micropython/py/mpz.c

#include <stdint.h>
#include <stdbool.h>
#include <stdlib.h>
#include <string.h>
#include <assert.h>

#include "misc.h"
#include "mpconfig.h"
#include "mpz.h"

#if MICROPY_LONGINT_IMPL == MICROPY_LONGINT_IMPL_MPZ

#define DIG_SIZE (15)
#define DIG_MASK ((1 << DIG_SIZE) - 1)

/*
 definition of normalise:
 ?
*/

/* compares i with j
   returns sign(i - j)
   assumes i, j are normalised
*/
int mpn_cmp(const mpz_dig_t *idig, uint ilen, const mpz_dig_t *jdig, uint jlen) {
    if (ilen < jlen) { return -1; }
    if (ilen > jlen) { return 1; }

    for (idig += ilen, jdig += ilen; ilen > 0; --ilen) {
        int cmp = *(--idig) - *(--jdig);
        if (cmp < 0) { return -1; }
        if (cmp > 0) { return 1; }
    }

    return 0;
}

/* computes i = j >> n
   returns number of digits in i
   assumes enough memory in i; assumes normalised j
   can have i, j pointing to same memory
*/
uint mpn_shr(mpz_dig_t *idig, mpz_dig_t *jdig, uint jlen, uint n) {
    uint n_whole = n / DIG_SIZE;
    uint n_part = n % DIG_SIZE;

    if (n_whole >= jlen) {
        return 0;
    }

    jdig += n_whole;
    jlen -= n_whole;

    for (uint i = jlen; i > 0; --i, ++idig, ++jdig) {
        mpz_dbl_dig_t d = *jdig;
        if (i > 1)
            d |= jdig[1] << DIG_SIZE;
        d >>= n_part;
        *idig = d & DIG_MASK;
    }

    if (idig[-1] == 0) {
        --jlen;
    }

    return jlen;
}

/* computes i = j + k
   returns number of digits in i
   assumes enough memory in i; assumes normalised j, k; assumes jlen >= klen
   can have i, j, k pointing to same memory
*/
uint mpn_add(mpz_dig_t *idig, const mpz_dig_t *jdig, uint jlen, const mpz_dig_t *kdig, uint klen) {
    mpz_dig_t *oidig = idig;
    mpz_dbl_dig_t carry = 0;

    jlen -= klen;

    for (; klen > 0; --klen, ++idig, ++jdig, ++kdig) {
        carry += *jdig + *kdig;
        *idig = carry & DIG_MASK;
        carry >>= DIG_SIZE;
    }

    for (; jlen > 0; --jlen, ++idig, ++jdig) {
        carry += *jdig;
        *idig = carry & DIG_MASK;
        carry >>= DIG_SIZE;
    }

    if (carry != 0) {
        *idig++ = carry;
    }

    return idig - oidig;
}

/* computes i = j - k
   returns number of digits in i
   assumes enough memory in i; assumes normalised j, k; assumes j >= k
   can have i, j, k pointing to same memory
*/
uint mpn_sub(mpz_dig_t *idig, const mpz_dig_t *jdig, uint jlen, const mpz_dig_t *kdig, uint klen) {
    mpz_dig_t *oidig = idig;
    mpz_dbl_dig_signed_t borrow = 0;

    jlen -= klen;

    for (; klen > 0; --klen, ++idig, ++jdig, ++kdig) {
        borrow += *jdig - *kdig;
        *idig = borrow & DIG_MASK;
        borrow >>= DIG_SIZE;
    }

    for (; jlen > 0; --jlen, ++idig, ++jdig) {
        borrow += *jdig;
        *idig = borrow & DIG_MASK;
        borrow >>= DIG_SIZE;
    }

    for (--idig; idig >= oidig && *idig == 0; --idig) {
    }

    return idig + 1 - oidig;
}

/* computes i = i * d1 + d2
   returns number of digits in i
   assumes enough memory in i; assumes normalised i; assumes dmul != 0
*/
uint mpn_mul_dig_add_dig(mpz_dig_t *idig, uint ilen, mpz_dig_t dmul, mpz_dig_t dadd) {
    mpz_dig_t *oidig = idig;
    mpz_dbl_dig_t carry = dadd;

    for (; ilen > 0; --ilen, ++idig) {
        carry += *idig * dmul; // will never overflow so long as DIG_SIZE <= WORD_SIZE / 2
        *idig = carry & DIG_MASK;
        carry >>= DIG_SIZE;
    }

    if (carry != 0) {
        *idig++ = carry;
    }

    return idig - oidig;
}

/* computes i = j * k
   returns number of digits in i
   assumes enough memory in i; assumes i is zeroed; assumes normalised j, k
   can have j, k point to same memory
*/
uint mpn_mul(mpz_dig_t *idig, mpz_dig_t *jdig, uint jlen, mpz_dig_t *kdig, uint klen) {
    mpz_dig_t *oidig = idig;
    uint ilen = 0;

    for (; klen > 0; --klen, ++idig, ++kdig) {
        mpz_dig_t *id = idig;
        mpz_dbl_dig_t carry = 0;

        uint jl = jlen;
        for (mpz_dig_t *jd = jdig; jl > 0; --jl, ++jd, ++id) {
            carry += *id + *jd * *kdig; // will never overflow so long as DIG_SIZE <= WORD_SIZE / 2
            *id = carry & DIG_MASK;
            carry >>= DIG_SIZE;
        }

        if (carry != 0) {
            *id++ = carry;
        }

        ilen = id - oidig;
    }

    return ilen;
}

/* natural_div - quo * den + new_num = old_num (ie num is replaced with rem)
   assumes den != 0
   assumes num_dig has enough memory to be extended by 1 digit
   assumes quo_dig has enough memory (as many digits as num)
   assumes quo_dig is filled with zeros
   modifies den_dig memory, but restors it to original state at end
*/

void mpn_div(mpz_dig_t *num_dig, machine_uint_t *num_len, mpz_dig_t *den_dig, machine_uint_t den_len, mpz_dig_t *quo_dig, machine_uint_t *quo_len) {
    mpz_dig_t *orig_num_dig = num_dig;
    mpz_dig_t *orig_quo_dig = quo_dig;
    mpz_dig_t norm_shift = 0;
    mpz_dbl_dig_t lead_den_digit;

    // handle simple cases
    {
        int cmp = mpn_cmp(num_dig, *num_len, den_dig, den_len);
        if (cmp == 0) {
            *num_len = 0;
            quo_dig[0] = 1;
            *quo_len = 1;
            return;
        } else if (cmp < 0) {
            // numerator remains the same
            *quo_len = 0;
            return;
        }
    }

    // count number of leading zeros in leading digit of denominator
    {
        mpz_dig_t d = den_dig[den_len - 1];
        while ((d & (1 << (DIG_SIZE - 1))) == 0) {
            d <<= 1;
            ++norm_shift;
        }
    }

    // normalise denomenator (leading bit of leading digit is 1)
    for (mpz_dig_t *den = den_dig, carry = 0; den < den_dig + den_len; ++den) {
        mpz_dig_t d = *den;
        *den = ((d << norm_shift) | carry) & DIG_MASK;
        carry = d >> (DIG_SIZE - norm_shift);
    }

    // now need to shift numerator by same amount as denominator
    // first, increase length of numerator in case we need more room to shift
    num_dig[*num_len] = 0;
    ++(*num_len);
    for (mpz_dig_t *num = num_dig, carry = 0; num < num_dig + *num_len; ++num) {
        mpz_dig_t n = *num;
        *num = ((n << norm_shift) | carry) & DIG_MASK;
        carry = n >> (DIG_SIZE - norm_shift);
    }

    // cache the leading digit of the denominator
    lead_den_digit = den_dig[den_len - 1];

    // point num_dig to last digit in numerator
    num_dig += *num_len - 1;

    // calculate number of digits in quotient
    *quo_len = *num_len - den_len;

    // point to last digit to store for quotient
    quo_dig += *quo_len - 1;

    // keep going while we have enough digits to divide
    while (*num_len > den_len) {
        mpz_dbl_dig_t quo = (*num_dig << DIG_SIZE) | num_dig[-1];

        // get approximate quotient
        quo /= lead_den_digit;

        // multiply quo by den and subtract from num get remainder
        {
            mpz_dbl_dig_signed_t borrow = 0;

            for (mpz_dig_t *n = num_dig - den_len, *d = den_dig; n < num_dig; ++n, ++d) {
                borrow += *n - quo * *d; // will overflow if DIG_SIZE >= 16
                *n = borrow & DIG_MASK;
                borrow >>= DIG_SIZE;
            }
            borrow += *num_dig; // will overflow if DIG_SIZE >= 16
            *num_dig = borrow & DIG_MASK;
            borrow >>= DIG_SIZE;

            // adjust quotient if it is too big
            for (; borrow != 0; --quo) {
                mpz_dbl_dig_t carry = 0;
                for (mpz_dig_t *n = num_dig - den_len, *d = den_dig; n < num_dig; ++n, ++d) {
                    carry += *n + *d;
                    *n = carry & DIG_MASK;
                    carry >>= DIG_SIZE;
                }
                carry += *num_dig;
                *num_dig = carry & DIG_MASK;
                carry >>= DIG_SIZE;

                borrow += carry;
            }
        }

        // store this digit of the quotient
        *quo_dig = quo & DIG_MASK;
        --quo_dig;

        // move down to next digit of numerator
        --num_dig;
        --(*num_len);
    }

    // unnormalise denomenator
    for (mpz_dig_t *den = den_dig + den_len - 1, carry = 0; den >= den_dig; --den) {
        mpz_dig_t d = *den;
        *den = ((d >> norm_shift) | carry) & DIG_MASK;
        carry = d << (DIG_SIZE - norm_shift);
    }

    // unnormalise numerator (remainder now)
    for (mpz_dig_t *num = orig_num_dig + *num_len - 1, carry = 0; num >= orig_num_dig; --num) {
        mpz_dig_t n = *num;
        *num = ((n >> norm_shift) | carry) & DIG_MASK;
        carry = n << (DIG_SIZE - norm_shift);
    }

    // strip trailing zeros

    while (*quo_len > 0 && orig_quo_dig[*quo_len - 1] == 0) {
        --(*quo_len);
    }

    while (*num_len > 0 && orig_num_dig[*num_len - 1] == 0) {
        --(*num_len);
    }
}

#define MIN_ALLOC (4)
#define ALIGN_ALLOC (2)
#define NUM_DIG_FOR_INT (sizeof(machine_int_t) * 8 / DIG_SIZE + 1)

static const uint log_base2_floor[] = {
    0,
    0, 1, 1, 2,
    2, 2, 2, 3,
    3, 3, 3, 3,
    3, 3, 3, 4,
    4, 4, 4, 4,
    4, 4, 4, 4,
    4, 4, 4, 4,
    4, 4, 4, 5
};

bool mpz_int_is_sml_int(machine_int_t i) {
    return -(1 << DIG_SIZE) < i && i < (1 << DIG_SIZE);
}

void mpz_init_zero(mpz_t *z) {
    z->alloc = 0;
    z->neg = 0;
    z->len = 0;
    z->dig = NULL;
}

void mpz_init_from_int(mpz_t *z, machine_int_t val) {
    mpz_init_zero(z);
    mpz_set_from_int(z, val);
}

void mpz_deinit(mpz_t *z) {
    if (z != NULL) {
        m_del(mpz_dig_t, z->dig, z->alloc);
    }
}

mpz_t *mpz_zero(void) {
    mpz_t *z = m_new_obj(mpz_t);
    mpz_init_zero(z);
    return z;
}

mpz_t *mpz_from_int(machine_int_t val) {
    mpz_t *z = mpz_zero();
    mpz_set_from_int(z, val);
    return z;
}

mpz_t *mpz_from_str(const char *str, uint len, bool neg, uint base) {
    mpz_t *z = mpz_zero();
    mpz_set_from_str(z, str, len, neg, base);
    return z;
}

void mpz_free(mpz_t *z) {
    if (z != NULL) {
        m_del(mpz_dig_t, z->dig, z->alloc);
        m_del_obj(mpz_t, z);
    }
}

STATIC void mpz_need_dig(mpz_t *z, uint need) {
    uint alloc;
    if (need < MIN_ALLOC) {
        alloc = MIN_ALLOC;
    } else {
        alloc = (need + ALIGN_ALLOC) & (~(ALIGN_ALLOC - 1));
    }

    if (z->dig == NULL || z->alloc < alloc) {
        z->dig = m_renew(mpz_dig_t, z->dig, z->alloc, alloc);
        z->alloc = alloc;
    }
}

mpz_t *mpz_clone(const mpz_t *src) {
    mpz_t *z = m_new_obj(mpz_t);
    z->alloc = src->alloc;
    z->neg = src->neg;
    z->len = src->len;
    if (src->dig == NULL) {
        z->dig = NULL;
    } else {
        z->dig = m_new(mpz_dig_t, z->alloc);
        memcpy(z->dig, src->dig, src->alloc * sizeof(mpz_dig_t));
    }
    return z;
}

void mpz_set(mpz_t *dest, const mpz_t *src) {
    mpz_need_dig(dest, src->len);
    dest->neg = src->neg;
    dest->len = src->len;
    memcpy(dest->dig, src->dig, src->len * sizeof(mpz_dig_t));
}

void mpz_set_from_int(mpz_t *z, machine_int_t val) {
    mpz_need_dig(z, NUM_DIG_FOR_INT);

    if (val < 0) {
        z->neg = 1;
        val = -val;
    } else {
        z->neg = 0;
    }

    z->len = 0;
    while (val > 0) {
        z->dig[z->len++] = val & DIG_MASK;
        val >>= DIG_SIZE;
    }
}

// returns number of bytes from str that were processed
uint mpz_set_from_str(mpz_t *z, const char *str, uint len, bool neg, uint base) {
    assert(base < 36);

    const char *cur = str;
    const char *top = str + len;

    mpz_need_dig(z, len * 8 / DIG_SIZE + 1);

    if (neg) {
        z->neg = 1;
    } else {
        z->neg = 0;
    }

    z->len = 0;
    for (; cur < top; ++cur) { // XXX UTF8 next char
        //uint v = char_to_numeric(cur#); // XXX UTF8 get char
        uint v = *cur;
        if ('0' <= v && v <= '9') {
            v -= '0';
        } else if ('A' <= v && v <= 'Z') {
            v -= 'A' - 10;
        } else if ('a' <= v && v <= 'z') {
            v -= 'a' - 10;
        } else {
            break;
        }
        if (v >= base) {
            break;
        }
        z->len = mpn_mul_dig_add_dig(z->dig, z->len, base, v);
    }

    return cur - str;
}

bool mpz_is_zero(const mpz_t *z) {
    return z->len == 0;
}

bool mpz_is_pos(const mpz_t *z) {
    return z->len > 0 && z->neg == 0;
}

bool mpz_is_neg(const mpz_t *z) {
    return z->len > 0 && z->neg != 0;
}

bool mpz_is_odd(const mpz_t *z) {
    return z->len > 0 && (z->dig[0] & 1) != 0;
}

bool mpz_is_even(const mpz_t *z) {
    return z->len == 0 || (z->dig[0] & 1) == 0;
}

int mpz_cmp(const mpz_t *z1, const mpz_t *z2) {
    int cmp = z2->neg - z1->neg;
    if (cmp != 0) {
        return cmp;
    }
    cmp = mpn_cmp(z1->dig, z1->len, z2->dig, z2->len);
    if (z1->neg != 0) {
        cmp = -cmp;
    }
    return cmp;
}

int mpz_cmp_sml_int(const mpz_t *z, machine_int_t sml_int) {
    int cmp;
    if (z->neg == 0) {
        if (sml_int < 0) return 1;
        if (sml_int == 0) {
            if (z->len == 0) return 0;
            return 1;
        }
        if (z->len == 0) return -1;
        assert(sml_int < (1 << DIG_SIZE));
        if (z->len != 1) return 1;
        cmp = z->dig[0] - sml_int;
    } else {
        if (sml_int > 0) return -1;
        if (sml_int == 0) {
            if (z->len == 0) return 0;
            return -1;
        }
        if (z->len == 0) return 1;
        assert(sml_int > -(1 << DIG_SIZE));
        if (z->len != 1) return -1;
        cmp = -z->dig[0] - sml_int;
    }
    if (cmp < 0) return -1;
    if (cmp > 0) return 1;
    return 0;
}

/* not finished
mpz_t *mpz_shl(mpz_t *dest, const mpz_t *lhs, int rhs)
{
    if (dest != lhs)
        dest = mpz_set(dest, lhs);

    if (dest.len == 0 || rhs == 0)
        return dest;

    if (rhs < 0)
        return mpz_shr(dest, dest, -rhs);

    printf("mpz_shl: not implemented\n");

    return dest;
}

mpz_t *mpz_shr(mpz_t *dest, const mpz_t *lhs, int rhs)
{
    if (dest != lhs)
        dest = mpz_set(dest, lhs);

    if (dest.len == 0 || rhs == 0)
        return dest;

    if (rhs < 0)
        return mpz_shl(dest, dest, -rhs);

    dest.len = mpn_shr(dest.len, dest.dig, rhs);
    dest.dig[dest.len .. dest->alloc] = 0;

    return dest;
}
*/


#if 0
these functions are unused

/* returns abs(z)
*/
mpz_t *mpz_abs(const mpz_t *z) {
    mpz_t *z2 = mpz_clone(z);
    z2->neg = 0;
    return z2;
}

/* returns -z
*/
mpz_t *mpz_neg(const mpz_t *z) {
    mpz_t *z2 = mpz_clone(z);
    z2->neg = 1 - z2->neg;
    return z2;
}

/* returns lhs + rhs
   can have lhs, rhs the same
*/
mpz_t *mpz_add(const mpz_t *lhs, const mpz_t *rhs) {
    mpz_t *z = mpz_zero();
    mpz_add_inpl(z, lhs, rhs);
    return z;
}

/* returns lhs - rhs
   can have lhs, rhs the same
*/
mpz_t *mpz_sub(const mpz_t *lhs, const mpz_t *rhs) {
    mpz_t *z = mpz_zero();
    mpz_sub_inpl(z, lhs, rhs);
    return z;
}

/* returns lhs * rhs
   can have lhs, rhs the same
*/
mpz_t *mpz_mul(const mpz_t *lhs, const mpz_t *rhs) {
    mpz_t *z = mpz_zero();
    mpz_mul_inpl(z, lhs, rhs);
    return z;
}

/* returns lhs ** rhs
   can have lhs, rhs the same
*/
mpz_t *mpz_pow(const mpz_t *lhs, const mpz_t *rhs) {
    mpz_t *z = mpz_zero();
    mpz_pow_inpl(z, lhs, rhs);
    return z;
}
#endif

/* computes dest = abs(z)
   can have dest, z the same
*/
void mpz_abs_inpl(mpz_t *dest, const mpz_t *z) {
    if (dest != z) {
        mpz_set(dest, z);
    }
    dest->neg = 0;
}

/* computes dest = -z
   can have dest, z the same
*/
void mpz_neg_inpl(mpz_t *dest, const mpz_t *z) {
    if (dest != z) {
        mpz_set(dest, z);
    }
    dest->neg = 1 - dest->neg;
}

/* computes dest = lhs + rhs
   can have dest, lhs, rhs the same
*/
void mpz_add_inpl(mpz_t *dest, const mpz_t *lhs, const mpz_t *rhs) {
    if (mpn_cmp(lhs->dig, lhs->len, rhs->dig, rhs->len) < 0) {
        const mpz_t *temp = lhs;
        lhs = rhs;
        rhs = temp;
    }

    if (lhs->neg == rhs->neg) {
        mpz_need_dig(dest, lhs->len + 1);
        dest->len = mpn_add(dest->dig, lhs->dig, lhs->len, rhs->dig, rhs->len);
    } else {
        mpz_need_dig(dest, lhs->len);
        dest->len = mpn_sub(dest->dig, lhs->dig, lhs->len, rhs->dig, rhs->len);
    }

    dest->neg = lhs->neg;
}

/* computes dest = lhs - rhs
   can have dest, lhs, rhs the same
*/
void mpz_sub_inpl(mpz_t *dest, const mpz_t *lhs, const mpz_t *rhs) {
    bool neg = false;

    if (mpn_cmp(lhs->dig, lhs->len, rhs->dig, rhs->len) < 0) {
        const mpz_t *temp = lhs;
        lhs = rhs;
        rhs = temp;
        neg = true;
    }

    if (lhs->neg != rhs->neg) {
        mpz_need_dig(dest, lhs->len + 1);
        dest->len = mpn_add(dest->dig, lhs->dig, lhs->len, rhs->dig, rhs->len);
    } else {
        mpz_need_dig(dest, lhs->len);
        dest->len = mpn_sub(dest->dig, lhs->dig, lhs->len, rhs->dig, rhs->len);
    }

    if (neg) {
        dest->neg = 1 - lhs->neg;
    } else {
        dest->neg = lhs->neg;
    }
}

/* computes dest = lhs * rhs
   can have dest, lhs, rhs the same
*/
void mpz_mul_inpl(mpz_t *dest, const mpz_t *lhs, const mpz_t *rhs)
{
    if (lhs->len == 0 || rhs->len == 0) {
        return mpz_set_from_int(dest, 0);
    }

    mpz_t *temp = NULL;
    if (lhs == dest) {
        lhs = temp = mpz_clone(lhs);
        if (rhs == dest) {
            rhs = lhs;
        }
    } else if (rhs == dest) {
        rhs = temp = mpz_clone(rhs);
    }

    mpz_need_dig(dest, lhs->len + rhs->len); // min mem l+r-1, max mem l+r
    memset(dest->dig, 0, dest->alloc * sizeof(mpz_dig_t));
    dest->len = mpn_mul(dest->dig, lhs->dig, lhs->len, rhs->dig, rhs->len);

    if (lhs->neg == rhs->neg) {
        dest->neg = 0;
    } else {
        dest->neg = 1;
    }

    mpz_free(temp);
}

/* computes dest = lhs ** rhs
   can have dest, lhs, rhs the same
*/
void mpz_pow_inpl(mpz_t *dest, const mpz_t *lhs, const mpz_t *rhs) {
    if (lhs->len == 0 || rhs->neg != 0) {
        return mpz_set_from_int(dest, 0);
    }

    if (rhs->len == 0) {
        return mpz_set_from_int(dest, 1);
    }

    mpz_t *x = mpz_clone(lhs);
    mpz_t *n = mpz_clone(rhs);

    mpz_set_from_int(dest, 1);

    while (n->len > 0) {
        if (mpz_is_odd(n)) {
            mpz_mul_inpl(dest, dest, x);
        }
        mpz_mul_inpl(x, x, x);
        n->len = mpn_shr(n->dig, n->dig, n->len, 1);
    }

    mpz_free(x);
    mpz_free(n);
}

/* computes gcd(z1, z2)
   based on Knuth's modified gcd algorithm (I think?)
   gcd(z1, z2) >= 0
   gcd(0, 0) = 0
   gcd(z, 0) = abs(z)
*/
mpz_t *mpz_gcd(const mpz_t *z1, const mpz_t *z2) {
    if (z1->len == 0) {
        mpz_t *a = mpz_clone(z2);
        a->neg = 0;
        return a;
    } else if (z2->len == 0) {
        mpz_t *a = mpz_clone(z1);
        a->neg = 0;
        return a;
    }

    mpz_t *a = mpz_clone(z1);
    mpz_t *b = mpz_clone(z2);
    mpz_t c; mpz_init_zero(&c);
    a->neg = 0;
    b->neg = 0;

    for (;;) {
        if (mpz_cmp(a, b) < 0) {
            if (a->len == 0) {
                mpz_free(a);
                mpz_deinit(&c);
                return b;
            }
            mpz_t *t = a; a = b; b = t;
        }
        if (!(b->len >= 2 || (b->len == 1 && b->dig[0] > 1))) { // compute b > 0; could be mpz_cmp_small_int(b, 1) > 0
            break;
        }
        mpz_set(&c, b);
        do {
            mpz_add_inpl(&c, &c, &c);
        } while (mpz_cmp(&c, a) <= 0);
        c.len = mpn_shr(c.dig, c.dig, c.len, 1);
        mpz_sub_inpl(a, a, &c);
    }

    mpz_deinit(&c);

    if (b->len == 1 && b->dig[0] == 1) { // compute b == 1; could be mpz_cmp_small_int(b, 1) == 0
        mpz_free(a);
        return b;
    } else {
        mpz_free(b);
        return a;
    }
}

/* computes lcm(z1, z2)
     = abs(z1) / gcd(z1, z2) * abs(z2)
  lcm(z1, z1) >= 0
  lcm(0, 0) = 0
  lcm(z, 0) = 0
*/
mpz_t *mpz_lcm(const mpz_t *z1, const mpz_t *z2)
{
    if (z1->len == 0 || z2->len == 0)
        return mpz_zero();

    mpz_t *gcd = mpz_gcd(z1, z2);
    mpz_t *quo = mpz_zero();
    mpz_t *rem = mpz_zero();
    mpz_divmod_inpl(quo, rem, z1, gcd);
    mpz_mul_inpl(rem, quo, z2);
    mpz_free(gcd);
    mpz_free(quo);
    rem->neg = 0;
    return rem;
}

/* computes new integers in quo and rem such that:
       quo * rhs + rem = lhs
       0 <= rem < rhs
   can have lhs, rhs the same
*/
void mpz_divmod(const mpz_t *lhs, const mpz_t *rhs, mpz_t **quo, mpz_t **rem) {
    *quo = mpz_zero();
    *rem = mpz_zero();
    mpz_divmod_inpl(*quo, *rem, lhs, rhs);
}

/* computes new integers in quo and rem such that:
       quo * rhs + rem = lhs
       0 <= rem < rhs
   can have lhs, rhs the same
*/
void mpz_divmod_inpl(mpz_t *dest_quo, mpz_t *dest_rem, const mpz_t *lhs, const mpz_t *rhs) {
    if (rhs->len == 0) {
        mpz_set_from_int(dest_quo, 0);
        mpz_set_from_int(dest_rem, 0);
        return;
    }

    mpz_need_dig(dest_quo, lhs->len + 1); // +1 necessary?
    memset(dest_quo->dig, 0, (lhs->len + 1) * sizeof(mpz_dig_t));
    dest_quo->len = 0;
    mpz_need_dig(dest_rem, lhs->len + 1); // +1 necessary?
    mpz_set(dest_rem, lhs);
    //rhs->dig[rhs->len] = 0;
    mpn_div(dest_rem->dig, &dest_rem->len, rhs->dig, rhs->len, dest_quo->dig, &dest_quo->len);

    if (lhs->neg != rhs->neg) {
        dest_quo->neg = 1;
    }
}

#if 0
these functions are unused

/* computes floor(lhs / rhs)
   can have lhs, rhs the same
*/
mpz_t *mpz_div(const mpz_t *lhs, const mpz_t *rhs) {
    mpz_t *quo = mpz_zero();
    mpz_t rem; mpz_init_zero(&rem);
    mpz_divmod_inpl(quo, &rem, lhs, rhs);
    mpz_deinit(&rem);
    return quo;
}

/* computes lhs % rhs ( >= 0)
   can have lhs, rhs the same
*/
mpz_t *mpz_mod(const mpz_t *lhs, const mpz_t *rhs) {
    mpz_t quo; mpz_init_zero(&quo);
    mpz_t *rem = mpz_zero();
    mpz_divmod_inpl(&quo, rem, lhs, rhs);
    mpz_deinit(&quo);
    return rem;
}
#endif

machine_int_t mpz_as_int(const mpz_t *i) {
    machine_int_t val = 0;
    mpz_dig_t *d = i->dig + i->len;

    while (--d >= i->dig)
    {
        machine_int_t oldval = val;
        val = (val << DIG_SIZE) | *d;
        if (val < oldval)
        {
            if (i->neg == 0) {
                return 0x7fffffff;
            } else {
                return 0x80000000;
            }
        }
    }

    if (i->neg != 0) {
        val = -val;
    }

    return val;
}

machine_float_t mpz_as_float(const mpz_t *i) {
    machine_float_t val = 0;
    mpz_dig_t *d = i->dig + i->len;

    while (--d >= i->dig) {
        val = val * (1 << DIG_SIZE) + *d;
    }

    if (i->neg != 0) {
        val = -val;
    }

    return val;
}

uint mpz_as_str_size(const mpz_t *i, uint base) {
    if (base < 2 || base > 32) {
        return 0;
    }

    return i->len * DIG_SIZE / log_base2_floor[base] + 2 + 1; // +1 for null byte termination
}

char *mpz_as_str(const mpz_t *i, uint base) {
    char *s = m_new(char, mpz_as_str_size(i, base));
    mpz_as_str_inpl(i, base, s);
    return s;
}

// assumes enough space as calculated by mpz_as_str_size
// returns length of string, not including null byte
uint mpz_as_str_inpl(const mpz_t *i, uint base, char *str) {
    if (str == NULL || base < 2 || base > 32) {
        str[0] = 0;
        return 0;
    }

    uint ilen = i->len;

    if (ilen == 0) {
        str[0] = '0';
        str[1] = 0;
        return 1;
    }

    // make a copy of mpz digits
    mpz_dig_t *dig = m_new(mpz_dig_t, ilen);
    memcpy(dig, i->dig, ilen * sizeof(mpz_dig_t));

    // convert
    char *s = str;
    bool done;
    do {
        mpz_dig_t *d = dig + ilen;
        mpz_dbl_dig_t a = 0;

        // compute next remainder
        while (--d >= dig) {
            a = (a << DIG_SIZE) | *d;
            *d = a / base;
            a %= base;
        }

        // convert to character
        a += '0';
        if (a > '9') {
            a += 'a' - '9' - 1;
        }
        *s++ = a;

        // check if number is zero
        done = true;
        for (d = dig; d < dig + ilen; ++d) {
            if (*d != 0) {
                done = false;
                break;
            }
        }
    } while (!done);

    if (i->neg != 0) {
        *s++ = '-';
    }

    // reverse string
    for (char *u = str, *v = s - 1; u < v; ++u, --v) {
        char temp = *u;
        *u = *v;
        *v = temp;
    }

    s[0] = 0; // null termination

    return s - str;
}

#endif // MICROPY_LONGINT_IMPL == MICROPY_LONGINT_IMPL_MPZ