference picture buffer, must be big enough for all frames dpb_size = image_size * NUM_MPEG2_REFS; break; case PIPE_VIDEO_FORMAT_MPEG4: // reference picture buffer dpb_size = image_size * max_references; // CM dpb_size += width_in_mb * height_in_mb * 64; // IT surface buffer dpb_size += align(width_in_mb * height_in_mb * 32, 64); dpb_size = MAX2(dpb_size, 30 * 1024 * 1024); break; case PIPE_VIDEO_FORMAT_JPEG: dpb_size = 0; break; default: // something is missing here assert(0); // at least use a sane default value dpb_size = 32 * 1024 * 1024; break; } return dpb_size; } /* free associated data in the video buffer callback */ static void ruvd_destroy_associated_data(void *data) { /* NOOP, since we only use an intptr */ } /* get h264 specific message bits */ static struct ruvd_h264 get_h264_msg(struct ruvd_decoder *dec, struct pipe_h264_picture_desc *pic) { struct ruvd_h264 result; memset(&result, 0, sizeof(result)); switch (pic->base.profile) { case PIPE_VIDEO_PROFILE_MPEG4_AVC_BASELINE: case PIPE_VIDEO_PROFILE_MPEG4_AVC_CONSTRAINED_BASELINE: result.profile = RUVD_H264_PROFILE_BASELINE; break; case PIPE_VIDEO_PROFILE_MPEG4_AVC_MAIN: result.profile = RUVD_H264_PROFILE_MAIN; break; case PIPE_VIDEO_PROFILE_MPEG4_AVC_HIGH: result.profile = RUVD_H264_PROFILE_HIGH; break; default: assert(0); break; } result.level = dec->base.level; result.sps_info_flags = 0; result.sps_info_flags |= pic->pps->sps->direct_8x8_inference_flag << 0; result.sps_info_flags |= pic->pps->sps->mb_adaptive_frame_field_flag << 1; result.sps_info_flags |= pic->pps->sps->frame_mbs_only_flag << 2; result.sps_info_flags |= pic->pps->sps->delta_pic_order_always_zero_flag << 3; result.bit_depth_luma_minus8 = pic->pps->sps->bit_depth_luma_minus8; result.bit_depth_chroma_minus8 = pic->pps->sps->bit_depth_chroma_minus8; result.log2_max_frame_num_minus4 = pic->pps->sps->log2_max_frame_num_minus4; result.pic_order_cnt_type = pic->pps->sps->pic_order_cnt_type; result.log2_max_pic_order_cnt_lsb_minus4 = pic->pps->sps->log2_max_pic_order_cnt_lsb_minus4; switch (dec->base.chroma_format) { case PIPE_VIDEO_CHROMA_FORMAT_NONE: /* TODO: assert? */ break; case PIPE_VIDEO_CHROMA_FORMAT_400: result.chroma_format = 0; break; case PIPE_VIDEO_CHROMA_FORMAT_420: result.chroma_format = 1; break; case PIPE_VIDEO_CHROMA_FORMAT_422: result.chroma_format = 2; break; case PIPE_VIDEO_CHROMA_FORMAT_444: result.chroma_format = 3; break; } result.pps_info_flags = 0; result.pps_info_flags |= pic->pps->transform_8x8_mode_flag << 0; result.pps_info_flags |= pic->pps->redundant_pic_cnt_present_flag << 1; result.pps_info_flags |= pic->pps->constrained_intra_pred_flag << 2; result.pps_info_flags |= pic->pps->deblocking_filter_control_present_flag << 3; result.pps_info_flags |= pic->pps->weighted_bipred_idc << 4; result.pps_info_flags |= pic->pps->weighted_pred_flag << 6; result.pps_info_flags |= pic->pps->bottom_field_pic_order_in_frame_present_flag << 7; result.pps_info_flags |= pic->pps->entropy_coding_mode_flag << 8; result.num_slice_groups_minus1 = pic->pps->num_slice_groups_minus1; result.slice_group_map_type = pic->pps->slice_group_map_type; result.slice_group_change_rate_minus1 = pic->pps->slice_group_change_rate_minus1; result.pic_init_qp_minus26 = pic->pps->pic_init_qp_minus26; result.chroma_qp_index_offset = pic->pps->chroma_qp_index_offset; result.second_chroma_qp_index_offset = pic->pps->second_chroma_qp_index_offset; memcpy(result.scaling_list_4x4, pic->pps->ScalingList4x4, 6*16); memcpy(result.scaling_list_8x8, pic->pps->ScalingList8x8, 2*64); if (dec->stream_type == RUVD_CODEC_H264_PERF) { memcpy(dec->it, result.scaling_list_4x4, 6*16); memcpy((dec->it + 96), result.scaling_list_8x8, 2*64); } result.num_ref_frames = pic->num_ref_frames; result.num_ref_idx_l0_active_minus1 = pic->num_ref_idx_l0_active_minus1; result.num_ref_idx_l1_active_minus1 = pic->num_ref_idx_l1_active_minus1; result.frame_num = pic->frame_num; memcpy(result.frame_num_list, pic->frame_num_list, 4*16); result.curr_field_order_cnt_list[0] = pic->field_order_cnt[0]; result.curr_field_order_cnt_list[1] = pic->field_order_cnt[1]; memcpy(result.field_order_cnt_list, pic->field_order_cnt_list, 4*16*2); result.decoded_pic_idx = pic->frame_num; return result; } /* get h265 specific message bits */ static struct ruvd_h265 get_h265_msg(struct ruvd_decoder *dec, struct pipe_video_buffer *target, struct pipe_h265_picture_desc *pic) { struct ruvd_h265 result; unsigned i; memset(&result, 0, sizeof(result)); result.sps_info_flags = 0; result.sps_info_flags |= pic->pps->sps->scaling_list_enabled_flag << 0; result.sps_info_flags |= pic->pps->sps->amp_enabled_flag << 1; result.sps_info_flags |= pic->pps->sps->sample_adaptive_offset_enabled_flag << 2; result.sps_info_flags |= pic->pps->sps->pcm_enabled_flag << 3; result.sps_info_flags |= pic->pps->sps->pcm_loop_filter_disabled_flag << 4; result.sps_info_flags |= pic->pps->sps->long_term_ref_pics_present_flag << 5; result.sps_info_flags |= pic->pps->sps->sps_temporal_mvp_enabled_flag << 6; result.sps_info_flags |= pic->pps->sps->strong_intra_smoothing_enabled_flag << 7; result.sps_info_flags |= pic->pps->sps->separate_colour_plane_flag << 8; if (((struct si_screen*)dec->screen)->info.family == CHIP_CARRIZO) result.sps_info_flags |= 1 << 9; if (pic->UseRefPicList == true) result.sps_info_flags |= 1 << 10; result.chroma_format = pic->pps->sps->chroma_format_idc; result.bit_depth_luma_minus8 = pic->pps->sps->bit_depth_luma_minus8; result.bit_depth_chroma_minus8 = pic->pps->sps->bit_depth_chroma_minus8; result.log2_max_pic_order_cnt_lsb_minus4 = pic->pps->sps->log2_max_pic_order_cnt_lsb_minus4; result.sps_max_dec_pic_buffering_minus1 = pic->pps->sps->sps_max_dec_pic_buffering_minus1; result.log2_min_luma_coding_block_size_minus3 = pic->pps->sps->log2_min_luma_coding_block_size_minus3; result.log2_diff_max_min_luma_coding_block_size = pic->pps->sps->log2_diff_max_min_luma_coding_block_size; result.log2_min_transform_block_size_minus2 = pic->pps->sps->log2_min_transform_block_size_minus2; result.log2_diff_max_min_transform_block_size = pic->pps->sps->log2_diff_max_min_transform_block_size; result.max_transform_hierarchy_depth_inter = pic->pps->sps->max_transform_hierarchy_depth_inter; result.max_transform_hierarchy_depth_intra = pic->pps->sps->max_transform_hierarchy_depth_intra; result.pcm_sample_bit_depth_luma_minus1 = pic->pps->sps->pcm_sample_bit_depth_luma_minus1; result.pcm_sample_bit_depth_chroma_minus1 = pic->pps->sps->pcm_sample_bit_depth_chroma_minus1; result.log2_min_pcm_luma_coding_block_size_minus3 = pic->pps->sps->log2_min_pcm_luma_coding_block_size_minus3; result.log2_diff_max_min_pcm_luma_coding_block_size = pic->pps->sps->log2_diff_max_min_pcm_luma_coding_block_size; result.num_short_term_ref_pic_sets = pic->pps->sps->num_short_term_ref_pic_sets; result.pps_info_flags = 0; result.pps_info_flags |= pic->pps->dependent_slice_segments_enabled_flag << 0; result.pps_info_flags |= pic->pps->output_flag_present_flag << 1; result.pps_info_flags |= pic->pps->sign_data_hiding_enabled_flag << 2; result.pps_info_flags |= pic->pps->cabac_init_present_flag << 3; result.pps_info_flags |= pic->pps->constrained_intra_pred_flag << 4; result.pps_info_flags |= pic->pps->transform_skip_enabled_flag << 5; result.pps_info_flags |= pic->pps->cu_qp_delta_enabled_flag << 6; result.pps_info_flags |= pic->pps->pps_slice_chroma_qp_offsets_present_flag << 7; result.pps_info_flags |= pic->pps->weighted_pred_flag << 8; result.pps_info_flags |= pic->pps->weighted_bipred_flag << 9; result.pps_info_flags |= pic->pps->transquant_bypass_enabled_flag << 10; result.pps_info_flags |= pic->pps->tiles_enabled_flag << 11; result.pps_info_flags |= pic->pps->entropy_coding_sync_enabled_flag << 12; result.pps_info_flags |= pic->pps->uniform_spacing_flag << 13; result.pps_info_flags |= pic->pps->loop_filter_across_tiles_enabled_flag << 14; result.pps_info_flags |= pic->pps->pps_loop_filter_across_slices_enabled_flag << 15; result.pps_info_flags |= pic->pps->deblocking_filter_override_enabled_flag << 16; result.pps_info_flags |= pic->pps->pps_deblocking_filter_disabled_flag << 17; result.pps_info_flags |= pic->pps->lists_modification_present_flag << 18; result.pps_info_flags |= pic->pps->slice_segment_header_extension_present_flag << 19; //result.pps_info_flags |= pic->pps->deblocking_filter_control_present_flag; ??? result.num_extra_slice_header_bits = pic->pps->num_extra_slice_header_bits; result.num_long_term_ref_pic_sps = pic->pps->sps->num_long_term_ref_pics_sps; result.num_ref_idx_l0_default_active_minus1 = pic->pps->num_ref_idx_l0_default_active_minus1; result.num_ref_idx_l1_default_active_minus1 = pic->pps->num_ref_idx_l1_default_active_minus1; result.pps_cb_qp_offset = pic->pps->pps_cb_qp_offset; result.pps_cr_qp_offset = pic->pps->pps_cr_qp_offset; result.pps_beta_offset_div2 = pic->pps->pps_beta_offset_div2; result.pps_tc_offset_div2 = pic->pps->pps_tc_offset_div2; result.diff_cu_qp_delta_depth = pic->pps->diff_cu_qp_delta_depth; result.num_tile_columns_minus1 = pic->pps->num_tile_columns_minus1; result.num_tile_rows_minus1 = pic->pps->num_tile_rows_minus1; result.log2_parallel_merge_level_minus2 = pic->pps->log2_parallel_merge_level_minus2; result.init_qp_minus26 = pic->pps->init_qp_minus26; for (i = 0; i < 19; ++i) result.column_width_minus1[i] = pic->pps->column_width_minus1[i]; for (i = 0; i < 21; ++i) result.row_height_minus1[i] = pic->pps->row_height_minus1[i]; result.num_delta_pocs_ref_rps_idx = pic->NumDeltaPocsOfRefRpsIdx; result.curr_idx = pic->CurrPicOrderCntVal; result.curr_poc = pic->CurrPicOrderCntVal; vl_video_buffer_set_associated_data(target, &dec->base, (void *)(uintptr_t)pic->CurrPicOrderCntVal, &ruvd_destroy_associated_data); for (i = 0; i < 16; ++i) { struct pipe_video_buffer *ref = pic->ref[i]; uintptr_t ref_pic = 0; result.poc_list[i] = pic->PicOrderCntVal[i]; if (ref) ref_pic = (uintptr_t)vl_video_buffer_get_associated_data(ref, &dec->base); else ref_pic = 0x7F; result.ref_pic_list[i] = ref_pic; } for (i = 0; i < 8; ++i) { result.ref_pic_set_st_curr_before[i] = 0xFF; result.ref_pic_set_st_curr_after[i] = 0xFF; result.ref_pic_set_lt_curr[i] = 0xFF; } for (i = 0; i < pic->NumPocStCurrBefore; ++i) result.ref_pic_set_st_curr_before[i] = pic->RefPicSetStCurrBefore[i]; for (i = 0; i < pic->NumPocStCurrAfter; ++i) result.ref_pic_set_st_curr_after[i] = pic->RefPicSetStCurrAfter[i]; for (i = 0; i < pic->NumPocLtCurr; ++i) result.ref_pic_set_lt_curr[i] = pic->RefPicSetLtCurr[i]; for (i = 0; i < 6; ++i) result.ucScalingListDCCoefSizeID2[i] = pic->pps->sps->ScalingListDCCoeff16x16[i]; for (i = 0; i < 2; ++i) result.ucScalingListDCCoefSizeID3[i] = pic->pps->sps->ScalingListDCCoeff32x32[i]; memcpy(dec->it, pic->pps->sps->ScalingList4x4, 6 * 16); memcpy(dec->it + 96, pic->pps->sps->ScalingList8x8, 6 * 64); memcpy(dec->it + 480, pic->pps->sps->ScalingList16x16, 6 * 64); memcpy(dec->it + 864, pic->pps->sps->ScalingList32x32, 2 * 64); for (i = 0 ; i < 2 ; i++) { for (int j = 0 ; j < 15 ; j++) result.direct_reflist[i][j] = pic->RefPicList[i][j]; } if (pic->base.profile == PIPE_VIDEO_PROFILE_HEVC_MAIN_10) { if (target->buffer_format == PIPE_FORMAT_P016) { result.p010_mode = 1; result.msb_mode = 1; } else { result.luma_10to8 = 5; result.chroma_10to8 = 5; result.sclr_luma10to8 = 4; result.sclr_chroma10to8 = 4; } } /* TODO result.highestTid; result.isNonRef; IDRPicFlag; RAPPicFlag; NumPocTotalCurr; NumShortTermPictureSliceHeaderBits; NumLongTermPictureSliceHeaderBits; IsLongTerm[16]; */ return result; } /* get vc1 specific message bits */ static struct ruvd_vc1 get_vc1_msg(struct pipe_vc1_picture_desc *pic) { struct ruvd_vc1 result; memset(&result, 0, sizeof(result)); switch(pic->base.profile) { case PIPE_VIDEO_PROFILE_VC1_SIMPLE: result.profile = RUVD_VC1_PROFILE_SIMPLE; result.level = 1; break; case PIPE_VIDEO_PROFILE_VC1_MAIN: result.profile = RUVD_VC1_PROFILE_MAIN; result.level = 2; break; case PIPE_VIDEO_PROFILE_VC1_ADVANCED: result.profile = RUVD_VC1_PROFILE_ADVANCED; result.level = 4; break; default: assert(0); } /* fields common for all profiles */ result.sps_info_flags |= pic->postprocflag << 7; result.sps_info_flags |= pic->pulldown << 6; result.sps_info_flags |= pic->interlace << 5; result.sps_info_flags |= pic->tfcntrflag << 4; result.sps_info_flags |= pic->finterpflag << 3; result.sps_info_flags |= pic->psf << 1; result.pps_info_flags |= pic->range_mapy_flag << 31; result.pps_info_flags |= pic->range_mapy << 28; result.pps_info_flags |= pic->range_mapuv_flag << 27; result.pps_info_flags |= pic->range_mapuv << 24; result.pps_info_flags |= pic->multires << 21; result.pps_info_flags |= pic->maxbframes << 16; result.pps_info_flags |= pic->overlap << 11; result.pps_info_flags |= pic->quantizer << 9; result.pps_info_flags |= pic->panscan_flag << 7; result.pps_info_flags |= pic->refdist_flag << 6; result.pps_info_flags |= pic->vstransform << 0; /* some fields only apply to main/advanced profile */ if (pic->base.profile != PIPE_VIDEO_PROFILE_VC1_SIMPLE) { result.pps_info_flags |= pic->syncmarker << 20; result.pps_info_flags |= pic->rangered << 19; result.pps_info_flags |= pic->loopfilter << 5; result.pps_info_flags |= pic->fastuvmc << 4; result.pps_info_flags |= pic->extended_mv << 3; result.pps_info_flags |= pic->extended_dmv << 8; result.pps_info_flags |= pic->dquant << 1; } result.chroma_format = 1; #if 0 //(((unsigned int)(pPicParams->advance.reserved1)) << SPS_INFO_VC1_RESERVED_SHIFT) uint32_t slice_count uint8_t picture_type uint8_t frame_coding_mode uint8_t deblockEnable uint8_t pquant #endif return result; } /* extract the frame number from a referenced video buffer */ static uint32_t get_ref_pic_idx(struct ruvd_decoder *dec, struct pipe_video_buffer *ref) { uint32_t min = MAX2(dec->frame_number, NUM_MPEG2_REFS) - NUM_MPEG2_REFS; uint32_t max = MAX2(dec->frame_number, 1) - 1; uintptr_t frame; /* seems to be the most sane fallback */ if (!ref) return max; /* get the frame number from the associated data */ frame = (uintptr_t)vl_video_buffer_get_associated_data(ref, &dec->base); /* limit the frame number to a valid range */ return MAX2(MIN2(frame, max), min); } /* get mpeg2 specific msg bits */ static struct ruvd_mpeg2 get_mpeg2_msg(struct ruvd_decoder *dec, struct pipe_mpeg12_picture_desc *pic) { const int *zscan = pic->alternate_scan ? vl_zscan_alternate : vl_zscan_normal; struct ruvd_mpeg2 result; unsigned i; memset(&result, 0, sizeof(result)); result.decoded_pic_idx = dec->frame_number; for (i = 0; i < 2; ++i) result.ref_pic_idx[i] = get_ref_pic_idx(dec, pic->ref[i]); result.load_intra_quantiser_matrix = 1; result.load_nonintra_quantiser_matrix = 1; for (i = 0; i < 64; ++i) { result.intra_quantiser_matrix[i] = pic->intra_matrix[zscan[i]]; result.nonintra_quantiser_matrix[i] = pic->non_intra_matrix[zscan[i]]; } result.profile_and_level_indication = 0; result.chroma_format = 0x1; result.picture_coding_type = pic->picture_coding_type; result.f_code[0][0] = pic->f_code[0][0] + 1; result.f_code[0][1] = pic->f_code[0][1] + 1; result.f_code[1][0] = pic->f_code[1][0] + 1; result.f_code[1][1] = pic->f_code[1][1] + 1; result.intra_dc_precision = pic->intra_dc_precision; result.pic_structure = pic->picture_structure; result.top_field_first = pic->top_field_first; result.frame_pred_frame_dct = pic->frame_pred_frame_dct; result.concealment_motion_vectors = pic->concealment_motion_vectors; result.q_scale_type = pic->q_scale_type; result.intra_vlc_format = pic->intra_vlc_format; result.alternate_scan = pic->alternate_scan; return result; } /* get mpeg4 specific msg bits */ static struct ruvd_mpeg4 get_mpeg4_msg(struct ruvd_decoder *dec, struct pipe_mpeg4_picture_desc *pic) { struct ruvd_mpeg4 result; unsigned i; memset(&result, 0, sizeof(result)); result.decoded_pic_idx = dec->frame_number; for (i = 0; i < 2; ++i) result.ref_pic_idx[i] = get_ref_pic_idx(dec, pic->ref[i]); result.variant_type = 0; result.profile_and_level_indication = 0xF0; // ASP Level0 result.video_object_layer_verid = 0x5; // advanced simple result.video_object_layer_shape = 0x0; // rectangular result.video_object_layer_width = dec->base.width; result.video_object_layer_height = dec->base.height; result.vop_time_increment_resolution = pic->vop_time_increment_resolution; result.flags |= pic->short_video_header << 0; //result.flags |= obmc_disable << 1; result.flags |= pic->interlaced << 2; result.flags |= 1 << 3; // load_intra_quant_mat result.flags |= 1 << 4; // load_nonintra_quant_mat result.flags |= pic->quarter_sample << 5; result.flags |= 1 << 6; // complexity_estimation_disable result.flags |= pic->resync_marker_disable << 7; //result.flags |= data_partitioned << 8; //result.flags |= reversible_vlc << 9; result.flags |= 0 << 10; // newpred_enable result.flags |= 0 << 11; // reduced_resolution_vop_enable //result.flags |= scalability << 12; //result.flags |= is_object_layer_identifier << 13; //result.flags |= fixed_vop_rate << 14; //result.flags |= newpred_segment_type << 15; result.quant_type = pic->quant_type; for (i = 0; i < 64; ++i) { result.intra_quant_mat[i] = pic->intra_matrix[vl_zscan_normal[i]]; result.nonintra_quant_mat[i] = pic->non_intra_matrix[vl_zscan_normal[i]]; } /* int32_t trd [2] int32_t trb [2] uint8_t vop_coding_type uint8_t vop_fcode_forward uint8_t vop_fcode_backward uint8_t rounding_control uint8_t alternate_vertical_scan_flag uint8_t top_field_first */ return result; } static void get_mjpeg_slice_header(struct ruvd_decoder *dec, struct pipe_mjpeg_picture_desc *pic) { int size = 0, saved_size, len_pos, i; uint16_t *bs; uint8_t *buf = dec->bs_ptr; /* SOI */ buf[size++] = 0xff; buf[size++] = 0xd8; /* DQT */ buf[size++] = 0xff; buf[size++] = 0xdb; len_pos = size++; size++; for (i = 0; i < 4; ++i) { if (pic->quantization_table.load_quantiser_table[i] == 0) continue; buf[size++] = i; memcpy((buf + size), &pic->quantization_table.quantiser_table[i], 64); size += 64; } bs = (uint16_t*)&buf[len_pos]; *bs = util_bswap16(size - 4); saved_size = size; /* DHT */ buf[size++] = 0xff; buf[size++] = 0xc4; len_pos = size++; size++; for (i = 0; i < 2; ++i) { if (pic->huffman_table.load_huffman_table[i] == 0) continue; buf[size++] = 0x00 | i; memcpy((buf + size), &pic->huffman_table.table[i].num_dc_codes, 16); size += 16; memcpy((buf + size), &pic->huffman_table.table[i].dc_values, 12); size += 12; } for (i = 0; i < 2; ++i) { if (pic->huffman_table.load_huffman_table[i] == 0) continue; buf[size++] = 0x10 | i; memcpy((buf + size), &pic->huffman_table.table[i].num_ac_codes, 16); size += 16; memcpy((buf + size), &pic->huffman_table.table[i].ac_values, 162); size += 162; } bs = (uint16_t*)&buf[len_pos]; *bs = util_bswap16(size - saved_size - 2); saved_size = size; /* DRI */ if (pic->slice_parameter.restart_interval) { buf[size++] = 0xff; buf[size++] = 0xdd; buf[size++] = 0x00; buf[size++] = 0x04; bs = (uint16_t*)&buf[size++]; *bs = util_bswap16(pic->slice_parameter.restart_interval); saved_size = ++size; } /* SOF */ buf[size++] = 0xff; buf[size++] = 0xc0; len_pos = size++; size++; buf[size++] = 0x08; bs = (uint16_t*)&buf[size++]; *bs = util_bswap16(pic->picture_parameter.picture_height); size++; bs = (uint16_t*)&buf[size++]; *bs = util_bswap16(pic->picture_parameter.picture_width); size++; buf[size++] = pic->picture_parameter.num_components; for (i = 0; i < pic->picture_parameter.num_components; ++i) { buf[size++] = pic->picture_parameter.components[i].component_id; buf[size++] = pic->picture_parameter.components[i].h_sampling_factor << 4 | pic->picture_parameter.components[i].v_sampling_factor; buf[size++] = pic->picture_parameter.components[i].quantiser_table_selector; } bs = (uint16_t*)&buf[len_pos]; *bs = util_bswap16(size - saved_size - 2); saved_size = size; /* SOS */ buf[size++] = 0xff; buf[size++] = 0xda; len_pos = size++; size++; buf[size++] = pic->slice_parameter.num_components; for (i = 0; i < pic->slice_parameter.num_components; ++i) { buf[size++] = pic->slice_parameter.components[i].component_selector; buf[size++] = pic->slice_parameter.components[i].dc_table_selector << 4 | pic->slice_parameter.components[i].ac_table_selector; } buf[size++] = 0x00; buf[size++] = 0x3f; buf[size++] = 0x00; bs = (uint16_t*)&buf[len_pos]; *bs = util_bswap16(size - saved_size - 2); dec->bs_ptr += size; dec->bs_size += size; } /** * destroy this video decoder */ static void ruvd_destroy(struct pipe_video_codec *decoder) { struct ruvd_decoder *dec = (struct ruvd_decoder*)decoder; unsigned i; assert(decoder); map_msg_fb_it_buf(dec); dec->msg->size = sizeof(*dec->msg); dec->msg->msg_type = RUVD_MSG_DESTROY; dec->msg->stream_handle = dec->stream_handle; send_msg_buf(dec); flush(dec, 0); dec->ws->cs_destroy(dec->cs); for (i = 0; i < NUM_BUFFERS; ++i) { si_vid_destroy_buffer(&dec->msg_fb_it_buffers[i]); si_vid_destroy_buffer(&dec->bs_buffers[i]); } si_vid_destroy_buffer(&dec->dpb); si_vid_destroy_buffer(&dec->ctx); si_vid_destroy_buffer(&dec->sessionctx); FREE(dec); } /** * start decoding of a new frame */ static void ruvd_begin_frame(struct pipe_video_codec *decoder, struct pipe_video_buffer *target, struct pipe_picture_desc *picture) { struct ruvd_decoder *dec = (struct ruvd_decoder*)decoder; uintptr_t frame; assert(decoder); frame = ++dec->frame_number; vl_video_buffer_set_associated_data(target, decoder, (void *)frame, &ruvd_destroy_associated_data); dec->bs_size = 0; dec->bs_ptr = dec->ws->buffer_map( dec->bs_buffers[dec->cur_buffer].res->buf, dec->cs, PIPE_TRANSFER_WRITE); } /** * decode a macroblock */ static void ruvd_decode_macroblock(struct pipe_video_codec *decoder, struct pipe_video_buffer *target, struct pipe_picture_desc *picture, const struct pipe_macroblock *macroblocks, unsigned num_macroblocks) { /* not supported (yet) */ assert(0); } /** * decode a bitstream */ static void ruvd_decode_bitstream(struct pipe_video_codec *decoder, struct pipe_video_buffer *target, struct pipe_picture_desc *picture, unsigned num_buffers, const void * const *buffers, const unsigned *sizes) { struct ruvd_decoder *dec = (struct ruvd_decoder*)decoder; enum pipe_video_format format = u_reduce_video_profile(picture->profile); unsigned i; assert(decoder); if (!dec->bs_ptr) return; if (format == PIPE_VIDEO_FORMAT_JPEG) get_mjpeg_slice_header(dec, (struct pipe_mjpeg_picture_desc*)picture); for (i = 0; i < num_buffers; ++i) { struct rvid_buffer *buf = &dec->bs_buffers[dec->cur_buffer]; unsigned new_size = dec->bs_size + sizes[i]; if (format == PIPE_VIDEO_FORMAT_JPEG) new_size += 2; /* save for EOI */ if (new_size > buf->res->buf->size) { dec->ws->buffer_unmap(buf->res->buf); if (!si_vid_resize_buffer(dec->screen, dec->cs, buf, new_size)) { RVID_ERR("Can't resize bitstream buffer!"); return; } dec->bs_ptr = dec->ws->buffer_map(buf->res->buf, dec->cs, PIPE_TRANSFER_WRITE); if (!dec->bs_ptr) return; dec->bs_ptr += dec->bs_size; } memcpy(dec->bs_ptr, buffers[i], sizes[i]); dec->bs_size += sizes[i]; dec->bs_ptr += sizes[i]; } if (format == PIPE_VIDEO_FORMAT_JPEG) { ((uint8_t *)dec->bs_ptr)[0] = 0xff; /* EOI */ ((uint8_t *)dec->bs_ptr)[1] = 0xd9; dec->bs_size += 2; dec->bs_ptr += 2; } } /** * end decoding of the current frame */ static void ruvd_end_frame(struct pipe_video_codec *decoder, struct pipe_video_buffer *target, struct pipe_picture_desc *picture) { struct ruvd_decoder *dec = (struct ruvd_decoder*)decoder; struct pb_buffer *dt; struct rvid_buffer *msg_fb_it_buf, *bs_buf; unsigned bs_size; assert(decoder); if (!dec->bs_ptr) return; msg_fb_it_buf = &dec->msg_fb_it_buffers[dec->cur_buffer]; bs_buf = &dec->bs_buffers[dec->cur_buffer]; bs_size = align(dec->bs_size, 128); memset(dec->bs_ptr, 0, bs_size - dec->bs_size); dec->ws->buffer_unmap(bs_buf->res->buf); map_msg_fb_it_buf(dec); dec->msg->size = sizeof(*dec->msg); dec->msg->msg_type = RUVD_MSG_DECODE; dec->msg->stream_handle = dec->stream_handle; dec->msg->status_report_feedback_number = dec->frame_number; dec->msg->body.decode.stream_type = dec->stream_type; dec->msg->body.decode.decode_flags = 0x1; dec->msg->body.decode.width_in_samples = dec->base.width; dec->msg->body.decode.height_in_samples = dec->base.height; if ((picture->profile == PIPE_VIDEO_PROFILE_VC1_SIMPLE) || (picture->profile == PIPE_VIDEO_PROFILE_VC1_MAIN)) { dec->msg->body.decode.width_in_samples = align(dec->msg->body.decode.width_in_samples, 16) / 16; dec->msg->body.decode.height_in_samples = align(dec->msg->body.decode.height_in_samples, 16) / 16; } if (dec->dpb.res) dec->msg->body.decode.dpb_size = dec->dpb.res->buf->size; dec->msg->body.decode.bsd_size = bs_size; dec->msg->body.decode.db_pitch = align(dec->base.width, get_db_pitch_alignment(dec)); if (dec->stream_type == RUVD_CODEC_H264_PERF && ((struct si_screen*)dec->screen)->info.family >= CHIP_POLARIS10) dec->msg->body.decode.dpb_reserved = dec->ctx.res->buf->size; dt = dec->set_dtb(dec->msg, (struct vl_video_buffer *)target); if (((struct si_screen*)dec->screen)->info.family >= CHIP_STONEY) dec->msg->body.decode.dt_wa_chroma_top_offset = dec->msg->body.decode.dt_pitch / 2; switch (u_reduce_video_profile(picture->profile)) { case PIPE_VIDEO_FORMAT_MPEG4_AVC: dec->msg->body.decode.codec.h264 = get_h264_msg(dec, (struct pipe_h264_picture_desc*)picture); break; case PIPE_VIDEO_FORMAT_HEVC: dec->msg->body.decode.codec.h265 = get_h265_msg(dec, target, (struct pipe_h265_picture_desc*)picture); if (dec->ctx.res == NULL) { unsigned ctx_size; if (dec->base.profile == PIPE_VIDEO_PROFILE_HEVC_MAIN_10) ctx_size = calc_ctx_size_h265_main10(dec, (struct pipe_h265_picture_desc*)picture); else ctx_size = calc_ctx_size_h265_main(dec); if (!si_vid_create_buffer(dec->screen, &dec->ctx, ctx_size, PIPE_USAGE_DEFAULT)) { RVID_ERR("Can't allocated context buffer.\n"); } si_vid_clear_buffer(decoder->context, &dec->ctx); } if (dec->ctx.res) dec->msg->body.decode.dpb_reserved = dec->ctx.res->buf->size; break; case PIPE_VIDEO_FORMAT_VC1: dec->msg->body.decode.codec.vc1 = get_vc1_msg((struct pipe_vc1_picture_desc*)picture); break; case PIPE_VIDEO_FORMAT_MPEG12: dec->msg->body.decode.codec.mpeg2 = get_mpeg2_msg(dec, (struct pipe_mpeg12_picture_desc*)picture); break; case PIPE_VIDEO_FORMAT_MPEG4: dec->msg->body.decode.codec.mpeg4 = get_mpeg4_msg(dec, (struct pipe_mpeg4_picture_desc*)picture); break; case PIPE_VIDEO_FORMAT_JPEG: break; default: assert(0); return; } dec->msg->body.decode.db_surf_tile_config = dec->msg->body.decode.dt_surf_tile_config; dec->msg->body.decode.extension_support = 0x1; /* set at least the feedback buffer size */ dec->fb[0] = dec->fb_size; send_msg_buf(dec); if (dec->dpb.res) send_cmd(dec, RUVD_CMD_DPB_BUFFER, dec->dpb.res->buf, 0, RADEON_USAGE_READWRITE, RADEON_DOMAIN_VRAM); if (dec->ctx.res) send_cmd(dec, RUVD_CMD_CONTEXT_BUFFER, dec->ctx.res->buf, 0, RADEON_USAGE_READWRITE, RADEON_DOMAIN_VRAM); send_cmd(dec, RUVD_CMD_BITSTREAM_BUFFER, bs_buf->res->buf, 0, RADEON_USAGE_READ, RADEON_DOMAIN_GTT); send_cmd(dec, RUVD_CMD_DECODING_TARGET_BUFFER, dt, 0, RADEON_USAGE_WRITE, RADEON_DOMAIN_VRAM); send_cmd(dec, RUVD_CMD_FEEDBACK_BUFFER, msg_fb_it_buf->res->buf, FB_BUFFER_OFFSET, RADEON_USAGE_WRITE, RADEON_DOMAIN_GTT); if (have_it(dec)) send_cmd(dec, RUVD_CMD_ITSCALING_TABLE_BUFFER, msg_fb_it_buf->res->buf, FB_BUFFER_OFFSET + dec->fb_size, RADEON_USAGE_READ, RADEON_DOMAIN_GTT); set_reg(dec, dec->reg.cntl, 1); flush(dec, PIPE_FLUSH_ASYNC); next_buffer(dec); } /** * flush any outstanding command buffers to the hardware */ static void ruvd_flush(struct pipe_video_codec *decoder) { } /** * create and UVD decoder */ struct pipe_video_codec *si_common_uvd_create_decoder(struct pipe_context *context, const struct pipe_video_codec *templ, ruvd_set_dtb set_dtb) { struct radeon_winsys* ws = ((struct r600_common_context *)context)->ws; struct r600_common_context *rctx = (struct r600_common_context*)context; unsigned dpb_size; unsigned width = templ->width, height = templ->height; unsigned bs_buf_size; struct ruvd_decoder *dec; int r, i; switch(u_reduce_video_profile(templ->profile)) { case PIPE_VIDEO_FORMAT_MPEG12: if (templ->entrypoint > PIPE_VIDEO_ENTRYPOINT_BITSTREAM) return vl_create_mpeg12_decoder(context, templ); /* fall through */ case PIPE_VIDEO_FORMAT_MPEG4: width = align(width, VL_MACROBLOCK_WIDTH); height = align(height, VL_MACROBLOCK_HEIGHT); break; case PIPE_VIDEO_FORMAT_MPEG4_AVC: width = align(width, VL_MACROBLOCK_WIDTH); height = align(height, VL_MACROBLOCK_HEIGHT); break; default: break; } dec = CALLOC_STRUCT(ruvd_decoder); if (!dec) return NULL; if (rctx->screen->info.drm_major < 3) dec->use_legacy = true; dec->base = *templ; dec->base.context = context; dec->base.width = width; dec->base.height = height; dec->base.destroy = ruvd_destroy; dec->base.begin_frame = ruvd_begin_frame; dec->base.decode_macroblock = ruvd_decode_macroblock; dec->base.decode_bitstream = ruvd_decode_bitstream; dec->base.end_frame = ruvd_end_frame; dec->base.flush = ruvd_flush; dec->stream_type = profile2stream_type(dec, rctx->family); dec->set_dtb = set_dtb; dec->stream_handle = si_vid_alloc_stream_handle(); dec->screen = context->screen; dec->ws = ws; dec->cs = ws->cs_create(rctx->ctx, RING_UVD, NULL, NULL); if (!dec->cs) { RVID_ERR("Can't get command submission context.\n"); goto error; } dec->fb_size = (rctx->family == CHIP_TONGA) ? FB_BUFFER_SIZE_TONGA : FB_BUFFER_SIZE; bs_buf_size = width * height * (512 / (16 * 16)); for (i = 0; i < NUM_BUFFERS; ++i) { unsigned msg_fb_it_size = FB_BUFFER_OFFSET + dec->fb_size; STATIC_ASSERT(sizeof(struct ruvd_msg) <= FB_BUFFER_OFFSET); if (have_it(dec)) msg_fb_it_size += IT_SCALING_TABLE_SIZE; if (!si_vid_create_buffer(dec->screen, &dec->msg_fb_it_buffers[i], msg_fb_it_size, PIPE_USAGE_STAGING)) { RVID_ERR("Can't allocated message buffers.\n"); goto error; } if (!si_vid_create_buffer(dec->screen, &dec->bs_buffers[i], bs_buf_size, PIPE_USAGE_STAGING)) { RVID_ERR("Can't allocated bitstream buffers.\n"); goto error; } si_vid_clear_buffer(context, &dec->msg_fb_it_buffers[i]); si_vid_clear_buffer(context, &dec->bs_buffers[i]); } dpb_size = calc_dpb_size(dec); if (dpb_size) { if (!si_vid_create_buffer(dec->screen, &dec->dpb, dpb_size, PIPE_USAGE_DEFAULT)) { RVID_ERR("Can't allocated dpb.\n"); goto error; } si_vid_clear_buffer(context, &dec->dpb); } if (dec->stream_type == RUVD_CODEC_H264_PERF && rctx->family >= CHIP_POLARIS10) { unsigned ctx_size = calc_ctx_size_h264_perf(dec); if (!si_vid_create_buffer(dec->screen, &dec->ctx, ctx_size, PIPE_USAGE_DEFAULT)) { RVID_ERR("Can't allocated context buffer.\n"); goto error; } si_vid_clear_buffer(context, &dec->ctx); } if (rctx->family >= CHIP_POLARIS10 && rctx->screen->info.drm_minor >= 3) { if (!si_vid_create_buffer(dec->screen, &dec->sessionctx, UVD_SESSION_CONTEXT_SIZE, PIPE_USAGE_DEFAULT)) { RVID_ERR("Can't allocated session ctx.\n"); goto error; } si_vid_clear_buffer(context, &dec->sessionctx); } if (rctx->family >= CHIP_VEGA10) { dec->reg.data0 = RUVD_GPCOM_VCPU_DATA0_SOC15; dec->reg.data1 = RUVD_GPCOM_VCPU_DATA1_SOC15; dec->reg.cmd = RUVD_GPCOM_VCPU_CMD_SOC15; dec->reg.cntl = RUVD_ENGINE_CNTL_SOC15; } else { dec->reg.data0 = RUVD_GPCOM_VCPU_DATA0; dec->reg.data1 = RUVD_GPCOM_VCPU_DATA1; dec->reg.cmd = RUVD_GPCOM_VCPU_CMD; dec->reg.cntl = RUVD_ENGINE_CNTL; } map_msg_fb_it_buf(dec); dec->msg->size = sizeof(*dec->msg); dec->msg->msg_type = RUVD_MSG_CREATE; dec->msg->stream_handle = dec->stream_handle; dec->msg->body.create.stream_type = dec->stream_type; dec->msg->body.create.width_in_samples = dec->base.width; dec->msg->body.create.height_in_samples = dec->base.height; dec->msg->body.create.dpb_size = dpb_size; send_msg_buf(dec); r = flush(dec, 0); if (r) goto error; next_buffer(dec); return &dec->base; error: if (dec->cs) dec->ws->cs_destroy(dec->cs); for (i = 0; i < NUM_BUFFERS; ++i) { si_vid_destroy_buffer(&dec->msg_fb_it_buffers[i]); si_vid_destroy_buffer(&dec->bs_buffers[i]); } si_vid_destroy_buffer(&dec->dpb); si_vid_destroy_buffer(&dec->ctx); si_vid_destroy_buffer(&dec->sessionctx); FREE(dec); return NULL; } /* calculate top/bottom offset */ static unsigned texture_offset(struct radeon_surf *surface, unsigned layer, enum ruvd_surface_type type) { switch (type) { default: case RUVD_SURFACE_TYPE_LEGACY: return surface->u.legacy.level[0].offset + layer * (uint64_t)surface->u.legacy.level[0].slice_size_dw * 4; break; case RUVD_SURFACE_TYPE_GFX9: return surface->u.gfx9.surf_offset + layer * surface->u.gfx9.surf_slice_size; break; } } /* hw encode the aspect of macro tiles */ static unsigned macro_tile_aspect(unsigned macro_tile_aspect) { switch (macro_tile_aspect) { default: case 1: macro_tile_aspect = 0; break; case 2: macro_tile_aspect = 1; break; case 4: macro_tile_aspect = 2; break; case 8: macro_tile_aspect = 3; break; } return macro_tile_aspect; } /* hw encode the bank width and height */ static unsigned bank_wh(unsigned bankwh) { switch (bankwh) { default: case 1: bankwh = 0; break; case 2: bankwh = 1; break; case 4: bankwh = 2; break; case 8: bankwh = 3; break; } return bankwh; } /** * fill decoding target field from the luma and chroma surfaces */ void si_uvd_set_dt_surfaces(struct ruvd_msg *msg, struct radeon_surf *luma, struct radeon_surf *chroma, enum ruvd_surface_type type) { switch (type) { default: case RUVD_SURFACE_TYPE_LEGACY: msg->body.decode.dt_pitch = luma->u.legacy.level[0].nblk_x * luma->blk_w; switch (luma->u.legacy.level[0].mode) { case RADEON_SURF_MODE_LINEAR_ALIGNED: msg->body.decode.dt_tiling_mode = RUVD_TILE_LINEAR; msg->body.decode.dt_array_mode = RUVD_ARRAY_MODE_LINEAR; break; case RADEON_SURF_MODE_1D: msg->body.decode.dt_tiling_mode = RUVD_TILE_8X8; msg->body.decode.dt_array_mode = RUVD_ARRAY_MODE_1D_THIN; break; case RADEON_SURF_MODE_2D: msg->body.decode.dt_tiling_mode = RUVD_TILE_8X8; msg->body.decode.dt_array_mode = RUVD_ARRAY_MODE_2D_THIN; break; default: assert(0); break; } msg->body.decode.dt_luma_top_offset = texture_offset(luma, 0, type); if (chroma) msg->body.decode.dt_chroma_top_offset = texture_offset(chroma, 0, type); if (msg->body.decode.dt_field_mode) { msg->body.decode.dt_luma_bottom_offset = texture_offset(luma, 1, type); if (chroma) msg->body.decode.dt_chroma_bottom_offset = texture_offset(chroma, 1, type); } else { msg->body.decode.dt_luma_bottom_offset = msg->body.decode.dt_luma_top_offset; msg->body.decode.dt_chroma_bottom_offset = msg->body.decode.dt_chroma_top_offset; } if (chroma) { assert(luma->u.legacy.bankw == chroma->u.legacy.bankw); assert(luma->u.legacy.bankh == chroma->u.legacy.bankh); assert(luma->u.legacy.mtilea == chroma->u.legacy.mtilea); } msg->body.decode.dt_surf_tile_config |= RUVD_BANK_WIDTH(bank_wh(luma->u.legacy.bankw)); msg->body.decode.dt_surf_tile_config |= RUVD_BANK_HEIGHT(bank_wh(luma->u.legacy.bankh)); msg->body.decode.dt_surf_tile_config |= RUVD_MACRO_TILE_ASPECT_RATIO(macro_tile_aspect(luma->u.legacy.mtilea)); break; case RUVD_SURFACE_TYPE_GFX9: msg->body.decode.dt_pitch = luma->u.gfx9.surf_pitch * luma->blk_w; /* SWIZZLE LINEAR MODE */ msg->body.decode.dt_tiling_mode = RUVD_TILE_LINEAR; msg->body.decode.dt_array_mode = RUVD_ARRAY_MODE_LINEAR; msg->body.decode.dt_luma_top_offset = texture_offset(luma, 0, type); msg->body.decode.dt_chroma_top_offset = texture_offset(chroma, 0, type); if (msg->body.decode.dt_field_mode) { msg->body.decode.dt_luma_bottom_offset = texture_offset(luma, 1, type); msg->body.decode.dt_chroma_bottom_offset = texture_offset(chroma, 1, type); } else { msg->body.decode.dt_luma_bottom_offset = msg->body.decode.dt_luma_top_offset; msg->body.decode.dt_chroma_bottom_offset = msg->body.decode.dt_chroma_top_offset; } msg->body.decode.dt_surf_tile_config = 0; break; } }