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coral / a71ch-crypto-support / 8dc1f1434da50a4b7361d651239c1f3f4f8cc25b / . / ext / open62541 / tests / check_chunking.c
blob: 6513582b989448af1a728780f302ef3c2c21b27a [file] [log] [blame]
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include <open62541/types.h>
#include "ua_securechannel.h"
#include "ua_types_encoding_binary.h"
#include <check.h>
UA_ByteString *buffers;
size_t bufIndex;
size_t counter;
size_t dataCount;
static UA_StatusCode
sendChunkMockUp(void *_, UA_Byte **bufPos, const UA_Byte **bufEnd) {
size_t offset = (uintptr_t)(*bufPos - buffers[bufIndex].data);
bufIndex++;
*bufPos = buffers[bufIndex].data;
*bufEnd = &(*bufPos)[buffers[bufIndex].length];
counter++;
dataCount += offset;
return UA_STATUSCODE_GOOD;
}
START_TEST(encodeArrayIntoFiveChunksShallWork) {
size_t arraySize = 30; //number of elements within the array which should be encoded
size_t chunkCount = 6; // maximum chunk count
size_t chunkSize = 30; //size in bytes of each chunk
bufIndex = 0;
counter = 0;
dataCount = 0;
buffers = (UA_ByteString*)UA_Array_new(chunkCount, &UA_TYPES[UA_TYPES_BYTESTRING]);
for(size_t i=0;i<chunkCount;i++){
UA_ByteString_allocBuffer(&buffers[i],chunkSize);
}
UA_Int32 *ar = (UA_Int32*)UA_Array_new(arraySize,&UA_TYPES[UA_TYPES_INT32]);
for(size_t i = 0; i < arraySize; i++)
ar[i] = (UA_Int32)i;
UA_Variant v;
UA_Variant_setArrayCopy(&v, ar, arraySize, &UA_TYPES[UA_TYPES_INT32]);
UA_ByteString workingBuffer = buffers[0];
UA_Byte *pos = workingBuffer.data;
const UA_Byte *end = &workingBuffer.data[workingBuffer.length];
UA_StatusCode retval = UA_encodeBinary(&v,&UA_TYPES[UA_TYPES_VARIANT],
&pos, &end, sendChunkMockUp, NULL);
ck_assert_uint_eq(retval,UA_STATUSCODE_GOOD);
ck_assert_int_eq(counter,4); //5 chunks allocated - callback called 4 times
dataCount += (uintptr_t)(pos - buffers[bufIndex].data);
ck_assert_int_eq(UA_calcSizeBinary(&v,&UA_TYPES[UA_TYPES_VARIANT]), dataCount);
UA_Variant_deleteMembers(&v);
UA_Array_delete(buffers, chunkCount, &UA_TYPES[UA_TYPES_BYTESTRING]);
UA_Array_delete(ar, arraySize, &UA_TYPES[UA_TYPES_INT32]);
} END_TEST
START_TEST(encodeStringIntoFiveChunksShallWork) {
size_t stringLength = 120; //number of elements within the array which should be encoded
size_t chunkCount = 6; // maximum chunk count
size_t chunkSize = 30; //size in bytes of each chunk
UA_String string;
bufIndex = 0;
counter = 0;
dataCount = 0;
UA_String_init(&string);
string.data = (UA_Byte*)UA_malloc(stringLength);
string.length = stringLength;
char tmpString[9] = {'o','p','e','n','6','2','5','4','1'};
//char tmpString[9] = {'1','4','5','2','6','n','e','p','o'};
buffers = (UA_ByteString*)UA_Array_new(chunkCount, &UA_TYPES[UA_TYPES_BYTESTRING]);
for(size_t i=0;i<chunkCount;i++){
UA_ByteString_allocBuffer(&buffers[i],chunkSize);
}
UA_ByteString workingBuffer=buffers[0];
for(size_t i=0;i<stringLength;i++){
size_t tmp = i % 9;
string.data[i] = tmpString[tmp];
}
UA_Variant v;
UA_Variant_setScalarCopy(&v,&string,&UA_TYPES[UA_TYPES_STRING]);
UA_Byte *pos = workingBuffer.data;
const UA_Byte *end = &workingBuffer.data[workingBuffer.length];
UA_StatusCode retval = UA_encodeBinary(&v, &UA_TYPES[UA_TYPES_VARIANT],
&pos, &end, sendChunkMockUp, NULL);
ck_assert_uint_eq(retval,UA_STATUSCODE_GOOD);
ck_assert_int_eq(counter,4); //5 chunks allocated - callback called 4 times
dataCount += (uintptr_t)(pos - buffers[bufIndex].data);
ck_assert_int_eq(UA_calcSizeBinary(&v,&UA_TYPES[UA_TYPES_VARIANT]), dataCount);
UA_Variant_deleteMembers(&v);
UA_Array_delete(buffers, chunkCount, &UA_TYPES[UA_TYPES_BYTESTRING]);
UA_String_deleteMembers(&string);
} END_TEST
START_TEST(encodeTwoStringsIntoTenChunksShallWork) {
size_t stringLength = 143; //number of elements within the array which should be encoded
size_t chunkCount = 10; // maximum chunk count
size_t chunkSize = 30; //size in bytes of each chunk
UA_String string;
bufIndex = 0;
counter = 0;
dataCount = 0;
UA_String_init(&string);
string.data = (UA_Byte*)UA_malloc(stringLength);
string.length = stringLength;
char tmpString[9] = {'o','p','e','n','6','2','5','4','1'};
buffers = (UA_ByteString*)UA_Array_new(chunkCount, &UA_TYPES[UA_TYPES_BYTESTRING]);
for(size_t i=0;i<chunkCount;i++){
UA_ByteString_allocBuffer(&buffers[i],chunkSize);
}
UA_ByteString workingBuffer=buffers[0];
for(size_t i=0;i<stringLength;i++){
size_t tmp = i % 9;
string.data[i] = tmpString[tmp];
}
UA_Byte *pos = workingBuffer.data;
const UA_Byte *end = &workingBuffer.data[workingBuffer.length];
UA_StatusCode retval = UA_encodeBinary(&string, &UA_TYPES[UA_TYPES_STRING],
&pos, &end, sendChunkMockUp, NULL);
ck_assert_uint_eq(retval,UA_STATUSCODE_GOOD);
ck_assert_int_eq(counter,4); //5 chunks allocated - callback called 4 times
size_t offset = (uintptr_t)(pos - buffers[bufIndex].data);
ck_assert_int_eq(UA_calcSizeBinary(&string,&UA_TYPES[UA_TYPES_STRING]), dataCount + offset);
retval = UA_encodeBinary(&string,&UA_TYPES[UA_TYPES_STRING],
&pos, &end, sendChunkMockUp, NULL);
dataCount += (uintptr_t)(pos - buffers[bufIndex].data);
ck_assert_uint_eq(retval,UA_STATUSCODE_GOOD);
ck_assert_int_eq(counter,9); //10 chunks allocated - callback called 4 times
ck_assert_int_eq(2 * UA_calcSizeBinary(&string,&UA_TYPES[UA_TYPES_STRING]), dataCount);
UA_Array_delete(buffers, chunkCount, &UA_TYPES[UA_TYPES_BYTESTRING]);
UA_String_deleteMembers(&string);
} END_TEST
int main(void) {
Suite *s = suite_create("Chunked encoding");
TCase *tc_message = tcase_create("encode chunking");
tcase_add_test(tc_message,encodeArrayIntoFiveChunksShallWork);
tcase_add_test(tc_message,encodeStringIntoFiveChunksShallWork);
tcase_add_test(tc_message,encodeTwoStringsIntoTenChunksShallWork);
suite_add_tcase(s, tc_message);
SRunner *sr = srunner_create(s);
srunner_set_fork_status(sr, CK_NOFORK);
srunner_run_all(sr, CK_NORMAL);
int number_failed = srunner_ntests_failed(sr);
srunner_free(sr);
return (number_failed == 0) ? EXIT_SUCCESS : EXIT_FAILURE;
}