ocaml/byterun/compare.c

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/***********************************************************************/
/* */
/* Objective Caml */
/* */
/* Xavier Leroy, projet Cristal, INRIA Rocquencourt */
/* */
/* Copyright 1996 Institut National de Recherche en Informatique et */
/* en Automatique. All rights reserved. This file is distributed */
/* under the terms of the GNU Library General Public License, with */
/* the special exception on linking described in file ../LICENSE. */
/* */
/***********************************************************************/
/* $Id$ */
#include <string.h>
#include <stdlib.h>
#include "custom.h"
#include "fail.h"
#include "memory.h"
#include "misc.h"
#include "mlvalues.h"
/* Structural comparison on trees. */
struct compare_item { value * v1, * v2; mlsize_t count; };
#define COMPARE_STACK_INIT_SIZE 256
#define COMPARE_STACK_MAX_SIZE (1024*1024)
static struct compare_item compare_stack_init[COMPARE_STACK_INIT_SIZE];
static struct compare_item * compare_stack = compare_stack_init;
static struct compare_item * compare_stack_limit = compare_stack_init
+ COMPARE_STACK_INIT_SIZE;
CAMLexport int caml_compare_unordered;
/* Free the compare stack if needed */
static void compare_free_stack(void)
{
if (compare_stack != compare_stack_init) {
free(compare_stack);
/* Reinitialize the globals for next time around */
compare_stack = compare_stack_init;
compare_stack_limit = compare_stack + COMPARE_STACK_INIT_SIZE;
}
}
/* Same, then raise Out_of_memory */
static void compare_stack_overflow(void)
{
caml_gc_message (0x04, "Stack overflow in structural comparison\n", 0);
compare_free_stack();
caml_raise_out_of_memory();
}
/* Grow the compare stack */
static struct compare_item * compare_resize_stack(struct compare_item * sp)
{
asize_t newsize = 2 * (compare_stack_limit - compare_stack);
asize_t sp_offset = sp - compare_stack;
struct compare_item * newstack;
if (newsize >= COMPARE_STACK_MAX_SIZE) compare_stack_overflow();
if (compare_stack == compare_stack_init) {
newstack = malloc(sizeof(struct compare_item) * newsize);
if (newstack == NULL) compare_stack_overflow();
memcpy(newstack, compare_stack_init,
sizeof(struct compare_item) * COMPARE_STACK_INIT_SIZE);
} else {
newstack =
realloc(compare_stack, sizeof(struct compare_item) * newsize);
if (newstack == NULL) compare_stack_overflow();
}
compare_stack = newstack;
compare_stack_limit = newstack + newsize;
return newstack + sp_offset;
}
/* Structural comparison */
#define LESS -1
#define EQUAL 0
#define GREATER 1
#define UNORDERED (1L << (8 * sizeof(value) - 1))
/* The return value of compare_val is as follows:
> 0 v1 is greater than v2
0 v1 is equal to v2
< 0 and > UNORDERED v1 is less than v2
UNORDERED v1 and v2 cannot be compared */
static intnat compare_val(value v1, value v2, int total)
{
struct compare_item * sp;
tag_t t1, t2;
sp = compare_stack;
while (1) {
if (v1 == v2 && total) goto next_item;
if (Is_long(v1)) {
if (v1 == v2) goto next_item;
if (Is_long(v2))
return Long_val(v1) - Long_val(v2);
/* Subtraction above cannot overflow and cannot result in UNORDERED */
if ((Is_atom(v2) || Is_young(v2) || Is_in_heap(v2)) &&
Tag_val(v2) == Forward_tag) {
v2 = Forward_val(v2);
continue;
}
return LESS; /* v1 long < v2 block */
}
if (Is_long(v2)) {
if ((Is_atom(v1) || Is_young(v1) || Is_in_heap(v1)) &&
Tag_val(v1) == Forward_tag) {
v1 = Forward_val(v1);
continue;
}
return GREATER; /* v1 block > v2 long */
}
/* If one of the objects is outside the heap (but is not an atom),
use address comparison. Since both addresses are 2-aligned,
shift lsb off to avoid overflow in subtraction. */
if ((!Is_atom(v1) && !Is_young(v1) && !Is_in_heap(v1)) ||
(!Is_atom(v2) && !Is_young(v2) && !Is_in_heap(v2))) {
if (v1 == v2) goto next_item;
return (v1 >> 1) - (v2 >> 1);
/* Subtraction above cannot result in UNORDERED */
}
t1 = Tag_val(v1);
t2 = Tag_val(v2);
if (t1 == Forward_tag) { v1 = Forward_val (v1); continue; }
if (t2 == Forward_tag) { v2 = Forward_val (v2); continue; }
if (t1 != t2) return (intnat)t1 - (intnat)t2;
switch(t1) {
case String_tag: {
mlsize_t len1, len2, len;
unsigned char * p1, * p2;
if (v1 == v2) break;
len1 = caml_string_length(v1);
len2 = caml_string_length(v2);
for (len = (len1 <= len2 ? len1 : len2),
p1 = (unsigned char *) String_val(v1),
p2 = (unsigned char *) String_val(v2);
len > 0;
len--, p1++, p2++)
if (*p1 != *p2) return (intnat)*p1 - (intnat)*p2;
if (len1 != len2) return len1 - len2;
break;
}
case Double_tag: {
double d1 = Double_val(v1);
double d2 = Double_val(v2);
if (d1 < d2) return LESS;
if (d1 > d2) return GREATER;
if (d1 != d2) {
if (! total) return UNORDERED;
/* One or both of d1 and d2 is NaN. Order according to the
convention NaN = NaN and NaN < f for all other floats f. */
if (d1 == d1) return GREATER; /* d1 is not NaN, d2 is NaN */
if (d2 == d2) return LESS; /* d2 is not NaN, d1 is NaN */
/* d1 and d2 are both NaN, thus equal: continue comparison */
}
break;
}
case Double_array_tag: {
mlsize_t sz1 = Wosize_val(v1) / Double_wosize;
mlsize_t sz2 = Wosize_val(v2) / Double_wosize;
mlsize_t i;
if (sz1 != sz2) return sz1 - sz2;
for (i = 0; i < sz1; i++) {
double d1 = Double_field(v1, i);
double d2 = Double_field(v2, i);
if (d1 < d2) return LESS;
if (d1 > d2) return GREATER;
if (d1 != d2) {
if (! total) return UNORDERED;
/* See comment for Double_tag case */
if (d1 == d1) return GREATER;
if (d2 == d2) return LESS;
}
}
break;
}
case Abstract_tag:
compare_free_stack();
caml_invalid_argument("equal: abstract value");
case Closure_tag:
case Infix_tag:
compare_free_stack();
caml_invalid_argument("equal: functional value");
case Object_tag: {
intnat oid1 = Oid_val(v1);
intnat oid2 = Oid_val(v2);
if (oid1 != oid2) return oid1 - oid2;
break;
}
case Custom_tag: {
int res;
int (*compare)(value v1, value v2) = Custom_ops_val(v1)->compare;
if (compare == NULL) caml_invalid_argument("equal: abstract value");
caml_compare_unordered = 0;
res = Custom_ops_val(v1)->compare(v1, v2);
if (caml_compare_unordered && !total) return UNORDERED;
if (res != 0) return res;
break;
}
default: {
mlsize_t sz1 = Wosize_val(v1);
mlsize_t sz2 = Wosize_val(v2);
/* Compare sizes first for speed */
if (sz1 != sz2) return sz1 - sz2;
if (sz1 == 0) break;
/* Remember that we still have to compare fields 1 ... sz - 1 */
if (sz1 > 1) {
sp++;
if (sp >= compare_stack_limit) sp = compare_resize_stack(sp);
sp->v1 = &Field(v1, 1);
sp->v2 = &Field(v2, 1);
sp->count = sz1 - 1;
}
/* Continue comparison with first field */
v1 = Field(v1, 0);
v2 = Field(v2, 0);
continue;
}
}
next_item:
/* Pop one more item to compare, if any */
if (sp == compare_stack) return EQUAL; /* we're done */
v1 = *((sp->v1)++);
v2 = *((sp->v2)++);
if (--(sp->count) == 0) sp--;
}
}
CAMLprim value caml_compare(value v1, value v2)
{
intnat res = compare_val(v1, v2, 1);
/* Free stack if needed */
if (compare_stack != compare_stack_init) compare_free_stack();
if (res < 0)
return Val_int(LESS);
else if (res > 0)
return Val_int(GREATER);
else
return Val_int(EQUAL);
}
CAMLprim value caml_equal(value v1, value v2)
{
intnat res = compare_val(v1, v2, 0);
if (compare_stack != compare_stack_init) compare_free_stack();
return Val_int(res == 0);
}
CAMLprim value caml_notequal(value v1, value v2)
{
intnat res = compare_val(v1, v2, 0);
if (compare_stack != compare_stack_init) compare_free_stack();
return Val_int(res != 0);
}
CAMLprim value caml_lessthan(value v1, value v2)
{
intnat res = compare_val(v1, v2, 0);
if (compare_stack != compare_stack_init) compare_free_stack();
return Val_int(res - 1 < -1);
}
CAMLprim value caml_lessequal(value v1, value v2)
{
intnat res = compare_val(v1, v2, 0);
if (compare_stack != compare_stack_init) compare_free_stack();
return Val_int(res - 1 <= -1);
}
CAMLprim value caml_greaterthan(value v1, value v2)
{
intnat res = compare_val(v1, v2, 0);
if (compare_stack != compare_stack_init) compare_free_stack();
return Val_int(res > 0);
}
CAMLprim value caml_greaterequal(value v1, value v2)
{
intnat res = compare_val(v1, v2, 0);
if (compare_stack != compare_stack_init) compare_free_stack();
return Val_int(res >= 0);
}