/* from https://github.com/smealum/ctrulib * modified to allow reducing __linear_heap_size at runtime */ #include <3ds.h> #include #include <3ds/util/rbtree.h> #include "ctr_debug.h" struct MemChunk { u8* addr; u32 size; }; struct MemBlock { MemBlock *prev, *next; u8* base; u32 size; static MemBlock* Create(u8* base, u32 size) { auto b = (MemBlock*)malloc(sizeof(MemBlock)); if (!b) return nullptr; b->prev = nullptr; b->next = nullptr; b->base = base; b->size = size; return b; } }; struct MemPool { MemBlock *first, *last; bool Ready() { return first != nullptr; } void AddBlock(MemBlock* blk) { blk->prev = last; if (last) last->next = blk; if (!first) first = blk; last = blk; } void DelBlock(MemBlock* b) { auto prev = b->prev, &pNext = prev ? prev->next : first; auto next = b->next, &nPrev = next ? next->prev : last; pNext = next; nPrev = prev; free(b); } void InsertBefore(MemBlock* b, MemBlock* p) { auto prev = b->prev, &pNext = prev ? prev->next : first; b->prev = p; p->next = b; p->prev = prev; pNext = p; } void InsertAfter(MemBlock* b, MemBlock* n) { auto next = b->next, &nPrev = next ? next->prev : last; b->next = n; n->prev = b; n->next = next; nPrev = n; } //void CoalesceLeft(MemBlock* b); void CoalesceRight(MemBlock* b); bool Allocate(MemChunk& chunk, u32 size, int align); void Deallocate(const MemChunk& chunk); void Destroy() { MemBlock* next = nullptr; for (auto b = first; b; b = next) { next = b->next; free(b); } first = nullptr; last = nullptr; } //void Dump(const char* title); u32 GetFreeSpace(); }; static rbtree_t sAddrMap; struct addrMapNode { rbtree_node node; MemChunk chunk; }; #define getAddrMapNode(x) rbtree_item((x), addrMapNode, node) static int addrMapNodeComparator(const rbtree_node_t* _lhs, const rbtree_node_t* _rhs) { auto lhs = getAddrMapNode(_lhs)->chunk.addr; auto rhs = getAddrMapNode(_rhs)->chunk.addr; if (lhs < rhs) return -1; if (lhs > rhs) return 1; return 0; } static void addrMapNodeDestructor(rbtree_node_t* a) { free(getAddrMapNode(a)); } static addrMapNode* getNode(void* addr) { addrMapNode n; n.chunk.addr = (u8*)addr; auto p = rbtree_find(&sAddrMap, &n.node); return p ? getAddrMapNode(p) : nullptr; } static addrMapNode* newNode(const MemChunk& chunk) { auto p = (addrMapNode*)malloc(sizeof(addrMapNode)); if (!p) return nullptr; p->chunk = chunk; return p; } static void delNode(addrMapNode* node) { rbtree_remove(&sAddrMap, &node->node, addrMapNodeDestructor); } extern u32 __linear_heap, __linear_heap_size; static MemPool sLinearPool; static u32 sLinearPool_maxaddr; static bool linearInit() { auto blk = MemBlock::Create((u8*)__linear_heap, __linear_heap_size); if (blk) { sLinearPool.AddBlock(blk); sLinearPool_maxaddr = __linear_heap; rbtree_init(&sAddrMap, addrMapNodeComparator); return true; } return false; } void* linearMemAlign(size_t size, size_t alignment) { // Enforce minimum alignment if (alignment < 16) alignment = 16; // Convert alignment to shift amount int shift; for (shift = 4; shift < 32; shift ++) { if ((1U<node)); if (sLinearPool_maxaddr < (u32)sLinearPool.last->base) sLinearPool_maxaddr = (u32)sLinearPool.last->base; return chunk.addr; } void* linearAlloc(size_t size) { // extern PrintConsole* currentConsole; // if(currentConsole->consoleInitialised) // { // printf("linearAlloc : 0x%08X\n", size); // DEBUG_HOLD(); // } return linearMemAlign(size, 0x80); } void* linearRealloc(void* mem, size_t size) { // TODO return NULL; } void linearFree(void* mem) { auto node = getNode(mem); if (!node) return; // Free the chunk sLinearPool.Deallocate(node->chunk); // Free the node delNode(node); } u32 linearSpaceFree() { return sLinearPool.GetFreeSpace(); } extern "C" u32 ctr_get_linear_free(void) { if(sLinearPool.last->base + sLinearPool.last->size != (u8*)__linear_heap + __linear_heap_size) return 0; return sLinearPool.last->size; } extern "C" u32 ctr_get_linear_unused(void) { return __linear_heap + __linear_heap_size - sLinearPool_maxaddr; } extern "C" void ctr_linear_free_pages(u32 pages) { if(sLinearPool.last->base + sLinearPool.last->size != (u8*)__linear_heap + __linear_heap_size) return; u32 size = pages << 12; if(size > sLinearPool.last->size) return; sLinearPool.last->size -= size; __linear_heap_size -= size; u32 tmp; svcControlMemory(&tmp, __linear_heap + __linear_heap_size, 0x0, size, MEMOP_FREE, (MemPerm)(MEMPERM_READ | MEMPERM_WRITE)); // printf("l:0x%08X-->0x%08X(-0x%08X) \n", sLinearPool.last->size + size, sLinearPool.last->size, size); // DEBUG_HOLD(); } extern "C" void ctr_linear_get_stats(void) { printf("last:\n"); printf("0x%08X --> 0x%08X (0x%08X) \n", sLinearPool.last->base, sLinearPool.last->base + sLinearPool.last->size, sLinearPool.last->size); printf("free: 0x%08X unused: 0x%08X \n", ctr_get_linear_unused(), ctr_get_linear_free()); }