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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 "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;
    double a[4];
    char c;
    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);
}
 

Line No.	Rev	Author	Line
1	879	markom	`/* timings.c -- OpenRISC Custom Unit Compiler, timing and size estimation`
2			`* Copyright (C) 2002 Marko Mlinar, markom@opencores.org`
3			`*`
4			`* This file is part of OpenRISC 1000 Architectural Simulator.`
5			`*`
6			`* This program is free software; you can redistribute it and/or modify`
7			`* it under the terms of the GNU General Public License as published by`
8			`* the Free Software Foundation; either version 2 of the License, or`
9			`* (at your option) any later version.`
10			`*`
11			`* This program is distributed in the hope that it will be useful,`
12			`* but WITHOUT ANY WARRANTY; without even the implied warranty of`
13			`* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the`
14			`* GNU General Public License for more details.`
15			`*`
16			`* You should have received a copy of the GNU General Public License`
17			`* along with this program; if not, write to the Free Software`
18			`* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */`
19
20			`#include <stdio.h>`
21			`#include <stdlib.h>`
22			`#include <stdarg.h>`
23			`#include <assert.h>`
24			`#include <math.h>`
25	897	markom	`#include "sim-config.h"`
26	879	markom	`#include "cuc.h"`
27			`#include "insn.h"`
28
29			`static cuc_timing_table *timing_table;`
30	897	markom	`static double max_bb_delay;`
31	879	markom
32	883	markom	`/* Returns instruction delay */`
33			`double insn_time (cuc_insn *ii)`
34	879	markom	`{`
35	930	markom	`if (ii->opt[2] & OPT_CONST) {`
36			`if (ii->opt[1] & OPT_CONST) return 0.;`
37			`else return timing_table[ii->index].delayi;`
38			`} else return timing_table[ii->index].delay;`
39	879	markom	`}`
40
41	883	markom	`/* Returns instruction size */`
42			`double insn_size (cuc_insn *ii)`
43			`{`
44	930	markom	`double s = (ii->opt[2] & OPT_CONST) ? timing_table[ii->index].sizei`
45			`: timing_table[ii->index].size;`
46			`if (ii->opt[1] & OPT_CONST) return 0.;`
47			`if (ii->type & IT_COND && (ii->index == II_CMOV \|\| ii->index == II_ADD)) return s / 32.;`
48			`else return s;`
49	883	markom	`}`
50
51			`/* Returns normal instruction size */`
52			`double ii_size (int index, int imm)`
53			`{`
54			`if (imm) return timing_table[index].sizei;`
55			`else return timing_table[index].size;`
56			`}`
57
58	879	markom	`/* Returns dataflow tree height in cycles */`
59			`static double max_delay (cuc_func *f, int b)`
60			`{`
61			`double max_d = 0.;`
62			`double *d;`
63			`cuc_bb *bb = &f->bb[b];`
64			`int i, j;`
65			`d = (double ) malloc (sizeof (double) bb->ninsn);`
66			`for (i = 0; i < bb->ninsn; i++) {`
67			`double md = 0.;`
68			`for (j = 0; j < MAX_OPERANDS; j++) {`
69			`int op = bb->insn[i].op[j];`
70			`if (bb->insn[i].opt[j] & OPT_REF && op >= 0 && REF_BB (op) == b && REF_I (op) < i) {`
71			`double t = d[REF_I (op)];`
72			`if (t > md) md = t;`
73			`}`
74			`}`
75			`d[i] = md + insn_time (&bb->insn[i]);`
76			`if (d[i] > max_d) max_d = d[i];`
77			`}`
78			`free (d);`
79			`//printf ("max_d%i=%f\n", b, max_d);`
80			`return max_d;`
81			`}`
82
83			`/* Calculates memory delay of a single run of a basic block */`
84			`static int memory_delay (cuc_func *f, int b)`
85			`{`
86			`int i;`
87			`int d = 0;`
88			`for (i = 0; i < f->nmsched; i++)`
89			`if (REF_BB (f->msched[i]) == b) {`
90	907	markom	`if (f->mtype[i] & MT_STORE) {`
91	897	markom	`if (!(f->mtype[i] & MT_BURST) \|\| f->mtype[i] & MT_BURSTE) d += runtime.cuc.mdelay[2];`
92			`else d += runtime.cuc.mdelay[3];`
93	907	markom	`} else if (f->mtype[i] & MT_LOAD) {`
94	897	markom	`if (!(f->mtype[i] & MT_BURST) \|\| f->mtype[i] & MT_BURSTE) d += runtime.cuc.mdelay[0];`
95			`else d += runtime.cuc.mdelay[1];`
96	879	markom	`}`
97			`}`
98			`//printf ("md%i=%i\n", b, d);`
99			`return d;`
100			`}`
101
102			`/* Cuts the tree and marks registers */`
103			`void cut_tree (cuc_func *f, int b, double sd)`
104			`{`
105			`int i, j;`
106			`double *depths;`
107			`cuc_bb *bb = &f->bb[b];`
108			`depths = (double ) malloc (sizeof (double) bb->ninsn);`
109
110			`for (i = 0; i < bb->ninsn; i++) {`
111			`double md = 0.;`
112			`int mg = 0;`
113			`for (j = 0; j < MAX_OPERANDS; j++) {`
114			`int op = bb->insn[i].op[j];`
115			`if (bb->insn[i].opt[j] & OPT_REF && op >= 0 && REF_BB (op) == b && REF_I (op) < i) {`
116			`double t = depths[REF_I (op)];`
117			`if (f->INSN(op).type & IT_CUT) {`
118			`if (f->INSN(op).tmp + 1 >= mg) {`
119			`if (f->INSN(op).tmp + 1 > mg) md = 0.;`
120			`mg = f->INSN(op).tmp + 1;`
121			`if (t > md) md = t;`
122			`}`
123			`} else {`
124			`if (f->INSN(op).tmp >= mg) {`
125			`if (f->INSN(op).tmp > mg) md = 0.;`
126			`mg = f->INSN(op).tmp;`
127			`if (t > md) md = t;`
128			`}`
129			`}`
130			`}`
131			`}`
132			`//printf ("%2x md%.1f ", i, md);`
133			`md += insn_time (&bb->insn[i]);`
134			`//printf ("md%.1f mg%i %.1f\n", md, mg, sd);`
135			`bb->insn[i].tmp = mg;`
136			`if (md > sd) {`
137			`bb->insn[i].type \|= IT_CUT;`
138	897	markom	`if (md > runtime.cuc.cycle_duration)`
139	879	markom	`log ("WARNING: operation t%x_%x may need to be registered inbetween\n", b, i);`
140			`depths[i] = 0.;`
141			`} else depths[i] = md;`
142			`}`
143			`free (depths);`
144			`}`
145
146			`/* How many cycles we need now to get through the BB */`
147			`static int new_bb_cycles (cuc_func *f, int b, int cut)`
148			`{`
149			`long d;`
150			`double x = max_delay (f, b);`
151	897	markom	`d = ceil (x / runtime.cuc.cycle_duration);`
152	879	markom	`if (d < 1) d = 1;`
153	897	markom	`if (cut && x > runtime.cuc.cycle_duration) cut_tree (f, b, x / d);`
154	879	markom
155			`if (x / d > max_bb_delay) max_bb_delay = x / d;`
156	883	markom
157	879	markom	`return memory_delay (f, b) + d;`
158			`}`
159
160			`/* Cuts the tree and marks registers */`
161			`void mark_cut (cuc_func *f)`
162			`{`
163			`int b, i;`
164			`for (b = 0; b < f->num_bb; b++)`
165			`for (i = 0; i < f->bb[b].ninsn; i++)`
166			`f->bb[b].insn[i].tmp = 0; /* Set starting groups */`
167	897	markom	`if (config.cuc.no_multicycle)`
168	879	markom	`for (b = 0; b < f->num_bb; b++)`
169			`new_bb_cycles (f, b, 1);`
170			`}`
171
172			`/* Returns basic block circuit area */`
173			`static double bb_size (cuc_bb *bb)`
174			`{`
175			`int i;`
176			`double d = 0.;`
177			`for (i = 0; i < bb->ninsn; i++) {`
178			`if (bb->insn[i].opt[2] & OPT_CONST)`
179			`d = d + timing_table[bb->insn[i].index].sizei;`
180			`else d = d + timing_table[bb->insn[i].index].size;`
181			`}`
182			`return d;`
183			`}`
184
185			`/* Recalculates bb[].cnt values, based on generated profile file */`
186			`void recalc_cnts (cuc_func f, char bb_filename)`
187			`{`
188			`int i, r, b, prevbb = -1, prevcnt = 0;`
189			`int buf[256];`
190			`const int bufsize = 256;`
191			`FILE *fi = fopen (bb_filename, "rb");`
192
193			`assert (fi);`
194
195			`/* initialize counts */`
196			`for (b = 0; b < f->num_bb; b++) f->bb[b].cnt = 0;`
197
198			`/* read control flow from file and set counts */`
199			`do {`
200			`r = fread (buf, sizeof (int), bufsize, fi);`
201			`for (i = 0; i < r; i++) {`
202			`b = f->init_bb_reloc[buf[i]];`
203			`if (b < 0) continue;`
204			`/* Were we in the loop? */`
205			`if (b == prevbb) {`
206			`prevcnt++;`
207			`} else {`
208			`/* End the block */`
209	932	markom	`if (prevbb >= 0 && prevbb != BBID_START)`
210			`f->bb[prevbb].cnt += prevcnt / f->bb[prevbb].unrolled + 1;`
211	879	markom	`prevcnt = 0;`
212			`prevbb = b;`
213			`}`
214			`}`
215			`} while (r == bufsize);`
216
217			`fclose (fi);`
218			`}`
219
220			`/* Analizes current version of design and places results into timings structure */`
221			`void analyse_timings (cuc_func f, cuc_timings timings)`
222			`{`
223			`long new_time = 0;`
224			`double size = 0.;`
225	883	markom	`int b, i;`
226	879	markom
227	883	markom	`/* Add time needed for mtspr/mfspr */`
228			`for (i = 0; i < MAX_REGS; i++) if (f->used_regs[i]) new_time++;`
229			`new_time++; /* always one mfspr at the end */`
230			`new_time *= f->num_runs;`
231
232	879	markom	`max_bb_delay = 0.;`
233			`for (b = 0; b < f->num_bb; b++) {`
234			`new_time += new_bb_cycles (f, b, 0) * f->bb[b].cnt;`
235			`size = size + bb_size (&f->bb[b]);`
236			`}`
237			`timings->new_time = new_time;`
238			`timings->size = size;`
239			`log ("Max circuit delay %.2fns; max circuit clock speed %.1fMHz\n",`
240			`max_bb_delay, 1000. / max_bb_delay);`
241			`}`
242
243			`/* Loads in the specified timings table */`
244			`void load_timing_table (char *filename)`
245			`{`
246			`int i;`
247			`FILE *fi;`
248
249			`log ("Loading timings from %s\n", filename);`
250	897	markom	`log ("Using clock delay %.2fns (frequency %.0fMHz)\n", runtime.cuc.cycle_duration,`
251			`1000. / runtime.cuc.cycle_duration);`
252	879	markom	`assert (fi = fopen (filename, "rt"));`
253
254			`timing_table = (cuc_timing_table )malloc ((II_LAST + 1) sizeof (cuc_timing_table));`
255			`assert (timing_table);`
256			`for (i = 0; i <= II_LAST; i++) {`
257			`timing_table[i].size = -1.;`
258			`timing_table[i].sizei = -1.;`
259			`timing_table[i].delay = -1.;`
260			`timing_table[i].delayi = -1.;`
261			`}`
262
263			`while (!feof(fi)) {`
264			`char tmp[256];`
265			`int index;`
266			`double a[4];`
267			`char c;`
268			`if (fscanf (fi, "%s", tmp) != 1) break;`
269			`if (tmp[0] == '#') {`
270			`while (!feof (fi) && fgetc (fi) != '\n');`
271			`continue;`
272			`}`
273			`for (i = 0; i <= II_LAST; i++)`
274			`if (strcmp (known[i].name, tmp) == 0) {`
275			`index = i;`
276			`break;`
277			`}`
278			`assert (index <= II_LAST);`
279			`i = index;`
280			`if (fscanf (fi, "%lf%lf%lf%lf\n", &timing_table[i].size,`
281			`&timing_table[i].sizei, &timing_table[i].delay, &timing_table[i].delayi) != 4) break;`
282			`/*printf ("!%s size %f,%f delay %f,%f\n", known[i].name, timing_table[i].size,`
283			`timing_table[i].sizei, timing_table[i].delay, timing_table[i].delayi);*/`
284			`}`
285
286			`/* Was everything initialized? */`
287			`for (i = 0; i <= II_LAST; i++) {`
288			`assert (timing_table[i].size >= 0 && timing_table[i].sizei >= 0`
289			`&& timing_table[i].delay >= 0 && timing_table[i].delayi >= 0);`
290			`/*printf ("%s size %f,%f delay %f,%f\n", known[i], timing_table[i].size,`
291			`timing_table[i].sizei, timing_table[i].delay, timing_table[i].delayi);*/`
292			`}`
293
294			`fclose (fi);`
295			`}`
296

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