File: [local] / OpenXM_contrib2 / asir2000 / builtin / strobj.c (download)
Revision 1.119, Thu Sep 4 01:42:25 2008 UTC (16 years ago) by noro
Branch: MAIN
CVS Tags: R_1_3_1-2, RELEASE_1_2_3_12 Changes since 1.118: +9 -3
lines
eval_str(S) now accepts any single statement S. If one wants to
execute multiple statements, then they should be passwd as a block.
If S is a block, then the returned value is the value of the last
statemant in the block.
|
/*
* Copyright (c) 1994-2000 FUJITSU LABORATORIES LIMITED
* All rights reserved.
*
* FUJITSU LABORATORIES LIMITED ("FLL") hereby grants you a limited,
* non-exclusive and royalty-free license to use, copy, modify and
* redistribute, solely for non-commercial and non-profit purposes, the
* computer program, "Risa/Asir" ("SOFTWARE"), subject to the terms and
* conditions of this Agreement. For the avoidance of doubt, you acquire
* only a limited right to use the SOFTWARE hereunder, and FLL or any
* third party developer retains all rights, including but not limited to
* copyrights, in and to the SOFTWARE.
*
* (1) FLL does not grant you a license in any way for commercial
* purposes. You may use the SOFTWARE only for non-commercial and
* non-profit purposes only, such as academic, research and internal
* business use.
* (2) The SOFTWARE is protected by the Copyright Law of Japan and
* international copyright treaties. If you make copies of the SOFTWARE,
* with or without modification, as permitted hereunder, you shall affix
* to all such copies of the SOFTWARE the above copyright notice.
* (3) An explicit reference to this SOFTWARE and its copyright owner
* shall be made on your publication or presentation in any form of the
* results obtained by use of the SOFTWARE.
* (4) In the event that you modify the SOFTWARE, you shall notify FLL by
* e-mail at risa-admin@sec.flab.fujitsu.co.jp of the detailed specification
* for such modification or the source code of the modified part of the
* SOFTWARE.
*
* THE SOFTWARE IS PROVIDED AS IS WITHOUT ANY WARRANTY OF ANY KIND. FLL
* MAKES ABSOLUTELY NO WARRANTIES, EXPRESSED, IMPLIED OR STATUTORY, AND
* EXPRESSLY DISCLAIMS ANY IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS
* FOR A PARTICULAR PURPOSE OR NONINFRINGEMENT OF THIRD PARTIES'
* RIGHTS. NO FLL DEALER, AGENT, EMPLOYEES IS AUTHORIZED TO MAKE ANY
* MODIFICATIONS, EXTENSIONS, OR ADDITIONS TO THIS WARRANTY.
* UNDER NO CIRCUMSTANCES AND UNDER NO LEGAL THEORY, TORT, CONTRACT,
* OR OTHERWISE, SHALL FLL BE LIABLE TO YOU OR ANY OTHER PERSON FOR ANY
* DIRECT, INDIRECT, SPECIAL, INCIDENTAL, PUNITIVE OR CONSEQUENTIAL
* DAMAGES OF ANY CHARACTER, INCLUDING, WITHOUT LIMITATION, DAMAGES
* ARISING OUT OF OR RELATING TO THE SOFTWARE OR THIS AGREEMENT, DAMAGES
* FOR LOSS OF GOODWILL, WORK STOPPAGE, OR LOSS OF DATA, OR FOR ANY
* DAMAGES, EVEN IF FLL SHALL HAVE BEEN INFORMED OF THE POSSIBILITY OF
* SUCH DAMAGES, OR FOR ANY CLAIM BY ANY OTHER PARTY. EVEN IF A PART
* OF THE SOFTWARE HAS BEEN DEVELOPED BY A THIRD PARTY, THE THIRD PARTY
* 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 1.119 2008/09/04 01:42:25 noro Exp $
*/
#include "ca.h"
#include "parse.h"
#include "ctype.h"
#if defined(PARI)
#include "genpari.h"
# if !(PARI_VERSION_CODE > 131588)
extern jmp_buf environnement;
# endif
#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;
};
#define OPNAME(f) (((ARF)FA0(f))->name[0])
#define IS_ZERO(f) (((f)->id==I_FORMULA) && FA0(f)==0 )
#define IS_BINARYPWR(f) (((f)->id==I_BOP) &&(OPNAME(f)=='^'))
#define IS_NARYADD(f) (((f)->id==I_NARYOP) &&(OPNAME(f)=='+'))
#define IS_NARYMUL(f) (((f)->id==I_NARYOP) &&(OPNAME(f)=='*'))
#define IS_MUL(f) (((f)->id==I_NARYOP||(f)->id==I_BOP) &&(OPNAME(f)=='*'))
extern char *parse_strp;
void Psprintf();
void Prtostr(), Pstrtov(), Peval_str();
void Pstrtoascii(), Pasciitostr();
void Pstr_len(), Pstr_chr(), Psub_str();
void Pwrite_to_tb();
void Ptb_to_string();
void Pclear_tb();
void Pstring_to_tb();
void Pquotetotex_tb();
void Pquotetotex();
void Pquotetotex_env();
void Pflatten_quote();
void Pqt_is_integer(),Pqt_is_rational(),Pqt_is_number(),Pqt_is_coef();
void Pqt_is_dependent(),Pqt_is_function(),Pqt_is_var();
void Pqt_set_ord(),Pqt_set_coef(),Pqt_set_weight();
void Pqt_normalize();
void Pnqt_comp(),Pnqt_weight();
void Pnqt_match();
void Pnqt_match_rewrite();
void Pqt_to_nbp();
void Pshuffle_mul(), Pharmonic_mul();
void Pnbp_hm(), Pnbp_ht(), Pnbp_hc(), Pnbp_rest();
void Pnbp_tm(), Pnbp_tt(), Pnbp_tc(), Pnbp_trest();
void Pnbm_deg(), Pnbm_index();
void Pnbm_hp_rest();
void Pnbm_hxky(), Pnbm_xky_rest();
void Pnbm_hv(), Pnbm_tv(), Pnbm_rest(),Pnbm_trest();
void Pquote_to_funargs(),Pfunargs_to_quote(),Pget_function_name();
void Pqt_match(),Pget_quote_id();
void Pqt_to_nary(),Pqt_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);
char *conv_rule(char *name);
char *conv_subs(char *name);
char *call_convfunc(char *name);
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 qt_match(Obj f,Obj pat,NODE *rp);
FNODE partial_eval(FNODE), fnode_to_nary(FNODE), fnode_to_bin(FNODE,int);
FNODE nfnode_add(FNODE a1,FNODE a2,int expand);
FNODE nfnode_mul(FNODE a1,FNODE a2,int expand);
FNODE nfnode_pwr(FNODE a1,FNODE a2,int expand);
FNODE nfnode_mul_coef(Obj c,FNODE f,int expand);
FNODE fnode_expand_pwr(FNODE f,int n,int expand);
FNODE to_narymul(FNODE f);
FNODE to_naryadd(FNODE f);
FNODE fnode_node_to_nary(ARF op,NODE n);
void fnode_base_exp(FNODE f,FNODE *bp,FNODE *ep);
void fnode_coef_body(FNODE f,Obj *cp,FNODE *bp);
FNODE nfnode_match_rewrite(FNODE f,FNODE p,FNODE c,FNODE a,int mode);
FNODE fnode_apply(FNODE f,FNODE (*func)(),int expand);
FNODE fnode_normalize(FNODE f,int expand);
FNODE rewrite_fnode(FNODE f,NODE arg,int qarg);
struct ftab str_tab[] = {
{"sprintf",Psprintf,-99999999},
{"rtostr",Prtostr,1},
{"strtov",Pstrtov,1},
{"eval_str",Peval_str,1},
{"strtoascii",Pstrtoascii,1},
{"asciitostr",Pasciitostr,1},
{"str_len",Pstr_len,1},
{"str_chr",Pstr_chr,3},
{"sub_str",Psub_str,3},
{"write_to_tb",Pwrite_to_tb,2},
{"clear_tb",Pclear_tb,1},
{"tb_to_string",Ptb_to_string,1},
{"string_to_tb",Pstring_to_tb,1},
{"get_quote_id",Pget_quote_id,1},
{"qt_is_var",Pqt_is_var,1},
{"qt_is_coef",Pqt_is_coef,1},
{"qt_is_number",Pqt_is_number,1},
{"qt_is_rational",Pqt_is_rational,1},
{"qt_is_integer",Pqt_is_integer,1},
{"qt_is_function",Pqt_is_function,1},
{"qt_is_dependent",Pqt_is_dependent,2},
{"qt_set_coef",Pqt_set_coef,-1},
{"qt_set_ord",Pqt_set_ord,-1},
{"qt_set_weight",Pqt_set_weight,-1},
{"qt_normalize",Pqt_normalize,-2},
{"qt_match",Pqt_match,2},
{"nqt_match_rewrite",Pnqt_match_rewrite,3},
{"nqt_weight",Pnqt_weight,1},
{"nqt_comp",Pnqt_comp,2},
{"nqt_match",Pnqt_match,-3},
{"qt_to_nbp",Pqt_to_nbp,1},
{"shuffle_mul",Pshuffle_mul,2},
{"harmonic_mul",Pharmonic_mul,2},
{"nbp_hm", Pnbp_hm,1},
{"nbp_ht", Pnbp_ht,1},
{"nbp_hc", Pnbp_hc,1},
{"nbp_rest", Pnbp_rest,1},
{"nbp_tm", Pnbp_tm,1},
{"nbp_tt", Pnbp_tt,1},
{"nbp_tc", Pnbp_tc,1},
{"nbp_trest", Pnbp_trest,1},
{"nbm_deg", Pnbm_deg,1},
{"nbm_index", Pnbm_index,1},
{"nbm_hxky", Pnbm_hxky,1},
{"nbm_xky_rest", Pnbm_xky_rest,1},
{"nbm_hp_rest", Pnbm_hp_rest,1},
{"nbm_hv", Pnbm_hv,1},
{"nbm_tv", Pnbm_tv,1},
{"nbm_rest", Pnbm_rest,1},
{"nbm_trest", Pnbm_trest,1},
{"qt_to_nary",Pqt_to_nary,1},
{"qt_to_bin",Pqt_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},
{"funargs_to_quote",Pfunargs_to_quote,1},
{"get_function_name",Pget_function_name,1},
{0,0,0},
};
void write_tb(char *s,TB tb)
{
if ( tb->next == tb->size ) {
tb->size *= 2;
tb->body = (char **)REALLOC(tb->body,tb->size*sizeof(char *));
}
tb->body[tb->next] = s;
tb->next++;
}
int register_symbol_table(Obj arg);
int register_conv_rule(Obj arg);
int register_conv_func(Obj arg);
int register_dp_vars(Obj arg);
int register_dp_vars_origin(Obj arg);
int register_dp_dvars_origin(Obj arg);
int register_dp_dvars_prefix(Obj arg);
int register_dp_vars_prefix(Obj arg);
int register_dp_vars_hweyl(Obj arg);
int register_show_lt(Obj arg);
char *objtostr(Obj obj);
static struct TeXSymbol *user_texsymbol;
static char **dp_vars;
static int dp_vars_len;
static char *dp_vars_prefix;
static char *dp_dvars_prefix;
static int dp_vars_origin;
static int dp_dvars_origin;
static int show_lt;
static FUNC convfunc;
static int is_lt;
static int conv_flag;
static int dp_vars_hweyl;
#define CONV_TABLE (1U<<0)
#define CONV_SUBS (1U<<1)
#define CONV_DMODE (1U<<2)
static struct {
char *name;
Obj value;
int (*reg)();
} qtot_env[] = {
{"symbol_table",0,register_symbol_table},
{"conv_rule",0,register_conv_rule},
{"conv_func",0,register_conv_func},
{"dp_vars",0,register_dp_vars},
{"dp_vars_prefix",0,register_dp_vars_prefix},
{"dp_dvars_prefix",0,register_dp_dvars_prefix},
{"dp_vars_origin",0,register_dp_vars_origin},
{"dp_dvars_origin",0,register_dp_dvars_origin},
{"dp_vars_hweyl",0,register_dp_vars_hweyl},
{"show_lt",0,register_show_lt},
{0,0,0},
};
#define PARTIAL "\\partial"
char *conv_rule(char *name)
{
char *body,*r;
int len;
if ( convfunc )
name = call_convfunc(name);
if ( conv_flag & CONV_TABLE ) {
r = symbol_name(name);
if ( r ) return r;
}
if ( (conv_flag & CONV_DMODE) && *name == 'd' ) {
body = conv_rule(name+1);
r = MALLOC_ATOMIC((strlen(PARTIAL)+strlen(body)+5)*sizeof(char));
if ( !body || !(len=strlen(body)) )
strcpy(r,PARTIAL);
else if ( len == 1 )
sprintf(r,"%s_%s",PARTIAL,body);
else
sprintf(r,"%s_{%s}",PARTIAL,body);
return r;
} else
return conv_subs(name);
}
int _is_delimiter(char c)
{
if ( (c == ' ' || c == '_' || c == ',') ) return 1;
else return 0;
}
int _is_alpha(char c)
{
if ( isdigit(c) || c == '{' || _is_delimiter(c) ) return 0;
else return 1;
}
char *conv_subs(char *name)
{
int i,j,k,len,clen,slen,start,level;
char *buf,*head,*r,*h,*brace,*buf_conv;
char **subs;
if ( !name || !(len=strlen(name)) ) return "";
if ( !(conv_flag&CONV_SUBS) ) return name;
subs = (char **)ALLOCA(len*sizeof(char* ));
for ( i = 0, j = 0, start = i; ; j++ ) {
while ( (i < len) && _is_delimiter(name[i]) ) i++;
start = i;
if ( i == len ) break;
if ( name[i] == '{' ) {
for ( level = 1, i++; i < len && level; i++ ) {
if ( name[i] == '{' ) level++;
else if ( name[i] == '}' ) level--;
}
slen = i-start;
if ( slen >= 3 ) {
brace = (char *)ALLOCA((slen+1)*sizeof(char));
strncpy(brace,name+start+1,slen-2);
brace[slen-2] = 0;
buf = conv_subs(brace);
subs[j] = (char *)ALLOCA((strlen(buf)+3)*sizeof(char));
if ( strlen(buf) == 1 )
strcpy(subs[j],buf);
else
sprintf(subs[j],"{%s}",buf);
} else
subs[j] = "{}";
} else {
if ( isdigit(name[i]) )
while ( i < len && isdigit(name[i]) ) i++;
else
while ( i < len && _is_alpha(name[i]) ) i++;
slen = i-start;
buf = (char *)ALLOCA((slen+1)*sizeof(char));
strncpy(buf,name+start,slen); buf[slen] = 0;
buf_conv = symbol_name(buf);
subs[j] = buf_conv?buf_conv:buf;
}
}
for ( k = 0, clen = 0; k < j; k++ ) clen += strlen(subs[k]);
/* {subs(0)}_{{subs(1)},...,{subs(j-1)}} => {}:j+1 _:1 ,:j-2 */
h = r = MALLOC_ATOMIC((clen+(j+1)*2+1+(j-2)+1)*sizeof(char));
if ( j == 1 )
sprintf(h,"{%s}",subs[0]);
else {
sprintf(h,"{%s}_{%s",subs[0],subs[1]);
h += strlen(h);
for ( k = 2; k < j; k++ ) {
sprintf(h,",%s",subs[k]);
h += strlen(h);
}
strcpy(h,"}");
}
return r;
}
char *call_convfunc(char *name)
{
STRING str,r;
NODE arg;
MKSTR(str,name);
arg = mknode(1,str);
r = (STRING)bevalf(convfunc,arg);
if ( !r || OID(r) != O_STR )
error("call_convfunc : invalid result");
return BDY(r);
}
int register_symbol_table(Obj arg)
{
NODE n,t;
Obj b;
STRING a0,a1;
struct TeXSymbol *uts;
int i,len;
/* check */
if ( !arg ) {
user_texsymbol = 0;
return 1;
}
if ( OID(arg) != O_LIST ) return 0;
n = BDY((LIST)arg);
len = length(n);
uts = (struct TeXSymbol *)MALLOC((len+1)*sizeof(struct TeXSymbol));
for ( i = 0; n; n = NEXT(n), i++ ) {
b = (Obj)BDY(n);
if ( !b || OID(b) != O_LIST ) return 0;
t = BDY((LIST)b);
if ( !t || !NEXT(t) ) return 0;
a0 = (STRING)BDY(t);
a1 = (STRING)BDY(NEXT(t));
if ( !a0 ) return 0;
if ( OID(a0) == O_STR )
uts[i].text = BDY(a0);
else if ( OID(a0) == O_P )
uts[i].text = NAME(VR((P)a0));
else
return 0;
if ( !a1 ) return 0;
if ( OID(a1) == O_STR )
uts[i].symbol = BDY(a1);
else if ( OID(a1) == O_P )
uts[i].symbol = NAME(VR((P)a1));
else
return 0;
}
uts[i].text = 0;
uts[i].symbol = 0;
user_texsymbol = uts;
return 1;
}
int register_dp_vars_origin(Obj arg)
{
if ( INT(arg) ) {
dp_vars_origin = QTOS((Q)arg);
return 1;
} else return 0;
}
int register_dp_dvars_origin(Obj arg)
{
if ( INT(arg) ) {
dp_dvars_origin = QTOS((Q)arg);
return 1;
} else return 0;
}
int register_dp_vars_hweyl(Obj arg)
{
if ( INT(arg) ) {
dp_vars_hweyl = QTOS((Q)arg);
return 1;
} else return 0;
}
int register_show_lt(Obj arg)
{
if ( INT(arg) ) {
show_lt = QTOS((Q)arg);
return 1;
} else return 0;
}
int register_conv_rule(Obj arg)
{
if ( INT(arg) ) {
conv_flag = QTOS((Q)arg);
convfunc = 0;
return 1;
} else return 0;
}
int register_conv_func(Obj arg)
{
if ( !arg ) {
convfunc = 0;
return 1;
} else if ( OID(arg) == O_P && (long)(VR((P)arg))->attr == V_SR ) {
convfunc = (FUNC)(VR((P)arg)->priv);
/* f must be a function which takes single argument */
return 1;
} else return 0;
}
int register_dp_vars(Obj arg)
{
int l,i;
char **r;
NODE n;
STRING a;
if ( !arg ) {
dp_vars = 0;
dp_vars_len = 0;
return 1;
} else if ( OID(arg) != O_LIST )
return 0;
else {
n = BDY((LIST)arg);
l = length(n);
r = (char **)MALLOC_ATOMIC(l*sizeof(char *));
for ( i = 0; i < l; i++, n = NEXT(n) ) {
a = (STRING)BDY(n);
if ( !a ) return 0;
if ( OID(a) == O_STR )
r[i] = BDY(a);
else if ( OID(a) == O_P )
r[i] = NAME(VR((P)a));
else
return 0;
}
dp_vars = r;
dp_vars_len = l;
return 1;
}
}
int register_dp_vars_prefix(Obj arg)
{
if ( !arg ) {
dp_vars_prefix = 0;
return 1;
} else if ( OID(arg) == O_STR ) {
dp_vars_prefix = BDY((STRING)arg);
return 1;
} else if ( OID(arg) == O_P ) {
dp_vars_prefix = NAME(VR((P)arg));
return 1;
} else return 0;
}
int register_dp_dvars_prefix(Obj arg)
{
if ( !arg ) {
dp_dvars_prefix = 0;
return 1;
} else if ( OID(arg) == O_STR ) {
dp_dvars_prefix = BDY((STRING)arg);
return 1;
} else if ( OID(arg) == O_P ) {
dp_dvars_prefix = NAME(VR((P)arg));
return 1;
} else return 0;
}
void Pquotetotex_env(NODE arg,Obj *rp)
{
int ac,i;
char *name;
NODE n,n0;
STRING s;
LIST l;
ac = argc(arg);
if ( !ac ) {
n0 = 0;
for ( i = 0; qtot_env[i].name; i++ ) {
NEXTNODE(n0,n); MKSTR(s,qtot_env[i].name); BDY(n) = (pointer)s;
NEXTNODE(n0,n); BDY(n) = (Q)qtot_env[i].value;
}
NEXT(n) = 0;
MKLIST(l,n0);
*rp = (Obj)l;
} else if ( ac == 1 && !ARG0(arg) ) {
/* set to default */
for ( i = 0; qtot_env[i].name; i++ ) {
(qtot_env[i].reg)(0);
qtot_env[i].value = 0;
}
*rp = 0;
} else if ( ac == 1 || ac == 2 ) {
asir_assert(ARG0(arg),O_STR,"quotetotex_env");
name = BDY((STRING)ARG0(arg));
for ( i = 0; qtot_env[i].name; i++ )
if ( !strcmp(qtot_env[i].name,name) ) {
if ( ac == 2 ) {
if ( (qtot_env[i].reg)((Obj)ARG1(arg)) )
qtot_env[i].value = (Obj)ARG1(arg);
else
error("quotetotex_env : invalid argument");
}
*rp = qtot_env[i].value;
return;
}
*rp = 0;
} else
*rp = 0;
}
void Pwrite_to_tb(NODE arg,Q *rp)
{
int i;
Obj obj;
TB tb;
asir_assert(ARG1(arg),O_TB,"write_to_tb");
obj = ARG0(arg);
if ( !obj )
write_tb("",ARG1(arg));
else if ( OID(obj) == O_STR )
write_tb(BDY((STRING)obj),ARG1(arg));
else if ( OID(obj) == O_TB ) {
tb = (TB)obj;
for ( i = 0; i < tb->next; i++ )
write_tb(tb->body[i],ARG1(arg));
}
*rp = 0;
}
void Pqt_to_nary(NODE arg,QUOTE *rp)
{
FNODE f;
f = fnode_to_nary(BDY((QUOTE)ARG0(arg)));
MKQUOTE(*rp,f);
}
void Pqt_to_bin(NODE arg,QUOTE *rp)
{
FNODE f;
int direction;
direction = QTOS((Q)ARG1(arg));
f = fnode_to_bin(BDY((QUOTE)ARG0(arg)),direction);
MKQUOTE(*rp,f);
}
void Pqt_is_var(NODE arg,Q *rp)
{
QUOTE q;
int ret;
q = (QUOTE)ARG0(arg);
asir_assert(q,O_QUOTE,"qt_is_var");
ret = fnode_is_var(BDY(q));
STOQ(ret,*rp);
}
void Pqt_is_coef(NODE arg,Q *rp)
{
QUOTE q;
int ret;
q = (QUOTE)ARG0(arg);
asir_assert(q,O_QUOTE,"qt_is_coef");
ret = fnode_is_coef(BDY(q));
STOQ(ret,*rp);
}
void Pqt_is_number(NODE arg,Q *rp)
{
QUOTE q;
int ret;
q = (QUOTE)ARG0(arg);
asir_assert(q,O_QUOTE,"qt_is_number");
ret = fnode_is_number(BDY(q));
STOQ(ret,*rp);
}
void Pqt_is_rational(NODE arg,Q *rp)
{
QUOTE q;
int ret;
q = (QUOTE)ARG0(arg);
asir_assert(q,O_QUOTE,"qt_is_rational");
ret = fnode_is_rational(BDY(q));
STOQ(ret,*rp);
}
void Pqt_is_integer(NODE arg,Q *rp)
{
QUOTE q;
int ret;
q = (QUOTE)ARG0(arg);
asir_assert(q,O_QUOTE,"qt_is_integer");
ret = fnode_is_integer(BDY(q));
STOQ(ret,*rp);
}
void Pqt_is_function(NODE arg,Q *rp)
{
QUOTE q;
int ret;
q = (QUOTE)ARG0(arg);
asir_assert(q,O_QUOTE,"qt_is_function");
if ( q->id == I_FUNC || q->id == I_IFUNC )
ret = 1;
else
ret = 0;
STOQ(ret,*rp);
}
void Pqt_is_dependent(NODE arg,Q *rp)
{
P x;
QUOTE q,v;
int ret;
V var;
q = (QUOTE)ARG0(arg);
v = (QUOTE)ARG1(arg);
asir_assert(q,O_QUOTE,"qt_is_dependent");
asir_assert(v,O_QUOTE,"qt_is_dependent");
x = (P)eval(BDY(v));
if ( !x || OID(x) != O_P )
*rp = 0;
var = VR(x);
ret = fnode_is_dependent(BDY(q),var);
STOQ(ret,*rp);
}
void Pqt_match(NODE arg,Q *rp)
{
FNODE f,g;
Obj obj;
QUOTE q;
NODE r;
int ret;
obj = (Obj)ARG0(arg);
ret = qt_match(obj,(Obj)ARG1(arg),&r);
if ( ret ) {
do_assign(r);
*rp = ONE;
} else
*rp = 0;
}
void Pnqt_match(NODE arg,Q *rp)
{
QUOTE fq,pq;
FNODE f,p;
int ret;
Q mode;
NODE r;
mode = argc(arg)==3 ? (Q)ARG2(arg) : 0;
fq = (QUOTE)ARG0(arg); Pqt_normalize(mknode(2,fq,mode),&fq); f = (FNODE)BDY(fq);
pq = (QUOTE)ARG1(arg); Pqt_normalize(mknode(2,pq,mode),&pq); p = (FNODE)BDY(pq);
ret = nfnode_match(f,p,&r);
if ( ret ) {
fnode_do_assign(r);
*rp = ONE;
} else
*rp = 0;
}
void Pnqt_match_rewrite(NODE arg,Obj *rp)
{
FNODE f,p,c,a,r;
Obj obj,pat,cond,action;
NODE rule;
QUOTE q;
Q mode;
int m;
obj = (Obj)ARG0(arg);
rule = BDY((LIST)ARG1(arg));
mode = (Q)ARG2(arg);
if ( length(rule) == 2 ) {
pat = ARG0(rule);
cond = (Obj)ONE;
action = (Obj)ARG1(rule);
} else {
pat = ARG0(rule);
cond = ARG1(rule);
action = (Obj)ARG2(rule);
}
Pqt_normalize(mknode(2,obj,mode),&q); f = (FNODE)BDY(q);
Pqt_normalize(mknode(2,pat,mode),&q); p = (FNODE)BDY(q);
Pqt_normalize(mknode(2,action,mode),&q);
a = (FNODE)BDY(q);
if ( OID(cond) == O_QUOTE ) c = BDY((QUOTE)cond);
else c = mkfnode(1,I_FORMULA,ONE);
m = QTOS(mode);
r = nfnode_match_rewrite(f,p,c,a,m);
if ( r ) {
MKQUOTE(q,r);
*rp = (Obj)q;
} else
*rp = obj;
}
/* f is NARYOP => do submatch */
#define PV_ANY 99999999
FNODE nfnode_match_rewrite(FNODE f,FNODE p,FNODE c,FNODE a,int mode)
{
ARF op;
NODE arg,h0,t,h,valuen;
NODE r,s0,s,pair;
FNODE any,pany,head,tail,a1,a2;
QUOTE q;
int ret;
FNODE value;
int ind;
if ( f->id == I_NARYOP ) {
op = (ARF)FA0(f);
arg = (NODE)FA1(f);
pany = 0;
for ( h0 = 0, t = arg; t; t = NEXT(t) ) {
tail = fnode_node_to_nary(op,t);
ret = nfnode_match(tail,p,&r) && eval(rewrite_fnode(c,r,1));
if ( ret ) break;
/* append a variable to the pattern */
if ( !pany ) {
any = mkfnode(1,I_PVAR,PV_ANY);
pany = mkfnode(3,I_BOP,op,p,any);
pany = fnode_normalize(pany,mode);
}
ret = nfnode_match(tail,pany,&r) && eval(rewrite_fnode(c,r,1));
if ( ret ) {
a = fnode_normalize(mkfnode(3,I_BOP,op,a,any),mode);
break;
}
NEXTNODE(h0,h);
BDY(h) = BDY(t);
}
if ( t ) {
if ( h0 ) NEXT(h) = 0;
head = fnode_node_to_nary(op,h0);
a = fnode_normalize(mkfnode(3,I_BOP,op,head,a),mode);
ret = 1;
} else
ret = 0;
} else
ret = nfnode_match(f,p,&r) && eval(rewrite_fnode(c,r,1));
if ( ret ) {
a1 = rewrite_fnode(a,r,0);
a2 = partial_eval(a1);
return fnode_normalize(a2,mode);
} else
return 0;
}
void do_assign(NODE arg)
{
NODE t,pair;
int pv;
QUOTE value;
for ( t = arg; t; t = NEXT(t) ) {
pair = BDY((LIST)BDY(t));
pv = (long)FA0((FNODE)BDY((QUOTE)BDY(pair)));
value = (QUOTE)(BDY(NEXT(pair)));
ASSPV(pv,value);
}
}
/* [[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
*/
int merge_matching_node(NODE n,NODE a,NODE *rp)
{
NODE ta,ba,tn,bn;
QUOTE pa,va,pn,vn;
if ( !n ) {
*rp = a;
return 1;
}
for ( ta = a; ta; ta = NEXT(ta) ) {
ba = BDY((LIST)BDY(ta));
if ( !ba ) continue;
pa = (QUOTE)BDY(ba); va = (QUOTE)BDY(NEXT(ba));
for ( tn = n; tn; tn = NEXT(tn) ) {
bn = BDY((LIST)BDY(tn));
if ( !bn ) continue;
pn = (QUOTE)BDY(bn); vn = (QUOTE)BDY(NEXT(bn));
if ( !compquote(CO,pa,pn) ) {
if ( !compquote(CO,va,vn) ) break;
else return 0;
}
}
if ( !tn ) {
MKNODE(tn,(pointer)BDY(ta),n);
n = tn;
}
}
*rp = n;
return 1;
}
int qt_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 = qt_match((Obj)BDY(tf),(Obj)BDY(tp),&a);
if ( !ret ) return 0;
ret = merge_matching_node(r,a,&r1);
if ( !ret ) return 0;
else r = r1;
}
*rp = r;
return 1;
}
/* f = [a,b,c,...] pat = [X,Y,...] rpat matches the rest of f */
int qt_match_cons(NODE f,NODE pat,Obj rpat,NODE *rp) {
QUOTE q;
Q id;
FNODE fn;
NODE r,a,tf,tp,r1,arg;
int ret;
LIST list,alist;
/* matching of the head part */
if ( length(f) < length(pat) ) return 0;
r = 0;
for ( tf = f, tp = pat; tp; tf = NEXT(tf), tp = NEXT(tp) ) {
ret = qt_match((Obj)BDY(tf),(Obj)BDY(tp),&a);
if ( !ret ) return 0;
ret = merge_matching_node(r,a,&r1);
if ( !ret ) return 0;
else r = r1;
}
/* matching of the rest */
MKLIST(list,tf);
STOQ(I_LIST,id); a = mknode(2,id,list);
MKLIST(alist,a);
arg = mknode(1,alist);
Pfunargs_to_quote(arg,&q);
ret = qt_match((Obj)q,rpat,&a);
if ( !ret ) return 0;
ret = merge_matching_node(r,a,&r1);
if ( !ret ) return 0;
*rp = r1;
return 1;
}
void get_quote_id_arg(QUOTE f,int *id,NODE *r)
{
LIST fa;
NODE arg,fab;
arg = mknode(1,f); Pquote_to_funargs(arg,&fa); fab = BDY((LIST)fa);
*id = QTOS((Q)BDY(fab)); *r = NEXT(fab);
}
/* *rp : [[quote(A),quote(1)],...] */
int qt_match(Obj f, Obj pat, NODE *rp)
{
NODE tf,tp,head,body;
NODE parg,farg,r;
Obj rpat;
LIST fa,l;
int pid,id;
FUNC ff,pf;
int ret;
QUOTE q;
FNODE g;
if ( !f )
if ( !pat ) {
*rp = 0; return 1;
} else
return 0;
else if ( OID(pat) == O_LIST ) {
if ( OID(f) == O_LIST )
return qt_match_node(BDY((LIST)f),BDY((LIST)pat),rp);
else
return 0;
} else if ( OID(pat) == O_QUOTE ) {
pid = ((FNODE)BDY((QUOTE)pat))->id;
switch ( pid ) {
case I_FORMULA:
if ( compquote(CO,f,pat) )
return 0;
else {
*rp = 0; return 1;
}
break;
case I_LIST: case I_CONS:
get_quote_id_arg((QUOTE)pat,&pid,&parg);
if ( OID(f) == O_LIST )
tf = BDY((LIST)f);
else if ( OID(f) == O_QUOTE
&& ((FNODE)BDY((QUOTE)f))->id == pid ) {
get_quote_id_arg((QUOTE)f,&id,&farg);
tf = BDY((LIST)BDY(farg));
} else
return 0;
tp = BDY((LIST)BDY(parg));
if ( pid == I_LIST )
return qt_match_node(tf,tp,rp);
else {
rpat = (Obj)BDY(NEXT(parg));
return qt_match_cons(tf,tp,rpat,rp);
}
case I_PVAR:
/* [[pat,f]] */
r = mknode(2,pat,f); MKLIST(l,r);
*rp = mknode(1,l);
return 1;
case I_IFUNC:
/* F(X,Y,...) = ... */
get_quote_id_arg((QUOTE)f,&id,&farg);
get_quote_id_arg((QUOTE)pat,&pid,&parg);
if ( id == I_FUNC ) {
r = mknode(2,BDY(parg),BDY(farg)); MKLIST(l,r);
head = mknode(1,l);
ret = qt_match(BDY(NEXT(farg)),
BDY(NEXT(parg)),&body);
if ( !ret ) return 0;
else return merge_matching_node(head,body,rp);
} else
return 0;
case I_NARYOP: case I_BOP: case I_FUNC:
/* X+Y = ... */
/* f(...) = ... */
if ( OID(f) != O_QUOTE ) return 0;
id = ((FNODE)BDY((QUOTE)f))->id;
if ( pid == I_FUNC )
;
else {
/* XXX converting to I_BOP */
if ( pid == I_NARYOP ) {
g = fnode_to_bin(BDY((QUOTE)pat),1);
MKQUOTE(q,g); pat = (Obj)q;
}
if ( id == I_NARYOP ) {
g = fnode_to_bin(BDY((QUOTE)f),1);
MKQUOTE(q,g); f = (Obj)q;
}
}
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 qt_match_node(NEXT(farg),NEXT(parg),rp);
default:
if ( OID(f) != O_QUOTE ) return 0;
id = ((FNODE)BDY((QUOTE)f))->id;
if ( id != pid ) return 0;
get_quote_id_arg((QUOTE)pat,&pid,&parg);
get_quote_id_arg((QUOTE)f,&id,&farg);
return qt_match_node(farg,parg,rp);
}
}
}
void Pquotetotex(NODE arg,STRING *rp)
{
TB tb;
NEWTB(tb);
/* XXX for DP */
is_lt = 1;
fnodetotex_tb(BDY((QUOTE)ARG0(arg)),tb);
tb_to_string(tb,rp);
}
void Pquotetotex_tb(NODE arg,Q *rp)
{
int i;
TB tb;
asir_assert(ARG1(arg),O_TB,"quotetotex_tb");
/* XXX for DP */
is_lt = 1;
fnodetotex_tb(BDY((QUOTE)ARG0(arg)),ARG1(arg));
*rp = 0;
}
void Pstring_to_tb(NODE arg,TB *rp)
{
TB tb;
asir_assert(ARG0(arg),O_STR,"string_to_tb");
NEWTB(tb);
tb->body[0] = BDY((STRING)ARG0(arg));
tb->next++;
*rp = tb;
}
void Ptb_to_string(NODE arg,STRING *rp)
{
TB tb;
asir_assert(ARG0(arg),O_TB,"tb_to_string");
tb = (TB)ARG0(arg);
tb_to_string(tb,rp);
}
void tb_to_string(TB tb,STRING *rp)
{
int j,len;
char *all,*p,*q;
for ( j = 0, len = 0; j < tb->next; j++ )
len += strlen(tb->body[j]);
all = (char *)MALLOC_ATOMIC((len+1)*sizeof(char));
for ( j = 0, p = all; j < tb->next; j++ )
for ( q = tb->body[j]; *q; *p++ = *q++ );
*p = 0;
MKSTR(*rp,all);
}
void Pclear_tb(NODE arg,Q *rp)
{
TB tb;
int j;
asir_assert(ARG0(arg),O_TB,"clear_tb");
tb = (TB)ARG0(arg);
for ( j = 0; j < tb->next; j++ )
tb->body[j] = 0;
tb->next = 0;
*rp = 0;
}
void Pstr_len(arg,rp)
NODE arg;
Q *rp;
{
Obj obj;
TB tb;
int r,i;
obj = (Obj)ARG0(arg);
if ( !obj || (OID(obj) != O_STR && OID(obj) != O_TB) )
error("str_len : invalid argument");
if ( OID(obj) == O_STR)
r = strlen(BDY((STRING)obj));
else if ( OID(obj) == O_TB ) {
tb = (TB)obj;
for ( r = i = 0; i < tb->next; i++ )
r += strlen(tb->body[i]);
}
STOQ(r,*rp);
}
void Pstr_chr(arg,rp)
NODE arg;
Q *rp;
{
STRING str,terminator;
Q start;
char *p,*ind;
int chr,spos,r;
str = (STRING)ARG0(arg);
start = (Q)ARG1(arg);
terminator = (STRING)ARG2(arg);
asir_assert(str,O_STR,"str_chr");
asir_assert(start,O_N,"str_chr");
asir_assert(terminator,O_STR,"str_chr");
p = BDY(str);
spos = QTOS(start);
chr = BDY(terminator)[0];
if ( spos > (int)strlen(p) )
r = -1;
else {
ind = strchr(p+spos,chr);
if ( ind )
r = ind-p;
else
r = -1;
}
STOQ(r,*rp);
}
void Psub_str(arg,rp)
NODE arg;
STRING *rp;
{
STRING str;
Q head,tail;
char *p,*r;
int spos,epos,len;
str = (STRING)ARG0(arg);
head = (Q)ARG1(arg);
tail = (Q)ARG2(arg);
asir_assert(str,O_STR,"sub_str");
asir_assert(head,O_N,"sub_str");
asir_assert(tail,O_N,"sub_str");
p = BDY(str);
spos = QTOS(head);
epos = QTOS(tail);
len = strlen(p);
if ( (spos >= len) || (epos < spos) ) {
*rp = 0; return;
}
if ( epos >= len )
epos = len-1;
len = epos-spos+1;
r = (char *)MALLOC(len+1);
strncpy(r,p+spos,len);
r[len] = 0;
MKSTR(*rp,r);
}
void Pstrtoascii(arg,rp)
NODE arg;
LIST *rp;
{
STRING str;
unsigned char *p;
int len,i;
NODE n,n1;
Q q;
str = (STRING)ARG0(arg);
asir_assert(str,O_STR,"strtoascii");
p = BDY(str);
len = strlen(p);
for ( i = len-1, n = 0; i >= 0; i-- ) {
UTOQ((unsigned int)p[i],q);
MKNODE(n1,q,n);
n = n1;
}
MKLIST(*rp,n);
}
void Pasciitostr(arg,rp)
NODE arg;
STRING *rp;
{
LIST list;
unsigned char *p;
int len,i,j;
NODE n;
Q q;
list = (LIST)ARG0(arg);
asir_assert(list,O_LIST,"asciitostr");
n = BDY(list);
len = length(n);
p = MALLOC_ATOMIC(len+1);
for ( i = 0; i < len; i++, n = NEXT(n) ) {
q = (Q)BDY(n);
asir_assert(q,O_N,"asciitostr");
j = QTOS(q);
if ( j >= 256 || j <= 0 )
error("asciitostr : argument out of range");
p[i] = j;
}
p[i] = 0;
MKSTR(*rp,(char *)p);
}
void Peval_str(arg,rp)
NODE arg;
Obj *rp;
{
FNODE fnode;
SNODE snode;
char *cmd;
#if defined(PARI)
void recover(int);
recover(0);
# if !(PARI_VERSION_CODE > 131588)
if ( setjmp(environnement) ) {
avma = top; recover(1);
resetenv("");
}
# endif
#endif
cmd = BDY((STRING)ARG0(arg));
#if 0
exprparse_create_var(0,cmd,&fnode);
*rp = eval(fnode);
#else
exprparse_create_var(0,cmd,&snode);
*rp = evalstat(snode);
#endif
}
void Prtostr(arg,rp)
NODE arg;
STRING *rp;
{
char *b;
int len;
len = estimate_length(CO,ARG0(arg));
b = (char *)MALLOC_ATOMIC(len+1);
soutput_init(b);
sprintexpr(CO,ARG0(arg));
MKSTR(*rp,b);
}
void Pstrtov(arg,rp)
NODE arg;
P *rp;
{
char *p;
p = BDY((STRING)ARG0(arg));
#if 0
if ( !islower(*p) )
*rp = 0;
else {
for ( t = p+1; t && (isalnum(*t) || *t == '_'); t++ );
if ( *t )
*rp = 0;
else
makevar(p,rp);
}
#else
makevar(p,rp);
#endif
}
static struct TeXSymbol texsymbol[] = {
{"sin","\\sin"},
{"cos","\\cos"},
{"tan","\\tan"},
{"sinh","\\sinh"},
{"cosh","\\cosh"},
{"tanh","\\tanh"},
{"exp","\\exp"},
{"log","\\log"},
/* Greek Letters (lower case) */
{"alpha","\\alpha"},
{"beta","\\beta"},
{"gamma","\\gamma"},
{"delta","\\delta"},
{"epsilon","\\epsilon"},
{"varepsilon","\\varepsilon"},
{"zeta","\\zeta"},
{"eta","\\eta"},
{"theta","\\theta"},
{"vartheta","\\vartheta"},
{"iota","\\iota"},
{"kappa","\\kappa"},
{"lambda","\\lambda"},
{"mu","\\mu"},
{"nu","\\nu"},
{"xi","\\xi"},
{"pi","\\pi"},
{"varpi","\\varpi"},
{"rho","\\rho"},
{"sigma","\\sigma"},
{"varsigma","\\varsigma"},
{"tau","\\tau"},
{"upsilon","\\upsilon"},
{"phi","\\phi"},
{"varphi","\\varphi"},
{"chi","\\chi"},
{"omega","\\omega"},
/* Greek Letters, (upper case) */
{"ggamma","\\Gamma"},
{"ddelta","\\Delta"},
{"ttheta","\\Theta"},
{"llambda","\\Lambda"},
{"xxi","\\Xi"},
{"ppi","\\Pi"},
{"ssigma","\\Sigma"},
{"uupsilon","\\Upsilon"},
{"pphi","\\Phi"},
{"ppsi","\\Psi"},
{"oomega","\\Omega"},
/* Our own mathematical functions */
{"algebra_tensor","\\otimes"},
{"base_where","{\\rm \\ where \\ }"},
/* Mathematical constants */
{"c_pi","\\pi"},
{"c_i","\\sqrt{-1}"},
/* Temporary */
{0,0}
};
char *symbol_name(char *name)
{
int i;
if ( !name || strlen(name) == 0 )
return "";
if ( !(conv_flag & CONV_TABLE) )
return name;
if ( user_texsymbol )
for ( i = 0; user_texsymbol[i].text; i++ )
if ( !strcmp(user_texsymbol[i].text,name) )
return user_texsymbol[i].symbol;
for ( i = 0; texsymbol[i].text; i++ )
if ( !strcmp(texsymbol[i].text,name) )
return texsymbol[i].symbol;
return 0;
}
void Pget_function_name(NODE arg,STRING *rp)
{
QUOTEARG qa;
ARF f;
char *opname;
qa = (QUOTEARG)BDY(arg);
if ( !qa || OID(qa) != O_QUOTEARG || qa->type != A_arf )
*rp = 0;
else {
f = (ARF)BDY(qa);
opname = f->name;
MKSTR(*rp,opname);
}
}
FNODE strip_paren(FNODE);
void objtotex_tb(Obj obj,TB tb);
void fnodetotex_tb(FNODE f,TB tb)
{
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;
char *r;
FNODE fi,f2,f1;
write_tb(" ",tb);
if ( !f ) {
write_tb("0",tb);
return;
}
switch ( f->id ) {
/* unary operators */
case I_NOT:
write_tb("\\neg (",tb);
fnodetotex_tb((FNODE)FA0(f),tb);
write_tb(")",tb);
break;
case I_PAREN:
write_tb("(",tb);
fnodetotex_tb((FNODE)FA0(f),tb);
write_tb(")",tb);
break;
case I_MINUS:
write_tb("-",tb);
fnodetotex_tb((FNODE)FA0(f),tb);
break;
/* binary operators */
/* arg list */
/* I_AND, I_OR => FA0(f), FA1(f) */
/* otherwise => FA1(f), FA2(f) */
case I_BOP:
opname = ((ARF)FA0(f))->name;
switch ( opname[0] ) {
case '+':
fnodetotex_tb((FNODE)FA1(f),tb);
if ( !top_is_minus((FNODE)FA2(f)) ) write_tb(opname,tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case '-':
if ( FA1(f) ) fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(opname,tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case '*':
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" ",tb);
/* XXX special care for DP */
f2 = (FNODE)FA2(f);
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((FNODE)FA2(f),tb);
} else
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case '/':
write_tb("\\frac{",tb);
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb("} {",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
write_tb("}",tb);
break;
case '^':
f1 = (FNODE)FA1(f);
if ( fnode_is_var(f1) )
fnodetotex_tb(f1,tb);
else {
write_tb("(",tb);
fnodetotex_tb(f1,tb);
write_tb(")",tb);
}
write_tb("^{",tb);
fnodetotex_tb(strip_paren((FNODE)FA2(f)),tb);
write_tb("} ",tb);
break;
case '%':
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" {\\rm mod}\\, ",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
default:
error("invalid binary operator");
break;
}
break;
case I_NARYOP:
args = (NODE)FA1(f);
switch ( OPNAME(f) ) {
case '+':
fnodetotex_tb((FNODE)BDY(args),tb);
for ( args = NEXT(args); args; args = NEXT(args) ) {
write_tb("+",tb);
f1 = (FNODE)BDY(args);
/* if ( fnode_is_var(f1) || IS_MUL(f1) )
fnodetotex_tb(f1,tb);
else */ {
write_tb("(",tb);
fnodetotex_tb(f1,tb);
write_tb(")",tb);
}
}
break;
case '*':
f1 = (FNODE)BDY(args);
if ( f1->id == I_FORMULA && MUNIQ(FA0(f1)) ) {
write_tb("- ",tb); args = NEXT(args);
}
for ( ; args; args = NEXT(args) ) {
f2 = (FNODE)BDY(args);
if ( fnode_is_var(f2) || IS_BINARYPWR(f2) )
fnodetotex_tb(f2,tb);
else {
write_tb("(",tb);
fnodetotex_tb(f2,tb);
write_tb(")",tb);
}
}
break;
default:
error("invalid nary op");
break;
}
break;
case I_COP:
switch( (cid)FA0(f) ) {
case C_EQ:
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" = ",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case C_NE:
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" \\neq ",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case C_GT:
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" > ",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case C_LT:
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" < ",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case C_GE:
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" \\geq ",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case C_LE:
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" \\leq ",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
}
break;
case I_LOP:
switch( (lid)FA0(f) ) {
case L_EQ:
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" = ",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case L_NE:
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" \\neq ",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case L_GT:
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" > ",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case L_LT:
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" < ",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case L_GE:
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" \\geq ",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case L_LE:
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" \\leq ",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case L_AND:
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" {\\rm \\ and\\ } ",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case L_OR:
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(" {\\rm \\ or\\ } ",tb);
fnodetotex_tb((FNODE)FA2(f),tb);
break;
case L_NOT:
/* XXX : L_NOT is a unary operator */
write_tb("\\neg (",tb);
fnodetotex_tb((FNODE)FA1(f),tb);
write_tb(")",tb);
return;
}
break;
case I_AND:
fnodetotex_tb((FNODE)FA0(f),tb);
write_tb(" {\\rm \\ and\\ } ",tb);
fnodetotex_tb((FNODE)FA1(f),tb);
break;
case I_OR:
fnodetotex_tb((FNODE)FA0(f),tb);
write_tb(" {\\rm \\ or\\ } ",tb);
fnodetotex_tb((FNODE)FA1(f),tb);
break;
/* ternary operators */
case I_CE:
error("fnodetotex_tb : not implemented yet");
break;
/* lists */
case I_LIST:
write_tb(" [ ",tb);
n = (NODE)FA0(f);
fnodenodetotex_tb(n,tb);
write_tb("]",tb);
break;
/* function */
case I_FUNC:
if ( !strcmp(((FUNC)FA0(f))->name,"@pi") )
write_tb("\\pi",tb);
else if ( !strcmp(((FUNC)FA0(f))->name,"@e") )
write_tb("e",tb);
else {
opname = conv_rule(((FUNC)FA0(f))->name);
write_tb(opname,tb);
write_tb("(",tb);
fargstotex_tb(opname,FA1(f),tb);
write_tb(")",tb);
}
break;
/* XXX */
case I_CAR:
opname = conv_rule("car");
write_tb(opname,tb);
write_tb("(",tb);
fargstotex_tb(opname,FA0(f),tb);
write_tb(")",tb);
break;
case I_CDR:
opname = conv_rule("cdr");
write_tb(opname,tb);
write_tb("(",tb);
fargstotex_tb(opname,FA0(f),tb);
write_tb(")",tb);
break;
/* exponent vector */
case I_EV:
n = (NODE)FA0(f);
if ( dp_vars_hweyl ) {
elen = length(n);
elen2 = elen>>1;
elen = elen2<<1;
}
allzero = 1;
if ( show_lt && is_lt )
write_tb("\\underline{",tb);
for ( t0 = 0, i = 0; n; n = NEXT(n), i++ ) {
fi = (FNODE)BDY(n);
if ( fi->id == I_FORMULA && !FA0(fi) ) continue;
allzero = 0;
if ( dp_vars && i < dp_vars_len ) {
strcpy(vname,dp_vars[i]);
vname_conv = conv_rule(vname);
} else {
if ( dp_vars_hweyl ) {
if ( i < elen2 ) {
strcpy(prefix,dp_vars_prefix?dp_vars_prefix:"x");
prefix_conv = conv_rule(prefix);
vname_conv = (char *)ALLOCA(strlen(prefix_conv)+50);
si = i+dp_vars_origin;
sprintf(vname_conv,(si>=0&&si<10)?"%s_%d":"%s_{%d}",
prefix_conv,si);
} else if ( i < elen ) {
strcpy(prefix,
dp_dvars_prefix?dp_dvars_prefix:"\\partial");
prefix_conv = conv_rule(prefix);
vname_conv = (char *)ALLOCA(strlen(prefix_conv)+50);
si = i+dp_dvars_origin-elen2;
sprintf(vname_conv,(si>=0&&si<10)?"%s_%d":"%s_{%d}",
prefix_conv,si);
} else {
strcpy(prefix,"h");
vname_conv = conv_rule(prefix);
}
} else {
strcpy(prefix,dp_vars_prefix?dp_vars_prefix:"x");
prefix_conv = conv_rule(prefix);
vname_conv = (char *)ALLOCA(strlen(prefix_conv)+50);
si = i+dp_vars_origin;
sprintf(vname_conv,(si>=0&&si<10)?"%s_%d":"%s_{%d}",
prefix_conv,si);
}
}
if ( fi->id == I_FORMULA && UNIQ(FA0(fi)) ) {
len = strlen(vname_conv);
opname = MALLOC_ATOMIC(len+2);
sprintf(opname,"%s ",vname_conv);
write_tb(opname,tb);
} else {
len = strlen(vname_conv);
/* 2: ^{ */
opname = MALLOC_ATOMIC(len+1+2);
sprintf(opname,"%s^{",vname_conv);
write_tb(opname,tb);
fnodetotex_tb((FNODE)BDY(n),tb);
write_tb("} ",tb);
}
}
/* XXX */
if ( allzero )
write_tb(" 1 ",tb);
if ( show_lt && is_lt ) {
write_tb("}",tb);
is_lt = 0;
}
break;
/* string */
case I_STR:
write_tb((char *)FA0(f),tb);
break;
/* internal object */
case I_FORMULA:
objtotex_tb((Obj)FA0(f),tb);
break;
/* program variable */
case I_PVAR:
if ( FA1(f) )
error("fnodetotex_tb : not implemented yet");
GETPVNAME(FA0(f),opname);
write_tb(opname,tb);
break;
default:
error("fnodetotex_tb : not implemented yet");
}
}
void objtotex_tb(Obj obj,TB tb)
{
C cplx;
char *r;
P t;
DCP dc;
char *v;
if ( !obj ) {
write_tb("0",tb);
return;
}
switch ( OID(obj) ) {
case O_N:
switch ( NID(obj) ) {
case N_C:
cplx = (C)obj;
write_tb("(",tb);
if ( cplx->r ) {
r = objtostr((Obj)cplx->r); write_tb(r,tb);
}
if ( cplx->i ) {
if ( cplx->r && compnum(0,cplx->i,0) > 0 ) {
write_tb("+",tb);
if ( !UNIQ(cplx->i) ) {
r = objtostr((Obj)cplx->i); write_tb(r,tb);
}
} else if ( MUNIQ(cplx->i) )
write_tb("-",tb);
else if ( !UNIQ(cplx->i) ) {
r = objtostr((Obj)cplx->i); write_tb(r,tb);
}
write_tb("\\sqrt{-1}",tb);
}
write_tb(")",tb);
break;
default:
write_tb(objtostr(obj),tb);
break;
}
break;
case O_P:
v = conv_rule(VR((P)obj)->name);
for ( dc = DC((P)obj); dc; dc = NEXT(dc) ) {
if ( !DEG(dc) )
objtotex_tb((Obj)COEF(dc),tb);
else {
if ( NUM(COEF(dc)) && UNIQ((Q)COEF(dc)) )
;
else if ( NUM(COEF(dc)) && MUNIQ((Q)COEF(dc)) )
write_tb("-",tb);
else if ( NUM(COEF(dc)) || !NEXT(DC(COEF(dc))))
objtotex_tb((Obj)COEF(dc),tb);
else {
write_tb("(",tb); objtotex_tb((Obj)COEF(dc),tb);
write_tb(")",tb);
}
write_tb(v,tb);
if ( cmpq(DEG(dc),ONE) ) {
write_tb("^",tb);
if ( INT(DEG(dc)) && SGN(DEG(dc))>0 ) {
write_tb("{",tb);
objtotex_tb((Obj)DEG(dc),tb);
write_tb("}",tb);
} else {
write_tb("{",tb); objtotex_tb((Obj)DEG(dc),tb);
write_tb("}",tb);
}
}
}
if ( NEXT(dc) ) {
t = COEF(NEXT(dc));
if ( !DEG(NEXT(dc)) ) {
if ( NUM(t) ) {
if ( !mmono(t) ) write_tb("+",tb);
} else {
if ( !mmono(COEF(DC(t))) ) write_tb("+",tb);
}
} else {
if ( !mmono(t) ) write_tb("+",tb);
}
}
}
break;
case O_R:
write_tb("\\frac{",tb);
objtotex_tb((Obj)NM((R)obj),tb);
write_tb("}{",tb);
objtotex_tb((Obj)DN((R)obj),tb);
write_tb("}",tb);
break;
default:
write_tb(objtostr(obj),tb);
break;
}
}
char *objtostr(Obj obj)
{
int len;
char *r;
len = estimate_length(CO,obj);
r = (char *)MALLOC_ATOMIC(len+1);
soutput_init(r);
sprintexpr(CO,obj);
return r;
}
void Psprintf(NODE arg,STRING *rp)
{
STRING string;
char *s,*t,*r;
int argc,n,len;
NODE node;
string = (STRING)ARG0(arg);
asir_assert(string,O_STR,"sprintf");
s = BDY(string);
for(n = 0, t = s; *t; t++) {
if (*t=='%' && *(t+1)=='a') {
n++;
}
}
for(node = NEXT(arg), argc = 0, len = strlen(s); node; node = NEXT(node), argc++) {
len += estimate_length(CO,BDY(node));
}
if (argc < n) {
error("sprintf: invalid argument");
}
r = (char *)MALLOC_ATOMIC(len);
for(node = NEXT(arg), t = r; *s; s++) {
if (*s=='%' && *(s+1)=='a') {
strcpy(t,objtostr(BDY(node)));
node = NEXT(node);
t = strchr(t,0);
s++;
}else {
*t++ = *s;
}
}
*t = 0;
MKSTR(*rp,r);
}
void fnodenodetotex_tb(NODE n,TB tb)
{
for ( ; n; n = NEXT(n) ) {
is_lt = 1;
fnodetotex_tb((FNODE)BDY(n),tb);
if ( NEXT(n) ) write_tb(", ",tb);
}
}
void fargstotex_tb(char *name,FNODE f,TB tb)
{
NODE n;
if ( !strcmp(name,"matrix") ) {
error("fargstotex_tb : not implemented yet");
} else if ( !strcmp(name,"vector") ) {
error("fargstotex_tb : not implemented yet");
} else {
if ( f->id == I_LIST ) {
n = (NODE)FA0(f);
fnodenodetotex_tb(n,tb);
} else
fnodetotex_tb(f,tb);
}
}
int top_is_minus(FNODE f)
{
char *opname;
int len;
Obj obj;
if ( !f )
return 0;
switch ( f->id ) {
case I_MINUS:
return 1;
case I_BOP:
opname = ((ARF)FA0(f))->name;
switch ( opname[0] ) {
case '+': case '*': case '/': case '^': case '%':
return top_is_minus((FNODE)FA1(f));
case '-':
if ( FA1(f) )
return top_is_minus((FNODE)FA1(f));
else
return 1;
default:
return 0;
}
break;
case I_COP:
return top_is_minus((FNODE)FA1(f));
case I_LOP:
if ( (lid)FA0(f) == L_NOT ) return 0;
else return top_is_minus((FNODE)FA1(f));
case I_AND: case I_OR:
return top_is_minus((FNODE)FA0(f));
case I_FORMULA:
obj = (Obj)FA0(f);
if ( !obj )
return 0;
else {
switch ( OID(obj) ) {
case O_N:
return mmono((P)obj);
case O_P:
#if 0
/* must be a variable */
opname = conv_rule(VR((P)obj)->name);
return opname[0]=='-';
#else
return mmono((P)obj);
#endif
default:
/* ??? */
len = estimate_length(CO,obj);
opname = (char *)MALLOC_ATOMIC(len+1);
soutput_init(opname);
sprintexpr(CO,obj);
return opname[0]=='-';
}
}
case I_NARYOP:
return top_is_minus((FNODE)BDY((NODE)FA1(f)));
default:
return 0;
}
}
FNODE flatten_fnode(FNODE,char *);
void Pflatten_quote(NODE arg,Obj *rp)
{
FNODE f;
QUOTE q;
if ( !ARG0(arg) || OID((Obj)ARG0(arg)) != O_QUOTE )
*rp = (Obj)ARG0(arg);
else if ( argc(arg) == 1 ) {
f = flatten_fnode(BDY((QUOTE)ARG0(arg)),"+");
f = flatten_fnode(f,"*");
MKQUOTE(q,f);
*rp = (Obj)q;
} else {
f = flatten_fnode(BDY((QUOTE)ARG0(arg)),BDY((STRING)ARG1(arg)));
MKQUOTE(q,f);
*rp = (Obj)q;
}
}
void Pget_quote_id(NODE arg,Q *rp)
{
FNODE f;
QUOTE q;
q = (QUOTE)ARG0(arg);
if ( !q || OID(q) != O_QUOTE )
error("get_quote_id : invalid argument");
f = BDY(q);
STOQ((int)f->id,*rp);
}
void Pquote_to_funargs(NODE arg,LIST *rp)
{
fid_spec_p spec;
QUOTE q;
QUOTEARG qa;
FNODE f;
STRING s;
QUOTE r;
int i;
Q id,a;
LIST l;
NODE t0,t,w,u,u0;
q = (QUOTE)ARG0(arg);
if ( !q || OID(q) != O_QUOTE )
error("quote_to_funargs : invalid argument");
f = BDY(q);
if ( !f ) {
MKLIST(*rp,0);
return;
}
get_fid_spec(f->id,&spec);
if ( !spec )
error("quote_to_funargs : not supported yet");
t0 = 0;
STOQ((int)f->id,id);
NEXTNODE(t0,t);
BDY(t) = (pointer)id;
for ( i = 0; spec->type[i] != A_end; i++ ) {
NEXTNODE(t0,t);
switch ( spec->type[i] ) {
case A_fnode:
MKQUOTE(r,(FNODE)f->arg[i]);
BDY(t) = (pointer)r;
break;
case A_int:
STOQ((int)f->arg[i],a);
BDY(t) = (pointer)a;
break;
case A_str:
MKSTR(s,(char *)f->arg[i]);
BDY(t) = (pointer)s;
break;
case A_internal:
BDY(t) = (pointer)f->arg[i];
break;
case A_node:
w = (NODE)f->arg[i];
for ( u0 = 0; w; w = NEXT(w) ){
NEXTNODE(u0,u);
MKQUOTE(r,(FNODE)BDY(w));
BDY(u) = (pointer)r;
}
if ( u0 ) NEXT(u) = 0;
MKLIST(l,u0);
BDY(t) = (pointer)l;
break;
default:
MKQUOTEARG(qa,spec->type[i],f->arg[i]);
BDY(t) = (pointer)qa;
break;
}
}
if ( t0 ) NEXT(t) = 0;
MKLIST(*rp,t0);
}
void Pfunargs_to_quote(NODE arg,QUOTE *rp)
{
fid_spec_p spec;
QUOTE q;
QUOTEARG qa;
FNODE f;
STRING s;
QUOTE r,b;
int i;
LIST l;
fid id;
Obj a;
NODE t0,t,u0,u,w;
l = (LIST)ARG0(arg);
if ( !l || OID(l) != O_LIST || !(t=BDY(l)) )
error("funargs_to_quote : invalid argument");
t = BDY(l);
id = (fid)QTOS((Q)BDY(t)); t = NEXT(t);
get_fid_spec(id,&spec);
if ( !spec )
error("funargs_to_quote : not supported yet");
for ( i = 0; spec->type[i] != A_end; i++ );
NEWFNODE(f,i);
f->id = id;
for ( i = 0; spec->type[i] != A_end; i++, t = NEXT(t) ) {
if ( !t )
error("funargs_to_quote : argument mismatch");
a = (Obj)BDY(t);
switch ( spec->type[i] ) {
case A_fnode:
if ( !a || OID(a) != O_QUOTE )
error("funargs_to_quote : invalid argument");
f->arg[i] = BDY((QUOTE)a);
break;
case A_int:
if ( !INT(a) )
error("funargs_to_quote : invalid argument");
f->arg[i] = (pointer)QTOS((Q)a);
break;
case A_str:
if ( !a || OID(a) != O_STR )
error("funargs_to_quote : invalid argument");
f->arg[i] = (pointer)BDY((STRING)a);
break;
case A_internal:
f->arg[i] = (pointer)a;
break;
case A_node:
if ( !a || OID(a) != O_LIST )
error("funargs_to_quote : invalid argument");
u0 = 0;
for ( w = BDY((LIST)a); w; w = NEXT(w) ) {
NEXTNODE(u0,u);
b = (QUOTE)BDY(w);
if ( !b || OID(b) != O_QUOTE )
error("funargs_to_quote : invalid argument");
BDY(u) = BDY(b);
}
if ( u0 ) NEXT(u) = 0;
f->arg[i] = (pointer)u0;
break;
default:
if ( !a || OID(a) != O_QUOTEARG ||
((QUOTEARG)a)->type != spec->type[i] )
error("funargs_to_quote : invalid argument");
f->arg[i] = BDY((QUOTEARG)a);
break;
}
}
MKQUOTE(*rp,f);
}
VL reordvars(VL vl0,NODE head)
{
VL vl,svl,tvl;
int i,j;
NODE n;
P t;
V *va;
V v;
for ( vl = 0, i = 0, n = head; n; n = NEXT(n), i++ ) {
NEXTVL(vl,tvl);
if ( !(t = (P)BDY(n)) || (OID(t) != O_P) )
error("reordvars : invalid argument");
VR(tvl) = VR(t);
}
va = (V *)ALLOCA(i*sizeof(V));
for ( j = 0, svl = vl; j < i; j++, svl = NEXT(svl) )
va[j] = VR(svl);
for ( svl = vl0; svl; svl = NEXT(svl) ) {
v = VR(svl);
for ( j = 0; j < i; j++ )
if ( v == va[j] )
break;
if ( j == i ) {
NEXTVL(vl,tvl);
VR(tvl) = v;
}
}
if ( vl )
NEXT(tvl) = 0;
return vl;
}
struct wtab {
V v;
int w;
};
struct wtab *qt_weight_tab;
VL qt_current_ord, qt_current_coef;
LIST qt_current_ord_obj,qt_current_coef_obj,qt_current_weight_obj;
LIST qt_current_weight_obj;
void Pqt_set_ord(NODE arg,LIST *rp)
{
NODE r0,r;
VL vl;
P v;
if ( !argc(arg) )
*rp = qt_current_ord_obj;
else if ( !ARG0(arg) ) {
qt_current_ord_obj = 0;
qt_current_ord = 0;
} else {
qt_current_ord = reordvars(CO,BDY((LIST)ARG0(arg)));
for ( r0 = 0, vl = qt_current_ord; vl; vl = NEXT(vl) ) {
NEXTNODE(r0,r); MKV(vl->v,v); BDY(r) = v;
}
if ( r0 ) NEXT(r) = 0;
MKLIST(*rp,r0);
qt_current_ord_obj = *rp;
}
}
void Pqt_set_weight(NODE arg,LIST *rp)
{
NODE n,pair;
int l,i;
struct wtab *tab;
if ( !argc(arg) )
*rp = qt_current_weight_obj;
else if ( !ARG0(arg) ) {
qt_current_weight_obj = 0;
qt_weight_tab = 0;
} else {
n = BDY((LIST)ARG0(arg));
l = length(n);
tab = qt_weight_tab = (struct wtab *)MALLOC((l+1)*sizeof(struct wtab));
for ( i = 0; i < l; i++, n = NEXT(n) ) {
pair = BDY((LIST)BDY(n));
tab[i].v = VR((P)ARG0(pair));
tab[i].w = QTOS((Q)ARG1(pair));
}
tab[i].v = 0;
qt_current_weight_obj = (LIST)ARG0(arg);
*rp = qt_current_weight_obj;
}
}
void Pqt_set_coef(NODE arg,LIST *rp)
{
NODE r0,r,n;
VL vl0,vl;
P v;
if ( !argc(arg) )
*rp = qt_current_coef_obj;
else if ( !ARG0(arg) ) {
qt_current_coef_obj = 0;
qt_current_coef = 0;
} else {
n = BDY((LIST)ARG0(arg));
for ( vl0 = 0, r0 = 0; n; n = NEXT(n) ) {
NEXTNODE(r0,r);
NEXTVL(vl0,vl);
vl->v = VR((P)BDY(n));
MKV(vl->v,v); BDY(r) = v;
}
if ( r0 ) NEXT(r) = 0;
if ( vl0 ) NEXT(vl) = 0;
qt_current_coef = vl0;
MKLIST(*rp,r0);
qt_current_coef_obj = *rp;
}
}
void Pqt_normalize(NODE arg,QUOTE *rp)
{
QUOTE q,r;
FNODE f;
int expand,ac;
ac = argc(arg);
if ( !ac ) error("qt_normalize : invalid argument");
q = (QUOTE)ARG0(arg);
if ( ac == 2 )
expand = QTOS((Q)ARG1(arg));
if ( !q || OID(q) != O_QUOTE )
*rp = q;
else {
f = fnode_normalize(BDY(q),expand);
MKQUOTE(r,f);
*rp = r;
}
}
NBP fnode_to_nbp(FNODE f);
void Pqt_to_nbp(NODE arg,NBP *rp)
{
QUOTE q;
FNODE f;
q = (QUOTE)ARG0(arg); f = (FNODE)BDY(q);
f = fnode_normalize(f,0);
*rp = fnode_to_nbp(f);
}
void Pshuffle_mul(NODE arg,NBP *rp)
{
NBP p1,p2;
p1 = (NBP)ARG0(arg);
p2 = (NBP)ARG1(arg);
shuffle_mulnbp(CO,p1,p2,rp);
}
void Pharmonic_mul(NODE arg,NBP *rp)
{
NBP p1,p2;
p1 = (NBP)ARG0(arg);
p2 = (NBP)ARG1(arg);
harmonic_mulnbp(CO,p1,p2,rp);
}
void Pnbp_hm(NODE arg, NBP *rp)
{
NBP p;
NODE n;
NBM m;
p = (NBP)ARG0(arg);
if ( !p ) *rp = 0;
else {
m = (NBM)BDY(BDY(p));
MKNODE(n,m,0);
MKNBP(*rp,n);
}
}
void Pnbp_ht(NODE arg, NBP *rp)
{
NBP p;
NODE n;
NBM m,m1;
p = (NBP)ARG0(arg);
if ( !p ) *rp = 0;
else {
m = (NBM)BDY(BDY(p));
NEWNBM(m1);
m1->d = m->d; m1->c = (P)ONE; m1->b = m->b;
MKNODE(n,m1,0);
MKNBP(*rp,n);
}
}
void Pnbp_hc(NODE arg, P *rp)
{
NBP p;
NBM m;
p = (NBP)ARG0(arg);
if ( !p ) *rp = 0;
else {
m = (NBM)BDY(BDY(p));
*rp = m->c;
}
}
void Pnbp_rest(NODE arg, NBP *rp)
{
NBP p;
NODE n;
p = (NBP)ARG0(arg);
if ( !p ) *rp = 0;
else {
n = BDY(p);
if ( !NEXT(n) ) *rp = 0;
else
MKNBP(*rp,NEXT(n));
}
}
void Pnbp_tm(NODE arg, NBP *rp)
{
NBP p;
NODE n;
NBM m;
p = (NBP)ARG0(arg);
if ( !p ) *rp = 0;
else {
for ( n = BDY(p); NEXT(n); n = NEXT(n) );
m = (NBM)BDY(n);
MKNODE(n,m,0);
MKNBP(*rp,n);
}
}
void Pnbp_tt(NODE arg, NBP *rp)
{
NBP p;
NODE n;
NBM m,m1;
p = (NBP)ARG0(arg);
if ( !p ) *rp = 0;
else {
for ( n = BDY(p); NEXT(n); n = NEXT(n) );
m = (NBM)BDY(n);
NEWNBM(m1);
m1->d = m->d; m1->c = (P)ONE; m1->b = m->b;
MKNODE(n,m1,0);
MKNBP(*rp,n);
}
}
void Pnbp_tc(NODE arg, P *rp)
{
NBP p;
NBM m;
NODE n;
p = (NBP)ARG0(arg);
if ( !p ) *rp = 0;
else {
for ( n = BDY(p); NEXT(n); n = NEXT(n) );
m = (NBM)BDY(n);
*rp = m->c;
}
}
void Pnbp_trest(NODE arg, NBP *rp)
{
NBP p;
NODE n,r,r0;
p = (NBP)ARG0(arg);
if ( !p ) *rp = 0;
else {
n = BDY(p);
for ( r0 = 0; NEXT(n); n = NEXT(n) ) {
NEXTNODE(r0,r);
BDY(r) = (pointer)BDY(n);
}
if ( r0 ) {
NEXT(r) = 0;
MKNBP(*rp,r0);
} else
*rp = 0;
}
}
void Pnbm_deg(NODE arg, Q *rp)
{
NBP p;
NBM m;
p = (NBP)ARG0(arg);
if ( !p )
STOQ(-1,*rp);
else {
m = (NBM)BDY(BDY(p));
STOQ(m->d,*rp);
}
}
void Pnbm_index(NODE arg, Q *rp)
{
NBP p;
NBM m;
unsigned int *b;
int d,i,r;
p = (NBP)ARG0(arg);
if ( !p )
STOQ(0,*rp);
else {
m = (NBM)BDY(BDY(p));
d = m->d;
if ( d > 32 )
error("nbm_index : weight too large");
b = m->b;
for ( r = 0, i = d-2; i > 0; i-- )
if ( !NBM_GET(b,i) ) r |= (1<<(d-2-i));
STOQ(r,*rp);
}
}
void Pnbm_hp_rest(NODE arg, LIST *rp)
{
NBP p,h,r;
NBM m,m1;
NODE n;
int *b,*b1;
int d,d1,v,i,j,k;
p = (NBP)ARG0(arg);
if ( !p )
MKLIST(*rp,0);
else {
m = (NBM)BDY(BDY(p));
b = m->b; d = m->d;
if ( !d )
MKLIST(*rp,0);
else {
v = NBM_GET(b,0);
for ( i = 1; i < d; i++ )
if ( NBM_GET(b,i) != v ) break;
NEWNBM(m1); NEWNBMBDY(m1,i);
b1 = m1->b; m1->d = i; m1->c = (P)ONE;
if ( v ) for ( j = 0; j < i; j++ ) NBM_SET(b1,j);
else for ( j = 0; j < i; j++ ) NBM_CLR(b1,j);
MKNODE(n,m1,0); MKNBP(h,n);
d1 = d-i;
NEWNBM(m1); NEWNBMBDY(m1,d1);
b1 = m1->b; m1->d = d1; m1->c = (P)ONE;
for ( j = 0, k = i; j < d1; j++, k++ )
if ( NBM_GET(b,k) ) NBM_SET(b1,j);
else NBM_CLR(b1,j);
MKNODE(n,m1,0); MKNBP(r,n);
n = mknode(2,h,r);
MKLIST(*rp,n);
}
}
}
void Pnbm_hxky(NODE arg, LIST *rp)
{
NBP p;
p = (NBP)ARG0(arg);
if ( !p )
*rp = 0;
else
separate_xky_nbm((NBM)BDY(BDY(p)),0,rp,0);
}
void Pnbm_xky_rest(NODE arg,NBP *rp)
{
NBP p;
p = (NBP)ARG0(arg);
if ( !p )
*rp = 0;
else
separate_xky_nbm((NBM)BDY(BDY(p)),0,0,rp);
}
void Pnbm_hv(NODE arg, NBP *rp)
{
NBP p;
p = (NBP)ARG0(arg);
if ( !p )
*rp = 0;
else
separate_nbm((NBM)BDY(BDY(p)),0,rp,0);
}
void Pnbm_rest(NODE arg, NBP *rp)
{
NBP p;
p = (NBP)ARG0(arg);
if ( !p )
*rp = 0;
else
separate_nbm((NBM)BDY(BDY(p)),0,0,rp);
}
void Pnbm_tv(NODE arg, NBP *rp)
{
NBP p;
p = (NBP)ARG0(arg);
if ( !p )
*rp = 0;
else
separate_tail_nbm((NBM)BDY(BDY(p)),0,0,rp);
}
void Pnbm_trest(NODE arg, NBP *rp)
{
NBP p;
p = (NBP)ARG0(arg);
if ( !p )
*rp = 0;
else
separate_tail_nbm((NBM)BDY(BDY(p)),0,rp,0);
}
NBP fnode_to_nbp(FNODE f)
{
Q r;
int n,i;
NBM m;
V v;
NBP u,u1,u2;
NODE t,b;
if ( f->id == I_FORMULA ) {
r = eval(f);
NEWNBM(m);
if ( OID(r) == O_N ) {
m->d = 0; m->c = (P)r; m->b = 0;
} else {
v = VR((P)r);
m->d = 1; m->c = (P)ONE; NEWNBMBDY(m,1);
if ( !strcmp(NAME(v),"x") ) NBM_SET(m->b,0);
else NBM_CLR(m->b,0);
}
MKNODE(b,m,0); MKNBP(u,b);
return u;
} else if ( IS_NARYADD(f) ) {
t = (NODE)FA1(f); u = fnode_to_nbp((FNODE)BDY(t));
for ( t = NEXT(t); t; t = NEXT(t) ) {
u1 = fnode_to_nbp((FNODE)BDY(t));
addnbp(CO,u,u1,&u2); u = u2;
}
return u;
} else if ( IS_NARYMUL(f) ) {
t = (NODE)FA1(f); u = fnode_to_nbp((FNODE)BDY(t));
for ( t = NEXT(t); t; t = NEXT(t) ) {
u1 = fnode_to_nbp((FNODE)BDY(t));
mulnbp(CO,u,u1,&u2); u = u2;
}
return u;
} else if ( IS_BINARYPWR(f) ) {
u = fnode_to_nbp((FNODE)FA1(f));
r = eval((FNODE)FA2(f));
pwrnbp(CO,u,r,&u1);
return u1;
}
}
void Pnqt_weight(NODE arg,Q *rp)
{
QUOTE q;
FNODE f;
int w;
q = (QUOTE)ARG0(arg); f = (FNODE)BDY(q);
f = fnode_normalize(f,0);
w = nfnode_weight(qt_weight_tab,f);
STOQ(w,*rp);
}
void Pnqt_comp(NODE arg,Q *rp)
{
QUOTE q1,q2;
FNODE f1,f2;
int r;
q1 = (QUOTE)ARG0(arg); f1 = (FNODE)BDY(q1);
q2 = (QUOTE)ARG1(arg); f2 = (FNODE)BDY(q2);
f1 = fnode_normalize(f1,0);
f2 = fnode_normalize(f2,0);
r = nfnode_comp(f1,f2);
STOQ(r,*rp);
}
int fnode_is_var(FNODE f)
{
Obj obj;
VL vl,t,s;
DCP dc;
if ( fnode_is_coef(f) ) return 0;
switch ( f->id ) {
case I_PAREN:
return fnode_is_var(FA0(f));
case I_FORMULA:
obj = FA0(f);
if ( obj && OID(obj) == O_P ) {
dc = DC((P)obj);
if ( !cmpq(DEG(dc),ONE) && !NEXT(dc)
&& !arf_comp(CO,(Obj)COEF(dc),(Obj)ONE) ) return 1;
else return 0;
} else return 0;
default:
return 0;
}
}
int fnode_is_coef(FNODE f)
{
Obj obj;
VL vl,t,s;
switch ( f->id ) {
case I_MINUS: case I_PAREN:
return fnode_is_coef(FA0(f));
case I_FORMULA:
obj = FA0(f);
if ( !obj ) return 1;
else if ( OID(obj) == O_QUOTE )
return fnode_is_coef(BDY((QUOTE)obj));
else if ( NUM(obj) ) return 1;
else if ( OID(obj) == O_P || OID(obj) == O_R) {
get_vars_recursive(obj,&vl);
for ( t = vl; t; t = NEXT(t) ) {
if ( t->v->attr == (pointer)V_PF ) continue;
for ( s = qt_current_coef; s; s = NEXT(s) )
if ( t->v == s->v ) break;
if ( !s )
return 0;
}
return 1;
} else return 0;
case I_BOP:
return fnode_is_coef(FA1(f)) && fnode_is_coef(FA2(f));
default:
return 0;
}
}
int fnode_is_number(FNODE f)
{
Obj obj;
switch ( f->id ) {
case I_MINUS: case I_PAREN:
return fnode_is_number(FA0(f));
case I_FORMULA:
obj = FA0(f);
if ( !obj ) return 1;
else if ( OID(obj) == O_QUOTE )
return fnode_is_number(BDY((QUOTE)obj));
else if ( NUM(obj) ) return 1;
else return 0;
case I_BOP:
return fnode_is_number(FA1(f)) && fnode_is_number(FA2(f));
default:
return 0;
}
}
int fnode_is_rational(FNODE f)
{
Obj obj;
switch ( f->id ) {
case I_MINUS: case I_PAREN:
return fnode_is_number(FA0(f));
case I_FORMULA:
obj = FA0(f);
if ( !obj ) return 1;
else if ( OID(obj) == O_QUOTE )
return fnode_is_rational(BDY((QUOTE)obj));
else if ( NUM(obj) && RATN(obj) ) return 1;
else return 0;
case I_BOP:
if ( !strcmp(((ARF)FA0(f))->name,"^") )
return fnode_is_rational(FA1(f)) && fnode_is_integer(FA2(f));
else
return fnode_is_rational(FA1(f)) && fnode_is_rational(FA2(f));
default:
return 0;
}
}
int fnode_is_integer(FNODE f)
{
Obj obj;
switch ( f->id ) {
case I_MINUS: case I_PAREN:
return fnode_is_integer(FA0(f));
case I_FORMULA:
obj = FA0(f);
if ( !obj ) return 1;
else if ( OID(obj) == O_QUOTE )
return fnode_is_integer(BDY((QUOTE)obj));
else if ( INT(obj)) return 1;
else return 0;
case I_BOP:
switch ( ((ARF)FA0(f))->name[0] ) {
case '^':
return fnode_is_integer(FA1(f))
&& fnode_is_nonnegative_integer(FA2(f));
case '/':
return fnode_is_integer(FA1(f)) &&
( fnode_is_one(FA2(f)) || fnode_is_minusone(FA2(f)) );
default:
return fnode_is_integer(FA1(f)) && fnode_is_integer(FA2(f));
}
break;
default:
return 0;
}
}
int fnode_is_nonnegative_integer(FNODE f)
{
Q n;
n = eval(f);
if ( !n || (INT(n) && SGN(n) > 0) ) return 1;
else return 0;
}
int fnode_is_one(FNODE f)
{
Q n;
n = eval(f);
if ( UNIQ(n) ) return 1;
else return 0;
}
int fnode_is_minusone(FNODE f)
{
Q n;
n = eval(f);
if ( MUNIQ(n) ) return 1;
else return 0;
}
int fnode_is_dependent(FNODE f,V v)
{
Obj obj;
FNODE arg;
NODE t;
switch ( f->id ) {
case I_MINUS: case I_PAREN:
return fnode_is_dependent(FA0(f),v);
case I_FORMULA:
obj = FA0(f);
if ( !obj ) return 0;
else if ( OID(obj) == O_QUOTE )
return fnode_is_dependent(BDY((QUOTE)obj),v);
else if ( obj_is_dependent(obj,v) ) return 1;
else return 0;
case I_BOP:
return fnode_is_dependent(FA1(f),v) || fnode_is_dependent(FA2(f),v);
case I_FUNC:
arg = (FNODE)FA1(f);
for ( t = FA0(arg); t; t = NEXT(t) )
if ( fnode_is_dependent(BDY(t),v) ) return 1;
return 0;
default:
return 0;
}
}
FNODE fnode_normalize(FNODE f,int expand)
{
FNODE a1,a2,mone,r,b2;
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:
r = fnode_normalize(FA0(f),expand);
break;
case I_MINUS:
r = nfnode_mul_coef((Obj)q,
fnode_normalize(FA0(f),expand),expand);
break;
case I_BOP:
/* arf fnode fnode */
a1 = fnode_normalize(FA1(f),expand);
a2 = fnode_normalize(FA2(f),expand);
switch ( OPNAME(f) ) {
case '+':
r = nfnode_add(a1,a2,expand);
break;
case '-':
a2 = nfnode_mul_coef((Obj)q,a2,expand);
r = nfnode_add(a1,a2,expand);
break;
case '*':
r = nfnode_mul(a1,a2,expand);
break;
case '/':
a2 = nfnode_pwr(a2,mone,expand);
r = nfnode_mul(a1,a2,expand);
break;
case '^':
r = nfnode_pwr(a1,a2,expand);
break;
default:
r = mkfnode(3,I_BOP,FA0(f),a1,a2);
break;
}
break;
case I_NARYOP:
switch ( OPNAME(f) ) {
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 = nfnode_add(r,a1,expand);
}
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 = nfnode_mul(r,a1,expand);
}
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)
{
fid_spec_p spec;
FNODE r;
int i,n;
NODE t,t0,s;
get_fid_spec(f->id,&spec);
for ( n = 0; spec->type[n] != A_end; n++ );
NEWFNODE(r,n); r->id = f->id;
for ( i = 0; i < n; i++ ) {
switch ( spec->type[i] ) {
case A_fnode:
r->arg[i] = func(f->arg[i],expand);
break;
case A_node:
s = (NODE)f->arg[i];
for ( t0 = 0; s; s = NEXT(s) ) {
NEXTNODE(t0,t);
BDY(t) = (pointer)func((FNODE)BDY(s),expand);
}
if ( t0 ) NEXT(t) = 0;
r->arg[i] = t0;
break;
default:
r->arg[i] = f->arg[i];
break;
}
}
return r;
}
FNODE nfnode_add(FNODE f1,FNODE f2,int expand)
{
NODE n1,n2,r0,r;
FNODE b1,b2;
int s;
Obj c1,c2,c;
if ( IS_ZERO(f1) ) return f2;
else if ( IS_ZERO(f2) ) return f1;
f1 = to_naryadd(f1); f2 = to_naryadd(f2);
n1 = (NODE)FA1(f1); n2 = (NODE)FA1(f2);
r0 = 0;
while ( n1 && n2 ) {
fnode_coef_body(BDY(n1),&c1,&b1); fnode_coef_body(BDY(n2),&c2,&b2);
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 {
arf_add(CO,c1,c2,&c);
if ( c ) {
NEXTNODE(r0,r); BDY(r) = nfnode_mul_coef(c,b1,expand);
}
n1 = NEXT(n1); n2 = NEXT(n2);
}
}
if ( n1 )
if ( r0 ) NEXT(r) = n1;
else r0 = n1;
else if ( n2 )
if ( r0 ) NEXT(r) = n2;
else r0 = n2;
else if ( r0 )
NEXT(r) = 0;
return fnode_node_to_nary(addfs,r0);
}
FNODE fnode_node_to_nary(ARF op,NODE n)
{
if ( !n ) {
if ( op->name[0] == '+' )
return mkfnode(1,I_FORMULA,0);
else
return mkfnode(1,I_FORMULA,ONE);
} else if ( !NEXT(n) ) return BDY(n);
else return mkfnode(2,I_NARYOP,op,n);
}
FNODE nfnode_mul(FNODE f1,FNODE f2,int expand)
{
NODE n1,n2,r0,r,r1;
FNODE b1,b2,e1,e2,cc,t,t1;
FNODE *m;
int s;
Obj c1,c2,c,e;
int l1,l,i,j;
if ( IS_ZERO(f1) || IS_ZERO(f2) ) return mkfnode(1,I_FORMULA,0);
else if ( fnode_is_coef(f1) )
return nfnode_mul_coef((Obj)eval(f1),f2,expand);
else if ( fnode_is_coef(f2) )
return nfnode_mul_coef((Obj)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 = nfnode_mul(BDY(n1),f2,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 = nfnode_mul(f1,BDY(n2),expand);
t = nfnode_add(t,t1,expand);
}
return t;
}
fnode_coef_body(f1,&c1,&b1); fnode_coef_body(f2,&c2,&b2);
arf_mul(CO,c1,c2,&c);
if ( !c ) return mkfnode(1,I_FORMULA,0);
n1 = (NODE)FA1(to_narymul(b1)); n2 = (NODE)FA1(to_narymul(b2));
l1 = length(n1); l = l1+length(n2);
m = (FNODE *)ALLOCA(l*sizeof(FNODE));
for ( r = n1, i = 0; i < l1; r = NEXT(r), i++ ) m[i] = BDY(r);
for ( r = n2; r; r = NEXT(r) ) {
if ( i == 0 )
m[i++] = BDY(r);
else {
fnode_base_exp(m[i-1],&b1,&e1); fnode_base_exp(BDY(r),&b2,&e2);
if ( compfnode(b1,b2) ) break;
arf_add(CO,eval(e1),eval(e2),&e);
if ( !e ) i--;
else if ( expand == 2 ) {
if ( INT(e) && SGN((Q)e) < 0 ) {
t1 = mkfnode(3,I_BOP,pwrfs,b1,mkfnode(1,I_FORMULA,e));
/* r=(r0|rest)->(r0,t1|rest) */
t = BDY(r);
MKNODE(r1,t1,NEXT(r));
MKNODE(r,t,r1);
i--;
} else
m[i++] = BDY(r);
} else if ( UNIQ(e) )
m[i-1] = b1;
else
m[i-1] = mkfnode(3,I_BOP,pwrfs,b1,mkfnode(1,I_FORMULA,e));
}
}
for ( j = i-1; j >= 0; j-- ) {
MKNODE(r1,m[j],r); r = r1;
}
if ( !UNIQ(c) ) {
cc = mkfnode(1,I_FORMULA,c); MKNODE(r1,cc,r); r = r1;
}
return fnode_node_to_nary(mulfs,r);
}
FNODE nfnode_pwr(FNODE f1,FNODE f2,int expand)
{
FNODE b,b1,e1,e,cc,r,mf2,mone,inv;
Obj c,c1;
Num nf2;
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_coef(f1) ) {
if ( fnode_is_integer(f2) ) {
if ( fnode_is_one(f2) ) return f1;
else {
arf_pwr(CO,eval(f1),(Obj)eval(f2),&c);
return mkfnode(1,I_FORMULA,c);
}
} else {
f1 = mkfnode(1,I_FORMULA,eval(f1));
return mkfnode(3,I_BOP,pwrfs,f1,f2);
}
} else if ( IS_BINARYPWR(f1) ) {
b1 = FA1(f1); e1 = FA2(f1);
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 ( expand && IS_NARYMUL(f1) && fnode_is_number(f2)
&& fnode_is_integer(f2) ) {
fnode_coef_body(f1,&c1,&b1);
nf2 = (Num)eval(f2);
arf_pwr(CO,c1,(Obj)nf2,&c);
ee = QTOS((Q)nf2);
cc = mkfnode(1,I_FORMULA,c);
if ( fnode_is_nonnegative_integer(f2) )
b = fnode_expand_pwr(b1,ee,expand);
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_nary(mulfs,t0);
b = fnode_expand_pwr(b1,-ee,expand);
}
if ( fnode_is_one(cc) )
return b;
else
return fnode_node_to_nary(mulfs,mknode(2,cc,b));
} else if ( expand && fnode_is_integer(f2)
&& fnode_is_nonnegative_integer(f2) ) {
q = (Q)eval(f2);
if ( PL(NM(q)) > 1 ) error("nfnode_pwr : exponent too large");
return fnode_expand_pwr(f1,QTOS(q),expand);
} else
return mkfnode(3,I_BOP,pwrfs,f1,f2);
}
FNODE fnode_expand_pwr(FNODE f,int n,int expand)
{
int n1,i;
FNODE f1,f2,fn;
Q q;
if ( !n ) return mkfnode(1,I_FORMULA,ONE);
else if ( IS_ZERO(f) ) return mkfnode(1,I_FORMULA,0);
else if ( n == 1 ) return f;
else {
switch ( expand ) {
case 1:
n1 = n/2;
f1 = fnode_expand_pwr(f,n1,expand);
f2 = nfnode_mul(f1,f1,expand);
if ( n%2 ) f2 = nfnode_mul(f2,f,1);
return f2;
case 2:
for ( i = 1, f1 = f; i < n; i++ )
f1 = nfnode_mul(f1,f,expand);
return f1;
case 0: default:
STOQ(n,q);
fn = mkfnode(1,I_FORMULA,q);
return mkfnode(3,I_BOP,pwrfs,f,fn);
}
}
}
/* f = b^e */
void fnode_base_exp(FNODE f,FNODE *bp,FNODE *ep)
{
if ( IS_BINARYPWR(f) ) {
*bp = FA1(f); *ep = FA2(f);
} else {
*bp = f; *ep = mkfnode(1,I_FORMULA,ONE);
}
}
FNODE to_naryadd(FNODE f)
{
FNODE r;
NODE n;
if ( IS_NARYADD(f) ) return f;
NEWFNODE(r,2); r->id = I_NARYOP;
FA0(r) = addfs; MKNODE(n,f,0); FA1(r) = n;
return r;
}
FNODE to_narymul(FNODE f)
{
FNODE r;
NODE n;
if ( IS_NARYMUL(f) ) return f;
NEWFNODE(r,2); r->id = I_NARYOP;
FA0(r) = mulfs; MKNODE(n,f,0); FA1(r) = n;
return r;
}
FNODE nfnode_mul_coef(Obj c,FNODE f,int expand)
{
FNODE b1,cc;
Obj c1,c2;
NODE n,r,r0;
if ( !c )
return mkfnode(I_FORMULA,0);
else {
fnode_coef_body(f,&c1,&b1);
arf_mul(CO,c,c1,&c2);
if ( UNIQ(c2) ) return b1;
else {
cc = mkfnode(1,I_FORMULA,c2);
if ( fnode_is_number(b1) ) {
if ( !fnode_is_one(b1) )
error("nfnode_mul_coef : cannot happen");
else
return cc;
} else if ( IS_NARYMUL(b1) ) {
MKNODE(n,cc,FA1(b1));
return fnode_node_to_nary(mulfs,n);
} else if ( expand && IS_NARYADD(b1) ) {
for ( r0 = 0, n = (NODE)FA1(b1); n; n = NEXT(n) ) {
NEXTNODE(r0,r);
BDY(r) = nfnode_mul_coef(c2,BDY(n),expand);
}
if ( r0 ) NEXT(r) = 0;
return fnode_node_to_nary(addfs,r0);
} else
return fnode_node_to_nary(mulfs,mknode(2,cc,b1));
}
}
}
void fnode_coef_body(FNODE f,Obj *cp,FNODE *bp)
{
FNODE c;
if ( fnode_is_coef(f) ) {
*cp = (Obj)eval(f); *bp = mkfnode(1,I_FORMULA,ONE);
} else if ( IS_NARYMUL(f) ) {
c=(FNODE)BDY((NODE)FA1(f));
if ( fnode_is_coef(c) ) {
*cp = (Obj)eval(c);
*bp = fnode_node_to_nary(mulfs,NEXT((NODE)FA1(f)));
} else {
*cp = (Obj)ONE; *bp = f;
}
} else {
*cp = (Obj)ONE; *bp = f;
}
}
int nfnode_weight(struct wtab *tab,FNODE f)
{
NODE n;
int w,w1;
int i;
Q a2;
V v;
switch ( f->id ) {
case I_FORMULA:
if ( fnode_is_coef(f) ) return 0;
else if ( fnode_is_var(f) ) {
if ( !tab ) return 0;
v = VR((P)FA0(f));
for ( i = 0; tab[i].v; i++ )
if ( v == tab[i].v ) return tab[i].w;
return 0;
} else return 0;
/* XXX */
case I_PVAR: return 1;
/* XXX */
case I_FUNC: I_FUNC: I_FUNC_QARG:
/* w(f) = 1 */
/* w(f(a1,...,an)=w(a1)+...+w(an) */
n = FA0((FNODE)FA1(f));
for ( w = 0; n; n = NEXT(n) )
w += nfnode_weight(tab,BDY(n));
return w;
case I_NARYOP:
n = (NODE)FA1(f);
if ( IS_NARYADD(f) )
for ( w = nfnode_weight(tab,BDY(n)),
n = NEXT(n); n; n = NEXT(n) ) {
w1 = nfnode_weight(tab,BDY(n));
w = MAX(w,w1);
}
else
for ( w = 0; n; n = NEXT(n) )
w += nfnode_weight(tab,BDY(n));
return w;
case I_BOP:
/* must be binary power */
/* XXX w(2^x)=0 ? */
if ( fnode_is_rational(FA2(f)) ) {
a2 = (Q)eval(FA2(f));
w = QTOS(a2);
} else
w = nfnode_weight(tab,FA2(f));
return nfnode_weight(tab,FA1(f))*w;
default:
error("nfnode_weight : not_implemented");
}
}
int nfnode_comp(FNODE f1,FNODE f2)
{
int w1,w2;
if ( qt_weight_tab ) {
w1 = nfnode_weight(qt_weight_tab,f1);
w2 = nfnode_weight(qt_weight_tab,f2);
if ( w1 > w2 ) return 1;
if ( w1 < w2 ) return -1;
}
return nfnode_comp_lex(f1,f2);
}
int nfnode_comp_lex(FNODE f1,FNODE f2)
{
NODE n1,n2;
int r,i1,i2,ret;
char *nm1,*nm2;
FNODE b1,b2,e1,e2,g,a1,a2,fn1,fn2,h1,h2;
Num ee,ee1;
Obj c1,c2;
int w1,w2;
if ( IS_NARYADD(f1) || IS_NARYADD(f2) ) {
f1 = to_naryadd(f1); f2 = to_naryadd(f2);
n1 = (NODE)FA1(f1); n2 = (NODE)FA1(f2);
for ( ; n1 && n2; n1 = NEXT(n1), n2 = NEXT(n2) ) {
r = nfnode_comp_lex(BDY(n1),BDY(n2));
if ( r ) return r;
}
if ( !n1 && !n2 ) return 0;
h1 = n1 ? (FNODE)BDY(n1) : mkfnode(1,I_FORMULA,0);
h2 = n2 ? (FNODE)BDY(n2) : mkfnode(1,I_FORMULA,0);
return nfnode_comp_lex(h1,h2);
}
if ( IS_NARYMUL(f1) || IS_NARYMUL(f2) ) {
fnode_coef_body(f1,&c1,&b1);
fnode_coef_body(f2,&c2,&b2);
if ( !compfnode(b1,b2) ) return arf_comp(CO,c1,c2);
b1 = to_narymul(b1); b2 = to_narymul(b2);
n1 = (NODE)FA1(b1); n2 = (NODE)FA1(b2);
for ( ; n1 && n2; n1 = NEXT(n1), n2 = NEXT(n2) ) {
r = nfnode_comp_lex(BDY(n1),BDY(n2));
if ( r ) return r;
}
if ( !n1 && !n2 ) return 0;
h1 = n1 ? (FNODE)BDY(n1) : mkfnode(1,I_FORMULA,ONE);
h2 = n2 ? (FNODE)BDY(n2) : mkfnode(1,I_FORMULA,ONE);
return nfnode_comp_lex(h1,h2);
}
if ( IS_BINARYPWR(f1) || IS_BINARYPWR(f2) ) {
fnode_base_exp(f1,&b1,&e1);
fnode_base_exp(f2,&b2,&e2);
if ( r = nfnode_comp_lex(b1,b2) ) {
if ( r > 0 )
return nfnode_comp_lex(e1,mkfnode(1,I_FORMULA,0));
else if ( r < 0 )
return nfnode_comp_lex(mkfnode(1,I_FORMULA,0),e2);
} else return nfnode_comp_lex(e1,e2);
}
/* now, IDs of f1 and f2 must be I_FORMULA, I_FUNC, I_IFUNC or I_PVAR */
/* I_IFUNC > I_PVAR > I_FUNC=I_FUNC_QARG > I_FORMULA */
switch ( f1->id ) {
case I_FORMULA:
switch ( f2->id ) {
case I_FORMULA:
return arf_comp(qt_current_ord?qt_current_ord:CO,FA0(f1),FA0(f2));
case I_FUNC: case I_IFUNC: case I_PVAR:
return -1;
default:
error("nfnode_comp_lex : undefined");
}
break;
case I_FUNC: case I_FUNC_QARG:
switch ( f2->id ) {
case I_FORMULA:
return 1;
case I_PVAR: case I_IFUNC:
return -1;
case I_FUNC: case I_FUNC_QARG:
nm1 = ((FUNC)FA0(f1))->name; nm2 = ((FUNC)FA0(f2))->name;
r = strcmp(nm1,nm2);
if ( r > 0 ) return 1;
else if ( r < 0 ) return -1;
else {
/* compare args */
n1 = FA0((FNODE)FA1(f1)); n2 = FA0((FNODE)FA1(f2));
while ( n1 && n2 )
if ( r = nfnode_comp_lex(BDY(n1),BDY(n2)) ) return r;
else {
n1 = NEXT(n1); n2 = NEXT(n2);
}
return n1?1:(n2?-1:0);
}
break;
default:
error("nfnode_comp_lex : undefined");
}
case I_PVAR:
switch ( f2->id ) {
case I_FORMULA: case I_FUNC: case I_FUNC_QARG:
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("nfnode_comp_lex : undefined");
}
break;
case I_IFUNC:
switch ( f2->id ) {
case I_FORMULA: case I_FUNC: case I_FUNC_QARG: 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_lex(BDY(n1),BDY(n2)) ) return r;
else {
n1 = NEXT(n1); n2 = NEXT(n2);
}
return n1?1:(n2?-1:0);
}
break;
default:
error("nfnode_comp_lex : undefined");
}
break;
default:
error("nfnode_comp_lex : undefined");
}
}
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;
if ( !pat )
if ( !f ) {
*rp = 0;
return 1;
} else
return 0;
else if ( !f )
return 0;
switch ( pat->id ) {
case I_PVAR:
/* [[pat,f]] */
*rp = mknode(1,mknode(2,(int)FA0(pat),f));
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,0);
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,0);
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_nary(addfs,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_nary(addfs,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 0;
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_nary(mulfs,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 0;
else {
for ( k = 0, t = a; k <= i; k++, t = NEXT(t) );
return fnode_node_to_nary(mulfs,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,0);
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,0);
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,0);
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 ( fi < pi ) continue;
if ( nfnode_match(BDY(s),pivot,&m) ) {
fleft = fnode_left_narymul(f,fi);
pleft1 = rewrite_fnode(pleft,m,0);
if ( nfnode_match(fleft,pleft1,&m1) ) {
m = append_node(m1,m);
fright = fnode_right_narymul(f,fi);
pright1 = rewrite_fnode(pright,m,0);
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");
}
}