OpenXM_contrib2/asir2000/builtin/strobj.c - diff

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Diff for /OpenXM_contrib2/asir2000/builtin/strobj.c between version 1.82 and 1.96

version 1.82, 2005/10/26 08:39:58

version 1.96, 2005/11/04 07:03:38

Line 45

* DEVELOPER SHALL HAVE NO LIABILITY IN CONNECTION WITH THE USE,

* PERFORMANCE OR NON-PERFORMANCE OF THE SOFTWARE.

* $OpenXM: OpenXM_contrib2/asir2000/builtin/strobj.c,v 1.81 2005/10/26 07:33:03 noro Exp $

* $OpenXM: OpenXM_contrib2/asir2000/builtin/strobj.c,v 1.95 2005/11/03 07:41:22 noro Exp $

#include "ca.h"

#include "parse.h"

Line 58 extern jmp_buf environnement;

#endif

#include <string.h>

#if defined(__GNUC__)

#define INLINE inline

#elif defined(VISUAL)

#define INLINE __inline

#else

#define INLINE

#endif

struct TeXSymbol {

char *text;

char *symbol;

Line 87 void Pflatten_quote();

Line 95 void Pflatten_quote();

void Pquote_is_integer(),Pquote_is_rational(),Pquote_is_number();

void Pquote_is_dependent(),Pquote_is_function();

void Pquote_normalize();

void Pquote_normalize_comp();

void Pnquote_comp();

void Pnquote_match();

void Pquote_to_funargs(),Pfunargs_to_quote(),Pget_function_name();

void Pquote_unify(),Pget_quote_id(),Pquote_match_rewrite();

void Pquote_match(),Pget_quote_id(),Pquote_match_rewrite();

void Pquote_to_nary(),Pquote_to_bin();

void fnode_do_assign(NODE arg);

void do_assign(NODE arg);

void fnodetotex_tb(FNODE f,TB tb);

char *symbol_name(char *name);

Line 102 void tb_to_string(TB tb,STRING *rp);

Line 112 void tb_to_string(TB tb,STRING *rp);

void fnodenodetotex_tb(NODE n,TB tb);

void fargstotex_tb(char *opname,FNODE f,TB tb);

int top_is_minus(FNODE f);

int quote_unify(Obj f,Obj pat,NODE *rp);

int quote_match(Obj f,Obj pat,NODE *rp);

struct ftab str_tab[] = {

{"sprintf",Psprintf,-99999999},

Line 127 struct ftab str_tab[] = {

Line 137 struct ftab str_tab[] = {

{"quote_is_dependent",Pquote_is_dependent,2},

{"quote_normalize",Pquote_normalize,-2},

{"quote_normalize_comp",Pquote_normalize_comp,2,0x3},

{"quote_match",Pquote_match,2},

{"quote_match_rewrite",Pquote_match_rewrite,-4},

{"nquote_comp",Pnquote_comp,2},

{"nquote_match",Pnquote_match,2},

{"quote_to_nary",Pquote_to_nary,1},

{"quote_to_bin",Pquote_to_bin,2},

{"quotetotex_tb",Pquotetotex_tb,2},

{"quotetotex",Pquotetotex,1},

{"quotetotex_env",Pquotetotex_env,-99999999},

{"flatten_quote",Pflatten_quote,-2},

{"quote_to_funargs",Pquote_to_funargs,1},

{"quote_unify",Pquote_unify,2},

{"quote_match_rewrite",Pquote_match_rewrite,-4},

{"funargs_to_quote",Pfunargs_to_quote,1},

{"get_function_name",Pget_function_name,1},

{0,0,0},

Line 623 void Pquote_is_dependent(NODE arg,Q *rp)

Line 635 void Pquote_is_dependent(NODE arg,Q *rp)

}

void Pquote_unify(NODE arg,Q *rp)

void Pquote_match(NODE arg,Q *rp)

{

FNODE f,g;

Obj obj;

Line 634 void Pquote_unify(NODE arg,Q *rp)

Line 646 void Pquote_unify(NODE arg,Q *rp)

#if 0

g = partial_eval(BDY(((QUOTE)ARG0(arg))));

MKQUOTE(q,g);

ret = quote_unify((Obj)q,(Obj)ARG1(arg),&r);

ret = quote_match((Obj)q,(Obj)ARG1(arg),&r);

#else

obj = (Obj)ARG0(arg);

ret = quote_unify(obj,(Obj)ARG1(arg),&r);

ret = quote_match(obj,(Obj)ARG1(arg),&r);

#endif

if ( ret ) {

do_assign(r);

Line 646 void Pquote_unify(NODE arg,Q *rp)

Line 658 void Pquote_unify(NODE arg,Q *rp)

*rp = 0;

}

void Pnquote_match(NODE arg,Q *rp)

{

QUOTE fq,pq;

FNODE f,p;

int ret;

NODE r;

fq = (QUOTE)ARG0(arg); Pquote_normalize(mknode(2,fq,0),&fq); f = (FNODE)BDY(fq);

pq = (QUOTE)ARG1(arg); Pquote_normalize(mknode(2,pq,0),&pq); p = (FNODE)BDY(pq);

ret = nfnode_match(f,p,&r);

if ( ret ) {

fnode_do_assign(r);

*rp = ONE;

} else

*rp = 0;

}

FNODE rewrite_fnode(FNODE,NODE);

extern Obj VOIDobj;

Line 659 void Pquote_match_rewrite(NODE arg,Obj *rp)

Line 688 void Pquote_match_rewrite(NODE arg,Obj *rp)

int ret,ind,ac;

obj = (Obj)ARG0(arg);

ret = quote_unify(obj,(Obj)ARG1(arg),&r);

ret = quote_match(obj,(Obj)ARG1(arg),&r);

if ( ret ) {

for ( t = r, s0 = 0; t; t = NEXT(t) ) {

NEXTNODE(s0,s);

Line 704 void do_assign(NODE arg)

Line 733 void do_assign(NODE arg)

}

/* [[index,fnode],...] */

void fnode_do_assign(NODE arg)

{

NODE t,pair;

int pv;

FNODE f;

QUOTE value;

QUOTEARG qa;

for ( t = arg; t; t = NEXT(t) ) {

pair = (NODE)BDY(t);

pv = (int)BDY(pair);

f = (FNODE)(BDY(NEXT(pair)));

if ( f->id == I_FUNC_HEAD ) {

/* XXX : I_FUNC_HEAD is a dummy id to pass FUNC */

MKQUOTEARG(qa,A_func,FA0(f));

value = (QUOTE)qa;

} else

MKQUOTE(value,f);

ASSPV(pv,value);

}

/* consistency check and merge

Line 739 int merge_matching_node(NODE n,NODE a,NODE *rp)

Line 792 int merge_matching_node(NODE n,NODE a,NODE *rp)

return 1;

}

int quote_unify_node(NODE f,NODE pat,NODE *rp) {

int quote_match_node(NODE f,NODE pat,NODE *rp) {

NODE r,a,tf,tp,r1;

int ret;

if ( length(f) != length(pat) ) return 0;

r = 0;

for ( tf = f, tp = pat; tf; tf = NEXT(tf), tp = NEXT(tp) ) {

ret = quote_unify((Obj)BDY(tf),(Obj)BDY(tp),&a);

ret = quote_match((Obj)BDY(tf),(Obj)BDY(tp),&a);

if ( !ret ) return 0;

ret = merge_matching_node(r,a,&r1);

if ( !ret ) return 0;

Line 758 int quote_unify_node(NODE f,NODE pat,NODE *rp) {

Line 811 int quote_unify_node(NODE f,NODE pat,NODE *rp) {

/* f = [a,b,c,...] pat = [X,Y,...] rpat matches the rest of f */

int quote_unify_cons(NODE f,NODE pat,Obj rpat,NODE *rp) {

int quote_match_cons(NODE f,NODE pat,Obj rpat,NODE *rp) {

QUOTE q;

Q id;

FNODE fn;

Line 770 int quote_unify_cons(NODE f,NODE pat,Obj rpat,NODE *rp

Line 823 int quote_unify_cons(NODE f,NODE pat,Obj rpat,NODE *rp

if ( length(f) < length(pat) ) return 0;

r = 0;

for ( tf = f, tp = pat; tp; tf = NEXT(tf), tp = NEXT(tp) ) {

ret = quote_unify((Obj)BDY(tf),(Obj)BDY(tp),&a);

ret = quote_match((Obj)BDY(tf),(Obj)BDY(tp),&a);

if ( !ret ) return 0;

ret = merge_matching_node(r,a,&r1);

if ( !ret ) return 0;

Line 782 int quote_unify_cons(NODE f,NODE pat,Obj rpat,NODE *rp

Line 835 int quote_unify_cons(NODE f,NODE pat,Obj rpat,NODE *rp

MKLIST(alist,a);

arg = mknode(1,alist);

Pfunargs_to_quote(arg,&q);

ret = quote_unify((Obj)q,rpat,&a);

ret = quote_match((Obj)q,rpat,&a);

if ( !ret ) return 0;

ret = merge_matching_node(r,a,&r1);

if ( !ret ) return 0;

Line 801 void get_quote_id_arg(QUOTE f,int *id,NODE *r)

Line 854 void get_quote_id_arg(QUOTE f,int *id,NODE *r)

/* *rp : [[quote(A),quote(1)],...] */

int quote_unify(Obj f, Obj pat, NODE *rp)

int quote_match(Obj f, Obj pat, NODE *rp)

{

NODE tf,tp,head,body;

NODE parg,farg,r;

Line 820 int quote_unify(Obj f, Obj pat, NODE *rp)

Line 873 int quote_unify(Obj f, Obj pat, NODE *rp)

return 0;

else if ( OID(pat) == O_LIST ) {

if ( OID(f) == O_LIST )

return quote_unify_node(BDY((LIST)f),BDY((LIST)pat),rp);

return quote_match_node(BDY((LIST)f),BDY((LIST)pat),rp);

else

return 0;

} else if ( OID(pat) == O_QUOTE ) {

Line 847 int quote_unify(Obj f, Obj pat, NODE *rp)

Line 900 int quote_unify(Obj f, Obj pat, NODE *rp)

tp = BDY((LIST)BDY(parg));

if ( pid == I_LIST )

return quote_unify_node(tf,tp,rp);

return quote_match_node(tf,tp,rp);

else {

rpat = (Obj)BDY(NEXT(parg));

return quote_unify_cons(tf,tp,rpat,rp);

return quote_match_cons(tf,tp,rpat,rp);

}

case I_PVAR:

Line 866 int quote_unify(Obj f, Obj pat, NODE *rp)

Line 919 int quote_unify(Obj f, Obj pat, NODE *rp)

if ( id == I_FUNC ) {

r = mknode(2,BDY(parg),BDY(farg)); MKLIST(l,r);

head = mknode(1,l);

ret = quote_unify(BDY(NEXT(farg)),

ret = quote_match(BDY(NEXT(farg)),

BDY(NEXT(parg)),&body);

if ( !ret ) return 0;

else return merge_matching_node(head,body,rp);

Line 894 int quote_unify(Obj f, Obj pat, NODE *rp)

Line 947 int quote_unify(Obj f, Obj pat, NODE *rp)

get_quote_id_arg((QUOTE)pat,&pid,&parg);

get_quote_id_arg((QUOTE)f,&id,&farg);

if ( compqa(CO,BDY(farg),BDY(parg)) ) return 0;

return quote_unify_node(NEXT(farg),NEXT(parg),rp);

return quote_match_node(NEXT(farg),NEXT(parg),rp);

default:

if ( OID(f) != O_QUOTE ) return 0;

Line 902 int quote_unify(Obj f, Obj pat, NODE *rp)

Line 955 int quote_unify(Obj f, Obj pat, NODE *rp)

if ( id != pid ) return 0;

get_quote_id_arg((QUOTE)pat,&pid,&parg);

get_quote_id_arg((QUOTE)f,&id,&farg);

return quote_unify_node(farg,parg,rp);

return quote_match_node(farg,parg,rp);

}

Line 1268 FNODE strip_paren(FNODE);

Line 1321 FNODE strip_paren(FNODE);

void fnodetotex_tb(FNODE f,TB tb)

{

NODE n,t,t0;

NODE n,t,t0,args;

char vname[BUFSIZ],prefix[BUFSIZ];

char *opname,*vname_conv,*prefix_conv;

Obj obj;

int i,len,allzero,elen,elen2,si;

C cplx;

char *r;

FNODE fi,f2;

FNODE fi,f2,f1;

write_tb(" ",tb);

if ( !f ) {

Line 1356 void fnodetotex_tb(FNODE f,TB tb)

Line 1409 void fnodetotex_tb(FNODE f,TB tb)

break;

}

break;

case I_NARYOP:

args = (NODE)FA1(f);

write_tb("(",tb);

switch ( OPNAME(f) ) {

case '+':

fnodetotex_tb((FNODE)BDY(args),tb);

for ( args = NEXT(args); args; args = NEXT(args) ) {

write_tb("+",tb);

fnodetotex_tb((FNODE)BDY(args),tb);

}

break;

case '*':

f1 = (FNODE)BDY(args);

if ( f1->id == I_FORMULA && MUNIQ(FA0(f1)) )

write_tb("-",tb);

else

fnodetotex_tb(f1,tb);

write_tb(" ",tb);

for ( args = NEXT(args); args; args = NEXT(args) ) {

/* XXX special care for DP */

f2 = (FNODE)BDY(args);

if ( f2->id == I_EV ) {

n = (NODE)FA0(f2);

for ( i = 0; n; n = NEXT(n), i++ ) {

fi = (FNODE)BDY(n);

if ( fi->id != I_FORMULA || FA0(fi) )

break;

}

if ( n )

fnodetotex_tb(f2,tb);

} else

fnodetotex_tb(f2,tb);

}

break;

default:

error("invalid nary op");

break;

}

write_tb(")",tb);

break;

case I_COP:

switch( (cid)FA0(f) ) {

Line 1748 int top_is_minus(FNODE f)

Line 1841 int top_is_minus(FNODE f)

return opname[0]=='-';

}

case I_NARYOP:

return top_is_minus((FNODE)BDY((NODE)FA1(f)));

default:

return 0;

}

Line 1942 void Pquote_normalize(NODE arg,QUOTE *rp)

Line 2038 void Pquote_normalize(NODE arg,QUOTE *rp)

if ( !q || OID(q) != O_QUOTE ) {

*rp = q;

return;

} else {

} else if ( q->normalized && (q->expanded || !expand) )

*rp = q;

else {

f = fnode_normalize(BDY(q),expand);

MKQUOTE(r,f);

r->normalized = 1;

if ( expand ) r->expanded = 1;

*rp = r;

}

void Pquote_normalize_comp(NODE arg,Q *rp)

void Pnquote_comp(NODE arg,Q *rp)

{

QUOTE q1,q2;

FNODE f1,f2;

int r;

f1 = BDY((QUOTE)ARG0(arg));

q1 = (QUOTE)ARG0(arg); f1 = (FNODE)BDY(q1);

f2 = BDY((QUOTE)ARG1(arg));

q2 = (QUOTE)ARG1(arg); f2 = (FNODE)BDY(q2);

f1 = fnode_normalize(f1,0);

if ( !q1->normalized ) f1 = fnode_normalize(f1,0);

f2 = fnode_normalize(f2,0);

if ( !q2->normalized ) f2 = fnode_normalize(f2,0);

r = fnode_normalize_comp(f1,f2);

r = nfnode_comp(f1,f2);

STOQ(r,*rp);

}

int fnode_is_number(FNODE f)

INLINE int fnode_is_number(FNODE f)

{

Obj obj;

Line 2106 int fnode_is_dependent(FNODE f,V v)

Line 2207 int fnode_is_dependent(FNODE f,V v)

}

FNODE fnode_normalize_add(FNODE a1,FNODE a2,int expand);

FNODE nfnode_add(FNODE a1,FNODE a2,int expand);

FNODE fnode_normalize_mul(FNODE a1,FNODE a2,int expand);

FNODE nfnode_mul(FNODE a1,FNODE a2,int expand);

FNODE fnode_normalize_pwr(FNODE a1,FNODE a2,int expand);

FNODE nfnode_pwr(FNODE a1,FNODE a2,int expand);

FNODE fnode_normalize_mul_coef(Num c,FNODE f,int expand);

FNODE nfnode_mul_coef(Num c,FNODE f,int expand);

FNODE fnode_expand_pwr(FNODE f,int n);

FNODE to_narymul(FNODE f);

FNODE to_naryadd(FNODE f);

Line 2125 FNODE fnode_normalize(FNODE f,int expand)

Line 2226 FNODE fnode_normalize(FNODE f,int expand)

NODE n;

Q q;

if ( f->normalized && (f->expanded || !expand) ) return f;

STOQ(-1,q);

mone = mkfnode(1,I_FORMULA,q);

switch ( f->id ) {

case I_PAREN:

return fnode_normalize(FA0(f),expand);

r = fnode_normalize(FA0(f),expand);

break;

case I_MINUS:

return fnode_normalize_mul_coef((Num)q,

r = nfnode_mul_coef((Num)q,

fnode_normalize(FA0(f),expand),expand);

break;

case I_BOP:

/* arf fnode fnode */

Line 2141 FNODE fnode_normalize(FNODE f,int expand)

Line 2245 FNODE fnode_normalize(FNODE f,int expand)

a2 = fnode_normalize(FA2(f),expand);

switch ( OPNAME(f) ) {

case '+':

return fnode_normalize_add(a1,a2,expand);

r = nfnode_add(a1,a2,expand);

break;

case '-':

a2 = fnode_normalize_mul_coef((Num)q,a2,expand);

a2 = nfnode_mul_coef((Num)q,a2,expand);

return fnode_normalize_add(a1,a2,expand);

r = nfnode_add(a1,a2,expand);

break;

case '*':

return fnode_normalize_mul(a1,a2,expand);

r = nfnode_mul(a1,a2,expand);

break;

case '/':

a2 = fnode_normalize_pwr(a2,mone,expand);

a2 = nfnode_pwr(a2,mone,expand);

return fnode_normalize_mul(a1,a2,expand);

r = nfnode_mul(a1,a2,expand);

break;

case '^':

return fnode_normalize_pwr(a1,a2,expand);

r = nfnode_pwr(a1,a2,expand);

break;

default:

return mkfnode(3,I_BOP,FA0(f),a1,a2);

r = mkfnode(3,I_BOP,FA0(f),a1,a2);

break;

}

break;

Line 2164 FNODE fnode_normalize(FNODE f,int expand)

Line 2274 FNODE fnode_normalize(FNODE f,int expand)

r = fnode_normalize(BDY(n),expand); n = NEXT(n);

for ( ; n; n = NEXT(n) ) {

a1 = fnode_normalize(BDY(n),expand);

r = fnode_normalize_add(r,a1,expand);

r = nfnode_add(r,a1,expand);

}

return r;

break;

case '*':

n = (NODE)FA1(f);

r = fnode_normalize(BDY(n),expand); n = NEXT(n);

for ( ; n; n = NEXT(n) ) {

a1 = fnode_normalize(BDY(n),expand);

r = fnode_normalize_mul(r,a1,expand);

r = nfnode_mul(r,a1,expand);

}

return r;

break;

default:

error("fnode_normallize : cannot happen");

}

break;

default:

return fnode_apply(f,fnode_normalize,expand);

}

r->normalized = 1;

r->expanded = expand;

return r;

}

FNODE fnode_apply(FNODE f,FNODE (*func)(),int expand)

Line 2216 FNODE fnode_apply(FNODE f,FNODE (*func)(),int expand)

Line 2330 FNODE fnode_apply(FNODE f,FNODE (*func)(),int expand)

return r;

}

FNODE fnode_normalize_add(FNODE f1,FNODE f2,int expand)

FNODE nfnode_add(FNODE f1,FNODE f2,int expand)

{

NODE n1,n2,r0,r;

FNODE b1,b2;

Line 2230 FNODE fnode_normalize_add(FNODE f1,FNODE f2,int expand

Line 2344 FNODE fnode_normalize_add(FNODE f1,FNODE f2,int expand

r0 = 0;

while ( n1 && n2 ) {

fnode_coef_body(BDY(n1),&c1,&b1); fnode_coef_body(BDY(n2),&c2,&b2);

if ( (s = fnode_normalize_comp(b1,b2)) > 0 ) {

if ( (s = nfnode_comp(b1,b2)) > 0 ) {

NEXTNODE(r0,r); BDY(r) = BDY(n1); n1 = NEXT(n1);

} else if ( s < 0 ) {

NEXTNODE(r0,r); BDY(r) = BDY(n2); n2 = NEXT(n2);

} else {

addnum(0,c1,c2,&c);

if ( c ) {

NEXTNODE(r0,r); BDY(r) = fnode_normalize_mul_coef(c,b1,expand);

NEXTNODE(r0,r); BDY(r) = nfnode_mul_coef(c,b1,expand);

}

n1 = NEXT(n1); n2 = NEXT(n2);

}

Line 2268 FNODE fnode_node_to_narymul(NODE n)

Line 2382 FNODE fnode_node_to_narymul(NODE n)

else return mkfnode(2,I_NARYOP,mulfs,n);

}

FNODE fnode_normalize_mul(FNODE f1,FNODE f2,int expand)

FNODE nfnode_mul(FNODE f1,FNODE f2,int expand)

{

NODE n1,n2,r0,r,r1;

FNODE b1,b2,e1,e2,cc,t,t1;

Line 2279 FNODE fnode_normalize_mul(FNODE f1,FNODE f2,int expand

Line 2393 FNODE fnode_normalize_mul(FNODE f1,FNODE f2,int expand

if ( IS_ZERO(f1) || IS_ZERO(f2) ) return mkfnode(1,I_FORMULA,0);

else if ( fnode_is_number(f1) )

return fnode_normalize_mul_coef((Num)eval(f1),f2,expand);

return nfnode_mul_coef((Num)eval(f1),f2,expand);

else if ( fnode_is_number(f2) )

return fnode_normalize_mul_coef((Num)eval(f2),f1,expand);

return nfnode_mul_coef((Num)eval(f2),f1,expand);

if ( expand && IS_NARYADD(f1) ) {

t = mkfnode(1,I_FORMULA,0);

for ( n1 = (NODE)FA1(f1); n1; n1 = NEXT(n1) ) {

t1 = fnode_normalize_mul(BDY(n1),f2,expand);

t1 = nfnode_mul(BDY(n1),f2,expand);

t = fnode_normalize_add(t,t1,expand);

t = nfnode_add(t,t1,expand);

}

return t;

}

if ( expand && IS_NARYADD(f2) ) {

t = mkfnode(1,I_FORMULA,0);

for ( n2 = (NODE)FA1(f2); n2; n2 = NEXT(n2) ) {

t1 = fnode_normalize_mul(f1,BDY(n2),expand);

t1 = nfnode_mul(f1,BDY(n2),expand);

t = fnode_normalize_add(t,t1,expand);

t = nfnode_add(t,t1,expand);

}

return t;

}

Line 2332 FNODE fnode_normalize_mul(FNODE f1,FNODE f2,int expand

Line 2446 FNODE fnode_normalize_mul(FNODE f1,FNODE f2,int expand

return fnode_node_to_narymul(r);

}

FNODE fnode_normalize_pwr(FNODE f1,FNODE f2,int expand)

FNODE nfnode_pwr(FNODE f1,FNODE f2,int expand)

{

FNODE b,b1,e1,e,cc,r;

FNODE b,b1,e1,e,cc,r,mf2,mone,inv;

Num c,c1;

Num c,c1,nf2;

NODE arg,n;

int ee;

NODE arg,n,t0,t1;

Q q;

if ( IS_ZERO(f2) ) return mkfnode(1,I_FORMULA,ONE);

else if ( IS_ZERO(f1) ) return mkfnode(1,I_FORMULA,0);

else if ( fnode_is_one(f2) ) return f1;

else if ( fnode_is_number(f1) ) {

else if ( fnode_is_number(f1) )

if ( fnode_is_integer(f2) ) {

pwrnum(0,(Num)eval(f1),(Num)eval(f2),&c);

if ( fnode_is_one(f2) ) return f1;

return mkfnode(1,I_FORMULA,c);

else {

pwrnum(0,(Num)eval(f1),(Num)eval(f2),&c);

return mkfnode(1,I_FORMULA,c);

}

} else

return mkfnode(3,I_BOP,pwrfs,f1,f2);

else if ( IS_BINARYPWR(f1) ) {

} else if ( IS_BINARYPWR(f1) ) {

b1 = FA1(f1); e1 = FA2(f1);

e = fnode_normalize_mul(e1,f2,expand);

e = nfnode_mul(e1,f2,expand);

if ( fnode_is_one(e) )

return b1;

else

return mkfnode(3,I_BOP,FA0(f1),b1,e);

} else if ( IS_NARYMUL(f1) && fnode_is_integer(f2) ) {

} else if ( expand && IS_NARYMUL(f1) && fnode_is_number(f2)

&& fnode_is_integer(f2) ) {

fnode_coef_body(f1,&c1,&b1);

pwrnum(0,(Num)c1,(Num)eval(f2),&c);

nf2 = (Num)eval(f2);

pwrnum(0,(Num)c1,nf2,&c);

ee = QTOS((Q)nf2);

cc = mkfnode(1,I_FORMULA,c);

b = fnode_normalize_pwr(b1,f2,expand);

if ( fnode_is_nonnegative_integer(f2) )

b = fnode_expand_pwr(b1,ee);

else {

STOQ(-1,q);

mone = mkfnode(1,I_FORMULA,q);

b1 = to_narymul(b1);

for ( t0 = 0, n = (NODE)FA1(b1); n; n = NEXT(n) ) {

inv = mkfnode(3,I_BOP,pwrfs,BDY(n),mone);

MKNODE(t1,inv,t0); t0 = t1;

}

b1 = fnode_node_to_narymul(t0);

b = fnode_expand_pwr(b1,-ee);

}

if ( fnode_is_one(cc) )

return b;

else

Line 2367 FNODE fnode_normalize_pwr(FNODE f1,FNODE f2,int expand

Line 2499 FNODE fnode_normalize_pwr(FNODE f1,FNODE f2,int expand

} else if ( expand && fnode_is_integer(f2)

&& fnode_is_nonnegative_integer(f2) ) {

q = (Q)eval(f2);

if ( PL(NM(q)) > 1 ) error("fnode_normalize_pwr : exponent too large");

if ( PL(NM(q)) > 1 ) error("nfnode_pwr : exponent too large");

return fnode_expand_pwr(f1,QTOS(q));

} else

return mkfnode(3,I_BOP,pwrfs,f1,f2);

Line 2384 FNODE fnode_expand_pwr(FNODE f,int n)

Line 2516 FNODE fnode_expand_pwr(FNODE f,int n)

else {

n1 = n/2;

f1 = fnode_expand_pwr(f,n1);

f2 = fnode_normalize_mul(f1,f1,1);

f2 = nfnode_mul(f1,f1,1);

if ( n%2 ) f2 = fnode_normalize_mul(f2,f,1);

if ( n%2 ) f2 = nfnode_mul(f2,f,1);

return f2;

}

Line 2424 FNODE to_narymul(FNODE f)

Line 2556 FNODE to_narymul(FNODE f)

return r;

}

FNODE fnode_normalize_mul_coef(Num c,FNODE f,int expand)

FNODE nfnode_mul_coef(Num c,FNODE f,int expand)

{

FNODE b1,cc;

Num c1,c2;

Line 2440 FNODE fnode_normalize_mul_coef(Num c,FNODE f,int expan

Line 2572 FNODE fnode_normalize_mul_coef(Num c,FNODE f,int expan

cc = mkfnode(1,I_FORMULA,c2);

if ( fnode_is_number(b1) ) {

if ( !fnode_is_one(b1) )

error("fnode_normalize_mul_coef : cannot happen");

error("nfnode_mul_coef : cannot happen");

else

return cc;

} else if ( IS_NARYMUL(b1) ) {

Line 2449 FNODE fnode_normalize_mul_coef(Num c,FNODE f,int expan

Line 2581 FNODE fnode_normalize_mul_coef(Num c,FNODE f,int expan

} else if ( expand && IS_NARYADD(b1) ) {

for ( r0 = 0, n = (NODE)FA1(b1); n; n = NEXT(n) ) {

NEXTNODE(r0,r);

BDY(r) = fnode_normalize_mul_coef(c2,BDY(n),expand);

BDY(r) = nfnode_mul_coef(c2,BDY(n),expand);

}

if ( r0 ) NEXT(r) = 0;

return fnode_node_to_naryadd(r0);

Line 2478 void fnode_coef_body(FNODE f,Num *cp,FNODE *bp)

Line 2610 void fnode_coef_body(FNODE f,Num *cp,FNODE *bp)

}

int fnode_normalize_comp_pwr(FNODE f1,FNODE f2);

int nfnode_comp_pwr(FNODE f1,FNODE f2);

int fnode_normalize_comp(FNODE f1,FNODE f2)

int nfnode_comp(FNODE f1,FNODE f2)

{

NODE n1,n2;

int r,i1,i2;

int r,i1,i2,ret;

char *nm1,*nm2;

FNODE b1,b2,e1,e2,g;

FNODE b1,b2,e1,e2,g,a1,a2,fn1,fn2;

Num ee,ee1;

Num ee,ee1,c1,c2;

if ( IS_ZERO(f1) )

if ( IS_ZERO(f2) ) return 0;

else return -1;

else if ( IS_ZERO(f2) ) return 1;

if ( IS_NARYADD(f1) || IS_NARYADD(f2) ) {

f1 = to_naryadd(f1); f2 = to_naryadd(f2);

n1 = (NODE)FA1(f1); n2 = (NODE)FA1(f2);

while ( n1 && n2 )

if ( r = fnode_normalize_comp(BDY(n1),BDY(n2)) ) return r;

if ( r = nfnode_comp(BDY(n1),BDY(n2)) ) return r;

else {

n1 = NEXT(n1); n2 = NEXT(n2);

}

if ( n1 ) return 1;

return n1?1:(n2?-1:0);

else if ( n2 ) return -1;

else return 0;

}

if ( IS_NARYMUL(f1) || IS_NARYMUL(f2) ) {

f1 = to_narymul(f1); f2 = to_narymul(f2);

fnode_coef_body(f1,&c1,&b1);

n1 = (NODE)FA1(f1); n2 = (NODE)FA1(f2);

fnode_coef_body(f2,&c2,&b2);

if ( !compfnode(b1,b2) ) return compnum(0,c1,c2);

b1 = to_narymul(b1); b2 = to_narymul(b2);

n1 = (NODE)FA1(b1); n2 = (NODE)FA1(b2);

while ( 1 ) {

while ( n1 && n2 && !compfnode(BDY(n1),BDY(n2)) ) {

n1 = NEXT(n1); n2 = NEXT(n2);

}

if ( !n1 || !n2 ) {

if ( n1 ) return 1;

return n1?1:(n2?-1:0);

else if ( n2 ) return -1;

else return 0;

}

fnode_base_exp(BDY(n1),&b1,&e1);

fnode_base_exp(BDY(n2),&b2,&e2);

n1 = NEXT(n1); n2 = NEXT(n2);

if ( r = fnode_normalize_comp(b1,b2) ) return r;

if ( r = nfnode_comp(b1,b2) ) {

else if ( fnode_is_number(e1) && fnode_is_number(e2) ) {

if ( r > 0 )

/* f1 = t b^e1 ... , f2 = t b^e2 ... */

return nfnode_comp(e1,mkfnode(1,I_FORMULA,0));

subnum(0,eval(e1),eval(e2),&ee);

else if ( r < 0 )

r = compnum(0,ee,0);

return nfnode_comp(mkfnode(1,I_FORMULA,0),e2);

if ( r > 0 ) {

/* e1>e2 */

g = mkfnode(3,I_BOP,pwrfs,b1,mkfnode(1,I_FORMULA,ee));

MKNODE(n1,g,n1);

} else if ( r < 0 ) {

/* e1<e2 */

chsgnnum(ee,&ee1); ee1 = ee;

g = mkfnode(3,I_BOP,pwrfs,b1,mkfnode(1,I_FORMULA,ee));

MKNODE(n2,g,n2);

}

} else {

r = fnode_normalize_comp(e1,e2);

n1 = NEXT(n1); n2 = NEXT(n2);

if ( r > 0 ) return 1;

if ( fnode_is_number(e1) && fnode_is_number(e2) ) {

else if ( r < 0 ) return -1;

/* f1 = t b^e1 ... , f2 = t b^e2 ... */

subnum(0,eval(e1),eval(e2),&ee);

r = compnum(0,ee,0);

if ( r > 0 ) {

g = mkfnode(3,I_BOP,pwrfs,b1,mkfnode(1,I_FORMULA,ee));

MKNODE(n1,g,n1);

} else if ( r < 0 ) {

chsgnnum(ee,&ee1);

g = mkfnode(3,I_BOP,pwrfs,b1,mkfnode(1,I_FORMULA,ee1));

MKNODE(n2,g,n2);

}

} else {

r = nfnode_comp(e1,e2);

if ( r > 0 ) return 1;

else if ( r < 0 ) return -1;

}

if ( IS_BINARYPWR(f1) || IS_BINARYPWR(f2) )

return fnode_normalize_comp_pwr(f1,f2);

return nfnode_comp_pwr(f1,f2);

/* now, IDs of f1 and f2 must be I_FORMULA, I_FUNC, or I_PVAR */

/* now, IDs of f1 and f2 must be I_FORMULA, I_FUNC, I_IFUNC or I_PVAR */

/* I_IFUNC > I_PVAR > I_FUNC > I_FORMULA */

switch ( f1->id ) {

case I_FORMULA:

switch ( f2->id ) {

case I_FORMULA:

return arf_comp(CO,FA0(f1),FA0(f2));

case I_FUNC: case I_PVAR:

case I_FUNC: case I_IFUNC: case I_PVAR:

return -1;

default:

error("fnode_normalize_comp : undefined");

error("nfnode_comp : undefined");

}

break;

case I_FUNC:

switch ( f2->id ) {

case I_FORMULA:

return 1;

case I_PVAR: case I_IFUNC:

return -1;

case I_FUNC:

nm1 = ((FUNC)FA0(f1))->name; nm2 = ((FUNC)FA0(f2))->name;

r = strcmp(nm1,nm2);

Line 2571 int fnode_normalize_comp(FNODE f1,FNODE f2)

Line 2704 int fnode_normalize_comp(FNODE f1,FNODE f2)

/* compare args */

n1 = FA0((FNODE)FA1(f1)); n2 = FA0((FNODE)FA1(f2));

while ( n1 && n2 )

if ( r = fnode_normalize_comp(BDY(n1),BDY(n2)) ) return r;

if ( r = nfnode_comp(BDY(n1),BDY(n2)) ) return r;

else {

n1 = NEXT(n1); n2 = NEXT(n2);

}

if ( n1 ) return 1;

return n1?1:(n2?-1:0);

else if ( n2 ) return -1;

else return 0;

}

break;

case I_PVAR:

return -1;

default:

error("fnode_normalize_comp : undefined");

error("nfnode_comp : undefined");

}

case I_PVAR:

switch ( f2->id ) {

case I_FORMULA: case I_FUNC:

return 1;

case I_IFUNC:

return -1;

case I_PVAR:

i1 = (int)FA0(f1); i2 = (int)FA0(f2);

if ( i1 > i2 ) return 1;

else if ( i1 < i2 ) return -1;

else return 0;

default:

error("fnode_normalize_comp : undefined");

error("nfnode_comp : undefined");

}

break;

case I_IFUNC:

switch ( f2->id ) {

case I_FORMULA: case I_FUNC: case I_PVAR:

return 1;

case I_IFUNC:

i1 = (int)FA0((FNODE)FA0(f1));

i2 = (int)FA0((FNODE)FA0(f2));

if ( i1 > i2 ) return 1;

else if ( i1 < i2 ) return -1;

else {

/* compare args */

n1 = FA0((FNODE)FA1(f1)); n2 = FA0((FNODE)FA1(f2));

while ( n1 && n2 )

if ( r = nfnode_comp(BDY(n1),BDY(n2)) ) return r;

else {

n1 = NEXT(n1); n2 = NEXT(n2);

}

return n1?1:(n2?-1:0);

}

break;

default:

error("nfnode_comp : undefined");

}

break;

default:

error("fnode_normalize_comp : undefined");

error("nfnode_comp : undefined");

}

int fnode_normalize_comp_pwr(FNODE f1,FNODE f2)

int nfnode_comp_pwr(FNODE f1,FNODE f2)

{

FNODE b1,b2,e1,e2;

int r;

fnode_base_exp(f1,&b1,&e1);

fnode_base_exp(f2,&b2,&e2);

if ( r = fnode_normalize_comp(b1,b2) ) return r;

if ( r = nfnode_comp(b1,b2) ) {

else return fnode_normalize_comp(e1,e2);

if ( r > 0 )

return nfnode_comp(e1,mkfnode(1,I_FORMULA,0));

else if ( r < 0 )

return nfnode_comp(mkfnode(1,I_FORMULA,0),e2);

} else return nfnode_comp(e1,e2);

}

NODE append_node(NODE a1,NODE a2)

{

NODE t,t0;

if ( !a1 )

return a2;

else {

for ( t0 = 0; a1; a1 = NEXT(a1) ) {

NEXTNODE(t0,t); BDY(t) = BDY(a1);

}

NEXT(t) = a2;

return t0;

}

int nfnode_match(FNODE f,FNODE pat,NODE *rp)

{

NODE m,m1,m2,base,exp,fa,pa,n;

LIST l;

QUOTE qp,qf;

FNODE fbase,fexp,a,fh;

FUNC ff,pf;

int r;

switch ( pat->id ) {

case I_PVAR:

/* [[pat,f]] */

*rp = mknode(1,mknode(2,(int)FA0(pat),f),0);

return 1;

case I_FORMULA:

if ( f->id == I_FORMULA && !arf_comp(CO,(Obj)FA0(f),(Obj)FA0(pat)) ) {

*rp = 0; return 1;

} else

return 0;

case I_BOP:

/* OPNAME should be "^" */

if ( !IS_BINARYPWR(pat) )

error("nfnode_match : invalid BOP");

if ( IS_BINARYPWR(f) ) {

fbase = FA1(f); fexp = FA2(f);

} else {

fbase = f; fexp = mkfnode(1,I_FORMULA,ONE);

}

if ( !nfnode_match(fbase,FA1(pat),&base) ) return 0;

a = rewrite_fnode(FA2(pat),base);

if ( !nfnode_match(fexp,a,&exp) ) return 0;

else {

*rp = append_node(base,exp);

return 1;

}

break;

case I_FUNC: case I_IFUNC:

if ( f->id != I_FUNC ) return 0;

ff = (FUNC)FA0(f);

if ( pat->id == I_FUNC ) {

pf = (FUNC)FA0(pat);

if ( strcmp(ff->fullname,pf->fullname) ) return 0;

m = 0;

} else {

/* XXX : I_FUNC_HEAD is a dummy id to pass FUNC */

fh = mkfnode(1,I_FUNC_HEAD,FA0(f));

m = mknode(1,mknode(2,FA0((FNODE)FA0(pat)),fh),0);

}

/* FA1(f) and FA1(pat) are I_LIST */

fa = (NODE)FA0((FNODE)FA1(f));

pa = (NODE)FA0((FNODE)FA1(pat));

while ( fa && pa ) {

a = rewrite_fnode(BDY(pa),m);

if ( !nfnode_match(BDY(fa),a,&m1) ) return 0;

m = append_node(m1,m);

fa = NEXT(fa); pa = NEXT(pa);

}

if ( fa || pa ) return 0;

else {

*rp = m;

return 1;

}

case I_NARYOP:

if ( IS_NARYADD(pat) )

return nfnode_match_naryadd(f,pat,rp);

else if ( IS_NARYMUL(pat) )

return nfnode_match_narymul(f,pat,rp);

else

error("nfnode_match : invalid NARYOP");

break;

default:

error("nfnode_match : invalid pattern");

}

/* remove i-th element */

FNODE fnode_removeith_naryadd(FNODE p,int i)

{

int k,l;

NODE t,r0,r,a;

a = (NODE)FA1(p);

l = length(a);

if ( i < 0 || i >= l ) error("fnode_removeith_naryadd: invalid index");

else if ( i == 0 )

return fnode_node_to_naryadd(NEXT(a));

else {

for ( r0 = 0, k = 0, t = a; k < i; k++, t = NEXT(t) ) {

NEXTNODE(r0,r);

BDY(r) = BDY(t);

}

NEXT(r) = NEXT(t);

return fnode_node_to_naryadd(r0);

}

/* a0,...,a(i-1) */

FNODE fnode_left_narymul(FNODE p,int i)

{

int k,l;

NODE t,r0,r,a;

a = (NODE)FA1(p);

l = length(a);

if ( i < 0 || i >= l ) error("fnode_left_narymul : invalid index");

if ( i == 0 ) return mkfnode(1,I_FORMULA,ONE);

else if ( i == 1 ) return (FNODE)BDY(a);

else {

for ( r0 = 0, k = 0, t = a; k < i; k++, t = NEXT(t) ) {

NEXTNODE(r0,r);

BDY(r) = BDY(t);

}

NEXT(r) = 0;

return fnode_node_to_narymul(r0);

}

/* a(i+1),...,a(l-1) */

FNODE fnode_right_narymul(FNODE p,int i)

{

NODE a,t;

int l,k;

a = (NODE)FA1(p);

l = length(a);

if ( i < 0 || i >= l ) error("fnode_right_narymul : invalid index");

if ( i == l-1 ) return mkfnode(1,I_FORMULA,ONE);

else {

for ( k = 0, t = a; k <= i; k++, t = NEXT(t) );

return fnode_node_to_narymul(t);

}

int nfnode_match_naryadd(FNODE f,FNODE p,NODE *rp)

{

int fl,pl,fi,pi;

NODE fa,pa,t,s,m,m1;

FNODE fr,pr,prr,pivot;

f = to_naryadd(f);

fa = (NODE)FA1(f); fl = length(fa);

pa = (NODE)FA1(p); pl = length(pa);

if ( fl < pl ) return 0;

else if ( pl == 1 ) {

if ( fl == 1 )

return nfnode_match(BDY(fa),BDY(pa),rp);

else

return 0;

} else {

for ( t = pa, pi = 0; t; t = NEXT(t), pi++ )

if ( ((FNODE)BDY(t))->id != I_PVAR ) break;

if ( !t ) {

/* all are I_PVAR */

m = 0;

for ( t = pa, s = fa; NEXT(t); t = NEXT(t), s = NEXT(s) ) {

nfnode_match(BDY(s),BDY(t),&m1);

m = append_node(m1,m);

}

if ( !NEXT(s) )

fr = (FNODE)BDY(s);

else

fr = mkfnode(2,I_NARYOP,FA0(f),s);

nfnode_match(fr,BDY(t),&m1);

*rp = append_node(m1,m);

return 1;

} else {

pivot = (FNODE)BDY(t);

pr = fnode_removeith_naryadd(p,pi);

for ( s = fa, fi = 0; s; s = NEXT(s), fi++ ) {

if ( nfnode_match(BDY(s),pivot,&m) ) {

fr = fnode_removeith_naryadd(f,fi);

prr = rewrite_fnode(pr,m);

if ( nfnode_match(fr,prr,&m1) ) {

*rp = append_node(m,m1);

return 1;

}

return 0;

}

int nfnode_match_narymul(FNODE f,FNODE p,NODE *rp)

{

int fl,pl,fi,pi;

NODE fa,pa,t,s,m,m1;

FNODE fr,pr,pleft,pleft1,pright,pright1,fleft,fright,pivot;

f = to_narymul(f);

fa = (NODE)FA1(f); fl = length(fa);

pa = (NODE)FA1(p); pl = length(pa);

if ( fl < pl ) return 0;

else if ( pl == 1 ) {

if ( fl == 1 )

return nfnode_match(BDY(fa),BDY(pa),rp);

else

return 0;

} else {

for ( t = pa, pi = 0; t; t = NEXT(t), pi++ )

if ( ((FNODE)BDY(t))->id != I_PVAR ) break;

if ( !t ) {

/* all are I_PVAR */

m = 0;

for ( t = pa, s = fa; NEXT(t); t = NEXT(t), s = NEXT(s) ) {

pr = rewrite_fnode(BDY(t),m);

if ( !nfnode_match(BDY(s),pr,&m1) ) return 0;

m = append_node(m1,m);

}

if ( !NEXT(s) )

fr = (FNODE)BDY(s);

else

fr = mkfnode(2,I_NARYOP,FA0(f),s);

pr = rewrite_fnode(BDY(t),m);

if ( !nfnode_match(fr,pr,&m1) ) return 0;

*rp = append_node(m1,m);

return 1;

} else {

pivot = (FNODE)BDY(t);

pleft = fnode_left_narymul(p,pi);

pright = fnode_right_narymul(p,pi);

/* XXX : incomplete */

for ( s = fa, fi = 0; s; s = NEXT(s), fi++ ) {

if ( nfnode_match(BDY(s),pivot,&m) ) {

fleft = fnode_left_narymul(f,fi);

pleft1 = rewrite_fnode(pleft,m);

if ( nfnode_match(fleft,pleft1,&m1) ) {

m = append_node(m1,m);

fright = fnode_right_narymul(f,fi);

pright1 = rewrite_fnode(pright,m);

if ( nfnode_match(fright,pright1,&m1) ) {

*rp = append_node(m1,m);

return 1;

}

return 0;

}

NODE nfnode_pvars(FNODE pat,NODE found)

{

int ind;

NODE prev,t;

int *pair;

switch ( pat->id ) {

case I_PVAR:

ind = (int)FA0(pat);

for ( prev = 0, t = found; t; prev = t, t = NEXT(t) ) {

pair = (int *)BDY(t);

if ( pair[0] == ind ) {

pair[1]++;

return found;

}

pair = (int *)MALLOC_ATOMIC(sizeof(int)*2);

pair[0] = ind; pair[1] = 1;

if ( !prev )

MKNODE(found,pair,0);

else

MKNODE(NEXT(prev),pair,0);

return found;

case I_FORMULA:

return found;

case I_BOP:

/* OPNAME should be "^" */

if ( !IS_BINARYPWR(pat) )

error("nfnode_pvar : invalid BOP");

found = nfnode_pvars(FA1(pat),found);

found = nfnode_pvars(FA2(pat),found);

return found;

case I_FUNC:

t = (NODE)FA0((FNODE)FA1(pat));

for ( ; t; t = NEXT(t) )

found = nfnode_pvars(BDY(t),found);

return found;

case I_NARYOP:

t = (NODE)FA1(pat);

for ( ; t; t = NEXT(t) )

found = nfnode_pvars(BDY(t),found);

return found;

default:

error("nfnode_match : invalid pattern");

}

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