// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (c) 2015-2019, The Linux Foundation. All rights reserved. */ #include "msm_vidc_bus.h" #include "msm_vidc_internal.h" struct lut const *__lut(int width, int height, int fps) { int frame_size = height * width, c = 0; do { if (LUT[c].frame_size >= frame_size && LUT[c].frame_rate >= fps) return &LUT[c]; } while (++c < ARRAY_SIZE(LUT)); return &LUT[ARRAY_SIZE(LUT) - 1]; } fp_t __compression_ratio(struct lut const *entry, int bpp) { int c = 0; for (c = 0; c < COMPRESSION_RATIO_MAX; ++c) { if (entry->compression_ratio[c].bpp == bpp) return entry->compression_ratio[c].ratio; } WARN(true, "Shouldn't be here, LUT possibly corrupted?\n"); return FP_ZERO; /* impossible */ } void __dump(struct dump dump[], int len) { int c = 0; for (c = 0; c < len; ++c) { char format_line[128] = "", formatted_line[128] = ""; if (dump[c].val == DUMP_HEADER_MAGIC) { snprintf(formatted_line, sizeof(formatted_line), "%s\n", dump[c].key); } else { bool fp_format = !strcmp(dump[c].format, DUMP_FP_FMT); if (!fp_format) { snprintf(format_line, sizeof(format_line), " %-35s: %s\n", dump[c].key, dump[c].format); snprintf(formatted_line, sizeof(formatted_line), format_line, dump[c].val); } else { size_t integer_part, fractional_part; integer_part = fp_int(dump[c].val); fractional_part = fp_frac(dump[c].val); snprintf(formatted_line, sizeof(formatted_line), " %-35s: %zd + %zd/%zd\n", dump[c].key, integer_part, fractional_part, fp_frac_base()); } } dprintk(VIDC_BUS, "%s", formatted_line); } } static unsigned long __calculate_vpe(struct vidc_bus_vote_data *d, enum vidc_bus_type type) { return 0; } static unsigned long __calculate_cvp(struct vidc_bus_vote_data *d, enum vidc_bus_type type) { unsigned long ret = 0; switch (type) { case DDR: ret = d->ddr_bw; break; case LLCC: ret = d->sys_cache_bw; break; default: dprintk(VIDC_ERR, "%s - Unknown type\n", __func__); break; } return ret; } static unsigned long __calculate_decoder(struct vidc_bus_vote_data *d, enum vidc_bus_type type) { /* * XXX: Don't fool around with any of the hardcoded numbers unless you * know /exactly/ what you're doing. Many of these numbers are * measured heuristics and hardcoded numbers taken from the firmware. */ /* Decoder parameters */ int width, height, lcu_size, fps, dpb_bpp; bool unified_dpb_opb, dpb_compression_enabled = true, opb_compression_enabled = false, llc_ref_read_l2_cache_enabled = false, llc_top_line_buf_enabled = false; fp_t dpb_read_compression_factor, dpb_opb_scaling_ratio, dpb_write_compression_factor, opb_write_compression_factor, qsmmu_bw_overhead_factor; bool is_h264_category = true; /* Derived parameters */ int lcu_per_frame, collocated_bytes_per_lcu, tnbr_per_lcu; unsigned long bitrate; fp_t bins_to_bit_factor, vsp_read_factor, vsp_write_factor, dpb_factor, dpb_write_factor, y_bw_no_ubwc_8bpp, y_bw_no_ubwc_10bpp, y_bw_10bpp_p010, motion_vector_complexity = 0; fp_t dpb_total = 0; /* Output parameters */ struct { fp_t vsp_read, vsp_write, collocated_read, collocated_write, dpb_read, dpb_write, opb_read, opb_write, line_buffer_read, line_buffer_write, total; } ddr = {0}; struct { fp_t dpb_read, line_buffer_read, line_buffer_write, total; } llc = {0}; unsigned long ret = 0; unsigned int integer_part, frac_part; width = max(d->input_width, BASELINE_DIMENSIONS.width); height = max(d->input_height, BASELINE_DIMENSIONS.height); fps = d->fps; lcu_size = d->lcu_size; dpb_bpp = d->num_formats >= 1 ? __bpp(d->color_formats[0]) : INT_MAX; unified_dpb_opb = d->num_formats == 1; dpb_opb_scaling_ratio = fp_div(FP_INT(d->input_width * d->input_height), FP_INT(d->output_width * d->output_height)); opb_compression_enabled = d->num_formats >= 2 && __ubwc(d->color_formats[1]); /* * convert q16 number into integer and fractional part upto 2 places. * ex : 105752 / 65536 = 1.61; 1.61 in q16 = 105752; * integer part = 105752 / 65536 = 1; * reminder = 105752 - 1 * 65536 = 40216; * fractional part = 40216 * 100 / 65536 = 61; * now converto to fp(1, 61, 100) for below code. */ integer_part = d->compression_ratio >> 16; frac_part = ((d->compression_ratio - (integer_part << 16)) * 100) >> 16; dpb_read_compression_factor = FP(integer_part, frac_part, 100); integer_part = d->complexity_factor >> 16; frac_part = ((d->complexity_factor - (integer_part << 16)) * 100) >> 16; motion_vector_complexity = FP(integer_part, frac_part, 100); dpb_write_compression_factor = dpb_read_compression_factor; opb_write_compression_factor = opb_compression_enabled ? dpb_write_compression_factor : FP_ONE; if (d->codec == HAL_VIDEO_CODEC_HEVC || d->codec == HAL_VIDEO_CODEC_VP9) { /* H264, VP8, MPEG2 use the same settings */ /* HEVC, VP9 use the same setting */ is_h264_category = false; } if (d->use_sys_cache) { llc_ref_read_l2_cache_enabled = true; if (is_h264_category) llc_top_line_buf_enabled = true; } /* Derived parameters setup */ lcu_per_frame = DIV_ROUND_UP(width, lcu_size) * DIV_ROUND_UP(height, lcu_size); bitrate = (d->bitrate + 1000000 - 1) / 1000000; bins_to_bit_factor = FP_INT(4); vsp_write_factor = bins_to_bit_factor; vsp_read_factor = bins_to_bit_factor + FP_INT(2); collocated_bytes_per_lcu = lcu_size == 16 ? 16 : lcu_size == 32 ? 64 : 256; dpb_factor = FP(1, 50, 100); dpb_write_factor = FP(1, 5, 100); tnbr_per_lcu = lcu_size == 16 ? 128 : lcu_size == 32 ? 64 : 128; /* .... For DDR & LLC ...... */ ddr.vsp_read = fp_div(fp_mult(FP_INT(bitrate), vsp_read_factor), FP_INT(8)); ddr.vsp_write = fp_div(fp_mult(FP_INT(bitrate), vsp_write_factor), FP_INT(8)); ddr.collocated_read = fp_div(FP_INT(lcu_per_frame * collocated_bytes_per_lcu * fps), FP_INT(bps(1))); ddr.collocated_write = ddr.collocated_read; y_bw_no_ubwc_8bpp = fp_div(fp_mult( FP_INT((int)(width * height)), FP_INT((int)fps)), FP_INT(1000 * 1000)); y_bw_no_ubwc_10bpp = fp_div(fp_mult(y_bw_no_ubwc_8bpp, FP_INT(256)), FP_INT(192)); y_bw_10bpp_p010 = y_bw_no_ubwc_8bpp * 2; ddr.dpb_read = dpb_bpp == 8 ? y_bw_no_ubwc_8bpp : y_bw_no_ubwc_10bpp; ddr.dpb_read = fp_div(fp_mult(ddr.dpb_read, fp_mult(dpb_factor, motion_vector_complexity)), dpb_read_compression_factor); ddr.dpb_write = dpb_bpp == 8 ? y_bw_no_ubwc_8bpp : y_bw_no_ubwc_10bpp; ddr.dpb_write = fp_div(fp_mult(ddr.dpb_write, fp_mult(dpb_factor, dpb_write_factor)), dpb_write_compression_factor); dpb_total = ddr.dpb_read + ddr.dpb_write; if (llc_ref_read_l2_cache_enabled) { ddr.dpb_read = fp_div(ddr.dpb_read, is_h264_category ? FP(1, 15, 100) : FP(1, 30, 100)); llc.dpb_read = dpb_total - ddr.dpb_write - ddr.dpb_read; } ddr.opb_read = FP_ZERO; ddr.opb_write = unified_dpb_opb ? FP_ZERO : (dpb_bpp == 8 ? y_bw_no_ubwc_8bpp : (opb_compression_enabled ? y_bw_no_ubwc_10bpp : y_bw_10bpp_p010)); ddr.opb_write = fp_div(fp_mult(dpb_factor, ddr.opb_write), fp_mult(dpb_opb_scaling_ratio, opb_write_compression_factor)); ddr.line_buffer_read = FP_INT(tnbr_per_lcu * lcu_per_frame * fps / bps(1)); ddr.line_buffer_write = ddr.line_buffer_read; if (llc_top_line_buf_enabled) { llc.line_buffer_read = ddr.line_buffer_read; llc.line_buffer_write = ddr.line_buffer_write; ddr.line_buffer_write = ddr.line_buffer_read = FP_ZERO; } ddr.total = ddr.vsp_read + ddr.vsp_write + ddr.collocated_read + ddr.collocated_write + ddr.dpb_read + ddr.dpb_write + ddr.opb_read + ddr.opb_write + ddr.line_buffer_read + ddr.line_buffer_write; qsmmu_bw_overhead_factor = FP(1, 3, 100); ddr.total = fp_mult(ddr.total, qsmmu_bw_overhead_factor); llc.total = llc.dpb_read + llc.line_buffer_read + llc.line_buffer_write + ddr.total; /* Dump all the variables for easier debugging */ if (msm_vidc_debug & VIDC_BUS) { struct dump dump[] = { {"DECODER PARAMETERS", "", DUMP_HEADER_MAGIC}, {"lcu size", "%d", lcu_size}, {"dpb bitdepth", "%d", dpb_bpp}, {"frame rate", "%d", fps}, {"dpb/opb unified", "%d", unified_dpb_opb}, {"dpb/opb downscaling ratio", DUMP_FP_FMT, dpb_opb_scaling_ratio}, {"dpb compression", "%d", dpb_compression_enabled}, {"opb compression", "%d", opb_compression_enabled}, {"dpb read compression factor", DUMP_FP_FMT, dpb_read_compression_factor}, {"dpb write compression factor", DUMP_FP_FMT, dpb_write_compression_factor}, {"frame width", "%d", width}, {"frame height", "%d", height}, {"llc ref read l2 cache enabled", "%d", llc_ref_read_l2_cache_enabled}, {"llc top line buf enabled", "%d", llc_top_line_buf_enabled}, {"DERIVED PARAMETERS (1)", "", DUMP_HEADER_MAGIC}, {"lcus/frame", "%d", lcu_per_frame}, {"bitrate (Mbit/sec)", "%d", bitrate}, {"bins to bit factor", DUMP_FP_FMT, bins_to_bit_factor}, {"dpb write factor", DUMP_FP_FMT, dpb_write_factor}, {"vsp read factor", DUMP_FP_FMT, vsp_read_factor}, {"vsp write factor", DUMP_FP_FMT, vsp_write_factor}, {"tnbr/lcu", "%d", tnbr_per_lcu}, {"collocated bytes/LCU", "%d", collocated_bytes_per_lcu}, {"bw for NV12 8bpc)", DUMP_FP_FMT, y_bw_no_ubwc_8bpp}, {"bw for NV12 10bpc)", DUMP_FP_FMT, y_bw_no_ubwc_10bpp}, {"DERIVED PARAMETERS (2)", "", DUMP_HEADER_MAGIC}, {"mv complexity", DUMP_FP_FMT, motion_vector_complexity}, {"qsmmu_bw_overhead_factor", DUMP_FP_FMT, qsmmu_bw_overhead_factor}, {"INTERMEDIATE DDR B/W", "", DUMP_HEADER_MAGIC}, {"vsp read", DUMP_FP_FMT, ddr.vsp_read}, {"vsp write", DUMP_FP_FMT, ddr.vsp_write}, {"collocated read", DUMP_FP_FMT, ddr.collocated_read}, {"collocated write", DUMP_FP_FMT, ddr.collocated_write}, {"line buffer read", DUMP_FP_FMT, ddr.line_buffer_read}, {"line buffer write", DUMP_FP_FMT, ddr.line_buffer_write}, {"opb read", DUMP_FP_FMT, ddr.opb_read}, {"opb write", DUMP_FP_FMT, ddr.opb_write}, {"dpb read", DUMP_FP_FMT, ddr.dpb_read}, {"dpb write", DUMP_FP_FMT, ddr.dpb_write}, {"dpb total", DUMP_FP_FMT, dpb_total}, {"INTERMEDIATE LLC B/W", "", DUMP_HEADER_MAGIC}, {"llc dpb read", DUMP_FP_FMT, llc.dpb_read}, {"llc line buffer read", DUMP_FP_FMT, llc.line_buffer_read}, {"llc line buffer write", DUMP_FP_FMT, llc.line_buffer_write}, }; __dump(dump, ARRAY_SIZE(dump)); } switch (type) { case DDR: ret = kbps(fp_round(ddr.total)); break; case LLCC: ret = kbps(fp_round(llc.total)); break; default: dprintk(VIDC_ERR, "%s - Unknown type\n", __func__); } return ret; } static unsigned long __calculate_encoder(struct vidc_bus_vote_data *d, enum vidc_bus_type type) { /* * XXX: Don't fool around with any of the hardcoded numbers unless you * know /exactly/ what you're doing. Many of these numbers are * measured heuristics and hardcoded numbers taken from the firmware. */ /* Encoder Parameters */ int width, height, fps, lcu_size, bitrate, lcu_per_frame, collocated_bytes_per_lcu, tnbr_per_lcu, dpb_bpp, original_color_format, vertical_tile_width; bool work_mode_1, original_compression_enabled, low_power, rotation, cropping_or_scaling, b_frames_enabled = false, llc_ref_chroma_cache_enabled = false, llc_top_line_buf_enabled = false, llc_vpss_rot_line_buf_enabled = false; fp_t bins_to_bit_factor, dpb_compression_factor, original_compression_factor, original_compression_factor_y, y_bw_no_ubwc_8bpp, y_bw_no_ubwc_10bpp, y_bw_10bpp_p010, input_compression_factor, downscaling_ratio, ref_y_read_bw_factor, ref_cbcr_read_bw_factor, recon_write_bw_factor, mese_read_factor, total_ref_read_crcb, qsmmu_bw_overhead_factor; fp_t integer_part, frac_part; unsigned long ret = 0; /* Output parameters */ struct { fp_t vsp_read, vsp_write, collocated_read, collocated_write, ref_read_y, ref_read_crcb, ref_write, ref_write_overlap, orig_read, line_buffer_read, line_buffer_write, mese_read, mese_write, total; } ddr = {0}; struct { fp_t ref_read_crcb, line_buffer, total; } llc = {0}; /* Encoder Parameters setup */ rotation = d->rotation; cropping_or_scaling = false; vertical_tile_width = 960; recon_write_bw_factor = FP(1, 8, 100); ref_y_read_bw_factor = FP(1, 30, 100); ref_cbcr_read_bw_factor = FP(1, 50, 100); /* Derived Parameters */ fps = d->fps; width = max(d->output_width, BASELINE_DIMENSIONS.width); height = max(d->output_height, BASELINE_DIMENSIONS.height); downscaling_ratio = fp_div(FP_INT(d->input_width * d->input_height), FP_INT(d->output_width * d->output_height)); downscaling_ratio = max(downscaling_ratio, FP_ONE); bitrate = d->bitrate > 0 ? (d->bitrate + 1000000 - 1) / 1000000 : __lut(width, height, fps)->bitrate; lcu_size = d->lcu_size; lcu_per_frame = DIV_ROUND_UP(width, lcu_size) * DIV_ROUND_UP(height, lcu_size); tnbr_per_lcu = 16; y_bw_no_ubwc_8bpp = fp_div(fp_mult( FP_INT((int)(width * height)), FP_INT(fps)), FP_INT(1000 * 1000)); y_bw_no_ubwc_10bpp = fp_div(fp_mult(y_bw_no_ubwc_8bpp, FP_INT(256)), FP_INT(192)); y_bw_10bpp_p010 = y_bw_no_ubwc_8bpp * 2; b_frames_enabled = d->b_frames_enabled; original_color_format = d->num_formats >= 1 ? d->color_formats[0] : HAL_UNUSED_COLOR; dpb_bpp = d->num_formats >= 1 ? __bpp(d->color_formats[0]) : INT_MAX; original_compression_enabled = __ubwc(original_color_format); work_mode_1 = d->work_mode == HFI_WORKMODE_1; low_power = d->power_mode == VIDC_POWER_LOW; bins_to_bit_factor = FP_INT(4); if (d->use_sys_cache) { llc_ref_chroma_cache_enabled = true; llc_top_line_buf_enabled = true, llc_vpss_rot_line_buf_enabled = true; } /* * Convert Q16 number into Integer and Fractional part upto 2 places. * Ex : 105752 / 65536 = 1.61; 1.61 in Q16 = 105752; * Integer part = 105752 / 65536 = 1; * Reminder = 105752 - 1 * 65536 = 40216; * Fractional part = 40216 * 100 / 65536 = 61; * Now converto to FP(1, 61, 100) for below code. */ integer_part = d->compression_ratio >> 16; frac_part = ((d->compression_ratio - (integer_part * 65536)) * 100) >> 16; dpb_compression_factor = FP(integer_part, frac_part, 100); integer_part = d->input_cr >> 16; frac_part = ((d->input_cr - (integer_part * 65536)) * 100) >> 16; input_compression_factor = FP(integer_part, frac_part, 100); original_compression_factor = original_compression_factor_y = !original_compression_enabled ? FP_ONE : __compression_ratio(__lut(width, height, fps), dpb_bpp); /* use input cr if it is valid (not 1), otherwise use lut */ if (original_compression_enabled && input_compression_factor != FP_ONE) { original_compression_factor = input_compression_factor; /* Luma usually has lower compression factor than Chroma, * input cf is overall cf, add 1.08 factor for Luma cf */ original_compression_factor_y = input_compression_factor > FP(1, 8, 100) ? fp_div(input_compression_factor, FP(1, 8, 100)) : input_compression_factor; } mese_read_factor = fp_div(FP_INT((width * height * fps)/4), original_compression_factor_y); mese_read_factor = fp_div(fp_mult(mese_read_factor, FP(2, 53, 100)), FP_INT(1000 * 1000)); ddr.vsp_read = fp_div(fp_mult(FP_INT(bitrate), bins_to_bit_factor), FP_INT(8)); ddr.vsp_write = ddr.vsp_read + fp_div(FP_INT(bitrate), FP_INT(8)); collocated_bytes_per_lcu = lcu_size == 16 ? 16 : lcu_size == 32 ? 64 : 256; ddr.collocated_read = fp_div(FP_INT(lcu_per_frame * collocated_bytes_per_lcu * fps), FP_INT(bps(1))); ddr.collocated_write = ddr.collocated_read; ddr.ref_read_y = ddr.ref_read_crcb = dpb_bpp == 8 ? y_bw_no_ubwc_8bpp : y_bw_no_ubwc_10bpp; if (width != vertical_tile_width) { ddr.ref_read_y = fp_mult(ddr.ref_read_y, ref_y_read_bw_factor); } ddr.ref_read_y = fp_div(ddr.ref_read_y, dpb_compression_factor); if (b_frames_enabled) ddr.ref_read_y = fp_mult(ddr.ref_read_y, FP_INT(2)); ddr.ref_read_crcb = fp_mult(ddr.ref_read_crcb, FP(0, 50, 100)); ddr.ref_read_crcb = fp_div(ddr.ref_read_crcb, dpb_compression_factor); if (b_frames_enabled) ddr.ref_read_crcb = fp_mult(ddr.ref_read_crcb, FP_INT(2)); if (llc_ref_chroma_cache_enabled) { total_ref_read_crcb = ddr.ref_read_crcb; ddr.ref_read_crcb = fp_div(ddr.ref_read_crcb, ref_cbcr_read_bw_factor); llc.ref_read_crcb = total_ref_read_crcb - ddr.ref_read_crcb; } ddr.ref_write = dpb_bpp == 8 ? y_bw_no_ubwc_8bpp : y_bw_no_ubwc_10bpp; ddr.ref_write = fp_mult(ddr.ref_write, (fp_div(FP(1, 50, 100), dpb_compression_factor))); ddr.ref_write_overlap = fp_div(fp_mult(ddr.ref_write, (recon_write_bw_factor - FP_ONE)), recon_write_bw_factor); ddr.orig_read = dpb_bpp == 8 ? y_bw_no_ubwc_8bpp : (original_compression_enabled ? y_bw_no_ubwc_10bpp : y_bw_10bpp_p010); ddr.orig_read = fp_div(fp_mult(fp_mult(ddr.orig_read, FP(1, 50, 100)), downscaling_ratio), original_compression_factor); if (rotation == 90 || rotation == 270) ddr.orig_read *= lcu_size == 32 ? (dpb_bpp == 8 ? 1 : 3) : 2; ddr.line_buffer_read = FP_INT(tnbr_per_lcu * lcu_per_frame * fps / bps(1)); ddr.line_buffer_write = ddr.line_buffer_read; if (llc_top_line_buf_enabled) { llc.line_buffer = ddr.line_buffer_read + ddr.line_buffer_write; ddr.line_buffer_read = ddr.line_buffer_write = FP_ZERO; } ddr.mese_read = dpb_bpp == 8 ? y_bw_no_ubwc_8bpp : y_bw_no_ubwc_10bpp; ddr.mese_read = fp_div(fp_mult(ddr.mese_read, FP(1, 37, 100)), original_compression_factor_y) + mese_read_factor; ddr.mese_write = FP_INT((width * height)/512) + fp_div(FP_INT((width * height)/4), original_compression_factor_y) + FP_INT((width * height)/128); ddr.mese_write = fp_div(fp_mult(ddr.mese_write, FP_INT(fps)), FP_INT(1000 * 1000)); ddr.total = ddr.vsp_read + ddr.vsp_write + ddr.collocated_read + ddr.collocated_write + ddr.ref_read_y + ddr.ref_read_crcb + ddr.ref_write + ddr.ref_write_overlap + ddr.orig_read + ddr.line_buffer_read + ddr.line_buffer_write + ddr.mese_read + ddr.mese_write; qsmmu_bw_overhead_factor = FP(1, 3, 100); ddr.total = fp_mult(ddr.total, qsmmu_bw_overhead_factor); llc.total = llc.ref_read_crcb + llc.line_buffer + ddr.total; if (msm_vidc_debug & VIDC_BUS) { struct dump dump[] = { {"ENCODER PARAMETERS", "", DUMP_HEADER_MAGIC}, {"width", "%d", width}, {"height", "%d", height}, {"fps", "%d", fps}, {"dpb bitdepth", "%d", dpb_bpp}, {"input downscaling ratio", DUMP_FP_FMT, downscaling_ratio}, {"rotation", "%d", rotation}, {"cropping or scaling", "%d", cropping_or_scaling}, {"low power mode", "%d", low_power}, {"work Mode", "%d", work_mode_1}, {"B frame enabled", "%d", b_frames_enabled}, {"original frame format", "%#x", original_color_format}, {"original compression enabled", "%d", original_compression_enabled}, {"dpb compression factor", DUMP_FP_FMT, dpb_compression_factor}, {"input compression factor", DUMP_FP_FMT, input_compression_factor}, {"llc ref chroma cache enabled", DUMP_FP_FMT, llc_ref_chroma_cache_enabled}, {"llc top line buf enabled", DUMP_FP_FMT, llc_top_line_buf_enabled}, {"llc vpss rot line buf enabled ", DUMP_FP_FMT, llc_vpss_rot_line_buf_enabled}, {"DERIVED PARAMETERS", "", DUMP_HEADER_MAGIC}, {"lcu size", "%d", lcu_size}, {"bitrate (Mbit/sec)", "%lu", bitrate}, {"bins to bit factor", DUMP_FP_FMT, bins_to_bit_factor}, {"original compression factor", DUMP_FP_FMT, original_compression_factor}, {"original compression factor y", DUMP_FP_FMT, original_compression_factor_y}, {"mese read factor", DUMP_FP_FMT, mese_read_factor}, {"qsmmu_bw_overhead_factor", DUMP_FP_FMT, qsmmu_bw_overhead_factor}, {"bw for NV12 8bpc)", DUMP_FP_FMT, y_bw_no_ubwc_8bpp}, {"bw for NV12 10bpc)", DUMP_FP_FMT, y_bw_no_ubwc_10bpp}, {"INTERMEDIATE B/W DDR", "", DUMP_HEADER_MAGIC}, {"vsp read", DUMP_FP_FMT, ddr.vsp_read}, {"vsp write", DUMP_FP_FMT, ddr.vsp_write}, {"collocated read", DUMP_FP_FMT, ddr.collocated_read}, {"collocated write", DUMP_FP_FMT, ddr.collocated_write}, {"ref read y", DUMP_FP_FMT, ddr.ref_read_y}, {"ref read crcb", DUMP_FP_FMT, ddr.ref_read_crcb}, {"ref write", DUMP_FP_FMT, ddr.ref_write}, {"ref write overlap", DUMP_FP_FMT, ddr.ref_write_overlap}, {"original read", DUMP_FP_FMT, ddr.orig_read}, {"line buffer read", DUMP_FP_FMT, ddr.line_buffer_read}, {"line buffer write", DUMP_FP_FMT, ddr.line_buffer_write}, {"mese read", DUMP_FP_FMT, ddr.mese_read}, {"mese write", DUMP_FP_FMT, ddr.mese_write}, {"INTERMEDIATE LLC B/W", "", DUMP_HEADER_MAGIC}, {"llc ref read crcb", DUMP_FP_FMT, llc.ref_read_crcb}, {"llc line buffer", DUMP_FP_FMT, llc.line_buffer}, }; __dump(dump, ARRAY_SIZE(dump)); } switch (type) { case DDR: ret = kbps(fp_round(ddr.total)); break; case LLCC: ret = kbps(fp_round(llc.total)); break; default: dprintk(VIDC_ERR, "%s - Unknown type\n", __func__); } return ret; } static unsigned long __calculate(struct vidc_bus_vote_data *d, enum vidc_bus_type type) { unsigned long value = 0; switch (d->domain) { case HAL_VIDEO_DOMAIN_VPE: value = __calculate_vpe(d, type); break; case HAL_VIDEO_DOMAIN_ENCODER: value = __calculate_encoder(d, type); break; case HAL_VIDEO_DOMAIN_DECODER: value = __calculate_decoder(d, type); break; case HAL_VIDEO_DOMAIN_CVP: value = __calculate_cvp(d, type); break; default: dprintk(VIDC_ERR, "Unknown Domain"); } return value; } unsigned long calc_bw_iris1(struct bus_info *bus, struct msm_vidc_bus_data *vidc_data) { unsigned long ab_kbps = 0, c = 0; enum vidc_bus_type type; if (!vidc_data || !vidc_data->data_count || !vidc_data->data) goto exit; for (c = 0; c < vidc_data->data_count; ++c) { if (vidc_data->data->power_mode == VIDC_POWER_TURBO) { ab_kbps = INT_MAX; goto exit; } } type = get_type_frm_name(bus->name); for (c = 0; c < vidc_data->data_count; ++c) ab_kbps += __calculate(&vidc_data->data[c], type); exit: trace_msm_vidc_perf_bus_vote(bus->name, ab_kbps); return ab_kbps; }