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[/] [openrisc/] [trunk/] [or1ksim/] [cuc/] [timings.c] - Rev 400
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/* timings.c -- OpenRISC Custom Unit Compiler, timing and size estimation * Copyright (C) 2002 Marko Mlinar, markom@opencores.org * * This file is part of OpenRISC 1000 Architectural Simulator. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include <stdio.h> #include <stdlib.h> #include <stdarg.h> #include <assert.h> #include <math.h> #include "config.h" #include "port.h" #include "arch.h" #include "abstract.h" #include "sim-config.h" #include "cuc.h" #include "insn.h" static cuc_timing_table *timing_table; static double max_bb_delay; /* Returns instruction delay */ double insn_time (cuc_insn *ii) { if (ii->opt[2] & OPT_CONST) { if (ii->opt[1] & OPT_CONST) return 0.; else return timing_table[ii->index].delayi; } else return timing_table[ii->index].delay; } /* Returns instruction size */ double insn_size (cuc_insn *ii) { double s = (ii->opt[2] & OPT_CONST) ? timing_table[ii->index].sizei : timing_table[ii->index].size; if (ii->opt[1] & OPT_CONST) return 0.; if (ii->type & IT_COND && (ii->index == II_CMOV || ii->index == II_ADD)) return s / 32.; else return s; } /* Returns normal instruction size */ double ii_size (int index, int imm) { if (imm) return timing_table[index].sizei; else return timing_table[index].size; } /* Returns dataflow tree height in cycles */ static double max_delay (cuc_func *f, int b) { double max_d = 0.; double *d; cuc_bb *bb = &f->bb[b]; int i, j; d = (double *) malloc (sizeof (double) * bb->ninsn); for (i = 0; i < bb->ninsn; i++) { double md = 0.; for (j = 0; j < MAX_OPERANDS; j++) { int op = bb->insn[i].op[j]; if (bb->insn[i].opt[j] & OPT_REF && op >= 0 && REF_BB (op) == b && REF_I (op) < i) { double t = d[REF_I (op)]; if (t > md) md = t; } } d[i] = md + insn_time (&bb->insn[i]); if (d[i] > max_d) max_d = d[i]; } free (d); //PRINTF ("max_d%i=%f\n", b, max_d); return max_d; } /* Calculates memory delay of a single run of a basic block */ static int memory_delay (cuc_func *f, int b) { int i; int d = 0; for (i = 0; i < f->nmsched; i++) if (REF_BB (f->msched[i]) == b) { if (f->mtype[i] & MT_STORE) { if (!(f->mtype[i] & MT_BURST) || f->mtype[i] & MT_BURSTE) d += runtime.cuc.mdelay[2]; else d += runtime.cuc.mdelay[3]; } else if (f->mtype[i] & MT_LOAD) { if (!(f->mtype[i] & MT_BURST) || f->mtype[i] & MT_BURSTE) d += runtime.cuc.mdelay[0]; else d += runtime.cuc.mdelay[1]; } } //PRINTF ("md%i=%i\n", b, d); return d; } /* Cuts the tree and marks registers */ void cut_tree (cuc_func *f, int b, double sd) { int i, j; double *depths; cuc_bb *bb = &f->bb[b]; depths = (double *) malloc (sizeof (double) * bb->ninsn); for (i = 0; i < bb->ninsn; i++) { double md = 0.; int mg = 0; for (j = 0; j < MAX_OPERANDS; j++) { int op = bb->insn[i].op[j]; if (bb->insn[i].opt[j] & OPT_REF && op >= 0 && REF_BB (op) == b && REF_I (op) < i) { double t = depths[REF_I (op)]; if (f->INSN(op).type & IT_CUT) { if (f->INSN(op).tmp + 1 >= mg) { if (f->INSN(op).tmp + 1 > mg) md = 0.; mg = f->INSN(op).tmp + 1; if (t > md) md = t; } } else { if (f->INSN(op).tmp >= mg) { if (f->INSN(op).tmp > mg) md = 0.; mg = f->INSN(op).tmp; if (t > md) md = t; } } } } //PRINTF ("%2x md%.1f ", i, md); md += insn_time (&bb->insn[i]); //PRINTF ("md%.1f mg%i %.1f\n", md, mg, sd); bb->insn[i].tmp = mg; if (md > sd) { bb->insn[i].type |= IT_CUT; if (md > runtime.cuc.cycle_duration) log ("WARNING: operation t%x_%x may need to be registered inbetween\n", b, i); depths[i] = 0.; } else depths[i] = md; } free (depths); } /* How many cycles we need now to get through the BB */ static int new_bb_cycles (cuc_func *f, int b, int cut) { long d; double x = max_delay (f, b); d = ceil (x / runtime.cuc.cycle_duration); if (d < 1) d = 1; if (cut && x > runtime.cuc.cycle_duration) cut_tree (f, b, x / d); if (x / d > max_bb_delay) max_bb_delay = x / d; return memory_delay (f, b) + d; } /* Cuts the tree and marks registers */ void mark_cut (cuc_func *f) { int b, i; for (b = 0; b < f->num_bb; b++) for (i = 0; i < f->bb[b].ninsn; i++) f->bb[b].insn[i].tmp = 0; /* Set starting groups */ if (config.cuc.no_multicycle) for (b = 0; b < f->num_bb; b++) new_bb_cycles (f, b, 1); } /* Returns basic block circuit area */ static double bb_size (cuc_bb *bb) { int i; double d = 0.; for (i = 0; i < bb->ninsn; i++) { if (bb->insn[i].opt[2] & OPT_CONST) d = d + timing_table[bb->insn[i].index].sizei; else d = d + timing_table[bb->insn[i].index].size; } return d; } /* Recalculates bb[].cnt values, based on generated profile file */ void recalc_cnts (cuc_func *f, char *bb_filename) { int i, r, b, prevbb = -1, prevcnt = 0; int buf[256]; const int bufsize = 256; FILE *fi = fopen (bb_filename, "rb"); assert (fi); /* initialize counts */ for (b = 0; b < f->num_bb; b++) f->bb[b].cnt = 0; /* read control flow from file and set counts */ do { r = fread (buf, sizeof (int), bufsize, fi); for (i = 0; i < r; i++) { b = f->init_bb_reloc[buf[i]]; if (b < 0) continue; /* Were we in the loop? */ if (b == prevbb) { prevcnt++; } else { /* End the block */ if (prevbb >= 0 && prevbb != BBID_START) f->bb[prevbb].cnt += prevcnt / f->bb[prevbb].unrolled + 1; prevcnt = 0; prevbb = b; } } } while (r == bufsize); fclose (fi); } /* Analizes current version of design and places results into timings structure */ void analyse_timings (cuc_func *f, cuc_timings *timings) { long new_time = 0; double size = 0.; int b, i; /* Add time needed for mtspr/mfspr */ for (i = 0; i < MAX_REGS; i++) if (f->used_regs[i]) new_time++; new_time++; /* always one mfspr at the end */ new_time *= f->num_runs; max_bb_delay = 0.; for (b = 0; b < f->num_bb; b++) { new_time += new_bb_cycles (f, b, 0) * f->bb[b].cnt; size = size + bb_size (&f->bb[b]); } timings->new_time = new_time; timings->size = size; log ("Max circuit delay %.2fns; max circuit clock speed %.1fMHz\n", max_bb_delay, 1000. / max_bb_delay); } /* Loads in the specified timings table */ void load_timing_table (char *filename) { int i; FILE *fi; log ("Loading timings from %s\n", filename); log ("Using clock delay %.2fns (frequency %.0fMHz)\n", runtime.cuc.cycle_duration, 1000. / runtime.cuc.cycle_duration); assert (fi = fopen (filename, "rt")); timing_table = (cuc_timing_table *)malloc ((II_LAST + 1) * sizeof (cuc_timing_table)); assert (timing_table); for (i = 0; i <= II_LAST; i++) { timing_table[i].size = -1.; timing_table[i].sizei = -1.; timing_table[i].delay = -1.; timing_table[i].delayi = -1.; } while (!feof(fi)) { char tmp[256]; int index = 0; if (fscanf (fi, "%s", tmp) != 1) break; if (tmp[0] == '#') { while (!feof (fi) && fgetc (fi) != '\n'); continue; } for (i = 0; i <= II_LAST; i++) if (strcmp (known[i].name, tmp) == 0) { index = i; break; } assert (index <= II_LAST); i = index; if (fscanf (fi, "%lf%lf%lf%lf\n", &timing_table[i].size, &timing_table[i].sizei, &timing_table[i].delay, &timing_table[i].delayi) != 4) break; /*PRINTF ("!%s size %f,%f delay %f,%f\n", known[i].name, timing_table[i].size, timing_table[i].sizei, timing_table[i].delay, timing_table[i].delayi);*/ } /* Was everything initialized? */ for (i = 0; i <= II_LAST; i++) { assert (timing_table[i].size >= 0 && timing_table[i].sizei >= 0 && timing_table[i].delay >= 0 && timing_table[i].delayi >= 0); /*PRINTF ("%s size %f,%f delay %f,%f\n", known[i], timing_table[i].size, timing_table[i].sizei, timing_table[i].delay, timing_table[i].delayi);*/ } fclose (fi); }
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