#ifndef HECL_HPP #define HECL_HPP #ifndef _WIN32 #include #include #include #include #include #include #include #else #ifndef WIN32_LEAN_AND_MEAN #define WIN32_LEAN_AND_MEAN 1 #endif #include #include #include "winsupport.hpp" #endif #include #include #include #include #include #include #include #include #include #include #include "../extern/blowfish/blowfish.h" /* Handy MIN/MAX macros */ #ifndef MAX #define MAX(x, y) (((x) > (y)) ? (x) : (y)) #define MIN(x, y) (((x) < (y)) ? (x) : (y)) #endif namespace HECL { extern unsigned VerbosityLevel; extern LogVisor::LogModule LogModule; #if _WIN32 && UNICODE #define HECL_UCS2 1 #endif std::string WideToUTF8(const std::wstring& src); std::wstring UTF8ToWide(const std::string& src); #if HECL_UCS2 typedef wchar_t SystemChar; static inline size_t StrLen(const SystemChar* str) {return wcslen(str);} typedef std::wstring SystemString; static inline void ToLower(SystemString& str) {std::transform(str.begin(), str.end(), str.begin(), towlower);} static inline void ToUpper(SystemString& str) {std::transform(str.begin(), str.end(), str.begin(), towupper);} class SystemUTF8View { std::string m_utf8; public: SystemUTF8View(const SystemString& str) : m_utf8(WideToUTF8(str)) {} inline operator const std::string&() const {return m_utf8;} inline const std::string& str() const {return m_utf8;} inline std::string operator+(const std::string& other) const {return m_utf8 + other;} inline std::string operator+(const char* other) const {return m_utf8 + other;} }; inline std::string operator+(const std::string& lhs, const SystemUTF8View& rhs) {return lhs + std::string(rhs);} inline std::string operator+(const char* lhs, const SystemUTF8View& rhs) {return lhs + std::string(rhs);} class SystemStringView { std::wstring m_sys; public: SystemStringView(const std::string& str) : m_sys(UTF8ToWide(str)) {} inline operator const std::wstring&() const {return m_sys;} inline const std::wstring& sys_str() const {return m_sys;} inline std::wstring operator+(const std::wstring& other) const {return m_sys + other;} inline std::wstring operator+(const wchar_t* other) const {return m_sys + other;} }; inline std::wstring operator+(const std::wstring& lhs, const SystemStringView& rhs) {return lhs + std::wstring(rhs);} inline std::wstring operator+(const wchar_t* lhs, const SystemStringView& rhs) {return lhs + std::wstring(rhs);} #ifndef _S #define _S(val) L ## val #endif typedef struct _stat Sstat; #else typedef char SystemChar; static inline size_t StrLen(const SystemChar* str) {return strlen(str);} typedef std::string SystemString; static inline void ToLower(SystemString& str) {std::transform(str.begin(), str.end(), str.begin(), tolower);} static inline void ToUpper(SystemString& str) {std::transform(str.begin(), str.end(), str.begin(), toupper);} class SystemUTF8View { const std::string& m_utf8; public: SystemUTF8View(const SystemString& str) : m_utf8(str) {} inline operator const std::string&() const {return m_utf8;} inline const std::string& str() const {return m_utf8;} inline std::string operator+(const std::string& other) const {return std::string(m_utf8) + other;} inline std::string operator+(const char* other) const {return std::string(m_utf8) + other;} }; inline std::string operator+(const std::string& lhs, const SystemUTF8View& rhs) {return lhs + std::string(rhs);} inline std::string operator+(const char* lhs, const SystemUTF8View& rhs) {return lhs + std::string(rhs);} class SystemStringView { const std::string& m_sys; public: SystemStringView(const std::string& str) : m_sys(str) {} inline operator const std::string&() const {return m_sys;} inline const std::string& sys_str() const {return m_sys;} inline std::string operator+(const std::string& other) const {return m_sys + other;} inline std::string operator+(const char* other) const {return m_sys + other;} }; inline std::string operator+(const std::string& lhs, const SystemStringView& rhs) {return lhs + std::string(rhs);} inline std::string operator+(const char* lhs, const SystemStringView& rhs) {return lhs + std::string(rhs);} #ifndef _S #define _S(val) val #endif typedef struct stat Sstat; #endif void SanitizePath(std::string& path); void SanitizePath(std::wstring& path); static inline void Unlink(const SystemChar* file) { #if _WIN32 _wunlink(file); #else unlink(file); #endif } static inline void MakeDir(const char* dir) { #if _WIN32 HRESULT err; if (!CreateDirectoryA(dir, NULL)) if ((err = GetLastError()) != ERROR_ALREADY_EXISTS) LogModule.report(LogVisor::FatalError, _S("MakeDir(%s)"), dir); #else if (mkdir(dir, 0755)) if (errno != EEXIST) LogModule.report(LogVisor::FatalError, "MakeDir(%s): %s", dir, strerror(errno)); #endif } #if _WIN32 static inline void MakeDir(const wchar_t* dir) { HRESULT err; if (!CreateDirectoryW(dir, NULL)) if ((err = GetLastError()) != ERROR_ALREADY_EXISTS) LogModule.report(LogVisor::FatalError, _S("MakeDir(%s)"), dir); } #endif static inline void MakeLink(const SystemChar* target, const SystemChar* linkPath) { #if _WIN32 HRESULT res = CreateShellLink(target, linkPath, _S("HECL Link")); /* :(( */ if (!SUCCEEDED(res)) { LPWSTR messageBuffer = nullptr; size_t size = FormatMessageW(FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS, NULL, res, MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT), (LPWSTR)&messageBuffer, 0, NULL); /* :((( */ LogModule.report(LogVisor::FatalError, _S("MakeLink(%s, %s): %s"), target, linkPath, messageBuffer); } #else if (symlink(target, linkPath)) /* :) */ if (errno != EEXIST) LogModule.report(LogVisor::FatalError, "MakeLink(%s, %s): %s", target, linkPath, strerror(errno)); #endif } static inline SystemChar* Getcwd(SystemChar* buf, int maxlen) { #if HECL_UCS2 return _wgetcwd(buf, maxlen); #else return getcwd(buf, maxlen); #endif } enum FileLockType { LNONE = 0, LREAD, LWRITE }; static inline FILE* Fopen(const SystemChar* path, const SystemChar* mode, FileLockType lock=LNONE) { #if HECL_UCS2 FILE* fp = _wfopen(path, mode); if (!fp) LogModule.report(LogVisor::FatalError, L"fopen %s: %s", path, _wcserror(errno)); #else FILE* fp = fopen(path, mode); if (!fp) LogModule.report(LogVisor::FatalError, "fopen %s: %s", path, strerror(errno)); #endif if (lock) { #if _WIN32 OVERLAPPED ov = {}; LockFileEx((HANDLE)(uintptr_t)_fileno(fp), (lock == LWRITE) ? LOCKFILE_EXCLUSIVE_LOCK : 0, 0, 0, 1, &ov); #else if (flock(fileno(fp), ((lock == LWRITE) ? LOCK_EX : LOCK_SH) | LOCK_NB)) LogModule.report(LogVisor::FatalError, "flock %s: %s", path, strerror(errno)); #endif } return fp; } static inline int Stat(const SystemChar* path, Sstat* statOut) { #if HECL_UCS2 return _wstat(path, statOut); #else return stat(path, statOut); #endif } static inline void Printf(const SystemChar* format, ...) { va_list va; va_start(va, format); #if HECL_UCS2 vwprintf(format, va); #else vprintf(format, va); #endif va_end(va); } static inline void FPrintf(FILE* fp, const SystemChar* format, ...) { va_list va; va_start(va, format); #if HECL_UCS2 vfwprintf(fp, format, va); #else vfprintf(fp, format, va); #endif va_end(va); } static inline void SNPrintf(SystemChar* str, size_t maxlen, const SystemChar* format, ...) { va_list va; va_start(va, format); #if HECL_UCS2 _vsnwprintf(str, maxlen, format, va); #else vsnprintf(str, maxlen, format, va); #endif va_end(va); } #define FORMAT_BUF_SZ 1024 static inline SystemString SysFormat(const SystemChar* format, ...) { SystemChar resultBuf[FORMAT_BUF_SZ]; va_list va; va_start(va, format); #if HECL_UCS2 int printSz = vswprintf(resultBuf, FORMAT_BUF_SZ, format, va); #else int printSz = vsnprintf(resultBuf, FORMAT_BUF_SZ, format, va); #endif va_end(va); return SystemString(resultBuf, printSz); } static inline std::string Format(const char* format, ...) { char resultBuf[FORMAT_BUF_SZ]; va_list va; va_start(va, format); int printSz = vsnprintf(resultBuf, FORMAT_BUF_SZ, format, va); va_end(va); return std::string(resultBuf, printSz); } static inline int ConsoleWidth() { int retval = 80; #if _WIN32 CONSOLE_SCREEN_BUFFER_INFO info; GetConsoleScreenBufferInfo(GetStdHandle(STD_OUTPUT_HANDLE), &info); retval = info.dwSize.X; #else struct winsize w; if (ioctl(STDOUT_FILENO, TIOCGWINSZ, &w) != -1) retval = w.ws_col; #endif if (retval < 10) return 10; return retval; } typedef std::basic_regex SystemRegex; typedef std::regex_token_iterator SystemRegexTokenIterator; typedef std::match_results SystemRegexMatch; class ProjectRootPath; /** * @brief FourCC representation used within HECL's database * * FourCCs are efficient, mnemonic four-char-sequences used to represent types * while fitting comfortably in a 32-bit word. HECL uses a four-char array * to remain endian-independent. * * This class also functions as a read/write Athena DNA type, * for easy initialization of FourCCs in DNA data records. */ class FourCC { protected: union { char fcc[4]; uint32_t num; }; public: FourCC() /* Sentinel FourCC */ : num(0) {} FourCC(const FourCC& other) {num = other.num;} FourCC(const char* name) : num(*(uint32_t*)name) {} FourCC(uint32_t n) : num(n) {} inline bool operator==(const FourCC& other) const {return num == other.num;} inline bool operator!=(const FourCC& other) const {return num != other.num;} inline bool operator==(const char* other) const {return num == *(uint32_t*)other;} inline bool operator!=(const char* other) const {return num != *(uint32_t*)other;} inline bool operator==(uint32_t other) const {return num == other;} inline bool operator!=(uint32_t other) const {return num != other;} inline std::string toString() const {return std::string(fcc, 4);} inline uint32_t toUint32() const {return num;} inline operator uint32_t() const {return num;} }; #define FOURCC(chars) FourCC(SBIG(chars)) /** * @brief Hash representation used for all storable and comparable objects * * Hashes are used within HECL to avoid redundant storage of objects; * providing a rapid mechanism to compare for equality. */ class Hash final { int64_t hash; public: Hash(const void* buf, size_t len) : hash(Blowfish_hash((uint8_t*)buf, len)) {} Hash(const std::string& str) : hash(Blowfish_hash((uint8_t*)str.data(), str.size())) {} Hash(const std::wstring& str) : hash(Blowfish_hash((uint8_t*)str.data(), str.size()*2)) {} Hash(int64_t hashin) : hash(hashin) {} Hash(const Hash& other) {hash = other.hash;} inline size_t val() const {return hash;} inline Hash& operator=(const Hash& other) {hash = other.hash; return *this;} inline bool operator==(const Hash& other) const {return hash == other.hash;} inline bool operator!=(const Hash& other) const {return hash != other.hash;} inline bool operator<(const Hash& other) const {return hash < other.hash;} inline bool operator>(const Hash& other) const {return hash > other.hash;} inline bool operator<=(const Hash& other) const {return hash <= other.hash;} inline bool operator>=(const Hash& other) const {return hash >= other.hash;} }; /** * @brief Timestamp representation used for comparing modtimes of cooked resources */ class Time final { time_t ts; public: Time() : ts(time(NULL)) {} Time(time_t ti) : ts(ti) {} Time(const Time& other) {ts = other.ts;} inline time_t getTs() const {return ts;} inline Time& operator=(const Time& other) {ts = other.ts; return *this;} inline bool operator==(const Time& other) const {return ts == other.ts;} inline bool operator!=(const Time& other) const {return ts != other.ts;} inline bool operator<(const Time& other) const {return ts < other.ts;} inline bool operator>(const Time& other) const {return ts > other.ts;} inline bool operator<=(const Time& other) const {return ts <= other.ts;} inline bool operator>=(const Time& other) const {return ts >= other.ts;} }; /** * @brief Canonicalized project path representation using POSIX conventions * * HECL uses POSIX-style paths (with '/' separator) and directory tokens * ('.','..') to resolve files within a project. The database internally * uses this representation to track working files. * * This class provides a convenient way to resolve paths relative to the * project root. Part of this representation involves resolving symbolic * links to regular file/directory paths and determining its type. * * NOTE THAT PROJECT PATHS ARE TREATED AS CASE SENSITIVE!! */ class ProjectPath { protected: SystemString m_projRoot; SystemString m_absPath; SystemString m_relPath; Hash m_hash = 0; #if HECL_UCS2 std::string m_utf8AbsPath; std::string m_utf8RelPath; #endif ProjectPath(const SystemString& projRoot) : m_projRoot(projRoot), m_absPath(projRoot), m_relPath(_S(".")) { SanitizePath(m_projRoot); SanitizePath(m_relPath); SanitizePath(m_absPath); m_hash = Hash(m_relPath); #if HECL_UCS2 m_utf8AbsPath = WideToUTF8(m_absPath); m_utf8RelPath = "."; #endif } public: /** * @brief Empty constructor * * Used to preallocate ProjectPath for later population using assign() */ ProjectPath() {} /** * @brief Tests for non-empty project path */ operator bool() const {return m_absPath.size() != 0;} /** * @brief Construct a project subpath representation within another subpath * @param parentPath previously constructed ProjectPath which ultimately connects to a ProjectRootPath * @param path valid filesystem-path (relative or absolute) to subpath */ ProjectPath(const ProjectPath& parentPath, const SystemString& path) {assign(parentPath, path);} void assign(const ProjectPath& parentPath, const SystemString& path); #if HECL_UCS2 ProjectPath(const ProjectPath& parentPath, const std::string& path) {assign(parentPath, path);} void assign(const ProjectPath& parentPath, const std::string& path); #endif /** * @brief Determine if ProjectPath represents project root directory * @return true if project root directory */ inline bool isRoot() const {return m_relPath.empty();} /** * @brief Return new ProjectPath with extension added * @param ext file extension to add * @return new path with extension */ inline ProjectPath getWithExtension(const SystemChar* ext) const { ProjectPath pp(*this); pp.m_relPath += ext; pp.m_absPath += ext; return pp; } /** * @brief Access fully-canonicalized absolute path * @return Absolute path reference */ inline const SystemString& getAbsolutePath() const {return m_absPath;} /** * @brief Access fully-canonicalized project-relative path * @return Relative pointer to within absolute-path or "." for project root-directory (use isRoot to detect) */ inline const SystemString& getRelativePath() const { if (m_relPath.size()) return m_relPath; static const SystemString dot = _S("."); return dot; } /** * @brief Access fully-canonicalized absolute path in UTF-8 * @return Absolute path reference */ inline const std::string& getAbsolutePathUTF8() const { #if HECL_UCS2 return m_utf8AbsPath; #else return m_absPath; #endif } inline const std::string& getRelativePathUTF8() const { #if HECL_UCS2 return m_utf8RelPath; #else return m_relPath; #endif } /** * @brief Type of path */ enum PathType { PT_NONE, /**< If path doesn't reference a valid filesystem entity, this is returned */ PT_FILE, /**< Singular file path (confirmed with filesystem) */ PT_DIRECTORY, /**< Singular directory path (confirmed with filesystem) */ PT_GLOB /**< Glob-path (whenever one or more '*' occurs in syntax) */ }; /** * @brief Get type of path based on syntax and filesystem queries * @return Type of path */ PathType getPathType() const; /** * @brief Get time of last modification with special behaviors for directories and glob-paths * @return Time object representing entity's time of last modification * * Regular files simply return their modtime as queried from the OS * Directories return the latest modtime of all first-level regular files * Glob-paths return the latest modtime of all matched regular files */ Time getModtime() const; /** * @brief Insert glob matches into existing vector * @param outPaths Vector to add matches to (will not erase existing contents) */ void getGlobResults(std::vector& outPaths) const; /** * @brief Count how many directory levels deep in project path is * @return Level Count */ inline size_t levelCount() const { size_t count = 0; for (SystemChar ch : m_relPath) if (ch == _S('/') || ch == _S('\\')) ++count; return count; } /** * @brief Create directory at path * * Fatal log report is issued if directory is not able to be created or doesn't already exist. * If directory already exists, no action taken. */ inline void makeDir() const {MakeDir(m_absPath.c_str());} /** * @brief Create relative symbolic link at calling path targeting another path * @param target Path to target */ inline void makeLinkTo(const ProjectPath& target) const { SystemString relTarget; for (SystemChar ch : m_relPath) if (ch == _S('/') || ch == _S('\\')) relTarget += _S("../"); relTarget += target.m_relPath; MakeLink(relTarget.c_str(), m_absPath.c_str()); } /** * @brief HECL-specific blowfish hash * @return unique hash value */ inline size_t hash() const {return m_hash.val();} inline bool operator==(const ProjectPath& other) const {return m_hash == other.m_hash;} inline bool operator!=(const ProjectPath& other) const {return m_hash != other.m_hash;} }; /** * @brief Special ProjectRootPath subclass for opening HECLDatabase::IProject instances * * Constructing a ProjectPath requires supplying a ProjectRootPath to consistently * resolve canonicalized relative paths. */ class ProjectRootPath : public ProjectPath { public: ProjectRootPath(const SystemString& path) : ProjectPath(path) {} }; /** * @brief Search from within provided directory for the project root * @param path absolute or relative file path to search from * @return Newly-constructed root path or NULL if not found */ std::unique_ptr SearchForProject(const SystemString& path); #undef bswap16 #undef bswap32 #undef bswap64 /* Type-sensitive byte swappers */ template static inline T bswap16(T val) { #if __GNUC__ return __builtin_bswap16(val); #elif _WIN32 return _byteswap_ushort(val); #else return (val = (val << 8) | ((val >> 8) & 0xFF)); #endif } template static inline T bswap32(T val) { #if __GNUC__ return __builtin_bswap32(val); #elif _WIN32 return _byteswap_ulong(val); #else val = (val & 0x0000FFFF) << 16 | (val & 0xFFFF0000) >> 16; val = (val & 0x00FF00FF) << 8 | (val & 0xFF00FF00) >> 8; return val; #endif } template static inline T bswap64(T val) { #if __GNUC__ return __builtin_bswap64(val); #elif _WIN32 return _byteswap_uint64(val); #else return ((val & 0xFF00000000000000ULL) >> 56) | ((val & 0x00FF000000000000ULL) >> 40) | ((val & 0x0000FF0000000000ULL) >> 24) | ((val & 0x000000FF00000000ULL) >> 8) | ((val & 0x00000000FF000000ULL) << 8) | ((val & 0x0000000000FF0000ULL) << 24) | ((val & 0x000000000000FF00ULL) << 40) | ((val & 0x00000000000000FFULL) << 56); #endif } #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ static inline int16_t SBig(int16_t val) {return bswap16(val);} static inline uint16_t SBig(uint16_t val) {return bswap16(val);} static inline int32_t SBig(int32_t val) {return bswap32(val);} static inline uint32_t SBig(uint32_t val) {return bswap32(val);} static inline int64_t SBig(int64_t val) {return bswap64(val);} static inline uint64_t SBig(uint64_t val) {return bswap64(val);} #define SBIG(q) ( ( (q) & 0x000000FF ) << 24 | ( (q) & 0x0000FF00 ) << 8 \ | ( (q) & 0x00FF0000 ) >> 8 | ( (q) & 0xFF000000 ) >> 24 ) static inline int16_t SLittle(int16_t val) {return val;} static inline uint16_t SLittle(uint16_t val) {return val;} static inline int32_t SLittle(int32_t val) {return val;} static inline uint32_t SLittle(uint32_t val) {return val;} static inline int64_t SLittle(int64_t val) {return val;} static inline uint64_t SLittle(uint64_t val) {return val;} #define SLITTLE(q) (q) #else static inline int16_t SLittle(int16_t val) {return bswap16(val);} static inline uint16_t SLittle(uint16_t val) {return bswap16(val);} static inline int32_t SLittle(int32_t val) {return bswap32(val);} static inline uint32_t SLittle(uint32_t val) {return bswap32(val);} static inline int64_t SLittle(int64_t val) {return bswap64(val);} static inline uint64_t SLittle(uint64_t val) {return bswap64(val);} #define SLITTLE(q) ( ( (q) & 0x000000FF ) << 24 | ( (q) & 0x0000FF00 ) << 8 \ | ( (q) & 0x00FF0000 ) >> 8 | ( (q) & 0xFF000000 ) >> 24 ) static inline int16_t SBig(int16_t val) {return val;} static inline uint16_t SBig(uint16_t val) {return val;} static inline int32_t SBig(int32_t val) {return val;} static inline uint32_t SBig(uint32_t val) {return val;} static inline int64_t SBig(int64_t val) {return val;} static inline uint64_t SBig(uint64_t val) {return val;} #define SBIG(q) (q) #endif } #if _MSC_VER #define NOEXCEPT #else #define NOEXCEPT noexcept #endif namespace std { template <> struct hash { inline size_t operator()(const HECL::FourCC& val) const NOEXCEPT {return val.toUint32();} }; template <> struct hash { inline size_t operator()(const HECL::ProjectPath& val) const NOEXCEPT {return val.hash();} }; } #endif // HECL_HPP