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source: git/libpolys/coeffs/rmodulo2m.cc @ 0461f0

spielwiese

Last change on this file since 0461f0 was 44d5ad, checked in by Frank Seelisch <seelisch@…>, 13 years ago
added documentation in coeffs.h
Property mode set to `100644`
File size: 17.2 KB

Line
1	/****************************************
2	* Computer Algebra System SINGULAR *
3	****************************************/
4	/* $Id$ */
5	/*
6	* ABSTRACT: numbers modulo 2^m
7	*/
8
9	#include "config.h"
10	#include <misc/auxiliary.h>
11
12	#ifdef HAVE_RINGS
13
14	#include <misc/mylimits.h>
15	#include <coeffs/coeffs.h>
16	#include <reporter/reporter.h>
17	#include <omalloc/omalloc.h>
18	#include <coeffs/numbers.h>
19	#include <coeffs/longrat.h>
20	#include <coeffs/mpr_complex.h>
21	#include <coeffs/rmodulo2m.h>
22	#include "si_gmp.h"
23
24	#include <string.h>
25
26	/// Our Type!
27	static const n_coeffType ID = n_Z2m;
28
29	extern omBin gmp_nrz_bin; /* init in rintegers*/
30
31	void nr2mCoeffWrite (const coeffs r)
32	{
33	Print("// Z/2^%lu\n", r->modExponent);
34	}
35
36	BOOLEAN nr2mCoeffIsEqual(const coeffs r, n_coeffType n, void * p)
37	{
38	if (n==n_Z2m)
39	{
40	int m=(int)(long)(p);
41	unsigned long mm=r->mod2mMask;
42	if ((mm>>m)==1L) return TRUE;
43	}
44	return FALSE;
45	}
46	/* for initializing function pointers */
47	BOOLEAN nr2mInitChar (coeffs r, void* p)
48	{
49	assume( getCoeffType(r) == ID );
50	nr2mInitExp((int)(long)(p), r);
51	r->cfKillChar = ndKillChar; /* dummy*/
52	r->nCoeffIsEqual = nr2mCoeffIsEqual;
53
54	r->ringtype = 1;
55
56	/* next cast may yield an overflow as mod2mMask is an unsigned long */
57	r->ch = (int)r->mod2mMask + 1;
58
59	r->cfInit = nr2mInit;
60	r->cfCopy = ndCopy;
61	r->cfInt = nr2mInt;
62	r->cfAdd = nr2mAdd;
63	r->cfSub = nr2mSub;
64	r->cfMult = nr2mMult;
65	r->cfDiv = nr2mDiv;
66	r->cfIntDiv = nr2mIntDiv;
67	r->cfIntMod = nr2mMod;
68	r->cfExactDiv = nr2mDiv;
69	r->cfNeg = nr2mNeg;
70	r->cfInvers = nr2mInvers;
71	r->cfDivBy = nr2mDivBy;
72	r->cfDivComp = nr2mDivComp;
73	r->cfGreater = nr2mGreater;
74	r->cfEqual = nr2mEqual;
75	r->cfIsZero = nr2mIsZero;
76	r->cfIsOne = nr2mIsOne;
77	r->cfIsMOne = nr2mIsMOne;
78	r->cfGreaterZero = nr2mGreaterZero;
79	r->cfWrite = nr2mWrite;
80	r->cfRead = nr2mRead;
81	r->cfPower = nr2mPower;
82	r->cfSetMap = nr2mSetMap;
83	r->cfNormalize = ndNormalize;
84	r->cfLcm = nr2mLcm;
85	r->cfGcd = nr2mGcd;
86	r->cfIsUnit = nr2mIsUnit;
87	r->cfGetUnit = nr2mGetUnit;
88	r->cfExtGcd = nr2mExtGcd;
89	r->cfName = ndName;
90	r->cfCoeffWrite = nr2mCoeffWrite;
91	#ifdef LDEBUG
92	r->cfDBTest = nr2mDBTest;
93	#endif
94	r->has_simple_Alloc=TRUE;
95	return FALSE;
96	}
97
98	/*
99	* Multiply two numbers
100	*/
101	number nr2mMult(number a, number b, const coeffs r)
102	{
103	if (((NATNUMBER)a == 0) \|\| ((NATNUMBER)b == 0))
104	return (number)0;
105	else
106	return nr2mMultM(a, b, r);
107	}
108
109	/*
110	* Give the smallest k, such that a * x = k = b * y has a solution
111	*/
112	number nr2mLcm(number a, number b, const coeffs)
113	{
114	NATNUMBER res = 0;
115	if ((NATNUMBER)a == 0) a = (number) 1;
116	if ((NATNUMBER)b == 0) b = (number) 1;
117	while ((NATNUMBER)a % 2 == 0)
118	{
119	a = (number)((NATNUMBER)a / 2);
120	if ((NATNUMBER)b % 2 == 0) b = (number)((NATNUMBER)b / 2);
121	res++;
122	}
123	while ((NATNUMBER)b % 2 == 0)
124	{
125	b = (number)((NATNUMBER)b / 2);
126	res++;
127	}
128	return (number)(1L << res); // (2**res)
129	}
130
131	/*
132	* Give the largest k, such that a = x * k, b = y * k has
133	* a solution.
134	*/
135	number nr2mGcd(number a, number b, const coeffs)
136	{
137	NATNUMBER res = 0;
138	if ((NATNUMBER)a == 0 && (NATNUMBER)b == 0) return (number)1;
139	while ((NATNUMBER)a % 2 == 0 && (NATNUMBER)b % 2 == 0)
140	{
141	a = (number)((NATNUMBER)a / 2);
142	b = (number)((NATNUMBER)b / 2);
143	res++;
144	}
145	// if ((NATNUMBER)b % 2 == 0)
146	// {
147	// return (number)((1L << res)); // * (NATNUMBER) a); // (2*res)a a is a unit
148	// }
149	// else
150	// {
151	return (number)((1L << res)); // * (NATNUMBER) b); // (2*res)b b is a unit
152	// }
153	}
154
155	/*
156	* Give the largest k, such that a = x * k, b = y * k has
157	* a solution.
158	*/
159	number nr2mExtGcd(number a, number b, number s, number t, const coeffs r)
160	{
161	NATNUMBER res = 0;
162	if ((NATNUMBER)a == 0 && (NATNUMBER)b == 0) return (number)1;
163	while ((NATNUMBER)a % 2 == 0 && (NATNUMBER)b % 2 == 0)
164	{
165	a = (number)((NATNUMBER)a / 2);
166	b = (number)((NATNUMBER)b / 2);
167	res++;
168	}
169	if ((NATNUMBER)b % 2 == 0)
170	{
171	*t = NULL;
172	*s = nr2mInvers(a,r);
173	return (number)((1L << res)); // * (NATNUMBER) a); // (2*res)a a is a unit
174	}
175	else
176	{
177	*s = NULL;
178	*t = nr2mInvers(b,r);
179	return (number)((1L << res)); // * (NATNUMBER) b); // (2*res)b b is a unit
180	}
181	}
182
183	void nr2mPower(number a, int i, number * result, const coeffs r)
184	{
185	if (i == 0)
186	{
187	(NATNUMBER )result = 1;
188	}
189	else if (i == 1)
190	{
191	*result = a;
192	}
193	else
194	{
195	nr2mPower(a, i-1, result, r);
196	result = nr2mMultM(a, result, r);
197	}
198	}
199
200	/*
201	* create a number from int
202	*/
203	number nr2mInit(int i, const coeffs r)
204	{
205	if (i == 0) return (number)(NATNUMBER)i;
206
207	long ii = i;
208	NATNUMBER j = (NATNUMBER)1;
209	if (ii < 0) { j = r->mod2mMask; ii = -ii; }
210	NATNUMBER k = (NATNUMBER)ii;
211	k = k & r->mod2mMask;
212	/* now we have: i = j * k mod 2^m */
213	return (number)nr2mMult((number)j, (number)k, r);
214	}
215
216	/*
217	* convert a number to an int in ]-k/2 .. k/2],
218	* where k = 2^m; i.e., an int in ]-2^(m-1) .. 2^(m-1)];
219	* note that the code computes a long which will then
220	* automatically casted to int
221	*/
222	int nr2mInt(number &n, const coeffs r)
223	{
224	NATNUMBER nn = (unsigned long)(NATNUMBER)n & r->mod2mMask;
225	unsigned long l = r->mod2mMask >> 1; l++; /* now: l = 2^(m-1) */
226	if ((NATNUMBER)nn > l)
227	return (int)((NATNUMBER)nn - r->mod2mMask - 1);
228	else
229	return (int)((NATNUMBER)nn);
230	}
231
232	number nr2mAdd(number a, number b, const coeffs r)
233	{
234	return nr2mAddM(a, b, r);
235	}
236
237	number nr2mSub(number a, number b, const coeffs r)
238	{
239	return nr2mSubM(a, b, r);
240	}
241
242	BOOLEAN nr2mIsUnit(number a, const coeffs)
243	{
244	return ((NATNUMBER)a % 2 == 1);
245	}
246
247	number nr2mGetUnit(number k, const coeffs)
248	{
249	if (k == NULL) return (number)1;
250	NATNUMBER erg = (NATNUMBER)k;
251	while (erg % 2 == 0) erg = erg / 2;
252	return (number)erg;
253	}
254
255	BOOLEAN nr2mIsZero(number a, const coeffs)
256	{
257	return 0 == (NATNUMBER)a;
258	}
259
260	BOOLEAN nr2mIsOne(number a, const coeffs)
261	{
262	return 1 == (NATNUMBER)a;
263	}
264
265	BOOLEAN nr2mIsMOne(number a, const coeffs r)
266	{
267	return (r->mod2mMask == (NATNUMBER)a);
268	}
269
270	BOOLEAN nr2mEqual(number a, number b, const coeffs)
271	{
272	return (a == b);
273	}
274
275	BOOLEAN nr2mGreater(number a, number b, const coeffs r)
276	{
277	return nr2mDivBy(a, b,r);
278	}
279
280	/* Is 'a' divisible by 'b'? There are two cases:
281	1) a = 0 mod 2^m; then TRUE iff b = 0 or b is a power of 2
282	2) a, b <> 0; then TRUE iff b/gcd(a, b) is a unit mod 2^m */
283	BOOLEAN nr2mDivBy (number a, number b, const coeffs r)
284	{
285	if (a == NULL)
286	{
287	NATNUMBER c = r->mod2mMask + 1;
288	if (c != 0) /* i.e., if no overflow */
289	return (c % (NATNUMBER)b) == 0;
290	else
291	{
292	/* overflow: we need to check whether b
293	is zero or a power of 2: */
294	c = (NATNUMBER)b;
295	while (c != 0)
296	{
297	if ((c % 2) != 0) return FALSE;
298	c = c >> 1;
299	}
300	return TRUE;
301	}
302	}
303	else
304	{
305	number n = nr2mGcd(a, b, r);
306	n = nr2mDiv(b, n, r);
307	return nr2mIsUnit(n, r);
308	}
309	}
310
311	int nr2mDivComp(number as, number bs, const coeffs)
312	{
313	NATNUMBER a = (NATNUMBER)as;
314	NATNUMBER b = (NATNUMBER)bs;
315	assume(a != 0 && b != 0);
316	while (a % 2 == 0 && b % 2 == 0)
317	{
318	a = a / 2;
319	b = b / 2;
320	}
321	if (a % 2 == 0)
322	{
323	return -1;
324	}
325	else
326	{
327	if (b % 2 == 1)
328	{
329	return 2;
330	}
331	else
332	{
333	return 1;
334	}
335	}
336	}
337
338	/* TRUE iff 0 < k <= 2^m / 2 */
339	BOOLEAN nr2mGreaterZero(number k, const coeffs r)
340	{
341	if ((NATNUMBER)k == 0) return FALSE;
342	if ((NATNUMBER)k > ((r->mod2mMask >> 1) + 1)) return FALSE;
343	return TRUE;
344	}
345
346	/* assumes that 'a' is odd, i.e., a unit in Z/2^m, and computes
347	the extended gcd of 'a' and 2^m, in order to find some 's'
348	and 't' such that a * s + 2^m * t = gcd(a, 2^m) = 1;
349	this code will always find a positive 's' */
350	void specialXGCD(unsigned long& s, unsigned long a, const coeffs r)
351	{
352	int_number u = (int_number)omAlloc(sizeof(mpz_t));
353	mpz_init_set_ui(u, a);
354	int_number u0 = (int_number)omAlloc(sizeof(mpz_t));
355	mpz_init(u0);
356	int_number u1 = (int_number)omAlloc(sizeof(mpz_t));
357	mpz_init_set_ui(u1, 1);
358	int_number u2 = (int_number)omAlloc(sizeof(mpz_t));
359	mpz_init(u2);
360	int_number v = (int_number)omAlloc(sizeof(mpz_t));
361	mpz_init_set_ui(v, r->mod2mMask);
362	mpz_add_ui(v, v, 1); /* now: v = 2^m */
363	int_number v0 = (int_number)omAlloc(sizeof(mpz_t));
364	mpz_init(v0);
365	int_number v1 = (int_number)omAlloc(sizeof(mpz_t));
366	mpz_init(v1);
367	int_number v2 = (int_number)omAlloc(sizeof(mpz_t));
368	mpz_init_set_ui(v2, 1);
369	int_number q = (int_number)omAlloc(sizeof(mpz_t));
370	mpz_init(q);
371	int_number rr = (int_number)omAlloc(sizeof(mpz_t));
372	mpz_init(rr);
373
374	while (mpz_cmp_ui(v, 0) != 0) /* i.e., while v != 0 */
375	{
376	mpz_div(q, u, v);
377	mpz_mod(rr, u, v);
378	mpz_set(u, v);
379	mpz_set(v, rr);
380	mpz_set(u0, u2);
381	mpz_set(v0, v2);
382	mpz_mul(u2, u2, q); mpz_sub(u2, u1, u2); /* u2 = u1 - q * u2 */
383	mpz_mul(v2, v2, q); mpz_sub(v2, v1, v2); /* v2 = v1 - q * v2 */
384	mpz_set(u1, u0);
385	mpz_set(v1, v0);
386	}
387
388	while (mpz_cmp_ui(u1, 0) < 0) /* i.e., while u1 < 0 */
389	{
390	/* we add 2^m = (2^m - 1) + 1 to u1: */
391	mpz_add_ui(u1, u1, r->mod2mMask);
392	mpz_add_ui(u1, u1, 1);
393	}
394	s = mpz_get_ui(u1); /* now: 0 <= s <= 2^m - 1 */
395
396	mpz_clear(u); omFree((ADDRESS)u);
397	mpz_clear(u0); omFree((ADDRESS)u0);
398	mpz_clear(u1); omFree((ADDRESS)u1);
399	mpz_clear(u2); omFree((ADDRESS)u2);
400	mpz_clear(v); omFree((ADDRESS)v);
401	mpz_clear(v0); omFree((ADDRESS)v0);
402	mpz_clear(v1); omFree((ADDRESS)v1);
403	mpz_clear(v2); omFree((ADDRESS)v2);
404	mpz_clear(q); omFree((ADDRESS)q);
405	mpz_clear(rr); omFree((ADDRESS)rr);
406	}
407
408	NATNUMBER InvMod(NATNUMBER a, const coeffs r)
409	{
410	assume((NATNUMBER)a % 2 != 0);
411	unsigned long s;
412	specialXGCD(s, a, r);
413	return s;
414	}
415	//#endif
416
417	inline number nr2mInversM(number c, const coeffs r)
418	{
419	assume((NATNUMBER)c % 2 != 0);
420	// Table !!!
421	NATNUMBER inv;
422	inv = InvMod((NATNUMBER)c,r);
423	return (number)inv;
424	}
425
426	number nr2mDiv(number a, number b, const coeffs r)
427	{
428	if ((NATNUMBER)a == 0) return (number)0;
429	else if ((NATNUMBER)b % 2 == 0)
430	{
431	if ((NATNUMBER)b != 0)
432	{
433	while (((NATNUMBER)b % 2 == 0) && ((NATNUMBER)a % 2 == 0))
434	{
435	a = (number)((NATNUMBER)a / 2);
436	b = (number)((NATNUMBER)b / 2);
437	}
438	}
439	if ((NATNUMBER)b % 2 == 0)
440	{
441	WerrorS("Division not possible, even by cancelling zero divisors.");
442	WerrorS("Result is integer division without remainder.");
443	return (number) ((NATNUMBER) a / (NATNUMBER) b);
444	}
445	}
446	return (number)nr2mMult(a, nr2mInversM(b,r),r);
447	}
448
449	number nr2mMod(number a, number b, const coeffs r)
450	{
451	/*
452	We need to return the number rr which is uniquely determined by the
453	following two properties:
454	(1) 0 <= rr < \|b\| (with respect to '<' and '<=' performed in Z x Z)
455	(2) There exists some k in the integers Z such that a = k * b + rr.
456	Consider g := gcd(2^m, \|b\|). Note that then \|b\|/g is a unit in Z/2^m.
457	Now, there are three cases:
458	(a) g = 1
459	Then \|b\| is a unit in Z/2^m, i.e. \|b\| (and also b) divides a.
460	Thus rr = 0.
461	(b) g <> 1 and g divides a
462	Then a = (a/g) * (\|b\|/g)^(-1) * b (up to sign), i.e. again rr = 0.
463	(c) g <> 1 and g does not divide a
464	Let's denote the division with remainder of a by g as follows:
465	a = s * g + t. Then t = a - s * g = a - s * (\|b\|/g)^(-1) * \|b\|
466	fulfills (1) and (2), i.e. rr := t is the correct result. Hence
467	in this third case, rr is the remainder of division of a by g in Z.
468	This algorithm is the same as for the case Z/n, except that we may
469	compute the gcd of \|b\| and 2^m "by hand": We just extract the highest
470	power of 2 (<= 2^m) that is contained in b.
471	*/
472	assume((NATNUMBER)b != 0);
473	NATNUMBER g = 1;
474	NATNUMBER b_div = (NATNUMBER)b;
475	if (b_div < 0) b_div = -b_div; // b_div now represents \|b\|, BUT b_div is unsigned!
476	NATNUMBER rr = 0;
477	while ((g < r->mod2mMask ) && (b_div > 0) && (b_div % 2 == 0))
478	{
479	b_div = b_div >> 1;
480	g = g << 1;
481	} // g is now the gcd of 2^m and \|b\|
482
483	if (g != 1) rr = (NATNUMBER)a % g;
484	return (number)rr;
485	}
486
487	number nr2mIntDiv(number a, number b, const coeffs r)
488	{
489	if ((NATNUMBER)a == 0)
490	{
491	if ((NATNUMBER)b == 0)
492	return (number)1;
493	if ((NATNUMBER)b == 1)
494	return (number)0;
495	NATNUMBER c = r->mod2mMask + 1;
496	if (c != 0) /* i.e., if no overflow */
497	return (number)(c / (NATNUMBER)b);
498	else
499	{
500	/* overflow: c = 2^32 resp. 2^64, depending on platform */
501	int_number cc = (int_number)omAlloc(sizeof(mpz_t));
502	mpz_init_set_ui(cc, r->mod2mMask); mpz_add_ui(cc, cc, 1);
503	mpz_div_ui(cc, cc, (unsigned long)(NATNUMBER)b);
504	unsigned long s = mpz_get_ui(cc);
505	mpz_clear(cc); omFree((ADDRESS)cc);
506	return (number)(NATNUMBER)s;
507	}
508	}
509	else
510	{
511	if ((NATNUMBER)b == 0)
512	return (number)0;
513	return (number)((NATNUMBER) a / (NATNUMBER) b);
514	}
515	}
516
517	number nr2mInvers(number c, const coeffs r)
518	{
519	if ((NATNUMBER)c % 2 == 0)
520	{
521	WerrorS("division by zero divisor");
522	return (number)0;
523	}
524	return nr2mInversM(c, r);
525	}
526
527	number nr2mNeg(number c, const coeffs r)
528	{
529	if ((NATNUMBER)c == 0) return c;
530	return nr2mNegM(c, r);
531	}
532
533	number nr2mMapMachineInt(number from, const coeffs /src/, const coeffs dst)
534	{
535	NATNUMBER i = ((NATNUMBER)from) % dst->mod2mMask ;
536	return (number)i;
537	}
538
539	number nr2mMapZp(number from, const coeffs /src/, const coeffs dst)
540	{
541	NATNUMBER j = (NATNUMBER)1;
542	long ii = (long)from;
543	if (ii < 0) { j = dst->mod2mMask; ii = -ii; }
544	NATNUMBER i = (NATNUMBER)ii;
545	i = i & dst->mod2mMask;
546	/* now we have: from = j * i mod 2^m */
547	return (number)nr2mMult((number)i, (number)j, dst);
548	}
549
550	number nr2mMapQ(number from, const coeffs /src/, const coeffs dst)
551	{
552	int_number erg = (int_number)omAllocBin(gmp_nrz_bin);
553	mpz_init(erg);
554	int_number k = (int_number)omAlloc(sizeof(mpz_t));
555	mpz_init_set_ui(k, dst->mod2mMask);
556
557	nlGMP(from, (number)erg, dst);
558	mpz_and(erg, erg, k);
559	number res = (number)mpz_get_ui(erg);
560
561	mpz_clear(erg); omFree((ADDRESS)erg);
562	mpz_clear(k); omFree((ADDRESS)k);
563
564	return (number)res;
565	}
566
567	number nr2mMapGMP(number from, const coeffs /src/, const coeffs dst)
568	{
569	int_number erg = (int_number)omAllocBin(gmp_nrz_bin);
570	mpz_init(erg);
571	int_number k = (int_number)omAlloc(sizeof(mpz_t));
572	mpz_init_set_ui(k, dst->mod2mMask);
573
574	mpz_and(erg, (int_number)from, k);
575	number res = (number) mpz_get_ui(erg);
576
577	mpz_clear(erg); omFree((ADDRESS)erg);
578	mpz_clear(k); omFree((ADDRESS)k);
579
580	return (number)res;
581	}
582
583	nMapFunc nr2mSetMap(const coeffs src, const coeffs dst)
584	{
585	if (nCoeff_is_Ring_2toM(src)
586	&& (src->mod2mMask == dst->mod2mMask))
587	{
588	return ndCopyMap;
589	}
590	if (nCoeff_is_Ring_2toM(src)
591	&& (src->mod2mMask < dst->mod2mMask))
592	{ /* i.e. map an integer mod 2^s into Z mod 2^t, where t < s */
593	return nr2mMapMachineInt;
594	}
595	if (nCoeff_is_Ring_2toM(src)
596	&& (src->mod2mMask > dst->mod2mMask))
597	{ /* i.e. map an integer mod 2^s into Z mod 2^t, where t > s */
598	// to be done
599	}
600	if (nCoeff_is_Ring_Z(src))
601	{
602	return nr2mMapGMP;
603	}
604	if (nCoeff_is_Q(src))
605	{
606	return nr2mMapQ;
607	}
608	if (nCoeff_is_Zp(src) && (src->ch == 2))
609	{
610	return nr2mMapZp;
611	}
612	if (nCoeff_is_Ring_PtoM(src) \|\| nCoeff_is_Ring_ModN(src))
613	{
614	// Computing the n of Z/n
615	int_number modul = (int_number)omAllocBin(gmp_nrz_bin);
616	mpz_init_set(modul, src->modNumber);
617	int_number twoToTheK = (int_number)omAllocBin(gmp_nrz_bin);
618	mpz_init_set_ui(twoToTheK, src->mod2mMask);
619	mpz_add_ui(twoToTheK, twoToTheK, 1);
620	if (mpz_divisible_p(modul, twoToTheK))
621	{
622	mpz_clear(modul); omFree((void *)modul);
623	mpz_clear(twoToTheK); omFree((void *)twoToTheK);
624	return nr2mMapGMP;
625	}
626	mpz_clear(modul); omFree((void *) modul);
627	mpz_clear(twoToTheK); omFree((void *)twoToTheK);
628	}
629	return NULL; // default
630	}
631
632	/*
633	* set the exponent
634	*/
635
636	void nr2mSetExp(int m, coeffs r)
637	{
638	if (m > 1)
639	{
640	/* we want mod2mMask to be the bit pattern
641	'111..1' consisting of m one's: */
642	r->mod2mMask = 1;
643	for (int i = 1; i < m; i++) r->mod2mMask = (r->mod2mMask << 1) + 1;
644	}
645	else
646	{
647	/* code unexpectedly called with m = 1; we continue with m = 2: */
648	r->mod2mMask = 3; /* i.e., '11' in binary representation */
649	}
650	}
651
652	void nr2mInitExp(int m, coeffs r)
653	{
654	nr2mSetExp(m, r);
655	if (m < 2)
656	WarnS("nr2mInitExp unexpectedly called with m = 1 (we continue with Z/2^2");
657	}
658
659	#ifdef LDEBUG
660	BOOLEAN nr2mDBTest (number a, const char *, const int, const coeffs r)
661	{
662	//if ((NATNUMBER)a < 0) return FALSE; // is unsigned!
663	if (((NATNUMBER)a & r->mod2mMask) != (NATNUMBER)a) return FALSE;
664	return TRUE;
665	}
666	#endif
667
668	void nr2mWrite (number &a, const coeffs r)
669	{
670	int i = nr2mInt(a, r);
671	StringAppend("%d", i);
672	}
673
674	static const char* nr2mEati(const char s, int i, const coeffs r)
675	{
676
677	if (((s) >= '0') && ((s) <= '9'))
678	{
679	(*i) = 0;
680	do
681	{
682	(i) = 10;
683	(i) += s++ - '0';
684	if ((i) >= (MAX_INT_VAL / 10)) (i) = (*i) & r->mod2mMask;
685	}
686	while (((s) >= '0') && ((s) <= '9'));
687	(i) = (i) & r->mod2mMask;
688	}
689	else (*i) = 1;
690	return s;
691	}
692
693	const char * nr2mRead (const char s, number a, const coeffs r)
694	{
695	int z;
696	int n=1;
697
698	s = nr2mEati(s, &z,r);
699	if ((*s) == '/')
700	{
701	s++;
702	s = nr2mEati(s, &n,r);
703	}
704	if (n == 1)
705	*a = (number)z;
706	else
707	*a = nr2mDiv((number)z,(number)n,r);
708	return s;
709	}
710	#endif
711	/* #ifdef HAVE_RINGS */

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