/*
This file is part of TALER
Copyright (C) 2014-2021 Taler Systems SA
TALER is free software; you can redistribute it and/or modify it under the
terms of the GNU General Public License as published by the Free Software
Foundation; either version 3, or (at your option) any later version.
TALER is distributed in the hope that it will be useful, but WITHOUT ANY
WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR
A PARTICULAR PURPOSE. See the GNU General Public License for more details.
You should have received a copy of the GNU General Public License along with
TALER; see the file COPYING. If not, see
*/
/**
* @file util/amount.c
* @brief Common utility functions to deal with units of currency
* @author Sree Harsha Totakura
* @author Florian Dold
* @author Benedikt Mueller
* @author Christian Grothoff
*/
#include "platform.h"
#include "taler_util.h"
/**
* Set @a a to "invalid".
*
* @param[out] a amount to set to invalid
*/
static void
invalidate (struct TALER_Amount *a)
{
memset (a,
0,
sizeof (struct TALER_Amount));
}
enum GNUNET_GenericReturnValue
TALER_string_to_amount (const char *str,
struct TALER_Amount *amount)
{
int n;
uint32_t b;
const char *colon;
const char *value;
/* skip leading whitespace */
while (isspace ( (unsigned char) str[0]))
str++;
if ('\0' == str[0])
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
"Null before currency\n");
invalidate (amount);
return GNUNET_SYSERR;
}
/* parse currency */
colon = strchr (str, (int) ':');
if ( (NULL == colon) ||
((colon - str) >= TALER_CURRENCY_LEN) )
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
"Invalid currency specified before colon: `%s'\n",
str);
invalidate (amount);
return GNUNET_SYSERR;
}
GNUNET_assert (TALER_CURRENCY_LEN > (colon - str));
for (unsigned int i = 0; icurrency[i] = toupper (str[i]);
/* 0-terminate *and* normalize buffer by setting everything to '\0' */
memset (&amount->currency [colon - str],
0,
TALER_CURRENCY_LEN - (colon - str));
/* skip colon */
value = colon + 1;
if ('\0' == value[0])
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
"Actual value missing in amount `%s'\n",
str);
invalidate (amount);
return GNUNET_SYSERR;
}
amount->value = 0;
amount->fraction = 0;
/* parse value */
while ('.' != *value)
{
if ('\0' == *value)
{
/* we are done */
return GNUNET_OK;
}
if ( (*value < '0') ||
(*value > '9') )
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
"Invalid character `%c' in amount `%s'\n",
(int) *value,
str);
invalidate (amount);
return GNUNET_SYSERR;
}
n = *value - '0';
if ( (amount->value * 10 < amount->value) ||
(amount->value * 10 + n < amount->value) ||
(amount->value > TALER_AMOUNT_MAX_VALUE) ||
(amount->value * 10 + n > TALER_AMOUNT_MAX_VALUE) )
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
"Value specified in amount `%s' is too large\n",
str);
invalidate (amount);
return GNUNET_SYSERR;
}
amount->value = (amount->value * 10) + n;
value++;
}
/* skip the dot */
value++;
/* parse fraction */
if ('\0' == *value)
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
"Amount `%s' ends abruptly after `.'\n",
str);
invalidate (amount);
return GNUNET_SYSERR;
}
b = TALER_AMOUNT_FRAC_BASE / 10;
while ('\0' != *value)
{
if (0 == b)
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
"Fractional value too small (only %u digits supported) in amount `%s'\n",
(unsigned int) TALER_AMOUNT_FRAC_LEN,
str);
invalidate (amount);
return GNUNET_SYSERR;
}
if ( (*value < '0') ||
(*value > '9') )
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
"Error after dot\n");
invalidate (amount);
return GNUNET_SYSERR;
}
n = *value - '0';
amount->fraction += n * b;
b /= 10;
value++;
}
return GNUNET_OK;
}
enum GNUNET_GenericReturnValue
TALER_string_to_amount_nbo (const char *str,
struct TALER_AmountNBO *amount_nbo)
{
struct TALER_Amount amount;
if (GNUNET_OK !=
TALER_string_to_amount (str,
&amount))
return GNUNET_SYSERR;
TALER_amount_hton (amount_nbo,
&amount);
return GNUNET_OK;
}
void
TALER_amount_hton (struct TALER_AmountNBO *res,
const struct TALER_Amount *d)
{
GNUNET_assert (GNUNET_YES ==
TALER_amount_is_valid (d));
res->value = GNUNET_htonll (d->value);
res->fraction = htonl (d->fraction);
for (unsigned int i = 0; icurrency[i] = toupper (d->currency[i]);
}
void
TALER_amount_ntoh (struct TALER_Amount *res,
const struct TALER_AmountNBO *dn)
{
res->value = GNUNET_ntohll (dn->value);
res->fraction = ntohl (dn->fraction);
GNUNET_memcpy (res->currency,
dn->currency,
TALER_CURRENCY_LEN);
GNUNET_assert (GNUNET_YES ==
TALER_amount_is_valid (res));
}
enum GNUNET_GenericReturnValue
TALER_amount_set_zero (const char *cur,
struct TALER_Amount *amount)
{
size_t slen;
slen = strlen (cur);
if (slen >= TALER_CURRENCY_LEN)
return GNUNET_SYSERR;
memset (amount,
0,
sizeof (struct TALER_Amount));
for (unsigned int i = 0; icurrency[i] = toupper (cur[i]);
return GNUNET_OK;
}
enum GNUNET_GenericReturnValue
TALER_amount_is_valid (const struct TALER_Amount *amount)
{
if (amount->value > TALER_AMOUNT_MAX_VALUE)
return GNUNET_SYSERR;
return ('\0' != amount->currency[0]) ? GNUNET_OK : GNUNET_NO;
}
bool
TALER_amount_is_zero (const struct TALER_Amount *amount)
{
if (GNUNET_OK !=
TALER_amount_is_valid (amount))
return false;
return
(0 == amount->value) &&
(0 == amount->fraction);
}
enum GNUNET_GenericReturnValue
TALER_amount_is_currency (const struct TALER_Amount *amount,
const char *currency)
{
if (GNUNET_OK !=
TALER_amount_is_valid (amount))
return GNUNET_SYSERR;
return (0 == strcasecmp (currency,
amount->currency))
? GNUNET_OK
: GNUNET_NO;
}
/**
* Test if @a a is valid, NBO variant.
*
* @param a amount to test
* @return #GNUNET_YES if valid,
* #GNUNET_NO if invalid
*/
static enum GNUNET_GenericReturnValue
test_valid_nbo (const struct TALER_AmountNBO *a)
{
return ('\0' != a->currency[0]) ? GNUNET_YES : GNUNET_NO;
}
enum GNUNET_GenericReturnValue
TALER_amount_cmp_currency (const struct TALER_Amount *a1,
const struct TALER_Amount *a2)
{
if ( (GNUNET_NO == TALER_amount_is_valid (a1)) ||
(GNUNET_NO == TALER_amount_is_valid (a2)) )
return GNUNET_SYSERR;
if (0 == strcasecmp (a1->currency,
a2->currency))
return GNUNET_YES;
return GNUNET_NO;
}
enum GNUNET_GenericReturnValue
TALER_amount_cmp_currency_nbo (const struct TALER_AmountNBO *a1,
const struct TALER_AmountNBO *a2)
{
if ( (GNUNET_NO == test_valid_nbo (a1)) ||
(GNUNET_NO == test_valid_nbo (a2)) )
return GNUNET_SYSERR;
if (0 == strcasecmp (a1->currency,
a2->currency))
return GNUNET_YES;
return GNUNET_NO;
}
int
TALER_amount_cmp (const struct TALER_Amount *a1,
const struct TALER_Amount *a2)
{
struct TALER_Amount n1;
struct TALER_Amount n2;
GNUNET_assert (GNUNET_YES ==
TALER_amount_cmp_currency (a1,
a2));
n1 = *a1;
n2 = *a2;
GNUNET_assert (GNUNET_SYSERR !=
TALER_amount_normalize (&n1));
GNUNET_assert (GNUNET_SYSERR !=
TALER_amount_normalize (&n2));
if (n1.value == n2.value)
{
if (n1.fraction < n2.fraction)
return -1;
if (n1.fraction > n2.fraction)
return 1;
return 0;
}
if (n1.value < n2.value)
return -1;
return 1;
}
int
TALER_amount_cmp_nbo (const struct TALER_AmountNBO *a1,
const struct TALER_AmountNBO *a2)
{
struct TALER_Amount h1;
struct TALER_Amount h2;
TALER_amount_ntoh (&h1,
a1);
TALER_amount_ntoh (&h2,
a2);
return TALER_amount_cmp (&h1,
&h2);
}
enum TALER_AmountArithmeticResult
TALER_amount_subtract (struct TALER_Amount *diff,
const struct TALER_Amount *a1,
const struct TALER_Amount *a2)
{
struct TALER_Amount n1;
struct TALER_Amount n2;
if (GNUNET_YES !=
TALER_amount_cmp_currency (a1,
a2))
{
invalidate (diff);
return TALER_AAR_INVALID_CURRENCIES_INCOMPATIBLE;
}
/* make local copies to avoid aliasing problems between
diff and a1/a2 */
n1 = *a1;
n2 = *a2;
if ( (GNUNET_SYSERR == TALER_amount_normalize (&n1)) ||
(GNUNET_SYSERR == TALER_amount_normalize (&n2)) )
{
invalidate (diff);
return TALER_AAR_INVALID_NORMALIZATION_FAILED;
}
if (n1.fraction < n2.fraction)
{
if (0 == n1.value)
{
invalidate (diff);
return TALER_AAR_INVALID_NEGATIVE_RESULT;
}
n1.fraction += TALER_AMOUNT_FRAC_BASE;
n1.value--;
}
if (n1.value < n2.value)
{
invalidate (diff);
return TALER_AAR_INVALID_NEGATIVE_RESULT;
}
GNUNET_assert (GNUNET_OK ==
TALER_amount_set_zero (n1.currency,
diff));
GNUNET_assert (n1.fraction >= n2.fraction);
diff->fraction = n1.fraction - n2.fraction;
GNUNET_assert (n1.value >= n2.value);
diff->value = n1.value - n2.value;
if ( (0 == diff->fraction) &&
(0 == diff->value) )
return TALER_AAR_RESULT_ZERO;
return TALER_AAR_RESULT_POSITIVE;
}
enum TALER_AmountArithmeticResult
TALER_amount_add (struct TALER_Amount *sum,
const struct TALER_Amount *a1,
const struct TALER_Amount *a2)
{
struct TALER_Amount n1;
struct TALER_Amount n2;
struct TALER_Amount res;
if (GNUNET_YES !=
TALER_amount_cmp_currency (a1,
a2))
{
invalidate (sum);
return TALER_AAR_INVALID_CURRENCIES_INCOMPATIBLE;
}
/* make local copies to avoid aliasing problems between
diff and a1/a2 */
n1 = *a1;
n2 = *a2;
if ( (GNUNET_SYSERR ==
TALER_amount_normalize (&n1)) ||
(GNUNET_SYSERR ==
TALER_amount_normalize (&n2)) )
{
invalidate (sum);
return TALER_AAR_INVALID_NORMALIZATION_FAILED;
}
GNUNET_assert (GNUNET_OK ==
TALER_amount_set_zero (a1->currency,
&res));
res.value = n1.value + n2.value;
if (res.value < n1.value)
{
/* integer overflow */
invalidate (sum);
return TALER_AAR_INVALID_RESULT_OVERFLOW;
}
if (res.value > TALER_AMOUNT_MAX_VALUE)
{
/* too large to be legal */
invalidate (sum);
return TALER_AAR_INVALID_RESULT_OVERFLOW;
}
res.fraction = n1.fraction + n2.fraction;
if (GNUNET_SYSERR ==
TALER_amount_normalize (&res))
{
/* integer overflow via carry from fraction */
invalidate (sum);
return TALER_AAR_INVALID_RESULT_OVERFLOW;
}
*sum = res;
if ( (0 == sum->fraction) &&
(0 == sum->value) )
return TALER_AAR_RESULT_ZERO;
return TALER_AAR_RESULT_POSITIVE;
}
enum GNUNET_GenericReturnValue
TALER_amount_normalize (struct TALER_Amount *amount)
{
uint32_t overflow;
if (GNUNET_YES != TALER_amount_is_valid (amount))
return GNUNET_SYSERR;
if (amount->fraction < TALER_AMOUNT_FRAC_BASE)
return GNUNET_NO;
overflow = amount->fraction / TALER_AMOUNT_FRAC_BASE;
amount->fraction %= TALER_AMOUNT_FRAC_BASE;
amount->value += overflow;
if ( (amount->value < overflow) ||
(amount->value > TALER_AMOUNT_MAX_VALUE) )
{
invalidate (amount);
return GNUNET_SYSERR;
}
return GNUNET_OK;
}
/**
* Convert the fraction of @a amount to a string in decimals.
*
* @param amount value to convert
* @param[out] tail where to write the result
*/
static void
amount_to_tail (const struct TALER_Amount *amount,
char tail[TALER_AMOUNT_FRAC_LEN + 1])
{
uint32_t n = amount->fraction;
unsigned int i;
for (i = 0; (i < TALER_AMOUNT_FRAC_LEN) && (0 != n); i++)
{
tail[i] = '0' + (n / (TALER_AMOUNT_FRAC_BASE / 10));
n = (n * 10) % (TALER_AMOUNT_FRAC_BASE);
}
tail[i] = '\0';
}
char *
TALER_amount_to_string (const struct TALER_Amount *amount)
{
char *result;
struct TALER_Amount norm;
if (GNUNET_YES != TALER_amount_is_valid (amount))
return NULL;
norm = *amount;
GNUNET_break (GNUNET_SYSERR !=
TALER_amount_normalize (&norm));
if (0 != norm.fraction)
{
char tail[TALER_AMOUNT_FRAC_LEN + 1];
amount_to_tail (&norm,
tail);
GNUNET_asprintf (&result,
"%s:%llu.%s",
norm.currency,
(unsigned long long) norm.value,
tail);
}
else
{
GNUNET_asprintf (&result,
"%s:%llu",
norm.currency,
(unsigned long long) norm.value);
}
return result;
}
const char *
TALER_amount2s (const struct TALER_Amount *amount)
{
/* 24 is sufficient for a uint64_t value in decimal; 3 is for ":.\0" */
static TALER_THREAD_LOCAL char result[TALER_AMOUNT_FRAC_LEN
+ TALER_CURRENCY_LEN + 3 + 24];
struct TALER_Amount norm;
if (GNUNET_YES != TALER_amount_is_valid (amount))
return NULL;
norm = *amount;
GNUNET_break (GNUNET_SYSERR !=
TALER_amount_normalize (&norm));
if (0 != norm.fraction)
{
char tail[TALER_AMOUNT_FRAC_LEN + 1];
amount_to_tail (&norm,
tail);
GNUNET_snprintf (result,
sizeof (result),
"%s:%llu.%s",
norm.currency,
(unsigned long long) norm.value,
tail);
}
else
{
GNUNET_snprintf (result,
sizeof (result),
"%s:%llu",
norm.currency,
(unsigned long long) norm.value);
}
return result;
}
void
TALER_amount_divide (struct TALER_Amount *result,
const struct TALER_Amount *dividend,
uint32_t divisor)
{
uint64_t modr;
GNUNET_assert (0 != divisor); /* division by zero is discouraged */
*result = *dividend;
/* in case @a dividend was not yet normalized */
GNUNET_assert (GNUNET_SYSERR !=
TALER_amount_normalize (result));
if (1 == divisor)
return;
modr = result->value % divisor;
result->value /= divisor;
/* modr fits into 32 bits, so we can safely multiply by (<32-bit) base and add fraction! */
modr = (modr * TALER_AMOUNT_FRAC_BASE) + result->fraction;
result->fraction = (uint32_t) (modr / divisor);
/* 'fraction' could now be larger than #TALER_AMOUNT_FRAC_BASE, so we must normalize */
GNUNET_assert (GNUNET_SYSERR !=
TALER_amount_normalize (result));
}
int
TALER_amount_divide2 (const struct TALER_Amount *dividend,
const struct TALER_Amount *divisor)
{
double approx;
double d;
double r;
int ret;
struct TALER_Amount tmp;
struct TALER_Amount nxt;
if (GNUNET_YES !=
TALER_amount_cmp_currency (dividend,
divisor))
{
GNUNET_break (0);
return -1;
}
if ( (0 == divisor->fraction) &&
(0 == divisor->value) )
return INT_MAX;
/* first, get rounded approximation */
d = ((double) dividend->value) * ((double) TALER_AMOUNT_FRAC_BASE)
+ ( (double) dividend->fraction);
r = ((double) divisor->value) * ((double) TALER_AMOUNT_FRAC_BASE)
+ ( (double) divisor->fraction);
approx = d / r;
if (approx > ((double) INT_MAX))
return INT_MAX; /* 'infinity' */
/* round down */
if (approx < 2)
ret = 0;
else
ret = (int) approx - 2;
/* Now do *exact* calculation, using well rounded-down factor as starting
point to avoid having to do too many steps. */
GNUNET_assert (0 <=
TALER_amount_multiply (&tmp,
divisor,
ret));
/* in practice, this loop will only run for one or two iterations */
while (1)
{
GNUNET_assert (0 <=
TALER_amount_add (&nxt,
&tmp,
divisor));
if (1 ==
TALER_amount_cmp (&nxt,
dividend))
break; /* nxt > dividend */
ret++;
tmp = nxt;
}
return ret;
}
enum TALER_AmountArithmeticResult
TALER_amount_multiply (struct TALER_Amount *result,
const struct TALER_Amount *amount,
uint32_t factor)
{
struct TALER_Amount in = *amount;
if (GNUNET_SYSERR ==
TALER_amount_normalize (&in))
return TALER_AAR_INVALID_NORMALIZATION_FAILED;
GNUNET_memcpy (result->currency,
amount->currency,
TALER_CURRENCY_LEN);
if ( (0 == factor) ||
( (0 == in.value) &&
(0 == in.fraction) ) )
{
result->value = 0;
result->fraction = 0;
return TALER_AAR_RESULT_ZERO;
}
result->value = in.value * ((uint64_t) factor);
if (in.value != result->value / factor)
return TALER_AAR_INVALID_RESULT_OVERFLOW;
{
/* This multiplication cannot overflow since both inputs are 32-bit values */
uint64_t tmp = ((uint64_t) factor) * ((uint64_t) in.fraction);
uint64_t res;
res = tmp / TALER_AMOUNT_FRAC_BASE;
/* check for overflow */
if (result->value + res < result->value)
return TALER_AAR_INVALID_RESULT_OVERFLOW;
result->value += res;
result->fraction = tmp % TALER_AMOUNT_FRAC_BASE;
}
if (result->value > TALER_AMOUNT_MAX_VALUE)
return TALER_AAR_INVALID_RESULT_OVERFLOW;
/* This check should be redundant... */
GNUNET_assert (GNUNET_SYSERR !=
TALER_amount_normalize (result));
return TALER_AAR_RESULT_POSITIVE;
}
enum GNUNET_GenericReturnValue
TALER_amount_round_down (struct TALER_Amount *amount,
const struct TALER_Amount *round_unit)
{
if (GNUNET_OK !=
TALER_amount_cmp_currency (amount,
round_unit))
{
GNUNET_break (0);
return GNUNET_SYSERR;
}
if ( (0 != round_unit->fraction) &&
(0 != round_unit->value) )
{
GNUNET_break (0);
return GNUNET_SYSERR;
}
if ( (0 == round_unit->fraction) &&
(0 == round_unit->value) )
return GNUNET_NO; /* no rounding requested */
if (0 != round_unit->fraction)
{
uint32_t delta;
delta = amount->fraction % round_unit->fraction;
if (0 == delta)
return GNUNET_NO;
amount->fraction -= delta;
}
if (0 != round_unit->value)
{
uint64_t delta;
delta = amount->value % round_unit->value;
if (0 == delta)
return GNUNET_NO;
amount->value -= delta;
amount->fraction = 0;
}
return GNUNET_OK;
}
/* end of amount.c */