/* Copyright (c) 2008, Avian Contributors Permission to use, copy, modify, and/or distribute this software for any purpose with or without fee is hereby granted, provided that the above copyright notice and this permission notice appear in all copies. There is NO WARRANTY for this software. See license.txt for details. */ #include "bootimage.h" #include "heapwalk.h" #include "common.h" #include "machine.h" #include "util.h" #include "assembler.h" // since we aren't linking against libstdc++, we must implement this // ourselves: extern "C" void __cxa_pure_virtual(void) { abort(); } using namespace vm; namespace { bool endsWith(const char* suffix, const char* s, unsigned length) { unsigned suffixLength = strlen(suffix); return length >= suffixLength and memcmp(suffix, s + (length - suffixLength), suffixLength) == 0; } object makeCodeImage(Thread* t, Zone* zone, BootImage* image, uint8_t* code, unsigned capacity) { unsigned size = 0; t->m->processor->compileThunks(t, image, code, &size, capacity); object constants = 0; PROTECT(t, constants); object calls = 0; PROTECT(t, calls); for (Finder::Iterator it(t->m->finder); it.hasMore();) { unsigned nameSize; const char* name = it.next(&nameSize); if (endsWith(".class", name, nameSize)) { //fprintf(stderr, "%.*s\n", nameSize - 6, name); object c = resolveClass (t, makeByteArray(t, "%.*s", nameSize - 6, name)); PROTECT(t, c); if (classMethodTable(t, c)) { for (unsigned i = 0; i < arrayLength(t, classMethodTable(t, c)); ++i) { object method = arrayBody(t, classMethodTable(t, c), i); if (methodCode(t, method)) { t->m->processor->compileMethod (t, zone, code, &size, capacity, &constants, &calls, method); } } } } } for (; calls; calls = tripleThird(t, calls)) { static_cast(pointerValue(t, tripleSecond(t, calls))) ->listener->resolve(methodCompiled(t, tripleFirst(t, calls))); } image->codeSize = size; return constants; } unsigned objectSize(Thread* t, object o) { assert(t, not objectExtended(t, o)); return baseSize(t, o, objectClass(t, o)); } void visitRoots(Thread* t, BootImage* image, HeapWalker* w, object constants) { Machine* m = t->m; image->loader = w->visitRoot(m->loader); image->stringMap = w->visitRoot(m->stringMap); image->types = w->visitRoot(m->types); m->processor->visitRoots(image, w); for (; constants; constants = tripleThird(t, constants)) { w->visitRoot(tripleFirst(t, constants)); } } HeapWalker* makeHeapImage(Thread* t, BootImage* image, uintptr_t* heap, uintptr_t* map, unsigned capacity, object constants) { class Visitor: public HeapVisitor { public: Visitor(Thread* t, uintptr_t* heap, uintptr_t* map, unsigned capacity): t(t), currentObject(0), currentOffset(0), heap(heap), map(map), position(0), capacity(capacity) { } void visit(unsigned number) { if (currentObject) { unsigned index = currentObject - 1 + currentOffset; markBit(map, index); heap[index] = number; } currentObject = number; } virtual void root() { currentObject = 0; } virtual unsigned visitNew(object p) { if (p) { unsigned size = objectSize(t, p); assert(t, position + size < capacity); memcpy(heap + position, p, size * BytesPerWord); unsigned number = position + 1; position += size; visit(number); return number; } else { return 0; } } virtual void visitOld(object, unsigned number) { visit(number); } virtual void push(unsigned offset) { currentOffset = offset; } virtual void pop() { currentObject = 0; } Thread* t; unsigned currentObject; unsigned currentOffset; uintptr_t* heap; uintptr_t* map; unsigned position; unsigned capacity; } visitor(t, heap, map, capacity / BytesPerWord); HeapWalker* w = makeHeapWalker(t, &visitor); visitRoots(t, image, w, constants); image->heapSize = visitor.position * BytesPerWord; return w; } void updateConstants(Thread* t, object constants, uint8_t* code, uintptr_t* codeMap, HeapMap* heapTable) { for (; constants; constants = tripleThird(t, constants)) { intptr_t target = heapTable->find(tripleFirst(t, constants)); assert(t, target >= 0); void* dst = static_cast (pointerValue(t, tripleSecond(t, constants)))->listener->resolve(target); assert(t, reinterpret_cast(dst) >= reinterpret_cast(code)); markBit(codeMap, reinterpret_cast(dst) - reinterpret_cast(code)); } } unsigned offset(object a, uintptr_t* b) { return reinterpret_cast(b) - reinterpret_cast(a); } void writeBootImage(Thread* t, FILE* out) { Zone zone(t->m->system, t->m->heap, 64 * 1024); BootImage image; const unsigned CodeCapacity = 32 * 1024 * 1024; uint8_t* code = static_cast(t->m->heap->allocate(CodeCapacity)); uintptr_t* codeMap = static_cast (t->m->heap->allocate(codeMapSize(CodeCapacity))); memset(codeMap, 0, codeMapSize(CodeCapacity)); object constants = makeCodeImage(t, &zone, &image, code, CodeCapacity); const unsigned HeapCapacity = 32 * 1024 * 1024; uintptr_t* heap = static_cast (t->m->heap->allocate(HeapCapacity)); uintptr_t* heapMap = static_cast (t->m->heap->allocate(heapMapSize(HeapCapacity))); memset(heapMap, 0, heapMapSize(HeapCapacity)); HeapWalker* heapWalker = makeHeapImage (t, &image, heap, heapMap, HeapCapacity, constants); updateConstants(t, constants, code, codeMap, heapWalker->map()); heapWalker->dispose(); image.magic = BootImage::Magic; if (true) { fprintf(stderr, "heap size %d code size %d\n", image.heapSize, image.codeSize); } else { fwrite(&image, sizeof(BootImage), 1, out); fwrite(heapMap, pad(heapMapSize(image.heapSize)), 1, out); fwrite(heap, pad(image.heapSize), 1, out); fwrite(codeMap, pad(codeMapSize(image.codeSize)), 1, out); fwrite(code, pad(image.codeSize), 1, out); } } } // namespace int main(int ac, const char** av) { if (ac != 2) { fprintf(stderr, "usage: %s \n", av[0]); return -1; } System* s = makeSystem(0); Heap* h = makeHeap(s, 128 * 1024 * 1024); Finder* f = makeFinder(s, av[1], 0); Processor* p = makeProcessor(s, h); Machine* m = new (h->allocate(sizeof(Machine))) Machine(s, h, f, p, 0, 0); Thread* t = p->makeThread(m, 0, 0); enter(t, Thread::ActiveState); enter(t, Thread::IdleState); writeBootImage(t, stdout); return 0; }