Add testcase of PR c++/92542, already fixed.
[official-gcc.git] / gcc / poly-int.h
blobb953ffacec4e0954174d38f1556dc35b016baaa1
1 /* Polynomial integer classes.
2 Copyright (C) 2014-2020 Free Software Foundation, Inc.
4 This file is part of GCC.
6 GCC is free software; you can redistribute it and/or modify it under
7 the terms of the GNU General Public License as published by the Free
8 Software Foundation; either version 3, or (at your option) any later
9 version.
11 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
12 WARRANTY; without even the implied warranty of MERCHANTABILITY or
13 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
14 for more details.
16 You should have received a copy of the GNU General Public License
17 along with GCC; see the file COPYING3. If not see
18 <http://www.gnu.org/licenses/>. */
20 /* This file provides a representation of sizes and offsets whose exact
21 values depend on certain runtime properties. The motivating example
22 is the Arm SVE ISA, in which the number of vector elements is only
23 known at runtime. See doc/poly-int.texi for more details.
25 Tests for poly-int.h are located in testsuite/gcc.dg/plugin,
26 since they are too expensive (in terms of binary size) to be
27 included as selftests. */
29 #ifndef HAVE_POLY_INT_H
30 #define HAVE_POLY_INT_H
32 template<unsigned int N, typename T> struct poly_int_pod;
33 template<unsigned int N, typename T> class poly_int;
35 /* poly_coeff_traiits<T> describes the properties of a poly_int
36 coefficient type T:
38 - poly_coeff_traits<T1>::rank is less than poly_coeff_traits<T2>::rank
39 if T1 can promote to T2. For C-like types the rank is:
41 (2 * number of bytes) + (unsigned ? 1 : 0)
43 wide_ints don't have a normal rank and so use a value of INT_MAX.
44 Any fixed-width integer should be promoted to wide_int if possible
45 and lead to an error otherwise.
47 - poly_coeff_traits<T>::int_type is the type to which an integer
48 literal should be cast before comparing it with T.
50 - poly_coeff_traits<T>::precision is the number of bits that T can hold.
52 - poly_coeff_traits<T>::signedness is:
53 0 if T is unsigned
54 1 if T is signed
55 -1 if T has no inherent sign (as for wide_int).
57 - poly_coeff_traits<T>::max_value, if defined, is the maximum value of T.
59 - poly_coeff_traits<T>::result is a type that can hold results of
60 operations on T. This is different from T itself in cases where T
61 is the result of an accessor like wi::to_offset. */
62 template<typename T, wi::precision_type = wi::int_traits<T>::precision_type>
63 struct poly_coeff_traits;
65 template<typename T>
66 struct poly_coeff_traits<T, wi::FLEXIBLE_PRECISION>
68 typedef T result;
69 typedef T int_type;
70 static const int signedness = (T (0) >= T (-1));
71 static const int precision = sizeof (T) * CHAR_BIT;
72 static const T max_value = (signedness
73 ? ((T (1) << (precision - 2))
74 + ((T (1) << (precision - 2)) - 1))
75 : T (-1));
76 static const int rank = sizeof (T) * 2 + !signedness;
79 template<typename T>
80 struct poly_coeff_traits<T, wi::VAR_PRECISION>
82 typedef T result;
83 typedef int int_type;
84 static const int signedness = -1;
85 static const int precision = WIDE_INT_MAX_PRECISION;
86 static const int rank = INT_MAX;
89 template<typename T>
90 struct poly_coeff_traits<T, wi::CONST_PRECISION>
92 typedef WI_UNARY_RESULT (T) result;
93 typedef int int_type;
94 /* These types are always signed. */
95 static const int signedness = 1;
96 static const int precision = wi::int_traits<T>::precision;
97 static const int rank = precision * 2 / CHAR_BIT;
100 /* Information about a pair of coefficient types. */
101 template<typename T1, typename T2>
102 struct poly_coeff_pair_traits
104 /* True if T1 can represent all the values of T2.
106 Either:
108 - T1 should be a type with the same signedness as T2 and no less
109 precision. This allows things like int16_t -> int16_t and
110 uint32_t -> uint64_t.
112 - T1 should be signed, T2 should be unsigned, and T1 should be
113 wider than T2. This allows things like uint16_t -> int32_t.
115 This rules out cases in which T1 has less precision than T2 or where
116 the conversion would reinterpret the top bit. E.g. int16_t -> uint32_t
117 can be dangerous and should have an explicit cast if deliberate. */
118 static const bool lossless_p = (poly_coeff_traits<T1>::signedness
119 == poly_coeff_traits<T2>::signedness
120 ? (poly_coeff_traits<T1>::precision
121 >= poly_coeff_traits<T2>::precision)
122 : (poly_coeff_traits<T1>::signedness == 1
123 && poly_coeff_traits<T2>::signedness == 0
124 && (poly_coeff_traits<T1>::precision
125 > poly_coeff_traits<T2>::precision)));
127 /* 0 if T1 op T2 should promote to HOST_WIDE_INT,
128 1 if T1 op T2 should promote to unsigned HOST_WIDE_INT,
129 2 if T1 op T2 should use wide-int rules. */
130 #define RANK(X) poly_coeff_traits<X>::rank
131 static const int result_kind
132 = ((RANK (T1) <= RANK (HOST_WIDE_INT)
133 && RANK (T2) <= RANK (HOST_WIDE_INT))
135 : (RANK (T1) <= RANK (unsigned HOST_WIDE_INT)
136 && RANK (T2) <= RANK (unsigned HOST_WIDE_INT))
137 ? 1 : 2);
138 #undef RANK
141 /* SFINAE class that makes T3 available as "type" if T2 can represent all the
142 values in T1. */
143 template<typename T1, typename T2, typename T3,
144 bool lossless_p = poly_coeff_pair_traits<T1, T2>::lossless_p>
145 struct if_lossless;
146 template<typename T1, typename T2, typename T3>
147 struct if_lossless<T1, T2, T3, true>
149 typedef T3 type;
152 /* poly_int_traits<T> describes an integer type T that might be polynomial
153 or non-polynomial:
155 - poly_int_traits<T>::is_poly is true if T is a poly_int-based type
156 and false otherwise.
158 - poly_int_traits<T>::num_coeffs gives the number of coefficients in T
159 if T is a poly_int and 1 otherwise.
161 - poly_int_traits<T>::coeff_type gives the coefficent type of T if T
162 is a poly_int and T itself otherwise
164 - poly_int_traits<T>::int_type is a shorthand for
165 typename poly_coeff_traits<coeff_type>::int_type. */
166 template<typename T>
167 struct poly_int_traits
169 static const bool is_poly = false;
170 static const unsigned int num_coeffs = 1;
171 typedef T coeff_type;
172 typedef typename poly_coeff_traits<T>::int_type int_type;
174 template<unsigned int N, typename C>
175 struct poly_int_traits<poly_int_pod<N, C> >
177 static const bool is_poly = true;
178 static const unsigned int num_coeffs = N;
179 typedef C coeff_type;
180 typedef typename poly_coeff_traits<C>::int_type int_type;
182 template<unsigned int N, typename C>
183 struct poly_int_traits<poly_int<N, C> > : poly_int_traits<poly_int_pod<N, C> >
187 /* SFINAE class that makes T2 available as "type" if T1 is a non-polynomial
188 type. */
189 template<typename T1, typename T2 = T1,
190 bool is_poly = poly_int_traits<T1>::is_poly>
191 struct if_nonpoly {};
192 template<typename T1, typename T2>
193 struct if_nonpoly<T1, T2, false>
195 typedef T2 type;
198 /* SFINAE class that makes T3 available as "type" if both T1 and T2 are
199 non-polynomial types. */
200 template<typename T1, typename T2, typename T3,
201 bool is_poly1 = poly_int_traits<T1>::is_poly,
202 bool is_poly2 = poly_int_traits<T2>::is_poly>
203 struct if_nonpoly2 {};
204 template<typename T1, typename T2, typename T3>
205 struct if_nonpoly2<T1, T2, T3, false, false>
207 typedef T3 type;
210 /* SFINAE class that makes T2 available as "type" if T1 is a polynomial
211 type. */
212 template<typename T1, typename T2 = T1,
213 bool is_poly = poly_int_traits<T1>::is_poly>
214 struct if_poly {};
215 template<typename T1, typename T2>
216 struct if_poly<T1, T2, true>
218 typedef T2 type;
221 /* poly_result<T1, T2> describes the result of an operation on two
222 types T1 and T2, where at least one of the types is polynomial:
224 - poly_result<T1, T2>::type gives the result type for the operation.
225 The intention is to provide normal C-like rules for integer ranks,
226 except that everything smaller than HOST_WIDE_INT promotes to
227 HOST_WIDE_INT.
229 - poly_result<T1, T2>::cast is the type to which an operand of type
230 T1 should be cast before doing the operation, to ensure that
231 the operation is done at the right precision. Casting to
232 poly_result<T1, T2>::type would also work, but casting to this
233 type is more efficient. */
234 template<typename T1, typename T2 = T1,
235 int result_kind = poly_coeff_pair_traits<T1, T2>::result_kind>
236 struct poly_result;
238 /* Promote pair to HOST_WIDE_INT. */
239 template<typename T1, typename T2>
240 struct poly_result<T1, T2, 0>
242 typedef HOST_WIDE_INT type;
243 /* T1 and T2 are primitive types, so cast values to T before operating
244 on them. */
245 typedef type cast;
248 /* Promote pair to unsigned HOST_WIDE_INT. */
249 template<typename T1, typename T2>
250 struct poly_result<T1, T2, 1>
252 typedef unsigned HOST_WIDE_INT type;
253 /* T1 and T2 are primitive types, so cast values to T before operating
254 on them. */
255 typedef type cast;
258 /* Use normal wide-int rules. */
259 template<typename T1, typename T2>
260 struct poly_result<T1, T2, 2>
262 typedef WI_BINARY_RESULT (T1, T2) type;
263 /* Don't cast values before operating on them; leave the wi:: routines
264 to handle promotion as necessary. */
265 typedef const T1 &cast;
268 /* The coefficient type for the result of a binary operation on two
269 poly_ints, the first of which has coefficients of type C1 and the
270 second of which has coefficients of type C2. */
271 #define POLY_POLY_COEFF(C1, C2) typename poly_result<C1, C2>::type
273 /* Enforce that T2 is non-polynomial and provide the cofficient type of
274 the result of a binary operation in which the first operand is a
275 poly_int with coefficients of type C1 and the second operand is
276 a constant of type T2. */
277 #define POLY_CONST_COEFF(C1, T2) \
278 POLY_POLY_COEFF (C1, typename if_nonpoly<T2>::type)
280 /* Likewise in reverse. */
281 #define CONST_POLY_COEFF(T1, C2) \
282 POLY_POLY_COEFF (typename if_nonpoly<T1>::type, C2)
284 /* The result type for a binary operation on poly_int<N, C1> and
285 poly_int<N, C2>. */
286 #define POLY_POLY_RESULT(N, C1, C2) poly_int<N, POLY_POLY_COEFF (C1, C2)>
288 /* Enforce that T2 is non-polynomial and provide the result type
289 for a binary operation on poly_int<N, C1> and T2. */
290 #define POLY_CONST_RESULT(N, C1, T2) poly_int<N, POLY_CONST_COEFF (C1, T2)>
292 /* Enforce that T1 is non-polynomial and provide the result type
293 for a binary operation on T1 and poly_int<N, C2>. */
294 #define CONST_POLY_RESULT(N, T1, C2) poly_int<N, CONST_POLY_COEFF (T1, C2)>
296 /* Enforce that T1 and T2 are non-polynomial and provide the result type
297 for a binary operation on T1 and T2. */
298 #define CONST_CONST_RESULT(N, T1, T2) \
299 POLY_POLY_COEFF (typename if_nonpoly<T1>::type, \
300 typename if_nonpoly<T2>::type)
302 /* The type to which a coefficient of type C1 should be cast before
303 using it in a binary operation with a coefficient of type C2. */
304 #define POLY_CAST(C1, C2) typename poly_result<C1, C2>::cast
306 /* Provide the coefficient type for the result of T1 op T2, where T1
307 and T2 can be polynomial or non-polynomial. */
308 #define POLY_BINARY_COEFF(T1, T2) \
309 typename poly_result<typename poly_int_traits<T1>::coeff_type, \
310 typename poly_int_traits<T2>::coeff_type>::type
312 /* The type to which an integer constant should be cast before
313 comparing it with T. */
314 #define POLY_INT_TYPE(T) typename poly_int_traits<T>::int_type
316 /* RES is a poly_int result that has coefficients of type C and that
317 is being built up a coefficient at a time. Set coefficient number I
318 to VALUE in the most efficient way possible.
320 For primitive C it is better to assign directly, since it avoids
321 any further calls and so is more efficient when the compiler is
322 built at -O0. But for wide-int based C it is better to construct
323 the value in-place. This means that calls out to a wide-int.cc
324 routine can take the address of RES rather than the address of
325 a temporary.
327 The dummy comparison against a null C * is just a way of checking
328 that C gives the right type. */
329 #define POLY_SET_COEFF(C, RES, I, VALUE) \
330 ((void) (&(RES).coeffs[0] == (C *) 0), \
331 wi::int_traits<C>::precision_type == wi::FLEXIBLE_PRECISION \
332 ? (void) ((RES).coeffs[I] = VALUE) \
333 : (void) ((RES).coeffs[I].~C (), new (&(RES).coeffs[I]) C (VALUE)))
335 /* A base POD class for polynomial integers. The polynomial has N
336 coefficients of type C. */
337 template<unsigned int N, typename C>
338 struct poly_int_pod
340 public:
341 template<typename Ca>
342 poly_int_pod &operator = (const poly_int_pod<N, Ca> &);
343 template<typename Ca>
344 typename if_nonpoly<Ca, poly_int_pod>::type &operator = (const Ca &);
346 template<typename Ca>
347 poly_int_pod &operator += (const poly_int_pod<N, Ca> &);
348 template<typename Ca>
349 typename if_nonpoly<Ca, poly_int_pod>::type &operator += (const Ca &);
351 template<typename Ca>
352 poly_int_pod &operator -= (const poly_int_pod<N, Ca> &);
353 template<typename Ca>
354 typename if_nonpoly<Ca, poly_int_pod>::type &operator -= (const Ca &);
356 template<typename Ca>
357 typename if_nonpoly<Ca, poly_int_pod>::type &operator *= (const Ca &);
359 poly_int_pod &operator <<= (unsigned int);
361 bool is_constant () const;
363 template<typename T>
364 typename if_lossless<T, C, bool>::type is_constant (T *) const;
366 C to_constant () const;
368 template<typename Ca>
369 static poly_int<N, C> from (const poly_int_pod<N, Ca> &, unsigned int,
370 signop);
371 template<typename Ca>
372 static poly_int<N, C> from (const poly_int_pod<N, Ca> &, signop);
374 bool to_shwi (poly_int_pod<N, HOST_WIDE_INT> *) const;
375 bool to_uhwi (poly_int_pod<N, unsigned HOST_WIDE_INT> *) const;
376 poly_int<N, HOST_WIDE_INT> force_shwi () const;
377 poly_int<N, unsigned HOST_WIDE_INT> force_uhwi () const;
379 #if POLY_INT_CONVERSION
380 operator C () const;
381 #endif
383 C coeffs[N];
386 template<unsigned int N, typename C>
387 template<typename Ca>
388 inline poly_int_pod<N, C>&
389 poly_int_pod<N, C>::operator = (const poly_int_pod<N, Ca> &a)
391 for (unsigned int i = 0; i < N; i++)
392 POLY_SET_COEFF (C, *this, i, a.coeffs[i]);
393 return *this;
396 template<unsigned int N, typename C>
397 template<typename Ca>
398 inline typename if_nonpoly<Ca, poly_int_pod<N, C> >::type &
399 poly_int_pod<N, C>::operator = (const Ca &a)
401 POLY_SET_COEFF (C, *this, 0, a);
402 if (N >= 2)
403 for (unsigned int i = 1; i < N; i++)
404 POLY_SET_COEFF (C, *this, i, wi::ints_for<C>::zero (this->coeffs[0]));
405 return *this;
408 template<unsigned int N, typename C>
409 template<typename Ca>
410 inline poly_int_pod<N, C>&
411 poly_int_pod<N, C>::operator += (const poly_int_pod<N, Ca> &a)
413 for (unsigned int i = 0; i < N; i++)
414 this->coeffs[i] += a.coeffs[i];
415 return *this;
418 template<unsigned int N, typename C>
419 template<typename Ca>
420 inline typename if_nonpoly<Ca, poly_int_pod<N, C> >::type &
421 poly_int_pod<N, C>::operator += (const Ca &a)
423 this->coeffs[0] += a;
424 return *this;
427 template<unsigned int N, typename C>
428 template<typename Ca>
429 inline poly_int_pod<N, C>&
430 poly_int_pod<N, C>::operator -= (const poly_int_pod<N, Ca> &a)
432 for (unsigned int i = 0; i < N; i++)
433 this->coeffs[i] -= a.coeffs[i];
434 return *this;
437 template<unsigned int N, typename C>
438 template<typename Ca>
439 inline typename if_nonpoly<Ca, poly_int_pod<N, C> >::type &
440 poly_int_pod<N, C>::operator -= (const Ca &a)
442 this->coeffs[0] -= a;
443 return *this;
446 template<unsigned int N, typename C>
447 template<typename Ca>
448 inline typename if_nonpoly<Ca, poly_int_pod<N, C> >::type &
449 poly_int_pod<N, C>::operator *= (const Ca &a)
451 for (unsigned int i = 0; i < N; i++)
452 this->coeffs[i] *= a;
453 return *this;
456 template<unsigned int N, typename C>
457 inline poly_int_pod<N, C>&
458 poly_int_pod<N, C>::operator <<= (unsigned int a)
460 for (unsigned int i = 0; i < N; i++)
461 this->coeffs[i] <<= a;
462 return *this;
465 /* Return true if the polynomial value is a compile-time constant. */
467 template<unsigned int N, typename C>
468 inline bool
469 poly_int_pod<N, C>::is_constant () const
471 if (N >= 2)
472 for (unsigned int i = 1; i < N; i++)
473 if (this->coeffs[i] != 0)
474 return false;
475 return true;
478 /* Return true if the polynomial value is a compile-time constant,
479 storing its value in CONST_VALUE if so. */
481 template<unsigned int N, typename C>
482 template<typename T>
483 inline typename if_lossless<T, C, bool>::type
484 poly_int_pod<N, C>::is_constant (T *const_value) const
486 if (is_constant ())
488 *const_value = this->coeffs[0];
489 return true;
491 return false;
494 /* Return the value of a polynomial that is already known to be a
495 compile-time constant.
497 NOTE: When using this function, please add a comment above the call
498 explaining why we know the value is constant in that context. */
500 template<unsigned int N, typename C>
501 inline C
502 poly_int_pod<N, C>::to_constant () const
504 gcc_checking_assert (is_constant ());
505 return this->coeffs[0];
508 /* Convert X to a wide_int-based polynomial in which each coefficient
509 has BITSIZE bits. If X's coefficients are smaller than BITSIZE,
510 extend them according to SGN. */
512 template<unsigned int N, typename C>
513 template<typename Ca>
514 inline poly_int<N, C>
515 poly_int_pod<N, C>::from (const poly_int_pod<N, Ca> &a,
516 unsigned int bitsize, signop sgn)
518 poly_int<N, C> r;
519 for (unsigned int i = 0; i < N; i++)
520 POLY_SET_COEFF (C, r, i, C::from (a.coeffs[i], bitsize, sgn));
521 return r;
524 /* Convert X to a fixed_wide_int-based polynomial, extending according
525 to SGN. */
527 template<unsigned int N, typename C>
528 template<typename Ca>
529 inline poly_int<N, C>
530 poly_int_pod<N, C>::from (const poly_int_pod<N, Ca> &a, signop sgn)
532 poly_int<N, C> r;
533 for (unsigned int i = 0; i < N; i++)
534 POLY_SET_COEFF (C, r, i, C::from (a.coeffs[i], sgn));
535 return r;
538 /* Return true if the coefficients of this generic_wide_int-based
539 polynomial can be represented as signed HOST_WIDE_INTs without loss
540 of precision. Store the HOST_WIDE_INT representation in *R if so. */
542 template<unsigned int N, typename C>
543 inline bool
544 poly_int_pod<N, C>::to_shwi (poly_int_pod<N, HOST_WIDE_INT> *r) const
546 for (unsigned int i = 0; i < N; i++)
547 if (!wi::fits_shwi_p (this->coeffs[i]))
548 return false;
549 for (unsigned int i = 0; i < N; i++)
550 r->coeffs[i] = this->coeffs[i].to_shwi ();
551 return true;
554 /* Return true if the coefficients of this generic_wide_int-based
555 polynomial can be represented as unsigned HOST_WIDE_INTs without
556 loss of precision. Store the unsigned HOST_WIDE_INT representation
557 in *R if so. */
559 template<unsigned int N, typename C>
560 inline bool
561 poly_int_pod<N, C>::to_uhwi (poly_int_pod<N, unsigned HOST_WIDE_INT> *r) const
563 for (unsigned int i = 0; i < N; i++)
564 if (!wi::fits_uhwi_p (this->coeffs[i]))
565 return false;
566 for (unsigned int i = 0; i < N; i++)
567 r->coeffs[i] = this->coeffs[i].to_uhwi ();
568 return true;
571 /* Force a generic_wide_int-based constant to HOST_WIDE_INT precision,
572 truncating if necessary. */
574 template<unsigned int N, typename C>
575 inline poly_int<N, HOST_WIDE_INT>
576 poly_int_pod<N, C>::force_shwi () const
578 poly_int_pod<N, HOST_WIDE_INT> r;
579 for (unsigned int i = 0; i < N; i++)
580 r.coeffs[i] = this->coeffs[i].to_shwi ();
581 return r;
584 /* Force a generic_wide_int-based constant to unsigned HOST_WIDE_INT precision,
585 truncating if necessary. */
587 template<unsigned int N, typename C>
588 inline poly_int<N, unsigned HOST_WIDE_INT>
589 poly_int_pod<N, C>::force_uhwi () const
591 poly_int_pod<N, unsigned HOST_WIDE_INT> r;
592 for (unsigned int i = 0; i < N; i++)
593 r.coeffs[i] = this->coeffs[i].to_uhwi ();
594 return r;
597 #if POLY_INT_CONVERSION
598 /* Provide a conversion operator to constants. */
600 template<unsigned int N, typename C>
601 inline
602 poly_int_pod<N, C>::operator C () const
604 gcc_checking_assert (this->is_constant ());
605 return this->coeffs[0];
607 #endif
609 /* The main class for polynomial integers. The class provides
610 constructors that are necessarily missing from the POD base. */
611 template<unsigned int N, typename C>
612 class poly_int : public poly_int_pod<N, C>
614 public:
615 poly_int () {}
617 template<typename Ca>
618 poly_int (const poly_int<N, Ca> &);
619 template<typename Ca>
620 poly_int (const poly_int_pod<N, Ca> &);
621 template<typename C0>
622 poly_int (const C0 &);
623 template<typename C0, typename C1>
624 poly_int (const C0 &, const C1 &);
626 template<typename Ca>
627 poly_int &operator = (const poly_int_pod<N, Ca> &);
628 template<typename Ca>
629 typename if_nonpoly<Ca, poly_int>::type &operator = (const Ca &);
631 template<typename Ca>
632 poly_int &operator += (const poly_int_pod<N, Ca> &);
633 template<typename Ca>
634 typename if_nonpoly<Ca, poly_int>::type &operator += (const Ca &);
636 template<typename Ca>
637 poly_int &operator -= (const poly_int_pod<N, Ca> &);
638 template<typename Ca>
639 typename if_nonpoly<Ca, poly_int>::type &operator -= (const Ca &);
641 template<typename Ca>
642 typename if_nonpoly<Ca, poly_int>::type &operator *= (const Ca &);
644 poly_int &operator <<= (unsigned int);
647 template<unsigned int N, typename C>
648 template<typename Ca>
649 inline
650 poly_int<N, C>::poly_int (const poly_int<N, Ca> &a)
652 for (unsigned int i = 0; i < N; i++)
653 POLY_SET_COEFF (C, *this, i, a.coeffs[i]);
656 template<unsigned int N, typename C>
657 template<typename Ca>
658 inline
659 poly_int<N, C>::poly_int (const poly_int_pod<N, Ca> &a)
661 for (unsigned int i = 0; i < N; i++)
662 POLY_SET_COEFF (C, *this, i, a.coeffs[i]);
665 template<unsigned int N, typename C>
666 template<typename C0>
667 inline
668 poly_int<N, C>::poly_int (const C0 &c0)
670 POLY_SET_COEFF (C, *this, 0, c0);
671 for (unsigned int i = 1; i < N; i++)
672 POLY_SET_COEFF (C, *this, i, wi::ints_for<C>::zero (this->coeffs[0]));
675 template<unsigned int N, typename C>
676 template<typename C0, typename C1>
677 inline
678 poly_int<N, C>::poly_int (const C0 &c0, const C1 &c1)
680 STATIC_ASSERT (N >= 2);
681 POLY_SET_COEFF (C, *this, 0, c0);
682 POLY_SET_COEFF (C, *this, 1, c1);
683 for (unsigned int i = 2; i < N; i++)
684 POLY_SET_COEFF (C, *this, i, wi::ints_for<C>::zero (this->coeffs[0]));
687 template<unsigned int N, typename C>
688 template<typename Ca>
689 inline poly_int<N, C>&
690 poly_int<N, C>::operator = (const poly_int_pod<N, Ca> &a)
692 for (unsigned int i = 0; i < N; i++)
693 this->coeffs[i] = a.coeffs[i];
694 return *this;
697 template<unsigned int N, typename C>
698 template<typename Ca>
699 inline typename if_nonpoly<Ca, poly_int<N, C> >::type &
700 poly_int<N, C>::operator = (const Ca &a)
702 this->coeffs[0] = a;
703 if (N >= 2)
704 for (unsigned int i = 1; i < N; i++)
705 this->coeffs[i] = wi::ints_for<C>::zero (this->coeffs[0]);
706 return *this;
709 template<unsigned int N, typename C>
710 template<typename Ca>
711 inline poly_int<N, C>&
712 poly_int<N, C>::operator += (const poly_int_pod<N, Ca> &a)
714 for (unsigned int i = 0; i < N; i++)
715 this->coeffs[i] += a.coeffs[i];
716 return *this;
719 template<unsigned int N, typename C>
720 template<typename Ca>
721 inline typename if_nonpoly<Ca, poly_int<N, C> >::type &
722 poly_int<N, C>::operator += (const Ca &a)
724 this->coeffs[0] += a;
725 return *this;
728 template<unsigned int N, typename C>
729 template<typename Ca>
730 inline poly_int<N, C>&
731 poly_int<N, C>::operator -= (const poly_int_pod<N, Ca> &a)
733 for (unsigned int i = 0; i < N; i++)
734 this->coeffs[i] -= a.coeffs[i];
735 return *this;
738 template<unsigned int N, typename C>
739 template<typename Ca>
740 inline typename if_nonpoly<Ca, poly_int<N, C> >::type &
741 poly_int<N, C>::operator -= (const Ca &a)
743 this->coeffs[0] -= a;
744 return *this;
747 template<unsigned int N, typename C>
748 template<typename Ca>
749 inline typename if_nonpoly<Ca, poly_int<N, C> >::type &
750 poly_int<N, C>::operator *= (const Ca &a)
752 for (unsigned int i = 0; i < N; i++)
753 this->coeffs[i] *= a;
754 return *this;
757 template<unsigned int N, typename C>
758 inline poly_int<N, C>&
759 poly_int<N, C>::operator <<= (unsigned int a)
761 for (unsigned int i = 0; i < N; i++)
762 this->coeffs[i] <<= a;
763 return *this;
766 /* Return true if every coefficient of A is in the inclusive range [B, C]. */
768 template<typename Ca, typename Cb, typename Cc>
769 inline typename if_nonpoly<Ca, bool>::type
770 coeffs_in_range_p (const Ca &a, const Cb &b, const Cc &c)
772 return a >= b && a <= c;
775 template<unsigned int N, typename Ca, typename Cb, typename Cc>
776 inline typename if_nonpoly<Ca, bool>::type
777 coeffs_in_range_p (const poly_int_pod<N, Ca> &a, const Cb &b, const Cc &c)
779 for (unsigned int i = 0; i < N; i++)
780 if (a.coeffs[i] < b || a.coeffs[i] > c)
781 return false;
782 return true;
785 namespace wi {
786 /* Poly version of wi::shwi, with the same interface. */
788 template<unsigned int N>
789 inline poly_int<N, hwi_with_prec>
790 shwi (const poly_int_pod<N, HOST_WIDE_INT> &a, unsigned int precision)
792 poly_int<N, hwi_with_prec> r;
793 for (unsigned int i = 0; i < N; i++)
794 POLY_SET_COEFF (hwi_with_prec, r, i, wi::shwi (a.coeffs[i], precision));
795 return r;
798 /* Poly version of wi::uhwi, with the same interface. */
800 template<unsigned int N>
801 inline poly_int<N, hwi_with_prec>
802 uhwi (const poly_int_pod<N, unsigned HOST_WIDE_INT> &a, unsigned int precision)
804 poly_int<N, hwi_with_prec> r;
805 for (unsigned int i = 0; i < N; i++)
806 POLY_SET_COEFF (hwi_with_prec, r, i, wi::uhwi (a.coeffs[i], precision));
807 return r;
810 /* Poly version of wi::sext, with the same interface. */
812 template<unsigned int N, typename Ca>
813 inline POLY_POLY_RESULT (N, Ca, Ca)
814 sext (const poly_int_pod<N, Ca> &a, unsigned int precision)
816 typedef POLY_POLY_COEFF (Ca, Ca) C;
817 poly_int<N, C> r;
818 for (unsigned int i = 0; i < N; i++)
819 POLY_SET_COEFF (C, r, i, wi::sext (a.coeffs[i], precision));
820 return r;
823 /* Poly version of wi::zext, with the same interface. */
825 template<unsigned int N, typename Ca>
826 inline POLY_POLY_RESULT (N, Ca, Ca)
827 zext (const poly_int_pod<N, Ca> &a, unsigned int precision)
829 typedef POLY_POLY_COEFF (Ca, Ca) C;
830 poly_int<N, C> r;
831 for (unsigned int i = 0; i < N; i++)
832 POLY_SET_COEFF (C, r, i, wi::zext (a.coeffs[i], precision));
833 return r;
837 template<unsigned int N, typename Ca, typename Cb>
838 inline POLY_POLY_RESULT (N, Ca, Cb)
839 operator + (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b)
841 typedef POLY_CAST (Ca, Cb) NCa;
842 typedef POLY_POLY_COEFF (Ca, Cb) C;
843 poly_int<N, C> r;
844 for (unsigned int i = 0; i < N; i++)
845 POLY_SET_COEFF (C, r, i, NCa (a.coeffs[i]) + b.coeffs[i]);
846 return r;
849 template<unsigned int N, typename Ca, typename Cb>
850 inline POLY_CONST_RESULT (N, Ca, Cb)
851 operator + (const poly_int_pod<N, Ca> &a, const Cb &b)
853 typedef POLY_CAST (Ca, Cb) NCa;
854 typedef POLY_CONST_COEFF (Ca, Cb) C;
855 poly_int<N, C> r;
856 POLY_SET_COEFF (C, r, 0, NCa (a.coeffs[0]) + b);
857 if (N >= 2)
858 for (unsigned int i = 1; i < N; i++)
859 POLY_SET_COEFF (C, r, i, NCa (a.coeffs[i]));
860 return r;
863 template<unsigned int N, typename Ca, typename Cb>
864 inline CONST_POLY_RESULT (N, Ca, Cb)
865 operator + (const Ca &a, const poly_int_pod<N, Cb> &b)
867 typedef POLY_CAST (Cb, Ca) NCb;
868 typedef CONST_POLY_COEFF (Ca, Cb) C;
869 poly_int<N, C> r;
870 POLY_SET_COEFF (C, r, 0, a + NCb (b.coeffs[0]));
871 if (N >= 2)
872 for (unsigned int i = 1; i < N; i++)
873 POLY_SET_COEFF (C, r, i, NCb (b.coeffs[i]));
874 return r;
877 namespace wi {
878 /* Poly versions of wi::add, with the same interface. */
880 template<unsigned int N, typename Ca, typename Cb>
881 inline poly_int<N, WI_BINARY_RESULT (Ca, Cb)>
882 add (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b)
884 typedef WI_BINARY_RESULT (Ca, Cb) C;
885 poly_int<N, C> r;
886 for (unsigned int i = 0; i < N; i++)
887 POLY_SET_COEFF (C, r, i, wi::add (a.coeffs[i], b.coeffs[i]));
888 return r;
891 template<unsigned int N, typename Ca, typename Cb>
892 inline poly_int<N, WI_BINARY_RESULT (Ca, Cb)>
893 add (const poly_int_pod<N, Ca> &a, const Cb &b)
895 typedef WI_BINARY_RESULT (Ca, Cb) C;
896 poly_int<N, C> r;
897 POLY_SET_COEFF (C, r, 0, wi::add (a.coeffs[0], b));
898 for (unsigned int i = 1; i < N; i++)
899 POLY_SET_COEFF (C, r, i, wi::add (a.coeffs[i],
900 wi::ints_for<Cb>::zero (b)));
901 return r;
904 template<unsigned int N, typename Ca, typename Cb>
905 inline poly_int<N, WI_BINARY_RESULT (Ca, Cb)>
906 add (const Ca &a, const poly_int_pod<N, Cb> &b)
908 typedef WI_BINARY_RESULT (Ca, Cb) C;
909 poly_int<N, C> r;
910 POLY_SET_COEFF (C, r, 0, wi::add (a, b.coeffs[0]));
911 for (unsigned int i = 1; i < N; i++)
912 POLY_SET_COEFF (C, r, i, wi::add (wi::ints_for<Ca>::zero (a),
913 b.coeffs[i]));
914 return r;
917 template<unsigned int N, typename Ca, typename Cb>
918 inline poly_int<N, WI_BINARY_RESULT (Ca, Cb)>
919 add (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b,
920 signop sgn, wi::overflow_type *overflow)
922 typedef WI_BINARY_RESULT (Ca, Cb) C;
923 poly_int<N, C> r;
924 POLY_SET_COEFF (C, r, 0, wi::add (a.coeffs[0], b.coeffs[0], sgn, overflow));
925 for (unsigned int i = 1; i < N; i++)
927 wi::overflow_type suboverflow;
928 POLY_SET_COEFF (C, r, i, wi::add (a.coeffs[i], b.coeffs[i], sgn,
929 &suboverflow));
930 wi::accumulate_overflow (*overflow, suboverflow);
932 return r;
936 template<unsigned int N, typename Ca, typename Cb>
937 inline POLY_POLY_RESULT (N, Ca, Cb)
938 operator - (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b)
940 typedef POLY_CAST (Ca, Cb) NCa;
941 typedef POLY_POLY_COEFF (Ca, Cb) C;
942 poly_int<N, C> r;
943 for (unsigned int i = 0; i < N; i++)
944 POLY_SET_COEFF (C, r, i, NCa (a.coeffs[i]) - b.coeffs[i]);
945 return r;
948 template<unsigned int N, typename Ca, typename Cb>
949 inline POLY_CONST_RESULT (N, Ca, Cb)
950 operator - (const poly_int_pod<N, Ca> &a, const Cb &b)
952 typedef POLY_CAST (Ca, Cb) NCa;
953 typedef POLY_CONST_COEFF (Ca, Cb) C;
954 poly_int<N, C> r;
955 POLY_SET_COEFF (C, r, 0, NCa (a.coeffs[0]) - b);
956 if (N >= 2)
957 for (unsigned int i = 1; i < N; i++)
958 POLY_SET_COEFF (C, r, i, NCa (a.coeffs[i]));
959 return r;
962 template<unsigned int N, typename Ca, typename Cb>
963 inline CONST_POLY_RESULT (N, Ca, Cb)
964 operator - (const Ca &a, const poly_int_pod<N, Cb> &b)
966 typedef POLY_CAST (Cb, Ca) NCb;
967 typedef CONST_POLY_COEFF (Ca, Cb) C;
968 poly_int<N, C> r;
969 POLY_SET_COEFF (C, r, 0, a - NCb (b.coeffs[0]));
970 if (N >= 2)
971 for (unsigned int i = 1; i < N; i++)
972 POLY_SET_COEFF (C, r, i, -NCb (b.coeffs[i]));
973 return r;
976 namespace wi {
977 /* Poly versions of wi::sub, with the same interface. */
979 template<unsigned int N, typename Ca, typename Cb>
980 inline poly_int<N, WI_BINARY_RESULT (Ca, Cb)>
981 sub (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b)
983 typedef WI_BINARY_RESULT (Ca, Cb) C;
984 poly_int<N, C> r;
985 for (unsigned int i = 0; i < N; i++)
986 POLY_SET_COEFF (C, r, i, wi::sub (a.coeffs[i], b.coeffs[i]));
987 return r;
990 template<unsigned int N, typename Ca, typename Cb>
991 inline poly_int<N, WI_BINARY_RESULT (Ca, Cb)>
992 sub (const poly_int_pod<N, Ca> &a, const Cb &b)
994 typedef WI_BINARY_RESULT (Ca, Cb) C;
995 poly_int<N, C> r;
996 POLY_SET_COEFF (C, r, 0, wi::sub (a.coeffs[0], b));
997 for (unsigned int i = 1; i < N; i++)
998 POLY_SET_COEFF (C, r, i, wi::sub (a.coeffs[i],
999 wi::ints_for<Cb>::zero (b)));
1000 return r;
1003 template<unsigned int N, typename Ca, typename Cb>
1004 inline poly_int<N, WI_BINARY_RESULT (Ca, Cb)>
1005 sub (const Ca &a, const poly_int_pod<N, Cb> &b)
1007 typedef WI_BINARY_RESULT (Ca, Cb) C;
1008 poly_int<N, C> r;
1009 POLY_SET_COEFF (C, r, 0, wi::sub (a, b.coeffs[0]));
1010 for (unsigned int i = 1; i < N; i++)
1011 POLY_SET_COEFF (C, r, i, wi::sub (wi::ints_for<Ca>::zero (a),
1012 b.coeffs[i]));
1013 return r;
1016 template<unsigned int N, typename Ca, typename Cb>
1017 inline poly_int<N, WI_BINARY_RESULT (Ca, Cb)>
1018 sub (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b,
1019 signop sgn, wi::overflow_type *overflow)
1021 typedef WI_BINARY_RESULT (Ca, Cb) C;
1022 poly_int<N, C> r;
1023 POLY_SET_COEFF (C, r, 0, wi::sub (a.coeffs[0], b.coeffs[0], sgn, overflow));
1024 for (unsigned int i = 1; i < N; i++)
1026 wi::overflow_type suboverflow;
1027 POLY_SET_COEFF (C, r, i, wi::sub (a.coeffs[i], b.coeffs[i], sgn,
1028 &suboverflow));
1029 wi::accumulate_overflow (*overflow, suboverflow);
1031 return r;
1035 template<unsigned int N, typename Ca>
1036 inline POLY_POLY_RESULT (N, Ca, Ca)
1037 operator - (const poly_int_pod<N, Ca> &a)
1039 typedef POLY_CAST (Ca, Ca) NCa;
1040 typedef POLY_POLY_COEFF (Ca, Ca) C;
1041 poly_int<N, C> r;
1042 for (unsigned int i = 0; i < N; i++)
1043 POLY_SET_COEFF (C, r, i, -NCa (a.coeffs[i]));
1044 return r;
1047 namespace wi {
1048 /* Poly version of wi::neg, with the same interface. */
1050 template<unsigned int N, typename Ca>
1051 inline poly_int<N, WI_UNARY_RESULT (Ca)>
1052 neg (const poly_int_pod<N, Ca> &a)
1054 typedef WI_UNARY_RESULT (Ca) C;
1055 poly_int<N, C> r;
1056 for (unsigned int i = 0; i < N; i++)
1057 POLY_SET_COEFF (C, r, i, wi::neg (a.coeffs[i]));
1058 return r;
1061 template<unsigned int N, typename Ca>
1062 inline poly_int<N, WI_UNARY_RESULT (Ca)>
1063 neg (const poly_int_pod<N, Ca> &a, wi::overflow_type *overflow)
1065 typedef WI_UNARY_RESULT (Ca) C;
1066 poly_int<N, C> r;
1067 POLY_SET_COEFF (C, r, 0, wi::neg (a.coeffs[0], overflow));
1068 for (unsigned int i = 1; i < N; i++)
1070 wi::overflow_type suboverflow;
1071 POLY_SET_COEFF (C, r, i, wi::neg (a.coeffs[i], &suboverflow));
1072 wi::accumulate_overflow (*overflow, suboverflow);
1074 return r;
1078 template<unsigned int N, typename Ca>
1079 inline POLY_POLY_RESULT (N, Ca, Ca)
1080 operator ~ (const poly_int_pod<N, Ca> &a)
1082 if (N >= 2)
1083 return -1 - a;
1084 return ~a.coeffs[0];
1087 template<unsigned int N, typename Ca, typename Cb>
1088 inline POLY_CONST_RESULT (N, Ca, Cb)
1089 operator * (const poly_int_pod<N, Ca> &a, const Cb &b)
1091 typedef POLY_CAST (Ca, Cb) NCa;
1092 typedef POLY_CONST_COEFF (Ca, Cb) C;
1093 poly_int<N, C> r;
1094 for (unsigned int i = 0; i < N; i++)
1095 POLY_SET_COEFF (C, r, i, NCa (a.coeffs[i]) * b);
1096 return r;
1099 template<unsigned int N, typename Ca, typename Cb>
1100 inline CONST_POLY_RESULT (N, Ca, Cb)
1101 operator * (const Ca &a, const poly_int_pod<N, Cb> &b)
1103 typedef POLY_CAST (Ca, Cb) NCa;
1104 typedef CONST_POLY_COEFF (Ca, Cb) C;
1105 poly_int<N, C> r;
1106 for (unsigned int i = 0; i < N; i++)
1107 POLY_SET_COEFF (C, r, i, NCa (a) * b.coeffs[i]);
1108 return r;
1111 namespace wi {
1112 /* Poly versions of wi::mul, with the same interface. */
1114 template<unsigned int N, typename Ca, typename Cb>
1115 inline poly_int<N, WI_BINARY_RESULT (Ca, Cb)>
1116 mul (const poly_int_pod<N, Ca> &a, const Cb &b)
1118 typedef WI_BINARY_RESULT (Ca, Cb) C;
1119 poly_int<N, C> r;
1120 for (unsigned int i = 0; i < N; i++)
1121 POLY_SET_COEFF (C, r, i, wi::mul (a.coeffs[i], b));
1122 return r;
1125 template<unsigned int N, typename Ca, typename Cb>
1126 inline poly_int<N, WI_BINARY_RESULT (Ca, Cb)>
1127 mul (const Ca &a, const poly_int_pod<N, Cb> &b)
1129 typedef WI_BINARY_RESULT (Ca, Cb) C;
1130 poly_int<N, C> r;
1131 for (unsigned int i = 0; i < N; i++)
1132 POLY_SET_COEFF (C, r, i, wi::mul (a, b.coeffs[i]));
1133 return r;
1136 template<unsigned int N, typename Ca, typename Cb>
1137 inline poly_int<N, WI_BINARY_RESULT (Ca, Cb)>
1138 mul (const poly_int_pod<N, Ca> &a, const Cb &b,
1139 signop sgn, wi::overflow_type *overflow)
1141 typedef WI_BINARY_RESULT (Ca, Cb) C;
1142 poly_int<N, C> r;
1143 POLY_SET_COEFF (C, r, 0, wi::mul (a.coeffs[0], b, sgn, overflow));
1144 for (unsigned int i = 1; i < N; i++)
1146 wi::overflow_type suboverflow;
1147 POLY_SET_COEFF (C, r, i, wi::mul (a.coeffs[i], b, sgn, &suboverflow));
1148 wi::accumulate_overflow (*overflow, suboverflow);
1150 return r;
1154 template<unsigned int N, typename Ca, typename Cb>
1155 inline POLY_POLY_RESULT (N, Ca, Ca)
1156 operator << (const poly_int_pod<N, Ca> &a, const Cb &b)
1158 typedef POLY_CAST (Ca, Ca) NCa;
1159 typedef POLY_POLY_COEFF (Ca, Ca) C;
1160 poly_int<N, C> r;
1161 for (unsigned int i = 0; i < N; i++)
1162 POLY_SET_COEFF (C, r, i, NCa (a.coeffs[i]) << b);
1163 return r;
1166 namespace wi {
1167 /* Poly version of wi::lshift, with the same interface. */
1169 template<unsigned int N, typename Ca, typename Cb>
1170 inline poly_int<N, WI_BINARY_RESULT (Ca, Ca)>
1171 lshift (const poly_int_pod<N, Ca> &a, const Cb &b)
1173 typedef WI_BINARY_RESULT (Ca, Ca) C;
1174 poly_int<N, C> r;
1175 for (unsigned int i = 0; i < N; i++)
1176 POLY_SET_COEFF (C, r, i, wi::lshift (a.coeffs[i], b));
1177 return r;
1181 /* Return true if a0 + a1 * x might equal b0 + b1 * x for some nonnegative
1182 integer x. */
1184 template<typename Ca, typename Cb>
1185 inline bool
1186 maybe_eq_2 (const Ca &a0, const Ca &a1, const Cb &b0, const Cb &b1)
1188 if (a1 != b1)
1189 /* a0 + a1 * x == b0 + b1 * x
1190 ==> (a1 - b1) * x == b0 - a0
1191 ==> x == (b0 - a0) / (a1 - b1)
1193 We need to test whether that's a valid value of x.
1194 (b0 - a0) and (a1 - b1) must not have opposite signs
1195 and the result must be integral. */
1196 return (a1 < b1
1197 ? b0 <= a0 && (a0 - b0) % (b1 - a1) == 0
1198 : b0 >= a0 && (b0 - a0) % (a1 - b1) == 0);
1199 return a0 == b0;
1202 /* Return true if a0 + a1 * x might equal b for some nonnegative
1203 integer x. */
1205 template<typename Ca, typename Cb>
1206 inline bool
1207 maybe_eq_2 (const Ca &a0, const Ca &a1, const Cb &b)
1209 if (a1 != 0)
1210 /* a0 + a1 * x == b
1211 ==> x == (b - a0) / a1
1213 We need to test whether that's a valid value of x.
1214 (b - a0) and a1 must not have opposite signs and the
1215 result must be integral. */
1216 return (a1 < 0
1217 ? b <= a0 && (a0 - b) % a1 == 0
1218 : b >= a0 && (b - a0) % a1 == 0);
1219 return a0 == b;
1222 /* Return true if A might equal B for some indeterminate values. */
1224 template<unsigned int N, typename Ca, typename Cb>
1225 inline bool
1226 maybe_eq (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b)
1228 STATIC_ASSERT (N <= 2);
1229 if (N == 2)
1230 return maybe_eq_2 (a.coeffs[0], a.coeffs[1], b.coeffs[0], b.coeffs[1]);
1231 return a.coeffs[0] == b.coeffs[0];
1234 template<unsigned int N, typename Ca, typename Cb>
1235 inline typename if_nonpoly<Cb, bool>::type
1236 maybe_eq (const poly_int_pod<N, Ca> &a, const Cb &b)
1238 STATIC_ASSERT (N <= 2);
1239 if (N == 2)
1240 return maybe_eq_2 (a.coeffs[0], a.coeffs[1], b);
1241 return a.coeffs[0] == b;
1244 template<unsigned int N, typename Ca, typename Cb>
1245 inline typename if_nonpoly<Ca, bool>::type
1246 maybe_eq (const Ca &a, const poly_int_pod<N, Cb> &b)
1248 STATIC_ASSERT (N <= 2);
1249 if (N == 2)
1250 return maybe_eq_2 (b.coeffs[0], b.coeffs[1], a);
1251 return a == b.coeffs[0];
1254 template<typename Ca, typename Cb>
1255 inline typename if_nonpoly2<Ca, Cb, bool>::type
1256 maybe_eq (const Ca &a, const Cb &b)
1258 return a == b;
1261 /* Return true if A might not equal B for some indeterminate values. */
1263 template<unsigned int N, typename Ca, typename Cb>
1264 inline bool
1265 maybe_ne (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b)
1267 if (N >= 2)
1268 for (unsigned int i = 1; i < N; i++)
1269 if (a.coeffs[i] != b.coeffs[i])
1270 return true;
1271 return a.coeffs[0] != b.coeffs[0];
1274 template<unsigned int N, typename Ca, typename Cb>
1275 inline typename if_nonpoly<Cb, bool>::type
1276 maybe_ne (const poly_int_pod<N, Ca> &a, const Cb &b)
1278 if (N >= 2)
1279 for (unsigned int i = 1; i < N; i++)
1280 if (a.coeffs[i] != 0)
1281 return true;
1282 return a.coeffs[0] != b;
1285 template<unsigned int N, typename Ca, typename Cb>
1286 inline typename if_nonpoly<Ca, bool>::type
1287 maybe_ne (const Ca &a, const poly_int_pod<N, Cb> &b)
1289 if (N >= 2)
1290 for (unsigned int i = 1; i < N; i++)
1291 if (b.coeffs[i] != 0)
1292 return true;
1293 return a != b.coeffs[0];
1296 template<typename Ca, typename Cb>
1297 inline typename if_nonpoly2<Ca, Cb, bool>::type
1298 maybe_ne (const Ca &a, const Cb &b)
1300 return a != b;
1303 /* Return true if A is known to be equal to B. */
1304 #define known_eq(A, B) (!maybe_ne (A, B))
1306 /* Return true if A is known to be unequal to B. */
1307 #define known_ne(A, B) (!maybe_eq (A, B))
1309 /* Return true if A might be less than or equal to B for some
1310 indeterminate values. */
1312 template<unsigned int N, typename Ca, typename Cb>
1313 inline bool
1314 maybe_le (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b)
1316 if (N >= 2)
1317 for (unsigned int i = 1; i < N; i++)
1318 if (a.coeffs[i] < b.coeffs[i])
1319 return true;
1320 return a.coeffs[0] <= b.coeffs[0];
1323 template<unsigned int N, typename Ca, typename Cb>
1324 inline typename if_nonpoly<Cb, bool>::type
1325 maybe_le (const poly_int_pod<N, Ca> &a, const Cb &b)
1327 if (N >= 2)
1328 for (unsigned int i = 1; i < N; i++)
1329 if (a.coeffs[i] < 0)
1330 return true;
1331 return a.coeffs[0] <= b;
1334 template<unsigned int N, typename Ca, typename Cb>
1335 inline typename if_nonpoly<Ca, bool>::type
1336 maybe_le (const Ca &a, const poly_int_pod<N, Cb> &b)
1338 if (N >= 2)
1339 for (unsigned int i = 1; i < N; i++)
1340 if (b.coeffs[i] > 0)
1341 return true;
1342 return a <= b.coeffs[0];
1345 template<typename Ca, typename Cb>
1346 inline typename if_nonpoly2<Ca, Cb, bool>::type
1347 maybe_le (const Ca &a, const Cb &b)
1349 return a <= b;
1352 /* Return true if A might be less than B for some indeterminate values. */
1354 template<unsigned int N, typename Ca, typename Cb>
1355 inline bool
1356 maybe_lt (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b)
1358 if (N >= 2)
1359 for (unsigned int i = 1; i < N; i++)
1360 if (a.coeffs[i] < b.coeffs[i])
1361 return true;
1362 return a.coeffs[0] < b.coeffs[0];
1365 template<unsigned int N, typename Ca, typename Cb>
1366 inline typename if_nonpoly<Cb, bool>::type
1367 maybe_lt (const poly_int_pod<N, Ca> &a, const Cb &b)
1369 if (N >= 2)
1370 for (unsigned int i = 1; i < N; i++)
1371 if (a.coeffs[i] < 0)
1372 return true;
1373 return a.coeffs[0] < b;
1376 template<unsigned int N, typename Ca, typename Cb>
1377 inline typename if_nonpoly<Ca, bool>::type
1378 maybe_lt (const Ca &a, const poly_int_pod<N, Cb> &b)
1380 if (N >= 2)
1381 for (unsigned int i = 1; i < N; i++)
1382 if (b.coeffs[i] > 0)
1383 return true;
1384 return a < b.coeffs[0];
1387 template<typename Ca, typename Cb>
1388 inline typename if_nonpoly2<Ca, Cb, bool>::type
1389 maybe_lt (const Ca &a, const Cb &b)
1391 return a < b;
1394 /* Return true if A may be greater than or equal to B. */
1395 #define maybe_ge(A, B) maybe_le (B, A)
1397 /* Return true if A may be greater than B. */
1398 #define maybe_gt(A, B) maybe_lt (B, A)
1400 /* Return true if A is known to be less than or equal to B. */
1401 #define known_le(A, B) (!maybe_gt (A, B))
1403 /* Return true if A is known to be less than B. */
1404 #define known_lt(A, B) (!maybe_ge (A, B))
1406 /* Return true if A is known to be greater than B. */
1407 #define known_gt(A, B) (!maybe_le (A, B))
1409 /* Return true if A is known to be greater than or equal to B. */
1410 #define known_ge(A, B) (!maybe_lt (A, B))
1412 /* Return true if A and B are ordered by the partial ordering known_le. */
1414 template<typename T1, typename T2>
1415 inline bool
1416 ordered_p (const T1 &a, const T2 &b)
1418 return ((poly_int_traits<T1>::num_coeffs == 1
1419 && poly_int_traits<T2>::num_coeffs == 1)
1420 || known_le (a, b)
1421 || known_le (b, a));
1424 /* Assert that A and B are known to be ordered and return the minimum
1425 of the two.
1427 NOTE: When using this function, please add a comment above the call
1428 explaining why we know the values are ordered in that context. */
1430 template<unsigned int N, typename Ca, typename Cb>
1431 inline POLY_POLY_RESULT (N, Ca, Cb)
1432 ordered_min (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b)
1434 if (known_le (a, b))
1435 return a;
1436 else
1438 if (N > 1)
1439 gcc_checking_assert (known_le (b, a));
1440 return b;
1444 template<unsigned int N, typename Ca, typename Cb>
1445 inline CONST_POLY_RESULT (N, Ca, Cb)
1446 ordered_min (const Ca &a, const poly_int_pod<N, Cb> &b)
1448 if (known_le (a, b))
1449 return a;
1450 else
1452 if (N > 1)
1453 gcc_checking_assert (known_le (b, a));
1454 return b;
1458 template<unsigned int N, typename Ca, typename Cb>
1459 inline POLY_CONST_RESULT (N, Ca, Cb)
1460 ordered_min (const poly_int_pod<N, Ca> &a, const Cb &b)
1462 if (known_le (a, b))
1463 return a;
1464 else
1466 if (N > 1)
1467 gcc_checking_assert (known_le (b, a));
1468 return b;
1472 /* Assert that A and B are known to be ordered and return the maximum
1473 of the two.
1475 NOTE: When using this function, please add a comment above the call
1476 explaining why we know the values are ordered in that context. */
1478 template<unsigned int N, typename Ca, typename Cb>
1479 inline POLY_POLY_RESULT (N, Ca, Cb)
1480 ordered_max (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b)
1482 if (known_le (a, b))
1483 return b;
1484 else
1486 if (N > 1)
1487 gcc_checking_assert (known_le (b, a));
1488 return a;
1492 template<unsigned int N, typename Ca, typename Cb>
1493 inline CONST_POLY_RESULT (N, Ca, Cb)
1494 ordered_max (const Ca &a, const poly_int_pod<N, Cb> &b)
1496 if (known_le (a, b))
1497 return b;
1498 else
1500 if (N > 1)
1501 gcc_checking_assert (known_le (b, a));
1502 return a;
1506 template<unsigned int N, typename Ca, typename Cb>
1507 inline POLY_CONST_RESULT (N, Ca, Cb)
1508 ordered_max (const poly_int_pod<N, Ca> &a, const Cb &b)
1510 if (known_le (a, b))
1511 return b;
1512 else
1514 if (N > 1)
1515 gcc_checking_assert (known_le (b, a));
1516 return a;
1520 /* Return a constant lower bound on the value of A, which is known
1521 to be nonnegative. */
1523 template<unsigned int N, typename Ca>
1524 inline Ca
1525 constant_lower_bound (const poly_int_pod<N, Ca> &a)
1527 gcc_checking_assert (known_ge (a, POLY_INT_TYPE (Ca) (0)));
1528 return a.coeffs[0];
1531 /* Return the constant lower bound of A, given that it is no less than B. */
1533 template<unsigned int N, typename Ca, typename Cb>
1534 inline POLY_CONST_COEFF (Ca, Cb)
1535 constant_lower_bound_with_limit (const poly_int_pod<N, Ca> &a, const Cb &b)
1537 if (known_ge (a, b))
1538 return a.coeffs[0];
1539 return b;
1542 /* Return the constant upper bound of A, given that it is no greater
1543 than B. */
1545 template<unsigned int N, typename Ca, typename Cb>
1546 inline POLY_CONST_COEFF (Ca, Cb)
1547 constant_upper_bound_with_limit (const poly_int_pod<N, Ca> &a, const Cb &b)
1549 if (known_le (a, b))
1550 return a.coeffs[0];
1551 return b;
1554 /* Return a value that is known to be no greater than A and B. This
1555 will be the greatest lower bound for some indeterminate values but
1556 not necessarily for all. */
1558 template<unsigned int N, typename Ca, typename Cb>
1559 inline POLY_CONST_RESULT (N, Ca, Cb)
1560 lower_bound (const poly_int_pod<N, Ca> &a, const Cb &b)
1562 typedef POLY_CAST (Ca, Cb) NCa;
1563 typedef POLY_CAST (Cb, Ca) NCb;
1564 typedef POLY_INT_TYPE (Cb) ICb;
1565 typedef POLY_CONST_COEFF (Ca, Cb) C;
1567 poly_int<N, C> r;
1568 POLY_SET_COEFF (C, r, 0, MIN (NCa (a.coeffs[0]), NCb (b)));
1569 if (N >= 2)
1570 for (unsigned int i = 1; i < N; i++)
1571 POLY_SET_COEFF (C, r, i, MIN (NCa (a.coeffs[i]), ICb (0)));
1572 return r;
1575 template<unsigned int N, typename Ca, typename Cb>
1576 inline CONST_POLY_RESULT (N, Ca, Cb)
1577 lower_bound (const Ca &a, const poly_int_pod<N, Cb> &b)
1579 return lower_bound (b, a);
1582 template<unsigned int N, typename Ca, typename Cb>
1583 inline POLY_POLY_RESULT (N, Ca, Cb)
1584 lower_bound (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b)
1586 typedef POLY_CAST (Ca, Cb) NCa;
1587 typedef POLY_CAST (Cb, Ca) NCb;
1588 typedef POLY_POLY_COEFF (Ca, Cb) C;
1590 poly_int<N, C> r;
1591 for (unsigned int i = 0; i < N; i++)
1592 POLY_SET_COEFF (C, r, i, MIN (NCa (a.coeffs[i]), NCb (b.coeffs[i])));
1593 return r;
1596 template<typename Ca, typename Cb>
1597 inline CONST_CONST_RESULT (N, Ca, Cb)
1598 lower_bound (const Ca &a, const Cb &b)
1600 return a < b ? a : b;
1603 /* Return a value that is known to be no less than A and B. This will
1604 be the least upper bound for some indeterminate values but not
1605 necessarily for all. */
1607 template<unsigned int N, typename Ca, typename Cb>
1608 inline POLY_CONST_RESULT (N, Ca, Cb)
1609 upper_bound (const poly_int_pod<N, Ca> &a, const Cb &b)
1611 typedef POLY_CAST (Ca, Cb) NCa;
1612 typedef POLY_CAST (Cb, Ca) NCb;
1613 typedef POLY_INT_TYPE (Cb) ICb;
1614 typedef POLY_CONST_COEFF (Ca, Cb) C;
1616 poly_int<N, C> r;
1617 POLY_SET_COEFF (C, r, 0, MAX (NCa (a.coeffs[0]), NCb (b)));
1618 if (N >= 2)
1619 for (unsigned int i = 1; i < N; i++)
1620 POLY_SET_COEFF (C, r, i, MAX (NCa (a.coeffs[i]), ICb (0)));
1621 return r;
1624 template<unsigned int N, typename Ca, typename Cb>
1625 inline CONST_POLY_RESULT (N, Ca, Cb)
1626 upper_bound (const Ca &a, const poly_int_pod<N, Cb> &b)
1628 return upper_bound (b, a);
1631 template<unsigned int N, typename Ca, typename Cb>
1632 inline POLY_POLY_RESULT (N, Ca, Cb)
1633 upper_bound (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b)
1635 typedef POLY_CAST (Ca, Cb) NCa;
1636 typedef POLY_CAST (Cb, Ca) NCb;
1637 typedef POLY_POLY_COEFF (Ca, Cb) C;
1639 poly_int<N, C> r;
1640 for (unsigned int i = 0; i < N; i++)
1641 POLY_SET_COEFF (C, r, i, MAX (NCa (a.coeffs[i]), NCb (b.coeffs[i])));
1642 return r;
1645 /* Return the greatest common divisor of all nonzero coefficients, or zero
1646 if all coefficients are zero. */
1648 template<unsigned int N, typename Ca>
1649 inline POLY_BINARY_COEFF (Ca, Ca)
1650 coeff_gcd (const poly_int_pod<N, Ca> &a)
1652 /* Find the first nonzero coefficient, stopping at 0 whatever happens. */
1653 unsigned int i;
1654 for (i = N - 1; i > 0; --i)
1655 if (a.coeffs[i] != 0)
1656 break;
1657 typedef POLY_BINARY_COEFF (Ca, Ca) C;
1658 C r = a.coeffs[i];
1659 for (unsigned int j = 0; j < i; ++j)
1660 if (a.coeffs[j] != 0)
1661 r = gcd (r, C (a.coeffs[j]));
1662 return r;
1665 /* Return a value that is a multiple of both A and B. This will be the
1666 least common multiple for some indeterminate values but necessarily
1667 for all. */
1669 template<unsigned int N, typename Ca, typename Cb>
1670 POLY_CONST_RESULT (N, Ca, Cb)
1671 common_multiple (const poly_int_pod<N, Ca> &a, Cb b)
1673 POLY_BINARY_COEFF (Ca, Ca) xgcd = coeff_gcd (a);
1674 return a * (least_common_multiple (xgcd, b) / xgcd);
1677 template<unsigned int N, typename Ca, typename Cb>
1678 inline CONST_POLY_RESULT (N, Ca, Cb)
1679 common_multiple (const Ca &a, const poly_int_pod<N, Cb> &b)
1681 return common_multiple (b, a);
1684 /* Return a value that is a multiple of both A and B, asserting that
1685 such a value exists. The result will be the least common multiple
1686 for some indeterminate values but necessarily for all.
1688 NOTE: When using this function, please add a comment above the call
1689 explaining why we know the values have a common multiple (which might
1690 for example be because we know A / B is rational). */
1692 template<unsigned int N, typename Ca, typename Cb>
1693 POLY_POLY_RESULT (N, Ca, Cb)
1694 force_common_multiple (const poly_int_pod<N, Ca> &a,
1695 const poly_int_pod<N, Cb> &b)
1697 if (b.is_constant ())
1698 return common_multiple (a, b.coeffs[0]);
1699 if (a.is_constant ())
1700 return common_multiple (a.coeffs[0], b);
1702 typedef POLY_CAST (Ca, Cb) NCa;
1703 typedef POLY_CAST (Cb, Ca) NCb;
1704 typedef POLY_BINARY_COEFF (Ca, Cb) C;
1705 typedef POLY_INT_TYPE (Ca) ICa;
1707 for (unsigned int i = 1; i < N; ++i)
1708 if (a.coeffs[i] != ICa (0))
1710 C lcm = least_common_multiple (NCa (a.coeffs[i]), NCb (b.coeffs[i]));
1711 C amul = lcm / a.coeffs[i];
1712 C bmul = lcm / b.coeffs[i];
1713 for (unsigned int j = 0; j < N; ++j)
1714 gcc_checking_assert (a.coeffs[j] * amul == b.coeffs[j] * bmul);
1715 return a * amul;
1717 gcc_unreachable ();
1720 /* Compare A and B for sorting purposes, returning -1 if A should come
1721 before B, 0 if A and B are identical, and 1 if A should come after B.
1722 This is a lexicographical compare of the coefficients in reverse order.
1724 A consequence of this is that all constant sizes come before all
1725 non-constant ones, regardless of magnitude (since a size is never
1726 negative). This is what most callers want. For example, when laying
1727 data out on the stack, it's better to keep all the constant-sized
1728 data together so that it can be accessed as a constant offset from a
1729 single base. */
1731 template<unsigned int N, typename Ca, typename Cb>
1732 inline int
1733 compare_sizes_for_sort (const poly_int_pod<N, Ca> &a,
1734 const poly_int_pod<N, Cb> &b)
1736 for (unsigned int i = N; i-- > 0; )
1737 if (a.coeffs[i] != b.coeffs[i])
1738 return a.coeffs[i] < b.coeffs[i] ? -1 : 1;
1739 return 0;
1742 /* Return true if we can calculate VALUE & (ALIGN - 1) at compile time. */
1744 template<unsigned int N, typename Ca, typename Cb>
1745 inline bool
1746 can_align_p (const poly_int_pod<N, Ca> &value, Cb align)
1748 for (unsigned int i = 1; i < N; i++)
1749 if ((value.coeffs[i] & (align - 1)) != 0)
1750 return false;
1751 return true;
1754 /* Return true if we can align VALUE up to the smallest multiple of
1755 ALIGN that is >= VALUE. Store the aligned value in *ALIGNED if so. */
1757 template<unsigned int N, typename Ca, typename Cb>
1758 inline bool
1759 can_align_up (const poly_int_pod<N, Ca> &value, Cb align,
1760 poly_int_pod<N, Ca> *aligned)
1762 if (!can_align_p (value, align))
1763 return false;
1764 *aligned = value + (-value.coeffs[0] & (align - 1));
1765 return true;
1768 /* Return true if we can align VALUE down to the largest multiple of
1769 ALIGN that is <= VALUE. Store the aligned value in *ALIGNED if so. */
1771 template<unsigned int N, typename Ca, typename Cb>
1772 inline bool
1773 can_align_down (const poly_int_pod<N, Ca> &value, Cb align,
1774 poly_int_pod<N, Ca> *aligned)
1776 if (!can_align_p (value, align))
1777 return false;
1778 *aligned = value - (value.coeffs[0] & (align - 1));
1779 return true;
1782 /* Return true if we can align A and B up to the smallest multiples of
1783 ALIGN that are >= A and B respectively, and if doing so gives the
1784 same value. */
1786 template<unsigned int N, typename Ca, typename Cb, typename Cc>
1787 inline bool
1788 known_equal_after_align_up (const poly_int_pod<N, Ca> &a,
1789 const poly_int_pod<N, Cb> &b,
1790 Cc align)
1792 poly_int<N, Ca> aligned_a;
1793 poly_int<N, Cb> aligned_b;
1794 return (can_align_up (a, align, &aligned_a)
1795 && can_align_up (b, align, &aligned_b)
1796 && known_eq (aligned_a, aligned_b));
1799 /* Return true if we can align A and B down to the largest multiples of
1800 ALIGN that are <= A and B respectively, and if doing so gives the
1801 same value. */
1803 template<unsigned int N, typename Ca, typename Cb, typename Cc>
1804 inline bool
1805 known_equal_after_align_down (const poly_int_pod<N, Ca> &a,
1806 const poly_int_pod<N, Cb> &b,
1807 Cc align)
1809 poly_int<N, Ca> aligned_a;
1810 poly_int<N, Cb> aligned_b;
1811 return (can_align_down (a, align, &aligned_a)
1812 && can_align_down (b, align, &aligned_b)
1813 && known_eq (aligned_a, aligned_b));
1816 /* Assert that we can align VALUE to ALIGN at compile time and return
1817 the smallest multiple of ALIGN that is >= VALUE.
1819 NOTE: When using this function, please add a comment above the call
1820 explaining why we know the non-constant coefficients must already
1821 be a multiple of ALIGN. */
1823 template<unsigned int N, typename Ca, typename Cb>
1824 inline poly_int<N, Ca>
1825 force_align_up (const poly_int_pod<N, Ca> &value, Cb align)
1827 gcc_checking_assert (can_align_p (value, align));
1828 return value + (-value.coeffs[0] & (align - 1));
1831 /* Assert that we can align VALUE to ALIGN at compile time and return
1832 the largest multiple of ALIGN that is <= VALUE.
1834 NOTE: When using this function, please add a comment above the call
1835 explaining why we know the non-constant coefficients must already
1836 be a multiple of ALIGN. */
1838 template<unsigned int N, typename Ca, typename Cb>
1839 inline poly_int<N, Ca>
1840 force_align_down (const poly_int_pod<N, Ca> &value, Cb align)
1842 gcc_checking_assert (can_align_p (value, align));
1843 return value - (value.coeffs[0] & (align - 1));
1846 /* Return a value <= VALUE that is a multiple of ALIGN. It will be the
1847 greatest such value for some indeterminate values but not necessarily
1848 for all. */
1850 template<unsigned int N, typename Ca, typename Cb>
1851 inline poly_int<N, Ca>
1852 aligned_lower_bound (const poly_int_pod<N, Ca> &value, Cb align)
1854 poly_int<N, Ca> r;
1855 for (unsigned int i = 0; i < N; i++)
1856 /* This form copes correctly with more type combinations than
1857 value.coeffs[i] & -align would. */
1858 POLY_SET_COEFF (Ca, r, i, (value.coeffs[i]
1859 - (value.coeffs[i] & (align - 1))));
1860 return r;
1863 /* Return a value >= VALUE that is a multiple of ALIGN. It will be the
1864 least such value for some indeterminate values but not necessarily
1865 for all. */
1867 template<unsigned int N, typename Ca, typename Cb>
1868 inline poly_int<N, Ca>
1869 aligned_upper_bound (const poly_int_pod<N, Ca> &value, Cb align)
1871 poly_int<N, Ca> r;
1872 for (unsigned int i = 0; i < N; i++)
1873 POLY_SET_COEFF (Ca, r, i, (value.coeffs[i]
1874 + (-value.coeffs[i] & (align - 1))));
1875 return r;
1878 /* Assert that we can align VALUE to ALIGN at compile time. Align VALUE
1879 down to the largest multiple of ALIGN that is <= VALUE, then divide by
1880 ALIGN.
1882 NOTE: When using this function, please add a comment above the call
1883 explaining why we know the non-constant coefficients must already
1884 be a multiple of ALIGN. */
1886 template<unsigned int N, typename Ca, typename Cb>
1887 inline poly_int<N, Ca>
1888 force_align_down_and_div (const poly_int_pod<N, Ca> &value, Cb align)
1890 gcc_checking_assert (can_align_p (value, align));
1892 poly_int<N, Ca> r;
1893 POLY_SET_COEFF (Ca, r, 0, ((value.coeffs[0]
1894 - (value.coeffs[0] & (align - 1)))
1895 / align));
1896 if (N >= 2)
1897 for (unsigned int i = 1; i < N; i++)
1898 POLY_SET_COEFF (Ca, r, i, value.coeffs[i] / align);
1899 return r;
1902 /* Assert that we can align VALUE to ALIGN at compile time. Align VALUE
1903 up to the smallest multiple of ALIGN that is >= VALUE, then divide by
1904 ALIGN.
1906 NOTE: When using this function, please add a comment above the call
1907 explaining why we know the non-constant coefficients must already
1908 be a multiple of ALIGN. */
1910 template<unsigned int N, typename Ca, typename Cb>
1911 inline poly_int<N, Ca>
1912 force_align_up_and_div (const poly_int_pod<N, Ca> &value, Cb align)
1914 gcc_checking_assert (can_align_p (value, align));
1916 poly_int<N, Ca> r;
1917 POLY_SET_COEFF (Ca, r, 0, ((value.coeffs[0]
1918 + (-value.coeffs[0] & (align - 1)))
1919 / align));
1920 if (N >= 2)
1921 for (unsigned int i = 1; i < N; i++)
1922 POLY_SET_COEFF (Ca, r, i, value.coeffs[i] / align);
1923 return r;
1926 /* Return true if we know at compile time the difference between VALUE
1927 and the equal or preceding multiple of ALIGN. Store the value in
1928 *MISALIGN if so. */
1930 template<unsigned int N, typename Ca, typename Cb, typename Cm>
1931 inline bool
1932 known_misalignment (const poly_int_pod<N, Ca> &value, Cb align, Cm *misalign)
1934 gcc_checking_assert (align != 0);
1935 if (!can_align_p (value, align))
1936 return false;
1937 *misalign = value.coeffs[0] & (align - 1);
1938 return true;
1941 /* Return X & (Y - 1), asserting that this value is known. Please add
1942 an a comment above callers to this function to explain why the condition
1943 is known to hold. */
1945 template<unsigned int N, typename Ca, typename Cb>
1946 inline POLY_BINARY_COEFF (Ca, Ca)
1947 force_get_misalignment (const poly_int_pod<N, Ca> &a, Cb align)
1949 gcc_checking_assert (can_align_p (a, align));
1950 return a.coeffs[0] & (align - 1);
1953 /* Return the maximum alignment that A is known to have. Return 0
1954 if A is known to be zero. */
1956 template<unsigned int N, typename Ca>
1957 inline POLY_BINARY_COEFF (Ca, Ca)
1958 known_alignment (const poly_int_pod<N, Ca> &a)
1960 typedef POLY_BINARY_COEFF (Ca, Ca) C;
1961 C r = a.coeffs[0];
1962 for (unsigned int i = 1; i < N; ++i)
1963 r |= a.coeffs[i];
1964 return r & -r;
1967 /* Return true if we can compute A | B at compile time, storing the
1968 result in RES if so. */
1970 template<unsigned int N, typename Ca, typename Cb, typename Cr>
1971 inline typename if_nonpoly<Cb, bool>::type
1972 can_ior_p (const poly_int_pod<N, Ca> &a, Cb b, Cr *result)
1974 /* Coefficients 1 and above must be a multiple of something greater
1975 than B. */
1976 typedef POLY_INT_TYPE (Ca) int_type;
1977 if (N >= 2)
1978 for (unsigned int i = 1; i < N; i++)
1979 if ((-(a.coeffs[i] & -a.coeffs[i]) & b) != int_type (0))
1980 return false;
1981 *result = a;
1982 result->coeffs[0] |= b;
1983 return true;
1986 /* Return true if A is a constant multiple of B, storing the
1987 multiple in *MULTIPLE if so. */
1989 template<unsigned int N, typename Ca, typename Cb, typename Cm>
1990 inline typename if_nonpoly<Cb, bool>::type
1991 constant_multiple_p (const poly_int_pod<N, Ca> &a, Cb b, Cm *multiple)
1993 typedef POLY_CAST (Ca, Cb) NCa;
1994 typedef POLY_CAST (Cb, Ca) NCb;
1996 /* Do the modulus before the constant check, to catch divide by
1997 zero errors. */
1998 if (NCa (a.coeffs[0]) % NCb (b) != 0 || !a.is_constant ())
1999 return false;
2000 *multiple = NCa (a.coeffs[0]) / NCb (b);
2001 return true;
2004 template<unsigned int N, typename Ca, typename Cb, typename Cm>
2005 inline typename if_nonpoly<Ca, bool>::type
2006 constant_multiple_p (Ca a, const poly_int_pod<N, Cb> &b, Cm *multiple)
2008 typedef POLY_CAST (Ca, Cb) NCa;
2009 typedef POLY_CAST (Cb, Ca) NCb;
2010 typedef POLY_INT_TYPE (Ca) int_type;
2012 /* Do the modulus before the constant check, to catch divide by
2013 zero errors. */
2014 if (NCa (a) % NCb (b.coeffs[0]) != 0
2015 || (a != int_type (0) && !b.is_constant ()))
2016 return false;
2017 *multiple = NCa (a) / NCb (b.coeffs[0]);
2018 return true;
2021 template<unsigned int N, typename Ca, typename Cb, typename Cm>
2022 inline bool
2023 constant_multiple_p (const poly_int_pod<N, Ca> &a,
2024 const poly_int_pod<N, Cb> &b, Cm *multiple)
2026 typedef POLY_CAST (Ca, Cb) NCa;
2027 typedef POLY_CAST (Cb, Ca) NCb;
2028 typedef POLY_INT_TYPE (Ca) ICa;
2029 typedef POLY_INT_TYPE (Cb) ICb;
2030 typedef POLY_BINARY_COEFF (Ca, Cb) C;
2032 if (NCa (a.coeffs[0]) % NCb (b.coeffs[0]) != 0)
2033 return false;
2035 C r = NCa (a.coeffs[0]) / NCb (b.coeffs[0]);
2036 for (unsigned int i = 1; i < N; ++i)
2037 if (b.coeffs[i] == ICb (0)
2038 ? a.coeffs[i] != ICa (0)
2039 : (NCa (a.coeffs[i]) % NCb (b.coeffs[i]) != 0
2040 || NCa (a.coeffs[i]) / NCb (b.coeffs[i]) != r))
2041 return false;
2043 *multiple = r;
2044 return true;
2047 /* Return true if A is a multiple of B. */
2049 template<typename Ca, typename Cb>
2050 inline typename if_nonpoly2<Ca, Cb, bool>::type
2051 multiple_p (Ca a, Cb b)
2053 return a % b == 0;
2056 /* Return true if A is a (polynomial) multiple of B. */
2058 template<unsigned int N, typename Ca, typename Cb>
2059 inline typename if_nonpoly<Cb, bool>::type
2060 multiple_p (const poly_int_pod<N, Ca> &a, Cb b)
2062 for (unsigned int i = 0; i < N; ++i)
2063 if (a.coeffs[i] % b != 0)
2064 return false;
2065 return true;
2068 /* Return true if A is a (constant) multiple of B. */
2070 template<unsigned int N, typename Ca, typename Cb>
2071 inline typename if_nonpoly<Ca, bool>::type
2072 multiple_p (Ca a, const poly_int_pod<N, Cb> &b)
2074 typedef POLY_INT_TYPE (Ca) int_type;
2076 /* Do the modulus before the constant check, to catch divide by
2077 potential zeros. */
2078 return a % b.coeffs[0] == 0 && (a == int_type (0) || b.is_constant ());
2081 /* Return true if A is a (polynomial) multiple of B. This handles cases
2082 where either B is constant or the multiple is constant. */
2084 template<unsigned int N, typename Ca, typename Cb>
2085 inline bool
2086 multiple_p (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b)
2088 if (b.is_constant ())
2089 return multiple_p (a, b.coeffs[0]);
2090 POLY_BINARY_COEFF (Ca, Ca) tmp;
2091 return constant_multiple_p (a, b, &tmp);
2094 /* Return true if A is a (constant) multiple of B, storing the
2095 multiple in *MULTIPLE if so. */
2097 template<typename Ca, typename Cb, typename Cm>
2098 inline typename if_nonpoly2<Ca, Cb, bool>::type
2099 multiple_p (Ca a, Cb b, Cm *multiple)
2101 if (a % b != 0)
2102 return false;
2103 *multiple = a / b;
2104 return true;
2107 /* Return true if A is a (polynomial) multiple of B, storing the
2108 multiple in *MULTIPLE if so. */
2110 template<unsigned int N, typename Ca, typename Cb, typename Cm>
2111 inline typename if_nonpoly<Cb, bool>::type
2112 multiple_p (const poly_int_pod<N, Ca> &a, Cb b, poly_int_pod<N, Cm> *multiple)
2114 if (!multiple_p (a, b))
2115 return false;
2116 for (unsigned int i = 0; i < N; ++i)
2117 multiple->coeffs[i] = a.coeffs[i] / b;
2118 return true;
2121 /* Return true if B is a constant and A is a (constant) multiple of B,
2122 storing the multiple in *MULTIPLE if so. */
2124 template<unsigned int N, typename Ca, typename Cb, typename Cm>
2125 inline typename if_nonpoly<Ca, bool>::type
2126 multiple_p (Ca a, const poly_int_pod<N, Cb> &b, Cm *multiple)
2128 typedef POLY_CAST (Ca, Cb) NCa;
2130 /* Do the modulus before the constant check, to catch divide by
2131 potential zeros. */
2132 if (a % b.coeffs[0] != 0 || (NCa (a) != 0 && !b.is_constant ()))
2133 return false;
2134 *multiple = a / b.coeffs[0];
2135 return true;
2138 /* Return true if A is a (polynomial) multiple of B, storing the
2139 multiple in *MULTIPLE if so. This handles cases where either
2140 B is constant or the multiple is constant. */
2142 template<unsigned int N, typename Ca, typename Cb, typename Cm>
2143 inline bool
2144 multiple_p (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b,
2145 poly_int_pod<N, Cm> *multiple)
2147 if (b.is_constant ())
2148 return multiple_p (a, b.coeffs[0], multiple);
2149 return constant_multiple_p (a, b, multiple);
2152 /* Return A / B, given that A is known to be a multiple of B. */
2154 template<unsigned int N, typename Ca, typename Cb>
2155 inline POLY_CONST_RESULT (N, Ca, Cb)
2156 exact_div (const poly_int_pod<N, Ca> &a, Cb b)
2158 typedef POLY_CONST_COEFF (Ca, Cb) C;
2159 poly_int<N, C> r;
2160 for (unsigned int i = 0; i < N; i++)
2162 gcc_checking_assert (a.coeffs[i] % b == 0);
2163 POLY_SET_COEFF (C, r, i, a.coeffs[i] / b);
2165 return r;
2168 /* Return A / B, given that A is known to be a multiple of B. */
2170 template<unsigned int N, typename Ca, typename Cb>
2171 inline POLY_POLY_RESULT (N, Ca, Cb)
2172 exact_div (const poly_int_pod<N, Ca> &a, const poly_int_pod<N, Cb> &b)
2174 if (b.is_constant ())
2175 return exact_div (a, b.coeffs[0]);
2177 typedef POLY_CAST (Ca, Cb) NCa;
2178 typedef POLY_CAST (Cb, Ca) NCb;
2179 typedef POLY_BINARY_COEFF (Ca, Cb) C;
2180 typedef POLY_INT_TYPE (Cb) int_type;
2182 gcc_checking_assert (a.coeffs[0] % b.coeffs[0] == 0);
2183 C r = NCa (a.coeffs[0]) / NCb (b.coeffs[0]);
2184 for (unsigned int i = 1; i < N; ++i)
2185 gcc_checking_assert (b.coeffs[i] == int_type (0)
2186 ? a.coeffs[i] == int_type (0)
2187 : (a.coeffs[i] % b.coeffs[i] == 0
2188 && NCa (a.coeffs[i]) / NCb (b.coeffs[i]) == r));
2190 return r;
2193 /* Return true if there is some constant Q and polynomial r such that:
2195 (1) a = b * Q + r
2196 (2) |b * Q| <= |a|
2197 (3) |r| < |b|
2199 Store the value Q in *QUOTIENT if so. */
2201 template<unsigned int N, typename Ca, typename Cb, typename Cq>
2202 inline typename if_nonpoly2<Cb, Cq, bool>::type
2203 can_div_trunc_p (const poly_int_pod<N, Ca> &a, Cb b, Cq *quotient)
2205 typedef POLY_CAST (Ca, Cb) NCa;
2206 typedef POLY_CAST (Cb, Ca) NCb;
2208 /* Do the division before the constant check, to catch divide by
2209 zero errors. */
2210 Cq q = NCa (a.coeffs[0]) / NCb (b);
2211 if (!a.is_constant ())
2212 return false;
2213 *quotient = q;
2214 return true;
2217 template<unsigned int N, typename Ca, typename Cb, typename Cq>
2218 inline typename if_nonpoly<Cq, bool>::type
2219 can_div_trunc_p (const poly_int_pod<N, Ca> &a,
2220 const poly_int_pod<N, Cb> &b,
2221 Cq *quotient)
2223 /* We can calculate Q from the case in which the indeterminates
2224 are zero. */
2225 typedef POLY_CAST (Ca, Cb) NCa;
2226 typedef POLY_CAST (Cb, Ca) NCb;
2227 typedef POLY_INT_TYPE (Ca) ICa;
2228 typedef POLY_INT_TYPE (Cb) ICb;
2229 typedef POLY_BINARY_COEFF (Ca, Cb) C;
2230 C q = NCa (a.coeffs[0]) / NCb (b.coeffs[0]);
2232 /* Check the other coefficients and record whether the division is exact.
2233 The only difficult case is when it isn't. If we require a and b to
2234 ordered wrt zero, there can be no two coefficients of the same value
2235 that have opposite signs. This means that:
2237 |a| = |a0| + |a1 * x1| + |a2 * x2| + ...
2238 |b| = |b0| + |b1 * x1| + |b2 * x2| + ...
2240 The Q we've just calculated guarantees:
2242 |b0 * Q| <= |a0|
2243 |a0 - b0 * Q| < |b0|
2245 and so:
2247 (2) |b * Q| <= |a|
2249 is satisfied if:
2251 |bi * xi * Q| <= |ai * xi|
2253 for each i in [1, N]. This is trivially true when xi is zero.
2254 When it isn't we need:
2256 (2') |bi * Q| <= |ai|
2258 r is calculated as:
2260 r = r0 + r1 * x1 + r2 * x2 + ...
2261 where ri = ai - bi * Q
2263 Restricting to ordered a and b also guarantees that no two ris
2264 have opposite signs, so we have:
2266 |r| = |r0| + |r1 * x1| + |r2 * x2| + ...
2268 We know from the calculation of Q that |r0| < |b0|, so:
2270 (3) |r| < |b|
2272 is satisfied if:
2274 (3') |ai - bi * Q| <= |bi|
2276 for each i in [1, N]. */
2277 bool rem_p = NCa (a.coeffs[0]) % NCb (b.coeffs[0]) != 0;
2278 for (unsigned int i = 1; i < N; ++i)
2280 if (b.coeffs[i] == ICb (0))
2282 /* For bi == 0 we simply need: (3') |ai| == 0. */
2283 if (a.coeffs[i] != ICa (0))
2284 return false;
2286 else
2288 if (q == 0)
2290 /* For Q == 0 we simply need: (3') |ai| <= |bi|. */
2291 if (a.coeffs[i] != ICa (0))
2293 /* Use negative absolute to avoid overflow, i.e.
2294 -|ai| >= -|bi|. */
2295 C neg_abs_a = (a.coeffs[i] < 0 ? a.coeffs[i] : -a.coeffs[i]);
2296 C neg_abs_b = (b.coeffs[i] < 0 ? b.coeffs[i] : -b.coeffs[i]);
2297 if (neg_abs_a < neg_abs_b)
2298 return false;
2299 rem_p = true;
2302 else
2304 /* Otherwise just check for the case in which ai / bi == Q. */
2305 if (NCa (a.coeffs[i]) / NCb (b.coeffs[i]) != q)
2306 return false;
2307 if (NCa (a.coeffs[i]) % NCb (b.coeffs[i]) != 0)
2308 rem_p = true;
2313 /* If the division isn't exact, require both values to be ordered wrt 0,
2314 so that we can guarantee conditions (2) and (3) for all indeterminate
2315 values. */
2316 if (rem_p && (!ordered_p (a, ICa (0)) || !ordered_p (b, ICb (0))))
2317 return false;
2319 *quotient = q;
2320 return true;
2323 /* Likewise, but also store r in *REMAINDER. */
2325 template<unsigned int N, typename Ca, typename Cb, typename Cq, typename Cr>
2326 inline typename if_nonpoly<Cq, bool>::type
2327 can_div_trunc_p (const poly_int_pod<N, Ca> &a,
2328 const poly_int_pod<N, Cb> &b,
2329 Cq *quotient, Cr *remainder)
2331 if (!can_div_trunc_p (a, b, quotient))
2332 return false;
2333 *remainder = a - *quotient * b;
2334 return true;
2337 /* Return true if there is some polynomial q and constant R such that:
2339 (1) a = B * q + R
2340 (2) |B * q| <= |a|
2341 (3) |R| < |B|
2343 Store the value q in *QUOTIENT if so. */
2345 template<unsigned int N, typename Ca, typename Cb, typename Cq>
2346 inline typename if_nonpoly<Cb, bool>::type
2347 can_div_trunc_p (const poly_int_pod<N, Ca> &a, Cb b,
2348 poly_int_pod<N, Cq> *quotient)
2350 /* The remainder must be constant. */
2351 for (unsigned int i = 1; i < N; ++i)
2352 if (a.coeffs[i] % b != 0)
2353 return false;
2354 for (unsigned int i = 0; i < N; ++i)
2355 quotient->coeffs[i] = a.coeffs[i] / b;
2356 return true;
2359 /* Likewise, but also store R in *REMAINDER. */
2361 template<unsigned int N, typename Ca, typename Cb, typename Cq, typename Cr>
2362 inline typename if_nonpoly<Cb, bool>::type
2363 can_div_trunc_p (const poly_int_pod<N, Ca> &a, Cb b,
2364 poly_int_pod<N, Cq> *quotient, Cr *remainder)
2366 if (!can_div_trunc_p (a, b, quotient))
2367 return false;
2368 *remainder = a.coeffs[0] % b;
2369 return true;
2372 /* Return true if we can compute A / B at compile time, rounding towards zero.
2373 Store the result in QUOTIENT if so.
2375 This handles cases in which either B is constant or the result is
2376 constant. */
2378 template<unsigned int N, typename Ca, typename Cb, typename Cq>
2379 inline bool
2380 can_div_trunc_p (const poly_int_pod<N, Ca> &a,
2381 const poly_int_pod<N, Cb> &b,
2382 poly_int_pod<N, Cq> *quotient)
2384 if (b.is_constant ())
2385 return can_div_trunc_p (a, b.coeffs[0], quotient);
2386 if (!can_div_trunc_p (a, b, &quotient->coeffs[0]))
2387 return false;
2388 for (unsigned int i = 1; i < N; ++i)
2389 quotient->coeffs[i] = 0;
2390 return true;
2393 /* Return true if there is some constant Q and polynomial r such that:
2395 (1) a = b * Q + r
2396 (2) |a| <= |b * Q|
2397 (3) |r| < |b|
2399 Store the value Q in *QUOTIENT if so. */
2401 template<unsigned int N, typename Ca, typename Cb, typename Cq>
2402 inline typename if_nonpoly<Cq, bool>::type
2403 can_div_away_from_zero_p (const poly_int_pod<N, Ca> &a,
2404 const poly_int_pod<N, Cb> &b,
2405 Cq *quotient)
2407 if (!can_div_trunc_p (a, b, quotient))
2408 return false;
2409 if (maybe_ne (*quotient * b, a))
2410 *quotient += (*quotient < 0 ? -1 : 1);
2411 return true;
2414 /* Use print_dec to print VALUE to FILE, where SGN is the sign
2415 of the values. */
2417 template<unsigned int N, typename C>
2418 void
2419 print_dec (const poly_int_pod<N, C> &value, FILE *file, signop sgn)
2421 if (value.is_constant ())
2422 print_dec (value.coeffs[0], file, sgn);
2423 else
2425 fprintf (file, "[");
2426 for (unsigned int i = 0; i < N; ++i)
2428 print_dec (value.coeffs[i], file, sgn);
2429 fputc (i == N - 1 ? ']' : ',', file);
2434 /* Likewise without the signop argument, for coefficients that have an
2435 inherent signedness. */
2437 template<unsigned int N, typename C>
2438 void
2439 print_dec (const poly_int_pod<N, C> &value, FILE *file)
2441 STATIC_ASSERT (poly_coeff_traits<C>::signedness >= 0);
2442 print_dec (value, file,
2443 poly_coeff_traits<C>::signedness ? SIGNED : UNSIGNED);
2446 /* Use print_hex to print VALUE to FILE. */
2448 template<unsigned int N, typename C>
2449 void
2450 print_hex (const poly_int_pod<N, C> &value, FILE *file)
2452 if (value.is_constant ())
2453 print_hex (value.coeffs[0], file);
2454 else
2456 fprintf (file, "[");
2457 for (unsigned int i = 0; i < N; ++i)
2459 print_hex (value.coeffs[i], file);
2460 fputc (i == N - 1 ? ']' : ',', file);
2465 /* Helper for calculating the distance between two points P1 and P2,
2466 in cases where known_le (P1, P2). T1 and T2 are the types of the
2467 two positions, in either order. The coefficients of P2 - P1 have
2468 type unsigned HOST_WIDE_INT if the coefficients of both T1 and T2
2469 have C++ primitive type, otherwise P2 - P1 has its usual
2470 wide-int-based type.
2472 The actual subtraction should look something like this:
2474 typedef poly_span_traits<T1, T2> span_traits;
2475 span_traits::cast (P2) - span_traits::cast (P1)
2477 Applying the cast before the subtraction avoids undefined overflow
2478 for signed T1 and T2.
2480 The implementation of the cast tries to avoid unnecessary arithmetic
2481 or copying. */
2482 template<typename T1, typename T2,
2483 typename Res = POLY_BINARY_COEFF (POLY_BINARY_COEFF (T1, T2),
2484 unsigned HOST_WIDE_INT)>
2485 struct poly_span_traits
2487 template<typename T>
2488 static const T &cast (const T &x) { return x; }
2491 template<typename T1, typename T2>
2492 struct poly_span_traits<T1, T2, unsigned HOST_WIDE_INT>
2494 template<typename T>
2495 static typename if_nonpoly<T, unsigned HOST_WIDE_INT>::type
2496 cast (const T &x) { return x; }
2498 template<unsigned int N, typename T>
2499 static poly_int<N, unsigned HOST_WIDE_INT>
2500 cast (const poly_int_pod<N, T> &x) { return x; }
2503 /* Return true if SIZE represents a known size, assuming that all-ones
2504 indicates an unknown size. */
2506 template<typename T>
2507 inline bool
2508 known_size_p (const T &a)
2510 return maybe_ne (a, POLY_INT_TYPE (T) (-1));
2513 /* Return true if range [POS, POS + SIZE) might include VAL.
2514 SIZE can be the special value -1, in which case the range is
2515 open-ended. */
2517 template<typename T1, typename T2, typename T3>
2518 inline bool
2519 maybe_in_range_p (const T1 &val, const T2 &pos, const T3 &size)
2521 typedef poly_span_traits<T1, T2> start_span;
2522 typedef poly_span_traits<T3, T3> size_span;
2523 if (known_lt (val, pos))
2524 return false;
2525 if (!known_size_p (size))
2526 return true;
2527 if ((poly_int_traits<T1>::num_coeffs > 1
2528 || poly_int_traits<T2>::num_coeffs > 1)
2529 && maybe_lt (val, pos))
2530 /* In this case we don't know whether VAL >= POS is true at compile
2531 time, so we can't prove that VAL >= POS + SIZE. */
2532 return true;
2533 return maybe_lt (start_span::cast (val) - start_span::cast (pos),
2534 size_span::cast (size));
2537 /* Return true if range [POS, POS + SIZE) is known to include VAL.
2538 SIZE can be the special value -1, in which case the range is
2539 open-ended. */
2541 template<typename T1, typename T2, typename T3>
2542 inline bool
2543 known_in_range_p (const T1 &val, const T2 &pos, const T3 &size)
2545 typedef poly_span_traits<T1, T2> start_span;
2546 typedef poly_span_traits<T3, T3> size_span;
2547 return (known_size_p (size)
2548 && known_ge (val, pos)
2549 && known_lt (start_span::cast (val) - start_span::cast (pos),
2550 size_span::cast (size)));
2553 /* Return true if the two ranges [POS1, POS1 + SIZE1) and [POS2, POS2 + SIZE2)
2554 might overlap. SIZE1 and/or SIZE2 can be the special value -1, in which
2555 case the range is open-ended. */
2557 template<typename T1, typename T2, typename T3, typename T4>
2558 inline bool
2559 ranges_maybe_overlap_p (const T1 &pos1, const T2 &size1,
2560 const T3 &pos2, const T4 &size2)
2562 if (maybe_in_range_p (pos2, pos1, size1))
2563 return maybe_ne (size2, POLY_INT_TYPE (T4) (0));
2564 if (maybe_in_range_p (pos1, pos2, size2))
2565 return maybe_ne (size1, POLY_INT_TYPE (T2) (0));
2566 return false;
2569 /* Return true if the two ranges [POS1, POS1 + SIZE1) and [POS2, POS2 + SIZE2)
2570 are known to overlap. SIZE1 and/or SIZE2 can be the special value -1,
2571 in which case the range is open-ended. */
2573 template<typename T1, typename T2, typename T3, typename T4>
2574 inline bool
2575 ranges_known_overlap_p (const T1 &pos1, const T2 &size1,
2576 const T3 &pos2, const T4 &size2)
2578 typedef poly_span_traits<T1, T3> start_span;
2579 typedef poly_span_traits<T2, T2> size1_span;
2580 typedef poly_span_traits<T4, T4> size2_span;
2581 /* known_gt (POS1 + SIZE1, POS2) [infinite precision]
2582 --> known_gt (SIZE1, POS2 - POS1) [infinite precision]
2583 --> known_gt (SIZE1, POS2 - lower_bound (POS1, POS2)) [infinite precision]
2584 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ always nonnegative
2585 --> known_gt (SIZE1, span1::cast (POS2 - lower_bound (POS1, POS2))).
2587 Using the saturating subtraction enforces that SIZE1 must be
2588 nonzero, since known_gt (0, x) is false for all nonnegative x.
2589 If POS2.coeff[I] < POS1.coeff[I] for some I > 0, increasing
2590 indeterminate number I makes the unsaturated condition easier to
2591 satisfy, so using a saturated coefficient of zero tests the case in
2592 which the indeterminate is zero (the minimum value). */
2593 return (known_size_p (size1)
2594 && known_size_p (size2)
2595 && known_lt (start_span::cast (pos2)
2596 - start_span::cast (lower_bound (pos1, pos2)),
2597 size1_span::cast (size1))
2598 && known_lt (start_span::cast (pos1)
2599 - start_span::cast (lower_bound (pos1, pos2)),
2600 size2_span::cast (size2)));
2603 /* Return true if range [POS1, POS1 + SIZE1) is known to be a subrange of
2604 [POS2, POS2 + SIZE2). SIZE1 and/or SIZE2 can be the special value -1,
2605 in which case the range is open-ended. */
2607 template<typename T1, typename T2, typename T3, typename T4>
2608 inline bool
2609 known_subrange_p (const T1 &pos1, const T2 &size1,
2610 const T3 &pos2, const T4 &size2)
2612 typedef typename poly_int_traits<T2>::coeff_type C2;
2613 typedef poly_span_traits<T1, T3> start_span;
2614 typedef poly_span_traits<T2, T4> size_span;
2615 return (known_gt (size1, POLY_INT_TYPE (T2) (0))
2616 && (poly_coeff_traits<C2>::signedness > 0
2617 || known_size_p (size1))
2618 && known_size_p (size2)
2619 && known_ge (pos1, pos2)
2620 && known_le (size1, size2)
2621 && known_le (start_span::cast (pos1) - start_span::cast (pos2),
2622 size_span::cast (size2) - size_span::cast (size1)));
2625 /* Return true if the endpoint of the range [POS, POS + SIZE) can be
2626 stored in a T, or if SIZE is the special value -1, which makes the
2627 range open-ended. */
2629 template<typename T>
2630 inline typename if_nonpoly<T, bool>::type
2631 endpoint_representable_p (const T &pos, const T &size)
2633 return (!known_size_p (size)
2634 || pos <= poly_coeff_traits<T>::max_value - size);
2637 template<unsigned int N, typename C>
2638 inline bool
2639 endpoint_representable_p (const poly_int_pod<N, C> &pos,
2640 const poly_int_pod<N, C> &size)
2642 if (known_size_p (size))
2643 for (unsigned int i = 0; i < N; ++i)
2644 if (pos.coeffs[i] > poly_coeff_traits<C>::max_value - size.coeffs[i])
2645 return false;
2646 return true;
2649 template<unsigned int N, typename C>
2650 void
2651 gt_ggc_mx (poly_int_pod<N, C> *)
2655 template<unsigned int N, typename C>
2656 void
2657 gt_pch_nx (poly_int_pod<N, C> *)
2661 template<unsigned int N, typename C>
2662 void
2663 gt_pch_nx (poly_int_pod<N, C> *, void (*) (void *, void *), void *)
2667 #undef POLY_SET_COEFF
2668 #undef POLY_INT_TYPE
2669 #undef POLY_BINARY_COEFF
2670 #undef CONST_CONST_RESULT
2671 #undef POLY_CONST_RESULT
2672 #undef CONST_POLY_RESULT
2673 #undef POLY_POLY_RESULT
2674 #undef POLY_CONST_COEFF
2675 #undef CONST_POLY_COEFF
2676 #undef POLY_POLY_COEFF
2678 #endif