#include "cachesim.h" #include #include #include #include #include uint64_t timestamp = 0; double sc_time_stamp() { return timestamp; } CacheSim::CacheSim() { // force random values for uninitialized signals Verilated::randReset(2); ram_ = nullptr; cache_ = new VVX_cache(); mem_rsp_active_ = false; snp_req_active_ = false; //#ifdef VCD_OUTPUT Verilated::traceEverOn(true); trace_ = new VerilatedVcdC; cache_->trace(trace_, 99); trace_->open("trace.vcd"); //#endif } CacheSim::~CacheSim() { //#ifdef VCD_OUTPUT trace_->close(); //#endif delete cache_; //need to delete the req and rsp vectors } void CacheSim::attach_ram(RAM* ram) { ram_ = ram; mem_rsp_vec_.clear(); } void CacheSim::reset() { #ifndef NDEBUG std::cout << timestamp << ": [sim] reset()" << std::endl; #endif cache_->reset = 1; this->step(); cache_->reset = 0; this->step(); mem_rsp_vec_.clear(); //clear req and rsp vecs } void CacheSim::step() { //std::cout << timestamp << ": [sim] step()" << std::endl; //toggle clock cache_->clk = 0; this->eval(); cache_->clk = 1; this->eval(); //handle core and memory reqs and rsps this->eval_reqs(); this->eval_rsps(); this->eval_mem_bus(); timestamp++; } void CacheSim::eval() { cache_->eval(); //#ifdef VCD_OUTPUT trace_->dump(timestamp); //#endif ++timestamp; } void CacheSim::run(){ //#ifndef NDEBUG //#endif this->step(); int valid = 300; int stalls = 20 + 10; while (valid > -1) { this->step(); display_miss(); if(cache_->core_rsp_valid){ get_core_rsp(); } if(!cache_->core_req_valid && !cache_->core_rsp_valid){ valid--; } stalls--; if (stalls == 20){ //stall_mem(); //send_snoop_req(); stalls--; } } } void CacheSim::clear_req(){ cache_->core_req_valid = 0; } void CacheSim::send_req(core_req_t *req){ core_req_vec_.push(req); unsigned int *data = new unsigned int[4]; core_rsp_vec_.insert(std::pair(req->tag, data)); } bool CacheSim::get_core_req_ready(){ return cache_->core_req_ready; } bool CacheSim::get_core_rsp_ready(){ return cache_->core_rsp_ready; } void CacheSim::eval_reqs(){ //check to see if cache is accepting reqs if(!core_req_vec_.empty() && cache_->core_req_ready){ core_req_t *req = core_req_vec_.front(); cache_->core_req_valid = req->valid; cache_->core_req_rw = req->rw; cache_->core_req_byteen = req->byteen; cache_->core_req_addr[0] = req->addr[0]; cache_->core_req_addr[1] = req->addr[1]; cache_->core_req_addr[2] = req->addr[2]; cache_->core_req_addr[3] = req->addr[3]; cache_->core_req_data[0] = req->data[0]; cache_->core_req_data[1] = req->data[1]; cache_->core_req_data[2] = req->data[2]; cache_->core_req_data[3] = req->data[3]; cache_->core_req_tag = req->tag; core_req_vec_.pop(); } else { clear_req(); } } void CacheSim::eval_rsps(){ //check to see if a request has been responded to if (cache_->core_rsp_valid){ core_rsp_vec_.at(cache_->core_rsp_tag)[0] = cache_->core_rsp_data[0]; core_rsp_vec_.at(cache_->core_rsp_tag)[1] = cache_->core_rsp_data[1]; core_rsp_vec_.at(cache_->core_rsp_tag)[2] = cache_->core_rsp_data[2]; core_rsp_vec_.at(cache_->core_rsp_tag)[3] = cache_->core_rsp_data[3]; } } void CacheSim::stall_mem(){ cache_->mem_req_ready = 0; } void CacheSim::send_snoop_req(){ /*cache_->snp_req_valid = 1; cache_->snp_req_addr = 0x12222222; cache_->snp_req_invalidate = 1; cache_->snp_req_tag = 0xff; */ } void CacheSim::eval_mem_bus() { if (ram_ == nullptr) { cache_->mem_req_ready = 0; return; } // schedule memory responses int dequeue_index = -1; for (int i = 0; i < mem_rsp_vec_.size(); i++) { if (mem_rsp_vec_[i].cycles_left > 0) { mem_rsp_vec_[i].cycles_left -= 1; } if ((dequeue_index == -1) && (mem_rsp_vec_[i].cycles_left == 0)) { dequeue_index = i; } } // send memory response if (mem_rsp_active_ && cache_->mem_rsp_valid && cache_->mem_rsp_ready) { mem_rsp_active_ = false; } if (!mem_rsp_active_) { if (dequeue_index != -1) { //time to respond to the request cache_->mem_rsp_valid = 1; //copy data from the rsp queue to the cache module memcpy((uint8_t*)cache_->mem_rsp_data, mem_rsp_vec_[dequeue_index].data, MEM_BLOCK_SIZE); cache_->mem_rsp_tag = mem_rsp_vec_[dequeue_index].tag; free(mem_rsp_vec_[dequeue_index].data); //take data out of the queue mem_rsp_vec_.erase(mem_rsp_vec_.begin() + dequeue_index); mem_rsp_active_ = true; } else { cache_->mem_rsp_valid = 0; } } // handle memory stalls bool mem_stalled = false; #ifdef ENABLE_MEM_STALLS if (0 == ((timestamp/2) % MEM_STALLS_MODULO)) { mem_stalled = true; } else if (mem_rsp_vec_.size() >= MEM_RQ_SIZE) { mem_stalled = true; } #endif // process memory requests if (!mem_stalled) { if (cache_->mem_req_valid) { if (cache_->mem_req_rw) { //write = 1 uint64_t byteen = cache_->mem_req_byteen; unsigned base_addr = (cache_->mem_req_addr * MEM_BLOCK_SIZE); uint8_t* data = (uint8_t*)(cache_->mem_req_data); for (int i = 0; i < MEM_BLOCK_SIZE; i++) { if ((byteen >> i) & 0x1) { (*ram_)[base_addr + i] = data[i]; } } } else { mem_req_t mem_req; mem_req.cycles_left = MEM_LATENCY; mem_req.data = (uint8_t*)malloc(MEM_BLOCK_SIZE); mem_req.tag = cache_->mem_req_tag; ram_->read(cache_->mem_req_addr * MEM_BLOCK_SIZE, MEM_BLOCK_SIZE, mem_req.data); mem_rsp_vec_.push_back(mem_req); } } } cache_->mem_req_ready = ~mem_stalled; } bool CacheSim::assert_equal(unsigned int* data, unsigned int tag){ int check = 0; unsigned int *rsp = core_rsp_vec_.at(tag); for (int i = 0; i < 4; ++i){ for (int j = 0; j < 4; ++j){ if (data[i] == rsp[j]){ check++; } } } return check; } //DEBUG void CacheSim::display_miss(){ //int i = (unsigned int)cache_->miss_vec; //std::bitset<8> x(i); //if (i) std::cout << "Miss Vec " << x << std::endl; //std::cout << "Miss Vec 0" << cache_->miss_vec[0] << std::endl; } void CacheSim::get_core_req(unsigned int (&rsp)[4]){ rsp[0] = cache_->core_rsp_data[0]; rsp[1] = cache_->core_rsp_data[1]; rsp[2] = cache_->core_rsp_data[2]; rsp[3] = cache_->core_rsp_data[3]; //std::cout << std::hex << "core_rsp_valid: " << cache_->core_rsp_valid << std::endl; //std::cout << std::hex << "core_rsp_data: " << cache_->core_rsp_data << std::endl; //std::cout << std::hex << "core_rsp_tag: " << cache_->core_rsp_tag << std::endl; } void CacheSim::get_core_rsp(){ //std::cout << cache_->genblk5_BRA_0_KET_->bank->is_fill_in_pipe<< std::endl; char check = cache_->core_rsp_valid; std::cout << std::hex << "core_rsp_valid: " << (unsigned int) check << std::endl; std::cout << std::hex << "core_rsp_data[0]: " << cache_->core_rsp_data[0] << std::endl; std::cout << std::hex << "core_rsp_data[1]: " << cache_->core_rsp_data[1] << std::endl; std::cout << std::hex << "core_rsp_data[2]: " << cache_->core_rsp_data[2] << std::endl; std::cout << std::hex << "core_rsp_data[3]: " << cache_->core_rsp_data[3] << std::endl; std::cout << std::hex << "core_rsp_tag: " << cache_->core_rsp_tag << std::endl; } void CacheSim::get_mem_req(){ std::cout << std::hex << "mem_req_valid: " << cache_->mem_req_valid << std::endl; std::cout << std::hex << "mem_req_rw: " << cache_->mem_req_rw << std::endl; std::cout << std::hex << "mem_req_byteen: " << cache_->mem_req_byteen << std::endl; std::cout << std::hex << "mem_req_addr: " << cache_->mem_req_addr << std::endl; std::cout << std::hex << "mem_req_data: " << cache_->mem_req_data << std::endl; std::cout << std::hex << "mem_req_tag: " << cache_->mem_req_tag << std::endl; } void CacheSim::get_mem_rsp(){ std::cout << std::hex << "mem_rsp_valid: " << cache_->mem_rsp_valid << std::endl; std::cout << std::hex << "mem_rsp_data: " << cache_->mem_rsp_data << std::endl; std::cout << std::hex << "mem_rsp_tag: " << cache_->mem_rsp_tag << std::endl; std::cout << std::hex << "mem_rsp_ready: " << cache_->mem_rsp_ready << std::endl; }