diff options
Diffstat (limited to 'ext/dsent/model/std_cells/CellMacros.cc')
-rw-r--r-- | ext/dsent/model/std_cells/CellMacros.cc | 477 |
1 files changed, 477 insertions, 0 deletions
diff --git a/ext/dsent/model/std_cells/CellMacros.cc b/ext/dsent/model/std_cells/CellMacros.cc new file mode 100644 index 000000000..5b243942a --- /dev/null +++ b/ext/dsent/model/std_cells/CellMacros.cc @@ -0,0 +1,477 @@ +#include "model/std_cells/CellMacros.h" + +#include <cmath> +#include <vector> + +#include "model/std_cells/StdCell.h" +#include "model/timing_graph/ElectricalNet.h" +#include "model/timing_graph/ElectricalDriver.h" +#include "model/timing_graph/ElectricalLoad.h" + +namespace DSENT +{ + //------------------------------------------------------------------------- + // NOR2 Macro (TODO: Generalize to N-input macro once leakage calc is done) + //------------------------------------------------------------------------- + void CellMacros::addNor2(StdCell* cell_, const String& name_, + bool sizable_, bool a1_to_zn_path_, bool a2_to_zn_path_, + const String& a1_net_, const String& a2_net_, const String& zn_net_) + { + //Create electrical timing model for the nand + // Construct loads and drivers + cell_->createLoad(name_ + "_CgA1"); + cell_->createLoad(name_ + "_CgA2"); + cell_->createLoad(name_ + "_CdZN"); + cell_->createDriver(name_ + "_RonZN", sizable_); + + //Get references to loads and drivers + ElectricalLoad* gate_a1_load = cell_->getLoad(name_ + "_CgA1"); + ElectricalLoad* gate_a2_load = cell_->getLoad(name_ + "_CgA2"); + ElectricalLoad* drain_load = cell_->getLoad(name_ + "_CdZN"); + ElectricalDriver* zn_drive = cell_->getDriver(name_ + "_RonZN"); + ElectricalNet* a1_net = cell_->getNet(a1_net_); + ElectricalNet* a2_net = cell_->getNet(a2_net_); + ElectricalNet* zn_net = cell_->getNet(zn_net_); + + //Add loads and drivers to the specified nets + a1_net->addDownstreamNode(gate_a1_load); + a2_net->addDownstreamNode(gate_a2_load); + zn_net->addDownstreamNode(drain_load); + if (a1_to_zn_path_) gate_a1_load->addDownstreamNode(zn_drive); + if (a2_to_zn_path_) gate_a2_load->addDownstreamNode(zn_drive); + zn_drive->addDownstreamNode(zn_net); + + return; + } + + void CellMacros::updateNor2(StdCell* cell_, const String& name_, double normalized_size_) + { + ASSERT(normalized_size_ >= 0.0, "[Error] " + cell_->getInstanceName() + + " -> Cannot update a macro with a negative normalized size!"); + + //Grab pointer to tech model + const TechModel* tech = cell_->getTechModel(); + + // Get technology parameters + double vdd = tech->get("Vdd"); + double gate_cap = tech->get("Gate->CapPerWidth"); + double drain_cap = tech->get("Drain->CapPerWidth"); + double nmos_eff_res = tech->get("Nmos->EffResWidth"); + double pmos_eff_res = tech->get("Pmos->EffResWidth"); + double pmos_eff_res_stack_ratio = tech->get("Pmos->EffResStackRatio"); + double gate_pitch_contacted = tech->get("Gate->PitchContacted"); + double metal1_wire_min_width = tech->get("Wire->Metal1->MinWidth"); + + //Calculate number of folds and gate pitches needed + unsigned int folds = (normalized_size_ < 1.0) ? 1 : (unsigned int)ceil(normalized_size_); + cell_->getGenProperties()->set(name_ + "_GatePitches", 2 * folds); + + //Calculate widths, making sure they are above the minimum width + double nmos_width = std::max(calculateNmosWidth(cell_, 1, 2, 1) * normalized_size_ / folds, (double) tech->get("Gate->MinWidth")); + double pmos_width = std::max(calculatePmosWidth(cell_, 1, 2, 2) * normalized_size_ / folds, (double) tech->get("Gate->MinWidth")); + + //Calculate leakage power for each given input state + double leakage_power_00 = vdd * folds * 2 * tech->calculateNmosLeakageCurrent(1, nmos_width, 0x0); + double leakage_power_01 = vdd * folds * tech->calculatePmosLeakageCurrent(2, pmos_width, ~0x1); + double leakage_power_10 = vdd * folds * tech->calculatePmosLeakageCurrent(2, pmos_width, ~0x2); + double leakage_power_11 = vdd * folds * tech->calculatePmosLeakageCurrent(2, pmos_width, ~0x3); + cell_->getGenProperties()->set(name_ + "_LeakagePower_00", leakage_power_00); + cell_->getGenProperties()->set(name_ + "_LeakagePower_01", leakage_power_01); + cell_->getGenProperties()->set(name_ + "_LeakagePower_10", leakage_power_10); + cell_->getGenProperties()->set(name_ + "_LeakagePower_11", leakage_power_11); + + //Calculate R_on and capacitances + double pmos_stack2_balance = 1.0 + pmos_eff_res_stack_ratio; + double c_g = (nmos_width + pmos_width) * gate_cap * folds; + double c_d = (2 * pmos_width + 2 * nmos_width) * drain_cap * folds; + double r_on = (nmos_eff_res / nmos_width + pmos_stack2_balance * pmos_eff_res / pmos_width) / (folds * 2.0); + + // Estimate the wire cap and add them all at the output + double cell_height = cell_->getTotalHeight(); + double wire_width = metal1_wire_min_width; + double wire_spacing = gate_pitch_contacted - metal1_wire_min_width; + double wire_length = 2.0 * folds * cell_height; + double wire_cap = tech->calculateWireCapacitance("Metal1", wire_width, wire_spacing, wire_length); + + // Construct equivalent load and drive strength + cell_->getLoad(name_ + "_CgA1")->setLoadCap(c_g); + cell_->getLoad(name_ + "_CgA2")->setLoadCap(c_g); + cell_->getLoad(name_ + "_CdZN")->setLoadCap(c_d + wire_cap); + cell_->getDriver(name_ + "_RonZN")->setOutputRes(r_on); + + // Calculate flip energies + double zn_flip_energy = 0.5 * (c_d + wire_cap) * vdd * vdd; + double a1_flip_energy = 0.5 * c_g * vdd * vdd; + double a2_flip_energy = 0.5 * c_g * vdd * vdd; + cell_->getGenProperties()->set(name_ + "_ZN_Flip", zn_flip_energy); + cell_->getGenProperties()->set(name_ + "_A1_Flip", a1_flip_energy); + cell_->getGenProperties()->set(name_ + "_A2_Flip", a2_flip_energy); + } + //------------------------------------------------------------------------- + + //------------------------------------------------------------------------- + // NAND2 Macro (TODO: Generalize to N-input macro once leakage calc is done) + //------------------------------------------------------------------------- + //Adds a NAND2 to the standard cell, normalized to some size + void CellMacros::addNand2(StdCell* cell_, const String& name_, + bool sizable_, bool a1_to_zn_path_, bool a2_to_zn_path_, + const String& a1_net_, const String& a2_net_, const String& zn_net_) + { + //Create electrical timing model for the nor + // Construct loads and drivers + cell_->createLoad(name_ + "_CgA1"); + cell_->createLoad(name_ + "_CgA2"); + cell_->createLoad(name_ + "_CdZN"); + cell_->createDriver(name_ + "_RonZN", sizable_); + + //Get references to loads and drivers + ElectricalLoad* gate_a1_load = cell_->getLoad(name_ + "_CgA1"); + ElectricalLoad* gate_a2_load = cell_->getLoad(name_ + "_CgA2"); + ElectricalLoad* drain_load = cell_->getLoad(name_ + "_CdZN"); + ElectricalDriver* zn_drive = cell_->getDriver(name_ + "_RonZN"); + ElectricalNet* a1_net = cell_->getNet(a1_net_); + ElectricalNet* a2_net = cell_->getNet(a2_net_); + ElectricalNet* zn_net = cell_->getNet(zn_net_); + + a1_net->addDownstreamNode(gate_a1_load); + a2_net->addDownstreamNode(gate_a2_load); + zn_net->addDownstreamNode(drain_load); + if (a1_to_zn_path_) gate_a1_load->addDownstreamNode(zn_drive); + if (a2_to_zn_path_) gate_a2_load->addDownstreamNode(zn_drive); + zn_drive->addDownstreamNode(zn_net); + + return; + } + + //Updates a NAND2 to to the standard cell, normalized to some size + void CellMacros::updateNand2(StdCell* cell_, const String& name_, double normalized_size_) + { + ASSERT(normalized_size_ >= 0.0, "[Error] " + cell_->getInstanceName() + + " -> Cannot update a macro with a negative normalized size!"); + + //Grab pointer to tech model + const TechModel* tech = cell_->getTechModel(); + + // Get technology parameters + double vdd = tech->get("Vdd"); + double gate_cap = tech->get("Gate->CapPerWidth"); + double drain_cap = tech->get("Drain->CapPerWidth"); + double nmos_eff_res = tech->get("Nmos->EffResWidth"); + double pmos_eff_res = tech->get("Pmos->EffResWidth"); + double nmos_eff_res_stack_ratio = tech->get("Nmos->EffResStackRatio"); + double gate_pitch_contacted = tech->get("Gate->PitchContacted"); + double metal1_wire_min_width = tech->get("Wire->Metal1->MinWidth"); + + //Calculate number of folds needed + unsigned int folds = (normalized_size_ < 1.0) ? 1 : (unsigned int)ceil(normalized_size_); + cell_->getGenProperties()->set(name_ + "_GatePitches", 2 * folds); + + //Calculate widths, making sure they are above the minimum width + double nmos_width = std::max(calculateNmosWidth(cell_, 2, 1, 2) * normalized_size_ / folds, (double) tech->get("Gate->MinWidth")); + double pmos_width = std::max(calculatePmosWidth(cell_, 2, 1, 1) * normalized_size_ / folds, (double) tech->get("Gate->MinWidth")); + + // Leakage power calculation + double leakage_power_00 = vdd * folds * tech->calculateNmosLeakageCurrent(2, nmos_width, 0x0); + double leakage_power_01 = vdd * folds * tech->calculateNmosLeakageCurrent(2, nmos_width, 0x1); + double leakage_power_10 = vdd * folds * tech->calculateNmosLeakageCurrent(2, nmos_width, 0x2); + double leakage_power_11 = vdd * folds * 2 * tech->calculatePmosLeakageCurrent(1, pmos_width, ~0x3); + cell_->getGenProperties()->set(name_ + "_LeakagePower_00", leakage_power_00); + cell_->getGenProperties()->set(name_ + "_LeakagePower_01", leakage_power_01); + cell_->getGenProperties()->set(name_ + "_LeakagePower_10", leakage_power_10); + cell_->getGenProperties()->set(name_ + "_LeakagePower_11", leakage_power_11); + + // Get input parameters + double nmos_stack2_balance = 1.0 + nmos_eff_res_stack_ratio; + + //Calculate caps + double c_g = (nmos_width + pmos_width) * gate_cap * folds; + double c_d = (2 * pmos_width + 2 * nmos_width) * drain_cap * folds; + double r_on = (nmos_stack2_balance * nmos_eff_res / nmos_width + pmos_eff_res / pmos_width) / (folds * 2.0); + + // Estimate the wire cap and add them all at the output + double cell_height = cell_->getTotalHeight(); + double wire_width = metal1_wire_min_width; + double wire_spacing = gate_pitch_contacted - metal1_wire_min_width; + double wire_length = 2.0 * folds * cell_height; + double wire_cap = tech->calculateWireCapacitance("Metal1", wire_width, wire_spacing, wire_length); + + // Construct equivalent load and drive strength + cell_->getLoad(name_ + "_CgA1")->setLoadCap(c_g); + cell_->getLoad(name_ + "_CgA2")->setLoadCap(c_g); + cell_->getLoad(name_ + "_CdZN")->setLoadCap(c_d + wire_cap); + cell_->getDriver(name_ + "_RonZN")->setOutputRes(r_on); + + // Calculate flip energies + double zn_flip_energy = 0.5 * (c_d + wire_cap) * vdd * vdd; + double a1_flip_energy = 0.5 * c_g * vdd * vdd; + double a2_flip_energy = 0.5 * c_g * vdd * vdd; + cell_->getGenProperties()->set(name_ + "_ZN_Flip", zn_flip_energy); + cell_->getGenProperties()->set(name_ + "_A1_Flip", a1_flip_energy); + cell_->getGenProperties()->set(name_ + "_A2_Flip", a2_flip_energy); + } + //------------------------------------------------------------------------- + + //------------------------------------------------------------------------- + // INV Macro + //------------------------------------------------------------------------- + //Adds an inverter to the model, normalized to some size + void CellMacros::addInverter(StdCell* cell_, const String& name_, + bool sizable_, bool a_to_zn_path_, + const String& a_net_, const String& zn_net_) + { + //Create electrical timing model for the inverter + // Construct loads and drivers + cell_->createLoad(name_ + "_CgA"); + cell_->createLoad(name_ + "_CdZN"); + cell_->createDriver(name_ + "_RonZN", sizable_); + + //Get references to loads and drivers + ElectricalLoad* gate_load = cell_->getLoad(name_ + "_CgA"); + ElectricalLoad* drain_load = cell_->getLoad(name_ + "_CdZN"); + ElectricalDriver* out_drive = cell_->getDriver(name_ + "_RonZN"); + ElectricalNet* a_net = cell_->getNet(a_net_); + ElectricalNet* zn_net = cell_->getNet(zn_net_); + + // Setup connectivity of loads and drivers + a_net->addDownstreamNode(gate_load); + if (a_to_zn_path_) gate_load->addDownstreamNode(out_drive); + zn_net->addDownstreamNode(drain_load); + out_drive->addDownstreamNode(zn_net); + + return; + } + + //Updates the numbers of an inverter for some normalized size + void CellMacros::updateInverter(StdCell* cell_, const String& name_, double normalized_size_) + { + ASSERT(normalized_size_ >= 0.0, "[Error] " + cell_->getInstanceName() + + " -> Cannot update a macro with a negative normalized size!"); + + //Grab pointer to tech model + const TechModel* tech = cell_->getTechModel(); + + //Get values from technology library + double vdd = tech->get("Vdd"); + double gate_cap = tech->get("Gate->CapPerWidth"); + double drain_cap = tech->get("Drain->CapPerWidth"); + double nmos_eff_res = tech->get("Nmos->EffResWidth"); + double pmos_eff_res = tech->get("Pmos->EffResWidth"); + double gate_pitch_contacted = tech->get("Gate->PitchContacted"); + double metal1_wire_min_width = tech->get("Wire->Metal1->MinWidth"); + + //Calculate number of folds needed + unsigned int folds = (normalized_size_ < 1.0) ? 1 : (unsigned int)ceil(normalized_size_); + cell_->getGenProperties()->set(name_ + "_GatePitches", folds); + + //Calculate widths, making sure they are above the minimum width + double nmos_width = std::max(calculateNmosWidth(cell_, 1, 1, 1) * normalized_size_ / folds, (double) tech->get("Gate->MinWidth")); + double pmos_width = std::max(calculatePmosWidth(cell_, 1, 1, 1) * normalized_size_ / folds, (double) tech->get("Gate->MinWidth")); + + //Calculate leakage power for each given input state + double leakage_power_0 = vdd * folds * tech->calculateNmosLeakageCurrent(1, nmos_width, 0x0); + double leakage_power_1 = vdd * folds * tech->calculatePmosLeakageCurrent(1, pmos_width, ~0x1); + cell_->getGenProperties()->set(name_ + "_LeakagePower_0", leakage_power_0); + cell_->getGenProperties()->set(name_ + "_LeakagePower_1", leakage_power_1); + + //Calculate caps + double c_g = (nmos_width + pmos_width) * gate_cap * folds; + double c_d = (pmos_width + nmos_width) * drain_cap * folds; + double r_on = (nmos_eff_res / nmos_width + pmos_eff_res / pmos_width) / (folds * 2.0); + + // Estimate the wire cap and add them all at the output + double cell_height = cell_->getTotalHeight(); + double wire_width = metal1_wire_min_width; + double wire_spacing = gate_pitch_contacted - metal1_wire_min_width; + double wire_length = folds * cell_height; + double wire_cap = tech->calculateWireCapacitance("Metal1", wire_width, wire_spacing, wire_length); + + // Construct equivalent load and drive strength + cell_->getLoad(name_ + "_CgA")->setLoadCap(c_g); + cell_->getLoad(name_ + "_CdZN")->setLoadCap(c_d + wire_cap); + cell_->getDriver(name_ + "_RonZN")->setOutputRes(r_on); + + // Calculate flip energy (output flip) + // Calculate flip energies + double zn_flip_energy = 0.5 * (c_d + wire_cap) * vdd * vdd; + double a_flip_energy = 0.5 * c_g * vdd * vdd; + cell_->getGenProperties()->set(name_ + "_ZN_Flip", zn_flip_energy); + cell_->getGenProperties()->set(name_ + "_A_Flip", a_flip_energy); + + return; + } + //------------------------------------------------------------------------- + + //------------------------------------------------------------------------- + // INVZ Macro + //------------------------------------------------------------------------- + //Adds a tristated inverter to the model, normalized to some size + void CellMacros::addTristate(StdCell* cell_, const String& name_, + bool sizable_, bool a_to_zn_path_, bool oe_to_zn_path_, bool oen_to_zn_path_, + const String& a_net_, const String& oe_net_, const String& oen_net_, const String& zn_net_) + { + // Construct loads and drivers + cell_->createLoad(name_ + "_CgA"); + cell_->createLoad(name_ + "_CgOE"); + cell_->createLoad(name_ + "_CgOEN"); + cell_->createLoad(name_ + "_CdZN"); + cell_->createDriver(name_ + "_RonZN", sizable_); + + // Get references to loads, nets and drivers + ElectricalLoad* gate_a_load = cell_->getLoad(name_ + "_CgA"); + ElectricalLoad* gate_oe_load = cell_->getLoad(name_ + "_CgOE"); + ElectricalLoad* gate_oen_load = cell_->getLoad(name_ + "_CgOEN"); + ElectricalLoad* drain_load = cell_->getLoad(name_ + "_CdZN"); + ElectricalDriver* out_drive = cell_->getDriver(name_ + "_RonZN"); + ElectricalNet* a_net = cell_->getNet(a_net_); + ElectricalNet* oe_net = cell_->getNet(oe_net_); + ElectricalNet* oen_net = cell_->getNet(oen_net_); + ElectricalNet* zn_net = cell_->getNet(zn_net_); + + // Setup connectivity of loads and drivers + a_net->addDownstreamNode(gate_a_load); + oe_net->addDownstreamNode(gate_oe_load); + oen_net->addDownstreamNode(gate_oen_load); + if (a_to_zn_path_) gate_a_load->addDownstreamNode(out_drive); + if (oe_to_zn_path_) gate_oe_load->addDownstreamNode(out_drive); + if (oen_to_zn_path_) gate_oen_load->addDownstreamNode(out_drive); + zn_net->addDownstreamNode(drain_load); + out_drive->addDownstreamNode(zn_net); + + return; + } + + //Updates the numbers of an inverter for some normalized size + void CellMacros::updateTristate(StdCell* cell_, const String& name_, double normalized_size_) + { + ASSERT(normalized_size_ >= 0.0, "[Error] " + cell_->getInstanceName() + + " -> Cannot update a macro with a negative normalized size!"); + + //Grab pointer to tech model + const TechModel* tech = cell_->getTechModel(); + + //Get values from technology library + double vdd = tech->get("Vdd"); + double gate_cap = tech->get("Gate->CapPerWidth"); + double drain_cap = tech->get("Drain->CapPerWidth"); + double nmos_eff_res = tech->get("Nmos->EffResWidth"); + double pmos_eff_res = tech->get("Pmos->EffResWidth"); + double pmos_eff_res_stack_ratio = tech->get("Pmos->EffResStackRatio"); + double nmos_eff_res_stack_ratio = tech->get("Nmos->EffResStackRatio"); + double gate_pitch_contacted = tech->get("Gate->PitchContacted"); + double metal1_wire_min_width = tech->get("Wire->Metal1->MinWidth"); + + //Calculate number of folds and gate pitches needed + unsigned int folds = (normalized_size_ < 1.0) ? 1 : (unsigned int)ceil(normalized_size_); + cell_->getGenProperties()->set(name_ + "_GatePitches", 2 * folds); + + //Calculate widths, making sure they are above the minimum width + double nmos_width = std::max(calculateNmosWidth(cell_, 2, 2, 2) * normalized_size_ / folds, (double) tech->get("Gate->MinWidth")); + double pmos_width = std::max(calculatePmosWidth(cell_, 2, 2, 2) * normalized_size_ / folds, (double) tech->get("Gate->MinWidth")); + + //Calculate leakage power for each given input state + //if output_enable = 0, then it is possible that the PMOS may leak (if output = 0), + //or the NMOS will leak (if output = 1) + + //OE OEN A _ ZN + double leakage_power_010_0 = vdd * folds * tech->calculatePmosLeakageCurrent(2, pmos_width, ~0x2); + double leakage_power_010_1 = vdd * folds * tech->calculateNmosLeakageCurrent(2, nmos_width, 0x0); + double leakage_power_011_0 = vdd * folds * tech->calculatePmosLeakageCurrent(2, pmos_width, ~0x3); + double leakage_power_011_1 = vdd * folds * tech->calculateNmosLeakageCurrent(2, nmos_width, 0x1); + double leakage_power_100_1 = vdd * folds * tech->calculateNmosLeakageCurrent(2, nmos_width, 0x2); + double leakage_power_101_0 = vdd * folds * tech->calculatePmosLeakageCurrent(2, pmos_width, ~0x1); + cell_->getGenProperties()->set(name_ + "_LeakagePower_010_0", leakage_power_010_0); + cell_->getGenProperties()->set(name_ + "_LeakagePower_010_1", leakage_power_010_1); + cell_->getGenProperties()->set(name_ + "_LeakagePower_011_0", leakage_power_011_0); + cell_->getGenProperties()->set(name_ + "_LeakagePower_011_1", leakage_power_011_1); + cell_->getGenProperties()->set(name_ + "_LeakagePower_100_1", leakage_power_100_1); + cell_->getGenProperties()->set(name_ + "_LeakagePower_101_0", leakage_power_101_0); + + //Caculate stack balance + double pmos_stack2_balance = 1.0 + pmos_eff_res_stack_ratio; + double nmos_stack2_balance = 1.0 + nmos_eff_res_stack_ratio; + + //Calculate caps + double c_g_a = (nmos_width + pmos_width) * gate_cap * folds; + double c_g_oe = nmos_width * gate_cap * folds; + double c_g_oen = pmos_width * gate_cap * folds; + double c_d = (2 * pmos_width + 2 * nmos_width) * drain_cap * folds; + double r_on = (nmos_stack2_balance * nmos_eff_res / nmos_width + pmos_stack2_balance * pmos_eff_res / pmos_width) / (folds * 2.0); + + // Estimate the wire cap and add them all at the output + double cell_height = cell_->getTotalHeight(); + double wire_width = metal1_wire_min_width; + double wire_spacing = gate_pitch_contacted - metal1_wire_min_width; + double wire_length = 2.0 * folds * cell_height; + double wire_cap = tech->calculateWireCapacitance("Metal1", wire_width, wire_spacing, wire_length); + + // Construct equivalent load and drive strength + cell_->getLoad(name_ + "_CgA")->setLoadCap(c_g_a); + cell_->getLoad(name_ + "_CgOE")->setLoadCap(c_g_oe); + cell_->getLoad(name_ + "_CgOEN")->setLoadCap(c_g_oen); + cell_->getLoad(name_ + "_CdZN")->setLoadCap(c_d + wire_cap); + cell_->getDriver(name_ + "_RonZN")->setOutputRes(r_on); + + // Calculate flip energy (output flip) + double zn_flip_energy = 0.5 * (c_d + wire_cap) * vdd * vdd; + double a_flip_energy = 0.5 * c_g_a * vdd * vdd; + double oe_flip_energy = 0.5 * c_g_oe * vdd * vdd; + double oen_flip_energy = 0.5 * c_g_oen * vdd * vdd; + cell_->getGenProperties()->set(name_ + "_ZN_Flip", zn_flip_energy); + cell_->getGenProperties()->set(name_ + "_A_Flip", a_flip_energy); + cell_->getGenProperties()->set(name_ + "_OE_Flip", oe_flip_energy); + cell_->getGenProperties()->set(name_ + "_OEN_Flip", oen_flip_energy); + return; + } + //------------------------------------------------------------------------- + + + //------------------------------------------------------------------------- + // Helper Functions + //------------------------------------------------------------------------- + //Returns the width of NMOS transistors, given the NMOS and PMOS stacking + double CellMacros::calculateNmosWidth(const StdCell* cell_, unsigned int max_stacked_nmos_, unsigned int max_stacked_pmos_, unsigned int current_stacked_nmos_) + { + //Grab pointer to tech model + const TechModel* tech = cell_->getTechModel(); + + double nmos_eff_res_stack_ratio = tech->get("Nmos->EffResStackRatio"); + double pmos_eff_res_stack_ratio = tech->get("Pmos->EffResStackRatio"); + + double nmos_stack_balance = 1.0 + nmos_eff_res_stack_ratio * (double) (max_stacked_nmos_ - 1); + double pmos_stack_balance = 1.0 + pmos_eff_res_stack_ratio * (double) (max_stacked_pmos_ - 1); + double current_nmos_stack_balance = 1.0 + nmos_eff_res_stack_ratio * (double) (current_stacked_nmos_ - 1); + + double pn_ratio = cell_->getPToNRatio(); + double active_height = cell_->getActiveHeight(); + + //Calculate the width of the current device + double nmos_width = active_height * current_nmos_stack_balance / (nmos_stack_balance + pn_ratio * pmos_stack_balance); + + return nmos_width; + } + + //Returns the width of PMOS transistors, given the NMOS and PMOS stacking + double CellMacros::calculatePmosWidth(const StdCell* cell_, unsigned int max_stacked_nmos_, unsigned int max_stacked_pmos_, unsigned int current_stacked_pmos_) + { + //Grab pointer to tech model + const TechModel* tech = cell_->getTechModel(); + + double nmos_eff_res_stack_ratio = tech->get("Nmos->EffResStackRatio"); + double pmos_eff_res_stack_ratio = tech->get("Pmos->EffResStackRatio"); + + double nmos_stack_balance = 1.0 + nmos_eff_res_stack_ratio * (double) (max_stacked_nmos_ - 1); + double pmos_stack_balance = 1.0 + pmos_eff_res_stack_ratio * (double) (max_stacked_pmos_ - 1); + double current_pmos_stack_balance = 1.0 + pmos_eff_res_stack_ratio * (double) (current_stacked_pmos_ - 1); + + double pn_ratio = cell_->getPToNRatio(); + double active_height = cell_->getActiveHeight(); + + //Calculate the width of the current device + double pmos_width = active_height * current_pmos_stack_balance * pn_ratio / (nmos_stack_balance + pn_ratio * pmos_stack_balance); + + return pmos_width; + } + //------------------------------------------------------------------------- + +} // namespace DSENT + |