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main.c
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main.c
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/* main.c
* tracing procedure algorithm
* 1 May 2001: extend with example
*
* options:
* -A # accuracy for prior generation, maximally MAXACCURACY
* -b both normal and sequence form
* -c complementary pivoting steps shown
* -d degeneracy statistics in lexmin ratio test
* -e give equilibrium (when -m #)
* -E equilibrium leaves from input only
* -i interface with Audet/Hansen enumeration, NF/SF as chosen
* -g print raw game data
* -G file interface with GAMBIT via file (re-writes for each game,
* so don't use with -m )
* -l # bintree with # levels (e.g. #=3, any number in
* MINLEVEL .. MAXLEVEL is allowed)
* default (no -l option): solve tracingexample.
* negative number: -1 solve forward induction example
* -m # process multiple games, requires -l option
* -m 1 implies quiet mode
* -M # multiple priors per game
* -n compute with normal form (default: sequence form)
* -o output LCP
* -O output prior
* -p -- # # # # ... replace the payoffs at leaves by # # # #
* (leaf 0/pl 1, leaf 0/pl 2, leaf 1/pl 1, leaf 1/pl 2 ...)
* which should be NEGATIVE since invoked AFTER re-normalization;
* this must be the LAST option on the command line
* -r compute with RSF (not yet implemented)
* -s # payoff seed
* -S # prior seed
* -t tableaus at every pivoting step
*/
#include <stdio.h>
#include <string.h> /* strcpy */
#include <stdlib.h> /* atoi(), free() */
#include <ctype.h> /* isprint() */
/* #include <unistd.h> */
#include "getopt.h"
/* getopt(), optarg, optopt, optind */
#include <time.h>
/* clock_t, clock(), CLOCKS_PER_SEC */
#include <limits.h>
/* INT_MAX, INT_MIN */
#include "alloc.h"
#include "rat.h"
#include "lemke.h"
#include "mp.h" /* record_digits, DIG2DEC() */
#include "treedef.h"
#include "treegen.h"
#include "sfnf.h"
#include "seqform.h"
#include "normform.h"
#include "prior.h"
#include "leaves.h"
#include "gambit.h"
#include "interface.h"
#define MINLEVEL 1
#define MAXLEVEL 10
#define FILENAMELENGTH 50
#define CLOCKUNITSPERSECOND 1000.0
#define SCLOCKUNITS "millisecs"
#define WHICHFORMS 2 /* currently only SF (0), NF (1) */
#define REPEATHEADER 20 /* repeat header if more games than this */
/* global variables for generating and documenting computation */
static Flagsprior fprior;
static Bool boutlcp = 0; /* output LCP (-o option) */
static Bool boutprior = 0; /* output prior (-O option) */
static Bool bcomment = 0; /* complementary pivoting steps */
static Bool bequil = 1; /* output equilibrium */
static Bool bshortequil = 0; /* output equilibrium shortly */
static Bool bleavesonly = 0; /* equilibrium leaves only */
static Bool binterface = 0; /* interface with enumeration */
static Bool bgambit = 0; /* interface with gambit */
/* GAMBIT interface file, option parameter */
static char gintfname[FILENAMELENGTH] = "dummyname" ;
static Flagsrunlemke flemke;
static int timeused [WHICHFORMS], sumtimeused [WHICHFORMS];
static int pivots [WHICHFORMS], sumpivots [WHICHFORMS];
static int lcpsize [WHICHFORMS];
static int mpdigits [WHICHFORMS], summpdigits [WHICHFORMS];
static int eqsize [PLAYERS] [WHICHFORMS], sumeqsize [PLAYERS] [WHICHFORMS];
static Bool agreenfsf [PLAYERS] ;
/* initialize sumarray[WHICHFORMS] to zero */
void settozero(int *sumarray)
{
int i;
for (i = 0; i < WHICHFORMS; i++)
sumarray[i] = 0;
}
/* returns processor SCLOCKUNITS since the last call to
* stopwatch() and prints them to stdout if bprint==1
*/
int stopwatch(Bool bprint)
{
static clock_t time;
double x;
x = (double) (clock()) - (double) time;
if (x < 0)
x += 2 * (double) INT_MAX;
x /= ((double) CLOCKS_PER_SEC / CLOCKUNITSPERSECOND) ;
if (bprint)
printf("time elapsed [%s] %4.0f\n", SCLOCKUNITS, x);
time = clock();
return (int) x;
}
/* informs about tree size */
void infotree()
{
int pl;
printf("\nGame tree has %d nodes, ", lastnode - root);
printf("of which %d are terminal nodes.\n", lastoutcome - outcomes);
for (pl = 0; pl < PLAYERS; pl++)
{
printf(" Player %d has ", pl);
printf("%3d information sets, ", firstiset[pl+1] - firstiset[pl]);
printf("%3d moves in total\n", firstmove[pl+1] - firstmove[pl] - 1);
}
}
/* informs about normal form, compute and set lcpsize[NFORM] */
void infonf()
{
int dim[PLAYERS];
int pl;
for (pl = 1; pl < PLAYERS; pl++)
dim[pl] = numstratsnfpre(pl);
lcpsize [NFORM] = dim[1] + dim[2] + 2 ;
printf("Normal form LCP dimension is %d\n", lcpsize [NFORM] );
for (pl = 1; pl < PLAYERS; pl++)
{
printf(" Player %d has ", pl);
printf("%5d RNF pure strategies\n", dim[pl]);
}
}
/* informs about sequence form, set lcpsize[SFORM] */
void infosf()
{
int pl;
lcpsize [SFORM] = nseqs[1] + nisets[2]+1 + nseqs[2] + nisets[1]+1 ;
printf("Sequence form LCP dimension is %d\n", lcpsize [SFORM] );
for (pl = 1; pl < PLAYERS; pl++)
{
printf(" Player %d has ", pl);
printf("%3d sequences, ", nseqs[pl]);
printf("subject to %3d constraints\n", nisets[pl]+1);
}
}
/* give header columns for result information via inforesult(...) */
void inforesultheader (Bool bsf, Bool bnf)
{
printf("PRIOR/PAY| ");
if (bnf)
{
printf("NORMAL FORM support");
if (bsf)
printf(" |agrees| ");
}
if (bsf)
printf("SEQUENCE FORM mixiset");
printf("\n");
printf("Seed/seed| ");
if (bsf)
{
printf("pivot %%n [secs] digs pl1 pl2");
if (bnf)
printf(" |pl1,2 | ");
}
if (bnf)
printf("pivot %%n [secs] digs pl1 pl2");
printf("\n");
}
/* info about results for game with priorseed and (payoff) seed */
void inforesult (Bool bsf, Bool bnf, int priorseed, int seed)
{
char formatstring[] = "%4d %3.0f %6.2f %3d %3d %3d" ;
printf("%4d/%4d| ", priorseed, seed);
if (bnf)
{
printf(formatstring, pivots [NFORM],
(double) pivots [NFORM]*100.0 / (double) lcpsize [NFORM],
(double) timeused [NFORM] / CLOCKUNITSPERSECOND,
mpdigits [NFORM], eqsize [1] [NFORM], eqsize [2] [NFORM]);
if (bsf)
printf(" | %s %s | ", agreenfsf[1] ? "Y" : "N",
agreenfsf[2] ? "Y" : "N");
}
if (bsf)
printf(formatstring, pivots [SFORM],
(double) pivots [SFORM]*100.0 / (double) lcpsize [SFORM],
(double) timeused [SFORM] / CLOCKUNITSPERSECOND,
mpdigits [SFORM], eqsize [1] [SFORM], eqsize [2] [SFORM]);
printf("\n");
}
/* summary info about results for m games */
void infosumresult (Bool bsf, Bool bnf, int m)
{
double mm = (double) m;
char formatstring[] = "%6.1f %3.0f %6.2f %4.1f %3.1f %3.1f" ;
printf("---------| AVERAGES over %d games:\n", m);
if (m > REPEATHEADER)
inforesultheader (bsf, bnf);
printf(" ");
if (bnf)
{
printf(formatstring, (double) sumpivots [NFORM]/ mm,
(double) sumpivots [NFORM]*100.0 /
(double) (lcpsize [NFORM] * mm),
(double) sumtimeused [NFORM] / (CLOCKUNITSPERSECOND * mm),
(double) summpdigits [NFORM] / mm,
(double) sumeqsize [1] [NFORM] / mm,
(double) sumeqsize [2] [NFORM] / mm);
if (bsf)
printf(" ");
}
if (bsf)
printf(formatstring, (double) sumpivots [SFORM]/ mm,
(double) sumpivots [SFORM]*100.0 /
(double) (lcpsize [SFORM] * mm),
(double) sumtimeused [SFORM] / (CLOCKUNITSPERSECOND * mm),
(double) summpdigits [SFORM] / mm,
(double) sumeqsize [1] [SFORM] / mm,
(double) sumeqsize [2] [SFORM] / mm);
printf("\n");
}
/* process game for evaluation
* for comparison: call first for NF then SF
* bnf: NF is processed, compare result with SF result
* docuseed: what seed to output for short equilibrium output
* realplan[][] must be allocated
*/
void processgame (int whichform, Bool bnf, int docuseed)
{
int equilsize;
int offset;
int pl;
if (whichform == NFORM)
{
if (bcomment)
printf("Generating and solving normal form.\n");
nflcp();
}
else if (whichform == SFORM)
{
if (bcomment)
printf("Generating and solving sequence form.\n");
sflcp();
}
else
abort(); /* no RNF yet */
covvector(whichform);
if (boutlcp)
outlcp();
stopwatch(0);
record_digits = 0;
runlemke(flemke);
sumtimeused [whichform] += timeused [whichform] =
stopwatch(0);
sumpivots [whichform] += pivots [whichform] =
pivotcount;
summpdigits [whichform] += mpdigits [whichform] =
DIG2DEC(record_digits);
/* equilibrium size */
offset = 0;
for (pl = 1; pl < PLAYERS; pl++)
{
if (whichform == NFORM)
{
equilsize = supportsize(pl, solz + offset);
mixedtorealplan(pl, solz + offset, realplan[pl]);
/* the next is offset for player 2 */
offset = nstrats[1] + 1;
}
else if (whichform == SFORM)
{
equilsize = propermixisets(pl, solz + offset);
if (bnf)
agreenfsf[pl] = eqrealplans(pl, solz + offset,
realplan[pl], bcomment);
/* the next is offset for player 2 */
offset = nseqs[1] + 1 + nisets[2] ;
}
else
abort(); /* no RNF yet */
sumeqsize [pl] [whichform] +=
eqsize [pl] [whichform] = equilsize ;
}
if (bequil)
showeq (whichform, bshortequil, docuseed);
if (bgambit && whichform == SFORM)
gambshoweq();
}
int main(int argc, char *argv[])
{
int levels = 0; /* which game to process, (-l option)
* 0: tracing example BvS/Elzen/Talman,
* -1: forward induction example
* MINLEVEL..MAXLEVEL: bintree
*/
int multiplegames = 0; /* parameter for -m option */
int multipriors = 0; /* parameter for -M option */
int seed = 0; /* payoff seed for bintree (-s option) */
int newpayoffs = 0; /* number of payoffs to be replaced (-p)*/
int *newp1, *newp2; /* arrays for entering new payoffs */
/* whichform currently not used (later for RSF) */
int whichform = 0; /* 0: SF, 1: NF, 2: RSF */
Bool bheadfirst = 0;/* headers first (multiple games) */
Bool bsf = 1; /* Y/N process SF, default */
Bool bnf = 0; /* Y/N process NF (-n option) */
Bool bgame = 0; /* output the raw game tree (-g option) */
int c ;
flemke.maxcount = 0;
flemke.bdocupivot = 0;
flemke.binitabl = 0;
flemke.bouttabl = 0;
flemke.boutsol = 0;
flemke.binteract = 0;
flemke.blexstats = 0;
fprior.seed = 0 ;
fprior.accuracy = DEFAULTACCURACY ;
/* parse options */
while ( (c = getopt (argc, argv, "A:bcdeEgG:il:m:M:noOprs:S:t")) != -1)
switch (c)
{
int x;
case 'A':
x = atoi(optarg);
if (x <= MAXACCURACY && x > 0 )
fprior.accuracy = x ;
else
{
fprintf(stderr, "Entered accuracy %d for prior ", x);
fprintf(stderr, "not in 1..%d, not done.\n", MAXACCURACY);
}
break;
case 'b':
bnf = 1;
bsf = 1;
break;
case 'c':
bcomment = 1;
break;
case 'd':
flemke.blexstats = 1;
break;
case 'e':
bshortequil = 1;
break;
case 'E':
bleavesonly = 1;
break;
case 'g':
bgame = 1;
break;
case 'G':
bgambit = 1;
strcpy(gintfname, optarg);
break;
case 'i':
binterface = 1;
break;
case 'l':
levels = atoi(optarg);
if (levels >= MINLEVEL && levels <= MAXLEVEL)
break;
if (levels == -1)
break;
fprintf(stderr, "Binary tree level %d ", levels);
fprintf(stderr, "not in range %d .. %d, not done.\n",
MINLEVEL, MAXLEVEL);
return 1;
case 'm':
multiplegames = atoi(optarg);
break;
case 'M':
multipriors = atoi(optarg);
break;
case 'n':
bnf = 1;
bsf = 0;
break;
case 'o':
boutlcp = 1;
break;
case 'O':
boutprior = 1;
break;
case 'p':
newpayoffs = 1;
break;
case 'r':
whichform = RSFORM ;
break;
case 's':
seed = atoi(optarg);
break;
case 'S':
x = atoi(optarg);
if ( x > 0 )
fprior.seed = x ;
else
{
fprintf(stderr, "Entered Seed %d for prior ", x);
fprintf(stderr, "must be positive, ignored.\n");
}
break;
case 't':
flemke.bouttabl = 1;
flemke.binitabl = 1;
break;
case '?':
if (isprint (optopt))
fprintf (stderr, "Unknown option `-%c'.\n", optopt);
else
fprintf (stderr,
"Unknown option character `\\x%x'.\n",
optopt);
return 1;
default:
abort ();
}
/* options have been input, amend extras */
if (newpayoffs)
{
newpayoffs = (argc - optind)/2;
printf("Entering %d new payoff pair(s).\n", newpayoffs);
}
if (newpayoffs)
{
int i;
newp1 = TALLOC(newpayoffs, int);
newp2 = TALLOC(newpayoffs, int);
for (i = 0, c = optind; i < newpayoffs; i++)
{
newp1[i] = atoi(argv[c++]);
newp2[i] = atoi(argv[c++]);
}
}
if (multiplegames)
{
if (levels == 0)
{
printf("Multiple games only for binary tree, ");
printf("but will change equilibrium output.\n");
multiplegames = 0;
bequil = 0 ;
}
if (newpayoffs)
{
printf("Multiple games not with changed payoffs, ");
printf("but will change equilibrium output.\n");
multiplegames = 1;
}
/* else */
{
bequil = bshortequil;
bheadfirst = !bcomment && !boutlcp && !flemke.bouttabl &&
!flemke.blexstats && !bgame ;
}
}
if (multipriors > 0)
{
/* this would exclude the centroid for multiple priors
if ( fprior.seed == 0)
fprior.seed = 1 ;
*/
}
else
multipriors = 1 ;
if (bcomment)
{
flemke.bdocupivot = 1;
flemke.boutsol = 1;
}
/* options are parsed and flags set */
/* document the set options */
printf("Options chosen, [ ] = default:\n");
printf(" normal form %s [N], option -n\n",
bnf ? "Y" : "N");
printf(" sequence form %s [Y], option -b : both NF and SF\n",
bsf ? "Y" : "N");
printf(" interface to enumerate %s [N], option -i , NF/SF as above\n",
binterface ? "Y" : "N");
printf(" GAMBIT interface %s [N], ", bgambit ? "Y" : "N");
printf("option -G file, SF only\n");
printf(" levels binary tree %2d [0], option -l # ", levels);
printf("(default 0: simple example)\n");
printf(" seed payoffs %3d [0], option -s #\n", seed);
printf(" multiple games %3d [0], option -m # ", multiplegames);
printf("(no equilibria unless option -e)\n");
printf(" equilibrium one line %s [N], option -e\n",
bshortequil ? "Y" : "N");
printf(" equil leaves < stdin %s [N], option -E\n",
bleavesonly ? "Y" : "N");
printf(" payoffs new %3d [0], option -p -- # # ... #\n",
newpayoffs);
printf(" Multiple priors %4d [1], option -M #\n", multipriors);
printf(" Accuracy prior %4d [%d], option -A #\n",
fprior.accuracy, DEFAULTACCURACY);
printf(" Seed prior %3d [0], ",
fprior.seed);
printf("option -S # (default 0: centroid)\n");
printf(" Output prior %s [N], option -O\n",
boutprior ? "Y" : "N");
printf(" game output %s [N], option -g\n",
bgame ? "Y" : "N");
printf(" comment LCP pivs & sol %s [N], option -c\n",
bcomment ? "Y" : "N");
printf(" output LCP %s [N], option -o\n",
boutlcp ? "Y" : "N");
printf(" degeneracy statistics %s [N], option -d\n",
flemke.blexstats ? "Y" : "N");
printf(" tableaus %s [N], option -t\n",
flemke.bouttabl ? "Y" : "N");
if (levels == 0)
{
printf("Solving example from BvS/Elzen/Talman\n");
tracingexample();
}
else
if (levels == -1)
{
printf("Forward induction example\n");
forwardexample();
}
else
createbintree (levels, seed);
genseqin();
autoname();
maxpayminusone(bcomment);
if (newpayoffs)
{
int i;
if (newpayoffs > lastoutcome-outcomes)
{
newpayoffs = lastoutcome-outcomes;
printf("Only the %d outcomes get new payoffs.\n", newpayoffs);
}
for (i = 0; i < newpayoffs; i++)
{
outcomes[i].pay[0] = ratfromi(newp1[i]);
printf ("Outcome %2d pay1: %3d, ", i, newp1[i]);
outcomes[i].pay[1] = ratfromi(newp2[i]);
printf ("pay2: %3d\n", newp2[i]);
}
printf("re-normalize payoffs again.\n");
maxpayminusone(bcomment);
free(newp1);
free(newp2);
}
/* game tree is defined, give headline information */
infotree();
if (bleavesonly)
leavesfrominput();
else
{
if (bnf)
infonf();
if (bsf)
infosf();
/* process games */
if (multiplegames == 0)
multiplegames = 1; /* simplify counting */
{
int gamecount = 0;
int startprior = fprior.seed ;
allocrealplan(realplan);
if (bheadfirst) /* otherwise the header is garbled by LCP output */
inforesultheader (bsf, bnf);
while(1) /* process multiple games */
{
int priorcount ;
/* multiple priors */
if (bgambit)
gambopenfile(gintfname);
for (priorcount = 0; priorcount < multipriors; priorcount++)
{
genprior(fprior);
if (bgame)
rawtreeprint();
if (boutprior)
outprior();
if (bnf)
processgame(NFORM, bnf, seed + gamecount);
if (bsf)
processgame(SFORM, bnf, seed + gamecount);
if ( ! bheadfirst )
inforesultheader (bsf, bnf);
inforesult (bsf, bnf, fprior.seed, seed + gamecount);
fprior.seed++ ;
}
if (binterface)
{
interface(bnf, bsf);
binterface = 0;
}
if (bgambit)
gambclosefile() ;
/* next game */
gamecount++ ;
if (gamecount >= multiplegames)
break;
if (multipriors > 1)
printf("\n") ;
createbintree (levels, seed + gamecount);
genseqin();
autoname();
maxpayminusone(bcomment);
fprior.seed = startprior ;
} /* end of processing multiple games */
if (multipriors * multiplegames > 1) /* give averages */
infosumresult (bsf, bnf, multipriors * multiplegames);
freerealplan(realplan);
}
}
return 0;
}