//===-- Memory.cpp ----------------------------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "lldb/Target/Memory.h" // C Includes // C++ Includes // Other libraries and framework includes // Project includes #include "lldb/Core/DataBufferHeap.h" #include "lldb/Core/State.h" #include "lldb/Core/Log.h" #include "lldb/Target/Process.h" using namespace lldb; using namespace lldb_private; //---------------------------------------------------------------------- // MemoryCache constructor //---------------------------------------------------------------------- MemoryCache::MemoryCache(Process &process) : m_process (process), m_cache_line_byte_size (512), m_mutex (Mutex::eMutexTypeRecursive), m_cache (), m_invalid_ranges () { } //---------------------------------------------------------------------- // Destructor //---------------------------------------------------------------------- MemoryCache::~MemoryCache() { } void MemoryCache::Clear(bool clear_invalid_ranges) { Mutex::Locker locker (m_mutex); m_cache.clear(); if (clear_invalid_ranges) m_invalid_ranges.Clear(); } void MemoryCache::Flush (addr_t addr, size_t size) { if (size == 0) return; Mutex::Locker locker (m_mutex); if (m_cache.empty()) return; const uint32_t cache_line_byte_size = m_cache_line_byte_size; const addr_t end_addr = (addr + size - 1); const addr_t first_cache_line_addr = addr - (addr % cache_line_byte_size); const addr_t last_cache_line_addr = end_addr - (end_addr % cache_line_byte_size); // Watch for overflow where size will cause us to go off the end of the // 64 bit address space uint32_t num_cache_lines; if (last_cache_line_addr >= first_cache_line_addr) num_cache_lines = ((last_cache_line_addr - first_cache_line_addr)/cache_line_byte_size) + 1; else num_cache_lines = (UINT64_MAX - first_cache_line_addr + 1)/cache_line_byte_size; uint32_t cache_idx = 0; for (addr_t curr_addr = first_cache_line_addr; cache_idx < num_cache_lines; curr_addr += cache_line_byte_size, ++cache_idx) { BlockMap::iterator pos = m_cache.find (curr_addr); if (pos != m_cache.end()) m_cache.erase(pos); } } void MemoryCache::AddInvalidRange (lldb::addr_t base_addr, lldb::addr_t byte_size) { if (byte_size > 0) { Mutex::Locker locker (m_mutex); InvalidRanges::Entry range (base_addr, byte_size); m_invalid_ranges.Append(range); m_invalid_ranges.Sort(); } } bool MemoryCache::RemoveInvalidRange (lldb::addr_t base_addr, lldb::addr_t byte_size) { if (byte_size > 0) { Mutex::Locker locker (m_mutex); const uint32_t idx = m_invalid_ranges.FindEntryIndexThatContains(base_addr); if (idx != UINT32_MAX) { const InvalidRanges::Entry *entry = m_invalid_ranges.GetEntryAtIndex (idx); if (entry->GetRangeBase() == base_addr && entry->GetByteSize() == byte_size) return m_invalid_ranges.RemoveEntrtAtIndex (idx); } } return false; } size_t MemoryCache::Read (addr_t addr, void *dst, size_t dst_len, Error &error) { size_t bytes_left = dst_len; if (dst && bytes_left > 0) { const uint32_t cache_line_byte_size = m_cache_line_byte_size; uint8_t *dst_buf = (uint8_t *)dst; addr_t curr_addr = addr - (addr % cache_line_byte_size); addr_t cache_offset = addr - curr_addr; Mutex::Locker locker (m_mutex); while (bytes_left > 0) { if (m_invalid_ranges.FindEntryThatContains(curr_addr)) { error.SetErrorStringWithFormat("memory read failed for 0x%" PRIx64, curr_addr); return dst_len - bytes_left; } BlockMap::const_iterator pos = m_cache.find (curr_addr); BlockMap::const_iterator end = m_cache.end (); if (pos != end) { size_t curr_read_size = cache_line_byte_size - cache_offset; if (curr_read_size > bytes_left) curr_read_size = bytes_left; memcpy (dst_buf + dst_len - bytes_left, pos->second->GetBytes() + cache_offset, curr_read_size); bytes_left -= curr_read_size; curr_addr += curr_read_size + cache_offset; cache_offset = 0; if (bytes_left > 0) { // Get sequential cache page hits for (++pos; (pos != end) && (bytes_left > 0); ++pos) { assert ((curr_addr % cache_line_byte_size) == 0); if (pos->first != curr_addr) break; curr_read_size = pos->second->GetByteSize(); if (curr_read_size > bytes_left) curr_read_size = bytes_left; memcpy (dst_buf + dst_len - bytes_left, pos->second->GetBytes(), curr_read_size); bytes_left -= curr_read_size; curr_addr += curr_read_size; // We have a cache page that succeeded to read some bytes // but not an entire page. If this happens, we must cap // off how much data we are able to read... if (pos->second->GetByteSize() != cache_line_byte_size) return dst_len - bytes_left; } } } // We need to read from the process if (bytes_left > 0) { assert ((curr_addr % cache_line_byte_size) == 0); std::unique_ptr data_buffer_heap_ap(new DataBufferHeap (cache_line_byte_size, 0)); size_t process_bytes_read = m_process.ReadMemoryFromInferior (curr_addr, data_buffer_heap_ap->GetBytes(), data_buffer_heap_ap->GetByteSize(), error); if (process_bytes_read == 0) return dst_len - bytes_left; if (process_bytes_read != cache_line_byte_size) data_buffer_heap_ap->SetByteSize (process_bytes_read); m_cache[curr_addr] = DataBufferSP (data_buffer_heap_ap.release()); // We have read data and put it into the cache, continue through the // loop again to get the data out of the cache... } } } return dst_len - bytes_left; } AllocatedBlock::AllocatedBlock (lldb::addr_t addr, uint32_t byte_size, uint32_t permissions, uint32_t chunk_size) : m_addr (addr), m_byte_size (byte_size), m_permissions (permissions), m_chunk_size (chunk_size), m_offset_to_chunk_size () // m_allocated (byte_size / chunk_size) { assert (byte_size > chunk_size); } AllocatedBlock::~AllocatedBlock () { } lldb::addr_t AllocatedBlock::ReserveBlock (uint32_t size) { addr_t addr = LLDB_INVALID_ADDRESS; if (size <= m_byte_size) { const uint32_t needed_chunks = CalculateChunksNeededForSize (size); Log *log (GetLogIfAllCategoriesSet (LIBLLDB_LOG_PROCESS | LIBLLDB_LOG_VERBOSE)); if (m_offset_to_chunk_size.empty()) { m_offset_to_chunk_size[0] = needed_chunks; if (log) log->Printf ("[1] AllocatedBlock::ReserveBlock (size = %u (0x%x)) => offset = 0x%x, %u %u bit chunks", size, size, 0, needed_chunks, m_chunk_size); addr = m_addr; } else { uint32_t last_offset = 0; OffsetToChunkSize::const_iterator pos = m_offset_to_chunk_size.begin(); OffsetToChunkSize::const_iterator end = m_offset_to_chunk_size.end(); while (pos != end) { if (pos->first > last_offset) { const uint32_t bytes_available = pos->first - last_offset; const uint32_t num_chunks = CalculateChunksNeededForSize (bytes_available); if (num_chunks >= needed_chunks) { m_offset_to_chunk_size[last_offset] = needed_chunks; if (log) log->Printf ("[2] AllocatedBlock::ReserveBlock (size = %u (0x%x)) => offset = 0x%x, %u %u bit chunks", size, size, last_offset, needed_chunks, m_chunk_size); addr = m_addr + last_offset; break; } } last_offset = pos->first + pos->second * m_chunk_size; if (++pos == end) { // Last entry... const uint32_t chunks_left = CalculateChunksNeededForSize (m_byte_size - last_offset); if (chunks_left >= needed_chunks) { m_offset_to_chunk_size[last_offset] = needed_chunks; if (log) log->Printf ("[3] AllocatedBlock::ReserveBlock (size = %u (0x%x)) => offset = 0x%x, %u %u bit chunks", size, size, last_offset, needed_chunks, m_chunk_size); addr = m_addr + last_offset; break; } } } } // const uint32_t total_chunks = m_allocated.size (); // uint32_t unallocated_idx = 0; // uint32_t allocated_idx = m_allocated.find_first(); // uint32_t first_chunk_idx = UINT32_MAX; // uint32_t num_chunks; // while (1) // { // if (allocated_idx == UINT32_MAX) // { // // No more bits are set starting from unallocated_idx, so we // // either have enough chunks for the request, or we don't. // // Eiter way we break out of the while loop... // num_chunks = total_chunks - unallocated_idx; // if (needed_chunks <= num_chunks) // first_chunk_idx = unallocated_idx; // break; // } // else if (allocated_idx > unallocated_idx) // { // // We have some allocated chunks, check if there are enough // // free chunks to satisfy the request? // num_chunks = allocated_idx - unallocated_idx; // if (needed_chunks <= num_chunks) // { // // Yep, we have enough! // first_chunk_idx = unallocated_idx; // break; // } // } // // while (unallocated_idx < total_chunks) // { // if (m_allocated[unallocated_idx]) // ++unallocated_idx; // else // break; // } // // if (unallocated_idx >= total_chunks) // break; // // allocated_idx = m_allocated.find_next(unallocated_idx); // } // // if (first_chunk_idx != UINT32_MAX) // { // const uint32_t end_bit_idx = unallocated_idx + needed_chunks; // for (uint32_t idx = first_chunk_idx; idx < end_bit_idx; ++idx) // m_allocated.set(idx); // return m_addr + m_chunk_size * first_chunk_idx; // } } Log *log (GetLogIfAllCategoriesSet (LIBLLDB_LOG_PROCESS | LIBLLDB_LOG_VERBOSE)); if (log) log->Printf ("AllocatedBlock::ReserveBlock (size = %u (0x%x)) => 0x%16.16" PRIx64, size, size, (uint64_t)addr); return addr; } bool AllocatedBlock::FreeBlock (addr_t addr) { uint32_t offset = addr - m_addr; OffsetToChunkSize::iterator pos = m_offset_to_chunk_size.find (offset); bool success = false; if (pos != m_offset_to_chunk_size.end()) { m_offset_to_chunk_size.erase (pos); success = true; } Log *log (GetLogIfAllCategoriesSet (LIBLLDB_LOG_PROCESS | LIBLLDB_LOG_VERBOSE)); if (log) log->Printf ("AllocatedBlock::FreeBlock (addr = 0x%16.16" PRIx64 ") => %i", (uint64_t)addr, success); return success; } AllocatedMemoryCache::AllocatedMemoryCache (Process &process) : m_process (process), m_mutex (Mutex::eMutexTypeRecursive), m_memory_map() { } AllocatedMemoryCache::~AllocatedMemoryCache () { } void AllocatedMemoryCache::Clear() { Mutex::Locker locker (m_mutex); if (m_process.IsAlive()) { PermissionsToBlockMap::iterator pos, end = m_memory_map.end(); for (pos = m_memory_map.begin(); pos != end; ++pos) m_process.DoDeallocateMemory(pos->second->GetBaseAddress()); } m_memory_map.clear(); } AllocatedMemoryCache::AllocatedBlockSP AllocatedMemoryCache::AllocatePage (uint32_t byte_size, uint32_t permissions, uint32_t chunk_size, Error &error) { AllocatedBlockSP block_sp; const size_t page_size = 4096; const size_t num_pages = (byte_size + page_size - 1) / page_size; const size_t page_byte_size = num_pages * page_size; addr_t addr = m_process.DoAllocateMemory(page_byte_size, permissions, error); Log *log (GetLogIfAllCategoriesSet (LIBLLDB_LOG_PROCESS)); if (log) { log->Printf ("Process::DoAllocateMemory (byte_size = 0x%8.8zx, permissions = %s) => 0x%16.16" PRIx64, page_byte_size, GetPermissionsAsCString(permissions), (uint64_t)addr); } if (addr != LLDB_INVALID_ADDRESS) { block_sp.reset (new AllocatedBlock (addr, page_byte_size, permissions, chunk_size)); m_memory_map.insert (std::make_pair (permissions, block_sp)); } return block_sp; } lldb::addr_t AllocatedMemoryCache::AllocateMemory (size_t byte_size, uint32_t permissions, Error &error) { Mutex::Locker locker (m_mutex); addr_t addr = LLDB_INVALID_ADDRESS; std::pair range = m_memory_map.equal_range (permissions); for (PermissionsToBlockMap::iterator pos = range.first; pos != range.second; ++pos) { addr = (*pos).second->ReserveBlock (byte_size); } if (addr == LLDB_INVALID_ADDRESS) { AllocatedBlockSP block_sp (AllocatePage (byte_size, permissions, 16, error)); if (block_sp) addr = block_sp->ReserveBlock (byte_size); } Log *log (GetLogIfAllCategoriesSet (LIBLLDB_LOG_PROCESS)); if (log) log->Printf ("AllocatedMemoryCache::AllocateMemory (byte_size = 0x%8.8zx, permissions = %s) => 0x%16.16" PRIx64, byte_size, GetPermissionsAsCString(permissions), (uint64_t)addr); return addr; } bool AllocatedMemoryCache::DeallocateMemory (lldb::addr_t addr) { Mutex::Locker locker (m_mutex); PermissionsToBlockMap::iterator pos, end = m_memory_map.end(); bool success = false; for (pos = m_memory_map.begin(); pos != end; ++pos) { if (pos->second->Contains (addr)) { success = pos->second->FreeBlock (addr); break; } } Log *log (GetLogIfAllCategoriesSet (LIBLLDB_LOG_PROCESS)); if (log) log->Printf("AllocatedMemoryCache::DeallocateMemory (addr = 0x%16.16" PRIx64 ") => %i", (uint64_t)addr, success); return success; }