/***********************************/ /* SPICE Modeling for VPR */ /* Xifan TANG, EPFL/LSI */ /***********************************/ #include #include #include #include #include #include #include /* Include vpr structs*/ #include "util.h" #include "physical_types.h" #include "vpr_types.h" #include "globals.h" #include "rr_graph.h" #include "vpr_utils.h" /* Include spice support headers*/ #include "linkedlist.h" #include "fpga_spice_globals.h" #include "spice_globals.h" #include "fpga_spice_utils.h" #include "spice_utils.h" #include "spice_mux.h" #include "spice_pbtypes.h" #include "spice_subckt.h" /* For mrFPGA */ #ifdef MRFPGA_H #include "mrfpga_globals.h" #endif /***** Subroutines Declarations *****/ static void fprint_spice_meas_header(char* meas_file_name, t_spice_meas_params spice_meas_params); static void fprint_spice_stimulate_header(char* stimulate_file_name, t_spice_stimulate_params spice_stimulate_params, float vpr_clock_period, int num_clock); /***** Subroutines *****/ /* Print SPICE Netlists header*/ /* Print parameters for measurements */ static void fprint_spice_meas_header(char* meas_file_name, t_spice_meas_params spice_meas_params) { FILE* fp = NULL; /* Check */ assert(NULL != meas_file_name); /* Create File */ fp = fopen(meas_file_name, "w"); if (NULL == fp) { vpr_printf(TIO_MESSAGE_ERROR, "(File:%s,[LINE%d])Failure in create measure header file %s!\n", __FILE__, __LINE__, meas_file_name); exit(1); } /* Print parameters */ fprint_spice_head(fp, "Parameters for measurement"); fprintf(fp, "***** Parameters For Slew Measurement *****\n"); fprintf(fp, "***** Rising Edge *****\n"); fprintf(fp, ".param slew_upper_thres_pct_rise=%g\n", spice_meas_params.slew_upper_thres_pct_rise); fprintf(fp, ".param slew_lower_thres_pct_rise=%g\n", spice_meas_params.slew_lower_thres_pct_rise); fprintf(fp, "***** Falling Edge *****\n"); fprintf(fp, ".param slew_upper_thres_pct_fall=%g\n", spice_meas_params.slew_upper_thres_pct_fall); fprintf(fp, ".param slew_lower_thres_pct_fall=%g\n", spice_meas_params.slew_lower_thres_pct_fall); fprintf(fp, "***** Parameters For Delay Measurement *****\n"); fprintf(fp, "***** Rising Edge *****\n"); fprintf(fp, ".param input_thres_pct_rise=%g\n", spice_meas_params.input_thres_pct_rise); fprintf(fp, ".param output_thres_pct_rise=%g\n", spice_meas_params.output_thres_pct_rise); fprintf(fp, "***** Falling Edge *****\n"); fprintf(fp, ".param input_thres_pct_fall=%g\n", spice_meas_params.input_thres_pct_fall); fprintf(fp, ".param output_thres_pct_fall=%g\n", spice_meas_params.output_thres_pct_fall); /* Close File */ fclose(fp); return; } /* Print parameters for measurements */ static void fprint_spice_stimulate_header(char* stimulate_file_name, t_spice_stimulate_params spice_stimulate_params, float vpr_clock_period, int num_clock) { FILE* fp = NULL; float sim_clock_freq = 0.; float sim_clock_period = 0.; /* Check */ assert(NULL != stimulate_file_name); /* Create File */ fp = fopen(stimulate_file_name, "w"); if (NULL == fp) { vpr_printf(TIO_MESSAGE_ERROR, "(File:%s,[LINE%d])Failure in create stimulate header file %s!\n", __FILE__, __LINE__, stimulate_file_name); exit(1); } fprint_spice_head(fp, "Parameters for Stimulations"); /* if estimated clock frequency from VPR is 0. * this is a combinational circuit, clock frequency will never be used */ /* if the clock frequency is not specified in architecture file, * We define the clock frequency with estimated value and slack */ fprintf(fp, "***** Frequency *****\n"); sim_clock_freq = spice_stimulate_params.op_clock_freq; /* Simulate clock frequency should be larger than 0 !*/ assert(0. < sim_clock_freq); /*TODO: check this earlier!!! */ /* vpr_printf(TIO_MESSAGE_INFO, "Use Clock freqency %.2f [MHz] in SPICE simulation.\n", sim_clock_freq/1e6); */ fprintf(fp, ".param clock_period=%g\n", 1. / sim_clock_freq); sim_clock_period = 1./sim_clock_freq; /* Print parameters */ fprintf(fp, "***** Parameters For Input Stimulations *****\n"); switch (spice_stimulate_params.input_slew_rise_type) { case SPICE_ABS: if (sim_clock_period < (spice_stimulate_params.input_slew_rise_time + spice_stimulate_params.input_slew_fall_time)) { vpr_printf(TIO_MESSAGE_ERROR, "(File:%s,[LINE%d])Invalid input_slew_rise_time(%.2g), should be smaller than clock period(%.2g)!\n", __FILE__, __LINE__, spice_stimulate_params.input_slew_rise_time, sim_clock_period); exit(1); } fprintf(fp, ".param input_slew_pct_rise='%g/clock_period'\n", spice_stimulate_params.input_slew_rise_time); break; case SPICE_FRAC: fprintf(fp, ".param input_slew_pct_rise='%g'\n", spice_stimulate_params.input_slew_rise_time); break; default: vpr_printf(TIO_MESSAGE_ERROR, "(File:%s,[LINE%d])Invalid input_slew_rise_type!\n", __FILE__, __LINE__); exit(1); } switch (spice_stimulate_params.input_slew_fall_type) { case SPICE_ABS: if (sim_clock_period < (spice_stimulate_params.input_slew_rise_time + spice_stimulate_params.input_slew_fall_time)) { vpr_printf(TIO_MESSAGE_ERROR, "(File:%s,[LINE%d])Invalid input_slew_fall_time(%.2g), should be smaller than clock period(%.2g)!\n", __FILE__, __LINE__, spice_stimulate_params.input_slew_fall_time, sim_clock_period); exit(1); } fprintf(fp, ".param input_slew_pct_fall='%g/clock_period'\n", spice_stimulate_params.input_slew_fall_time); break; case SPICE_FRAC: fprintf(fp, ".param input_slew_pct_fall='%g'\n", spice_stimulate_params.input_slew_fall_time); break; default: vpr_printf(TIO_MESSAGE_ERROR, "(File:%s,[LINE%d])Invalid input_slew_fall_type!\n", __FILE__, __LINE__); exit(1); } fprintf(fp, "***** Parameters For Clock Stimulations *****\n"); fprintf(fp, "***** Slew *****\n"); switch (spice_stimulate_params.clock_slew_rise_type) { case SPICE_ABS: if (sim_clock_period < (spice_stimulate_params.clock_slew_rise_time + spice_stimulate_params.clock_slew_fall_time)) { vpr_printf(TIO_MESSAGE_ERROR, "(File:%s,[LINE%d])Invalid clock_slew_rise_time(%.2g)+clock_slew_fall_time(%.2g), should be smaller than clock period(%.2g)!\n", __FILE__, __LINE__, spice_stimulate_params.clock_slew_rise_time,spice_stimulate_params.clock_slew_fall_time, sim_clock_period); exit(1); } fprintf(fp, ".param clock_slew_pct_rise='%g/clock_period'\n", spice_stimulate_params.clock_slew_rise_time); break; case SPICE_FRAC: fprintf(fp, ".param clock_slew_pct_rise='%g'\n", spice_stimulate_params.clock_slew_rise_time); break; default: vpr_printf(TIO_MESSAGE_ERROR, "(File:%s,[LINE%d])Invalid clock_slew_rise_type!\n", __FILE__, __LINE__); exit(1); } switch (spice_stimulate_params.clock_slew_fall_type) { case SPICE_ABS: if (sim_clock_period < (spice_stimulate_params.clock_slew_rise_time + spice_stimulate_params.clock_slew_fall_time)) { vpr_printf(TIO_MESSAGE_ERROR, "(File:%s,[LINE%d])Invalid clock_slew_rise_time(%.2g)+clock_slew_fall_time(%.2g), should be smaller than clock period(%.2g)!\n", __FILE__, __LINE__, spice_stimulate_params.clock_slew_rise_time,spice_stimulate_params.clock_slew_fall_time, sim_clock_period); exit(1); } fprintf(fp, ".param clock_slew_pct_fall='%g/clock_period'\n", spice_stimulate_params.clock_slew_fall_time); break; case SPICE_FRAC: fprintf(fp, ".param clock_slew_pct_fall='%g'\n", spice_stimulate_params.clock_slew_fall_time); break; default: vpr_printf(TIO_MESSAGE_ERROR, "(File:%s,[LINE%d])Invalid input_slew_fall_type!\n", __FILE__, __LINE__); exit(1); } fclose(fp); return; } /* Print parameters for circuit designs */ static void fprint_spice_design_param_header(char* design_param_file_name, t_spice spice) { FILE* fp = NULL; /* Check */ assert(NULL != design_param_file_name); /* Create File */ fp = fopen(design_param_file_name, "w"); if (NULL == fp) { vpr_printf(TIO_MESSAGE_ERROR, "(File:%s,[LINE%d])Failure in create design parameter header file %s!\n", __FILE__, __LINE__, design_param_file_name); exit(1); } fprint_spice_head(fp, "Parameters for Circuit Designs"); fprint_tech_lib(fp, spice.spice_params.mc_params.cmos_variation, spice.tech_lib); /* For transistors */ fprint_spice_circuit_param(fp, spice.spice_params.mc_params, spice.num_spice_model, spice.spice_models); fclose(fp); return; } void spice_print_headers(char* include_dir_path, float vpr_clock_period, int num_clock, t_spice spice) { char* formatted_include_dir_path = format_dir_path(include_dir_path); char* meas_header_file_path = NULL; char* stimu_header_file_path = NULL; char* design_param_header_file_path = NULL; /* measurement header file */ meas_header_file_path = my_strcat(formatted_include_dir_path, meas_header_file_name); fprint_spice_meas_header(meas_header_file_path, spice.spice_params.meas_params); /* stimulate header file */ stimu_header_file_path = my_strcat(formatted_include_dir_path, stimu_header_file_name); fprint_spice_stimulate_header(stimu_header_file_path, spice.spice_params.stimulate_params, vpr_clock_period, num_clock); /* design parameter header file */ design_param_header_file_path = my_strcat(formatted_include_dir_path, design_param_header_file_name); fprint_spice_design_param_header(design_param_header_file_path, spice); return; }