/* * Copyright (c) 1999-2008 Mark D. Hill and David A. Wood * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer; * redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution; * neither the name of the copyright holders nor the names of its * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "base/intmath.hh" #include "mem/ruby/system/CacheMemory.hh" using namespace std; ostream& operator<<(ostream& out, const CacheMemory& obj) { obj.print(out); out << flush; return out; } CacheMemory * RubyCacheParams::create() { return new CacheMemory(this); } CacheMemory::CacheMemory(const Params *p) : SimObject(p) { m_cache_size = p->size; m_latency = p->latency; m_cache_assoc = p->assoc; m_policy = p->replacement_policy; m_profiler_ptr = new CacheProfiler(name()); m_start_index_bit = p->start_index_bit; } void CacheMemory::init() { m_cache_num_sets = (m_cache_size / m_cache_assoc) / RubySystem::getBlockSizeBytes(); assert(m_cache_num_sets > 1); m_cache_num_set_bits = floorLog2(m_cache_num_sets); assert(m_cache_num_set_bits > 0); if (m_policy == "PSEUDO_LRU") m_replacementPolicy_ptr = new PseudoLRUPolicy(m_cache_num_sets, m_cache_assoc); else if (m_policy == "LRU") m_replacementPolicy_ptr = new LRUPolicy(m_cache_num_sets, m_cache_assoc); else assert(false); m_cache.resize(m_cache_num_sets); for (int i = 0; i < m_cache_num_sets; i++) { m_cache[i].resize(m_cache_assoc); for (int j = 0; j < m_cache_assoc; j++) { m_cache[i][j] = NULL; } } } CacheMemory::~CacheMemory() { if (m_replacementPolicy_ptr != NULL) delete m_replacementPolicy_ptr; delete m_profiler_ptr; for (int i = 0; i < m_cache_num_sets; i++) { for (int j = 0; j < m_cache_assoc; j++) { delete m_cache[i][j]; } } } void CacheMemory::printConfig(ostream& out) { int block_size = RubySystem::getBlockSizeBytes(); out << "Cache config: " << m_cache_name << endl; out << " cache_associativity: " << m_cache_assoc << endl; out << " num_cache_sets_bits: " << m_cache_num_set_bits << endl; const int cache_num_sets = 1 << m_cache_num_set_bits; out << " num_cache_sets: " << cache_num_sets << endl; out << " cache_set_size_bytes: " << cache_num_sets * block_size << endl; out << " cache_set_size_Kbytes: " << double(cache_num_sets * block_size) / (1<<10) << endl; out << " cache_set_size_Mbytes: " << double(cache_num_sets * block_size) / (1<<20) << endl; out << " cache_size_bytes: " << cache_num_sets * block_size * m_cache_assoc << endl; out << " cache_size_Kbytes: " << double(cache_num_sets * block_size * m_cache_assoc) / (1<<10) << endl; out << " cache_size_Mbytes: " << double(cache_num_sets * block_size * m_cache_assoc) / (1<<20) << endl; } // convert a Address to its location in the cache Index CacheMemory::addressToCacheSet(const Address& address) const { assert(address == line_address(address)); return address.bitSelect(m_start_index_bit, m_start_index_bit + m_cache_num_set_bits - 1); } // Given a cache index: returns the index of the tag in a set. // returns -1 if the tag is not found. int CacheMemory::findTagInSet(Index cacheSet, const Address& tag) const { assert(tag == line_address(tag)); // search the set for the tags m5::hash_map
::const_iterator it = m_tag_index.find(tag); if (it != m_tag_index.end()) if (m_cache[cacheSet][it->second]->m_Permission != AccessPermission_NotPresent) return it->second; return -1; // Not found } // Given a cache index: returns the index of the tag in a set. // returns -1 if the tag is not found. int CacheMemory::findTagInSetIgnorePermissions(Index cacheSet, const Address& tag) const { assert(tag == line_address(tag)); // search the set for the tags m5::hash_map::const_iterator it = m_tag_index.find(tag); if (it != m_tag_index.end()) return it->second; return -1; // Not found } bool CacheMemory::tryCacheAccess(const Address& address, RubyRequestType type, DataBlock*& data_ptr) { assert(address == line_address(address)); DPRINTF(RubyCache, "address: %s\n", address); Index cacheSet = addressToCacheSet(address); int loc = findTagInSet(cacheSet, address); if (loc != -1) { // Do we even have a tag match? AbstractCacheEntry* entry = m_cache[cacheSet][loc]; m_replacementPolicy_ptr-> touch(cacheSet, loc, g_eventQueue_ptr->getTime()); data_ptr = &(entry->getDataBlk()); if (entry->m_Permission == AccessPermission_Read_Write) { return true; } if ((entry->m_Permission == AccessPermission_Read_Only) && (type == RubyRequestType_LD || type == RubyRequestType_IFETCH)) { return true; } // The line must not be accessible } data_ptr = NULL; return false; } bool CacheMemory::testCacheAccess(const Address& address, RubyRequestType type, DataBlock*& data_ptr) { assert(address == line_address(address)); DPRINTF(RubyCache, "address: %s\n", address); Index cacheSet = addressToCacheSet(address); int loc = findTagInSet(cacheSet, address); if (loc != -1) { // Do we even have a tag match? AbstractCacheEntry* entry = m_cache[cacheSet][loc]; m_replacementPolicy_ptr-> touch(cacheSet, loc, g_eventQueue_ptr->getTime()); data_ptr = &(entry->getDataBlk()); return m_cache[cacheSet][loc]->m_Permission != AccessPermission_NotPresent; } data_ptr = NULL; return false; } // tests to see if an address is present in the cache bool CacheMemory::isTagPresent(const Address& address) const { assert(address == line_address(address)); Index cacheSet = addressToCacheSet(address); int loc = findTagInSet(cacheSet, address); if (loc == -1) { // We didn't find the tag DPRINTF(RubyCache, "No tag match for address: %s\n", address); return false; } DPRINTF(RubyCache, "address: %s found\n", address); return true; } // Returns true if there is: // a) a tag match on this address or there is // b) an unused line in the same cache "way" bool CacheMemory::cacheAvail(const Address& address) const { assert(address == line_address(address)); Index cacheSet = addressToCacheSet(address); for (int i = 0; i < m_cache_assoc; i++) { AbstractCacheEntry* entry = m_cache[cacheSet][i]; if (entry != NULL) { if (entry->m_Address == address || entry->m_Permission == AccessPermission_NotPresent) { // Already in the cache or we found an empty entry return true; } } else { return true; } } return false; } AbstractCacheEntry* CacheMemory::allocate(const Address& address, AbstractCacheEntry* entry) { assert(address == line_address(address)); assert(!isTagPresent(address)); assert(cacheAvail(address)); DPRINTF(RubyCache, "address: %s\n", address); // Find the first open slot Index cacheSet = addressToCacheSet(address); std::vector