392 lines
12 KiB
C
392 lines
12 KiB
C
/***********************************************************************/
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/* */
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/* Objective Caml */
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/* */
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/* Xavier Leroy, projet Cristal, INRIA Rocquencourt */
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/* */
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/* Copyright 1996 Institut National de Recherche en Informatique et */
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/* en Automatique. All rights reserved. This file is distributed */
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/* under the terms of the GNU Library General Public License, with */
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/* the special exception on linking described in file ../../LICENSE. */
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/* */
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/***********************************************************************/
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/* $Id$ */
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#include "alloc.h"
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#include "config.h"
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#include "custom.h"
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#include "intext.h"
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#include "fail.h"
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#include "memory.h"
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#include "mlvalues.h"
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#include "bng.h"
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#include "nat.h"
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/* Stub code for the Nat module. */
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static void serialize_nat(value, uintnat *, uintnat *);
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static uintnat deserialize_nat(void * dst);
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static struct custom_operations nat_operations = {
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"_nat",
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custom_finalize_default,
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custom_compare_default,
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custom_hash_default,
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serialize_nat,
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deserialize_nat
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};
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CAMLprim value initialize_nat(value unit)
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{
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bng_init();
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register_custom_operations(&nat_operations);
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return Val_unit;
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}
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CAMLprim value create_nat(value size)
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{
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mlsize_t sz = Long_val(size);
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return alloc_custom(&nat_operations, sz * sizeof(value), 0, 1);
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}
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CAMLprim value length_nat(value nat)
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{
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return Val_long(Wosize_val(nat) - 1);
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}
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CAMLprim value set_to_zero_nat(value nat, value ofs, value len)
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{
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bng_zero(&Digit_val(nat, Long_val(ofs)), Long_val(len));
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return Val_unit;
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}
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CAMLprim value blit_nat(value nat1, value ofs1,
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value nat2, value ofs2,
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value len)
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{
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bng_assign(&Digit_val(nat1, Long_val(ofs1)),
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&Digit_val(nat2, Long_val(ofs2)),
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Long_val(len));
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return Val_unit;
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}
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CAMLprim value set_digit_nat(value nat, value ofs, value digit)
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{
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Digit_val(nat, Long_val(ofs)) = Long_val(digit);
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return Val_unit;
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}
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CAMLprim value nth_digit_nat(value nat, value ofs)
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{
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return Val_long(Digit_val(nat, Long_val(ofs)));
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}
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CAMLprim value set_digit_nat_native(value nat, value ofs, value digit)
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{
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Digit_val(nat, Long_val(ofs)) = Nativeint_val(digit);
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return Val_unit;
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}
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CAMLprim value nth_digit_nat_native(value nat, value ofs)
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{
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return caml_copy_nativeint(Digit_val(nat, Long_val(ofs)));
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}
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CAMLprim value num_digits_nat(value nat, value ofs, value len)
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{
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return Val_long(bng_num_digits(&Digit_val(nat, Long_val(ofs)),
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Long_val(len)));
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}
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CAMLprim value num_leading_zero_bits_in_digit(value nat, value ofs)
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{
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return
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Val_long(bng_leading_zero_bits(Digit_val(nat, Long_val(ofs))));
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}
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CAMLprim value is_digit_int(value nat, value ofs)
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{
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return Val_bool(Digit_val(nat, Long_val(ofs)) <= Max_long);
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}
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CAMLprim value is_digit_zero(value nat, value ofs)
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{
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return Val_bool(Digit_val(nat, Long_val(ofs)) == 0);
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}
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CAMLprim value is_digit_normalized(value nat, value ofs)
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{
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return
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Val_bool(Digit_val(nat, Long_val(ofs)) & ((bngdigit)1 << (BNG_BITS_PER_DIGIT-1)));
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}
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CAMLprim value is_digit_odd(value nat, value ofs)
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{
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return Val_bool(Digit_val(nat, Long_val(ofs)) & 1);
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}
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CAMLprim value incr_nat(value nat, value ofs, value len, value carry_in)
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{
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return Val_long(bng_add_carry(&Digit_val(nat, Long_val(ofs)),
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Long_val(len), Long_val(carry_in)));
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}
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value add_nat_native(value nat1, value ofs1, value len1,
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value nat2, value ofs2, value len2, value carry_in)
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{
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return Val_long(bng_add(&Digit_val(nat1, Long_val(ofs1)), Long_val(len1),
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&Digit_val(nat2, Long_val(ofs2)), Long_val(len2),
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Long_val(carry_in)));
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}
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CAMLprim value add_nat(value *argv, int argn)
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{
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return add_nat_native(argv[0], argv[1], argv[2], argv[3],
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argv[4], argv[5], argv[6]);
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}
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CAMLprim value complement_nat(value nat, value ofs, value len)
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{
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bng_complement(&Digit_val(nat, Long_val(ofs)), Long_val(len));
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return Val_unit;
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}
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CAMLprim value decr_nat(value nat, value ofs, value len, value carry_in)
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{
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return Val_long(1 ^ bng_sub_carry(&Digit_val(nat, Long_val(ofs)),
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Long_val(len), 1 ^ Long_val(carry_in)));
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}
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value sub_nat_native(value nat1, value ofs1, value len1,
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value nat2, value ofs2, value len2, value carry_in)
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{
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return Val_long(1 ^ bng_sub(&Digit_val(nat1, Long_val(ofs1)), Long_val(len1),
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&Digit_val(nat2, Long_val(ofs2)), Long_val(len2),
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1 ^ Long_val(carry_in)));
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}
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CAMLprim value sub_nat(value *argv, int argn)
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{
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return sub_nat_native(argv[0], argv[1], argv[2], argv[3],
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argv[4], argv[5], argv[6]);
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}
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value mult_digit_nat_native(value nat1, value ofs1, value len1,
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value nat2, value ofs2, value len2,
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value nat3, value ofs3)
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{
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return
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Val_long(bng_mult_add_digit(
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&Digit_val(nat1, Long_val(ofs1)), Long_val(len1),
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&Digit_val(nat2, Long_val(ofs2)), Long_val(len2),
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Digit_val(nat3, Long_val(ofs3))));
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}
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CAMLprim value mult_digit_nat(value *argv, int argn)
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{
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return mult_digit_nat_native(argv[0], argv[1], argv[2], argv[3],
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argv[4], argv[5], argv[6], argv[7]);
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}
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value mult_nat_native(value nat1, value ofs1, value len1,
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value nat2, value ofs2, value len2,
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value nat3, value ofs3, value len3)
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{
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return
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Val_long(bng_mult_add(&Digit_val(nat1, Long_val(ofs1)), Long_val(len1),
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&Digit_val(nat2, Long_val(ofs2)), Long_val(len2),
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&Digit_val(nat3, Long_val(ofs3)), Long_val(len3)));
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}
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CAMLprim value mult_nat(value *argv, int argn)
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{
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return mult_nat_native(argv[0], argv[1], argv[2], argv[3],
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argv[4], argv[5], argv[6], argv[7], argv[8]);
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}
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value square_nat_native(value nat1, value ofs1, value len1,
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value nat2, value ofs2, value len2)
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{
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return
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Val_long(bng_square_add(&Digit_val(nat1, Long_val(ofs1)), Long_val(len1),
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&Digit_val(nat2, Long_val(ofs2)), Long_val(len2)));
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}
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CAMLprim value square_nat(value *argv, int argn)
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{
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return square_nat_native(argv[0], argv[1], argv[2],
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argv[3], argv[4], argv[5]);
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}
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value shift_left_nat_native(value nat1, value ofs1, value len1,
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value nat2, value ofs2, value nbits)
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{
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Digit_val(nat2, Long_val(ofs2)) =
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bng_shift_left(&Digit_val(nat1, Long_val(ofs1)), Long_val(len1),
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Long_val(nbits));
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return Val_unit;
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}
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CAMLprim value shift_left_nat(value *argv, int argn)
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{
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return shift_left_nat_native(argv[0], argv[1], argv[2],
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argv[3], argv[4], argv[5]);
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}
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value div_digit_nat_native(value natq, value ofsq,
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value natr, value ofsr,
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value nat1, value ofs1, value len1,
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value nat2, value ofs2)
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{
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Digit_val(natr, Long_val(ofsr)) =
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bng_div_rem_digit(&Digit_val(natq, Long_val(ofsq)),
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&Digit_val(nat1, Long_val(ofs1)), Long_val(len1),
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Digit_val(nat2, Long_val(ofs2)));
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return Val_unit;
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}
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CAMLprim value div_digit_nat(value *argv, int argn)
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{
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return div_digit_nat_native(argv[0], argv[1], argv[2], argv[3],
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argv[4], argv[5], argv[6], argv[7], argv[8]);
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}
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value div_nat_native(value nat1, value ofs1, value len1,
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value nat2, value ofs2, value len2)
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{
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bng_div_rem(&Digit_val(nat1, Long_val(ofs1)), Long_val(len1),
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&Digit_val(nat2, Long_val(ofs2)), Long_val(len2));
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return Val_unit;
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}
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CAMLprim value div_nat(value *argv, int argn)
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{
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return div_nat_native(argv[0], argv[1], argv[2],
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argv[3], argv[4], argv[5]);
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}
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value shift_right_nat_native(value nat1, value ofs1, value len1,
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value nat2, value ofs2, value nbits)
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{
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Digit_val(nat2, Long_val(ofs2)) =
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bng_shift_right(&Digit_val(nat1, Long_val(ofs1)), Long_val(len1),
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Long_val(nbits));
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return Val_unit;
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}
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CAMLprim value shift_right_nat(value *argv, int argn)
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{
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return shift_right_nat_native(argv[0], argv[1], argv[2],
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argv[3], argv[4], argv[5]);
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}
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CAMLprim value compare_digits_nat(value nat1, value ofs1,
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value nat2, value ofs2)
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{
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bngdigit d1 = Digit_val(nat1, Long_val(ofs1));
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bngdigit d2 = Digit_val(nat2, Long_val(ofs2));
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if (d1 > d2) return Val_int(1);
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if (d1 < d2) return Val_int(-1);
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return Val_int(0);
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}
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value compare_nat_native(value nat1, value ofs1, value len1,
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value nat2, value ofs2, value len2)
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{
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return
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Val_int(bng_compare(&Digit_val(nat1, Long_val(ofs1)), Long_val(len1),
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&Digit_val(nat2, Long_val(ofs2)), Long_val(len2)));
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}
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CAMLprim value compare_nat(value *argv, int argn)
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{
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return compare_nat_native(argv[0], argv[1], argv[2],
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argv[3], argv[4], argv[5]);
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}
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CAMLprim value land_digit_nat(value nat1, value ofs1, value nat2, value ofs2)
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{
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Digit_val(nat1, Long_val(ofs1)) &= Digit_val(nat2, Long_val(ofs2));
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return Val_unit;
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}
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CAMLprim value lor_digit_nat(value nat1, value ofs1, value nat2, value ofs2)
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{
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Digit_val(nat1, Long_val(ofs1)) |= Digit_val(nat2, Long_val(ofs2));
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return Val_unit;
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}
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CAMLprim value lxor_digit_nat(value nat1, value ofs1, value nat2, value ofs2)
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{
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Digit_val(nat1, Long_val(ofs1)) ^= Digit_val(nat2, Long_val(ofs2));
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return Val_unit;
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}
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/* The wire format for a nat is:
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- 32-bit word: number of 32-bit words in nat
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- N 32-bit words (big-endian format)
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For little-endian platforms, the memory layout between 32-bit and 64-bit
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machines is identical, so we can write the nat using serialize_block_4.
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For big-endian 64-bit platforms, we need to swap the two 32-bit halves
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of 64-bit words to obtain the correct behavior. */
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static void serialize_nat(value nat,
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uintnat * wsize_32,
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uintnat * wsize_64)
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{
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mlsize_t len = Wosize_val(nat) - 1;
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#ifdef ARCH_SIXTYFOUR
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len = len * 2; /* two 32-bit words per 64-bit digit */
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if (len >= ((mlsize_t)1 << 32))
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failwith("output_value: nat too big");
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#endif
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serialize_int_4((int32) len);
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#if defined(ARCH_SIXTYFOUR) && defined(ARCH_BIG_ENDIAN)
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{ int32 * p;
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mlsize_t i;
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for (i = len, p = Data_custom_val(nat); i > 0; i -= 2, p += 2) {
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serialize_int_4(p[1]); /* low 32 bits of 64-bit digit */
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serialize_int_4(p[0]); /* high 32 bits of 64-bit digit */
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}
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}
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#else
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serialize_block_4(Data_custom_val(nat), len);
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#endif
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*wsize_32 = len * 4;
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*wsize_64 = len * 4;
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}
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static uintnat deserialize_nat(void * dst)
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{
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mlsize_t len;
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len = deserialize_uint_4();
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#if defined(ARCH_SIXTYFOUR) && defined(ARCH_BIG_ENDIAN)
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{ uint32 * p;
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mlsize_t i;
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for (i = len, p = dst; i > 1; i -= 2, p += 2) {
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p[1] = deserialize_uint_4(); /* low 32 bits of 64-bit digit */
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p[0] = deserialize_uint_4(); /* high 32 bits of 64-bit digit */
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}
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if (i > 0){
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p[1] = deserialize_uint_4(); /* low 32 bits of 64-bit digit */
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p[0] = 0; /* high 32 bits of 64-bit digit */
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++ len;
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}
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}
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#else
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deserialize_block_4(dst, len);
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#if defined(ARCH_SIXTYFOUR)
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if (len & 1){
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((uint32 *) dst)[len] = 0;
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++ len;
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}
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#endif
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#endif
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return len * 4;
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}
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