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Diffstat (limited to 'src/accelwattch/memoryctrl.cc')
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diff --git a/src/accelwattch/memoryctrl.cc b/src/accelwattch/memoryctrl.cc new file mode 100644 index 0000000..2abb1d9 --- /dev/null +++ b/src/accelwattch/memoryctrl.cc @@ -0,0 +1,1263 @@ +/***************************************************************************** + * McPAT + * SOFTWARE LICENSE AGREEMENT + * Copyright 2012 Hewlett-Packard Development Company, L.P. + * 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.” + * + ***************************************************************************/ +/******************************************************************** + * Modified by: + ** Jingwen Leng, Univeristy of Texas, Austin * Syed Gilani, + *University of Wisconsin–Madison * Tayler Hetherington, + *University of British Columbia * Ahmed ElTantawy, University of + *British Columbia * + ********************************************************************/ +// clang-format off +#include "io.h" +#include "parameter.h" +#include "const.h" +#include "logic.h" +#include "cacti/basic_circuit.h" +#include <iostream> +#include <algorithm> +#include "XML_Parse.h" +#include <string> +#include <cmath> +#include <assert.h> +#include "memoryctrl.h" +#include "basic_components.h" +// clang-format on +/* overview of MC models: + * McPAT memory controllers are modeled according to large number of industrial + * data points. The Basic memory controller architecture is base on the Synopsis + * designs (DesignWare DDR2/DDR3-Lite memory controllers and DDR2/DDR3-Lite + * protocol controllers) as in Cadence ChipEstimator Tool + * + * An MC has 3 parts as shown in this design. McPAT models both high performance + * MC based on Niagara processor designs and curving and low power MC based on + * data points in Cadence ChipEstimator Tool. + * + * The frontend is modeled analytically, the backend is modeled empirically + * according to DDR2/DDR3-Lite protocol controllers in Cadence ChipEstimator + * Tool The PHY is modeled based on "A 100mW 9.6Gb/s Transceiver in 90nm CMOS + * for next-generation memory interfaces ," ISSCC 2006, and A 14mW 6.25Gb/s + * Transceiver in 90nm CMOS for Serial Chip-to-Chip Communication," ISSCC 2007 + * + * In Cadence ChipEstimator Tool there are two types of memory controllers: the + * full memory controllers that includes the frontend as the DesignWare + * DDR2/DDR3-Lite memory controllers and the backend only memory controllers as + * the DDR2/DDR3-Lite protocol controllers (except DesignWare DDR2/DDR3-Lite + * memory controllers, all memory controller IP in Cadence ChipEstimator Tool + * are backend memory controllers such as DDRC 1600A and DDRC 800A). Thus,to + * some extend the area and power difference between DesignWare DDR2/DDR3-Lite + * memory controllers and DDR2/DDR3-Lite protocol controllers can be an + * estimation to the frontend power and area, which is very close the + * analitically modeled results of the frontend for Niagara2@65nm + * + */ + +MCBackend::MCBackend(InputParameter* interface_ip_, const MCParam& mcp_, + enum MemoryCtrl_type mc_type_) + : l_ip(*interface_ip_), mc_type(mc_type_), mcp(mcp_) { + local_result = init_interface(&l_ip); + compute(); +} + +void MCBackend::compute() { + // double max_row_addr_width = 20.0;//Current address 12~18bits + double C_MCB, mc_power, backend_dyn, + backend_gates; //, refresh_period,refresh_freq;//Equivalent per bit Cap + // for backend, + double pmos_to_nmos_sizing_r = pmos_to_nmos_sz_ratio(); + double NMOS_sizing, PMOS_sizing; + + if (mc_type == MC) { + if (mcp.type == 0) { + // area = + // (2.2927*log(peakDataTransferRate)-14.504)*memDataWidth/144.0*(l_ip.F_sz_um/0.09); + area.set_area((2.7927 * log(mcp.peakDataTransferRate * 2) - 19.862) / + 2.0 * mcp.dataBusWidth / 128.0 * (l_ip.F_sz_um / 0.09) * + mcp.num_channels * 1e6); // um^2 + // assuming the approximately same scaling factor as seen in processors. + // C_MCB=0.2/1.3/1.3/266/64/0.09*g_ip.F_sz_um;//based on AMD Geode + // processor which has a very basic mc on chip. C_MCB + // = 1.6/200/1e6/144/1.2/1.2*g_ip.F_sz_um/0.19;//Based on Niagara power + // numbers.The base power (W) is divided by device frequency and vdd and + // scale to target process. mc_power = 0.0291*2;//29.1mW@200MHz @130nm + // From Power Analysis of SystemLevel OnChip Communication Architectures + // by Lahiri et + mc_power = + 4.32 * + 0.1; // 4.32W@1GhzMHz @65nm Cadence ChipEstimator 10% for backend + C_MCB = mc_power / 1e9 / 72 / 1.1 / 1.1 * l_ip.F_sz_um / 0.065; + power_t.readOp.dynamic = + C_MCB * g_tp.peri_global.Vdd * g_tp.peri_global.Vdd * + (mcp.dataBusWidth /*+mcp.addressBusWidth*/); // per access energy in + // memory controller + power_t.readOp.leakage = + area.get_area() / 2 * (g_tp.scaling_factor.core_tx_density) * + cmos_Isub_leakage(g_tp.min_w_nmos_, + g_tp.min_w_nmos_ * pmos_to_nmos_sizing_r, 1, inv) * + g_tp.peri_global.Vdd; // unit W + power_t.readOp.gate_leakage = + area.get_area() / 2 * (g_tp.scaling_factor.core_tx_density) * + cmos_Ig_leakage(g_tp.min_w_nmos_, + g_tp.min_w_nmos_ * pmos_to_nmos_sizing_r, 1, inv) * + g_tp.peri_global.Vdd; // unit W + + } else { + NMOS_sizing = g_tp.min_w_nmos_; + PMOS_sizing = g_tp.min_w_nmos_ * pmos_to_nmos_sizing_r; + area.set_area(0.15 * mcp.dataBusWidth / 72.0 * (l_ip.F_sz_um / 0.065) * + (l_ip.F_sz_um / 0.065) * mcp.num_channels * 1e6); // um^2 + backend_dyn = + 0.9e-9 / 800e6 * mcp.clockRate / 12800 * mcp.peakDataTransferRate * + mcp.dataBusWidth / 72.0 * g_tp.peri_global.Vdd / 1.1 * + g_tp.peri_global.Vdd / 1.1 * + (l_ip.F_sz_nm / 65.0); // Average on DDR2/3 protocol controller and + // DDRC 1600/800A in Cadence ChipEstimate + // Scaling to technology and DIMM feature. The base IP support + // DDR3-1600(PC3 12800) + backend_gates = 50000 * mcp.dataBusWidth / + 64.0; // 5000 is from Cadence ChipEstimator + + power_t.readOp.dynamic = backend_dyn; + power_t.readOp.leakage = + (backend_gates)*cmos_Isub_leakage(NMOS_sizing, PMOS_sizing, 2, nand) * + g_tp.peri_global.Vdd; // unit W + power_t.readOp.gate_leakage = + (backend_gates)*cmos_Ig_leakage(NMOS_sizing, PMOS_sizing, 2, nand) * + g_tp.peri_global.Vdd; // unit W + } + } else { // skip old model + cout << "Unknown memory controllers" << endl; + exit(0); + area.set_area(0.243 * mcp.dataBusWidth / + 8); // area based on Cadence ChipEstimator for 8bit bus + // mc_power = 4.32*0.1;//4.32W@1GhzMHz @65nm Cadence ChipEstimator 10% for + // backend + C_MCB = mc_power / 1e9 / 72 / 1.1 / 1.1 * l_ip.F_sz_um / 0.065; + power_t.readOp.leakage = + area.get_area() / 2 * (g_tp.scaling_factor.core_tx_density) * + cmos_Isub_leakage(g_tp.min_w_nmos_, + g_tp.min_w_nmos_ * pmos_to_nmos_sizing_r, 1, inv) * + g_tp.peri_global.Vdd; // unit W + power_t.readOp.gate_leakage = + area.get_area() / 2 * (g_tp.scaling_factor.core_tx_density) * + cmos_Ig_leakage(g_tp.min_w_nmos_, + g_tp.min_w_nmos_ * pmos_to_nmos_sizing_r, 1, inv) * + g_tp.peri_global.Vdd; // unit W + power_t.readOp.dynamic *= 1.2; + power_t.readOp.leakage *= 1.2; + power_t.readOp.gate_leakage *= 1.2; + // flash controller has about 20% more backend power since BCH ECC in flash + // is complex and power hungry + } + double long_channel_device_reduction = + longer_channel_device_reduction(Uncore_device); + power_t.readOp.longer_channel_leakage = + power_t.readOp.leakage * long_channel_device_reduction; +} + +void MCBackend::computeEnergy(bool is_tdp) { + // backend uses internal data buswidth + if (is_tdp) { + power.reset(); // Jingwen + // init stats for Peak + stats_t.readAc.access = 0.5 * mcp.num_channels; + stats_t.writeAc.access = 0.5 * mcp.num_channels; + tdp_stats = stats_t; + } else { + rt_power.reset(); // Jingwen + // init stats for runtime power (RTP) + // Jingwen: should use stats from XML object, modified in + // MemoryController::computeEnergy + stats_t.readAc.access = mcp.reads; + stats_t.writeAc.access = mcp.writes; + tdp_stats = stats_t; + } + if (is_tdp) { + power = power_t; + power.readOp.dynamic = (stats_t.readAc.access + stats_t.writeAc.access) * + power_t.readOp.dynamic; + + } else { + rt_power.readOp.dynamic = (stats_t.readAc.access + stats_t.writeAc.access) * + mcp.llcBlockSize * 8.0 / mcp.dataBusWidth * + power_t.readOp.dynamic; + rt_power = rt_power + power_t * pppm_lkg; + rt_power.readOp.dynamic = + rt_power.readOp.dynamic + power.readOp.dynamic * 0.1 * mcp.clockRate * + mcp.num_mcs * mcp.executionTime; + // Assume 10% of peak power is consumed by routine job including memory + // refreshing and scrubbing + } +} + +MCPHY::MCPHY(InputParameter* interface_ip_, const MCParam& mcp_, + enum MemoryCtrl_type mc_type_) + : l_ip(*interface_ip_), mc_type(mc_type_), mcp(mcp_) { + local_result = init_interface(&l_ip); + compute(); +} + +void MCPHY::compute() { + // PHY uses internal data buswidth but the actuall off-chip datawidth is + // 64bits + ecc + double pmos_to_nmos_sizing_r = pmos_to_nmos_sz_ratio(); + /* + * according to "A 100mW 9.6Gb/s Transceiver in 90nm CMOS for next-generation + * memory interfaces ," ISSCC 2006; From Cadence ChipEstimator for normal I/O + * around 0.4~0.8 mW/Gb/s + */ + double power_per_gb_per_s, phy_gates, NMOS_sizing, PMOS_sizing; + + if (mc_type == MC) { + if (mcp.type == 0) { + power_per_gb_per_s = mcp.LVDS ? 0.01 : 0.04; + // Based on die photos from Niagara 1 and 2. + // TODO merge this into undifferentiated core.PHY only achieves square + // root of the ideal scaling. area = + // (6.4323*log(peakDataTransferRate)-34.76)*memDataWidth/128.0*(l_ip.F_sz_um/0.09); + area.set_area((6.4323 * log(mcp.peakDataTransferRate * 2) - 48.134) * + mcp.dataBusWidth / 128.0 * (l_ip.F_sz_um / 0.09) * + mcp.num_channels * 1e6 / 2); // TODO:/2 + // This is from curve fitting based on Niagara 1 and 2's PHY die photo. + // This is power not energy, 10mw/Gb/s @90nm for each channel and scaling + // down power.readOp.dynamic = 0.02*memAccesses*llcBlocksize*8;//change + // from Bytes to bits. + power_t.readOp.dynamic = power_per_gb_per_s * sqrt(l_ip.F_sz_um / 0.09) * + g_tp.peri_global.Vdd / 1.2 * + g_tp.peri_global.Vdd / 1.2; + power_t.readOp.leakage = + area.get_area() / 2 * (g_tp.scaling_factor.core_tx_density) * + cmos_Isub_leakage(g_tp.min_w_nmos_, + g_tp.min_w_nmos_ * pmos_to_nmos_sizing_r, 1, inv) * + g_tp.peri_global.Vdd; // unit W + power_t.readOp.gate_leakage = + area.get_area() / 2 * (g_tp.scaling_factor.core_tx_density) * + cmos_Ig_leakage(g_tp.min_w_nmos_, + g_tp.min_w_nmos_ * pmos_to_nmos_sizing_r, 1, inv) * + g_tp.peri_global.Vdd; // unit W + + } else { + NMOS_sizing = g_tp.min_w_nmos_; + PMOS_sizing = g_tp.min_w_nmos_ * pmos_to_nmos_sizing_r; + // Designware/synopsis 16bit DDR3 PHY is 1.3mm (WITH IOs) at 40nm for upto + // DDR3 2133 (PC3 17066) + double non_IO_percentage = 0.2; + area.set_area(1.3 * non_IO_percentage / 2133.0e6 * mcp.clockRate / 17066 * + mcp.peakDataTransferRate * mcp.dataBusWidth / 16.0 * + (l_ip.F_sz_um / 0.040) * (l_ip.F_sz_um / 0.040) * + mcp.num_channels * 1e6); // um^2 + phy_gates = 200000 * mcp.dataBusWidth / 64.0; + power_per_gb_per_s = 0.01; + // This is power not energy, 10mw/Gb/s @90nm for each channel and scaling + // down + power_t.readOp.dynamic = power_per_gb_per_s * (l_ip.F_sz_um / 0.09) * + g_tp.peri_global.Vdd / 1.2 * + g_tp.peri_global.Vdd / 1.2; + power_t.readOp.leakage = + (mcp.withPHY ? phy_gates : 0) * + cmos_Isub_leakage(NMOS_sizing, PMOS_sizing, 2, nand) * + g_tp.peri_global.Vdd; // unit W + power_t.readOp.gate_leakage = + (mcp.withPHY ? phy_gates : 0) * + cmos_Ig_leakage(NMOS_sizing, PMOS_sizing, 2, nand) * + g_tp.peri_global.Vdd; // unit W + } + + } else { + area.set_area(0.4e6 / 2 * mcp.dataBusWidth / + 8); // area based on Cadence ChipEstimator for 8bit bus + } + + // double phy_factor = (int)ceil(mcp.dataBusWidth/72.0);//Previous phy power + // numbers are based on 72 bit DIMM interface power_t.readOp.dynamic *= + // phy_factor; power_t.readOp.leakage *= phy_factor; + // power_t.readOp.gate_leakage *= phy_factor; + + double long_channel_device_reduction = + longer_channel_device_reduction(Uncore_device); + power_t.readOp.longer_channel_leakage = + power_t.readOp.leakage * long_channel_device_reduction; +} + +void MCPHY::computeEnergy(bool is_tdp) { + if (is_tdp) { + power.reset(); // Jingwen + // init stats for Peak + stats_t.readAc.access = 0.5 * mcp.num_channels; // time share on buses + stats_t.writeAc.access = 0.5 * mcp.num_channels; + tdp_stats = stats_t; + } else { + rt_power.reset(); // Jingwen + // init stats for runtime power (RTP) + // Jingwen: should use stats from XML object, modified in + // MemoryController::computeEnergy + stats_t.readAc.access = mcp.reads; + stats_t.writeAc.access = mcp.writes; + tdp_stats = stats_t; + } + + if (is_tdp) { + double data_transfer_unit = (mc_type == MC) ? 72 : 16; /*DIMM data width*/ + power = power_t; + power.readOp.dynamic = + power.readOp.dynamic * + (mcp.peakDataTransferRate * 8 * 1e6 / 1e9 /*change to Gbs*/) * + mcp.dataBusWidth / data_transfer_unit * mcp.num_channels / + mcp.clockRate; + // divide by clock rate is for match the final computation where *clock is + // used + //(stats_t.readAc.access*power_t.readOp.dynamic+ + // stats_t.writeAc.access*power_t.readOp.dynamic); + + } else { + rt_power = power_t; + // rt_power.readOp.dynamic = + // (stats_t.readAc.access*power_t.readOp.dynamic+ + // stats_t.writeAc.access*power_t.readOp.dynamic); + + rt_power.readOp.dynamic = power_t.readOp.dynamic * + (stats_t.readAc.access + stats_t.writeAc.access) * + (mcp.llcBlockSize) * 8 / 1e9 / mcp.executionTime * + (mcp.executionTime); + rt_power.readOp.dynamic = + rt_power.readOp.dynamic + power.readOp.dynamic * 0.1 * mcp.clockRate * + mcp.num_mcs * mcp.executionTime; + } +} + +MCFrontEnd::MCFrontEnd(ParseXML* XML_interface, InputParameter* interface_ip_, + const MCParam& mcp_, enum MemoryCtrl_type mc_type_) + : XML(XML_interface), + interface_ip(*interface_ip_), + mc_type(mc_type_), + mcp(mcp_), + MC_arb(0), + frontendBuffer(0), + readBuffer(0), + writeBuffer(0), + coalesce_scale(1.0) { + /* All computations are for a single MC + * + */ + + int tag, data; + bool is_default = true; // indication for default setup + + /* MC frontend engine channels share the same engines but logically + * partitioned For all hardware inside MC. different channels do not share + * resources. + * TODO: add docodeing/mux stage to steer memory requests to different + * channels. + */ + + // memory request reorder buffer + tag = mcp.addressBusWidth + EXTRA_TAG_BITS + mcp.opcodeW; + data = int(ceil((XML->sys.physical_address_width + mcp.opcodeW) / 8.0)); + interface_ip.cache_sz = data * XML->sys.mc.req_window_size_per_channel; + interface_ip.line_sz = data; + interface_ip.assoc = 0; + interface_ip.nbanks = 1; + interface_ip.out_w = interface_ip.line_sz * 8; + interface_ip.specific_tag = 1; + interface_ip.tag_w = tag; + interface_ip.access_mode = 0; + interface_ip.throughput = 1.0 / mcp.clockRate; + interface_ip.latency = 1.0 / mcp.clockRate; + interface_ip.is_cache = true; + interface_ip.pure_cam = false; + interface_ip.pure_ram = false; + interface_ip.obj_func_dyn_energy = 0; + interface_ip.obj_func_dyn_power = 0; + interface_ip.obj_func_leak_power = 0; + interface_ip.obj_func_cycle_t = 1; + interface_ip.num_rw_ports = 0; + interface_ip.num_rd_ports = XML->sys.mc.memory_channels_per_mc; + interface_ip.num_wr_ports = interface_ip.num_rd_ports; + interface_ip.num_se_rd_ports = 0; + interface_ip.num_search_ports = XML->sys.mc.memory_channels_per_mc; + frontendBuffer = + new ArrayST(&interface_ip, "MC ReorderBuffer", Uncore_device); + frontendBuffer->area.set_area(frontendBuffer->area.get_area() + + frontendBuffer->local_result.area * + XML->sys.mc.memory_channels_per_mc); + area.set_area(area.get_area() + frontendBuffer->local_result.area * + XML->sys.mc.memory_channels_per_mc); + + // selection and arbitration logic + MC_arb = + new selection_logic(is_default, XML->sys.mc.req_window_size_per_channel, + 1, &interface_ip, Uncore_device); + + // read buffers. + data = + (int)ceil(mcp.dataBusWidth / 8.0); // Support key words first operation + // //8 means converting bit to Byte + interface_ip.cache_sz = + data * XML->sys.mc.IO_buffer_size_per_channel; //*llcBlockSize; + interface_ip.line_sz = data; + interface_ip.assoc = 1; + interface_ip.nbanks = 1; + interface_ip.out_w = interface_ip.line_sz * 8; + interface_ip.access_mode = 1; + interface_ip.throughput = 1.0 / mcp.clockRate; + interface_ip.latency = 2.0 / mcp.clockRate; + interface_ip.is_cache = false; + interface_ip.pure_cam = false; + interface_ip.pure_ram = true; + interface_ip.obj_func_dyn_energy = 0; + interface_ip.obj_func_dyn_power = 0; + interface_ip.obj_func_leak_power = 0; + interface_ip.obj_func_cycle_t = 1; + interface_ip.num_rw_ports = + 0; // XML->sys.mc.memory_channels_per_mc*2>2?2:XML->sys.mc.memory_channels_per_mc*2; + interface_ip.num_rd_ports = XML->sys.mc.memory_channels_per_mc; + interface_ip.num_wr_ports = interface_ip.num_rd_ports; + interface_ip.num_se_rd_ports = 0; + readBuffer = new ArrayST(&interface_ip, "MC ReadBuffer", Uncore_device); + readBuffer->area.set_area(readBuffer->area.get_area() + + readBuffer->local_result.area * + XML->sys.mc.memory_channels_per_mc); + area.set_area(area.get_area() + readBuffer->local_result.area * + XML->sys.mc.memory_channels_per_mc); + + // write buffer + data = + (int)ceil(mcp.dataBusWidth / 8.0); // Support key words first operation + // //8 means converting bit to Byte + interface_ip.cache_sz = + data * XML->sys.mc.IO_buffer_size_per_channel; //*llcBlockSize; + interface_ip.line_sz = data; + interface_ip.assoc = 1; + interface_ip.nbanks = 1; + interface_ip.out_w = interface_ip.line_sz * 8; + interface_ip.access_mode = 0; + interface_ip.throughput = 1.0 / mcp.clockRate; + interface_ip.latency = 2.0 / mcp.clockRate; + interface_ip.obj_func_dyn_energy = 0; + interface_ip.obj_func_dyn_power = 0; + interface_ip.obj_func_leak_power = 0; + interface_ip.obj_func_cycle_t = 1; + interface_ip.num_rw_ports = 0; + interface_ip.num_rd_ports = XML->sys.mc.memory_channels_per_mc; + interface_ip.num_wr_ports = interface_ip.num_rd_ports; + interface_ip.num_se_rd_ports = 0; + writeBuffer = new ArrayST(&interface_ip, "MC writeBuffer", Uncore_device); + writeBuffer->area.set_area(writeBuffer->area.get_area() + + writeBuffer->local_result.area * + XML->sys.mc.memory_channels_per_mc); + area.set_area(area.get_area() + writeBuffer->local_result.area * + XML->sys.mc.memory_channels_per_mc); + + // SRAM structures for memory coalescing --Syed Gilani + // Pending Request Table (base addresses, offset addresses, threads IDs), + // Thread Masks + //***PRT + // We assume 24 bits of base address and 8 bits of offset address. + // THese values are used for coalesing memory requests to the same base + // address block. TIDs are assumed to be 8 bits + /*Contents of each PRT entry + * + * Warp ID (6 bits) | Memory address (32 bits) per thread | Request Size + * (2-bits) per thread | line size= 6+ 32*16 + 2*16 ~ 64 bytes + * + * + */ + data = + 64; // Support key words first operation //8 means converting bit to Byte + interface_ip.cache_sz = data * XML->sys.mc.PRT_entries; // PRT table; + interface_ip.line_sz = data; + interface_ip.assoc = 1; + interface_ip.nbanks = 1; + interface_ip.out_w = interface_ip.line_sz * 8; + interface_ip.access_mode = 0; + interface_ip.throughput = 1.0 / XML->sys.target_core_clockrate; + interface_ip.latency = 2.0 / XML->sys.target_core_clockrate; + interface_ip.obj_func_dyn_energy = 0; + interface_ip.obj_func_dyn_power = 0; + interface_ip.obj_func_leak_power = 0; + interface_ip.obj_func_cycle_t = 1; + interface_ip.num_rw_ports = 0; + interface_ip.num_rd_ports = 1; + interface_ip.num_wr_ports = 1; + interface_ip.num_se_rd_ports = 0; + PRT = new ArrayST(&interface_ip, "MC PRT", Uncore_device); + PRT->area.set_area(PRT->area.get_area() + + PRT->local_result.area * + XML->sys.mc.memory_channels_per_mc); + area.set_area(area.get_area() + + PRT->local_result.area * XML->sys.mc.memory_channels_per_mc); + + //***ThreadMasks storage (coalesced threads whose memory requests are + // satisfied by each memory access) + /* contents of the thread masks Array + * 16-bit bit masks for up to 16 memory requests of a warp | Number of + * pending memory requests (5 bits) + * + * 16*PRT_entry thread Mask, each entry has 16 mask bits. + * + */ + data = 2; + interface_ip.cache_sz = data * XML->sys.mc.PRT_entries * 16; // PRT table; + interface_ip.line_sz = data; + interface_ip.assoc = 1; + interface_ip.nbanks = 1; + interface_ip.out_w = interface_ip.line_sz * 8; + interface_ip.access_mode = 0; + interface_ip.throughput = 1.0 / XML->sys.target_core_clockrate; + interface_ip.latency = 2.0 / XML->sys.target_core_clockrate; + interface_ip.obj_func_dyn_energy = 0; + interface_ip.obj_func_dyn_power = 0; + interface_ip.obj_func_leak_power = 0; + interface_ip.obj_func_cycle_t = 1; + interface_ip.num_rw_ports = 0; + interface_ip.num_rd_ports = 1; + interface_ip.num_wr_ports = 1; + interface_ip.num_se_rd_ports = 0; + threadMasks = new ArrayST(&interface_ip, "MC ThreadMasks", Uncore_device); + threadMasks->area.set_area(threadMasks->area.get_area() + + threadMasks->local_result.area * + XML->sys.mc.memory_channels_per_mc); + area.set_area(area.get_area() + threadMasks->local_result.area * + XML->sys.mc.memory_channels_per_mc); + + //***Numer of pending requests per PRT entry + /* + * 1-byte data, PRT entries deep + */ + data = 1; + interface_ip.cache_sz = data * XML->sys.mc.PRT_entries; // PRT table; + interface_ip.line_sz = data; + interface_ip.assoc = 1; + interface_ip.nbanks = 1; + interface_ip.out_w = interface_ip.line_sz * 8; + interface_ip.access_mode = 0; + interface_ip.throughput = 1.0 / XML->sys.target_core_clockrate; + interface_ip.latency = 2.0 / XML->sys.target_core_clockrate; + interface_ip.obj_func_dyn_energy = 0; + interface_ip.obj_func_dyn_power = 0; + interface_ip.obj_func_leak_power = 0; + interface_ip.obj_func_cycle_t = 1; + interface_ip.num_rw_ports = 0; + interface_ip.num_rd_ports = 1; + interface_ip.num_wr_ports = 1; + interface_ip.num_se_rd_ports = 0; + PRC = new ArrayST(&interface_ip, "MC PendingRequestCount", Uncore_device); + PRC->area.set_area(PRC->area.get_area() + + PRC->local_result.area * + XML->sys.mc.memory_channels_per_mc); + area.set_area(area.get_area() + + PRC->local_result.area * XML->sys.mc.memory_channels_per_mc); +} + +void DRAM::computeEnergy(bool is_tdp) { + if (is_tdp) { + power.reset(); + return; /// not supporting TDP calculation for DRAM + } + rt_power.reset(); + dramp.executionTime = + XML->sys.total_cycles / (XML->sys.target_core_clockrate * 1e6); + + power_t.reset(); + power_t.readOp.dynamic += XML->sys.mc.memory_reads * dramp.rd_coeff; + power_t.readOp.dynamic += XML->sys.mc.memory_writes * dramp.wr_coeff; + power_t.readOp.dynamic += XML->sys.mc.dram_pre * dramp.pre_coeff; + + rt_power = rt_power + power_t; +} + +void MCFrontEnd::computeEnergy(bool is_tdp) { + if (is_tdp) { + power.reset(); + // init stats for Peak + frontendBuffer->stats_t.readAc.access = + frontendBuffer->l_ip.num_search_ports; + frontendBuffer->stats_t.writeAc.access = frontendBuffer->l_ip.num_wr_ports; + frontendBuffer->tdp_stats = frontendBuffer->stats_t; + + readBuffer->stats_t.readAc.access = + readBuffer->l_ip.num_rd_ports * mcp.frontend_duty_cycle; + readBuffer->stats_t.writeAc.access = + readBuffer->l_ip.num_wr_ports * mcp.frontend_duty_cycle; + readBuffer->tdp_stats = readBuffer->stats_t; + + writeBuffer->stats_t.readAc.access = + writeBuffer->l_ip.num_rd_ports * mcp.frontend_duty_cycle; + writeBuffer->stats_t.writeAc.access = + writeBuffer->l_ip.num_wr_ports * mcp.frontend_duty_cycle; + writeBuffer->tdp_stats = writeBuffer->stats_t; + + PRT->stats_t.readAc.access = + PRT->l_ip.num_rd_ports * mcp.frontend_duty_cycle; + PRT->stats_t.writeAc.access = + PRT->l_ip.num_wr_ports * mcp.frontend_duty_cycle; + PRT->tdp_stats = PRT->stats_t; + + threadMasks->stats_t.readAc.access = + threadMasks->l_ip.num_rd_ports * mcp.frontend_duty_cycle; + threadMasks->stats_t.writeAc.access = + threadMasks->l_ip.num_wr_ports * mcp.frontend_duty_cycle; + threadMasks->tdp_stats = threadMasks->stats_t; + + PRC->stats_t.readAc.access = + threadMasks->l_ip.num_rd_ports * mcp.frontend_duty_cycle; + PRC->stats_t.writeAc.access = + threadMasks->l_ip.num_wr_ports * mcp.frontend_duty_cycle; + PRC->tdp_stats = threadMasks->stats_t; + + } else { + rt_power.reset(); // Jingwen + // init stats for runtime power (RTP) + frontendBuffer->stats_t.readAc.access = + XML->sys.mc.memory_reads * mcp.llcBlockSize * 8.0 / mcp.dataBusWidth * + mcp.dataBusWidth / 72; + // For each channel, each memory word need to check the address data to + // achieve best scheduling results. and this need to be done on all physical + // DIMMs in each logical memory DIMM *mcp.dataBusWidth/72 + frontendBuffer->stats_t.writeAc.access = + XML->sys.mc.memory_writes * mcp.llcBlockSize * 8.0 / mcp.dataBusWidth * + mcp.dataBusWidth / 72; + frontendBuffer->rtp_stats = frontendBuffer->stats_t; + + readBuffer->stats_t.readAc.access = + XML->sys.mc.memory_reads * mcp.llcBlockSize * 8.0 / + mcp.dataBusWidth; // support key word first + readBuffer->stats_t.writeAc.access = + XML->sys.mc.memory_reads * mcp.llcBlockSize * 8.0 / + mcp.dataBusWidth; // support key word first + readBuffer->rtp_stats = readBuffer->stats_t; + + writeBuffer->stats_t.readAc.access = + XML->sys.mc.memory_writes * mcp.llcBlockSize * 8.0 / mcp.dataBusWidth; + writeBuffer->stats_t.writeAc.access = + XML->sys.mc.memory_writes * mcp.llcBlockSize * 8.0 / mcp.dataBusWidth; + writeBuffer->rtp_stats = writeBuffer->stats_t; + + // Pending request table + // Co-alesce all misses in caches and add an entry for them in PRT + // TODO: Change 0 to ithCore and move to LSU (Syed) + // TODO: Do these accesses represent coalesced accesses? + PRT->stats_t.readAc.access = XML->sys.core[0].dcache.read_accesses + + XML->sys.core[0].ccache.read_accesses + + XML->sys.core[0].tcache.read_accesses; + PRT->stats_t.writeAc.access = XML->sys.core[0].dcache.write_accesses + + XML->sys.core[0].ccache.write_accesses + + XML->sys.core[0].tcache.write_accesses; + PRT->rtp_stats = PRT->stats_t; + + threadMasks->stats_t.readAc.access = XML->sys.core[0].dcache.read_accesses + + XML->sys.core[0].ccache.read_accesses + + XML->sys.core[0].tcache.read_accesses; + threadMasks->stats_t.writeAc.access = + XML->sys.core[0].dcache.write_accesses + + XML->sys.core[0].ccache.write_accesses + + XML->sys.core[0].tcache.write_accesses; + threadMasks->rtp_stats = threadMasks->stats_t; + + PRC->stats_t.readAc.access = XML->sys.core[0].dcache.read_accesses + + XML->sys.core[0].ccache.read_accesses + + XML->sys.core[0].tcache.read_accesses; + PRC->stats_t.writeAc.access = XML->sys.core[0].dcache.write_accesses + + XML->sys.core[0].ccache.write_accesses + + XML->sys.core[0].tcache.write_accesses; + PRC->rtp_stats = threadMasks->stats_t; + } + + frontendBuffer->power_t.reset(); + readBuffer->power_t.reset(); + writeBuffer->power_t.reset(); + threadMasks->power_t.reset(); + PRT->power_t.reset(); + PRC->power_t.reset(); + + // frontendBuffer->power_t.readOp.dynamic += + //(frontendBuffer->stats_t.readAc.access* + // (frontendBuffer->local_result.power.searchOp.dynamic+frontendBuffer->local_result.power.readOp.dynamic)+ + // frontendBuffer->stats_t.writeAc.access*frontendBuffer->local_result.power.writeOp.dynamic); + + frontendBuffer->power_t.readOp.dynamic += + (frontendBuffer->stats_t.readAc.access + + frontendBuffer->stats_t.writeAc.access) * + frontendBuffer->local_result.power.searchOp.dynamic + + frontendBuffer->stats_t.readAc.access * + frontendBuffer->local_result.power.readOp.dynamic + + frontendBuffer->stats_t.writeAc.access * + frontendBuffer->local_result.power.writeOp.dynamic; + + readBuffer->power_t.readOp.dynamic += + (readBuffer->stats_t.readAc.access * + readBuffer->local_result.power.readOp.dynamic + + readBuffer->stats_t.writeAc.access * + readBuffer->local_result.power.writeOp.dynamic); + writeBuffer->power_t.readOp.dynamic += + (writeBuffer->stats_t.readAc.access * + writeBuffer->local_result.power.readOp.dynamic + + writeBuffer->stats_t.writeAc.access * + writeBuffer->local_result.power.writeOp.dynamic); + + PRT->power_t.readOp.dynamic += + (PRT->stats_t.readAc.access * PRT->local_result.power.readOp.dynamic + + PRT->stats_t.writeAc.access * PRT->local_result.power.writeOp.dynamic); + + threadMasks->power_t.readOp.dynamic += + (threadMasks->stats_t.readAc.access * + threadMasks->local_result.power.readOp.dynamic + + threadMasks->stats_t.writeAc.access * + threadMasks->local_result.power.writeOp.dynamic); + + PRC->power_t.readOp.dynamic += + (PRC->stats_t.readAc.access * PRC->local_result.power.readOp.dynamic + + PRC->stats_t.writeAc.access * PRC->local_result.power.writeOp.dynamic); + + // Add coalescing logic power (Estimated from Verilog HDL description and + // Synopsys PowerCompiler)--Syed +#define COALESCE_SCALE 1 + double perAccessCoalescingEnergy = + coalesce_scale * + ((0.443e-3) * (0.5e-9) * g_tp.peri_global.Vdd * g_tp.peri_global.Vdd) / + (1 * 1); + threadMasks->power_t.readOp.dynamic += (threadMasks->stats_t.readAc.access + + threadMasks->stats_t.writeAc.access) * + perAccessCoalescingEnergy; + + // printf("***PRT: %10.30f, threadMasks: %10.30f, PRC: + // %10.30f\n",PRT->power_t.readOp.dynamic,threadMasks->power_t.readOp.dynamic,PRC->power_t.readOp.dynamic); + // printf("***Accesses: read:%lf + // write:%lf\n",threadMasks->stats_t.readAc.access, + // threadMasks->stats_t.writeAc.access); + if (is_tdp) { + power = + power + frontendBuffer->power_t + readBuffer->power_t + + writeBuffer->power_t + PRT->power_t + threadMasks->power_t + + PRC->power_t + + (frontendBuffer->local_result.power + readBuffer->local_result.power + + writeBuffer->local_result.power + PRT->local_result.power + + threadMasks->local_result.power + PRC->local_result.power) * + pppm_lkg; + + } else { + rt_power = + rt_power + frontendBuffer->power_t + readBuffer->power_t + + writeBuffer->power_t + PRT->power_t + threadMasks->power_t + + PRC->power_t + + (frontendBuffer->local_result.power + readBuffer->local_result.power + + writeBuffer->local_result.power + PRT->local_result.power + + threadMasks->local_result.power + PRC->local_result.power) * + pppm_lkg; + rt_power.readOp.dynamic = + rt_power.readOp.dynamic + power.readOp.dynamic * 0.1 * mcp.clockRate * + mcp.num_mcs * mcp.executionTime; + } +} + +void MCFrontEnd::displayEnergy(uint32_t indent, int plevel, bool is_tdp) { + string indent_str(indent, ' '); + string indent_str_next(indent + 2, ' '); + + if (is_tdp) { + cout << indent_str << "Front End ROB:" << endl; + cout << indent_str_next + << "Area = " << frontendBuffer->area.get_area() * 1e-6 << " mm^2" + << endl; + cout << indent_str_next << "Peak Dynamic = " + << frontendBuffer->power.readOp.dynamic * mcp.clockRate << " W" + << endl; + cout << indent_str_next + << "Subthreshold Leakage = " << frontendBuffer->power.readOp.leakage + << " W" << endl; + cout << indent_str_next + << "Gate Leakage = " << frontendBuffer->power.readOp.gate_leakage + << " W" << endl; + cout << indent_str_next << "Runtime Dynamic = " + << frontendBuffer->rt_power.readOp.dynamic / mcp.executionTime << " W" + << endl; + + cout << endl; + cout << indent_str << "Read Buffer:" << endl; + cout << indent_str_next << "Area = " << readBuffer->area.get_area() * 1e-6 + << " mm^2" << endl; + cout << indent_str_next << "Peak Dynamic = " + << readBuffer->power.readOp.dynamic * mcp.clockRate << " W" << endl; + cout << indent_str_next + << "Subthreshold Leakage = " << readBuffer->power.readOp.leakage + << " W" << endl; + cout << indent_str_next + << "Gate Leakage = " << readBuffer->power.readOp.gate_leakage << " W" + << endl; + cout << indent_str_next << "Runtime Dynamic = " + << readBuffer->rt_power.readOp.dynamic / mcp.executionTime << " W" + << endl; + cout << endl; + cout << indent_str << "Write Buffer:" << endl; + cout << indent_str_next << "Area = " << writeBuffer->area.get_area() * 1e-6 + << " mm^2" << endl; + cout << indent_str_next << "Peak Dynamic = " + << writeBuffer->power.readOp.dynamic * mcp.clockRate << " W" << endl; + cout << indent_str_next + << "Subthreshold Leakage = " << writeBuffer->power.readOp.leakage + << " W" << endl; + cout << indent_str_next + << "Gate Leakage = " << writeBuffer->power.readOp.gate_leakage << " W" + << endl; + cout << indent_str_next << "Runtime Dynamic = " + << writeBuffer->rt_power.readOp.dynamic / mcp.executionTime << " W" + << endl; + cout << endl; + cout << indent_str << "PRT:" << endl; + cout << indent_str_next << "Area = " << PRT->area.get_area() * 1e-6 + << " mm^2" << endl; + cout << indent_str_next + << "Peak Dynamic = " << PRT->power.readOp.dynamic * mcp.clockRate + << " W" << endl; + cout << indent_str_next + << "Subthreshold Leakage = " << PRT->power.readOp.leakage << " W" + << endl; + cout << indent_str_next + << "Gate Leakage = " << PRT->power.readOp.gate_leakage << " W" << endl; + cout << indent_str_next << "Runtime Dynamic = " + << PRT->rt_power.readOp.dynamic / mcp.executionTime << " W" << endl; + cout << endl; + cout << indent_str << "Thread Masks and coalescing logic:" << endl; + cout << indent_str_next << "Area = " << threadMasks->area.get_area() * 1e-6 + << " mm^2" << endl; + cout << indent_str_next << "Peak Dynamic = " + << threadMasks->power.readOp.dynamic * mcp.clockRate << " W" << endl; + cout << indent_str_next + << "Subthreshold Leakage = " << threadMasks->power.readOp.leakage + << " W" << endl; + cout << indent_str_next + << "Gate Leakage = " << threadMasks->power.readOp.gate_leakage << " W" + << endl; + cout << indent_str_next << "Runtime Dynamic = " + << threadMasks->rt_power.readOp.dynamic / mcp.executionTime << " W" + << endl; + cout << endl; + + } else { + cout << indent_str << "Front End ROB:" << endl; + cout << indent_str_next + << "Area = " << frontendBuffer->area.get_area() * 1e-6 << " mm^2" + << endl; + cout << indent_str_next << "Peak Dynamic = " + << frontendBuffer->rt_power.readOp.dynamic * mcp.clockRate << " W" + << endl; + cout << indent_str_next + << "Subthreshold Leakage = " << frontendBuffer->rt_power.readOp.leakage + << " W" << endl; + cout << indent_str_next + << "Gate Leakage = " << frontendBuffer->rt_power.readOp.gate_leakage + << " W" << endl; + cout << endl; + cout << indent_str << "Read Buffer:" << endl; + cout << indent_str_next << "Area = " << readBuffer->area.get_area() * 1e-6 + << " mm^2" << endl; + cout << indent_str_next << "Peak Dynamic = " + << readBuffer->rt_power.readOp.dynamic * mcp.clockRate << " W" << endl; + cout << indent_str_next + << "Subthreshold Leakage = " << readBuffer->rt_power.readOp.leakage + << " W" << endl; + cout << indent_str_next + << "Gate Leakage = " << readBuffer->rt_power.readOp.gate_leakage + << " W" << endl; + cout << endl; + cout << indent_str << "Write Buffer:" << endl; + cout << indent_str_next << "Area = " << writeBuffer->area.get_area() * 1e-6 + << " mm^2" << endl; + cout << indent_str_next << "Peak Dynamic = " + << writeBuffer->rt_power.readOp.dynamic * mcp.clockRate << " W" + << endl; + cout << indent_str_next + << "Subthreshold Leakage = " << writeBuffer->rt_power.readOp.leakage + << " W" << endl; + cout << indent_str_next + << "Gate Leakage = " << writeBuffer->rt_power.readOp.gate_leakage + << " W" << endl; + cout << endl; + cout << indent_str << "PRT:" << endl; + cout << indent_str_next << "Area = " << PRT->area.get_area() * 1e-6 + << " mm^2" << endl; + cout << indent_str_next + << "Peak Dynamic = " << PRT->rt_power.readOp.dynamic * mcp.clockRate + << " W" << endl; + cout << indent_str_next + << "Subthreshold Leakage = " << PRT->rt_power.readOp.leakage << " W" + << endl; + cout << indent_str_next + << "Gate Leakage = " << PRT->rt_power.readOp.gate_leakage << " W" + << endl; + cout << endl; + cout << indent_str << "Thread masks and coalescing logic:" << endl; + cout << indent_str_next << "Area = " << threadMasks->area.get_area() * 1e-6 + << " mm^2" << endl; + cout << indent_str_next << "Peak Dynamic = " + << threadMasks->rt_power.readOp.dynamic * mcp.clockRate << " W" + << endl; + cout << indent_str_next + << "Subthreshold Leakage = " << threadMasks->rt_power.readOp.leakage + << " W" << endl; + cout << indent_str_next + << "Gate Leakage = " << threadMasks->rt_power.readOp.gate_leakage + << " W" << endl; + } +} + +DRAM::DRAM(ParseXML* XML_interface, InputParameter* interface_ip_, + enum Dram_type dram_type_) + : XML(XML_interface), interface_ip(*interface_ip_), dram_type(dram_type_) { + set_dram_param(); +} +MemoryController::MemoryController(ParseXML* XML_interface, + InputParameter* interface_ip_, + enum MemoryCtrl_type mc_type_, + enum Dram_type dram_type_) + : XML(XML_interface), + interface_ip(*interface_ip_), + mc_type(mc_type_), + frontend(0), + transecEngine(0), + PHY(0), + pipeLogic(0) { + /* All computations are for a single MC + * + */ + interface_ip.wire_is_mat_type = 2; + interface_ip.wire_os_mat_type = 2; + interface_ip.wt = Global; + set_mc_param(); + frontend = new MCFrontEnd(XML, &interface_ip, mcp, mc_type); + dram = new DRAM(XML, &interface_ip, dram_type_); + area.set_area(area.get_area() + frontend->area.get_area()); + transecEngine = new MCBackend(&interface_ip, mcp, mc_type); + area.set_area(area.get_area() + transecEngine->area.get_area()); + if (mcp.type == 0 || (mcp.type == 1 && mcp.withPHY)) { + PHY = new MCPHY(&interface_ip, mcp, mc_type); + area.set_area(area.get_area() + PHY->area.get_area()); + } + //+++++++++Transaction engine +++++++++++++++++ ////TODO needs better numbers, + // Run the RTL code from OpenSparc. + // transecEngine.initialize(&interface_ip); + // transecEngine.peakDataTransferRate = XML->sys.mem.peak_transfer_rate; + // transecEngine.memDataWidth = dataBusWidth; + // transecEngine.memRank = XML->sys.mem.number_ranks; + // //transecEngine.memAccesses=XML->sys.mc.memory_accesses; + // //transecEngine.llcBlocksize=llcBlockSize; + // transecEngine.compute(); + // transecEngine.area.set_area(XML->sys.mc.memory_channels_per_mc*transecEngine.area.get_area()) + // ; area.set_area(area.get_area()+ transecEngine.area.get_area()); + // ///cout<<"area="<<area<<endl; + //// + // //++++++++++++++PHY ++++++++++++++++++++++++++ //TODO needs better numbers + // PHY.initialize(&interface_ip); + // PHY.peakDataTransferRate = XML->sys.mem.peak_transfer_rate; + // PHY.memDataWidth = dataBusWidth; + // //PHY.memAccesses=PHY.peakDataTransferRate;//this is the max power + // //PHY.llcBlocksize=llcBlockSize; + // PHY.compute(); + // PHY.area.set_area(XML->sys.mc.memory_channels_per_mc*PHY.area.get_area()) + // ; area.set_area(area.get_area()+ PHY.area.get_area()); + /// cout<<"area="<<area<<endl; + // + // interface_ip.pipeline_stages = 5;//normal memory controller has five + // stages in the pipeline. interface_ip.per_stage_vector = addressBusWidth + + // XML->sys.core[0].opcode_width + dataBusWidth; pipeLogic = new + // pipeline(is_default, &interface_ip); + // //pipeLogic.init_pipeline(is_default, &interface_ip); + // pipeLogic->compute_pipeline(); + // area.set_area(area.get_area()+ pipeLogic->area.get_area()*1e-6); + // area.set_area((area.get_area()+mc_area*1e-6)*1.1);//placement and routing + // overhead + // + // + //// //clock + //// clockNetwork.init_wire_external(is_default, &interface_ip); + //// clockNetwork.clk_area =area*1.1;//10% of placement overhead. + /// rule of thumb / clockNetwork.end_wiring_level =5;//toplevel metal / + /// clockNetwork.start_wiring_level =5;//toplevel metal / + /// clockNetwork.num_regs = pipeLogic.tot_stage_vector; / + /// clockNetwork.optimize_wire(); +} +void MemoryController::computeEnergy(bool is_tdp) { + rt_power.reset(); // Jingwen + frontend->rt_power.reset(); + transecEngine->rt_power.reset(); + dram->rt_power.reset(); + mcp.executionTime = XML->sys.total_cycles / + (XML->sys.target_core_clockrate * 1e6); // Jingwen + frontend->mcp.executionTime = + XML->sys.total_cycles / + (XML->sys.target_core_clockrate * 1e6); // Jingwen + transecEngine->mcp.executionTime = + XML->sys.total_cycles / + (XML->sys.target_core_clockrate * 1e6); // Jingwen + + /*Jingwen: give stats for backend and phy */ + transecEngine->mcp.reads = XML->sys.mc.memory_reads; + transecEngine->mcp.writes = XML->sys.mc.memory_writes; + + // set_mc_param(); + + frontend->computeEnergy(is_tdp); + transecEngine->computeEnergy(is_tdp); + dram->computeEnergy(is_tdp); + if (mcp.type == 0 || (mcp.type == 1 && mcp.withPHY)) { + if (!is_tdp) PHY->rt_power.reset(); // Jingwen + PHY->mcp.reads = XML->sys.mc.memory_reads; + PHY->mcp.writes = XML->sys.mc.memory_writes; + PHY->mcp.executionTime = XML->sys.total_cycles / + (XML->sys.target_core_clockrate * 1e6); // Jingwen + PHY->computeEnergy(is_tdp); + } + if (is_tdp) { + power = power + frontend->power + transecEngine->power; + if (mcp.type == 0 || (mcp.type == 1 && mcp.withPHY)) { + power = power + PHY->power; + } + } else { + rt_power = rt_power + frontend->rt_power + transecEngine->rt_power + + dram->rt_power; + if (mcp.type == 0 || (mcp.type == 1 && mcp.withPHY)) { + rt_power = rt_power + PHY->rt_power; + } + } +} + +void MemoryController::displayEnergy(uint32_t indent, int plevel, bool is_tdp) { + string indent_str(indent, ' '); + string indent_str_next(indent + 2, ' '); + bool long_channel = XML->sys.longer_channel_device; + + if (is_tdp) { + cout << "Memory Controller:" << endl; + cout << indent_str << "Area = " << area.get_area() * 1e-6 << " mm^2" + << endl; + cout << indent_str + << "Peak Dynamic = " << power.readOp.dynamic * mcp.clockRate << " W" + << endl; + cout << indent_str << "Subthreshold Leakage = " + << (long_channel ? power.readOp.longer_channel_leakage + : power.readOp.leakage) + << " W" << endl; + // cout << indent_str<< "Subthreshold Leakage = " << + // power.readOp.longer_channel_leakage <<" W" << endl; + cout << indent_str << "Gate Leakage = " << power.readOp.gate_leakage << " W" + << endl; + cout << indent_str + << "Runtime Dynamic = " << rt_power.readOp.dynamic / mcp.executionTime + << " W" << endl; + cout << endl; + cout << indent_str << "Front End Engine:" << endl; + cout << indent_str_next << "Area = " << frontend->area.get_area() * 1e-6 + << " mm^2" << endl; + cout << indent_str_next + << "Peak Dynamic = " << frontend->power.readOp.dynamic * mcp.clockRate + << " W" << endl; + cout << indent_str_next << "Subthreshold Leakage = " + << (long_channel ? frontend->power.readOp.longer_channel_leakage + : frontend->power.readOp.leakage) + << " W" << endl; + cout << indent_str_next + << "Gate Leakage = " << frontend->power.readOp.gate_leakage << " W" + << endl; + cout << indent_str_next << "Runtime Dynamic = " + << frontend->rt_power.readOp.dynamic / mcp.executionTime << " W" + << endl; + cout << endl; + // if (plevel >2){ + frontend->displayEnergy(indent + 4, is_tdp); + //} + cout << indent_str << "Transaction Engine:" << endl; + cout << indent_str_next + << "Area = " << transecEngine->area.get_area() * 1e-6 << " mm^2" + << endl; + cout << indent_str_next << "Peak Dynamic = " + << transecEngine->power.readOp.dynamic * mcp.clockRate << " W" << endl; + cout << indent_str_next << "Subthreshold Leakage = " + << (long_channel ? transecEngine->power.readOp.longer_channel_leakage + : transecEngine->power.readOp.leakage) + << " W" << endl; + cout << indent_str_next + << "Gate Leakage = " << transecEngine->power.readOp.gate_leakage + << " W" << endl; + cout << indent_str_next << "Runtime Dynamic = " + << transecEngine->rt_power.readOp.dynamic / mcp.executionTime << " W" + << endl; + cout << endl; + if (mcp.type == 0 || (mcp.type == 1 && mcp.withPHY)) { + cout << indent_str << "PHY:" << endl; + cout << indent_str_next << "Area = " << PHY->area.get_area() * 1e-6 + << " mm^2" << endl; + cout << indent_str_next + << "Peak Dynamic = " << PHY->power.readOp.dynamic * mcp.clockRate + << " W" << endl; + cout << indent_str_next << "Subthreshold Leakage = " + << (long_channel ? PHY->power.readOp.longer_channel_leakage + : PHY->power.readOp.leakage) + << " W" << endl; + cout << indent_str_next + << "Gate Leakage = " << PHY->power.readOp.gate_leakage << " W" + << endl; + cout << indent_str_next << "Runtime Dynamic = " + << PHY->rt_power.readOp.dynamic / mcp.executionTime << " W" << endl; + cout << endl; + } + } else { + cout << "Memory Controller:" << endl; + cout << indent_str_next << "Area = " << area.get_area() * 1e-6 << " mm^2" + << endl; + cout << indent_str_next + << "Peak Dynamic = " << power.readOp.dynamic * mcp.clockRate << " W" + << endl; + cout << indent_str_next << "Subthreshold Leakage = " << power.readOp.leakage + << " W" << endl; + cout << indent_str_next << "Gate Leakage = " << power.readOp.gate_leakage + << " W" << endl; + cout << endl; + } +} + +void DRAM::set_dram_param() { + dramp.cmd_coeff = XML->sys.mc.dram_rd_coeff; + dramp.act_coeff = XML->sys.mc.dram_act_coeff; + dramp.nop_coeff = XML->sys.mc.dram_nop_coeff; + dramp.activity_coeff = XML->sys.mc.dram_activity_coeff; + dramp.pre_coeff = XML->sys.mc.dram_pre_coeff; + dramp.rd_coeff = XML->sys.mc.dram_rd_coeff; + dramp.wr_coeff = XML->sys.mc.dram_wr_coeff; + dramp.req_coeff = XML->sys.mc.dram_req_coeff; + dramp.const_coeff = XML->sys.mc.dram_const_coeff; +} + +void MemoryController::set_mc_param() { + if (mc_type == MC) { + mcp.clockRate = XML->sys.mc.mc_clock * 2; // DDR double pumped + mcp.clockRate *= 1e6; + mcp.executionTime = + XML->sys.total_cycles / (XML->sys.target_core_clockrate * 1e6); + + mcp.llcBlockSize = int(ceil(XML->sys.mc.llc_line_length / 8.0)) + + XML->sys.mc.llc_line_length; // ecc overhead + mcp.dataBusWidth = + int(ceil(XML->sys.mc.databus_width / 8.0)) + XML->sys.mc.databus_width; + mcp.addressBusWidth = int(ceil( + XML->sys.mc.addressbus_width)); // XML->sys.physical_address_width; + mcp.opcodeW = 16; + mcp.num_mcs = XML->sys.mc.number_mcs; + mcp.num_channels = XML->sys.mc.memory_channels_per_mc; + mcp.reads = XML->sys.mc.memory_reads; + mcp.writes = XML->sys.mc.memory_writes; + //+++++++++Transaction engine +++++++++++++++++ ////TODO needs better + // numbers, Run the RTL code from OpenSparc. + mcp.peakDataTransferRate = XML->sys.mc.peak_transfer_rate; + mcp.memRank = XML->sys.mc.number_ranks; + //++++++++++++++PHY ++++++++++++++++++++++++++ //TODO needs better numbers + // PHY.memAccesses=PHY.peakDataTransferRate;//this is the max power + // PHY.llcBlocksize=llcBlockSize; + mcp.frontend_duty_cycle = 0.5; // for max power, the actual off-chip links + // is bidirectional but time shared + mcp.LVDS = XML->sys.mc.LVDS; + mcp.type = XML->sys.mc.type; + mcp.withPHY = XML->sys.mc.withPHY; + } + // else if (mc_type==FLASHC) + // { + // mcp.clockRate =XML->sys.flashc.mc_clock*2;//DDR double + // pumped mcp.clockRate *= 1e6; mcp.executionTime = + // XML->sys.total_cycles/(XML->sys.target_core_clockrate*1e6); + // + // mcp.llcBlockSize + //=int(ceil(XML->sys.flashc.llc_line_length/8.0))+XML->sys.flashc.llc_line_length;//ecc + // overhead mcp.dataBusWidth + // =int(ceil(XML->sys.flashc.databus_width/8.0)) + + // XML->sys.flashc.databus_width; mcp.addressBusWidth + //=int(ceil(XML->sys.flashc.addressbus_width));//XML->sys.physical_address_width; + // mcp.opcodeW =16; + // mcp.num_mcs = XML->sys.flashc.number_mcs; + // mcp.num_channels = XML->sys.flashc.memory_channels_per_mc; + // mcp.reads = XML->sys.flashc.memory_reads; + // mcp.writes = XML->sys.flashc.memory_writes; + // //+++++++++Transaction engine +++++++++++++++++ ////TODO needs + // better numbers, Run the RTL code from OpenSparc. + // mcp.peakDataTransferRate = + // XML->sys.flashc.peak_transfer_rate; mcp.memRank = + // XML->sys.flashc.number_ranks; + // //++++++++++++++PHY ++++++++++++++++++++++++++ //TODO needs + // better numbers + // //PHY.memAccesses=PHY.peakDataTransferRate;//this is the max + // power + // //PHY.llcBlocksize=llcBlockSize; + // mcp.frontend_duty_cycle = 0.5;//for max power, the actual + // off-chip links is bidirectional but time shared mcp.LVDS = + // XML->sys.flashc.LVDS; mcp.type = XML->sys.flashc.type; + // } + else { + cout << "Unknown memory controller type: neither DRAM controller nor Flash " + "controller" + << endl; + exit(0); + } +} + +MCFrontEnd ::~MCFrontEnd() { + if (MC_arb) { + delete MC_arb; + MC_arb = 0; + } + if (frontendBuffer) { + delete frontendBuffer; + frontendBuffer = 0; + } + if (readBuffer) { + delete readBuffer; + readBuffer = 0; + } + if (writeBuffer) { + delete writeBuffer; + writeBuffer = 0; + } +} + +MemoryController ::~MemoryController() { + if (frontend) { + delete frontend; + frontend = 0; + } + if (transecEngine) { + delete transecEngine; + transecEngine = 0; + } + if (PHY) { + delete PHY; + PHY = 0; + } + if (pipeLogic) { + delete pipeLogic; + pipeLogic = 0; + } +} |
