#include "mem2alloc.hpp" #include #include #include #include "lockMutex.hpp" void CMEM2Alloc::init(unsigned int size) { m_baseAddress = (SBlock *)(((u32)SYS_GetArena2Lo() + 31) & ~31); m_endAddress = (SBlock *)((char *)m_baseAddress + std::min(size * 0x100000, SYS_GetArena2Size() & ~31)); if (m_endAddress > (SBlock *)0x93100000) m_endAddress = (SBlock *)0x93100000; SYS_SetArena2Lo(m_endAddress); LWP_MutexInit(&m_mutex, 0); } void CMEM2Alloc::init(void *addr, void *end) { m_baseAddress = (SBlock *)(((u32)addr + 31) & ~31); m_endAddress = (SBlock *)((u32)end & ~31); LWP_MutexInit(&m_mutex, 0); } void CMEM2Alloc::cleanup(void) { LWP_MutexDestroy(m_mutex); m_mutex = 0; m_first = 0; // Try to release the range we took through SYS functions if (SYS_GetArena2Lo() == m_endAddress) SYS_SetArena2Lo(m_baseAddress); m_baseAddress = 0; m_endAddress = 0; } void CMEM2Alloc::clear(void) { m_first = 0; memset(m_baseAddress, 0, (u8 *)m_endAddress - (u8 *)m_baseAddress); } unsigned int CMEM2Alloc::usableSize(void *p) { return p == 0 ? 0 : ((SBlock *)p - 1)->s * sizeof (SBlock); } void *CMEM2Alloc::allocate(unsigned int s) { if (s == 0) s = 1; // LockMutex lock(m_mutex); // s = (s - 1) / sizeof (SBlock) + 1; // First block if (m_first == 0) { if (m_baseAddress + s + 1 >= m_endAddress) return 0; m_first = m_baseAddress; m_first->next = 0; m_first->prev = 0; m_first->s = s; m_first->f = false; return (void *)(m_first + 1); } // Search for a free block SBlock *i; SBlock *j; for (i = m_first; i != 0; i = i->next) { if (i->f && i->s >= s) break; j = i; } // Create a new block if (i == 0) { i = j + j->s + 1; if (i + s + 1 >= m_endAddress) return 0; j->next = i; i->prev = j; i->next = 0; i->s = s; i->f = false; return (void *)(i + 1); } // Reuse a free block i->f = false; // Split it if (i->s > s + 1) { j = i + s + 1; j->f = true; j->s = i->s - s - 1; i->s = s; j->next = i->next; j->prev = i; i->next = j; if (j->next != 0) j->next->prev = j; } return (void *)(i + 1); } void CMEM2Alloc::release(void *p) { if (p == 0) return; LockMutex lock(m_mutex); SBlock *i = (SBlock *)p - 1; i->f = true; // If there are no other blocks following yet, // set the remaining size to free size. - Dimok if(i->next == 0) i->s = m_endAddress - i - 1; // Merge with previous block if (i->prev != 0 && i->prev->f) { i = i->prev; i->s += i->next->s + 1; i->next = i->next->next; if (i->next != 0) i->next->prev = i; } // Merge with next block if (i->next != 0 && i->next->f) { i->s += i->next->s + 1; i->next = i->next->next; if (i->next != 0) i->next->prev = i; } } void *CMEM2Alloc::reallocate(void *p, unsigned int s) { SBlock *i; SBlock *j; void *n; if (s == 0) s = 1; if (p == 0) return allocate(s); i = (SBlock *)p - 1; s = (s - 1) / sizeof (SBlock) + 1; { LockMutex lock(m_mutex); //out of memory /* Dimok */ if (i + s + 1 >= m_endAddress) { return 0; } // Last block if (i->next == 0 && i + s + 1 < m_endAddress) { i->s = s; return p; } // Size <= current size + next block if (i->next != 0 && i->s < s && i->next->f && i->s + i->next->s + 1 >= s) { // Merge i->s += i->next->s + 1; i->next = i->next->next; if (i->next != 0) i->next->prev = i; } // Size <= current size if (i->s >= s) { // Split if (i->s > s + 1) { j = i + s + 1; j->f = true; j->s = i->s - s - 1; i->s = s; j->next = i->next; j->prev = i; i->next = j; if (j->next != 0) j->next->prev = j; } return p; } } // Size > current size n = allocate(s * sizeof (SBlock)); if (n == 0) return 0; memcpy(n, p, i->s * sizeof (SBlock)); release(p); return n; } unsigned int CMEM2Alloc::FreeSize() { LockMutex lock(m_mutex); if (m_first == 0) return (const char *) m_endAddress - (const char *) m_baseAddress; SBlock *i; unsigned int size = 0; for(i = m_first; i != 0; i = i->next) { if(i->f && i->next != 0) size += i->s; else if(i->f && i->next == 0) size += m_endAddress - i - 1; else if(!i->f && i->next == 0) size += m_endAddress - i - i->s - 1; } return size*sizeof(SBlock); }