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/* adv.c -- OpenRISC Custom Unit Compiler, Advanced Optimizations
 *    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 "config.h"
 
#include "port.h"
#include "arch.h"
#include "sim-config.h"
#include "abstract.h"
#include "cuc.h"
#include "insn.h"
#include "support/profile.h"
#include "misc.h"
 
/* Marks successor of b with mask m */
static void mark_successors (cuc_func *f, int b, int m, int stopb)
{
  if (b < 0 || b == BBID_END) return;
  if (f->bb[b].tmp & m) return;
  f->bb[b].tmp |= m;
  /* mark stopb also; and stop searching -- we will gen new result in stopb */
  if (b == stopb) return;
  mark_successors (f, f->bb[b].next[0], m, stopb);
  mark_successors (f, f->bb[b].next[1], m, stopb);
}
 
static unsigned long mask (unsigned long c)
{
  if (c) return (1 << (log2_int (c) + 1)) - 1;
  else return 0;
}
 
/* Calculates facts, that are determined by conditionals */
void insert_conditional_facts (cuc_func *f)
{
  int b, j;
  int b1, i1, j1;
  cuc_insn n[2];
  for (b = 0; b < f->num_bb; b++) if (f->bb[b].ninsn > 0) {
    cuc_insn *ii = &f->bb[b].insn[f->bb[b].ninsn - 1];
    /* We have following situation
       x <= ...
       sfxx f, x, CONST
       bf ..., f */
    if (ii->type & IT_BRANCH && ii->opt[1] & OPT_REF && REF_BB(ii->op[1]) == b
     && f->INSN(ii->op[1]).opt[2] & OPT_CONST) {
      int ok = 0;
      unsigned long c = f->INSN(ii->op[1]).op[2];
      int rref = f->INSN(ii->op[1]).op[1];
      unsigned long r;
      if (!(f->INSN(ii->op[1]).opt[1] & OPT_REF)) continue;
      r = f->INSN(rref).op[0];
 
      /* Assignment must be in same basic block */
      if (REF_BB(rref) != b) continue;
 
      for (j = 0; j < 2; j++) {
        change_insn_type (&n[j], II_ADD);
        n[j].type = 0;
        n[j].dep = NULL;
        n[j].op[0] = r; n[j].opt[0] = OPT_REGISTER | OPT_DEST;
        n[j].op[1] = 0; n[j].opt[1] = OPT_CONST;
        n[j].op[2] = rref; n[j].opt[2] = OPT_REF;
        n[j].opt[3] = OPT_NONE;
        sprintf (n[j].disasm, "conditional %s fact", j ? "false" : "true");
      }
 
      /* First get the conditional and two instruction to place after the current BB */
      switch (f->INSN(ii->op[1]).index) {
        case II_SFEQ:
          change_insn_type (&n[0], II_ADD);
          n[0].op[0] = r; n[0].opt[0] = OPT_REGISTER | OPT_DEST;
          n[0].op[1] = 0; n[0].opt[1] = OPT_CONST;
          n[0].op[2] = c; n[0].opt[2] = OPT_CONST;
          ok = 1;
          break;
        case II_SFNE:
          change_insn_type (&n[1], II_ADD);
          n[1].op[0] = r; n[1].opt[0] = OPT_REGISTER | OPT_DEST;
          n[1].op[1] = 0; n[1].opt[1] = OPT_CONST;
          n[1].op[2] = c; n[1].opt[2] = OPT_CONST;
          ok = 2;
          break;
        case II_SFLT:
          change_insn_type (&n[0], II_AND);
          n[0].op[0] = r; n[0].opt[0] = OPT_REGISTER | OPT_DEST;
          n[0].op[1] = rref; n[0].opt[1] = OPT_REF;
          n[0].op[2] = mask (c); n[0].opt[2] = OPT_CONST;
          ok = 1;
          break;
        case II_SFGT:
          change_insn_type (&n[1], II_ADD);
          n[1].op[0] = r; n[1].opt[0] = OPT_REGISTER | OPT_DEST;
          n[1].op[1] = rref; n[1].opt[1] = OPT_REF;
          n[1].op[2] = mask (c + 1); n[1].opt[2] = OPT_CONST;
          ok = 2;
          break;
        case II_SFLE:
          change_insn_type (&n[0], II_AND);
          n[0].op[0] = r; n[0].opt[0] = OPT_REGISTER | OPT_DEST;
          n[0].op[1] = rref; n[0].opt[1] = OPT_REF;
          n[0].op[2] = mask (c); n[0].opt[2] = OPT_CONST;
          ok = 1;
          break;
        case II_SFGE:
          change_insn_type (&n[1], II_ADD);
          n[1].op[0] = r; n[1].opt[0] = OPT_REGISTER | OPT_DEST;
          n[1].op[1] = rref; n[1].opt[1] = OPT_REF;
          n[1].op[2] = mask (c + 1); n[1].opt[2] = OPT_CONST;
          ok = 2;
          break;
        default:
          ok = 0;
          break;
      }
 
      /* Now add two BBs at the end and relink */
      if (ok) {
        int cnt = 0;
        cucdebug (1, "%x rref %x cnt %i\n", b, rref, cnt);
        fflush (stdout);
        for (j = 0; j < 2; j++) {
          int nb = f->num_bb++;
          int sb;
          assert (nb < MAX_BB);
          f->bb[nb].type = 0;
          f->bb[nb].first = -1; f->bb[nb].last = -1;
          f->bb[nb].prev[0] = b; f->bb[nb].prev[1] = -1;
          sb = f->bb[nb].next[0] = f->bb[b].next[j]; f->bb[nb].next[1] = -1;
          assert (cnt >= 0);
          cucdebug (2, "%x %x %x rref %x cnt %i\n", b, sb, nb, rref, cnt);
          fflush (stdout);
          assert (sb >= 0);
          f->bb[b].next[j] = nb;
          if (sb != BBID_END) {
            if (f->bb[sb].prev[0] == b) f->bb[sb].prev[0] = nb;
            else if (f->bb[sb].prev[1] == b) f->bb[sb].prev[1] = nb;
            else assert (0);
          }
          f->bb[nb].insn = (cuc_insn *) malloc (sizeof (cuc_insn) * (cnt + 1));
          assert (f->bb[nb].insn);
          f->bb[nb].insn[0] = n[j];
          f->bb[nb].ninsn = cnt + 1;
          f->bb[nb].mdep = NULL;
          f->bb[nb].nmemory = 0;
          f->bb[nb].cnt = 0;
          f->bb[nb].unrolled = 0;
          f->bb[nb].ntim = 0;
          f->bb[nb].selected_tim = -1;
        }
        for (b1 = 0; b1 < f->num_bb; b1++) f->bb[b1].tmp = 0;
 
        /* Find successor blocks and change links accordingly */
        mark_successors (f, f->num_bb - 2, 2, b);
        mark_successors (f, f->num_bb - 1, 1, b);
        for (b1 = 0; b1 < f->num_bb - 2; b1++) if (f->bb[b1].tmp == 1 || f->bb[b1].tmp == 2) {
          int end;
          if (REF_BB (rref) == b1) end = REF_I (rref) + 1;
          else end = f->bb[b1].ninsn;
          for (i1 = 0; i1 < end; i1++)
            for (j1 = 0; j1 < MAX_OPERANDS; j1++)
              if (f->bb[b1].insn[i1].opt[j1] & OPT_REF && f->bb[b1].insn[i1].op[j1] == rref)
                f->bb[b1].insn[i1].op[j1] = REF (f->num_bb - f->bb[b1].tmp, 0);
        }
        if (cuc_debug >= 3) print_cuc_bb (f, "FACT");
      }
    }
  }
}
 
static unsigned long max_op (cuc_func *f, int ref, int o)
{
  if (f->INSN(ref).opt[o] & OPT_REF) return f->INSN(f->INSN(ref).op[o]).max;
  else if (f->INSN(ref).opt[o] & OPT_CONST) return f->INSN(ref).op[o];
  else if (f->INSN(ref).opt[o] & OPT_REGISTER) return 0xffffffff;
  else assert (0);
  return 0;
}
 
/* Returns maximum value, based on inputs */
static unsigned long calc_max (cuc_func *f, int ref)
{
  cuc_insn *ii = &f->INSN(ref);
  if (ii->type & IT_COND) return 1;
  switch (ii->index) {
    case II_ADD : return MIN ((unsigned long long) max_op (f, ref, 1)
                            + (unsigned long long)max_op (f, ref, 2), 0xffffffff);
    case II_SUB : return 0xffffffff;
    case II_AND : return MIN (max_op (f, ref, 1), max_op (f, ref, 2));
    case II_OR  : return max_op (f, ref, 1) | max_op (f, ref, 2);
    case II_XOR : return max_op (f, ref, 1) | max_op (f, ref, 2);
    case II_MUL : return MIN ((unsigned long long) max_op (f, ref, 1)
                            * (unsigned long long)max_op (f, ref, 2), 0xffffffff);
    case II_SLL : if (ii->opt[2] & OPT_CONST) return max_op (f, ref, 1) << ii->op[2];
                  else return max_op (f, ref, 1);
    case II_SRA : return max_op (f, ref, 1);
    case II_SRL : if (ii->opt[2] & OPT_CONST) return max_op (f, ref, 1) >> ii->op[2];
                  else return max_op (f, ref, 1);
    case II_LB  : return 0xff;
    case II_LH  : return 0xffff;
    case II_LW  : return 0xffffffff;
    case II_SB  :
    case II_SH  :
    case II_SW  : return 0;
    case II_SFEQ:
    case II_SFNE:
    case II_SFLE:
    case II_SFLT:
    case II_SFGE:
    case II_SFGT: return 1;
    case II_BF  : return 0;
    case II_LRBB: return 1;
    case II_CMOV: return MAX (max_op (f, ref, 1), max_op (f, ref, 2));
    case II_REG : return max_op (f, ref, 1);
    case II_NOP : assert (0);
    case II_CALL: assert (0);
    default:  assert (0);
  }
  return -1;
}
 
/* Width optimization -- detect maximum values;
   these values are actually estimates, since the problem
   is to hard otherwise...
   We calculate these maximums iteratively -- we are slowly
   approaching final solution. This algorithm is surely finite,
   but can be very slow; so we stop after some iterations;
   normal loops should be in this range */
void detect_max_values (cuc_func *f)
{
  int b, i;
  int modified = 0;
  int iteration = 0;
 
  for (b = 0; b < f->num_bb; b++) {
    for (i = 0; i < f->bb[b].ninsn; i++) f->bb[b].insn[i].max = 0;
    f->bb[b].tmp = 1;
  }
 
  /* Repeat until something is changing */
  do {
    modified = 0;
    for (b = 0; b < f->num_bb; b++) {
      if (f->bb[b].tmp) {
        for (i = 0; i < f->bb[b].ninsn; i++) {
          unsigned long m = calc_max (f, REF (b, i));
          if (m > f->bb[b].insn[i].max) {
            f->bb[b].insn[i].max = m;
            modified = 1;
          }
        }
      }
    }
    if (iteration++ > CUC_WIDTH_ITERATIONS) break;
  } while (modified);
 
  /* Something bad has happened; now we will assign 0xffffffff to all unsatisfied
     instructions; this one is stoppable in O(n ^ 2) */
  if (iteration > CUC_WIDTH_ITERATIONS) {
    do {
      modified = 0;
      for (b = 0; b < f->num_bb; b++)
        for (i = 0; i < f->bb[b].ninsn; i++) {
          unsigned long m = calc_max (f, REF (b, i));
          if (m > f->bb[b].insn[i].max) {
            f->bb[b].insn[i].max = 0xffffffff;
            modified = 1;
          }
        }
    } while (modified);
  }
  cucdebug (1, "detect_max_values %i iterations\n", iteration);
}
 

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[/] [openrisc/] [trunk/] [or1ksim/] [cuc/] [adv.c] - Blame information for rev 19

Line No.	Rev	Author	Line
1	19	jeremybenn	`/* adv.c -- OpenRISC Custom Unit Compiler, Advanced Optimizations`
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
25			`#include "config.h"`
26
27			`#include "port.h"`
28			`#include "arch.h"`
29			`#include "sim-config.h"`
30			`#include "abstract.h"`
31			`#include "cuc.h"`
32			`#include "insn.h"`
33			`#include "support/profile.h"`
34			`#include "misc.h"`
35
36			`/* Marks successor of b with mask m */`
37			`static void mark_successors (cuc_func *f, int b, int m, int stopb)`
38			`{`
39			`if (b < 0 \|\| b == BBID_END) return;`
40			`if (f->bb[b].tmp & m) return;`
41			`f->bb[b].tmp \|= m;`
42			`/* mark stopb also; and stop searching -- we will gen new result in stopb */`
43			`if (b == stopb) return;`
44			`mark_successors (f, f->bb[b].next[0], m, stopb);`
45			`mark_successors (f, f->bb[b].next[1], m, stopb);`
46			`}`
47
48			`static unsigned long mask (unsigned long c)`
49			`{`
50			`if (c) return (1 << (log2_int (c) + 1)) - 1;`
51			`else return 0;`
52			`}`
53
54			`/* Calculates facts, that are determined by conditionals */`
55			`void insert_conditional_facts (cuc_func *f)`
56			`{`
57			`int b, j;`
58			`int b1, i1, j1;`
59			`cuc_insn n[2];`
60			`for (b = 0; b < f->num_bb; b++) if (f->bb[b].ninsn > 0) {`
61			`cuc_insn *ii = &f->bb[b].insn[f->bb[b].ninsn - 1];`
62			`/* We have following situation`
63			`x <= ...`
64			`sfxx f, x, CONST`
65			`bf ..., f */`
66			`if (ii->type & IT_BRANCH && ii->opt[1] & OPT_REF && REF_BB(ii->op[1]) == b`
67			`&& f->INSN(ii->op[1]).opt[2] & OPT_CONST) {`
68			`int ok = 0;`
69			`unsigned long c = f->INSN(ii->op[1]).op[2];`
70			`int rref = f->INSN(ii->op[1]).op[1];`
71			`unsigned long r;`
72			`if (!(f->INSN(ii->op[1]).opt[1] & OPT_REF)) continue;`
73			`r = f->INSN(rref).op[0];`
74
75			`/* Assignment must be in same basic block */`
76			`if (REF_BB(rref) != b) continue;`
77
78			`for (j = 0; j < 2; j++) {`
79			`change_insn_type (&n[j], II_ADD);`
80			`n[j].type = 0;`
81			`n[j].dep = NULL;`
82			`n[j].op[0] = r; n[j].opt[0] = OPT_REGISTER \| OPT_DEST;`
83			`n[j].op[1] = 0; n[j].opt[1] = OPT_CONST;`
84			`n[j].op[2] = rref; n[j].opt[2] = OPT_REF;`
85			`n[j].opt[3] = OPT_NONE;`
86			`sprintf (n[j].disasm, "conditional %s fact", j ? "false" : "true");`
87			`}`
88
89			`/* First get the conditional and two instruction to place after the current BB */`
90			`switch (f->INSN(ii->op[1]).index) {`
91			`case II_SFEQ:`
92			`change_insn_type (&n[0], II_ADD);`
93			`n[0].op[0] = r; n[0].opt[0] = OPT_REGISTER \| OPT_DEST;`
94			`n[0].op[1] = 0; n[0].opt[1] = OPT_CONST;`
95			`n[0].op[2] = c; n[0].opt[2] = OPT_CONST;`
96			`ok = 1;`
97			`break;`
98			`case II_SFNE:`
99			`change_insn_type (&n[1], II_ADD);`
100			`n[1].op[0] = r; n[1].opt[0] = OPT_REGISTER \| OPT_DEST;`
101			`n[1].op[1] = 0; n[1].opt[1] = OPT_CONST;`
102			`n[1].op[2] = c; n[1].opt[2] = OPT_CONST;`
103			`ok = 2;`
104			`break;`
105			`case II_SFLT:`
106			`change_insn_type (&n[0], II_AND);`
107			`n[0].op[0] = r; n[0].opt[0] = OPT_REGISTER \| OPT_DEST;`
108			`n[0].op[1] = rref; n[0].opt[1] = OPT_REF;`
109			`n[0].op[2] = mask (c); n[0].opt[2] = OPT_CONST;`
110			`ok = 1;`
111			`break;`
112			`case II_SFGT:`
113			`change_insn_type (&n[1], II_ADD);`
114			`n[1].op[0] = r; n[1].opt[0] = OPT_REGISTER \| OPT_DEST;`
115			`n[1].op[1] = rref; n[1].opt[1] = OPT_REF;`
116			`n[1].op[2] = mask (c + 1); n[1].opt[2] = OPT_CONST;`
117			`ok = 2;`
118			`break;`
119			`case II_SFLE:`
120			`change_insn_type (&n[0], II_AND);`
121			`n[0].op[0] = r; n[0].opt[0] = OPT_REGISTER \| OPT_DEST;`
122			`n[0].op[1] = rref; n[0].opt[1] = OPT_REF;`
123			`n[0].op[2] = mask (c); n[0].opt[2] = OPT_CONST;`
124			`ok = 1;`
125			`break;`
126			`case II_SFGE:`
127			`change_insn_type (&n[1], II_ADD);`
128			`n[1].op[0] = r; n[1].opt[0] = OPT_REGISTER \| OPT_DEST;`
129			`n[1].op[1] = rref; n[1].opt[1] = OPT_REF;`
130			`n[1].op[2] = mask (c + 1); n[1].opt[2] = OPT_CONST;`
131			`ok = 2;`
132			`break;`
133			`default:`
134			`ok = 0;`
135			`break;`
136			`}`
137
138			`/* Now add two BBs at the end and relink */`
139			`if (ok) {`
140			`int cnt = 0;`
141			`cucdebug (1, "%x rref %x cnt %i\n", b, rref, cnt);`
142			`fflush (stdout);`
143			`for (j = 0; j < 2; j++) {`
144			`int nb = f->num_bb++;`
145			`int sb;`
146			`assert (nb < MAX_BB);`
147			`f->bb[nb].type = 0;`
148			`f->bb[nb].first = -1; f->bb[nb].last = -1;`
149			`f->bb[nb].prev[0] = b; f->bb[nb].prev[1] = -1;`
150			`sb = f->bb[nb].next[0] = f->bb[b].next[j]; f->bb[nb].next[1] = -1;`
151			`assert (cnt >= 0);`
152			`cucdebug (2, "%x %x %x rref %x cnt %i\n", b, sb, nb, rref, cnt);`
153			`fflush (stdout);`
154			`assert (sb >= 0);`
155			`f->bb[b].next[j] = nb;`
156			`if (sb != BBID_END) {`
157			`if (f->bb[sb].prev[0] == b) f->bb[sb].prev[0] = nb;`
158			`else if (f->bb[sb].prev[1] == b) f->bb[sb].prev[1] = nb;`
159			`else assert (0);`
160			`}`
161			`f->bb[nb].insn = (cuc_insn ) malloc (sizeof (cuc_insn) (cnt + 1));`
162			`assert (f->bb[nb].insn);`
163			`f->bb[nb].insn[0] = n[j];`
164			`f->bb[nb].ninsn = cnt + 1;`
165			`f->bb[nb].mdep = NULL;`
166			`f->bb[nb].nmemory = 0;`
167			`f->bb[nb].cnt = 0;`
168			`f->bb[nb].unrolled = 0;`
169			`f->bb[nb].ntim = 0;`
170			`f->bb[nb].selected_tim = -1;`
171			`}`
172			`for (b1 = 0; b1 < f->num_bb; b1++) f->bb[b1].tmp = 0;`
173
174			`/* Find successor blocks and change links accordingly */`
175			`mark_successors (f, f->num_bb - 2, 2, b);`
176			`mark_successors (f, f->num_bb - 1, 1, b);`
177			`for (b1 = 0; b1 < f->num_bb - 2; b1++) if (f->bb[b1].tmp == 1 \|\| f->bb[b1].tmp == 2) {`
178			`int end;`
179			`if (REF_BB (rref) == b1) end = REF_I (rref) + 1;`
180			`else end = f->bb[b1].ninsn;`
181			`for (i1 = 0; i1 < end; i1++)`
182			`for (j1 = 0; j1 < MAX_OPERANDS; j1++)`
183			`if (f->bb[b1].insn[i1].opt[j1] & OPT_REF && f->bb[b1].insn[i1].op[j1] == rref)`
184			`f->bb[b1].insn[i1].op[j1] = REF (f->num_bb - f->bb[b1].tmp, 0);`
185			`}`
186			`if (cuc_debug >= 3) print_cuc_bb (f, "FACT");`
187			`}`
188			`}`
189			`}`
190			`}`
191
192			`static unsigned long max_op (cuc_func *f, int ref, int o)`
193			`{`
194			`if (f->INSN(ref).opt[o] & OPT_REF) return f->INSN(f->INSN(ref).op[o]).max;`
195			`else if (f->INSN(ref).opt[o] & OPT_CONST) return f->INSN(ref).op[o];`
196			`else if (f->INSN(ref).opt[o] & OPT_REGISTER) return 0xffffffff;`
197			`else assert (0);`
198			`return 0;`
199			`}`
200
201			`/* Returns maximum value, based on inputs */`
202			`static unsigned long calc_max (cuc_func *f, int ref)`
203			`{`
204			`cuc_insn *ii = &f->INSN(ref);`
205			`if (ii->type & IT_COND) return 1;`
206			`switch (ii->index) {`
207			`case II_ADD : return MIN ((unsigned long long) max_op (f, ref, 1)`
208			`+ (unsigned long long)max_op (f, ref, 2), 0xffffffff);`
209			`case II_SUB : return 0xffffffff;`
210			`case II_AND : return MIN (max_op (f, ref, 1), max_op (f, ref, 2));`
211			`case II_OR : return max_op (f, ref, 1) \| max_op (f, ref, 2);`
212			`case II_XOR : return max_op (f, ref, 1) \| max_op (f, ref, 2);`
213			`case II_MUL : return MIN ((unsigned long long) max_op (f, ref, 1)`
214			`* (unsigned long long)max_op (f, ref, 2), 0xffffffff);`
215			`case II_SLL : if (ii->opt[2] & OPT_CONST) return max_op (f, ref, 1) << ii->op[2];`
216			`else return max_op (f, ref, 1);`
217			`case II_SRA : return max_op (f, ref, 1);`
218			`case II_SRL : if (ii->opt[2] & OPT_CONST) return max_op (f, ref, 1) >> ii->op[2];`
219			`else return max_op (f, ref, 1);`
220			`case II_LB : return 0xff;`
221			`case II_LH : return 0xffff;`
222			`case II_LW : return 0xffffffff;`
223			`case II_SB :`
224			`case II_SH :`
225			`case II_SW : return 0;`
226			`case II_SFEQ:`
227			`case II_SFNE:`
228			`case II_SFLE:`
229			`case II_SFLT:`
230			`case II_SFGE:`
231			`case II_SFGT: return 1;`
232			`case II_BF : return 0;`
233			`case II_LRBB: return 1;`
234			`case II_CMOV: return MAX (max_op (f, ref, 1), max_op (f, ref, 2));`
235			`case II_REG : return max_op (f, ref, 1);`
236			`case II_NOP : assert (0);`
237			`case II_CALL: assert (0);`
238			`default: assert (0);`
239			`}`
240			`return -1;`
241			`}`
242
243			`/* Width optimization -- detect maximum values;`
244			`these values are actually estimates, since the problem`
245			`is to hard otherwise...`
246			`We calculate these maximums iteratively -- we are slowly`
247			`approaching final solution. This algorithm is surely finite,`
248			`but can be very slow; so we stop after some iterations;`
249			`normal loops should be in this range */`
250			`void detect_max_values (cuc_func *f)`
251			`{`
252			`int b, i;`
253			`int modified = 0;`
254			`int iteration = 0;`
255
256			`for (b = 0; b < f->num_bb; b++) {`
257			`for (i = 0; i < f->bb[b].ninsn; i++) f->bb[b].insn[i].max = 0;`
258			`f->bb[b].tmp = 1;`
259			`}`
260
261			`/* Repeat until something is changing */`
262			`do {`
263			`modified = 0;`
264			`for (b = 0; b < f->num_bb; b++) {`
265			`if (f->bb[b].tmp) {`
266			`for (i = 0; i < f->bb[b].ninsn; i++) {`
267			`unsigned long m = calc_max (f, REF (b, i));`
268			`if (m > f->bb[b].insn[i].max) {`
269			`f->bb[b].insn[i].max = m;`
270			`modified = 1;`
271			`}`
272			`}`
273			`}`
274			`}`
275			`if (iteration++ > CUC_WIDTH_ITERATIONS) break;`
276			`} while (modified);`
277
278			`/* Something bad has happened; now we will assign 0xffffffff to all unsatisfied`
279			`instructions; this one is stoppable in O(n ^ 2) */`
280			`if (iteration > CUC_WIDTH_ITERATIONS) {`
281			`do {`
282			`modified = 0;`
283			`for (b = 0; b < f->num_bb; b++)`
284			`for (i = 0; i < f->bb[b].ninsn; i++) {`
285			`unsigned long m = calc_max (f, REF (b, i));`
286			`if (m > f->bb[b].insn[i].max) {`
287			`f->bb[b].insn[i].max = 0xffffffff;`
288			`modified = 1;`
289			`}`
290			`}`
291			`} while (modified);`
292			`}`
293			`cucdebug (1, "detect_max_values %i iterations\n", iteration);`
294			`}`
295