/**************************************************************************** * * ftmemory.h * * The FreeType memory management macros (specification). * * Copyright (C) 1996-2024 by * David Turner, Robert Wilhelm, and Werner Lemberg * * This file is part of the FreeType project, and may only be used, * modified, and distributed under the terms of the FreeType project * license, LICENSE.TXT. By continuing to use, modify, or distribute * this file you indicate that you have read the license and * understand and accept it fully. * */ #ifndef FTMEMORY_H_ #define FTMEMORY_H_ #include #include FT_CONFIG_CONFIG_H #include #include "compiler-macros.h" FT_BEGIN_HEADER /************************************************************************** * * @macro: * FT_SET_ERROR * * @description: * This macro is used to set an implicit 'error' variable to a given * expression's value (usually a function call), and convert it to a * boolean which is set whenever the value is != 0. */ #undef FT_SET_ERROR #define FT_SET_ERROR( expression ) \ ( ( error = (expression) ) != 0 ) /*************************************************************************/ /*************************************************************************/ /*************************************************************************/ /**** ****/ /**** ****/ /**** M E M O R Y ****/ /**** ****/ /**** ****/ /*************************************************************************/ /*************************************************************************/ /*************************************************************************/ /* The calculation `NULL + n' is undefined in C. Even if the resulting */ /* pointer doesn't get dereferenced, this causes warnings with */ /* sanitizers. */ /* */ /* We thus provide a macro that should be used if `base' can be NULL. */ #define FT_OFFSET( base, count ) ( (base) ? (base) + (count) : NULL ) /* * C++ refuses to handle statements like p = (void*)anything, with `p' a * typed pointer. Since we don't have a `typeof' operator in standard C++, * we have to use a template to emulate it. */ #ifdef __cplusplus extern "C++" { template inline T* cplusplus_typeof( T*, void *v ) { return static_cast ( v ); } } #define FT_ASSIGNP( p, val ) (p) = cplusplus_typeof( (p), (val) ) #else #define FT_ASSIGNP( p, val ) (p) = (val) #endif #ifdef FT_DEBUG_MEMORY FT_BASE( const char* ) ft_debug_file_; FT_BASE( long ) ft_debug_lineno_; #define FT_DEBUG_INNER( exp ) ( ft_debug_file_ = __FILE__, \ ft_debug_lineno_ = __LINE__, \ (exp) ) #define FT_ASSIGNP_INNER( p, exp ) ( ft_debug_file_ = __FILE__, \ ft_debug_lineno_ = __LINE__, \ FT_ASSIGNP( p, exp ) ) #else /* !FT_DEBUG_MEMORY */ #define FT_DEBUG_INNER( exp ) (exp) #define FT_ASSIGNP_INNER( p, exp ) FT_ASSIGNP( p, exp ) #endif /* !FT_DEBUG_MEMORY */ /* * The allocation functions return a pointer, and the error code is written * to through the `p_error' parameter. */ /* The `q' variants of the functions below (`q' for `quick') don't fill */ /* the allocated or reallocated memory with zero bytes. */ FT_BASE( FT_Pointer ) ft_mem_alloc( FT_Memory memory, FT_Long size, FT_Error *p_error ); FT_BASE( FT_Pointer ) ft_mem_qalloc( FT_Memory memory, FT_Long size, FT_Error *p_error ); FT_BASE( FT_Pointer ) ft_mem_realloc( FT_Memory memory, FT_Long item_size, FT_Long cur_count, FT_Long new_count, void* block, FT_Error *p_error ); FT_BASE( FT_Pointer ) ft_mem_qrealloc( FT_Memory memory, FT_Long item_size, FT_Long cur_count, FT_Long new_count, void* block, FT_Error *p_error ); FT_BASE( void ) ft_mem_free( FT_Memory memory, const void* P ); /* The `Q' variants of the macros below (`Q' for `quick') don't fill */ /* the allocated or reallocated memory with zero bytes. */ #define FT_MEM_ALLOC( ptr, size ) \ FT_ASSIGNP_INNER( ptr, ft_mem_alloc( memory, \ (FT_Long)(size), \ &error ) ) #define FT_MEM_FREE( ptr ) \ FT_BEGIN_STMNT \ FT_DEBUG_INNER( ft_mem_free( memory, (ptr) ) ); \ (ptr) = NULL; \ FT_END_STMNT #define FT_MEM_NEW( ptr ) \ FT_MEM_ALLOC( ptr, sizeof ( *(ptr) ) ) #define FT_MEM_REALLOC( ptr, cursz, newsz ) \ FT_ASSIGNP_INNER( ptr, ft_mem_realloc( memory, \ 1, \ (FT_Long)(cursz), \ (FT_Long)(newsz), \ (ptr), \ &error ) ) #define FT_MEM_QALLOC( ptr, size ) \ FT_ASSIGNP_INNER( ptr, ft_mem_qalloc( memory, \ (FT_Long)(size), \ &error ) ) #define FT_MEM_QNEW( ptr ) \ FT_MEM_QALLOC( ptr, sizeof ( *(ptr) ) ) #define FT_MEM_QREALLOC( ptr, cursz, newsz ) \ FT_ASSIGNP_INNER( ptr, ft_mem_qrealloc( memory, \ 1, \ (FT_Long)(cursz), \ (FT_Long)(newsz), \ (ptr), \ &error ) ) #define FT_MEM_ALLOC_MULT( ptr, count, item_size ) \ FT_ASSIGNP_INNER( ptr, ft_mem_realloc( memory, \ (FT_Long)(item_size), \ 0, \ (FT_Long)(count), \ NULL, \ &error ) ) #define FT_MEM_REALLOC_MULT( ptr, oldcnt, newcnt, itmsz ) \ FT_ASSIGNP_INNER( ptr, ft_mem_realloc( memory, \ (FT_Long)(itmsz), \ (FT_Long)(oldcnt), \ (FT_Long)(newcnt), \ (ptr), \ &error ) ) #define FT_MEM_QALLOC_MULT( ptr, count, item_size ) \ FT_ASSIGNP_INNER( ptr, ft_mem_qrealloc( memory, \ (FT_Long)(item_size), \ 0, \ (FT_Long)(count), \ NULL, \ &error ) ) #define FT_MEM_QREALLOC_MULT( ptr, oldcnt, newcnt, itmsz ) \ FT_ASSIGNP_INNER( ptr, ft_mem_qrealloc( memory, \ (FT_Long)(itmsz), \ (FT_Long)(oldcnt), \ (FT_Long)(newcnt), \ (ptr), \ &error ) ) #define FT_MEM_SET_ERROR( cond ) ( (cond), error != 0 ) #define FT_MEM_SET( dest, byte, count ) \ ft_memset( dest, byte, (FT_Offset)(count) ) #define FT_MEM_COPY( dest, source, count ) \ ft_memcpy( dest, source, (FT_Offset)(count) ) #define FT_MEM_MOVE( dest, source, count ) \ ft_memmove( dest, source, (FT_Offset)(count) ) #define FT_MEM_ZERO( dest, count ) FT_MEM_SET( dest, 0, count ) #define FT_ZERO( p ) FT_MEM_ZERO( p, sizeof ( *(p) ) ) #define FT_ARRAY_ZERO( dest, count ) \ FT_MEM_ZERO( dest, \ (FT_Offset)(count) * sizeof ( *(dest) ) ) #define FT_ARRAY_COPY( dest, source, count ) \ FT_MEM_COPY( dest, \ source, \ (FT_Offset)(count) * sizeof ( *(dest) ) ) #define FT_ARRAY_MOVE( dest, source, count ) \ FT_MEM_MOVE( dest, \ source, \ (FT_Offset)(count) * sizeof ( *(dest) ) ) /* * Return the maximum number of addressable elements in an array. We limit * ourselves to INT_MAX, rather than UINT_MAX, to avoid any problems. */ #define FT_ARRAY_MAX( ptr ) ( FT_INT_MAX / sizeof ( *(ptr) ) ) #define FT_ARRAY_CHECK( ptr, count ) ( (count) <= FT_ARRAY_MAX( ptr ) ) /************************************************************************** * * The following functions macros expect that their pointer argument is * _typed_ in order to automatically compute array element sizes. */ #define FT_MEM_NEW_ARRAY( ptr, count ) \ FT_ASSIGNP_INNER( ptr, ft_mem_realloc( memory, \ sizeof ( *(ptr) ), \ 0, \ (FT_Long)(count), \ NULL, \ &error ) ) #define FT_MEM_RENEW_ARRAY( ptr, cursz, newsz ) \ FT_ASSIGNP_INNER( ptr, ft_mem_realloc( memory, \ sizeof ( *(ptr) ), \ (FT_Long)(cursz), \ (FT_Long)(newsz), \ (ptr), \ &error ) ) #define FT_MEM_QNEW_ARRAY( ptr, count ) \ FT_ASSIGNP_INNER( ptr, ft_mem_qrealloc( memory, \ sizeof ( *(ptr) ), \ 0, \ (FT_Long)(count), \ NULL, \ &error ) ) #define FT_MEM_QRENEW_ARRAY( ptr, cursz, newsz ) \ FT_ASSIGNP_INNER( ptr, ft_mem_qrealloc( memory, \ sizeof ( *(ptr) ), \ (FT_Long)(cursz), \ (FT_Long)(newsz), \ (ptr), \ &error ) ) #define FT_ALLOC( ptr, size ) \ FT_MEM_SET_ERROR( FT_MEM_ALLOC( ptr, size ) ) #define FT_REALLOC( ptr, cursz, newsz ) \ FT_MEM_SET_ERROR( FT_MEM_REALLOC( ptr, cursz, newsz ) ) #define FT_ALLOC_MULT( ptr, count, item_size ) \ FT_MEM_SET_ERROR( FT_MEM_ALLOC_MULT( ptr, count, item_size ) ) #define FT_REALLOC_MULT( ptr, oldcnt, newcnt, itmsz ) \ FT_MEM_SET_ERROR( FT_MEM_REALLOC_MULT( ptr, oldcnt, \ newcnt, itmsz ) ) #define FT_QALLOC( ptr, size ) \ FT_MEM_SET_ERROR( FT_MEM_QALLOC( ptr, size ) ) #define FT_QREALLOC( ptr, cursz, newsz ) \ FT_MEM_SET_ERROR( FT_MEM_QREALLOC( ptr, cursz, newsz ) ) #define FT_QALLOC_MULT( ptr, count, item_size ) \ FT_MEM_SET_ERROR( FT_MEM_QALLOC_MULT( ptr, count, item_size ) ) #define FT_QREALLOC_MULT( ptr, oldcnt, newcnt, itmsz ) \ FT_MEM_SET_ERROR( FT_MEM_QREALLOC_MULT( ptr, oldcnt, \ newcnt, itmsz ) ) #define FT_FREE( ptr ) FT_MEM_FREE( ptr ) #define FT_NEW( ptr ) FT_MEM_SET_ERROR( FT_MEM_NEW( ptr ) ) #define FT_NEW_ARRAY( ptr, count ) \ FT_MEM_SET_ERROR( FT_MEM_NEW_ARRAY( ptr, count ) ) #define FT_RENEW_ARRAY( ptr, curcnt, newcnt ) \ FT_MEM_SET_ERROR( FT_MEM_RENEW_ARRAY( ptr, curcnt, newcnt ) ) #define FT_QNEW( ptr ) FT_MEM_SET_ERROR( FT_MEM_QNEW( ptr ) ) #define FT_QNEW_ARRAY( ptr, count ) \ FT_MEM_SET_ERROR( FT_MEM_QNEW_ARRAY( ptr, count ) ) #define FT_QRENEW_ARRAY( ptr, curcnt, newcnt ) \ FT_MEM_SET_ERROR( FT_MEM_QRENEW_ARRAY( ptr, curcnt, newcnt ) ) FT_BASE( FT_Pointer ) ft_mem_strdup( FT_Memory memory, const char* str, FT_Error *p_error ); FT_BASE( FT_Pointer ) ft_mem_dup( FT_Memory memory, const void* address, FT_ULong size, FT_Error *p_error ); #define FT_MEM_STRDUP( dst, str ) \ (dst) = (char*)ft_mem_strdup( memory, (const char*)(str), &error ) #define FT_STRDUP( dst, str ) \ FT_MEM_SET_ERROR( FT_MEM_STRDUP( dst, str ) ) #define FT_MEM_DUP( dst, address, size ) \ FT_ASSIGNP_INNER( dst, ft_mem_dup( memory, \ (address), \ (FT_ULong)(size), \ &error ) ) #define FT_DUP( dst, address, size ) \ FT_MEM_SET_ERROR( FT_MEM_DUP( dst, address, size ) ) /* Return >= 1 if a truncation occurs. */ /* Return 0 if the source string fits the buffer. */ /* This is *not* the same as strlcpy(). */ FT_BASE( FT_Int ) ft_mem_strcpyn( char* dst, const char* src, FT_ULong size ); #define FT_STRCPYN( dst, src, size ) \ ft_mem_strcpyn( (char*)dst, (const char*)(src), (FT_ULong)(size) ) FT_END_HEADER #endif /* FTMEMORY_H_ */ /* END */