#!/usr/bin/env -S perl -w ########################################### ## libppa.pl ## ## Written: David_Harris@hmc.edu ## Created: 28 January 2023 ## ## Purpose: Extract PPA information from Liberty files ## presently characterizes Skywater 90 and TSMC28hpc+ ## ## The user will need to change $libpath to point to the desired library in your local installation ## and for TSMC change the $cellname to the actual name of the inverter. ## ## A component of the CORE-V-WALLY configurable RISC-V project. ## https://github.com/openhwgroup/cvw ## ## Copyright (C) 2021-23 Harvey Mudd College & Oklahoma State University ## ## SPDX-License-Identifier: Apache-2.0 WITH SHL-2.1 ## ## Licensed under the Solderpad Hardware License v 2.1 (the “License”); you may not use this file ## except in compliance with the License, or, at your option, the Apache License version 2.0. You ## may obtain a copy of the License at ## ## https:##solderpad.org/licenses/SHL-2.1/ ## ## Unless required by applicable law or agreed to in writing, any work distributed under the ## License is distributed on an “AS IS” BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, ## either express or implied. See the License for the specific language governing permissions ## and limitations under the License. ################################################################################################ use strict; use warnings; # global variables for simplicity my @index1; my @index2; my @values; my @cr; my @cf; my @rt; my @ft; # cell and corners to analyze my $libpath; my $libbase; my $cellname; my @corners; # Sky130 $libpath ="$ENV{RISCV}/cad/lib/sky130_osu_sc_t12/12T_ms/lib"; $libbase = "sky130_osu_sc_12T_ms_"; $cellname = "sky130_osu_sc_12T_ms__inv_1"; @corners = ("TT_1P8_25C.ccs", "tt_1P80_25C.ccs", "tt_1P62_25C.ccs", "tt_1P89_25C.ccs", "ss_1P60_-40C.ccs", "ss_1P60_100C.ccs", "ss_1P60_150C.ccs", "ff_1P95_-40C.ccs", "ff_1P95_100C.ccs", "ff_1P95_150C.ccs"); printf("Library $libbase Cell $cellname\n"); foreach my $corner (@corners) { &analyzeCell($corner); } # Sky90 $libpath ="$ENV{RISCV}/cad/lib/sky90/sky90_sc/V1.7.4/lib"; $libbase = "scc9gena_"; $cellname = "scc9gena_inv_1"; @corners = ("tt_1.2v_25C", "tt_1.08v_25C", "tt_1.32v_25C", "tt_1.2v_-40C", "tt_1.2v_85C", "tt_1.2v_125C", "ss_1.2v_25C", "ss_1.08v_-40C", "ss_1.08v_25C", "ss_1.08v_125C", "ff_1.2v_25C", "ff_1.32v_-40C", "ff_1.32v_25C", "ff_1.32v_125C"); printf("Library $libbase Cell $cellname\n"); foreach my $corner (@corners) { &analyzeCell($corner); } # TSMC $libpath = "/proj/models/tsmc28/libraries/28nmtsmc/tcbn28hpcplusbwp30p140_190a/TSMCHOME/digital/Front_End/timing_power_noise/NLDM/tcbn28hpcplusbwp30p140_180a"; $libbase = "tcbn28hpcplusbwp30p140"; $cellname = "INVD1..."; # replace this with the full name of the library cell @corners = ("tt0p9v25c", "tt0p8v25c", "tt1v25c", "tt0p9v85c", "ssg0p9vm40c", "ssg0p9v125c", "ssg0p81vm40c", "ssg0p81v125c", "ffg0p88vm40c", "ffg0p88v125c", "ffg0p99vm40c", "ffg0p99v125c"); printf("\nLibrary $libbase Cell $cellname\n"); foreach my $corner (@corners) { &analyzeCell($corner); } ############# # subroutines ############# sub analyzeCell { my $corner = shift; my $fname = $libpath."/".$libbase.$corner.".lib"; open (FILE, $fname) || die("Can't read $fname"); my $incell = 0; my $inleakage = 0; my $inpin = 0; my $incellrise = 0; my $incellfall = 0; my $inrisetrans = 0; my $infalltrans = 0; my $inindex = 0; my $invalues = 0; my $searchstring = "cell (".$cellname.")"; my $area; my $leakage; my $cap; while () { if (index($_, $searchstring) != -1) { $incell = 1;} elsif ($incell) { if (/cell $/) { $incell = 0; close(FILE); last; } if (/area\s*:\s*(.*);/) { $area = $1; } if (/cell_leakage_power\s*:\s*(.*);/) { $leakage = $1; $inleakage = 2; } if ($inleakage == 0 && /leakage_power/) { $inleakage = 1; } if ($inleakage == 1 && /value\s*:\s*(.*);/) { $leakage = $1; $inleakage = 2; } if ($inpin == 0 && /pin/) { $inpin = 1; } if ($inpin == 1 && /\s+capacitance\s*:\s*(.*);/) { $cap = $1; $inpin = 2; } if ($inindex == 0 && /index_1/) { $inindex = 1; } if ($inindex == 1) { if (/index_1\s*\(\"(.*)\"$;/) { @index1 = split(/, /, $1); } if (/index_2\s*$\"(.*)\"$;/) { @index2 = split(/, /, $1); $inindex = 2; } } if ($incellrise == 0 && /cell_rise/) { $incellrise = 1; $invalues = 0;} if ($incellfall == 0 && /cell_fall/) { $incellfall = 1; $invalues = 0; } if ($inrisetrans == 0 && /rise_trans/) { $inrisetrans = 1; $invalues = 0; } if ($infalltrans == 0 && /fall_trans/) { $infalltrans = 1; $invalues = 0; } if ($incellrise == 1 || $incellfall == 1 || $inrisetrans == 1 || $infalltrans == 1) { if (/values/) { $invalues = 1; @values = (); } elsif ($invalues == 1) { if (/\);/) { $invalues = 2; if ($incellrise == 1) { @cr = &parseVals(); $incellrise = 2; } if ($incellfall == 1) { @cf = &parseVals(); $incellfall = 2; } if ($inrisetrans == 1) { @rt = &parseVals(); $inrisetrans = 2; } if ($infalltrans == 1) { @ft = &parseVals(); $infalltrans = 2; } } elsif (/\"(.*)\"/) { push(@values, $1); } } } # print $_; } } my $delay = &computeDelay($cap); my $cornerr = sprintf("%20s", $corner); my $delayr = sprintf("%2.1f", $delay*1000); my $leakager = sprintf("%3.3f", $leakage); print("$cornerr: Delay $delayr Leakage: $leakager capacitance: $cap\n"); #print("$cellname $corner: Area $area Leakage: $leakage capacitance: $cap delay $delay\n"); #print(" index1: @index1\n"); #print(" index2: @index2\n"); #print("Cell Rise\n"); printMatrix(\@cr); #print("Cell Fall\n"); printMatrix(\@cf); #print("Rise Trans\n"); printMatrix(\@rt); #print("Fall Trans\n"); printMatrix(\@ft); } sub computeDelay { # relies on cr, cf, rt, ft, index1, index2 # index1 for rows of matrix (different trans times, units of ns) # index2 for cols of matrix (different load capacitances, units of pF) # first, given true load, create a rise/fall delay and transition # as a function of trans time, interpolated my $cap = shift; my $fo4cap = 4*$cap; my @cri = &interp2(\@cr, $fo4cap); my @cfi = &interp2(\@cf, $fo4cap); my @rti = &interp2(\@rt, $fo4cap); my @fti = &interp2(\@ft, $fo4cap); # initially guess second smallest transition time my $tt = $index1[1]; # assume falling input with this transition, compute rise delay & trans my $cr0 = &interp1(\@cri, \@index1, $tt); my $rt0 = &interp1(\@rti, \@index1, $tt); # now assuming rising input with rt0, compute fall delay & trans my $cf1 = &interp1(\@cfi, \@index1, $rt0); my $ft1 = &interp1(\@fti, \@index1, $rt0); # now assuming falling input with ft1, compute rise delay & trans my $cr2 = &interp1(\@cri, \@index1, $ft1); my $rt2 = &interp1(\@rti, \@index1, $ft1); # now assuming rising input with rt2, compute fall delay & trans my $cf3 = &interp1(\@cfi, \@index1, $rt2); my $ft3 = &interp1(\@fti, \@index1, $rt2); # delay is average of rising and falling my $delay = ($cr2 + $cf3)/2; return $delay; # print("tt $tt cr0 $cr0 rt0 $rt0\n"); # print("cf1 $cf1 ft1 $ft1 cr2 $cr2 rt2 $rt2 cf3 $cf3 ft3 $ft3 delay $delay\n"); } sub interp2 { my $matref = shift; my @matrix = @$matref; my $fo4cap = shift; my @interp = (); my $i; # interpolate row by row for ($i=0; $i <= $#index1; $i++) { my @row = @{$matrix[$i]}; #print ("Extracted row $i = @row\n"); $interp[$i] = &interp1(\@row, \@index2, $fo4cap); } return @interp; } sub interp1 { my $vecref = shift; my @vec = @$vecref; my $indexref = shift; my @index = @$indexref; my $x = shift; # find entry i containing the first index greater than x my $i = 0; while ($index[$i] < $x) {$i++} my $start = $index[$i-1]; my $end = $index[$i]; my $fract = ($x-$start)/($end-$start); my $interp = $vec[$i-1] + ($vec[$i] - $vec[$i-1])*$fract; # print ("Interpolating $x as $interp from i $i start $start end $end based on index @index and vec @vec\n"); return $interp; } sub parseVals { # relies on global variables @values, @index1, @index2 my @vals; my $i; my $j; for ($i=0; $i <= $#index1; $i++) { my @row = split(/, /,$values[$i]); for ($j = 0; $j <= $#index2; $j++) { $vals[$i][$j] = $row[$j]; } } return @vals; } sub printMatrix { my $mat = shift; my @matrix = @$mat; my $i; my $j; for ($i=0; $i <= $#index1; $i++) { for ($j = 0; $j <= $#index2; $j++) { print($matrix[$i][$j]." "); } print("\n"); } }