package octez-proto-libs

Type of integers of arbitrary length.

Raised by conversion functions when the value cannot be represented in the destination type.

The number 0.

The number 1.

The number -1.

Converts from a base integer.

Converts from a 32-bit integer.

Converts from a 64-bit integer.

Converts a string to an integer. An optional - prefix indicates a negative number, while a + prefix is ignored. An optional prefix 0x, 0o, or 0b (following the optional - or + prefix) indicates that the number is, represented, in hexadecimal, octal, or binary, respectively. Otherwise, base 10 is assumed. (Unlike C, a lone 0 prefix does not denote octal.) Raises an Invalid_argument exception if the string is not a syntactically correct representation of an integer.

of_substring s ~pos ~len is the same as of_string (String.sub s pos len)

Parses a number represented as a string in the specified base, with optional - or + prefix. The base must be between 2 and 16.

of_substring_base base s ~pos ~len is the same as of_string_base base (String.sub s pos len)

Returns its argument plus one.

Returns its argument minus one.

Absolute value.

Unary negation.

Addition.

Subtraction.

Multiplication.

Integer division. The result is truncated towards zero and obeys the rule of signs. Raises Division_by_zero if the divisor (second argument) is 0.

Integer remainder. Can raise a Division_by_zero. The result of rem a b has the sign of a, and its absolute value is strictly smaller than the absolute value of b. The result satisfies the equality a = b * div a b + rem a b.

Computes both the integer quotient and the remainder. div_rem a b is equal to (div a b, rem a b). Raises Division_by_zero if b = 0.

Integer division with rounding towards +oo (ceiling). Can raise a Division_by_zero.

Integer division with rounding towards -oo (floor). Can raise a Division_by_zero.

Euclidean division and remainder. ediv_rem a b returns a pair (q, r) such that a = b * q + r and 0 <= r < |b|. Raises Division_by_zero if b = 0.

Euclidean division. ediv a b is equal to fst (ediv_rem a b). The result satisfies 0 <= a - b * ediv a b < |b|. Raises Division_by_zero if b = 0.

Euclidean remainder. erem a b is equal to snd (ediv_rem a b). The result satisfies 0 <= erem a b < |b| and a = b * ediv a b + erem a b. Raises Division_by_zero if b = 0.

divexact a b divides a by b, only producing correct result when the division is exact, i.e., when b evenly divides a. It should be faster than general division. Can raise a Division_by_zero.

divisible a b returns true if a is exactly divisible by b. Unlike the other division functions, b = 0 is accepted (only 0 is considered divisible by 0).

congruent a b c returns true if a is congruent to b modulo c. Unlike the other division functions, c = 0 is accepted (only equal numbers are considered equal congruent 0).

Bitwise logical and.

Bitwise logical or.

Bitwise logical exclusive or.

Bitwise logical negation. The identity lognot a=-a-1 always hold.

Shifts to the left. Equivalent to a multiplication by a power of 2. The second argument must be nonnegative.

Shifts to the right. This is an arithmetic shift, equivalent to a division by a power of 2 with rounding towards -oo. The second argument must be nonnegative.

Shifts to the right, rounding towards 0. This is equivalent to a division by a power of 2, with truncation. The second argument must be nonnegative.

Returns the number of significant bits in the given number. If x is zero, numbits x returns 0. Otherwise, numbits x returns a positive integer n such that 2^{n-1} <= |x| < 2^n. Note that numbits is defined for negative arguments, and that numbits (-x) = numbits x.

Returns the number of trailing 0 bits in the given number. If x is zero, trailing_zeros x returns max_int. Otherwise, trailing_zeros x returns a nonnegative integer n which is the largest n such that 2^n divides x evenly. Note that trailing_zeros is defined for negative arguments, and that trailing_zeros (-x) = trailing_zeros x.

testbit x n return the value of bit number n in x: true if the bit is 1, false if the bit is 0. Bits are numbered from 0. Raise Invalid_argument if n is negative.

Counts the number of bits set. Raises Overflow for negative arguments, as those have an infinite number of bits set.

Counts the number of different bits. Raises Overflow if the arguments have different signs (in which case the distance is infinite).

Converts to a base integer. May raise an Overflow.

Converts to a 32-bit integer. May raise Overflow.

Converts to a 64-bit integer. May raise Overflow.

Gives a human-readable, decimal string representation of the argument.

Gives a string representation of the argument in the specified printf-like format. The general specification has the following form:

% [flags] [width] type

Where the type actually indicates the base:

• i, d, u: decimal
• b: binary
• o: octal
• x: lowercase hexadecimal
• X: uppercase hexadecimal

Supported flags are:

• +: prefix positive numbers with a + sign
• space: prefix positive numbers with a space
• -: left-justify (default is right justification)
• 0: pad with zeroes (instead of spaces)
• #: alternate formatting (actually, simply output a literal-like prefix: 0x, 0b, 0o)

Unlike the classic printf, all numbers are signed (even hexadecimal ones), there is no precision field, and characters that are not part of the format are simply ignored (and not copied in the output).

Whether the argument fits in a regular int.

Whether the argument fits in an int32.

Whether the argument fits in an int64.

Prints the argument on the specified formatter. Can be used as %a format printer in Format.printf and as argument to #install_printer in the top-level.

Comparison. compare x y returns 0 if x equals y, -1 if x is smaller than y, and 1 if x is greater than y.

Note that Pervasive.compare can be used to compare reliably two integers only on OCaml 3.12.1 and later versions.

Equality test.

Less than or equal.

Greater than or equal.

Less than (and not equal).

Greater than (and not equal).

Returns -1, 0, or 1 when the argument is respectively negative, null, or positive.

Returns the minimum of its arguments.

Returns the maximum of its arguments.

Returns true if the argument is even (divisible by 2), false if odd.

Returns true if the argument is odd, false if even.

pow base exp raises base to the exp power. exp must be nonnegative. Note that only exponents fitting in a machine integer are supported, as larger exponents would surely make the result's size overflow the address space.

Returns the square root. The result is truncated (rounded down to an integer). Raises an Invalid_argument on negative arguments.

Returns the square root truncated, and the remainder. Raises an Invalid_argument on negative arguments.

root x n computes the n-th root of x. n must be positive and, if n is even, then x must be nonnegative. Otherwise, an Invalid_argument is raised.

rootrem x n computes the n-th root of x and the remainder x-root**n. n must be positive and, if n is even, then x must be nonnegative. Otherwise, an Invalid_argument is raised.

True if the argument has the form a^b, with b>1

True if the argument has the form a^2.

Returns the base-2 logarithm of its argument, rounded down to an integer. If x is positive, log2 x returns the largest n such that 2^n <= x. If x is negative or zero, log2 x raise the Invalid_argument exception.

Returns the base-2 logarithm of its argument, rounded up to an integer. If x is positive, log2up x returns the smallest n such that x <= 2^n. If x is negative or zero, log2up x raise the Invalid_argument exception.

Returns the number of machine words used to represent the number.

extract a off len returns a nonnegative number corresponding to bits off to off+len-1 of b. Negative a are considered in infinite-length 2's complement representation.

signed_extract a off len extracts bits off to off+len-1 of b, as extract does, then sign-extends bit len-1 of the result (that is, bit off + len - 1 of a). The result is between - 2{^[len]-1} (included) and 2{^[len]-1} (excluded), and equal to extract a off len modulo 2{^len}.

Returns a binary representation of the argument. The string result should be interpreted as a sequence of bytes, corresponding to the binary representation of the absolute value of the argument in little endian ordering. The sign is not stored in the string.

Constructs a number from a binary string representation. The string is interpreted as a sequence of bytes in little endian order, and the result is always positive. We have the identity: of_bits (to_bits x) = abs x. However, we can have to_bits (of_bits s) <> s due to the presence of trailing zeros in s.