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mpint.h
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mpint.h
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#ifndef PUTTY_MPINT_H
#define PUTTY_MPINT_H
/*
* PuTTY's multiprecision integer library.
*
* This library is written with the aim of avoiding leaking the input
* numbers via timing and cache side channels. This means avoiding
* making any control flow change, or deciding the address of any
* memory access, based on the value of potentially secret input data.
*
* But in a library that has to handle numbers of arbitrary size, you
* can't avoid your control flow depending on the _size_ of the input!
* So the rule is that an mp_int has a nominal size that need not be
* its mathematical size: i.e. if you call (say) mp_from_bytes_be to
* turn an array of 256 bytes into an integer, and all but the last of
* those bytes is zero, then you get an mp_int which has space for 256
* bytes of data but just happens to store the value 1. So the
* _nominal_ sizes of input data - e.g. the size in bits of some
* public-key modulus - are not considered secret, and control flow is
* allowed to do what it likes based on those sizes. But the same
* function, called with the same _nominally sized_ arguments
* containing different values, should run in the same length of time.
*
* When a function returns an 'mp_int *', it is newly allocated to an
* appropriate nominal size (which, again, depends only on the nominal
* sizes of the inputs). Other functions have 'into' in their name,
* and they instead overwrite the contents of an existing mp_int.
*
* Functions in this API which return values that are logically
* boolean return them as 'unsigned' rather than the C99 bool type.
* That's because C99 bool does an implicit test for non-zero-ness
* when converting any other integer type to it, which compilers might
* well implement using data-dependent control flow.
*/
/*
* Create and destroy mp_ints. A newly created one is initialised to
* zero. mp_clear also resets an existing number to zero.
*/
mp_int *mp_new(size_t maxbits);
void mp_free(mp_int *);
void mp_clear(mp_int *x);
/*
* Resize the physical size of existing mp_int, e.g. so that you have
* room to transform it in place to a larger value. Destroys the old
* mp_int in the process.
*/
mp_int *mp_resize(mp_int *, size_t newmaxbits);
/*
* Create mp_ints from various sources: little- and big-endian binary
* data, an ordinary C unsigned integer type, a decimal or hex string
* (given either as a ptrlen or a C NUL-terminated string), and
* another mp_int.
*
* The decimal and hex conversion functions have running time
* dependent on the length of the input data, of course.
*/
mp_int *mp_from_bytes_le(ptrlen bytes);
mp_int *mp_from_bytes_be(ptrlen bytes);
mp_int *mp_from_integer(uintmax_t n);
mp_int *mp_from_decimal_pl(ptrlen decimal);
mp_int *mp_from_decimal(const char *decimal);
mp_int *mp_from_hex_pl(ptrlen hex);
mp_int *mp_from_hex(const char *hex);
mp_int *mp_copy(mp_int *x);
/*
* A macro for declaring large fixed numbers in source code (such as
* elliptic curve parameters, or standard Diffie-Hellman moduli). The
* idea is that you just write something like
*
* mp_int *value = MP_LITERAL(0x19284376283754638745693467245);
*
* and it newly allocates you an mp_int containing that number.
*
* Internally, the macro argument is stringified and passed to
* mp_from_hex. That's not as fast as it could be if I had instead set
* up some kind of mp_from_array_of_uint64_t() function, but I think
* this system is valuable for the fact that the literal integers
* appear in a very natural syntax that can be pasted directly out
* into, say, Python if you want to cross-check a calculation.
*/
static inline mp_int *mp__from_string_literal(const char *lit)
{
/* Don't call this directly; it's not equipped to deal with
* hostile data. Use only via the MP_LITERAL macro. */
if (lit[0] && (lit[1] == 'x' || lit[1] == 'X'))
return mp_from_hex(lit+2);
else
return mp_from_decimal(lit);
}
#define MP_LITERAL(number) mp__from_string_literal(#number)
/*
* Create an mp_int with the value 2^power.
*/
mp_int *mp_power_2(size_t power);
/*
* Retrieve the value of a particular bit or byte of an mp_int. The
* byte / bit index is not considered to be secret data. Out-of-range
* byte/bit indices are handled cleanly and return zero.
*/
uint8_t mp_get_byte(mp_int *x, size_t byte);
unsigned mp_get_bit(mp_int *x, size_t bit);
/*
* Retrieve the value of an mp_int as a uintmax_t, assuming it's small
* enough to fit.
*/
uintmax_t mp_get_integer(mp_int *x);
/*
* Set an mp_int bit. Again, the bit index is not considered secret.
* Do not pass an out-of-range index, on pain of assertion failure.
*/
void mp_set_bit(mp_int *x, size_t bit, unsigned val);
/*
* Return the nominal size of an mp_int, in terms of the maximum
* number of bytes or bits that can fit in it.
*/
size_t mp_max_bytes(mp_int *x);
size_t mp_max_bits(mp_int *x);
/*
* Return the _mathematical_ bit count of an mp_int (not its nominal
* size), i.e. a value n such that 2^{n-1} <= x < 2^n.
*
* This function is supposed to run in constant time for a given
* nominal input size. Of course it's likely that clients of this
* function will promptly need to use the result as the limit of some
* loop (e.g. marshalling an mp_int into an SSH packet, which doesn't
* permit extra prefix zero bytes). But that's up to the caller to
* decide the safety of.
*/
size_t mp_get_nbits(mp_int *x);
/*
* Return the value of an mp_int as a decimal or hex string. The
* result is dynamically allocated, and the caller is responsible for
* freeing it.
*
* These functions should run in constant time for a given nominal
* input size, even though the exact number of digits returned is
* variable. They always allocate enough space for the largest output
* that might be needed, but they don't always fill it.
*/
char *mp_get_decimal(mp_int *x);
char *mp_get_hex(mp_int *x);
char *mp_get_hex_uppercase(mp_int *x);
/*
* Compare two mp_ints, or compare one mp_int against a C integer. The
* 'eq' functions return 1 if the two inputs are equal, or 0
* otherwise; the 'hs' functions return 1 if the first input is >= the
* second, and 0 otherwise.
*/
unsigned mp_cmp_hs(mp_int *a, mp_int *b);
unsigned mp_cmp_eq(mp_int *a, mp_int *b);
unsigned mp_hs_integer(mp_int *x, uintmax_t n);
unsigned mp_eq_integer(mp_int *x, uintmax_t n);
/*
* Take the minimum or maximum of two mp_ints, without using a
* conditional branch.
*/
void mp_min_into(mp_int *r, mp_int *x, mp_int *y);
void mp_max_into(mp_int *r, mp_int *x, mp_int *y);
mp_int *mp_min(mp_int *x, mp_int *y);
mp_int *mp_max(mp_int *x, mp_int *y);
/*
* Diagnostic function. Writes out x in hex to the supplied stdio
* stream, preceded by the string 'prefix' and followed by 'suffix'.
*
* This is useful to put temporarily into code, but it's also
* potentially useful to call from a debugger.
*/
void mp_dump(FILE *fp, const char *prefix, mp_int *x, const char *suffix);
/*
* Overwrite one mp_int with another, or with a plain integer.
*/
void mp_copy_into(mp_int *dest, mp_int *src);
void mp_copy_integer_into(mp_int *dest, uintmax_t n);
/*
* Conditional selection. Overwrites dest with either src0 or src1,
* according to the value of 'choose_src1'. choose_src1 should be 0 or
* 1; if it's 1, then dest is set to src1, otherwise src0.
*
* The value of choose_src1 is considered to be secret data, so
* control flow and memory access should not depend on it.
*/
void mp_select_into(mp_int *dest, mp_int *src0, mp_int *src1,
unsigned choose_src1);
/*
* Addition, subtraction and multiplication, either targeting an
* existing mp_int or making a new one large enough to hold whatever
* the output might be..
*/
void mp_add_into(mp_int *r, mp_int *a, mp_int *b);
void mp_sub_into(mp_int *r, mp_int *a, mp_int *b);
void mp_mul_into(mp_int *r, mp_int *a, mp_int *b);
mp_int *mp_add(mp_int *x, mp_int *y);
mp_int *mp_sub(mp_int *x, mp_int *y);
mp_int *mp_mul(mp_int *x, mp_int *y);
/*
* Bitwise operations.
*/
void mp_and_into(mp_int *r, mp_int *a, mp_int *b);
void mp_or_into(mp_int *r, mp_int *a, mp_int *b);
void mp_xor_into(mp_int *r, mp_int *a, mp_int *b);
void mp_bic_into(mp_int *r, mp_int *a, mp_int *b);
/*
* Addition, subtraction and multiplication with one argument small
* enough to fit in a C integer. For mp_mul_integer_into, it has to be
* even smaller than that.
*/
void mp_add_integer_into(mp_int *r, mp_int *a, uintmax_t n);
void mp_sub_integer_into(mp_int *r, mp_int *a, uintmax_t n);
void mp_mul_integer_into(mp_int *r, mp_int *a, uint16_t n);
/*
* Conditional addition/subtraction. If yes == 1, sets r to a+b or a-b
* (respectively). If yes == 0, sets r to just a. 'yes' is considered
* secret data.
*/
void mp_cond_add_into(mp_int *r, mp_int *a, mp_int *b, unsigned yes);
void mp_cond_sub_into(mp_int *r, mp_int *a, mp_int *b, unsigned yes);
/*
* Swap x0 and x1 if swap == 1, and not if swap == 0. 'swap' is
* considered secret.
*/
void mp_cond_swap(mp_int *x0, mp_int *x1, unsigned swap);
/*
* Set x to 0 if clear == 1, and otherwise leave it unchanged. 'clear'
* is considered secret.
*/
void mp_cond_clear(mp_int *x, unsigned clear);
/*
* Division. mp_divmod_into divides n by d, and writes the quotient
* into q and the remainder into r. You can pass either of q and r as
* NULL if you don't need one of the outputs.
*
* mp_div and mp_mod are wrappers that return one or other of those
* outputs as a freshly allocated mp_int of the appropriate size.
*
* Division by zero gives no error, and returns a quotient of 0 and a
* remainder of n (so as to still satisfy the division identity that
* n=qd+r).
*/
void mp_divmod_into(mp_int *n, mp_int *d, mp_int *q, mp_int *r);
mp_int *mp_div(mp_int *n, mp_int *d);
mp_int *mp_mod(mp_int *x, mp_int *modulus);
/*
* Compute the residue of x mod m, where m is a small integer. x is
* kept secret, but m is not.
*/
uint32_t mp_mod_known_integer(mp_int *x, uint32_t m);
/*
* Integer nth root. mp_nthroot returns the largest integer x such
* that x^n <= y, and if 'remainder' is non-NULL then it fills it with
* the residue (y - x^n).
*
* Currently, n has to be small enough that the largest binomial
* coefficient (n choose k) fits in 16 bits, which works out to at
* most 18.
*/
mp_int *mp_nthroot(mp_int *y, unsigned n, mp_int *remainder);
/*
* Trivially easy special case of mp_mod: reduce a number mod a power
* of two.
*/
void mp_reduce_mod_2to(mp_int *x, size_t p);
/*
* Modular inverses. mp_invert computes the inverse of x mod modulus
* (and will expect the two to be coprime). mp_invert_mod_2to computes
* the inverse of x mod 2^p, and is a great deal faster.
*/
mp_int *mp_invert_mod_2to(mp_int *x, size_t p);
mp_int *mp_invert(mp_int *x, mp_int *modulus);
/*
* Greatest common divisor.
*
* mp_gcd_into also returns a pair of Bezout coefficients, namely A,B
* such that a*A - b*B = gcd. (The minus sign is so that both returned
* coefficients can be positive.)
*
* You can pass any of mp_gcd_into's output pointers as NULL if you
* don't need that output value.
*
* mp_gcd is a wrapper with a less cumbersome API, for the case where
* the only output value you need is the gcd itself. mp_coprime is
* even easier, if all you care about is whether or not that gcd is 1.
*/
mp_int *mp_gcd(mp_int *a, mp_int *b);
void mp_gcd_into(mp_int *a, mp_int *b,
mp_int *gcd_out, mp_int *A_out, mp_int *B_out);
unsigned mp_coprime(mp_int *a, mp_int *b);
/*
* System for taking square roots modulo an odd prime.
*
* In order to do this efficiently, you need to provide an extra piece
* of information at setup time, namely a number which is not
* congruent mod p to any square. Given p and that non-square, you can
* use modsqrt_new to make a context containing all the necessary
* equipment for actually calculating the square roots, and then you
* can call mp_modsqrt as many times as you like on that context
* before freeing it.
*
* The output parameter '*success' will be filled in with 1 if the
* operation was successful, or 0 if the input number doesn't have a
* square root mod p at all. In the latter case, the returned mp_int
* will be nonsense and you shouldn't depend on it.
*
* ==== WARNING ====
*
* This function DOES NOT TREAT THE PRIME MODULUS AS SECRET DATA! It
* will protect the number you're taking the square root _of_, but not
* the number you're taking the root of it _mod_.
*
* (This is because the algorithm requires a number of loop iterations
* equal to the number of factors of 2 in p-1. And the expected use of
* this function is for elliptic-curve point decompression, in which
* the modulus is always a well-known one written down in standards
* documents.)
*/
typedef struct ModsqrtContext ModsqrtContext;
ModsqrtContext *modsqrt_new(mp_int *p, mp_int *any_nonsquare_mod_p);
void modsqrt_free(ModsqrtContext *);
mp_int *mp_modsqrt(ModsqrtContext *sc, mp_int *x, unsigned *success);
/*
* Functions for Montgomery multiplication, a fast technique for doing
* a long series of modular multiplications all with the same modulus
* (which has to be odd).
*
* You start by calling monty_new to set up a context structure
* containing all the precomputed bits and pieces needed by the
* algorithm. Then, any numbers you want to work with must first be
* transformed into the internal Montgomery representation using
* monty_import; having done that, you can use monty_mul and monty_pow
* to operate on them efficiently; and finally, monty_export will
* convert numbers back out of Montgomery representation to give their
* ordinary values.
*
* Addition and subtraction are not optimised by the Montgomery trick,
* but monty_add and monty_sub are provided anyway for convenience.
*
* There are also monty_invert and monty_modsqrt, which are analogues
* of mp_invert and mp_modsqrt which take their inputs in Montgomery
* representation. For mp_modsqrt, the prime modulus of the
* ModsqrtContext must be the same as the modulus of the MontyContext.
*
* The query functions monty_modulus and monty_identity return numbers
* stored inside the MontyContext, without copying them. The returned
* pointers are still owned by the MontyContext, so don't free them!
*/
MontyContext *monty_new(mp_int *modulus);
void monty_free(MontyContext *mc);
mp_int *monty_modulus(MontyContext *mc); /* doesn't transfer ownership */
mp_int *monty_identity(MontyContext *mc); /* doesn't transfer ownership */
void monty_import_into(MontyContext *mc, mp_int *r, mp_int *x);
mp_int *monty_import(MontyContext *mc, mp_int *x);
void monty_export_into(MontyContext *mc, mp_int *r, mp_int *x);
mp_int *monty_export(MontyContext *mc, mp_int *x);
void monty_mul_into(MontyContext *, mp_int *r, mp_int *, mp_int *);
mp_int *monty_add(MontyContext *, mp_int *, mp_int *);
mp_int *monty_sub(MontyContext *, mp_int *, mp_int *);
mp_int *monty_mul(MontyContext *, mp_int *, mp_int *);
mp_int *monty_pow(MontyContext *, mp_int *base, mp_int *exponent);
mp_int *monty_invert(MontyContext *, mp_int *);
mp_int *monty_modsqrt(ModsqrtContext *sc, mp_int *mx, unsigned *success);
/*
* Modular arithmetic functions which don't use an explicit
* MontyContext. mp_modpow will use one internally (on the assumption
* that the exponent is likely to be large enough to make it
* worthwhile); the other three will just do ordinary non-Montgomery-
* optimised modular reduction. Use mp_modmul if you only have one
* product to compute; if you have a lot, consider using a
* MontyContext in the client code.
*/
mp_int *mp_modpow(mp_int *base, mp_int *exponent, mp_int *modulus);
mp_int *mp_modmul(mp_int *x, mp_int *y, mp_int *modulus);
mp_int *mp_modadd(mp_int *x, mp_int *y, mp_int *modulus);
mp_int *mp_modsub(mp_int *x, mp_int *y, mp_int *modulus);
/*
* Shift an mp_int by a given number of bits. The shift count is
* considered to be secret data, and as a result, the algorithm takes
* O(n log n) time instead of the obvious O(n).
*
* There's no mp_lshift_safe, because the size of mp_int to allocate
* would not be able to avoid depending on the shift count. So if you
* need to behave independently of the size of a left shift, you have
* to know a bound on the space you'll need by some other means.
*/
void mp_lshift_safe_into(mp_int *r, mp_int *x, size_t shift);
void mp_rshift_safe_into(mp_int *r, mp_int *x, size_t shift);
mp_int *mp_rshift_safe(mp_int *x, size_t shift);
/*
* Shift an mp_int left or right by a fixed number of bits. The shift
* count is NOT considered to be secret data! Use this if you're
* always dividing by 2, for example, but don't use it to shift by a
* variable amount derived from another secret number.
*
* The upside is that these functions run in sensible linear time.
*/
void mp_lshift_fixed_into(mp_int *r, mp_int *a, size_t shift);
void mp_rshift_fixed_into(mp_int *r, mp_int *x, size_t shift);
mp_int *mp_lshift_fixed(mp_int *x, size_t shift);
mp_int *mp_rshift_fixed(mp_int *x, size_t shift);
/*
* Generate a random mp_int.
*
* The _function_ definitions here will expect to be given a gen_data
* function that provides random data. Normally you'd use this using
* random_read() from sshrand.c, and the macro wrappers automate that.
*
* (This is a bit of a dodge to avoid mpint.c having a link-time
* dependency on sshrand.c, so that programs can link against one but
* not the other: if a client of this header uses one of these macros
* then _they_ have link-time dependencies on both modules.)
*
* mp_random_bits[_fn] returns an integer 0 <= n < 2^bits.
* mp_random_upto[_fn](limit) returns an integer 0 <= n < limit.
* mp_random_in_range[_fn](lo,hi) returns an integer lo <= n < hi.
*/
typedef void (*random_read_fn_t)(void *, size_t);
mp_int *mp_random_bits_fn(size_t bits, random_read_fn_t randfn);
mp_int *mp_random_upto_fn(mp_int *limit, random_read_fn_t randfn);
mp_int *mp_random_in_range_fn(
mp_int *lo_inclusive, mp_int *hi_exclusive, random_read_fn_t randfn);
#define mp_random_bits(bits) mp_random_bits_fn(bits, random_read)
#define mp_random_upto(limit) mp_random_upto_fn(limit, random_read)
#define mp_random_in_range(lo, hi) mp_random_in_range_fn(lo, hi, random_read)
#endif /* PUTTY_MPINT_H */