// Copyright (c) 2017-2022, The Khronos Group Inc. // Copyright (c) 2017-2019 Valve Corporation // Copyright (c) 2017-2019 LunarG, Inc. // // SPDX-License-Identifier: Apache-2.0 OR MIT // // Initial Authors: Mark Young , Dave Houlton // #if defined(_MSC_VER) && !defined(_CRT_SECURE_NO_WARNINGS) #define _CRT_SECURE_NO_WARNINGS #endif // defined(_MSC_VER) && !defined(_CRT_SECURE_NO_WARNINGS) #include "manifest_file.hpp" #ifdef OPENXR_HAVE_COMMON_CONFIG #include "common_config.h" #endif // OPENXR_HAVE_COMMON_CONFIG #include "filesystem_utils.hpp" #include "loader_platform.hpp" #include "platform_utils.hpp" #include "loader_logger.hpp" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifndef FALLBACK_CONFIG_DIRS #define FALLBACK_CONFIG_DIRS "/etc/xdg" #endif // !FALLBACK_CONFIG_DIRS #ifndef FALLBACK_DATA_DIRS #define FALLBACK_DATA_DIRS "/usr/local/share:/usr/share" #endif // !FALLBACK_DATA_DIRS #ifndef SYSCONFDIR #define SYSCONFDIR "/etc" #endif // !SYSCONFDIR #ifdef XRLOADER_DISABLE_EXCEPTION_HANDLING #if JSON_USE_EXCEPTIONS #error \ "Loader is configured to not catch exceptions, but jsoncpp was built with exception-throwing enabled, which could violate the C ABI. One of those two things needs to change." #endif // JSON_USE_EXCEPTIONS #endif // !XRLOADER_DISABLE_EXCEPTION_HANDLING #include "runtime_interface.hpp" // Utility functions for finding files in the appropriate paths static inline bool StringEndsWith(const std::string &value, const std::string &ending) { if (ending.size() > value.size()) { return false; } return std::equal(ending.rbegin(), ending.rend(), value.rbegin()); } // If the file found is a manifest file name, add it to the out_files manifest list. static void AddIfJson(const std::string &full_file, std::vector &manifest_files) { if (full_file.empty() || !StringEndsWith(full_file, ".json")) { return; } manifest_files.push_back(full_file); } // Check the current path for any manifest files. If the provided search_path is a directory, look for // all included JSON files in that directory. Otherwise, just check the provided search_path which should // be a single filename. static void CheckAllFilesInThePath(const std::string &search_path, bool is_directory_list, std::vector &manifest_files) { if (FileSysUtilsPathExists(search_path)) { std::string absolute_path; if (!is_directory_list) { // If the file exists, try to add it if (FileSysUtilsIsRegularFile(search_path)) { FileSysUtilsGetAbsolutePath(search_path, absolute_path); AddIfJson(absolute_path, manifest_files); } } else { std::vector files; if (FileSysUtilsFindFilesInPath(search_path, files)) { for (std::string &cur_file : files) { std::string relative_path; FileSysUtilsCombinePaths(search_path, cur_file, relative_path); if (!FileSysUtilsGetAbsolutePath(relative_path, absolute_path)) { continue; } AddIfJson(absolute_path, manifest_files); } } } } } // Add all manifest files in the provided paths to the manifest_files list. If search_path // is made up of directory listings (versus direct manifest file names) search each path for // any manifest files. static void AddFilesInPath(const std::string &search_path, bool is_directory_list, std::vector &manifest_files) { std::size_t last_found = 0; std::size_t found = search_path.find_first_of(PATH_SEPARATOR); std::string cur_search; // Handle any path listings in the string (separated by the appropriate path separator) while (found != std::string::npos) { // substr takes a start index and length. std::size_t length = found - last_found; cur_search = search_path.substr(last_found, length); CheckAllFilesInThePath(cur_search, is_directory_list, manifest_files); // This works around issue if multiple path separator follow each other directly. last_found = found; while (found == last_found) { last_found = found + 1; found = search_path.find_first_of(PATH_SEPARATOR, last_found); } } // If there's something remaining in the string, copy it over if (last_found < search_path.size()) { cur_search = search_path.substr(last_found); CheckAllFilesInThePath(cur_search, is_directory_list, manifest_files); } } // Copy all paths listed in the cur_path string into output_path and append the appropriate relative_path onto the end of each. static void CopyIncludedPaths(bool is_directory_list, const std::string &cur_path, const std::string &relative_path, std::string &output_path) { if (!cur_path.empty()) { std::size_t last_found = 0; std::size_t found = cur_path.find_first_of(PATH_SEPARATOR); // Handle any path listings in the string (separated by the appropriate path separator) while (found != std::string::npos) { std::size_t length = found - last_found; output_path += cur_path.substr(last_found, length); if (is_directory_list && (cur_path[found - 1] != '\\' && cur_path[found - 1] != '/')) { output_path += DIRECTORY_SYMBOL; } output_path += relative_path; output_path += PATH_SEPARATOR; last_found = found; found = cur_path.find_first_of(PATH_SEPARATOR, found + 1); } // If there's something remaining in the string, copy it over size_t last_char = cur_path.size() - 1; if (last_found != last_char) { output_path += cur_path.substr(last_found); if (is_directory_list && (cur_path[last_char] != '\\' && cur_path[last_char] != '/')) { output_path += DIRECTORY_SYMBOL; } output_path += relative_path; output_path += PATH_SEPARATOR; } } } // Look for data files in the provided paths, but first check the environment override to determine if we should use that instead. static void ReadDataFilesInSearchPaths(const std::string &override_env_var, const std::string &relative_path, bool &override_active, std::vector &manifest_files) { std::string override_path; std::string search_path; if (!override_env_var.empty()) { bool permit_override = true; #ifndef XR_OS_WINDOWS if (geteuid() != getuid() || getegid() != getgid()) { // Don't allow setuid apps to use the env var permit_override = false; } #endif if (permit_override) { override_path = PlatformUtilsGetSecureEnv(override_env_var.c_str()); } } if (!override_path.empty()) { CopyIncludedPaths(true, override_path, "", search_path); override_active = true; } else { override_active = false; #if !defined(XR_OS_WINDOWS) && !defined(XR_OS_ANDROID) const char home_additional[] = ".local/share/"; // Determine how much space is needed to generate the full search path // for the current manifest files. std::string xdg_conf_dirs = PlatformUtilsGetSecureEnv("XDG_CONFIG_DIRS"); std::string xdg_data_dirs = PlatformUtilsGetSecureEnv("XDG_DATA_DIRS"); std::string xdg_data_home = PlatformUtilsGetSecureEnv("XDG_DATA_HOME"); std::string home = PlatformUtilsGetSecureEnv("HOME"); if (xdg_conf_dirs.empty()) { CopyIncludedPaths(true, FALLBACK_CONFIG_DIRS, relative_path, search_path); } else { CopyIncludedPaths(true, xdg_conf_dirs, relative_path, search_path); } CopyIncludedPaths(true, SYSCONFDIR, relative_path, search_path); #if defined(EXTRASYSCONFDIR) CopyIncludedPaths(true, EXTRASYSCONFDIR, relative_path, search_path); #endif if (xdg_data_dirs.empty()) { CopyIncludedPaths(true, FALLBACK_DATA_DIRS, relative_path, search_path); } else { CopyIncludedPaths(true, xdg_data_dirs, relative_path, search_path); } if (!xdg_data_home.empty()) { CopyIncludedPaths(true, xdg_data_home, relative_path, search_path); } else if (!home.empty()) { std::string relative_home_path = home_additional; relative_home_path += relative_path; CopyIncludedPaths(true, home, relative_home_path, search_path); } #else (void)relative_path; #endif } // Now, parse the paths and add any manifest files found in them. AddFilesInPath(search_path, true, manifest_files); } #ifdef XR_OS_LINUX // Get an XDG environment variable with a $HOME-relative default static std::string GetXDGEnvHome(const char *name, const char *fallback_path) { std::string result = PlatformUtilsGetSecureEnv(name); if (!result.empty()) { return result; } result = PlatformUtilsGetSecureEnv("HOME"); if (result.empty()) { return result; } result += "/"; result += fallback_path; return result; } // Get an XDG environment variable with absolute defaults static std::string GetXDGEnvAbsolute(const char *name, const char *fallback_paths) { std::string result = PlatformUtilsGetSecureEnv(name); if (!result.empty()) { return result; } return fallback_paths; } // Return the first instance of relative_path occurring in an XDG config dir according to standard // precedence order. static bool FindXDGConfigFile(const std::string &relative_path, std::string &out) { out = GetXDGEnvHome("XDG_CONFIG_HOME", ".config"); if (!out.empty()) { out += "/"; out += relative_path; LoaderLogger::LogInfoMessage("", "Looking for " + relative_path + " in XDG_CONFIG_HOME: " + out); if (FileSysUtilsPathExists(out)) { return true; } } std::istringstream iss(GetXDGEnvAbsolute("XDG_CONFIG_DIRS", FALLBACK_CONFIG_DIRS)); std::string path; while (std::getline(iss, path, PATH_SEPARATOR)) { if (path.empty()) { continue; } out = path; out += "/"; out += relative_path; LoaderLogger::LogInfoMessage("", "Looking for " + relative_path + " in an entry of XDG_CONFIG_DIRS: " + out); if (FileSysUtilsPathExists(out)) { return true; } } out = SYSCONFDIR; out += "/"; out += relative_path; LoaderLogger::LogInfoMessage("", "Looking for " + relative_path + " in compiled-in SYSCONFDIR: " + out); if (FileSysUtilsPathExists(out)) { return true; } #if defined(EXTRASYSCONFDIR) out = EXTRASYSCONFDIR; out += "/"; out += relative_path; LoaderLogger::LogInfoMessage("", "Looking for " + relative_path + " in compiled-in EXTRASYSCONFDIR: " + out); if (FileSysUtilsPathExists(out)) { return true; } #endif out.clear(); return false; } #endif #ifdef XR_OS_WINDOWS // Look for runtime data files in the provided paths, but first check the environment override to determine // if we should use that instead. static void ReadRuntimeDataFilesInRegistry(const std::string &runtime_registry_location, const std::string &default_runtime_value_name, std::vector &manifest_files) { HKEY hkey; DWORD access_flags; wchar_t value_w[1024]; DWORD value_size_w = sizeof(value_w); // byte size of the buffer. // Generate the full registry location for the registry information std::string full_registry_location = OPENXR_REGISTRY_LOCATION; full_registry_location += std::to_string(XR_VERSION_MAJOR(XR_CURRENT_API_VERSION)); full_registry_location += runtime_registry_location; const std::wstring full_registry_location_w = utf8_to_wide(full_registry_location); const std::wstring default_runtime_value_name_w = utf8_to_wide(default_runtime_value_name); // Use 64 bit regkey for 64bit application, and use 32 bit regkey in WOW for 32bit application. access_flags = KEY_QUERY_VALUE; LONG open_value = RegOpenKeyExW(HKEY_LOCAL_MACHINE, full_registry_location_w.c_str(), 0, access_flags, &hkey); if (ERROR_SUCCESS != open_value) { LoaderLogger::LogWarningMessage("", "ReadRuntimeDataFilesInRegistry - failed to open registry key " + full_registry_location); } else if (ERROR_SUCCESS != RegGetValueW(hkey, nullptr, default_runtime_value_name_w.c_str(), RRF_RT_REG_SZ | REG_EXPAND_SZ | RRF_ZEROONFAILURE, NULL, reinterpret_cast(&value_w), &value_size_w)) { LoaderLogger::LogWarningMessage( "", "ReadRuntimeDataFilesInRegistry - failed to read registry value " + default_runtime_value_name); } else { AddFilesInPath(wide_to_utf8(value_w), false, manifest_files); } } // Look for layer data files in the provided paths, but first check the environment override to determine // if we should use that instead. static void ReadLayerDataFilesInRegistry(const std::string ®istry_location, std::vector &manifest_files) { const std::wstring full_registry_location_w = utf8_to_wide(OPENXR_REGISTRY_LOCATION + std::to_string(XR_VERSION_MAJOR(XR_CURRENT_API_VERSION)) + registry_location); auto ReadLayerDataFilesInHive = [&](HKEY hive) { HKEY hkey; LONG open_value = RegOpenKeyExW(hive, full_registry_location_w.c_str(), 0, KEY_QUERY_VALUE, &hkey); if (ERROR_SUCCESS != open_value) { return false; } wchar_t name_w[1024]{}; LONG rtn_value; DWORD name_size = 1023; DWORD value; DWORD value_size = sizeof(value); DWORD key_index = 0; while (ERROR_SUCCESS == (rtn_value = RegEnumValueW(hkey, key_index++, name_w, &name_size, NULL, NULL, (LPBYTE)&value, &value_size))) { if (value_size == sizeof(value) && value == 0) { const std::string filename = wide_to_utf8(name_w); AddFilesInPath(filename, false, manifest_files); } // Reset some items for the next loop name_size = 1023; } RegCloseKey(hkey); return true; }; // Do not allow high integrity processes to act on data that can be controlled by medium integrity processes. const bool readFromCurrentUser = !IsHighIntegrityLevel(); bool found = ReadLayerDataFilesInHive(HKEY_LOCAL_MACHINE); if (readFromCurrentUser) { found |= ReadLayerDataFilesInHive(HKEY_CURRENT_USER); } if (!found) { std::string warning_message = "ReadLayerDataFilesInRegistry - failed to read registry location "; warning_message += registry_location; warning_message += (readFromCurrentUser ? " in either HKEY_LOCAL_MACHINE or HKEY_CURRENT_USER" : " in HKEY_LOCAL_MACHINE"); LoaderLogger::LogWarningMessage("", warning_message); } } #endif // XR_OS_WINDOWS ManifestFile::ManifestFile(ManifestFileType type, const std::string &filename, const std::string &library_path) : _filename(filename), _type(type), _library_path(library_path) {} bool ManifestFile::IsValidJson(const Json::Value &root_node, JsonVersion &version) { if (root_node["file_format_version"].isNull() || !root_node["file_format_version"].isString()) { LoaderLogger::LogErrorMessage("", "ManifestFile::IsValidJson - JSON file missing \"file_format_version\""); return false; } std::string file_format = root_node["file_format_version"].asString(); const int num_fields = sscanf(file_format.c_str(), "%u.%u.%u", &version.major, &version.minor, &version.patch); // Only version 1.0.0 is defined currently. Eventually we may have more version, but // some of the versions may only be valid for layers or runtimes specifically. if (num_fields != 3 || version.major != 1 || version.minor != 0 || version.patch != 0) { std::ostringstream error_ss; error_ss << "ManifestFile::IsValidJson - JSON \"file_format_version\" " << version.major << "." << version.minor << "." << version.patch << " is not supported"; LoaderLogger::LogErrorMessage("", error_ss.str()); return false; } return true; } static void GetExtensionProperties(const std::vector &extensions, std::vector &props) { for (const auto &ext : extensions) { auto it = std::find_if(props.begin(), props.end(), [&](XrExtensionProperties &prop) { return prop.extensionName == ext.name; }); if (it != props.end()) { it->extensionVersion = std::max(it->extensionVersion, ext.extension_version); } else { XrExtensionProperties prop = {}; prop.type = XR_TYPE_EXTENSION_PROPERTIES; prop.next = nullptr; strncpy(prop.extensionName, ext.name.c_str(), XR_MAX_EXTENSION_NAME_SIZE - 1); prop.extensionName[XR_MAX_EXTENSION_NAME_SIZE - 1] = '\0'; prop.extensionVersion = ext.extension_version; props.push_back(prop); } } } // Return any instance extensions found in the manifest files in the proper form for // OpenXR (XrExtensionProperties). void ManifestFile::GetInstanceExtensionProperties(std::vector &props) { GetExtensionProperties(_instance_extensions, props); } const std::string &ManifestFile::GetFunctionName(const std::string &func_name) const { if (!_functions_renamed.empty()) { auto found = _functions_renamed.find(func_name); if (found != _functions_renamed.end()) { return found->second; } } return func_name; } RuntimeManifestFile::RuntimeManifestFile(const std::string &filename, const std::string &library_path) : ManifestFile(MANIFEST_TYPE_RUNTIME, filename, library_path) {} static void ParseExtension(Json::Value const &ext, std::vector &extensions) { Json::Value ext_name = ext["name"]; Json::Value ext_version = ext["extension_version"]; // Allow "extension_version" as a String or a UInt to maintain backwards compatibility, even though it should be a String. // Internal Issue 1411: https://gitlab.khronos.org/openxr/openxr/-/issues/1411 // Internal MR !1867: https://gitlab.khronos.org/openxr/openxr/-/merge_requests/1867 if (ext_name.isString() && (ext_version.isString() || ext_version.isUInt())) { ExtensionListing ext_listing = {}; ext_listing.name = ext_name.asString(); if (ext_version.isUInt()) { ext_listing.extension_version = ext_version.asUInt(); } else { ext_listing.extension_version = atoi(ext_version.asString().c_str()); } extensions.push_back(ext_listing); } } void ManifestFile::ParseCommon(Json::Value const &root_node) { const Json::Value &inst_exts = root_node["instance_extensions"]; if (!inst_exts.isNull() && inst_exts.isArray()) { for (const auto &ext : inst_exts) { ParseExtension(ext, _instance_extensions); } } const Json::Value &funcs_renamed = root_node["functions"]; if (!funcs_renamed.isNull() && !funcs_renamed.empty()) { for (Json::ValueConstIterator func_it = funcs_renamed.begin(); func_it != funcs_renamed.end(); ++func_it) { if (!(*func_it).isString()) { LoaderLogger::LogWarningMessage( "", "ManifestFile::ParseCommon " + _filename + " \"functions\" section contains non-string values."); continue; } std::string original_name = func_it.key().asString(); std::string new_name = (*func_it).asString(); _functions_renamed.emplace(original_name, new_name); } } } void RuntimeManifestFile::CreateIfValid(std::string const &filename, std::vector> &manifest_files) { std::ifstream json_stream(filename, std::ifstream::in); LoaderLogger::LogInfoMessage("", "RuntimeManifestFile::CreateIfValid - attempting to load " + filename); std::ostringstream error_ss("RuntimeManifestFile::CreateIfValid "); if (!json_stream.is_open()) { error_ss << "failed to open " << filename << ". Does it exist?"; LoaderLogger::LogErrorMessage("", error_ss.str()); return; } Json::CharReaderBuilder builder; std::string errors; Json::Value root_node = Json::nullValue; if (!Json::parseFromStream(builder, json_stream, &root_node, &errors) || !root_node.isObject()) { error_ss << "failed to parse " << filename << "."; if (!errors.empty()) { error_ss << " (Error message: " << errors << ")"; } error_ss << " Is it a valid runtime manifest file?"; LoaderLogger::LogErrorMessage("", error_ss.str()); return; } CreateIfValid(root_node, filename, manifest_files); } void RuntimeManifestFile::CreateIfValid(const Json::Value &root_node, const std::string &filename, std::vector> &manifest_files) { std::ostringstream error_ss("RuntimeManifestFile::CreateIfValid "); JsonVersion file_version = {}; if (!ManifestFile::IsValidJson(root_node, file_version)) { error_ss << "isValidJson indicates " << filename << " is not a valid manifest file."; LoaderLogger::LogErrorMessage("", error_ss.str()); return; } const Json::Value &runtime_root_node = root_node["runtime"]; // The Runtime manifest file needs the "runtime" root as well as a sub-node for "library_path". If any of those aren't there, // fail. if (runtime_root_node.isNull() || runtime_root_node["library_path"].isNull() || !runtime_root_node["library_path"].isString()) { error_ss << filename << " is missing required fields. Verify all proper fields exist."; LoaderLogger::LogErrorMessage("", error_ss.str()); return; } std::string lib_path = runtime_root_node["library_path"].asString(); // If the library_path variable has no directory symbol, it's just a file name and should be accessible on the // global library path. if (lib_path.find('\\') != std::string::npos || lib_path.find('/') != std::string::npos) { // If the library_path is an absolute path, just use that if it exists if (FileSysUtilsIsAbsolutePath(lib_path)) { if (!FileSysUtilsPathExists(lib_path)) { error_ss << filename << " library " << lib_path << " does not appear to exist"; LoaderLogger::LogErrorMessage("", error_ss.str()); return; } } else { // Otherwise, treat the library path as a relative path based on the JSON file. std::string canonical_path; std::string combined_path; std::string file_parent; // Search relative to the real manifest file, not relative to the symlink if (!FileSysUtilsGetCanonicalPath(filename, canonical_path)) { // Give relative to the non-canonical path a chance canonical_path = filename; } if (!FileSysUtilsGetParentPath(canonical_path, file_parent) || !FileSysUtilsCombinePaths(file_parent, lib_path, combined_path) || !FileSysUtilsPathExists(combined_path)) { error_ss << filename << " library " << combined_path << " does not appear to exist"; LoaderLogger::LogErrorMessage("", error_ss.str()); return; } lib_path = combined_path; } } // Add this runtime manifest file manifest_files.emplace_back(new RuntimeManifestFile(filename, lib_path)); // Add any extensions to it after the fact. // Handle any renamed functions manifest_files.back()->ParseCommon(runtime_root_node); } // Find all manifest files in the appropriate search paths/registries for the given type. XrResult RuntimeManifestFile::FindManifestFiles(std::vector> &manifest_files) { XrResult result = XR_SUCCESS; std::string filename = PlatformUtilsGetSecureEnv(OPENXR_RUNTIME_JSON_ENV_VAR); if (!filename.empty()) { LoaderLogger::LogInfoMessage( "", "RuntimeManifestFile::FindManifestFiles - using environment variable override runtime file " + filename); } else { #ifdef XR_OS_WINDOWS std::vector filenames; ReadRuntimeDataFilesInRegistry("", "ActiveRuntime", filenames); if (filenames.size() == 0) { LoaderLogger::LogErrorMessage( "", "RuntimeManifestFile::FindManifestFiles - failed to find active runtime file in registry"); return XR_ERROR_RUNTIME_UNAVAILABLE; } if (filenames.size() > 1) { LoaderLogger::LogWarningMessage( "", "RuntimeManifestFile::FindManifestFiles - found too many default runtime files in registry"); } filename = filenames[0]; LoaderLogger::LogInfoMessage("", "RuntimeManifestFile::FindManifestFiles - using registry-specified runtime file " + filename); #elif defined(XR_OS_LINUX) const std::string relative_path = "openxr/" + std::to_string(XR_VERSION_MAJOR(XR_CURRENT_API_VERSION)) + "/active_runtime.json"; if (!FindXDGConfigFile(relative_path, filename)) { LoaderLogger::LogErrorMessage( "", "RuntimeManifestFile::FindManifestFiles - failed to determine active runtime file path for this environment"); return XR_ERROR_RUNTIME_UNAVAILABLE; } #else #if defined(XR_KHR_LOADER_INIT_SUPPORT) Json::Value virtualManifest; result = GetPlatformRuntimeVirtualManifest(virtualManifest); if (XR_SUCCESS == result) { RuntimeManifestFile::CreateIfValid(virtualManifest, "", manifest_files); return result; } #endif // defined(XR_KHR_LOADER_INIT_SUPPORT) if (!PlatformGetGlobalRuntimeFileName(XR_VERSION_MAJOR(XR_CURRENT_API_VERSION), filename)) { LoaderLogger::LogErrorMessage( "", "RuntimeManifestFile::FindManifestFiles - failed to determine active runtime file path for this environment"); return XR_ERROR_RUNTIME_UNAVAILABLE; } result = XR_SUCCESS; LoaderLogger::LogInfoMessage("", "RuntimeManifestFile::FindManifestFiles - using global runtime file " + filename); #endif } RuntimeManifestFile::CreateIfValid(filename, manifest_files); return result; } ApiLayerManifestFile::ApiLayerManifestFile(ManifestFileType type, const std::string &filename, const std::string &layer_name, const std::string &description, const JsonVersion &api_version, const uint32_t &implementation_version, const std::string &library_path) : ManifestFile(type, filename, library_path), _api_version(api_version), _layer_name(layer_name), _description(description), _implementation_version(implementation_version) {} void ApiLayerManifestFile::CreateIfValid(ManifestFileType type, const std::string &filename, std::vector> &manifest_files) { std::ifstream json_stream(filename, std::ifstream::in); std::ostringstream error_ss("ApiLayerManifestFile::CreateIfValid "); if (!json_stream.is_open()) { error_ss << "failed to open " << filename << ". Does it exist?"; LoaderLogger::LogErrorMessage("", error_ss.str()); return; } Json::CharReaderBuilder builder; std::string errors; Json::Value root_node = Json::nullValue; if (!Json::parseFromStream(builder, json_stream, &root_node, &errors) || !root_node.isObject()) { error_ss << "failed to parse " << filename << "."; if (!errors.empty()) { error_ss << " (Error message: " << errors << ")"; } error_ss << " Is it a valid layer manifest file?"; LoaderLogger::LogErrorMessage("", error_ss.str()); return; } JsonVersion file_version = {}; if (!ManifestFile::IsValidJson(root_node, file_version)) { error_ss << "isValidJson indicates " << filename << " is not a valid manifest file."; LoaderLogger::LogErrorMessage("", error_ss.str()); return; } Json::Value layer_root_node = root_node["api_layer"]; // The API Layer manifest file needs the "api_layer" root as well as other sub-nodes. // If any of those aren't there, fail. if (layer_root_node.isNull() || layer_root_node["name"].isNull() || !layer_root_node["name"].isString() || layer_root_node["api_version"].isNull() || !layer_root_node["api_version"].isString() || layer_root_node["library_path"].isNull() || !layer_root_node["library_path"].isString() || layer_root_node["implementation_version"].isNull() || !layer_root_node["implementation_version"].isString()) { error_ss << filename << " is missing required fields. Verify all proper fields exist."; LoaderLogger::LogErrorMessage("", error_ss.str()); return; } if (MANIFEST_TYPE_IMPLICIT_API_LAYER == type) { bool enabled = true; // Implicit layers require the disable environment variable. if (layer_root_node["disable_environment"].isNull() || !layer_root_node["disable_environment"].isString()) { error_ss << "Implicit layer " << filename << " is missing \"disable_environment\""; LoaderLogger::LogErrorMessage("", error_ss.str()); return; } // Check if there's an enable environment variable provided if (!layer_root_node["enable_environment"].isNull() && layer_root_node["enable_environment"].isString()) { std::string env_var = layer_root_node["enable_environment"].asString(); // If it's not set in the environment, disable the layer if (!PlatformUtilsGetEnvSet(env_var.c_str())) { enabled = false; } } // Check for the disable environment variable, which must be provided in the JSON std::string env_var = layer_root_node["disable_environment"].asString(); // If the env var is set, disable the layer. Disable env var overrides enable above if (PlatformUtilsGetEnvSet(env_var.c_str())) { enabled = false; } // Not enabled, so pretend like it isn't even there. if (!enabled) { error_ss << "Implicit layer " << filename << " is disabled"; LoaderLogger::LogInfoMessage("", error_ss.str()); return; } } std::string layer_name = layer_root_node["name"].asString(); std::string api_version_string = layer_root_node["api_version"].asString(); JsonVersion api_version = {}; const int num_fields = sscanf(api_version_string.c_str(), "%u.%u", &api_version.major, &api_version.minor); api_version.patch = 0; if ((num_fields != 2) || (api_version.major == 0 && api_version.minor == 0) || api_version.major > XR_VERSION_MAJOR(XR_CURRENT_API_VERSION)) { error_ss << "layer " << filename << " has invalid API Version. Skipping layer."; LoaderLogger::LogWarningMessage("", error_ss.str()); return; } uint32_t implementation_version = atoi(layer_root_node["implementation_version"].asString().c_str()); std::string library_path = layer_root_node["library_path"].asString(); // If the library_path variable has no directory symbol, it's just a file name and should be accessible on the // global library path. if (library_path.find('\\') != std::string::npos || library_path.find('/') != std::string::npos) { // If the library_path is an absolute path, just use that if it exists if (FileSysUtilsIsAbsolutePath(library_path)) { if (!FileSysUtilsPathExists(library_path)) { error_ss << filename << " library " << library_path << " does not appear to exist"; LoaderLogger::LogErrorMessage("", error_ss.str()); return; } } else { // Otherwise, treat the library path as a relative path based on the JSON file. std::string combined_path; std::string file_parent; if (!FileSysUtilsGetParentPath(filename, file_parent) || !FileSysUtilsCombinePaths(file_parent, library_path, combined_path) || !FileSysUtilsPathExists(combined_path)) { error_ss << filename << " library " << combined_path << " does not appear to exist"; LoaderLogger::LogErrorMessage("", error_ss.str()); return; } library_path = combined_path; } } std::string description; if (!layer_root_node["description"].isNull() && layer_root_node["description"].isString()) { description = layer_root_node["description"].asString(); } // Add this layer manifest file manifest_files.emplace_back( new ApiLayerManifestFile(type, filename, layer_name, description, api_version, implementation_version, library_path)); // Add any extensions to it after the fact. manifest_files.back()->ParseCommon(layer_root_node); } void ApiLayerManifestFile::PopulateApiLayerProperties(XrApiLayerProperties &props) const { props.layerVersion = _implementation_version; props.specVersion = XR_MAKE_VERSION(_api_version.major, _api_version.minor, _api_version.patch); strncpy(props.layerName, _layer_name.c_str(), XR_MAX_API_LAYER_NAME_SIZE - 1); if (_layer_name.size() >= XR_MAX_API_LAYER_NAME_SIZE - 1) { props.layerName[XR_MAX_API_LAYER_NAME_SIZE - 1] = '\0'; } strncpy(props.description, _description.c_str(), XR_MAX_API_LAYER_DESCRIPTION_SIZE - 1); if (_description.size() >= XR_MAX_API_LAYER_DESCRIPTION_SIZE - 1) { props.description[XR_MAX_API_LAYER_DESCRIPTION_SIZE - 1] = '\0'; } } // Find all layer manifest files in the appropriate search paths/registries for the given type. XrResult ApiLayerManifestFile::FindManifestFiles(ManifestFileType type, std::vector> &manifest_files) { std::string relative_path; std::string override_env_var; std::string registry_location; // Add the appropriate top-level folders for the relative path. These should be // the string "openxr/" followed by the API major version as a string. relative_path = OPENXR_RELATIVE_PATH; relative_path += std::to_string(XR_VERSION_MAJOR(XR_CURRENT_API_VERSION)); switch (type) { case MANIFEST_TYPE_IMPLICIT_API_LAYER: relative_path += OPENXR_IMPLICIT_API_LAYER_RELATIVE_PATH; override_env_var = ""; #ifdef XR_OS_WINDOWS registry_location = OPENXR_IMPLICIT_API_LAYER_REGISTRY_LOCATION; #endif break; case MANIFEST_TYPE_EXPLICIT_API_LAYER: relative_path += OPENXR_EXPLICIT_API_LAYER_RELATIVE_PATH; override_env_var = OPENXR_API_LAYER_PATH_ENV_VAR; #ifdef XR_OS_WINDOWS registry_location = OPENXR_EXPLICIT_API_LAYER_REGISTRY_LOCATION; #endif break; default: LoaderLogger::LogErrorMessage("", "ApiLayerManifestFile::FindManifestFiles - unknown manifest file requested"); return XR_ERROR_FILE_ACCESS_ERROR; } bool override_active = false; std::vector filenames; ReadDataFilesInSearchPaths(override_env_var, relative_path, override_active, filenames); #ifdef XR_OS_WINDOWS // Read the registry if the override wasn't active. if (!override_active) { ReadLayerDataFilesInRegistry(registry_location, filenames); } #endif for (std::string &cur_file : filenames) { ApiLayerManifestFile::CreateIfValid(type, cur_file, manifest_files); } return XR_SUCCESS; }