/**************************************************************************/ /* */ /* OCaml */ /* */ /* 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 Lesser General Public License version 2.1, with the */ /* special exception on linking described in the file LICENSE. */ /* */ /**************************************************************************/ #define CAML_INTERNALS #include #include #include "caml/alloc.h" #include "caml/custom.h" #include "caml/fail.h" #include "caml/intext.h" #include "caml/memory.h" #include "caml/misc.h" #include "caml/mlvalues.h" static const char * parse_sign_and_base(const char * p, /*out*/ int * base, /*out*/ int * signedness, /*out*/ int * sign) { *sign = 1; if (*p == '-') { *sign = -1; p++; } else if (*p == '+') p++; *base = 10; *signedness = 1; if (*p == '0') { switch (p[1]) { case 'x': case 'X': *base = 16; *signedness = 0; p += 2; break; case 'o': case 'O': *base = 8; *signedness = 0; p += 2; break; case 'b': case 'B': *base = 2; *signedness = 0; p += 2; break; case 'u': case 'U': *signedness = 0; p += 2; break; } } return p; } static int parse_digit(char c) { if (c >= '0' && c <= '9') return c - '0'; else if (c >= 'A' && c <= 'F') return c - 'A' + 10; else if (c >= 'a' && c <= 'f') return c - 'a' + 10; else return -1; } #define INT_ERRMSG "int_of_string" #define INT32_ERRMSG "Int32.of_string" #define INT64_ERRMSG "Int64.of_string" #define INTNAT_ERRMSG "Nativeint.of_string" static intnat parse_intnat(value s, int nbits, const char *errmsg) { const char * p; uintnat res, threshold; int sign, base, signedness, d; p = parse_sign_and_base(String_val(s), &base, &signedness, &sign); threshold = ((uintnat) -1) / base; d = parse_digit(*p); if (d < 0 || d >= base) caml_failwith(errmsg); for (p++, res = d; /*nothing*/; p++) { char c = *p; if (c == '_') continue; d = parse_digit(c); if (d < 0 || d >= base) break; /* Detect overflow in multiplication base * res */ if (res > threshold) caml_failwith(errmsg); res = base * res + d; /* Detect overflow in addition (base * res) + d */ if (res < (uintnat) d) caml_failwith(errmsg); } if (p != String_val(s) + caml_string_length(s)){ caml_failwith(errmsg); } if (signedness) { /* Signed representation expected, allow -2^(nbits-1) to 2^(nbits-1) - 1 */ if (sign >= 0) { if (res >= (uintnat)1 << (nbits - 1)) caml_failwith(errmsg); } else { if (res > (uintnat)1 << (nbits - 1)) caml_failwith(errmsg); } } else { /* Unsigned representation expected, allow 0 to 2^nbits - 1 and tolerate -(2^nbits - 1) to 0 */ if (nbits < sizeof(uintnat) * 8 && res >= (uintnat)1 << nbits) caml_failwith(errmsg); } return sign < 0 ? -((intnat) res) : (intnat) res; } value caml_bswap16_direct(value x) { return ((((x & 0x00FF) << 8) | ((x & 0xFF00) >> 8))); } CAMLprim value caml_bswap16(value v) { intnat x = Int_val(v); return (Val_int ((((x & 0x00FF) << 8) | ((x & 0xFF00) >> 8)))); } /* Tagged integers */ CAMLprim value caml_int_compare(value v1, value v2) { int res = (v1 > v2) - (v1 < v2); return Val_int(res); } CAMLprim value caml_int_of_string(value s) { return Val_long(parse_intnat(s, 8 * sizeof(value) - 1, INT_ERRMSG)); } #define FORMAT_BUFFER_SIZE 32 static char parse_format(value fmt, char * suffix, char format_string[FORMAT_BUFFER_SIZE]) { char * p; char lastletter; mlsize_t len, len_suffix; /* Copy OCaml format fmt to format_string, adding the suffix before the last letter of the format */ len = caml_string_length(fmt); len_suffix = strlen(suffix); if (len + len_suffix + 1 >= FORMAT_BUFFER_SIZE) caml_invalid_argument("format_int: format too long"); memmove(format_string, String_val(fmt), len); p = format_string + len - 1; lastletter = *p; /* Compress two-letter formats, ignoring the [lnL] annotation */ if (p[-1] == 'l' || p[-1] == 'n' || p[-1] == 'L') p--; memmove(p, suffix, len_suffix); p += len_suffix; *p++ = lastletter; *p = 0; /* Return the conversion type (last letter) */ return lastletter; } CAMLprim value caml_format_int(value fmt, value arg) { char format_string[FORMAT_BUFFER_SIZE]; char conv; value res; conv = parse_format(fmt, ARCH_INTNAT_PRINTF_FORMAT, format_string); switch (conv) { case 'u': case 'x': case 'X': case 'o': res = caml_alloc_sprintf(format_string, Unsigned_long_val(arg)); break; default: res = caml_alloc_sprintf(format_string, Long_val(arg)); break; } return res; } /* 32-bit integers */ static int int32_cmp(value v1, value v2) { int32_t i1 = Int32_val(v1); int32_t i2 = Int32_val(v2); return (i1 > i2) - (i1 < i2); } static intnat int32_hash(value v) { return Int32_val(v); } static void int32_serialize(value v, uintnat * bsize_32, uintnat * bsize_64) { caml_serialize_int_4(Int32_val(v)); *bsize_32 = *bsize_64 = 4; } static uintnat int32_deserialize(void * dst) { *((int32_t *) dst) = caml_deserialize_sint_4(); return 4; } CAMLexport struct custom_operations caml_int32_ops = { "_i", custom_finalize_default, int32_cmp, int32_hash, int32_serialize, int32_deserialize, custom_compare_ext_default }; CAMLexport value caml_copy_int32(int32_t i) { value res = caml_alloc_custom(&caml_int32_ops, 4, 0, 1); Int32_val(res) = i; return res; } CAMLprim value caml_int32_neg(value v) { return caml_copy_int32(- Int32_val(v)); } CAMLprim value caml_int32_add(value v1, value v2) { return caml_copy_int32(Int32_val(v1) + Int32_val(v2)); } CAMLprim value caml_int32_sub(value v1, value v2) { return caml_copy_int32(Int32_val(v1) - Int32_val(v2)); } CAMLprim value caml_int32_mul(value v1, value v2) { return caml_copy_int32(Int32_val(v1) * Int32_val(v2)); } CAMLprim value caml_int32_div(value v1, value v2) { int32_t dividend = Int32_val(v1); int32_t divisor = Int32_val(v2); if (divisor == 0) caml_raise_zero_divide(); /* PR#4740: on some processors, division crashes on overflow. Implement the same behavior as for type "int". */ if (dividend == (1<<31) && divisor == -1) return v1; return caml_copy_int32(dividend / divisor); } CAMLprim value caml_int32_mod(value v1, value v2) { int32_t dividend = Int32_val(v1); int32_t divisor = Int32_val(v2); if (divisor == 0) caml_raise_zero_divide(); /* PR#4740: on some processors, modulus crashes if division overflows. Implement the same behavior as for type "int". */ if (dividend == (1<<31) && divisor == -1) return caml_copy_int32(0); return caml_copy_int32(dividend % divisor); } CAMLprim value caml_int32_and(value v1, value v2) { return caml_copy_int32(Int32_val(v1) & Int32_val(v2)); } CAMLprim value caml_int32_or(value v1, value v2) { return caml_copy_int32(Int32_val(v1) | Int32_val(v2)); } CAMLprim value caml_int32_xor(value v1, value v2) { return caml_copy_int32(Int32_val(v1) ^ Int32_val(v2)); } CAMLprim value caml_int32_shift_left(value v1, value v2) { return caml_copy_int32(Int32_val(v1) << Int_val(v2)); } CAMLprim value caml_int32_shift_right(value v1, value v2) { return caml_copy_int32(Int32_val(v1) >> Int_val(v2)); } CAMLprim value caml_int32_shift_right_unsigned(value v1, value v2) { return caml_copy_int32((uint32_t)Int32_val(v1) >> Int_val(v2)); } static int32_t caml_swap32(int32_t x) { return (((x & 0x000000FF) << 24) | ((x & 0x0000FF00) << 8) | ((x & 0x00FF0000) >> 8) | ((x & 0xFF000000) >> 24)); } value caml_int32_direct_bswap(value v) { return caml_swap32(v); } CAMLprim value caml_int32_bswap(value v) { return caml_copy_int32(caml_swap32(Int32_val(v))); } CAMLprim value caml_int32_of_int(value v) { return caml_copy_int32(Long_val(v)); } CAMLprim value caml_int32_to_int(value v) { return Val_long(Int32_val(v)); } int32_t caml_int32_of_float_unboxed(double x) { return x; } CAMLprim value caml_int32_of_float(value v) { return caml_copy_int32((int32_t)(Double_val(v))); } double caml_int32_to_float_unboxed(int32_t x) { return x; } CAMLprim value caml_int32_to_float(value v) { return caml_copy_double((double)(Int32_val(v))); } intnat caml_int32_compare_unboxed(int32_t i1, int32_t i2) { return (i1 > i2) - (i1 < i2); } CAMLprim value caml_int32_compare(value v1, value v2) { return Val_int(caml_int32_compare_unboxed(Int32_val(v1),Int32_val(v2))); } CAMLprim value caml_int32_format(value fmt, value arg) { char format_string[FORMAT_BUFFER_SIZE]; parse_format(fmt, ARCH_INT32_PRINTF_FORMAT, format_string); return caml_alloc_sprintf(format_string, Int32_val(arg)); } CAMLprim value caml_int32_of_string(value s) { return caml_copy_int32(parse_intnat(s, 32, INT32_ERRMSG)); } int32_t caml_int32_bits_of_float_unboxed(double d) { union { float d; int32_t i; } u; u.d = d; return u.i; } double caml_int32_float_of_bits_unboxed(int32_t i) { union { float d; int32_t i; } u; u.i = i; return u.d; } CAMLprim value caml_int32_bits_of_float(value vd) { return caml_copy_int32(caml_int32_bits_of_float_unboxed(Double_val(vd))); } CAMLprim value caml_int32_float_of_bits(value vi) { return caml_copy_double(caml_int32_float_of_bits_unboxed(Int32_val(vi))); } /* 64-bit integers */ #ifdef ARCH_ALIGN_INT64 CAMLexport int64_t caml_Int64_val(value v) { union { int32_t i[2]; int64_t j; } buffer; buffer.i[0] = ((int32_t *) Data_custom_val(v))[0]; buffer.i[1] = ((int32_t *) Data_custom_val(v))[1]; return buffer.j; } #endif static int int64_cmp(value v1, value v2) { int64_t i1 = Int64_val(v1); int64_t i2 = Int64_val(v2); return (i1 > i2) - (i1 < i2); } static intnat int64_hash(value v) { int64_t x = Int64_val(v); uint32_t lo = (uint32_t) x, hi = (uint32_t) (x >> 32); return hi ^ lo; } static void int64_serialize(value v, uintnat * bsize_32, uintnat * bsize_64) { caml_serialize_int_8(Int64_val(v)); *bsize_32 = *bsize_64 = 8; } static uintnat int64_deserialize(void * dst) { #ifndef ARCH_ALIGN_INT64 *((int64_t *) dst) = caml_deserialize_sint_8(); #else union { int32_t i[2]; int64_t j; } buffer; buffer.j = caml_deserialize_sint_8(); ((int32_t *) dst)[0] = buffer.i[0]; ((int32_t *) dst)[1] = buffer.i[1]; #endif return 8; } CAMLexport struct custom_operations caml_int64_ops = { "_j", custom_finalize_default, int64_cmp, int64_hash, int64_serialize, int64_deserialize, custom_compare_ext_default }; CAMLexport value caml_copy_int64(int64_t i) { value res = caml_alloc_custom(&caml_int64_ops, 8, 0, 1); #ifndef ARCH_ALIGN_INT64 Int64_val(res) = i; #else union { int32_t i[2]; int64_t j; } buffer; buffer.j = i; ((int32_t *) Data_custom_val(res))[0] = buffer.i[0]; ((int32_t *) Data_custom_val(res))[1] = buffer.i[1]; #endif return res; } CAMLprim value caml_int64_neg(value v) { return caml_copy_int64(- Int64_val(v)); } CAMLprim value caml_int64_add(value v1, value v2) { return caml_copy_int64(Int64_val(v1) + Int64_val(v2)); } CAMLprim value caml_int64_sub(value v1, value v2) { return caml_copy_int64(Int64_val(v1) - Int64_val(v2)); } CAMLprim value caml_int64_mul(value v1, value v2) { return caml_copy_int64(Int64_val(v1) * Int64_val(v2)); } #define Int64_min_int ((intnat) 1 << (sizeof(intnat) * 8 - 1)) CAMLprim value caml_int64_div(value v1, value v2) { int64_t dividend = Int64_val(v1); int64_t divisor = Int64_val(v2); if (divisor == 0) caml_raise_zero_divide(); /* PR#4740: on some processors, division crashes on overflow. Implement the same behavior as for type "int". */ if (dividend == ((int64_t)1 << 63) && divisor == -1) return v1; return caml_copy_int64(Int64_val(v1) / divisor); } CAMLprim value caml_int64_mod(value v1, value v2) { int64_t dividend = Int64_val(v1); int64_t divisor = Int64_val(v2); if (divisor == 0) caml_raise_zero_divide(); /* PR#4740: on some processors, division crashes on overflow. Implement the same behavior as for type "int". */ if (dividend == ((int64_t)1 << 63) && divisor == -1){ return caml_copy_int64(0); } return caml_copy_int64(Int64_val(v1) % divisor); } CAMLprim value caml_int64_and(value v1, value v2) { return caml_copy_int64(Int64_val(v1) & Int64_val(v2)); } CAMLprim value caml_int64_or(value v1, value v2) { return caml_copy_int64(Int64_val(v1) | Int64_val(v2)); } CAMLprim value caml_int64_xor(value v1, value v2) { return caml_copy_int64(Int64_val(v1) ^ Int64_val(v2)); } CAMLprim value caml_int64_shift_left(value v1, value v2) { return caml_copy_int64(Int64_val(v1) << Int_val(v2)); } CAMLprim value caml_int64_shift_right(value v1, value v2) { return caml_copy_int64(Int64_val(v1) >> Int_val(v2)); } CAMLprim value caml_int64_shift_right_unsigned(value v1, value v2) { return caml_copy_int64((uint64_t) (Int64_val(v1)) >> Int_val(v2)); } #ifdef ARCH_SIXTYFOUR static value caml_swap64(value x) { return (((((x) & 0x00000000000000FF) << 56) | (((x) & 0x000000000000FF00) << 40) | (((x) & 0x0000000000FF0000) << 24) | (((x) & 0x00000000FF000000) << 8) | (((x) & 0x000000FF00000000) >> 8) | (((x) & 0x0000FF0000000000) >> 24) | (((x) & 0x00FF000000000000) >> 40) | (((x) & 0xFF00000000000000) >> 56))); } value caml_int64_direct_bswap(value v) { return caml_swap64(v); } #endif CAMLprim value caml_int64_bswap(value v) { int64_t x = Int64_val(v); return caml_copy_int64 (((x & INT64_LITERAL(0x00000000000000FFU)) << 56) | ((x & INT64_LITERAL(0x000000000000FF00U)) << 40) | ((x & INT64_LITERAL(0x0000000000FF0000U)) << 24) | ((x & INT64_LITERAL(0x00000000FF000000U)) << 8) | ((x & INT64_LITERAL(0x000000FF00000000U)) >> 8) | ((x & INT64_LITERAL(0x0000FF0000000000U)) >> 24) | ((x & INT64_LITERAL(0x00FF000000000000U)) >> 40) | ((x & INT64_LITERAL(0xFF00000000000000U)) >> 56)); } CAMLprim value caml_int64_of_int(value v) { return caml_copy_int64((int64_t) (Long_val(v))); } CAMLprim value caml_int64_to_int(value v) { return Val_long((intnat) (Int64_val(v))); } int64_t caml_int64_of_float_unboxed(double x) { return x; } CAMLprim value caml_int64_of_float(value v) { return caml_copy_int64((int64_t) (Double_val(v))); } double caml_int64_to_float_unboxed(int64_t x) { return x; } CAMLprim value caml_int64_to_float(value v) { return caml_copy_double((double) (Int64_val(v))); } CAMLprim value caml_int64_of_int32(value v) { return caml_copy_int64((int64_t) (Int32_val(v))); } CAMLprim value caml_int64_to_int32(value v) { return caml_copy_int32((int32_t) (Int64_val(v))); } CAMLprim value caml_int64_of_nativeint(value v) { return caml_copy_int64((int64_t) (Nativeint_val(v))); } CAMLprim value caml_int64_to_nativeint(value v) { return caml_copy_nativeint((intnat) (Int64_val(v))); } intnat caml_int64_compare_unboxed(int64_t i1, int64_t i2) { return (i1 > i2) - (i1 < i2); } CAMLprim value caml_int64_compare(value v1, value v2) { return Val_int(caml_int64_compare_unboxed(Int64_val(v1),Int64_val(v2))); } CAMLprim value caml_int64_format(value fmt, value arg) { char format_string[FORMAT_BUFFER_SIZE]; parse_format(fmt, ARCH_INT64_PRINTF_FORMAT, format_string); return caml_alloc_sprintf(format_string, Int64_val(arg)); } CAMLprim value caml_int64_of_string(value s) { const char * p; uint64_t res, threshold; int sign, base, signedness, d; p = parse_sign_and_base(String_val(s), &base, &signedness, &sign); threshold = ((uint64_t) -1) / base; d = parse_digit(*p); if (d < 0 || d >= base) caml_failwith(INT64_ERRMSG); res = d; for (p++; /*nothing*/; p++) { char c = *p; if (c == '_') continue; d = parse_digit(c); if (d < 0 || d >= base) break; /* Detect overflow in multiplication base * res */ if (res > threshold) caml_failwith(INT64_ERRMSG); res = base * res + d; /* Detect overflow in addition (base * res) + d */ if (res < (uint64_t) d) caml_failwith(INT64_ERRMSG); } if (p != String_val(s) + caml_string_length(s)){ caml_failwith(INT64_ERRMSG); } if (signedness) { /* Signed representation expected, allow -2^63 to 2^63 - 1 only */ if (sign >= 0) { if (res >= (uint64_t)1 << 63) caml_failwith(INT64_ERRMSG); } else { if (res > (uint64_t)1 << 63) caml_failwith(INT64_ERRMSG); } } if (sign < 0) res = - res; return caml_copy_int64(res); } int64_t caml_int64_bits_of_float_unboxed(double d) { union { double d; int64_t i; int32_t h[2]; } u; u.d = d; #if defined(__arm__) && !defined(__ARM_EABI__) { int32_t t = u.h[0]; u.h[0] = u.h[1]; u.h[1] = t; } #endif return u.i; } double caml_int64_float_of_bits_unboxed(int64_t i) { union { double d; int64_t i; int32_t h[2]; } u; u.i = i; #if defined(__arm__) && !defined(__ARM_EABI__) { int32_t t = u.h[0]; u.h[0] = u.h[1]; u.h[1] = t; } #endif return u.d; } CAMLprim value caml_int64_bits_of_float(value vd) { return caml_copy_int64(caml_int64_bits_of_float_unboxed(Double_val(vd))); } CAMLprim value caml_int64_float_of_bits(value vi) { return caml_copy_double(caml_int64_float_of_bits_unboxed(Int64_val(vi))); } /* Native integers */ static int nativeint_cmp(value v1, value v2) { intnat i1 = Nativeint_val(v1); intnat i2 = Nativeint_val(v2); return (i1 > i2) - (i1 < i2); } static intnat nativeint_hash(value v) { intnat n = Nativeint_val(v); #ifdef ARCH_SIXTYFOUR /* 32/64 bits compatibility trick. See explanations in file "hash.c", function caml_hash_mix_intnat. */ return (n >> 32) ^ (n >> 63) ^ n; #else return n; #endif } static void nativeint_serialize(value v, uintnat * bsize_32, uintnat * bsize_64) { intnat l = Nativeint_val(v); #ifdef ARCH_SIXTYFOUR if (l >= -((intnat)1 << 31) && l < ((intnat)1 << 31)) { caml_serialize_int_1(1); caml_serialize_int_4((int32_t) l); } else { caml_serialize_int_1(2); caml_serialize_int_8(l); } #else caml_serialize_int_1(1); caml_serialize_int_4(l); #endif *bsize_32 = 4; *bsize_64 = 8; } static uintnat nativeint_deserialize(void * dst) { switch (caml_deserialize_uint_1()) { case 1: *((intnat *) dst) = caml_deserialize_sint_4(); break; case 2: #ifdef ARCH_SIXTYFOUR *((intnat *) dst) = caml_deserialize_sint_8(); #else caml_deserialize_error("input_value: native integer value too large"); #endif break; default: caml_deserialize_error("input_value: ill-formed native integer"); } return sizeof(intnat); } CAMLexport struct custom_operations caml_nativeint_ops = { "_n", custom_finalize_default, nativeint_cmp, nativeint_hash, nativeint_serialize, nativeint_deserialize, custom_compare_ext_default }; CAMLexport value caml_copy_nativeint(intnat i) { value res = caml_alloc_custom(&caml_nativeint_ops, sizeof(intnat), 0, 1); Nativeint_val(res) = i; return res; } CAMLprim value caml_nativeint_neg(value v) { return caml_copy_nativeint(- Nativeint_val(v)); } CAMLprim value caml_nativeint_add(value v1, value v2) { return caml_copy_nativeint(Nativeint_val(v1) + Nativeint_val(v2)); } CAMLprim value caml_nativeint_sub(value v1, value v2) { return caml_copy_nativeint(Nativeint_val(v1) - Nativeint_val(v2)); } CAMLprim value caml_nativeint_mul(value v1, value v2) { return caml_copy_nativeint(Nativeint_val(v1) * Nativeint_val(v2)); } #define Nativeint_min_int ((intnat) 1 << (sizeof(intnat) * 8 - 1)) CAMLprim value caml_nativeint_div(value v1, value v2) { intnat dividend = Nativeint_val(v1); intnat divisor = Nativeint_val(v2); if (divisor == 0) caml_raise_zero_divide(); /* PR#4740: on some processors, modulus crashes if division overflows. Implement the same behavior as for type "int". */ if (dividend == Nativeint_min_int && divisor == -1) return v1; return caml_copy_nativeint(dividend / divisor); } CAMLprim value caml_nativeint_mod(value v1, value v2) { intnat dividend = Nativeint_val(v1); intnat divisor = Nativeint_val(v2); if (divisor == 0) caml_raise_zero_divide(); /* PR#4740: on some processors, modulus crashes if division overflows. Implement the same behavior as for type "int". */ if (dividend == Nativeint_min_int && divisor == -1){ return caml_copy_nativeint(0); } return caml_copy_nativeint(dividend % divisor); } CAMLprim value caml_nativeint_and(value v1, value v2) { return caml_copy_nativeint(Nativeint_val(v1) & Nativeint_val(v2)); } CAMLprim value caml_nativeint_or(value v1, value v2) { return caml_copy_nativeint(Nativeint_val(v1) | Nativeint_val(v2)); } CAMLprim value caml_nativeint_xor(value v1, value v2) { return caml_copy_nativeint(Nativeint_val(v1) ^ Nativeint_val(v2)); } CAMLprim value caml_nativeint_shift_left(value v1, value v2) { return caml_copy_nativeint(Nativeint_val(v1) << Int_val(v2)); } CAMLprim value caml_nativeint_shift_right(value v1, value v2) { return caml_copy_nativeint(Nativeint_val(v1) >> Int_val(v2)); } CAMLprim value caml_nativeint_shift_right_unsigned(value v1, value v2) { return caml_copy_nativeint((uintnat)Nativeint_val(v1) >> Int_val(v2)); } value caml_nativeint_direct_bswap(value v) { #ifdef ARCH_SIXTYFOUR return caml_swap64(v); #else return caml_swap32(v); #endif } CAMLprim value caml_nativeint_bswap(value v) { #ifdef ARCH_SIXTYFOUR return caml_copy_nativeint(caml_swap64(Nativeint_val(v))); #else return caml_copy_nativeint(caml_swap32(Nativeint_val(v))); #endif } CAMLprim value caml_nativeint_of_int(value v) { return caml_copy_nativeint(Long_val(v)); } CAMLprim value caml_nativeint_to_int(value v) { return Val_long(Nativeint_val(v)); } intnat caml_nativeint_of_float_unboxed(double x) { return x; } CAMLprim value caml_nativeint_of_float(value v) { return caml_copy_nativeint((intnat)(Double_val(v))); } double caml_nativeint_to_float_unboxed(intnat x) { return x; } CAMLprim value caml_nativeint_to_float(value v) { return caml_copy_double((double)(Nativeint_val(v))); } CAMLprim value caml_nativeint_of_int32(value v) { return caml_copy_nativeint(Int32_val(v)); } CAMLprim value caml_nativeint_to_int32(value v) { return caml_copy_int32(Nativeint_val(v)); } intnat caml_nativeint_compare_unboxed(intnat i1, intnat i2) { return (i1 > i2) - (i1 < i2); } CAMLprim value caml_nativeint_compare(value v1, value v2) { return Val_int(caml_nativeint_compare_unboxed(Nativeint_val(v1), Nativeint_val(v2))); } CAMLprim value caml_nativeint_format(value fmt, value arg) { char format_string[FORMAT_BUFFER_SIZE]; parse_format(fmt, ARCH_INTNAT_PRINTF_FORMAT, format_string); return caml_alloc_sprintf(format_string, Nativeint_val(arg)); } CAMLprim value caml_nativeint_of_string(value s) { return caml_copy_nativeint(parse_intnat(s, 8 * sizeof(value), INTNAT_ERRMSG)); }