/** * This module contains a minimal garbage collector implementation according to * published requirements. This library is mostly intended to serve as an * example, but it is usable in applications which do not rely on a garbage * collector to clean up memory (ie. when dynamic array resizing is not used, * and all memory allocated with 'new' is freed deterministically with * 'delete'). * * Please note that block attribute data must be tracked, or at a minimum, the * FINALIZE bit must be tracked for any allocated memory block because calling * rt_finalize on a non-object block can result in an access violation. In the * allocator below, this tracking is done via a leading uint bitmask. A real * allocator may do better to store this data separately, similar to the basic * GC. * * Copyright: Copyright Sean Kelly 2005 - 2009. * License: $(WEB www.boost.org/LICENSE_1_0.txt, Boost License 1.0). * Authors: Sean Kelly */ /* Copyright Sean Kelly 2005 - 2009. * Distributed under the Boost Software License, Version 1.0. * (See accompanying file LICENSE or copy at * http://www.boost.org/LICENSE_1_0.txt) */ module gc.gc; private { import core.stdc.stdlib; import core.stdc.stdio; static import core.memory; private alias BlkAttr = core.memory.GC.BlkAttr; private alias BlkInfo = core.memory.GC.BlkInfo; extern (C) void thread_init(); extern (C) void onOutOfMemoryError(void* pretend_sideffect = null) @trusted pure nothrow @nogc; /* dmd @@@BUG11461@@@ */ struct Proxy { extern (C) void function() gc_enable; extern (C) void function() gc_disable; extern (C) void function() gc_collect; extern (C) void function() gc_minimize; extern (C) uint function(void*) gc_getAttr; extern (C) uint function(void*, uint) gc_setAttr; extern (C) uint function(void*, uint) gc_clrAttr; extern (C) void* function(size_t, uint, const TypeInfo) gc_malloc; extern (C) BlkInfo function(size_t, uint, const TypeInfo) gc_qalloc; extern (C) void* function(size_t, uint, const TypeInfo) gc_calloc; extern (C) void* function(void*, size_t, uint ba, const TypeInfo) gc_realloc; extern (C) size_t function(void*, size_t, size_t, const TypeInfo) gc_extend; extern (C) size_t function(size_t) gc_reserve; extern (C) void function(void*) gc_free; extern (C) void* function(void*) gc_addrOf; extern (C) size_t function(void*) gc_sizeOf; extern (C) BlkInfo function(void*) gc_query; extern (C) void function(void*) gc_addRoot; extern (C) void function(void*, size_t, const TypeInfo ti) gc_addRange; extern (C) void function(void*) gc_removeRoot; extern (C) void function(void*) gc_removeRange; extern (C) void function(in void[]) gc_runFinalizers; extern (C) bool function() gc_inFinalizer; } __gshared Proxy pthis; __gshared Proxy* proxy; void initProxy() { pthis.gc_enable = &gc_enable; pthis.gc_disable = &gc_disable; pthis.gc_collect = &gc_collect; pthis.gc_minimize = &gc_minimize; pthis.gc_getAttr = &gc_getAttr; pthis.gc_setAttr = &gc_setAttr; pthis.gc_clrAttr = &gc_clrAttr; pthis.gc_malloc = &gc_malloc; pthis.gc_qalloc = &gc_qalloc; pthis.gc_calloc = &gc_calloc; pthis.gc_realloc = &gc_realloc; pthis.gc_extend = &gc_extend; pthis.gc_reserve = &gc_reserve; pthis.gc_free = &gc_free; pthis.gc_addrOf = &gc_addrOf; pthis.gc_sizeOf = &gc_sizeOf; pthis.gc_query = &gc_query; pthis.gc_addRoot = &gc_addRoot; pthis.gc_addRange = &gc_addRange; pthis.gc_removeRoot = &gc_removeRoot; pthis.gc_removeRange = &gc_removeRange; pthis.gc_runFinalizers = &gc_runFinalizers; pthis.gc_inFinalizer = &gc_inFinalizer; } __gshared void** roots = null; __gshared size_t nroots = 0; struct Range { void* pos; size_t len; TypeInfo ti; // should be tail const, but doesn't exist for references } __gshared Range* ranges = null; __gshared size_t nranges = 0; } extern (C) void gc_init() { // NOTE: The GC must initialize the thread library before its first // collection, and always before returning from gc_init(). thread_init(); initProxy(); } extern (C) void gc_term() { free( roots ); free( ranges ); } extern (C) void gc_enable() { if( proxy is null ) return; return proxy.gc_enable(); } extern (C) void gc_disable() { if( proxy is null ) return; return proxy.gc_disable(); } extern (C) void gc_collect() { if( proxy is null ) return; return proxy.gc_collect(); } extern (C) void gc_minimize() { if( proxy is null ) return; return proxy.gc_minimize(); } extern (C) uint gc_getAttr( void* p ) { if( proxy is null ) return 0; return proxy.gc_getAttr( p ); } extern (C) uint gc_setAttr( void* p, uint a ) { if( proxy is null ) return 0; return proxy.gc_setAttr( p, a ); } extern (C) uint gc_clrAttr( void* p, uint a ) { if( proxy is null ) return 0; return proxy.gc_clrAttr( p, a ); } extern (C) void* gc_malloc( size_t sz, uint ba = 0, const TypeInfo ti = null ) { if( proxy is null ) { void* p = malloc( sz ); if( sz && p is null ) onOutOfMemoryError(); return p; } return proxy.gc_malloc( sz, ba, ti ); } extern (C) BlkInfo gc_qalloc( size_t sz, uint ba = 0, const TypeInfo ti = null ) { if( proxy is null ) { BlkInfo retval; retval.base = gc_malloc(sz, ba); retval.size = sz; retval.attr = ba; return retval; } return proxy.gc_qalloc( sz, ba, ti ); } extern (C) void* gc_calloc( size_t sz, uint ba = 0, const TypeInfo ti = null ) { if( proxy is null ) { void* p = calloc( 1, sz ); if( sz && p is null ) onOutOfMemoryError(); return p; } return proxy.gc_calloc( sz, ba, ti ); } extern (C) void* gc_realloc( void* p, size_t sz, uint ba = 0, const TypeInfo ti = null ) { if( proxy is null ) { p = realloc( p, sz ); if( sz && p is null ) onOutOfMemoryError(); return p; } return proxy.gc_realloc( p, sz, ba, ti ); } extern (C) size_t gc_extend( void* p, size_t mx, size_t sz, const TypeInfo ti = null ) { if( proxy is null ) return 0; return proxy.gc_extend( p, mx, sz, ti ); } extern (C) size_t gc_reserve( size_t sz ) { if( proxy is null ) return 0; return proxy.gc_reserve( sz ); } extern (C) void gc_free( void* p ) { if( proxy is null ) return free( p ); return proxy.gc_free( p ); } extern (C) void* gc_addrOf( void* p ) { if( proxy is null ) return null; return proxy.gc_addrOf( p ); } extern (C) size_t gc_sizeOf( void* p ) { if( proxy is null ) return 0; return proxy.gc_sizeOf( p ); } extern (C) BlkInfo gc_query( void* p ) { if( proxy is null ) return BlkInfo.init; return proxy.gc_query( p ); } extern (C) void gc_addRoot( void* p ) { if( proxy is null ) { void** r = cast(void**) realloc( roots, (nroots+1) * roots[0].sizeof ); if( r is null ) onOutOfMemoryError(); r[nroots++] = p; roots = r; return; } return proxy.gc_addRoot( p ); } extern (C) void gc_addRange( void* p, size_t sz, const TypeInfo ti = null ) { //printf("gcstub::gc_addRange() proxy = %p\n", proxy); if( proxy is null ) { Range* r = cast(Range*) realloc( ranges, (nranges+1) * ranges[0].sizeof ); if( r is null ) onOutOfMemoryError(); r[nranges].pos = p; r[nranges].len = sz; r[nranges].ti = cast()ti; ranges = r; ++nranges; return; } return proxy.gc_addRange( p, sz, ti ); } extern (C) void gc_removeRoot( void *p ) { if( proxy is null ) { for( size_t i = 0; i < nroots; ++i ) { if( roots[i] is p ) { roots[i] = roots[--nroots]; return; } } assert( false ); } return proxy.gc_removeRoot( p ); } extern (C) void gc_removeRange( void *p ) { if( proxy is null ) { for( size_t i = 0; i < nranges; ++i ) { if( ranges[i].pos is p ) { ranges[i] = ranges[--nranges]; return; } } assert( false ); } return proxy.gc_removeRange( p ); } extern (C) void gc_runFinalizers( in void[] segment ) { if( proxy !is null ) proxy.gc_runFinalizers( segment ); } extern (C) bool gc_inFinalizer() { if( proxy !is null ) return proxy.gc_inFinalizer(); return false; } extern (C) Proxy* gc_getProxy() { return &pthis; } export extern (C) void gc_setProxy( Proxy* p ) { if( proxy !is null ) { // TODO: Decide if this is an error condition. } proxy = p; foreach( r; roots[0 .. nroots] ) proxy.gc_addRoot( r ); foreach( r; ranges[0 .. nranges] ) proxy.gc_addRange( r.pos, r.len, r.ti ); } export extern (C) void gc_clrProxy() { foreach( r; ranges[0 .. nranges] ) proxy.gc_removeRange( r.pos ); foreach( r; roots[0 .. nroots] ) proxy.gc_removeRoot( r ); proxy = null; }