main.cpp - platform/system/libvintf - Git at Google

 /*
  * Copyright (C) 2017 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include <getopt.h>

 #include <android-base/strings.h>
 #include <vintf/VintfObject.h>
 #include <vintf/parse_string.h>
 #include <vintf/parse_xml.h>
 #include <iomanip>
 #include <iostream>
 #include <string>
 #include <vector>

 using namespace ::android::vintf;

 static const std::string kColumnSeperator = "   ";

 std::string existString(bool value) {
     return value ? "GOOD" : "DOES NOT EXIST";
 }

 std::string compatibleString(int32_t value) {
     switch (value) {
         case COMPATIBLE:
             return "GOOD";
         case INCOMPATIBLE:
             return "INCOMPATIBLE";
         default:
             return strerror(-value);
     }
 }

 std::string boolCompatString(bool value) {
     return compatibleString(value ? COMPATIBLE : INCOMPATIBLE);
 }

 std::string deprecateString(int32_t value) {
     switch (value) {
         case NO_DEPRECATED_HALS:
             return "GOOD";
         case DEPRECATED:
             return "DEPRECATED";
         default:
             return strerror(-value);
     }
 }

 enum Status : int {
     OK = 0,
     USAGE,
 };

 struct ParsedOptions {
     bool verbose = false;
 };

 struct Option {
     char shortOption = '\0';
     std::string longOption;
     std::string help;
     std::function<Status(ParsedOptions*)> op;
 };

 std::string getShortOptions(const std::vector<Option>& options) {
     std::stringstream ret;
     for (const auto& e : options)
         if (e.shortOption != '\0') ret << e.shortOption;
     return ret.str();
 }

 std::unique_ptr<struct option[]> getLongOptions(const std::vector<Option>& options,
                                                 int* longOptFlag) {
     std::unique_ptr<struct option[]> ret{new struct option[options.size() + 1]};
     int i = 0;
     for (const auto& e : options) {
         ret[i].name = e.longOption.c_str();
         ret[i].has_arg = no_argument;
         ret[i].flag = longOptFlag;
         ret[i].val = i;

         i++;
     }
     // getopt_long last option has all zeros
     ret[i].name = NULL;
     ret[i].has_arg = 0;
     ret[i].flag = NULL;
     ret[i].val = 0;

     return ret;
 }

 Status parseOptions(int argc, char** argv, const std::vector<Option>& options, ParsedOptions* out) {
     int longOptFlag;
     std::unique_ptr<struct option[]> longOptions = getLongOptions(options, &longOptFlag);
     std::string shortOptions = getShortOptions(options);
     int optionIndex;
     for (;;) {
         int c = getopt_long(argc, argv, shortOptions.c_str(), longOptions.get(), &optionIndex);
         if (c == -1) {
             break;
         }
         const Option* found = nullptr;
         for (size_t i = 0; i < options.size(); ++i)
             if ((c == 0 && longOptFlag == static_cast<int>(i)) ||
                 (c != 0 && c == options[i].shortOption))

                 found = &options[i];

         if (found == nullptr) {
             // see unrecognized options
             std::cerr << "unrecognized option `" << argv[optind - 1] << "'" << std::endl;
             return USAGE;
         }

         Status status = found->op(out);
         if (status != OK) return status;
     }
     if (optind < argc) {
         // see non option
         std::cerr << "unrecognized option `" << argv[optind] << "'" << std::endl;
         return USAGE;
     }
     return OK;
 }

 void usage(char* me, const std::vector<Option>& options) {
     std::cerr << me << ": dump VINTF metadata via libvintf." << std::endl;
     for (const auto& e : options) {
         if (e.help.empty()) continue;
         std::cerr << "        ";
         if (e.shortOption != '\0') std::cerr << "-" << e.shortOption;
         if (e.shortOption != '\0' && !e.longOption.empty()) std::cerr << ", ";
         if (!e.longOption.empty()) std::cerr << "--" << e.longOption;
         std::cerr << ": "
                   << android::base::Join(android::base::Split(e.help, "\n"), "\n            ")
                   << std::endl;
     }
 }

 struct TableRow {
     // Whether the HAL version is in device manifest, framework manifest, device compatibility
     // matrix, framework compatibility matrix, respectively.
     bool dm = false;
     bool fm = false;
     bool dcm = false;
     bool fcm = false;
     // If the HAL version is in device / framework compatibility matrix, whether it is required
     // or not.
     bool required = false;

     // Return true if:
     // - not a required HAL version; OR
     // - required in device matrix and framework manifest;
     // - required in framework matrix and device manifest.
     bool meetsReqeuirement() const {
         if (!required) return true;
         if (dcm && !fm) return false;
         if (fcm && !dm) return false;
         return true;
     }
 };

 std::ostream& operator<<(std::ostream& out, const TableRow& row) {
     return out << (row.required ? "R" : " ") << (row.meetsReqeuirement() ? " " : "!")
                << kColumnSeperator << (row.dm ? "DM" : "  ") << kColumnSeperator
                << (row.fm ? "FM" : "  ") << kColumnSeperator << (row.fcm ? "FCM" : "   ")
                << kColumnSeperator << (row.dcm ? "DCM" : "   ");
 }

 using RowMutator = std::function<void(TableRow*)>;
 using Table = std::map<std::string, TableRow>;

 // Insert each fqInstanceName foo@x.y::IFoo/instance to the table by inserting the key
 // if it does not exist and setting the corresponding indicator (as specified by "mutate").
 void insert(const HalManifest* manifest, Table* table, const RowMutator& mutate) {
     if (manifest == nullptr) return;
     manifest->forEachInstance([&](const auto& manifestInstance) {
         std::string key = toFQNameString(manifestInstance.package(), manifestInstance.version(),
                                          manifestInstance.interface(), manifestInstance.instance());
         mutate(&(*table)[key]);
         return true;
     });
 }

 void insert(const CompatibilityMatrix* matrix, Table* table, const RowMutator& mutate) {
     if (matrix == nullptr) return;
     matrix->forEachInstance([&](const auto& matrixInstance) {
         for (auto minorVer = matrixInstance.versionRange().minMinor;
              minorVer <= matrixInstance.versionRange().maxMinor; ++minorVer) {
             std::string key = toFQNameString(
                 matrixInstance.package(), Version{matrixInstance.versionRange().majorVer, minorVer},
                 matrixInstance.interface(),
                 matrixInstance.isRegex() ? matrixInstance.regexPattern()
                                          : matrixInstance.exactInstance());
             auto it = table->find(key);
             if (it == table->end()) {
                 mutate(&(*table)[key]);
             } else {
                 mutate(&it->second);
                 if (minorVer == matrixInstance.versionRange().minMinor) {
                     it->second.required = !matrixInstance.optional();
                 }
             }
         }
         return true;
     });
 }

 Table generateHalSummary(const HalManifest* vm, const HalManifest* fm,
                          const CompatibilityMatrix* vcm, const CompatibilityMatrix* fcm) {
     Table table;
     insert(vm, &table, [](auto* row) { row->dm = true; });
     insert(fm, &table, [](auto* row) { row->fm = true; });
     insert(vcm, &table, [](auto* row) { row->dcm = true; });
     insert(fcm, &table, [](auto* row) { row->fcm = true; });

     return table;
 }

 static const std::vector<Option> gAvailableOptions{
     {'h', "help", "Print help message.", [](auto) { return USAGE; }},
     {'v', "verbose", "Dump detailed and raw content, including kernel configurations", [](auto o) {
          o->verbose = true;
          return OK;
      }}};
 // A convenience binary to dump information available through libvintf.
 int main(int argc, char** argv) {
     ParsedOptions options;
     Status status = parseOptions(argc, argv, gAvailableOptions, &options);
     if (status == USAGE) usage(argv[0], gAvailableOptions);
     if (status != OK) return status;

     auto vm = VintfObject::GetDeviceHalManifest();
     auto fm = VintfObject::GetFrameworkHalManifest();
     auto vcm = VintfObject::GetDeviceCompatibilityMatrix();
     auto fcm = VintfObject::GetFrameworkCompatibilityMatrix();
     auto ki = VintfObject::GetRuntimeInfo();

     if (!options.verbose) {
         std::cout << "======== HALs =========" << std::endl
                   << "R: required. (empty): optional or missing from matrices. "
                   << "!: required and not in manifest." << std::endl
                   << "DM: device manifest. FM: framework manifest." << std::endl
                   << "FCM: framework compatibility matrix. DCM: device compatibility matrix."
                   << std::endl
                   << std::endl;
         auto table = generateHalSummary(vm.get(), fm.get(), vcm.get(), fcm.get());

         for (const auto& pair : table)
             std::cout << pair.second << kColumnSeperator << pair.first << std::endl;

         std::cout << std::endl;
     }

     SerializeFlags::Type flags = SerializeFlags::EVERYTHING;
     if (!options.verbose) {
         flags = flags.disableHals().disableKernel();
     }
     std::cout << "======== Device HAL Manifest =========" << std::endl;
     if (vm != nullptr) std::cout << gHalManifestConverter(*vm, flags);
     std::cout << "======== Framework HAL Manifest =========" << std::endl;
     if (fm != nullptr) std::cout << gHalManifestConverter(*fm, flags);
     std::cout << "======== Device Compatibility Matrix =========" << std::endl;
     if (vcm != nullptr) std::cout << gCompatibilityMatrixConverter(*vcm, flags);
     std::cout << "======== Framework Compatibility Matrix =========" << std::endl;
     if (fcm != nullptr) std::cout << gCompatibilityMatrixConverter(*fcm, flags);

     std::cout << "======== Runtime Info =========" << std::endl;
     if (ki != nullptr) std::cout << dump(*ki, options.verbose);

     std::cout << std::endl;

     std::cout << "======== Summary =========" << std::endl;
     std::cout << "Device Manifest?    " << existString(vm != nullptr) << std::endl
               << "Device Matrix?      " << existString(vcm != nullptr) << std::endl
               << "Framework Manifest? " << existString(fm != nullptr) << std::endl
               << "Framework Matrix?   " << existString(fcm != nullptr) << std::endl;
     std::string error;
     if (vm && fcm) {
         bool compatible = vm->checkCompatibility(*fcm, &error);
         std::cout << "Device HAL Manifest <==> Framework Compatibility Matrix? "
                   << boolCompatString(compatible);
         if (!compatible)
             std::cout << ", " << error;
         std::cout << std::endl;
     }
     if (fm && vcm) {
         bool compatible = fm->checkCompatibility(*vcm, &error);
         std::cout << "Framework HAL Manifest <==> Device Compatibility Matrix? "
                   << boolCompatString(compatible);
         if (!compatible)
             std::cout << ", " << error;
         std::cout << std::endl;
     }
     if (ki && fcm) {
         bool compatible = ki->checkCompatibility(*fcm, &error);
         std::cout << "Runtime info <==> Framework Compatibility Matrix?        "
                   << boolCompatString(compatible);
         if (!compatible) std::cout << ", " << error;
         std::cout << std::endl;
     }

     {
         auto compatible = VintfObject::CheckCompatibility({}, &error);
         std::cout << "VintfObject::CheckCompatibility?                         "
                   << compatibleString(compatible);
         if (compatible != COMPATIBLE) std::cout << ", " << error;
         std::cout << std::endl;
     }

     if (vm && fcm) {
         auto deprecate = VintfObject::CheckDeprecation(&error);
         std::cout << "VintfObject::CheckDeprecation (against device manifest)? "
                   << deprecateString(deprecate);
         if (deprecate != NO_DEPRECATED_HALS) std::cout << ", " << error;
         std::cout << std::endl;
     }
 }
	/*
	* Copyright (C) 2017 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include <getopt.h>

	#include <android-base/strings.h>
	#include <vintf/VintfObject.h>
	#include <vintf/parse_string.h>
	#include <vintf/parse_xml.h>
	#include <iomanip>
	#include <iostream>
	#include <string>
	#include <vector>

	using namespace ::android::vintf;

	static const std::string kColumnSeperator = " ";

	std::string existString(bool value) {
	return value ? "GOOD" : "DOES NOT EXIST";
	}

	std::string compatibleString(int32_t value) {
	switch (value) {
	case COMPATIBLE:
	return "GOOD";
	case INCOMPATIBLE:
	return "INCOMPATIBLE";
	default:
	return strerror(-value);
	}
	}

	std::string boolCompatString(bool value) {
	return compatibleString(value ? COMPATIBLE : INCOMPATIBLE);
	}

	std::string deprecateString(int32_t value) {
	switch (value) {
	case NO_DEPRECATED_HALS:
	return "GOOD";
	case DEPRECATED:
	return "DEPRECATED";
	default:
	return strerror(-value);
	}
	}

	enum Status : int {
	OK = 0,
	USAGE,
	};

	struct ParsedOptions {
	bool verbose = false;
	};

	struct Option {
	char shortOption = '\0';
	std::string longOption;
	std::string help;
	std::function<Status(ParsedOptions*)> op;
	};

	std::string getShortOptions(const std::vector<Option>& options) {
	std::stringstream ret;
	for (const auto& e : options)
	if (e.shortOption != '\0') ret << e.shortOption;
	return ret.str();
	}

	std::unique_ptr<struct option[]> getLongOptions(const std::vector<Option>& options,
	int* longOptFlag) {
	std::unique_ptr<struct option[]> ret{new struct option[options.size() + 1]};
	int i = 0;
	for (const auto& e : options) {
	ret[i].name = e.longOption.c_str();
	ret[i].has_arg = no_argument;
	ret[i].flag = longOptFlag;
	ret[i].val = i;

	i++;
	}
	// getopt_long last option has all zeros
	ret[i].name = NULL;
	ret[i].has_arg = 0;
	ret[i].flag = NULL;
	ret[i].val = 0;

	return ret;
	}

	Status parseOptions(int argc, char** argv, const std::vector<Option>& options, ParsedOptions* out) {
	int longOptFlag;
	std::unique_ptr<struct option[]> longOptions = getLongOptions(options, &longOptFlag);
	std::string shortOptions = getShortOptions(options);
	int optionIndex;
	for (;;) {
	int c = getopt_long(argc, argv, shortOptions.c_str(), longOptions.get(), &optionIndex);
	if (c == -1) {
	break;
	}
	const Option* found = nullptr;
	for (size_t i = 0; i < options.size(); ++i)
	if ((c == 0 && longOptFlag == static_cast<int>(i)) \|\|
	(c != 0 && c == options[i].shortOption))

	found = &options[i];

	if (found == nullptr) {
	// see unrecognized options
	std::cerr << "unrecognized option `" << argv[optind - 1] << "'" << std::endl;
	return USAGE;
	}

	Status status = found->op(out);
	if (status != OK) return status;
	}
	if (optind < argc) {
	// see non option
	std::cerr << "unrecognized option `" << argv[optind] << "'" << std::endl;
	return USAGE;
	}
	return OK;
	}

	void usage(char* me, const std::vector<Option>& options) {
	std::cerr << me << ": dump VINTF metadata via libvintf." << std::endl;
	for (const auto& e : options) {
	if (e.help.empty()) continue;
	std::cerr << " ";
	if (e.shortOption != '\0') std::cerr << "-" << e.shortOption;
	if (e.shortOption != '\0' && !e.longOption.empty()) std::cerr << ", ";
	if (!e.longOption.empty()) std::cerr << "--" << e.longOption;
	std::cerr << ": "
	<< android::base::Join(android::base::Split(e.help, "\n"), "\n ")
	<< std::endl;
	}
	}

	struct TableRow {
	// Whether the HAL version is in device manifest, framework manifest, device compatibility
	// matrix, framework compatibility matrix, respectively.
	bool dm = false;
	bool fm = false;
	bool dcm = false;
	bool fcm = false;
	// If the HAL version is in device / framework compatibility matrix, whether it is required
	// or not.
	bool required = false;

	// Return true if:
	// - not a required HAL version; OR
	// - required in device matrix and framework manifest;
	// - required in framework matrix and device manifest.
	bool meetsReqeuirement() const {
	if (!required) return true;
	if (dcm && !fm) return false;
	if (fcm && !dm) return false;
	return true;
	}
	};

	std::ostream& operator<<(std::ostream& out, const TableRow& row) {
	return out << (row.required ? "R" : " ") << (row.meetsReqeuirement() ? " " : "!")
	<< kColumnSeperator << (row.dm ? "DM" : " ") << kColumnSeperator
	<< (row.fm ? "FM" : " ") << kColumnSeperator << (row.fcm ? "FCM" : " ")
	<< kColumnSeperator << (row.dcm ? "DCM" : " ");
	}

	using RowMutator = std::function<void(TableRow*)>;
	using Table = std::map<std::string, TableRow>;

	// Insert each fqInstanceName foo@x.y::IFoo/instance to the table by inserting the key
	// if it does not exist and setting the corresponding indicator (as specified by "mutate").
	void insert(const HalManifest* manifest, Table* table, const RowMutator& mutate) {
	if (manifest == nullptr) return;
	manifest->forEachInstance([&](const auto& manifestInstance) {
	std::string key = toFQNameString(manifestInstance.package(), manifestInstance.version(),
	manifestInstance.interface(), manifestInstance.instance());
	mutate(&(*table)[key]);
	return true;
	});
	}

	void insert(const CompatibilityMatrix* matrix, Table* table, const RowMutator& mutate) {
	if (matrix == nullptr) return;
	matrix->forEachInstance([&](const auto& matrixInstance) {
	for (auto minorVer = matrixInstance.versionRange().minMinor;
	minorVer <= matrixInstance.versionRange().maxMinor; ++minorVer) {
	std::string key = toFQNameString(
	matrixInstance.package(), Version{matrixInstance.versionRange().majorVer, minorVer},
	matrixInstance.interface(),
	matrixInstance.isRegex() ? matrixInstance.regexPattern()
	: matrixInstance.exactInstance());
	auto it = table->find(key);
	if (it == table->end()) {
	mutate(&(*table)[key]);
	} else {
	mutate(&it->second);
	if (minorVer == matrixInstance.versionRange().minMinor) {
	it->second.required = !matrixInstance.optional();
	}
	}
	}
	return true;
	});
	}

	Table generateHalSummary(const HalManifest* vm, const HalManifest* fm,
	const CompatibilityMatrix* vcm, const CompatibilityMatrix* fcm) {
	Table table;
	insert(vm, &table, [](auto* row) { row->dm = true; });
	insert(fm, &table, [](auto* row) { row->fm = true; });
	insert(vcm, &table, [](auto* row) { row->dcm = true; });
	insert(fcm, &table, [](auto* row) { row->fcm = true; });

	return table;
	}

	static const std::vector<Option> gAvailableOptions{
	{'h', "help", "Print help message.", [](auto) { return USAGE; }},
	{'v', "verbose", "Dump detailed and raw content, including kernel configurations", [](auto o) {
	o->verbose = true;
	return OK;
	}}};
	// A convenience binary to dump information available through libvintf.
	int main(int argc, char** argv) {
	ParsedOptions options;
	Status status = parseOptions(argc, argv, gAvailableOptions, &options);
	if (status == USAGE) usage(argv[0], gAvailableOptions);
	if (status != OK) return status;

	auto vm = VintfObject::GetDeviceHalManifest();
	auto fm = VintfObject::GetFrameworkHalManifest();
	auto vcm = VintfObject::GetDeviceCompatibilityMatrix();
	auto fcm = VintfObject::GetFrameworkCompatibilityMatrix();
	auto ki = VintfObject::GetRuntimeInfo();

	if (!options.verbose) {
	std::cout << "======== HALs =========" << std::endl
	<< "R: required. (empty): optional or missing from matrices. "
	<< "!: required and not in manifest." << std::endl
	<< "DM: device manifest. FM: framework manifest." << std::endl
	<< "FCM: framework compatibility matrix. DCM: device compatibility matrix."
	<< std::endl
	<< std::endl;
	auto table = generateHalSummary(vm.get(), fm.get(), vcm.get(), fcm.get());

	for (const auto& pair : table)
	std::cout << pair.second << kColumnSeperator << pair.first << std::endl;

	std::cout << std::endl;
	}

	SerializeFlags::Type flags = SerializeFlags::EVERYTHING;
	if (!options.verbose) {
	flags = flags.disableHals().disableKernel();
	}
	std::cout << "======== Device HAL Manifest =========" << std::endl;
	if (vm != nullptr) std::cout << gHalManifestConverter(*vm, flags);
	std::cout << "======== Framework HAL Manifest =========" << std::endl;
	if (fm != nullptr) std::cout << gHalManifestConverter(*fm, flags);
	std::cout << "======== Device Compatibility Matrix =========" << std::endl;
	if (vcm != nullptr) std::cout << gCompatibilityMatrixConverter(*vcm, flags);
	std::cout << "======== Framework Compatibility Matrix =========" << std::endl;
	if (fcm != nullptr) std::cout << gCompatibilityMatrixConverter(*fcm, flags);

	std::cout << "======== Runtime Info =========" << std::endl;
	if (ki != nullptr) std::cout << dump(*ki, options.verbose);

	std::cout << std::endl;

	std::cout << "======== Summary =========" << std::endl;
	std::cout << "Device Manifest? " << existString(vm != nullptr) << std::endl
	<< "Device Matrix? " << existString(vcm != nullptr) << std::endl
	<< "Framework Manifest? " << existString(fm != nullptr) << std::endl
	<< "Framework Matrix? " << existString(fcm != nullptr) << std::endl;
	std::string error;
	if (vm && fcm) {
	bool compatible = vm->checkCompatibility(*fcm, &error);
	std::cout << "Device HAL Manifest <==> Framework Compatibility Matrix? "
	<< boolCompatString(compatible);
	if (!compatible)
	std::cout << ", " << error;
	std::cout << std::endl;
	}
	if (fm && vcm) {
	bool compatible = fm->checkCompatibility(*vcm, &error);
	std::cout << "Framework HAL Manifest <==> Device Compatibility Matrix? "
	<< boolCompatString(compatible);
	if (!compatible)
	std::cout << ", " << error;
	std::cout << std::endl;
	}
	if (ki && fcm) {
	bool compatible = ki->checkCompatibility(*fcm, &error);
	std::cout << "Runtime info <==> Framework Compatibility Matrix? "
	<< boolCompatString(compatible);
	if (!compatible) std::cout << ", " << error;
	std::cout << std::endl;
	}

	{
	auto compatible = VintfObject::CheckCompatibility({}, &error);
	std::cout << "VintfObject::CheckCompatibility? "
	<< compatibleString(compatible);
	if (compatible != COMPATIBLE) std::cout << ", " << error;
	std::cout << std::endl;
	}

	if (vm && fcm) {
	auto deprecate = VintfObject::CheckDeprecation(&error);
	std::cout << "VintfObject::CheckDeprecation (against device manifest)? "
	<< deprecateString(deprecate);
	if (deprecate != NO_DEPRECATED_HALS) std::cout << ", " << error;
	std::cout << std::endl;
	}
	}