#pragma once /// @file Aliases and wrapper functions that are transparently GC-enabled /// if Lix is compiled with BoehmGC enabled. #include #include #include #include #include #include #include #if HAVE_BOEHMGC #include // std::less #include // std::pair #define GC_INCLUDE_NEW #include #include #include #include "checked-arithmetic.hh" /// calloc, transparently GC-enabled. #define LIX_GC_CALLOC(size) GC_MALLOC(size) /// strdup, transaprently GC-enabled. #define LIX_GC_STRDUP(str) GC_STRDUP(str) /// Atomic GC malloc() with GC enabled, or regular malloc() otherwise. #define LIX_GC_MALLOC_ATOMIC(size) GC_MALLOC_ATOMIC(size) namespace nix { /// Alias for std::map which uses BoehmGC's allocator conditional on this Lix /// build having GC enabled. template using GcMap = std::map< KeyT, ValueT, std::less, traceable_allocator> >; /// Alias for std::vector which uses BoehmGC's allocator conditional on this Lix /// build having GC enabled. template using GcVector = std::vector>; /// Alias for std::list which uses BoehmGC's allocator conditional on this Lix /// build having GC enabled. template using GcList = std::list>; } #else #include /// calloc, transparently GC-enabled. #define LIX_GC_CALLOC(size) calloc(size, 1) /// strdup, transparently GC-enabled. #define LIX_GC_STRDUP(str) strdup(str) /// Atomic GC malloc() with GC enabled, or regular malloc() otherwise. /// The returned memory must never contain pointers. #define LIX_GC_MALLOC_ATOMIC(size) malloc(size) namespace nix { /// Alias for std::map which uses BoehmGC's allocator conditional on this Lix /// build having GC enabled. template using GcMap = std::map; /// Alias for std::vector which uses BoehmGC's allocator conditional on this Lix /// build having GC enabled. template using GcVector = std::vector; /// Alias for std::list which uses BoehmGC's allocator conditional on this Lix /// build having GC enabled. template using GcList = std::list; } #endif namespace nix { [[gnu::always_inline]] inline void * gcAllocBytes(size_t n) { // Note: various places expect the allocated memory to be zero. // Hence: calloc(). void * ptr = LIX_GC_CALLOC(n); if (ptr == nullptr) { throw std::bad_alloc(); } return ptr; } /// Typed, safe wrapper around calloc() (transparently GC-enabled). Allocates /// enough for the requested count of the specified type. Also checks for /// nullptr (and throws @ref std::bad_alloc), and casts the void pointer to /// a pointer of the specified type, for type-convenient goodness. template [[gnu::always_inline]] inline T * gcAllocType(size_t howMany = 1) { // NOTE: size_t * size_t, which can definitely overflow. // Unsigned integer overflow is definitely a bug, but isn't undefined // behavior, so we can just check if we overflowed after the fact. // However, people can and do request zero sized allocations, so we need // to check that neither of our multiplicands were zero before complaining // about it. auto checkedSz = checked::Checked(howMany) * sizeof(T); size_t sz = checkedSz.valueWrapping(); if (checkedSz.overflowed()) { // Congrats, you done did an overflow. throw std::bad_alloc(); } return static_cast(gcAllocBytes(sz)); } /// GC-transparently allocates a buffer for a C-string of @ref size *bytes*, /// meaning you should include the size needed by the NUL terminator in the /// passed size. Memory allocated with this function must never contain other /// pointers. inline char * gcAllocString(size_t size) { char * cstr = static_cast(LIX_GC_MALLOC_ATOMIC(size)); if (cstr == nullptr) { throw std::bad_alloc(); } return cstr; } /// Returns a C-string copied from @ref toCopyFrom, or a single, static empty /// string if @ref toCopyFrom is also empty. char const * gcCopyStringIfNeeded(std::string_view toCopyFrom); }