LeOS-Genesis/external/badvpn/ncd/modules/arithmetic.c

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2020-10-05 13:12:00 +02:00
/**
* @file arithmetic.c
* @author Ambroz Bizjak <ambrop7@gmail.com>
*
* @section LICENSE
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. Neither the name of the author nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* @section DESCRIPTION
*
* Arithmetic functions for unsigned integers.
*
* Synopsis:
* num_lesser(string n1, string n2)
* num_greater(string n1, string n2)
* num_lesser_equal(string n1, string n2)
* num_greater_equal(string n1, string n2)
* num_equal(string n1, string n2)
* num_different(string n1, string n2)
*
* Variables:
* (empty) - "true" or "false", reflecting the value of the relation in question
*
* Description:
* These statements perform arithmetic comparisons. The operands passed must be
* non-negative decimal integers representable in a uintmax_t. Otherwise, an error
* is triggered.
*
* Synopsis:
* num_add(string n1, string n2)
* num_subtract(string n1, string n2)
* num_multiply(string n1, string n2)
* num_divide(string n1, string n2)
* num_modulo(string n1, string n2)
*
* Description:
* These statements perform arithmetic operations. The operands passed must be
* non-negative decimal integers representable in a uintmax_t, and the result must
* also be representable and non-negative. For divide and modulo, n2 must be non-zero.
* If any of these restrictions is violated, an error is triggered.
*
* Variables:
* (empty) - the result of the operation as a string representing a decimal number
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <inttypes.h>
#include <limits.h>
#include <misc/parse_number.h>
#include <ncd/NCDModule.h>
#include <ncd/static_strings.h>
#include <ncd/extra/value_utils.h>
#include <generated/blog_channel_ncd_arithmetic.h>
#define ModuleLog(i, ...) NCDModuleInst_Backend_Log((i), BLOG_CURRENT_CHANNEL, __VA_ARGS__)
struct boolean_instance {
NCDModuleInst *i;
int value;
};
typedef int (*boolean_compute_func) (uintmax_t n1, uintmax_t n2);
struct number_instance {
NCDModuleInst *i;
uintmax_t value;
};
typedef int (*number_compute_func) (NCDModuleInst *i, uintmax_t n1, uintmax_t n2, uintmax_t *out);
static int compute_lesser (uintmax_t n1, uintmax_t n2)
{
return n1 < n2;
}
static int compute_greater (uintmax_t n1, uintmax_t n2)
{
return n1 > n2;
}
static int compute_lesser_equal (uintmax_t n1, uintmax_t n2)
{
return n1 <= n2;
}
static int compute_greater_equal (uintmax_t n1, uintmax_t n2)
{
return n1 >= n2;
}
static int compute_equal (uintmax_t n1, uintmax_t n2)
{
return n1 == n2;
}
static int compute_different (uintmax_t n1, uintmax_t n2)
{
return n1 != n2;
}
static int compute_add (NCDModuleInst *i, uintmax_t n1, uintmax_t n2, uintmax_t *out)
{
if (n1 > UINTMAX_MAX - n2) {
ModuleLog(i, BLOG_ERROR, "addition overflow");
return 0;
}
*out = n1 + n2;
return 1;
}
static int compute_subtract (NCDModuleInst *i, uintmax_t n1, uintmax_t n2, uintmax_t *out)
{
if (n1 < n2) {
ModuleLog(i, BLOG_ERROR, "subtraction underflow");
return 0;
}
*out = n1 - n2;
return 1;
}
static int compute_multiply (NCDModuleInst *i, uintmax_t n1, uintmax_t n2, uintmax_t *out)
{
if (n1 > UINTMAX_MAX / n2) {
ModuleLog(i, BLOG_ERROR, "multiplication overflow");
return 0;
}
*out = n1 * n2;
return 1;
}
static int compute_divide (NCDModuleInst *i, uintmax_t n1, uintmax_t n2, uintmax_t *out)
{
if (n2 == 0) {
ModuleLog(i, BLOG_ERROR, "division quotient is zero");
return 0;
}
*out = n1 / n2;
return 1;
}
static int compute_modulo (NCDModuleInst *i, uintmax_t n1, uintmax_t n2, uintmax_t *out)
{
if (n2 == 0) {
ModuleLog(i, BLOG_ERROR, "modulo modulus is zero");
return 0;
}
*out = n1 % n2;
return 1;
}
static void new_boolean_templ (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params, boolean_compute_func cfunc)
{
struct boolean_instance *o = vo;
o->i = i;
NCDValRef n1_arg;
NCDValRef n2_arg;
if (!NCDVal_ListRead(params->args, 2, &n1_arg, &n2_arg)) {
ModuleLog(i, BLOG_ERROR, "wrong arity");
goto fail0;
}
if (!NCDVal_IsString(n1_arg) || !NCDVal_IsString(n2_arg)) {
ModuleLog(o->i, BLOG_ERROR, "wrong type");
goto fail0;
}
uintmax_t n1;
if (!ncd_read_uintmax(n1_arg, &n1)) {
ModuleLog(o->i, BLOG_ERROR, "wrong first argument");
goto fail0;
}
uintmax_t n2;
if (!ncd_read_uintmax(n2_arg, &n2)) {
ModuleLog(o->i, BLOG_ERROR, "wrong second argument");
goto fail0;
}
o->value = cfunc(n1, n2);
NCDModuleInst_Backend_Up(i);
return;
fail0:
NCDModuleInst_Backend_DeadError(i);
}
static int boolean_func_getvar2 (void *vo, NCD_string_id_t name, NCDValMem *mem, NCDValRef *out)
{
struct boolean_instance *o = vo;
if (name == NCD_STRING_EMPTY) {
*out = ncd_make_boolean(mem, o->value, o->i->params->iparams->string_index);
return 1;
}
return 0;
}
static void new_number_templ (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params, number_compute_func cfunc)
{
struct number_instance *o = vo;
o->i = i;
NCDValRef n1_arg;
NCDValRef n2_arg;
if (!NCDVal_ListRead(params->args, 2, &n1_arg, &n2_arg)) {
ModuleLog(i, BLOG_ERROR, "wrong arity");
goto fail0;
}
if (!NCDVal_IsString(n1_arg) || !NCDVal_IsString(n2_arg)) {
ModuleLog(o->i, BLOG_ERROR, "wrong type");
goto fail0;
}
uintmax_t n1;
if (!ncd_read_uintmax(n1_arg, &n1)) {
ModuleLog(o->i, BLOG_ERROR, "wrong first argument");
goto fail0;
}
uintmax_t n2;
if (!ncd_read_uintmax(n2_arg, &n2)) {
ModuleLog(o->i, BLOG_ERROR, "wrong second argument");
goto fail0;
}
if (!cfunc(i, n1, n2, &o->value)) {
goto fail0;
}
NCDModuleInst_Backend_Up(i);
return;
fail0:
NCDModuleInst_Backend_DeadError(i);
}
static int number_func_getvar2 (void *vo, NCD_string_id_t name, NCDValMem *mem, NCDValRef *out)
{
struct number_instance *o = vo;
if (name == NCD_STRING_EMPTY) {
*out = ncd_make_uintmax(mem, o->value);
return 1;
}
return 0;
}
static void func_new_lesser (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params)
{
new_boolean_templ(vo, i, params, compute_lesser);
}
static void func_new_greater (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params)
{
new_boolean_templ(vo, i, params, compute_greater);
}
static void func_new_lesser_equal (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params)
{
new_boolean_templ(vo, i, params, compute_lesser_equal);
}
static void func_new_greater_equal (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params)
{
new_boolean_templ(vo, i, params, compute_greater_equal);
}
static void func_new_equal (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params)
{
new_boolean_templ(vo, i, params, compute_equal);
}
static void func_new_different (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params)
{
new_boolean_templ(vo, i, params, compute_different);
}
static void func_new_add (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params)
{
new_number_templ(vo, i, params, compute_add);
}
static void func_new_subtract (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params)
{
new_number_templ(vo, i, params, compute_subtract);
}
static void func_new_multiply (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params)
{
new_number_templ(vo, i, params, compute_multiply);
}
static void func_new_divide (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params)
{
new_number_templ(vo, i, params, compute_divide);
}
static void func_new_modulo (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params)
{
new_number_templ(vo, i, params, compute_modulo);
}
static struct NCDModule modules[] = {
{
.type = "num_lesser",
.func_new2 = func_new_lesser,
.func_getvar2 = boolean_func_getvar2,
.alloc_size = sizeof(struct boolean_instance),
.flags = NCDMODULE_FLAG_ACCEPT_NON_CONTINUOUS_STRINGS
}, {
.type = "num_greater",
.func_new2 = func_new_greater,
.func_getvar2 = boolean_func_getvar2,
.alloc_size = sizeof(struct boolean_instance),
.flags = NCDMODULE_FLAG_ACCEPT_NON_CONTINUOUS_STRINGS
}, {
.type = "num_lesser_equal",
.func_new2 = func_new_lesser_equal,
.func_getvar2 = boolean_func_getvar2,
.alloc_size = sizeof(struct boolean_instance),
.flags = NCDMODULE_FLAG_ACCEPT_NON_CONTINUOUS_STRINGS
}, {
.type = "num_greater_equal",
.func_new2 = func_new_greater_equal,
.func_getvar2 = boolean_func_getvar2,
.alloc_size = sizeof(struct boolean_instance),
.flags = NCDMODULE_FLAG_ACCEPT_NON_CONTINUOUS_STRINGS
}, {
.type = "num_equal",
.func_new2 = func_new_equal,
.func_getvar2 = boolean_func_getvar2,
.alloc_size = sizeof(struct boolean_instance),
.flags = NCDMODULE_FLAG_ACCEPT_NON_CONTINUOUS_STRINGS
}, {
.type = "num_different",
.func_new2 = func_new_different,
.func_getvar2 = boolean_func_getvar2,
.alloc_size = sizeof(struct boolean_instance),
.flags = NCDMODULE_FLAG_ACCEPT_NON_CONTINUOUS_STRINGS
}, {
.type = "num_add",
.func_new2 = func_new_add,
.func_getvar2 = number_func_getvar2,
.alloc_size = sizeof(struct number_instance),
.flags = NCDMODULE_FLAG_ACCEPT_NON_CONTINUOUS_STRINGS
}, {
.type = "num_subtract",
.func_new2 = func_new_subtract,
.func_getvar2 = number_func_getvar2,
.alloc_size = sizeof(struct number_instance),
.flags = NCDMODULE_FLAG_ACCEPT_NON_CONTINUOUS_STRINGS
}, {
.type = "num_multiply",
.func_new2 = func_new_multiply,
.func_getvar2 = number_func_getvar2,
.alloc_size = sizeof(struct number_instance),
.flags = NCDMODULE_FLAG_ACCEPT_NON_CONTINUOUS_STRINGS
}, {
.type = "num_divide",
.func_new2 = func_new_divide,
.func_getvar2 = number_func_getvar2,
.alloc_size = sizeof(struct number_instance),
.flags = NCDMODULE_FLAG_ACCEPT_NON_CONTINUOUS_STRINGS
}, {
.type = "num_modulo",
.func_new2 = func_new_modulo,
.func_getvar2 = number_func_getvar2,
.alloc_size = sizeof(struct number_instance),
.flags = NCDMODULE_FLAG_ACCEPT_NON_CONTINUOUS_STRINGS
}, {
.type = NULL
}
};
const struct NCDModuleGroup ncdmodule_arithmetic = {
.modules = modules
};