/* * Copyright (c) 2016-2017, The Linux Foundation. All rights reserved. * * Redistribution and use in source and binary forms, with or without modification, are permitted * provided that the following conditions are met: * * Redistributions of source code must retain the above copyright notice, this list of * conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright notice, this list of * conditions and the following disclaimer in the documentation and/or other materials provided * with the distribution. * * Neither the name of The Linux Foundation nor the names of its contributors may be used to * endorse or promote products derived from this software without specific prior written * permission. * * THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NON-INFRINGEMENT ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include #include #include "hw_scale.h" #define __CLASS__ "HWScale" namespace sdm { DisplayError HWScale::Create(HWScale **intf, bool has_qseed3) { if (has_qseed3) { *intf = new HWScaleV2(); } else { *intf = new HWScaleV1(); } return kErrorNone; } DisplayError HWScale::Destroy(HWScale *intf) { delete intf; return kErrorNone; } void HWScaleV1::SetHWScaleData(const HWScaleData &scale_data, uint32_t index, mdp_layer_commit_v1 *mdp_commit, HWSubBlockType sub_block_type) { if (!scale_data.enable.scale) { return; } if (sub_block_type == kHWDestinationScalar) { return; } mdp_input_layer *mdp_layer = &mdp_commit->input_layers[index]; mdp_layer->flags |= MDP_LAYER_ENABLE_PIXEL_EXT; mdp_scale_data *mdp_scale = &scale_data_v1_.at(index); mdp_scale->enable_pxl_ext = scale_data.enable.scale; for (int i = 0; i < MAX_PLANES; i++) { const HWPlane &plane = scale_data.plane[i]; mdp_scale->init_phase_x[i] = plane.init_phase_x; mdp_scale->phase_step_x[i] = plane.phase_step_x; mdp_scale->init_phase_y[i] = plane.init_phase_y; mdp_scale->phase_step_y[i] = plane.phase_step_y; mdp_scale->num_ext_pxls_left[i] = plane.left.extension; mdp_scale->left_ftch[i] = plane.left.overfetch; mdp_scale->left_rpt[i] = plane.left.repeat; mdp_scale->num_ext_pxls_top[i] = plane.top.extension; mdp_scale->top_ftch[i] = plane.top.overfetch; mdp_scale->top_rpt[i] = plane.top.repeat; mdp_scale->num_ext_pxls_right[i] = plane.right.extension; mdp_scale->right_ftch[i] = plane.right.overfetch; mdp_scale->right_rpt[i] = plane.right.repeat; mdp_scale->num_ext_pxls_btm[i] = plane.bottom.extension; mdp_scale->btm_ftch[i] = plane.bottom.overfetch; mdp_scale->btm_rpt[i] = plane.bottom.repeat; mdp_scale->roi_w[i] = plane.roi_width; } return; } void* HWScaleV1::GetScaleDataRef(uint32_t index, HWSubBlockType sub_block_type) { if (sub_block_type != kHWDestinationScalar) { return &scale_data_v1_.at(index); } return NULL; } void HWScaleV1::DumpScaleData(void *mdp_scale) { if (!mdp_scale) { return; } mdp_scale_data *scale = reinterpret_cast(mdp_scale); if (scale->enable_pxl_ext) { DLOGD_IF(kTagDriverConfig, "Scale Enable = %d", scale->enable_pxl_ext); for (int j = 0; j < MAX_PLANES; j++) { DLOGV_IF(kTagDriverConfig, "Scale Data[%d] : Phase=[%x %x %x %x] Pixel_Ext=[%d %d %d %d]", j, scale->init_phase_x[j], scale->phase_step_x[j], scale->init_phase_y[j], scale->phase_step_y[j], scale->num_ext_pxls_left[j], scale->num_ext_pxls_top[j], scale->num_ext_pxls_right[j], scale->num_ext_pxls_btm[j]); DLOGV_IF(kTagDriverConfig, "Fetch=[%d %d %d %d] Repeat=[%d %d %d %d] roi_width = %d", scale->left_ftch[j], scale->top_ftch[j], scale->right_ftch[j], scale->btm_ftch[j], scale->left_rpt[j], scale->top_rpt[j], scale->right_rpt[j], scale->btm_rpt[j], scale->roi_w[j]); } } return; } void HWScaleV2::SetHWScaleData(const HWScaleData &scale_data, uint32_t index, mdp_layer_commit_v1 *mdp_commit, HWSubBlockType sub_block_type) { if (!scale_data.enable.scale && !scale_data.enable.direction_detection && !scale_data.enable.detail_enhance ) { return; } mdp_scale_data_v2 *mdp_scale; if (sub_block_type != kHWDestinationScalar) { mdp_input_layer *mdp_layer = &mdp_commit->input_layers[index]; mdp_layer->flags |= MDP_LAYER_ENABLE_QSEED3_SCALE; mdp_scale = &scale_data_v2_.at(index); } else { mdp_scale_data_v2 mdp_dest_scale = {0}; dest_scale_data_v2_.insert(std::make_pair(index, mdp_dest_scale)); mdp_scale = &dest_scale_data_v2_[index]; } mdp_scale->enable = (scale_data.enable.scale ? ENABLE_SCALE : 0) | (scale_data.enable.direction_detection ? ENABLE_DIRECTION_DETECTION : 0) | (scale_data.enable.detail_enhance ? ENABLE_DETAIL_ENHANCE : 0); if (sub_block_type == kHWDestinationScalar) { mdp_destination_scaler_data *mdp_dest_scalar = reinterpret_cast(mdp_commit->dest_scaler); mdp_dest_scalar[index].flags = mdp_scale->enable ? MDP_DESTSCALER_ENABLE : 0; if (scale_data.enable.detail_enhance) { mdp_dest_scalar[index].flags |= MDP_DESTSCALER_ENHANCER_UPDATE; } } for (int i = 0; i < MAX_PLANES; i++) { const HWPlane &plane = scale_data.plane[i]; mdp_scale->init_phase_x[i] = plane.init_phase_x; mdp_scale->phase_step_x[i] = plane.phase_step_x; mdp_scale->init_phase_y[i] = plane.init_phase_y; mdp_scale->phase_step_y[i] = plane.phase_step_y; mdp_scale->num_ext_pxls_left[i] = UINT32(plane.left.extension); mdp_scale->left_ftch[i] = plane.left.overfetch; mdp_scale->left_rpt[i] = plane.left.repeat; mdp_scale->num_ext_pxls_top[i] = UINT32(plane.top.extension); mdp_scale->top_ftch[i] = UINT32(plane.top.overfetch); mdp_scale->top_rpt[i] = UINT32(plane.top.repeat); mdp_scale->num_ext_pxls_right[i] = UINT32(plane.right.extension); mdp_scale->right_ftch[i] = plane.right.overfetch; mdp_scale->right_rpt[i] = plane.right.repeat; mdp_scale->num_ext_pxls_btm[i] = UINT32(plane.bottom.extension); mdp_scale->btm_ftch[i] = UINT32(plane.bottom.overfetch); mdp_scale->btm_rpt[i] = UINT32(plane.bottom.repeat); mdp_scale->roi_w[i] = plane.roi_width; mdp_scale->preload_x[i] = UINT32(plane.preload_x); mdp_scale->preload_y[i] = UINT32(plane.preload_y); mdp_scale->src_width[i] = plane.src_width; mdp_scale->src_height[i] = plane.src_height; } mdp_scale->dst_width = scale_data.dst_width; mdp_scale->dst_height = scale_data.dst_height; mdp_scale->y_rgb_filter_cfg = GetMDPScalingFilter(scale_data.y_rgb_filter_cfg); mdp_scale->uv_filter_cfg = GetMDPScalingFilter(scale_data.uv_filter_cfg); mdp_scale->alpha_filter_cfg = GetMDPAlphaInterpolation(scale_data.alpha_filter_cfg); mdp_scale->blend_cfg = scale_data.blend_cfg; mdp_scale->lut_flag = (scale_data.lut_flag.lut_swap ? SCALER_LUT_SWAP : 0) | (scale_data.lut_flag.lut_dir_wr ? SCALER_LUT_DIR_WR : 0) | (scale_data.lut_flag.lut_y_cir_wr ? SCALER_LUT_Y_CIR_WR : 0) | (scale_data.lut_flag.lut_uv_cir_wr ? SCALER_LUT_UV_CIR_WR : 0) | (scale_data.lut_flag.lut_y_sep_wr ? SCALER_LUT_Y_SEP_WR : 0) | (scale_data.lut_flag.lut_uv_sep_wr ? SCALER_LUT_UV_SEP_WR : 0); mdp_scale->dir_lut_idx = scale_data.dir_lut_idx; mdp_scale->y_rgb_cir_lut_idx = scale_data.y_rgb_cir_lut_idx; mdp_scale->uv_cir_lut_idx = scale_data.uv_cir_lut_idx; mdp_scale->y_rgb_sep_lut_idx = scale_data.y_rgb_sep_lut_idx; mdp_scale->uv_sep_lut_idx = scale_data.uv_sep_lut_idx; if (mdp_scale->enable & ENABLE_DETAIL_ENHANCE) { mdp_det_enhance_data *mdp_det_enhance = &mdp_scale->detail_enhance; mdp_det_enhance->enable = scale_data.detail_enhance.enable; mdp_det_enhance->sharpen_level1 = scale_data.detail_enhance.sharpen_level1; mdp_det_enhance->sharpen_level2 = scale_data.detail_enhance.sharpen_level2; mdp_det_enhance->clip = scale_data.detail_enhance.clip; mdp_det_enhance->limit = scale_data.detail_enhance.limit; mdp_det_enhance->thr_quiet = scale_data.detail_enhance.thr_quiet; mdp_det_enhance->thr_dieout = scale_data.detail_enhance.thr_dieout; mdp_det_enhance->thr_low = scale_data.detail_enhance.thr_low; mdp_det_enhance->thr_high = scale_data.detail_enhance.thr_high; mdp_det_enhance->prec_shift = scale_data.detail_enhance.prec_shift; for (int i = 0; i < MAX_DET_CURVES; i++) { mdp_det_enhance->adjust_a[i] = scale_data.detail_enhance.adjust_a[i]; mdp_det_enhance->adjust_b[i] = scale_data.detail_enhance.adjust_b[i]; mdp_det_enhance->adjust_c[i] = scale_data.detail_enhance.adjust_c[i]; } } return; } void* HWScaleV2::GetScaleDataRef(uint32_t index, HWSubBlockType sub_block_type) { if (sub_block_type != kHWDestinationScalar) { return &scale_data_v2_.at(index); } else { return &dest_scale_data_v2_[index]; } } uint32_t HWScaleV2::GetMDPScalingFilter(ScalingFilterConfig filter_cfg) { switch (filter_cfg) { case kFilterEdgeDirected: return FILTER_EDGE_DIRECTED_2D; case kFilterCircular: return FILTER_CIRCULAR_2D; case kFilterSeparable: return FILTER_SEPARABLE_1D; case kFilterBilinear: return FILTER_BILINEAR; default: DLOGE("Invalid Scaling Filter"); return kFilterMax; } } uint32_t HWScaleV2::GetMDPAlphaInterpolation(HWAlphaInterpolation alpha_filter_cfg) { switch (alpha_filter_cfg) { case kInterpolationPixelRepeat: return FILTER_ALPHA_DROP_REPEAT; case kInterpolationBilinear: return FILTER_ALPHA_BILINEAR; default: DLOGE("Invalid Alpha Interpolation"); return kInterpolationMax; } } void HWScaleV2::DumpScaleData(void *mdp_scale) { if (!mdp_scale) { return; } mdp_scale_data_v2 *scale = reinterpret_cast(mdp_scale); if (scale->enable) { DLOGD_IF(kTagDriverConfig, "Scale Enable = %d", scale->enable); for (int j = 0; j < MAX_PLANES; j++) { DLOGV_IF(kTagDriverConfig, "Scale Data[%d]: Phase_init[x y]=[%x %x] Phase_step:[x y]=[%x %x]", j, scale->init_phase_x[j], scale->init_phase_y[j], scale->phase_step_x[j], scale->phase_step_y[j]); DLOGV_IF(kTagDriverConfig, "Preload[x y]=[%x %x], Pixel Ext=[%d %d] Ovfetch=[%d %d %d %d]", scale->preload_x[j], scale->preload_y[j], scale->num_ext_pxls_left[j], scale->num_ext_pxls_top[j], scale->left_ftch[j], scale->top_ftch[j], scale->right_ftch[j], scale->btm_ftch[j]); DLOGV_IF(kTagDriverConfig, "Repeat=[%d %d %d %d] Src[w x h]=[%d %d] roi_width = %d", scale->left_rpt[j], scale->top_rpt[j], scale->right_rpt[j], scale->btm_rpt[j], scale->src_width[j], scale->src_height[j], scale->roi_w[j]); } DLOGD_IF(kTagDriverConfig, "LUT flags = %d", scale->lut_flag); DLOGV_IF(kTagDriverConfig, "y_rgb_filter=%d, uv_filter=%d, alpha_filter=%d, blend_cfg=%d", scale->y_rgb_filter_cfg, scale->uv_filter_cfg, scale->alpha_filter_cfg, scale->blend_cfg); DLOGV_IF(kTagDriverConfig, "dir_lut=%d, y_rgb_cir=%d, uv_cir=%d, y_rgb_sep=%d, uv_sep=%d", scale->dir_lut_idx, scale->y_rgb_cir_lut_idx, scale->uv_cir_lut_idx, scale->y_rgb_sep_lut_idx, scale->uv_sep_lut_idx); if (scale->enable & ENABLE_DETAIL_ENHANCE) { mdp_det_enhance_data *de = &scale->detail_enhance; DLOGV_IF(kTagDriverConfig, "Detail Enhance: enable: %d sharpen_level1: %d sharpen_level2: %d", de->enable, de->sharpen_level1, de->sharpen_level2); DLOGV_IF(kTagDriverConfig, "clip: %d limit:%d thr_quiet: %d thr_dieout: %d", de->clip, de->limit, de->thr_quiet, de->thr_dieout); DLOGV_IF(kTagDriverConfig, "thr_low: %d thr_high: %d prec_shift: %d", de->thr_low, de->thr_high, de->prec_shift); for (uint32_t i = 0; i < MAX_DET_CURVES; i++) { DLOGV_IF(kTagDriverConfig, "adjust_a[%d]: %d adjust_b[%d]: %d adjust_c[%d]: %d", i, de->adjust_a[i], i, de->adjust_b[i], i, de->adjust_c[i]); } } } return; } } // namespace sdm