/* * Copyright (c) 2015 - 2018, 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 #include #include #include #include #include #include #include #include #include #include #include #include "hw_hdmi.h" #define __CLASS__ "HWHDMI" #define MIN_HDR_RESET_WAITTIME_SEC 2 namespace sdm { #ifdef MDP_HDR_STREAM static int32_t GetEOTF(const GammaTransfer &transfer) { int32_t mdp_transfer = -1; switch (transfer) { case Transfer_SMPTE_ST2084: mdp_transfer = MDP_HDR_EOTF_SMTPE_ST2084; break; case Transfer_HLG: mdp_transfer = MDP_HDR_EOTF_HLG; break; default: DLOGW("Unknown Transfer: %d", transfer); } return mdp_transfer; } static int32_t GetColoriMetry(const LayerBuffer & layer_buffer) { bool is_yuv = layer_buffer.flags.video; int32_t colorimetry = -1; if (is_yuv) { switch (layer_buffer.color_metadata.colorPrimaries) { case ColorPrimaries_BT601_6_525: case ColorPrimaries_BT601_6_625: colorimetry = MDP_COLORIMETRY_YCBCR_ITU_R_BT_601; break; case ColorPrimaries_BT709_5: colorimetry = MDP_COLORIMETRY_YCBCR_ITU_R_BT_709; break; case ColorPrimaries_BT2020: colorimetry = MDP_COLORIMETRY_YCBCR_ITU_R_BT_2020_YCBCR; break; default: DLOGW("Unknown color primary = %d for YUV", layer_buffer.color_metadata.colorPrimaries); } } return colorimetry; } static int32_t GetPixelEncoding(const LayerBuffer &layer_buffer) { bool is_yuv = layer_buffer.flags.video; int32_t mdp_pixel_encoding = -1; mdp_pixel_encoding = MDP_PIXEL_ENCODING_RGB; // set RGB as default if (is_yuv) { switch (layer_buffer.format) { case kFormatYCbCr420SemiPlanarVenus: case kFormatYCbCr420SPVenusUbwc: case kFormatYCbCr420Planar: case kFormatYCrCb420Planar: case kFormatYCrCb420PlanarStride16: case kFormatYCbCr420SemiPlanar: case kFormatYCrCb420SemiPlanar: case kFormatYCbCr420P010: case kFormatYCbCr420TP10Ubwc: mdp_pixel_encoding = MDP_PIXEL_ENCODING_YCBCR_420; break; case kFormatYCbCr422H2V1Packed: case kFormatYCrCb422H2V1SemiPlanar: case kFormatYCrCb422H1V2SemiPlanar: case kFormatYCbCr422H2V1SemiPlanar: case kFormatYCbCr422H1V2SemiPlanar: mdp_pixel_encoding = MDP_PIXEL_ENCODING_YCBCR_422; break; default: // other yuv formats DLOGW("New YUV format = %d, need to add support", layer_buffer.format); break; } } return mdp_pixel_encoding; } static int32_t GetBitsPerComponent(const LayerBuffer &layer_buffer) { bool is_yuv = layer_buffer.flags.video; bool is_10_bit = Is10BitFormat(layer_buffer.format); int32_t mdp_bpc = -1; if (is_yuv) { mdp_bpc = is_10_bit ? MDP_YUV_10_BPC : MDP_YUV_8_BPC; } else { mdp_bpc = is_10_bit ? MDP_RGB_10_BPC : MDP_RGB_8_BPC; } return mdp_bpc; } static uint32_t GetRange(const ColorRange &range) { return ((range == Range_Full) ? MDP_DYNAMIC_RANGE_VESA : MDP_DYNAMIC_RANGE_CEA); } static uint32_t GetContentType(const LayerBuffer &layer_buffer) { return (layer_buffer.flags.video ? MDP_CONTENT_TYPE_VIDEO : MDP_CONTENT_TYPE_GRAPHICS); } #endif static bool MapHDMIDisplayTiming(const msm_hdmi_mode_timing_info *mode, fb_var_screeninfo *info) { if (!mode || !info) { return false; } info->reserved[0] = 0; info->reserved[1] = 0; info->reserved[2] = 0; info->reserved[3] = (info->reserved[3] & 0xFFFF) | (mode->video_format << 16); info->xoffset = 0; info->yoffset = 0; info->xres = mode->active_h; info->yres = mode->active_v; info->pixclock = (mode->pixel_freq) * 1000; info->vmode = mode->interlaced ? FB_VMODE_INTERLACED : FB_VMODE_NONINTERLACED; info->right_margin = mode->front_porch_h; info->hsync_len = mode->pulse_width_h; info->left_margin = mode->back_porch_h; info->lower_margin = mode->front_porch_v; info->vsync_len = mode->pulse_width_v; info->upper_margin = mode->back_porch_v; info->grayscale = V4L2_PIX_FMT_RGB24; // If the mode supports YUV420 set grayscale to the FOURCC value for YUV420. std::bitset<32> pixel_formats = mode->pixel_formats; if (pixel_formats[1]) { info->grayscale = V4L2_PIX_FMT_NV12; } return true; } HWHDMI::HWHDMI(BufferSyncHandler *buffer_sync_handler, HWInfoInterface *hw_info_intf) : HWDevice(buffer_sync_handler), hw_scan_info_(), active_config_index_(0) { HWDevice::device_type_ = kDevicePluggable; HWDevice::device_name_ = "Pluggable Display Device"; HWDevice::hw_info_intf_ = hw_info_intf; (void)hdr_reset_start_; (void)hdr_reset_end_; (void)reset_hdr_flag_; (void)cdm_color_space_; } DisplayError HWHDMI::Init() { DisplayError error = kErrorNone; SetSourceProductInformation("vendor_name", "ro.product.manufacturer"); SetSourceProductInformation("product_description", "ro.product.name"); error = HWDevice::Init(); if (error != kErrorNone) { return error; } mdp_dest_scalar_data_.resize(hw_resource_.hw_dest_scalar_info.count); error = ReadEDIDInfo(); if (error != kErrorNone) { Deinit(); return error; } if (!IsResolutionFilePresent()) { Deinit(); return kErrorHardware; } error = ReadTimingInfo(); if (error != kErrorNone) { Deinit(); return error; } ReadScanInfo(); GetPanelS3DMode(); error = SetDisplayAttributes(active_config_index_); if (error != kErrorNone) { Deinit(); return error; } s3d_mode_sdm_to_mdp_.insert(std::pair (kS3DModeNone, HDMI_S3D_NONE)); s3d_mode_sdm_to_mdp_.insert(std::pair (kS3DModeLR, HDMI_S3D_SIDE_BY_SIDE)); s3d_mode_sdm_to_mdp_.insert(std::pair (kS3DModeRL, HDMI_S3D_SIDE_BY_SIDE)); s3d_mode_sdm_to_mdp_.insert(std::pair (kS3DModeTB, HDMI_S3D_TOP_AND_BOTTOM)); s3d_mode_sdm_to_mdp_.insert(std::pair (kS3DModeFP, HDMI_S3D_FRAME_PACKING)); return error; } DisplayError HWHDMI::GetNumDisplayAttributes(uint32_t *count) { *count = UINT32(hdmi_modes_.size()); if (*count <= 0) { return kErrorHardware; } return kErrorNone; } DisplayError HWHDMI::GetActiveConfig(uint32_t *active_config_index) { *active_config_index = active_config_index_; return kErrorNone; } DisplayError HWHDMI::ReadEDIDInfo() { ssize_t length = -1; char edid_str[kPageSize] = {'\0'}; char edid_path[kMaxStringLength] = {'\0'}; snprintf(edid_path, sizeof(edid_path), "%s%d/edid_modes", fb_path_, fb_node_index_); int edid_file = Sys::open_(edid_path, O_RDONLY); if (edid_file < 0) { DLOGE("EDID file open failed."); return kErrorHardware; } length = Sys::pread_(edid_file, edid_str, sizeof(edid_str)-1, 0); if (length <= 0) { DLOGE("%s: edid_modes file empty"); return kErrorHardware; } Sys::close_(edid_file); DLOGI("EDID mode string: %s", edid_str); while (length > 1 && isspace(edid_str[length-1])) { --length; } edid_str[length] = '\0'; if (length > 0) { // Get EDID modes from the EDID string char *ptr = edid_str; const uint32_t edid_count_max = 128; char *tokens[edid_count_max] = { NULL }; uint32_t hdmi_mode_count = 0; ParseLine(ptr, tokens, edid_count_max, &hdmi_mode_count); supported_video_modes_.resize(hdmi_mode_count); hdmi_modes_.resize(hdmi_mode_count); for (uint32_t i = 0; i < hdmi_mode_count; i++) { hdmi_modes_[i] = UINT32(atoi(tokens[i])); } } return kErrorNone; } DisplayError HWHDMI::GetDisplayAttributes(uint32_t index, HWDisplayAttributes *display_attributes) { DTRACE_SCOPED(); if (index >= hdmi_modes_.size()) { return kErrorNotSupported; } // Get the resolution info from the look up table msm_hdmi_mode_timing_info *timing_mode = &supported_video_modes_[0]; for (uint32_t i = 0; i < hdmi_modes_.size(); i++) { msm_hdmi_mode_timing_info *cur = &supported_video_modes_[i]; if (cur->video_format == hdmi_modes_[index]) { timing_mode = cur; break; } } display_attributes->x_pixels = timing_mode->active_h; display_attributes->y_pixels = timing_mode->active_v; display_attributes->v_front_porch = timing_mode->front_porch_v; display_attributes->v_back_porch = timing_mode->back_porch_v; display_attributes->v_pulse_width = timing_mode->pulse_width_v; uint32_t h_blanking = timing_mode->front_porch_h + timing_mode->back_porch_h + timing_mode->pulse_width_h; display_attributes->h_total = timing_mode->active_h + h_blanking; display_attributes->x_dpi = 0; display_attributes->y_dpi = 0; display_attributes->fps = timing_mode->refresh_rate / 1000; display_attributes->vsync_period_ns = UINT32(1000000000L / display_attributes->fps); display_attributes->is_device_split = false; if (display_attributes->x_pixels > hw_resource_.max_mixer_width) { display_attributes->is_device_split = true; display_attributes->h_total += h_blanking; } GetDisplayS3DSupport(index, display_attributes); std::bitset<32> pixel_formats = timing_mode->pixel_formats; display_attributes->is_yuv = pixel_formats[1]; return kErrorNone; } DisplayError HWHDMI::SetDisplayAttributes(uint32_t index) { DTRACE_SCOPED(); if (index > hdmi_modes_.size()) { return kErrorNotSupported; } // Variable screen info fb_var_screeninfo vscreeninfo = {}; if (Sys::ioctl_(device_fd_, FBIOGET_VSCREENINFO, &vscreeninfo) < 0) { IOCTL_LOGE(FBIOGET_VSCREENINFO, device_type_); return kErrorHardware; } DLOGI("GetInfo", vscreeninfo.reserved[3], vscreeninfo.xres, vscreeninfo.yres, vscreeninfo.right_margin, vscreeninfo.hsync_len, vscreeninfo.left_margin, vscreeninfo.lower_margin, vscreeninfo.vsync_len, vscreeninfo.upper_margin, vscreeninfo.pixclock/1000000); msm_hdmi_mode_timing_info *timing_mode = &supported_video_modes_[0]; for (uint32_t i = 0; i < hdmi_modes_.size(); i++) { msm_hdmi_mode_timing_info *cur = &supported_video_modes_[i]; if (cur->video_format == hdmi_modes_[index]) { timing_mode = cur; break; } } if (MapHDMIDisplayTiming(timing_mode, &vscreeninfo) == false) { return kErrorParameters; } msmfb_metadata metadata = {}; metadata.op = metadata_op_vic; metadata.data.video_info_code = timing_mode->video_format; if (Sys::ioctl_(device_fd_, MSMFB_METADATA_SET, &metadata) < 0) { IOCTL_LOGE(MSMFB_METADATA_SET, device_type_); return kErrorHardware; } DLOGI("SetInfo", vscreeninfo.reserved[3] & 0xFF00, vscreeninfo.xres, vscreeninfo.yres, vscreeninfo.right_margin, vscreeninfo.hsync_len, vscreeninfo.left_margin, vscreeninfo.lower_margin, vscreeninfo.vsync_len, vscreeninfo.upper_margin, vscreeninfo.pixclock/1000000); vscreeninfo.activate = FB_ACTIVATE_NOW | FB_ACTIVATE_ALL | FB_ACTIVATE_FORCE; if (Sys::ioctl_(device_fd_, FBIOPUT_VSCREENINFO, &vscreeninfo) < 0) { IOCTL_LOGE(FBIOPUT_VSCREENINFO, device_type_); return kErrorHardware; } active_config_index_ = index; frame_rate_ = timing_mode->refresh_rate; // Get the display attributes for current active config index GetDisplayAttributes(active_config_index_, &display_attributes_); UpdateMixerAttributes(); supported_s3d_modes_.clear(); supported_s3d_modes_.push_back(kS3DModeNone); for (uint32_t mode = kS3DModeNone + 1; mode < kS3DModeMax; mode ++) { if (display_attributes_.s3d_config[(HWS3DMode)mode]) { supported_s3d_modes_.push_back((HWS3DMode)mode); } } SetS3DMode(kS3DModeNone); return kErrorNone; } DisplayError HWHDMI::GetConfigIndex(char *mode, uint32_t *index) { std::string str(mode); uint32_t value = UINT32(stoi(str)); // Check if the mode is valid and return corresponding index for (uint32_t i = 0; i < hdmi_modes_.size(); i++) { if (hdmi_modes_[i] == value) { *index = i; DLOGI("Index = %d for config = %d", *index, value); return kErrorNone; } } DLOGE("Config = %d not supported", value); return kErrorNotSupported; } DisplayError HWHDMI::Validate(HWLayers *hw_layers) { HWDevice::ResetDisplayParams(); return HWDevice::Validate(hw_layers); } DisplayError HWHDMI::Commit(HWLayers *hw_layers) { DisplayError error = UpdateHDRMetaData(hw_layers); if (error != kErrorNone) { return error; } if (cdm_color_space_commit_) { #ifdef MDP_COMMIT_UPDATE_CDM_COLOR_SPACE mdp_layer_commit_v1 &mdp_commit = mdp_disp_commit_.commit_v1; mdp_commit.cdm_color_space = cdm_color_space_; mdp_commit.flags |= MDP_COMMIT_UPDATE_CDM_COLOR_SPACE; #endif } error = HWDevice::Commit(hw_layers); if (cdm_color_space_commit_) cdm_color_space_commit_ = false; return error; } DisplayError HWHDMI::GetHWScanInfo(HWScanInfo *scan_info) { if (!scan_info) { return kErrorParameters; } *scan_info = hw_scan_info_; return kErrorNone; } DisplayError HWHDMI::GetVideoFormat(uint32_t config_index, uint32_t *video_format) { if (config_index > hdmi_modes_.size()) { return kErrorNotSupported; } *video_format = hdmi_modes_[config_index]; return kErrorNone; } DisplayError HWHDMI::GetMaxCEAFormat(uint32_t *max_cea_format) { *max_cea_format = HDMI_VFRMT_END; return kErrorNone; } DisplayError HWHDMI::OnMinHdcpEncryptionLevelChange(uint32_t min_enc_level) { DisplayError error = kErrorNone; int fd = -1; char data[kMaxStringLength] = {'\0'}; snprintf(data, sizeof(data), "%s%d/hdcp2p2/min_level_change", fb_path_, fb_node_index_); fd = Sys::open_(data, O_WRONLY); if (fd < 0) { DLOGW("File '%s' could not be opened.", data); return kErrorHardware; } snprintf(data, sizeof(data), "%d", min_enc_level); ssize_t err = Sys::pwrite_(fd, data, strlen(data), 0); if (err <= 0) { DLOGE("Write failed, Error = %s", strerror(errno)); error = kErrorHardware; } Sys::close_(fd); return error; } HWScanSupport HWHDMI::MapHWScanSupport(uint32_t value) { switch (value) { // TODO(user): Read the scan type from driver defined values instead of hardcoding case 0: return kScanNotSupported; case 1: return kScanAlwaysOverscanned; case 2: return kScanAlwaysUnderscanned; case 3: return kScanBoth; default: return kScanNotSupported; break; } } void HWHDMI::ReadScanInfo() { int scan_info_file = -1; ssize_t len = -1; char data[kPageSize] = {'\0'}; snprintf(data, sizeof(data), "%s%d/scan_info", fb_path_, fb_node_index_); scan_info_file = Sys::open_(data, O_RDONLY); if (scan_info_file < 0) { DLOGW("File '%s' not found.", data); return; } memset(&data[0], 0, sizeof(data)); len = Sys::pread_(scan_info_file, data, sizeof(data) - 1, 0); if (len <= 0) { Sys::close_(scan_info_file); DLOGW("File %s%d/scan_info is empty.", fb_path_, fb_node_index_); return; } data[len] = '\0'; Sys::close_(scan_info_file); const uint32_t scan_info_max_count = 3; uint32_t scan_info_count = 0; char *tokens[scan_info_max_count] = { NULL }; ParseLine(data, tokens, scan_info_max_count, &scan_info_count); if (scan_info_count != scan_info_max_count) { DLOGW("Failed to parse scan info string %s", data); return; } hw_scan_info_.pt_scan_support = MapHWScanSupport(UINT32(atoi(tokens[0]))); hw_scan_info_.it_scan_support = MapHWScanSupport(UINT32(atoi(tokens[1]))); hw_scan_info_.cea_scan_support = MapHWScanSupport(UINT32(atoi(tokens[2]))); DLOGI("PT %d IT %d CEA %d", hw_scan_info_.pt_scan_support, hw_scan_info_.it_scan_support, hw_scan_info_.cea_scan_support); } int HWHDMI::OpenResolutionFile(int file_mode) { char file_path[kMaxStringLength]; memset(file_path, 0, sizeof(file_path)); snprintf(file_path , sizeof(file_path), "%s%d/res_info", fb_path_, fb_node_index_); int fd = Sys::open_(file_path, file_mode); if (fd < 0) { DLOGE("file '%s' not found : ret = %d err str: %s", file_path, fd, strerror(errno)); } return fd; } // Method to request HDMI driver to write a new page of timing info into res_info node void HWHDMI::RequestNewPage(uint32_t page_number) { char page_string[kPageSize]; int fd = OpenResolutionFile(O_WRONLY); if (fd < 0) { return; } snprintf(page_string, sizeof(page_string), "%d", page_number); DLOGI_IF(kTagDriverConfig, "page=%s", page_string); ssize_t err = Sys::pwrite_(fd, page_string, sizeof(page_string), 0); if (err <= 0) { DLOGE("Write to res_info failed (%s)", strerror(errno)); } Sys::close_(fd); } // Reads the contents of res_info node into a buffer if the file is not empty bool HWHDMI::ReadResolutionFile(char *config_buffer) { ssize_t bytes_read = 0; int fd = OpenResolutionFile(O_RDONLY); if (fd >= 0) { bytes_read = Sys::pread_(fd, config_buffer, kPageSize, 0); Sys::close_(fd); } DLOGI_IF(kTagDriverConfig, "bytes_read = %d", bytes_read); return (bytes_read > 0); } // Populates the internal timing info structure with the timing info obtained // from the HDMI driver DisplayError HWHDMI::ReadTimingInfo() { uint32_t config_index = 0; uint32_t page_number = MSM_HDMI_INIT_RES_PAGE; uint32_t size = sizeof(msm_hdmi_mode_timing_info); while (true) { char config_buffer[kPageSize] = {0}; msm_hdmi_mode_timing_info *info = reinterpret_cast(config_buffer); RequestNewPage(page_number); if (!ReadResolutionFile(config_buffer)) { break; } while (info->video_format && size < kPageSize && config_index < hdmi_modes_.size()) { supported_video_modes_[config_index] = *info; size += sizeof(msm_hdmi_mode_timing_info); DLOGI_IF(kTagDriverConfig, "Config=%d Mode %d: (%dx%d) @ %d, pixel formats %d", config_index, supported_video_modes_[config_index].video_format, supported_video_modes_[config_index].active_h, supported_video_modes_[config_index].active_v, supported_video_modes_[config_index].refresh_rate, supported_video_modes_[config_index].pixel_formats); info++; config_index++; } size = sizeof(msm_hdmi_mode_timing_info); // Request HDMI driver to populate res_info with more // timing information page_number++; } if (page_number == MSM_HDMI_INIT_RES_PAGE || config_index == 0) { DLOGE("No timing information found."); return kErrorHardware; } return kErrorNone; } bool HWHDMI::IsResolutionFilePresent() { bool is_file_present = false; int fd = OpenResolutionFile(O_RDONLY); if (fd >= 0) { is_file_present = true; Sys::close_(fd); } return is_file_present; } void HWHDMI::SetSourceProductInformation(const char *node, const char *name) { char property_value[kMaxStringLength]; char sys_fs_path[kMaxStringLength]; int hdmi_node_index = GetFBNodeIndex(kDevicePluggable); if (hdmi_node_index < 0) { return; } ssize_t length = 0; DisplayError error = Debug::GetProperty(name, property_value); if (error != kErrorNone) { return; } snprintf(sys_fs_path , sizeof(sys_fs_path), "%s%d/%s", fb_path_, hdmi_node_index, node); length = HWDevice::SysFsWrite(sys_fs_path, property_value, static_cast(strlen(property_value))); if (length <= 0) { DLOGW("Failed to write %s = %s", node, property_value); } } DisplayError HWHDMI::GetDisplayS3DSupport(uint32_t index, HWDisplayAttributes *attrib) { ssize_t length = -1; char edid_s3d_str[kPageSize] = {'\0'}; char edid_s3d_path[kMaxStringLength] = {'\0'}; snprintf(edid_s3d_path, sizeof(edid_s3d_path), "%s%d/edid_3d_modes", fb_path_, fb_node_index_); if (index > hdmi_modes_.size()) { return kErrorNotSupported; } attrib->s3d_config[kS3DModeNone] = 1; // Three level inception! // The string looks like 16=SSH,4=FP:TAB:SSH,5=FP:SSH,32=FP:TAB:SSH // Initialize all the pointers to NULL to avoid crash in function strtok_r() char *saveptr_l1 = NULL, *saveptr_l2 = NULL, *saveptr_l3 = NULL; char *l1 = NULL, *l2 = NULL, *l3 = NULL; int edid_s3d_node = Sys::open_(edid_s3d_path, O_RDONLY); if (edid_s3d_node < 0) { DLOGW("%s could not be opened : %s", edid_s3d_path, strerror(errno)); return kErrorNotSupported; } length = Sys::pread_(edid_s3d_node, edid_s3d_str, sizeof(edid_s3d_str)-1, 0); if (length <= 0) { Sys::close_(edid_s3d_node); return kErrorNotSupported; } l1 = strtok_r(edid_s3d_str, ",", &saveptr_l1); while (l1 != NULL) { l2 = strtok_r(l1, "=", &saveptr_l2); if (l2 != NULL) { if (hdmi_modes_[index] == (uint32_t)atoi(l2)) { l3 = strtok_r(saveptr_l2, ":", &saveptr_l3); while (l3 != NULL) { if (strncmp("SSH", l3, strlen("SSH")) == 0) { attrib->s3d_config[kS3DModeLR] = 1; attrib->s3d_config[kS3DModeRL] = 1; } else if (strncmp("TAB", l3, strlen("TAB")) == 0) { attrib->s3d_config[kS3DModeTB] = 1; } else if (strncmp("FP", l3, strlen("FP")) == 0) { attrib->s3d_config[kS3DModeFP] = 1; } l3 = strtok_r(NULL, ":", &saveptr_l3); } } } l1 = strtok_r(NULL, ",", &saveptr_l1); } Sys::close_(edid_s3d_node); return kErrorNone; } bool HWHDMI::IsSupportedS3DMode(HWS3DMode s3d_mode) { for (uint32_t i = 0; i < supported_s3d_modes_.size(); i++) { if (supported_s3d_modes_[i] == s3d_mode) { return true; } } return false; } DisplayError HWHDMI::SetS3DMode(HWS3DMode s3d_mode) { if (!IsSupportedS3DMode(s3d_mode)) { DLOGW("S3D mode is not supported s3d_mode = %d", s3d_mode); return kErrorNotSupported; } std::map::iterator it = s3d_mode_sdm_to_mdp_.find(s3d_mode); if (it == s3d_mode_sdm_to_mdp_.end()) { return kErrorNotSupported; } msm_hdmi_s3d_mode s3d_mdp_mode = it->second; if (active_mdp_s3d_mode_ == s3d_mdp_mode) { // HDMI_S3D_SIDE_BY_SIDE is an mdp mapping for kS3DModeLR and kS3DModeRL s3d modes. So no need // to update the s3d_mode node. hw_panel_info needs to be updated to differentiate these two s3d // modes in strategy hw_panel_info_.s3d_mode = s3d_mode; return kErrorNone; } ssize_t length = -1; char s3d_mode_path[kMaxStringLength] = {'\0'}; char s3d_mode_string[kMaxStringLength] = {'\0'}; snprintf(s3d_mode_path, sizeof(s3d_mode_path), "%s%d/s3d_mode", fb_path_, fb_node_index_); int s3d_mode_node = Sys::open_(s3d_mode_path, O_RDWR); if (s3d_mode_node < 0) { DLOGW("%s could not be opened : %s", s3d_mode_path, strerror(errno)); return kErrorNotSupported; } snprintf(s3d_mode_string, sizeof(s3d_mode_string), "%d", s3d_mdp_mode); length = Sys::pwrite_(s3d_mode_node, s3d_mode_string, sizeof(s3d_mode_string), 0); if (length <= 0) { DLOGW("Failed to write into s3d node: %s", strerror(errno)); Sys::close_(s3d_mode_node); return kErrorNotSupported; } active_mdp_s3d_mode_ = s3d_mdp_mode; hw_panel_info_.s3d_mode = s3d_mode; Sys::close_(s3d_mode_node); DLOGI_IF(kTagDriverConfig, "Set s3d mode %d", hw_panel_info_.s3d_mode); return kErrorNone; } DisplayError HWHDMI::GetPanelS3DMode() { ssize_t length = -1; char s3d_mode_path[kMaxStringLength] = {'\0'}; char s3d_mode_string[kMaxStringLength] = {'\0'}; snprintf(s3d_mode_path, sizeof(s3d_mode_path), "%s%d/s3d_mode", fb_path_, fb_node_index_); int panel_s3d_mode = 0; int s3d_mode_node = Sys::open_(s3d_mode_path, O_RDWR); if (s3d_mode_node < 0) { DLOGE("%s could not be opened : %s", s3d_mode_path, strerror(errno)); return kErrorNotSupported; } length = Sys::pread_(s3d_mode_node, s3d_mode_string, sizeof(s3d_mode_string), 0); if (length <= 0) { DLOGE("Failed read s3d node: %s", strerror(errno)); Sys::close_(s3d_mode_node); return kErrorNotSupported; } panel_s3d_mode = atoi(s3d_mode_string); if (panel_s3d_mode < HDMI_S3D_NONE || panel_s3d_mode >= HDMI_S3D_MAX) { Sys::close_(s3d_mode_node); DLOGW("HDMI panel S3D mode is not supported panel_s3d_mode = %d", panel_s3d_mode); return kErrorUndefined; } active_mdp_s3d_mode_ = static_cast(panel_s3d_mode); Sys::close_(s3d_mode_node); DLOGI_IF(kTagDriverConfig, "Get HDMI panel s3d mode %d", active_mdp_s3d_mode_); return kErrorNone; } DisplayError HWHDMI::GetDynamicFrameRateMode(uint32_t refresh_rate, uint32_t *mode, DynamicFPSData *data, uint32_t *config_index) { msm_hdmi_mode_timing_info *cur = NULL; msm_hdmi_mode_timing_info *dst = NULL; uint32_t i = 0; int pre_refresh_rate_diff = 0; bool pre_unstd_mode = false; for (i = 0; i < hdmi_modes_.size(); i++) { msm_hdmi_mode_timing_info *timing_mode = &supported_video_modes_[i]; if (timing_mode->video_format == hdmi_modes_[active_config_index_]) { cur = timing_mode; break; } } if (cur == NULL) { DLOGE("can't find timing info for active config index(%d)", active_config_index_); return kErrorUndefined; } if (cur->refresh_rate != frame_rate_) { pre_unstd_mode = true; } if (i >= hdmi_modes_.size()) { return kErrorNotSupported; } dst = cur; pre_refresh_rate_diff = static_cast(dst->refresh_rate) - static_cast(refresh_rate); for (i = 0; i < hdmi_modes_.size(); i++) { msm_hdmi_mode_timing_info *timing_mode = &supported_video_modes_[i]; if (cur->active_h == timing_mode->active_h && cur->active_v == timing_mode->active_v && cur->pixel_formats == timing_mode->pixel_formats ) { int cur_refresh_rate_diff = static_cast(timing_mode->refresh_rate) - static_cast(refresh_rate); if (abs(pre_refresh_rate_diff) > abs(cur_refresh_rate_diff)) { pre_refresh_rate_diff = cur_refresh_rate_diff; dst = timing_mode; } } } if (pre_refresh_rate_diff > kThresholdRefreshRate) { return kErrorNotSupported; } char mode_val[kVideoFormatArrayMax]={}; snprintf(mode_val, sizeof(mode_val), "%d", dst->video_format); GetConfigIndex(mode_val, config_index); data->hor_front_porch = dst->front_porch_h; data->hor_back_porch = dst->back_porch_h; data->hor_pulse_width = dst->pulse_width_h; data->clk_rate_hz = dst->pixel_freq; data->fps = refresh_rate; if (dst->front_porch_h != cur->front_porch_h) { *mode = kModeHFP; } if (dst->refresh_rate != refresh_rate || dst->pixel_freq != cur->pixel_freq) { if (*mode == kModeHFP) { if (dst->refresh_rate != refresh_rate) { *mode = kModeHFPCalcClock; } else { *mode = kModeClockHFP; } } else { *mode = kModeClock; } } if (pre_unstd_mode && (*mode == kModeHFP)) { *mode = kModeClockHFP; } return kErrorNone; } DisplayError HWHDMI::SetRefreshRate(uint32_t refresh_rate) { char mode_path[kMaxStringLength] = {0}; char node_path[kMaxStringLength] = {0}; uint32_t mode = kModeClock; uint32_t config_index = 0; DynamicFPSData data; DisplayError error = kErrorNone; if (refresh_rate == frame_rate_) { return error; } error = GetDynamicFrameRateMode(refresh_rate, &mode, &data, &config_index); if (error != kErrorNone) { return error; } snprintf(mode_path, sizeof(mode_path), "%s%d/msm_fb_dfps_mode", fb_path_, fb_node_index_); snprintf(node_path, sizeof(node_path), "%s%d/dynamic_fps", fb_path_, fb_node_index_); int fd_mode = Sys::open_(mode_path, O_WRONLY); if (fd_mode < 0) { DLOGE("Failed to open %s with error %s", mode_path, strerror(errno)); return kErrorFileDescriptor; } char dfps_mode[kMaxStringLength]; snprintf(dfps_mode, sizeof(dfps_mode), "%d", mode); DLOGI_IF(kTagDriverConfig, "Setting dfps_mode = %d", mode); ssize_t len = Sys::pwrite_(fd_mode, dfps_mode, strlen(dfps_mode), 0); if (len < 0) { DLOGE("Failed to enable dfps mode %d with error %s", mode, strerror(errno)); Sys::close_(fd_mode); return kErrorUndefined; } Sys::close_(fd_mode); int fd_node = Sys::open_(node_path, O_WRONLY); if (fd_node < 0) { DLOGE("Failed to open %s with error %s", node_path, strerror(errno)); return kErrorFileDescriptor; } char refresh_rate_string[kMaxStringLength]; if (mode == kModeHFP || mode == kModeClock) { snprintf(refresh_rate_string, sizeof(refresh_rate_string), "%d", data.fps); DLOGI_IF(kTagDriverConfig, "Setting refresh rate = %d", data.fps); } else { snprintf(refresh_rate_string, sizeof(refresh_rate_string), "%d %d %d %d %d", data.hor_front_porch, data.hor_back_porch, data.hor_pulse_width, data.clk_rate_hz, data.fps); } len = Sys::pwrite_(fd_node, refresh_rate_string, strlen(refresh_rate_string), 0); if (len < 0) { DLOGE("Failed to write %d with error %s", refresh_rate, strerror(errno)); Sys::close_(fd_node); return kErrorUndefined; } Sys::close_(fd_node); error = ReadTimingInfo(); if (error != kErrorNone) { return error; } GetDisplayAttributes(config_index, &display_attributes_); UpdateMixerAttributes(); frame_rate_ = refresh_rate; active_config_index_ = config_index; DLOGI_IF(kTagDriverConfig, "config_index(%d) Mode(%d) frame_rate(%d)", config_index, mode, frame_rate_); return kErrorNone; } void HWHDMI::UpdateMixerAttributes() { mixer_attributes_.width = display_attributes_.x_pixels; mixer_attributes_.height = display_attributes_.y_pixels; mixer_attributes_.split_left = display_attributes_.is_device_split ? (display_attributes_.x_pixels / 2) : mixer_attributes_.width; } DisplayError HWHDMI::UpdateHDRMetaData(HWLayers *hw_layers) { if (!hw_panel_info_.hdr_enabled) { return kErrorNone; } DisplayError error = kErrorNone; #ifdef MDP_HDR_STREAM const HWHDRLayerInfo &hdr_layer_info = hw_layers->info.hdr_layer_info; char hdr_stream_path[kMaxStringLength] = {}; snprintf(hdr_stream_path, sizeof(hdr_stream_path), "%s%d/hdr_stream", fb_path_, fb_node_index_); Layer hdr_layer = {}; if (hdr_layer_info.operation == HWHDRLayerInfo::kSet && hdr_layer_info.layer_index > -1) { hdr_layer = *(hw_layers->info.stack->layers.at(UINT32(hdr_layer_info.layer_index))); } const LayerBuffer *layer_buffer = &hdr_layer.input_buffer; const MasteringDisplay &mastering_display = layer_buffer->color_metadata.masteringDisplayInfo; const ContentLightLevel &light_level = layer_buffer->color_metadata.contentLightLevel; const Primaries &primaries = mastering_display.primaries; mdp_hdr_stream_ctrl hdr_ctrl = {}; if (hdr_layer_info.operation == HWHDRLayerInfo::kSet) { int32_t eotf = GetEOTF(layer_buffer->color_metadata.transfer); hdr_ctrl.hdr_stream.eotf = (eotf < 0) ? 0 : UINT32(eotf); hdr_ctrl.hdr_stream.white_point_x = primaries.whitePoint[0]; hdr_ctrl.hdr_stream.white_point_y = primaries.whitePoint[1]; hdr_ctrl.hdr_stream.display_primaries_x[0] = primaries.rgbPrimaries[0][0]; hdr_ctrl.hdr_stream.display_primaries_y[0] = primaries.rgbPrimaries[0][1]; hdr_ctrl.hdr_stream.display_primaries_x[1] = primaries.rgbPrimaries[1][0]; hdr_ctrl.hdr_stream.display_primaries_y[1] = primaries.rgbPrimaries[1][1]; hdr_ctrl.hdr_stream.display_primaries_x[2] = primaries.rgbPrimaries[2][0]; hdr_ctrl.hdr_stream.display_primaries_y[2] = primaries.rgbPrimaries[2][1]; hdr_ctrl.hdr_stream.min_luminance = mastering_display.minDisplayLuminance; hdr_ctrl.hdr_stream.max_luminance = mastering_display.maxDisplayLuminance/10000; hdr_ctrl.hdr_stream.max_content_light_level = light_level.maxContentLightLevel; hdr_ctrl.hdr_stream.max_average_light_level = light_level.minPicAverageLightLevel; hdr_ctrl.hdr_state = HDR_ENABLE; reset_hdr_flag_ = false; #ifdef MDP_COMMIT_UPDATE_CDM_COLOR_SPACE HWDevice::SetCSC(layer_buffer->color_metadata, &cdm_color_space_); cdm_color_space_commit_ = true; #endif // DP related int32_t pixel_encoding = GetPixelEncoding(hdr_layer.input_buffer); hdr_ctrl.hdr_stream.pixel_encoding = (pixel_encoding < 0) ? 0 : UINT32(pixel_encoding); int32_t colorimetry = GetColoriMetry(hdr_layer.input_buffer); hdr_ctrl.hdr_stream.colorimetry = (colorimetry < 0) ? 0 : UINT32(colorimetry); hdr_ctrl.hdr_stream.range = GetRange(hdr_layer.input_buffer.color_metadata.range); int32_t bits_per_component = GetBitsPerComponent(hdr_layer.input_buffer); hdr_ctrl.hdr_stream.bits_per_component = (bits_per_component < 0) ? 0 : UINT32(bits_per_component); hdr_ctrl.hdr_stream.content_type = GetContentType(hdr_layer.input_buffer); DLOGD_IF(kTagDriverConfig, "kSet: HDR Stream : MaxDisplayLuminance = %d\n" "MinDisplayLuminance = %d MaxContentLightLevel = %d MaxAverageLightLevel = %d\n" "Red_x = %d Red_y = %d Green_x = %d Green_y = %d Blue_x = %d Blue_y = %d\n" "WhitePoint_x = %d WhitePoint_y = %d EOTF = %d PixelEncoding = %d Colorimetry = %d\n" "Range = %d BPC = %d ContentType = %d hdr_state = %d", hdr_ctrl.hdr_stream.max_luminance, hdr_ctrl.hdr_stream.min_luminance, hdr_ctrl.hdr_stream.max_content_light_level, hdr_ctrl.hdr_stream.max_average_light_level, hdr_ctrl.hdr_stream.display_primaries_x[0], hdr_ctrl.hdr_stream.display_primaries_y[0], hdr_ctrl.hdr_stream.display_primaries_x[1], hdr_ctrl.hdr_stream.display_primaries_y[1], hdr_ctrl.hdr_stream.display_primaries_x[2], hdr_ctrl.hdr_stream.display_primaries_y[2], hdr_ctrl.hdr_stream.white_point_x, hdr_ctrl.hdr_stream.white_point_x, hdr_ctrl.hdr_stream.eotf, hdr_ctrl.hdr_stream.pixel_encoding, hdr_ctrl.hdr_stream.colorimetry, hdr_ctrl.hdr_stream.range, hdr_ctrl.hdr_stream.bits_per_component, hdr_ctrl.hdr_stream.content_type, hdr_ctrl.hdr_state); } else if (hdr_layer_info.operation == HWHDRLayerInfo::kReset) { memset(&hdr_ctrl.hdr_stream, 0, sizeof(hdr_ctrl.hdr_stream)); hdr_ctrl.hdr_state = HDR_RESET; reset_hdr_flag_ = true; hdr_reset_start_ = time(NULL); #ifdef MDP_COMMIT_UPDATE_CDM_COLOR_SPACE cdm_color_space_ = (mdp_color_space) MDP_CSC_DEFAULT; cdm_color_space_commit_ = true; #endif DLOGD_IF(kTagDriverConfig, "kReset: HDR Stream: HDR_RESET"); } else if (hdr_layer_info.operation == HWHDRLayerInfo::kNoOp) { if (reset_hdr_flag_) { hdr_reset_end_ = time(NULL); if ((hdr_reset_end_ - hdr_reset_start_) >= MIN_HDR_RESET_WAITTIME_SEC) { reset_hdr_flag_ = false; memset(&hdr_ctrl.hdr_stream, 0, sizeof(hdr_ctrl.hdr_stream)); hdr_ctrl.hdr_state = HDR_DISABLE; DLOGD_IF(kTagDriverConfig, "kNoOp: HDR Stream: HDR_DISABLE"); } else { return kErrorNone; } } else { return kErrorNone; } } int fd = Sys::open_(hdr_stream_path, O_WRONLY); if (fd < 0) { DLOGE("Failed to open %s with error %s", hdr_stream_path, strerror(errno)); return kErrorFileDescriptor; } const void *hdr_metadata = reinterpret_cast(&hdr_ctrl); ssize_t len = Sys::pwrite_(fd, hdr_metadata, sizeof(hdr_ctrl), 0); if (len <= 0) { DLOGE("Failed to write hdr_metadata"); error = kErrorUndefined; } Sys::close_(fd); #endif return error; } } // namespace sdm