Add a VEC_SERIES rtl code
[official-gcc.git] / gcc / fixed-value.c
blob3c92453955c4ef4b6439a554d2277fed031ccb30
1 /* Fixed-point arithmetic support.
2 Copyright (C) 2006-2017 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 #include "config.h"
21 #include "system.h"
22 #include "coretypes.h"
23 #include "tm.h"
24 #include "tree.h"
25 #include "diagnostic-core.h"
27 /* Compare two fixed objects for bitwise identity. */
29 bool
30 fixed_identical (const FIXED_VALUE_TYPE *a, const FIXED_VALUE_TYPE *b)
32 return (a->mode == b->mode
33 && a->data.high == b->data.high
34 && a->data.low == b->data.low);
37 /* Calculate a hash value. */
39 unsigned int
40 fixed_hash (const FIXED_VALUE_TYPE *f)
42 return (unsigned int) (f->data.low ^ f->data.high);
45 /* Define the enum code for the range of the fixed-point value. */
46 enum fixed_value_range_code {
47 FIXED_OK, /* The value is within the range. */
48 FIXED_UNDERFLOW, /* The value is less than the minimum. */
49 FIXED_GT_MAX_EPS, /* The value is greater than the maximum, but not equal
50 to the maximum plus the epsilon. */
51 FIXED_MAX_EPS /* The value equals the maximum plus the epsilon. */
54 /* Check REAL_VALUE against the range of the fixed-point mode.
55 Return FIXED_OK, if it is within the range.
56 FIXED_UNDERFLOW, if it is less than the minimum.
57 FIXED_GT_MAX_EPS, if it is greater than the maximum, but not equal to
58 the maximum plus the epsilon.
59 FIXED_MAX_EPS, if it is equal to the maximum plus the epsilon. */
61 static enum fixed_value_range_code
62 check_real_for_fixed_mode (REAL_VALUE_TYPE *real_value, machine_mode mode)
64 REAL_VALUE_TYPE max_value, min_value, epsilon_value;
66 real_2expN (&max_value, GET_MODE_IBIT (mode), VOIDmode);
67 real_2expN (&epsilon_value, -GET_MODE_FBIT (mode), VOIDmode);
69 if (SIGNED_FIXED_POINT_MODE_P (mode))
70 min_value = real_value_negate (&max_value);
71 else
72 real_from_string (&min_value, "0.0");
74 if (real_compare (LT_EXPR, real_value, &min_value))
75 return FIXED_UNDERFLOW;
76 if (real_compare (EQ_EXPR, real_value, &max_value))
77 return FIXED_MAX_EPS;
78 real_arithmetic (&max_value, MINUS_EXPR, &max_value, &epsilon_value);
79 if (real_compare (GT_EXPR, real_value, &max_value))
80 return FIXED_GT_MAX_EPS;
81 return FIXED_OK;
85 /* Construct a CONST_FIXED from a bit payload and machine mode MODE.
86 The bits in PAYLOAD are sign-extended/zero-extended according to MODE. */
88 FIXED_VALUE_TYPE
89 fixed_from_double_int (double_int payload, scalar_mode mode)
91 FIXED_VALUE_TYPE value;
93 gcc_assert (GET_MODE_BITSIZE (mode) <= HOST_BITS_PER_DOUBLE_INT);
95 if (SIGNED_SCALAR_FIXED_POINT_MODE_P (mode))
96 value.data = payload.sext (1 + GET_MODE_IBIT (mode) + GET_MODE_FBIT (mode));
97 else if (UNSIGNED_SCALAR_FIXED_POINT_MODE_P (mode))
98 value.data = payload.zext (GET_MODE_IBIT (mode) + GET_MODE_FBIT (mode));
99 else
100 gcc_unreachable ();
102 value.mode = mode;
104 return value;
108 /* Initialize from a decimal or hexadecimal string. */
110 void
111 fixed_from_string (FIXED_VALUE_TYPE *f, const char *str, scalar_mode mode)
113 REAL_VALUE_TYPE real_value, fixed_value, base_value;
114 unsigned int fbit;
115 enum fixed_value_range_code temp;
116 bool fail;
118 f->mode = mode;
119 fbit = GET_MODE_FBIT (mode);
121 real_from_string (&real_value, str);
122 temp = check_real_for_fixed_mode (&real_value, f->mode);
123 /* We don't want to warn the case when the _Fract value is 1.0. */
124 if (temp == FIXED_UNDERFLOW
125 || temp == FIXED_GT_MAX_EPS
126 || (temp == FIXED_MAX_EPS && ALL_ACCUM_MODE_P (f->mode)))
127 warning (OPT_Woverflow,
128 "large fixed-point constant implicitly truncated to fixed-point type");
129 real_2expN (&base_value, fbit, VOIDmode);
130 real_arithmetic (&fixed_value, MULT_EXPR, &real_value, &base_value);
131 wide_int w = real_to_integer (&fixed_value, &fail,
132 GET_MODE_PRECISION (mode));
133 f->data.low = w.ulow ();
134 f->data.high = w.elt (1);
136 if (temp == FIXED_MAX_EPS && ALL_FRACT_MODE_P (f->mode))
138 /* From the spec, we need to evaluate 1 to the maximal value. */
139 f->data.low = -1;
140 f->data.high = -1;
141 f->data = f->data.zext (GET_MODE_FBIT (f->mode)
142 + GET_MODE_IBIT (f->mode));
144 else
145 f->data = f->data.ext (SIGNED_FIXED_POINT_MODE_P (f->mode)
146 + GET_MODE_FBIT (f->mode)
147 + GET_MODE_IBIT (f->mode),
148 UNSIGNED_FIXED_POINT_MODE_P (f->mode));
151 /* Render F as a decimal floating point constant. */
153 void
154 fixed_to_decimal (char *str, const FIXED_VALUE_TYPE *f_orig,
155 size_t buf_size)
157 REAL_VALUE_TYPE real_value, base_value, fixed_value;
159 signop sgn = UNSIGNED_FIXED_POINT_MODE_P (f_orig->mode) ? UNSIGNED : SIGNED;
160 real_2expN (&base_value, GET_MODE_FBIT (f_orig->mode), VOIDmode);
161 real_from_integer (&real_value, VOIDmode,
162 wide_int::from (f_orig->data,
163 GET_MODE_PRECISION (f_orig->mode), sgn),
164 sgn);
165 real_arithmetic (&fixed_value, RDIV_EXPR, &real_value, &base_value);
166 real_to_decimal (str, &fixed_value, buf_size, 0, 1);
169 /* If SAT_P, saturate A to the maximum or the minimum, and save to *F based on
170 the machine mode MODE.
171 Do not modify *F otherwise.
172 This function assumes the width of double_int is greater than the width
173 of the fixed-point value (the sum of a possible sign bit, possible ibits,
174 and fbits).
175 Return true, if !SAT_P and overflow. */
177 static bool
178 fixed_saturate1 (machine_mode mode, double_int a, double_int *f,
179 bool sat_p)
181 bool overflow_p = false;
182 bool unsigned_p = UNSIGNED_FIXED_POINT_MODE_P (mode);
183 int i_f_bits = GET_MODE_IBIT (mode) + GET_MODE_FBIT (mode);
185 if (unsigned_p) /* Unsigned type. */
187 double_int max;
188 max.low = -1;
189 max.high = -1;
190 max = max.zext (i_f_bits);
191 if (a.ugt (max))
193 if (sat_p)
194 *f = max;
195 else
196 overflow_p = true;
199 else /* Signed type. */
201 double_int max, min;
202 max.high = -1;
203 max.low = -1;
204 max = max.zext (i_f_bits);
205 min.high = 0;
206 min.low = 1;
207 min = min.alshift (i_f_bits, HOST_BITS_PER_DOUBLE_INT);
208 min = min.sext (1 + i_f_bits);
209 if (a.sgt (max))
211 if (sat_p)
212 *f = max;
213 else
214 overflow_p = true;
216 else if (a.slt (min))
218 if (sat_p)
219 *f = min;
220 else
221 overflow_p = true;
224 return overflow_p;
227 /* If SAT_P, saturate {A_HIGH, A_LOW} to the maximum or the minimum, and
228 save to *F based on the machine mode MODE.
229 Do not modify *F otherwise.
230 This function assumes the width of two double_int is greater than the width
231 of the fixed-point value (the sum of a possible sign bit, possible ibits,
232 and fbits).
233 Return true, if !SAT_P and overflow. */
235 static bool
236 fixed_saturate2 (machine_mode mode, double_int a_high, double_int a_low,
237 double_int *f, bool sat_p)
239 bool overflow_p = false;
240 bool unsigned_p = UNSIGNED_FIXED_POINT_MODE_P (mode);
241 int i_f_bits = GET_MODE_IBIT (mode) + GET_MODE_FBIT (mode);
243 if (unsigned_p) /* Unsigned type. */
245 double_int max_r, max_s;
246 max_r.high = 0;
247 max_r.low = 0;
248 max_s.high = -1;
249 max_s.low = -1;
250 max_s = max_s.zext (i_f_bits);
251 if (a_high.ugt (max_r)
252 || (a_high == max_r &&
253 a_low.ugt (max_s)))
255 if (sat_p)
256 *f = max_s;
257 else
258 overflow_p = true;
261 else /* Signed type. */
263 double_int max_r, max_s, min_r, min_s;
264 max_r.high = 0;
265 max_r.low = 0;
266 max_s.high = -1;
267 max_s.low = -1;
268 max_s = max_s.zext (i_f_bits);
269 min_r.high = -1;
270 min_r.low = -1;
271 min_s.high = 0;
272 min_s.low = 1;
273 min_s = min_s.alshift (i_f_bits, HOST_BITS_PER_DOUBLE_INT);
274 min_s = min_s.sext (1 + i_f_bits);
275 if (a_high.sgt (max_r)
276 || (a_high == max_r &&
277 a_low.ugt (max_s)))
279 if (sat_p)
280 *f = max_s;
281 else
282 overflow_p = true;
284 else if (a_high.slt (min_r)
285 || (a_high == min_r &&
286 a_low.ult (min_s)))
288 if (sat_p)
289 *f = min_s;
290 else
291 overflow_p = true;
294 return overflow_p;
297 /* Return the sign bit based on I_F_BITS. */
299 static inline int
300 get_fixed_sign_bit (double_int a, int i_f_bits)
302 if (i_f_bits < HOST_BITS_PER_WIDE_INT)
303 return (a.low >> i_f_bits) & 1;
304 else
305 return (a.high >> (i_f_bits - HOST_BITS_PER_WIDE_INT)) & 1;
308 /* Calculate F = A + (SUBTRACT_P ? -B : B).
309 If SAT_P, saturate the result to the max or the min.
310 Return true, if !SAT_P and overflow. */
312 static bool
313 do_fixed_add (FIXED_VALUE_TYPE *f, const FIXED_VALUE_TYPE *a,
314 const FIXED_VALUE_TYPE *b, bool subtract_p, bool sat_p)
316 bool overflow_p = false;
317 bool unsigned_p;
318 double_int temp;
319 int i_f_bits;
321 /* This was a conditional expression but it triggered a bug in
322 Sun C 5.5. */
323 if (subtract_p)
324 temp = -b->data;
325 else
326 temp = b->data;
328 unsigned_p = UNSIGNED_FIXED_POINT_MODE_P (a->mode);
329 i_f_bits = GET_MODE_IBIT (a->mode) + GET_MODE_FBIT (a->mode);
330 f->mode = a->mode;
331 f->data = a->data + temp;
332 if (unsigned_p) /* Unsigned type. */
334 if (subtract_p) /* Unsigned subtraction. */
336 if (a->data.ult (b->data))
338 if (sat_p)
340 f->data.high = 0;
341 f->data.low = 0;
343 else
344 overflow_p = true;
347 else /* Unsigned addition. */
349 f->data = f->data.zext (i_f_bits);
350 if (f->data.ult (a->data)
351 || f->data.ult (b->data))
353 if (sat_p)
355 f->data.high = -1;
356 f->data.low = -1;
358 else
359 overflow_p = true;
363 else /* Signed type. */
365 if ((!subtract_p
366 && (get_fixed_sign_bit (a->data, i_f_bits)
367 == get_fixed_sign_bit (b->data, i_f_bits))
368 && (get_fixed_sign_bit (a->data, i_f_bits)
369 != get_fixed_sign_bit (f->data, i_f_bits)))
370 || (subtract_p
371 && (get_fixed_sign_bit (a->data, i_f_bits)
372 != get_fixed_sign_bit (b->data, i_f_bits))
373 && (get_fixed_sign_bit (a->data, i_f_bits)
374 != get_fixed_sign_bit (f->data, i_f_bits))))
376 if (sat_p)
378 f->data.low = 1;
379 f->data.high = 0;
380 f->data = f->data.alshift (i_f_bits, HOST_BITS_PER_DOUBLE_INT);
381 if (get_fixed_sign_bit (a->data, i_f_bits) == 0)
383 --f->data;
386 else
387 overflow_p = true;
390 f->data = f->data.ext ((!unsigned_p) + i_f_bits, unsigned_p);
391 return overflow_p;
394 /* Calculate F = A * B.
395 If SAT_P, saturate the result to the max or the min.
396 Return true, if !SAT_P and overflow. */
398 static bool
399 do_fixed_multiply (FIXED_VALUE_TYPE *f, const FIXED_VALUE_TYPE *a,
400 const FIXED_VALUE_TYPE *b, bool sat_p)
402 bool overflow_p = false;
403 bool unsigned_p = UNSIGNED_FIXED_POINT_MODE_P (a->mode);
404 int i_f_bits = GET_MODE_IBIT (a->mode) + GET_MODE_FBIT (a->mode);
405 f->mode = a->mode;
406 if (GET_MODE_PRECISION (f->mode) <= HOST_BITS_PER_WIDE_INT)
408 f->data = a->data * b->data;
409 f->data = f->data.lshift (-GET_MODE_FBIT (f->mode),
410 HOST_BITS_PER_DOUBLE_INT, !unsigned_p);
411 overflow_p = fixed_saturate1 (f->mode, f->data, &f->data, sat_p);
413 else
415 /* The result of multiplication expands to two double_int. */
416 double_int a_high, a_low, b_high, b_low;
417 double_int high_high, high_low, low_high, low_low;
418 double_int r, s, temp1, temp2;
419 int carry = 0;
421 /* Decompose a and b to four double_int. */
422 a_high.low = a->data.high;
423 a_high.high = 0;
424 a_low.low = a->data.low;
425 a_low.high = 0;
426 b_high.low = b->data.high;
427 b_high.high = 0;
428 b_low.low = b->data.low;
429 b_low.high = 0;
431 /* Perform four multiplications. */
432 low_low = a_low * b_low;
433 low_high = a_low * b_high;
434 high_low = a_high * b_low;
435 high_high = a_high * b_high;
437 /* Accumulate four results to {r, s}. */
438 temp1.high = high_low.low;
439 temp1.low = 0;
440 s = low_low + temp1;
441 if (s.ult (low_low)
442 || s.ult (temp1))
443 carry ++; /* Carry */
444 temp1.high = s.high;
445 temp1.low = s.low;
446 temp2.high = low_high.low;
447 temp2.low = 0;
448 s = temp1 + temp2;
449 if (s.ult (temp1)
450 || s.ult (temp2))
451 carry ++; /* Carry */
453 temp1.low = high_low.high;
454 temp1.high = 0;
455 r = high_high + temp1;
456 temp1.low = low_high.high;
457 temp1.high = 0;
458 r += temp1;
459 temp1.low = carry;
460 temp1.high = 0;
461 r += temp1;
463 /* We need to subtract b from r, if a < 0. */
464 if (!unsigned_p && a->data.high < 0)
465 r -= b->data;
466 /* We need to subtract a from r, if b < 0. */
467 if (!unsigned_p && b->data.high < 0)
468 r -= a->data;
470 /* Shift right the result by FBIT. */
471 if (GET_MODE_FBIT (f->mode) == HOST_BITS_PER_DOUBLE_INT)
473 s.low = r.low;
474 s.high = r.high;
475 if (unsigned_p)
477 r.low = 0;
478 r.high = 0;
480 else
482 r.low = -1;
483 r.high = -1;
485 f->data.low = s.low;
486 f->data.high = s.high;
488 else
490 s = s.llshift ((-GET_MODE_FBIT (f->mode)), HOST_BITS_PER_DOUBLE_INT);
491 f->data = r.llshift ((HOST_BITS_PER_DOUBLE_INT
492 - GET_MODE_FBIT (f->mode)),
493 HOST_BITS_PER_DOUBLE_INT);
494 f->data.low = f->data.low | s.low;
495 f->data.high = f->data.high | s.high;
496 s.low = f->data.low;
497 s.high = f->data.high;
498 r = r.lshift (-GET_MODE_FBIT (f->mode),
499 HOST_BITS_PER_DOUBLE_INT, !unsigned_p);
502 overflow_p = fixed_saturate2 (f->mode, r, s, &f->data, sat_p);
505 f->data = f->data.ext ((!unsigned_p) + i_f_bits, unsigned_p);
506 return overflow_p;
509 /* Calculate F = A / B.
510 If SAT_P, saturate the result to the max or the min.
511 Return true, if !SAT_P and overflow. */
513 static bool
514 do_fixed_divide (FIXED_VALUE_TYPE *f, const FIXED_VALUE_TYPE *a,
515 const FIXED_VALUE_TYPE *b, bool sat_p)
517 bool overflow_p = false;
518 bool unsigned_p = UNSIGNED_FIXED_POINT_MODE_P (a->mode);
519 int i_f_bits = GET_MODE_IBIT (a->mode) + GET_MODE_FBIT (a->mode);
520 f->mode = a->mode;
521 if (GET_MODE_PRECISION (f->mode) <= HOST_BITS_PER_WIDE_INT)
523 f->data = a->data.lshift (GET_MODE_FBIT (f->mode),
524 HOST_BITS_PER_DOUBLE_INT, !unsigned_p);
525 f->data = f->data.div (b->data, unsigned_p, TRUNC_DIV_EXPR);
526 overflow_p = fixed_saturate1 (f->mode, f->data, &f->data, sat_p);
528 else
530 double_int pos_a, pos_b, r, s;
531 double_int quo_r, quo_s, mod, temp;
532 int num_of_neg = 0;
533 int i;
535 /* If a < 0, negate a. */
536 if (!unsigned_p && a->data.high < 0)
538 pos_a = -a->data;
539 num_of_neg ++;
541 else
542 pos_a = a->data;
544 /* If b < 0, negate b. */
545 if (!unsigned_p && b->data.high < 0)
547 pos_b = -b->data;
548 num_of_neg ++;
550 else
551 pos_b = b->data;
553 /* Left shift pos_a to {r, s} by FBIT. */
554 if (GET_MODE_FBIT (f->mode) == HOST_BITS_PER_DOUBLE_INT)
556 r = pos_a;
557 s.high = 0;
558 s.low = 0;
560 else
562 s = pos_a.llshift (GET_MODE_FBIT (f->mode), HOST_BITS_PER_DOUBLE_INT);
563 r = pos_a.llshift (- (HOST_BITS_PER_DOUBLE_INT
564 - GET_MODE_FBIT (f->mode)),
565 HOST_BITS_PER_DOUBLE_INT);
568 /* Divide r by pos_b to quo_r. The remainder is in mod. */
569 quo_r = r.divmod (pos_b, 1, TRUNC_DIV_EXPR, &mod);
570 quo_s = double_int_zero;
572 for (i = 0; i < HOST_BITS_PER_DOUBLE_INT; i++)
574 /* Record the leftmost bit of mod. */
575 int leftmost_mod = (mod.high < 0);
577 /* Shift left mod by 1 bit. */
578 mod = mod.lshift (1);
580 /* Test the leftmost bit of s to add to mod. */
581 if (s.high < 0)
582 mod.low += 1;
584 /* Shift left quo_s by 1 bit. */
585 quo_s = quo_s.lshift (1);
587 /* Try to calculate (mod - pos_b). */
588 temp = mod - pos_b;
590 if (leftmost_mod == 1 || mod.ucmp (pos_b) != -1)
592 quo_s.low += 1;
593 mod = temp;
596 /* Shift left s by 1 bit. */
597 s = s.lshift (1);
601 if (num_of_neg == 1)
603 quo_s = -quo_s;
604 if (quo_s.high == 0 && quo_s.low == 0)
605 quo_r = -quo_r;
606 else
608 quo_r.low = ~quo_r.low;
609 quo_r.high = ~quo_r.high;
613 f->data = quo_s;
614 overflow_p = fixed_saturate2 (f->mode, quo_r, quo_s, &f->data, sat_p);
617 f->data = f->data.ext ((!unsigned_p) + i_f_bits, unsigned_p);
618 return overflow_p;
621 /* Calculate F = A << B if LEFT_P. Otherwise, F = A >> B.
622 If SAT_P, saturate the result to the max or the min.
623 Return true, if !SAT_P and overflow. */
625 static bool
626 do_fixed_shift (FIXED_VALUE_TYPE *f, const FIXED_VALUE_TYPE *a,
627 const FIXED_VALUE_TYPE *b, bool left_p, bool sat_p)
629 bool overflow_p = false;
630 bool unsigned_p = UNSIGNED_FIXED_POINT_MODE_P (a->mode);
631 int i_f_bits = GET_MODE_IBIT (a->mode) + GET_MODE_FBIT (a->mode);
632 f->mode = a->mode;
634 if (b->data.low == 0)
636 f->data = a->data;
637 return overflow_p;
640 if (GET_MODE_PRECISION (f->mode) <= HOST_BITS_PER_WIDE_INT || (!left_p))
642 f->data = a->data.lshift (left_p ? b->data.low : -b->data.low,
643 HOST_BITS_PER_DOUBLE_INT, !unsigned_p);
644 if (left_p) /* Only left shift saturates. */
645 overflow_p = fixed_saturate1 (f->mode, f->data, &f->data, sat_p);
647 else /* We need two double_int to store the left-shift result. */
649 double_int temp_high, temp_low;
650 if (b->data.low == HOST_BITS_PER_DOUBLE_INT)
652 temp_high = a->data;
653 temp_low.high = 0;
654 temp_low.low = 0;
656 else
658 temp_low = a->data.lshift (b->data.low,
659 HOST_BITS_PER_DOUBLE_INT, !unsigned_p);
660 /* Logical shift right to temp_high. */
661 temp_high = a->data.llshift (b->data.low - HOST_BITS_PER_DOUBLE_INT,
662 HOST_BITS_PER_DOUBLE_INT);
664 if (!unsigned_p && a->data.high < 0) /* Signed-extend temp_high. */
665 temp_high = temp_high.ext (b->data.low, unsigned_p);
666 f->data = temp_low;
667 overflow_p = fixed_saturate2 (f->mode, temp_high, temp_low, &f->data,
668 sat_p);
670 f->data = f->data.ext ((!unsigned_p) + i_f_bits, unsigned_p);
671 return overflow_p;
674 /* Calculate F = -A.
675 If SAT_P, saturate the result to the max or the min.
676 Return true, if !SAT_P and overflow. */
678 static bool
679 do_fixed_neg (FIXED_VALUE_TYPE *f, const FIXED_VALUE_TYPE *a, bool sat_p)
681 bool overflow_p = false;
682 bool unsigned_p = UNSIGNED_FIXED_POINT_MODE_P (a->mode);
683 int i_f_bits = GET_MODE_IBIT (a->mode) + GET_MODE_FBIT (a->mode);
684 f->mode = a->mode;
685 f->data = -a->data;
686 f->data = f->data.ext ((!unsigned_p) + i_f_bits, unsigned_p);
688 if (unsigned_p) /* Unsigned type. */
690 if (f->data.low != 0 || f->data.high != 0)
692 if (sat_p)
694 f->data.low = 0;
695 f->data.high = 0;
697 else
698 overflow_p = true;
701 else /* Signed type. */
703 if (!(f->data.high == 0 && f->data.low == 0)
704 && f->data.high == a->data.high && f->data.low == a->data.low )
706 if (sat_p)
708 /* Saturate to the maximum by subtracting f->data by one. */
709 f->data.low = -1;
710 f->data.high = -1;
711 f->data = f->data.zext (i_f_bits);
713 else
714 overflow_p = true;
717 return overflow_p;
720 /* Perform the binary or unary operation described by CODE.
721 Note that OP0 and OP1 must have the same mode for binary operators.
722 For a unary operation, leave OP1 NULL.
723 Return true, if !SAT_P and overflow. */
725 bool
726 fixed_arithmetic (FIXED_VALUE_TYPE *f, int icode, const FIXED_VALUE_TYPE *op0,
727 const FIXED_VALUE_TYPE *op1, bool sat_p)
729 switch (icode)
731 case NEGATE_EXPR:
732 return do_fixed_neg (f, op0, sat_p);
734 case PLUS_EXPR:
735 gcc_assert (op0->mode == op1->mode);
736 return do_fixed_add (f, op0, op1, false, sat_p);
738 case MINUS_EXPR:
739 gcc_assert (op0->mode == op1->mode);
740 return do_fixed_add (f, op0, op1, true, sat_p);
742 case MULT_EXPR:
743 gcc_assert (op0->mode == op1->mode);
744 return do_fixed_multiply (f, op0, op1, sat_p);
746 case TRUNC_DIV_EXPR:
747 gcc_assert (op0->mode == op1->mode);
748 return do_fixed_divide (f, op0, op1, sat_p);
750 case LSHIFT_EXPR:
751 return do_fixed_shift (f, op0, op1, true, sat_p);
753 case RSHIFT_EXPR:
754 return do_fixed_shift (f, op0, op1, false, sat_p);
756 default:
757 gcc_unreachable ();
759 return false;
762 /* Compare fixed-point values by tree_code.
763 Note that OP0 and OP1 must have the same mode. */
765 bool
766 fixed_compare (int icode, const FIXED_VALUE_TYPE *op0,
767 const FIXED_VALUE_TYPE *op1)
769 enum tree_code code = (enum tree_code) icode;
770 gcc_assert (op0->mode == op1->mode);
772 switch (code)
774 case NE_EXPR:
775 return op0->data != op1->data;
777 case EQ_EXPR:
778 return op0->data == op1->data;
780 case LT_EXPR:
781 return op0->data.cmp (op1->data,
782 UNSIGNED_FIXED_POINT_MODE_P (op0->mode)) == -1;
784 case LE_EXPR:
785 return op0->data.cmp (op1->data,
786 UNSIGNED_FIXED_POINT_MODE_P (op0->mode)) != 1;
788 case GT_EXPR:
789 return op0->data.cmp (op1->data,
790 UNSIGNED_FIXED_POINT_MODE_P (op0->mode)) == 1;
792 case GE_EXPR:
793 return op0->data.cmp (op1->data,
794 UNSIGNED_FIXED_POINT_MODE_P (op0->mode)) != -1;
796 default:
797 gcc_unreachable ();
801 /* Extend or truncate to a new mode.
802 If SAT_P, saturate the result to the max or the min.
803 Return true, if !SAT_P and overflow. */
805 bool
806 fixed_convert (FIXED_VALUE_TYPE *f, scalar_mode mode,
807 const FIXED_VALUE_TYPE *a, bool sat_p)
809 bool overflow_p = false;
810 if (mode == a->mode)
812 *f = *a;
813 return overflow_p;
816 if (GET_MODE_FBIT (mode) > GET_MODE_FBIT (a->mode))
818 /* Left shift a to temp_high, temp_low based on a->mode. */
819 double_int temp_high, temp_low;
820 int amount = GET_MODE_FBIT (mode) - GET_MODE_FBIT (a->mode);
821 temp_low = a->data.lshift (amount,
822 HOST_BITS_PER_DOUBLE_INT,
823 SIGNED_FIXED_POINT_MODE_P (a->mode));
824 /* Logical shift right to temp_high. */
825 temp_high = a->data.llshift (amount - HOST_BITS_PER_DOUBLE_INT,
826 HOST_BITS_PER_DOUBLE_INT);
827 if (SIGNED_FIXED_POINT_MODE_P (a->mode)
828 && a->data.high < 0) /* Signed-extend temp_high. */
829 temp_high = temp_high.sext (amount);
830 f->mode = mode;
831 f->data = temp_low;
832 if (SIGNED_FIXED_POINT_MODE_P (a->mode) ==
833 SIGNED_FIXED_POINT_MODE_P (f->mode))
834 overflow_p = fixed_saturate2 (f->mode, temp_high, temp_low, &f->data,
835 sat_p);
836 else
838 /* Take care of the cases when converting between signed and
839 unsigned. */
840 if (SIGNED_FIXED_POINT_MODE_P (a->mode))
842 /* Signed -> Unsigned. */
843 if (a->data.high < 0)
845 if (sat_p)
847 f->data.low = 0; /* Set to zero. */
848 f->data.high = 0; /* Set to zero. */
850 else
851 overflow_p = true;
853 else
854 overflow_p = fixed_saturate2 (f->mode, temp_high, temp_low,
855 &f->data, sat_p);
857 else
859 /* Unsigned -> Signed. */
860 if (temp_high.high < 0)
862 if (sat_p)
864 /* Set to maximum. */
865 f->data.low = -1; /* Set to all ones. */
866 f->data.high = -1; /* Set to all ones. */
867 f->data = f->data.zext (GET_MODE_FBIT (f->mode)
868 + GET_MODE_IBIT (f->mode));
869 /* Clear the sign. */
871 else
872 overflow_p = true;
874 else
875 overflow_p = fixed_saturate2 (f->mode, temp_high, temp_low,
876 &f->data, sat_p);
880 else
882 /* Right shift a to temp based on a->mode. */
883 double_int temp;
884 temp = a->data.lshift (GET_MODE_FBIT (mode) - GET_MODE_FBIT (a->mode),
885 HOST_BITS_PER_DOUBLE_INT,
886 SIGNED_FIXED_POINT_MODE_P (a->mode));
887 f->mode = mode;
888 f->data = temp;
889 if (SIGNED_FIXED_POINT_MODE_P (a->mode) ==
890 SIGNED_FIXED_POINT_MODE_P (f->mode))
891 overflow_p = fixed_saturate1 (f->mode, f->data, &f->data, sat_p);
892 else
894 /* Take care of the cases when converting between signed and
895 unsigned. */
896 if (SIGNED_FIXED_POINT_MODE_P (a->mode))
898 /* Signed -> Unsigned. */
899 if (a->data.high < 0)
901 if (sat_p)
903 f->data.low = 0; /* Set to zero. */
904 f->data.high = 0; /* Set to zero. */
906 else
907 overflow_p = true;
909 else
910 overflow_p = fixed_saturate1 (f->mode, f->data, &f->data,
911 sat_p);
913 else
915 /* Unsigned -> Signed. */
916 if (temp.high < 0)
918 if (sat_p)
920 /* Set to maximum. */
921 f->data.low = -1; /* Set to all ones. */
922 f->data.high = -1; /* Set to all ones. */
923 f->data = f->data.zext (GET_MODE_FBIT (f->mode)
924 + GET_MODE_IBIT (f->mode));
925 /* Clear the sign. */
927 else
928 overflow_p = true;
930 else
931 overflow_p = fixed_saturate1 (f->mode, f->data, &f->data,
932 sat_p);
937 f->data = f->data.ext (SIGNED_FIXED_POINT_MODE_P (f->mode)
938 + GET_MODE_FBIT (f->mode)
939 + GET_MODE_IBIT (f->mode),
940 UNSIGNED_FIXED_POINT_MODE_P (f->mode));
941 return overflow_p;
944 /* Convert to a new fixed-point mode from an integer.
945 If UNSIGNED_P, this integer is unsigned.
946 If SAT_P, saturate the result to the max or the min.
947 Return true, if !SAT_P and overflow. */
949 bool
950 fixed_convert_from_int (FIXED_VALUE_TYPE *f, scalar_mode mode,
951 double_int a, bool unsigned_p, bool sat_p)
953 bool overflow_p = false;
954 /* Left shift a to temp_high, temp_low. */
955 double_int temp_high, temp_low;
956 int amount = GET_MODE_FBIT (mode);
957 if (amount == HOST_BITS_PER_DOUBLE_INT)
959 temp_high = a;
960 temp_low.low = 0;
961 temp_low.high = 0;
963 else
965 temp_low = a.llshift (amount, HOST_BITS_PER_DOUBLE_INT);
967 /* Logical shift right to temp_high. */
968 temp_high = a.llshift (amount - HOST_BITS_PER_DOUBLE_INT,
969 HOST_BITS_PER_DOUBLE_INT);
971 if (!unsigned_p && a.high < 0) /* Signed-extend temp_high. */
972 temp_high = temp_high.sext (amount);
974 f->mode = mode;
975 f->data = temp_low;
977 if (unsigned_p == UNSIGNED_FIXED_POINT_MODE_P (f->mode))
978 overflow_p = fixed_saturate2 (f->mode, temp_high, temp_low, &f->data,
979 sat_p);
980 else
982 /* Take care of the cases when converting between signed and unsigned. */
983 if (!unsigned_p)
985 /* Signed -> Unsigned. */
986 if (a.high < 0)
988 if (sat_p)
990 f->data.low = 0; /* Set to zero. */
991 f->data.high = 0; /* Set to zero. */
993 else
994 overflow_p = true;
996 else
997 overflow_p = fixed_saturate2 (f->mode, temp_high, temp_low,
998 &f->data, sat_p);
1000 else
1002 /* Unsigned -> Signed. */
1003 if (temp_high.high < 0)
1005 if (sat_p)
1007 /* Set to maximum. */
1008 f->data.low = -1; /* Set to all ones. */
1009 f->data.high = -1; /* Set to all ones. */
1010 f->data = f->data.zext (GET_MODE_FBIT (f->mode)
1011 + GET_MODE_IBIT (f->mode));
1012 /* Clear the sign. */
1014 else
1015 overflow_p = true;
1017 else
1018 overflow_p = fixed_saturate2 (f->mode, temp_high, temp_low,
1019 &f->data, sat_p);
1022 f->data = f->data.ext (SIGNED_FIXED_POINT_MODE_P (f->mode)
1023 + GET_MODE_FBIT (f->mode)
1024 + GET_MODE_IBIT (f->mode),
1025 UNSIGNED_FIXED_POINT_MODE_P (f->mode));
1026 return overflow_p;
1029 /* Convert to a new fixed-point mode from a real.
1030 If SAT_P, saturate the result to the max or the min.
1031 Return true, if !SAT_P and overflow. */
1033 bool
1034 fixed_convert_from_real (FIXED_VALUE_TYPE *f, scalar_mode mode,
1035 const REAL_VALUE_TYPE *a, bool sat_p)
1037 bool overflow_p = false;
1038 REAL_VALUE_TYPE real_value, fixed_value, base_value;
1039 bool unsigned_p = UNSIGNED_FIXED_POINT_MODE_P (mode);
1040 int i_f_bits = GET_MODE_IBIT (mode) + GET_MODE_FBIT (mode);
1041 unsigned int fbit = GET_MODE_FBIT (mode);
1042 enum fixed_value_range_code temp;
1043 bool fail;
1045 real_value = *a;
1046 f->mode = mode;
1047 real_2expN (&base_value, fbit, VOIDmode);
1048 real_arithmetic (&fixed_value, MULT_EXPR, &real_value, &base_value);
1050 wide_int w = real_to_integer (&fixed_value, &fail,
1051 GET_MODE_PRECISION (mode));
1052 f->data.low = w.ulow ();
1053 f->data.high = w.elt (1);
1054 temp = check_real_for_fixed_mode (&real_value, mode);
1055 if (temp == FIXED_UNDERFLOW) /* Minimum. */
1057 if (sat_p)
1059 if (unsigned_p)
1061 f->data.low = 0;
1062 f->data.high = 0;
1064 else
1066 f->data.low = 1;
1067 f->data.high = 0;
1068 f->data = f->data.alshift (i_f_bits, HOST_BITS_PER_DOUBLE_INT);
1069 f->data = f->data.sext (1 + i_f_bits);
1072 else
1073 overflow_p = true;
1075 else if (temp == FIXED_GT_MAX_EPS || temp == FIXED_MAX_EPS) /* Maximum. */
1077 if (sat_p)
1079 f->data.low = -1;
1080 f->data.high = -1;
1081 f->data = f->data.zext (i_f_bits);
1083 else
1084 overflow_p = true;
1086 f->data = f->data.ext ((!unsigned_p) + i_f_bits, unsigned_p);
1087 return overflow_p;
1090 /* Convert to a new real mode from a fixed-point. */
1092 void
1093 real_convert_from_fixed (REAL_VALUE_TYPE *r, scalar_mode mode,
1094 const FIXED_VALUE_TYPE *f)
1096 REAL_VALUE_TYPE base_value, fixed_value, real_value;
1098 signop sgn = UNSIGNED_FIXED_POINT_MODE_P (f->mode) ? UNSIGNED : SIGNED;
1099 real_2expN (&base_value, GET_MODE_FBIT (f->mode), VOIDmode);
1100 real_from_integer (&fixed_value, VOIDmode,
1101 wide_int::from (f->data, GET_MODE_PRECISION (f->mode),
1102 sgn), sgn);
1103 real_arithmetic (&real_value, RDIV_EXPR, &fixed_value, &base_value);
1104 real_convert (r, mode, &real_value);
1107 /* Determine whether a fixed-point value F is negative. */
1109 bool
1110 fixed_isneg (const FIXED_VALUE_TYPE *f)
1112 if (SIGNED_FIXED_POINT_MODE_P (f->mode))
1114 int i_f_bits = GET_MODE_IBIT (f->mode) + GET_MODE_FBIT (f->mode);
1115 int sign_bit = get_fixed_sign_bit (f->data, i_f_bits);
1116 if (sign_bit == 1)
1117 return true;
1120 return false;