#include "stream_expectations.h" struct test_assertion assertions_queue[MAX_QUEUE_ITEMS]; int queue_size = 0; int current_expectation = 0; int clean_up_stream_assertions(void **state) { if (queue_size != current_expectation) { return 1; // We have not matched all expectations correctly } queue_size = current_expectation = 0; free(*state); return 0; } /* Callbacks */ struct test_assertion current(void) { return assertions_queue[current_expectation]; } /* Assertions builders and matcher callbacks */ void assert_uint8_eq(uint8_t actual) { assertions_queue[queue_size++] = (struct test_assertion){ UINT8_EQ, (union test_expectation_data){.int8 = actual}}; } void uint8_callback(void *_CBOR_UNUSED(_context), uint8_t actual) { assert_true(current().expectation == UINT8_EQ); assert_true(current().data.int8 == actual); current_expectation++; } void assert_uint16_eq(uint16_t actual) { assertions_queue[queue_size++] = (struct test_assertion){ UINT16_EQ, (union test_expectation_data){.int16 = actual}}; } void uint16_callback(void *_CBOR_UNUSED(_context), uint16_t actual) { assert_true(current().expectation == UINT16_EQ); assert_true(current().data.int16 == actual); current_expectation++; } void assert_uint32_eq(uint32_t actual) { assertions_queue[queue_size++] = (struct test_assertion){ UINT32_EQ, (union test_expectation_data){.int32 = actual}}; } void uint32_callback(void *_CBOR_UNUSED(_context), uint32_t actual) { assert_true(current().expectation == UINT32_EQ); assert_true(current().data.int32 == actual); current_expectation++; } void assert_uint64_eq(uint64_t actual) { assertions_queue[queue_size++] = (struct test_assertion){ UINT64_EQ, (union test_expectation_data){.int64 = actual}}; } void uint64_callback(void *_CBOR_UNUSED(_context), uint64_t actual) { assert_true(current().expectation == UINT64_EQ); assert_true(current().data.int64 == actual); current_expectation++; } void assert_negint8_eq(uint8_t actual) { assertions_queue[queue_size++] = (struct test_assertion){ NEGINT8_EQ, (union test_expectation_data){.int8 = actual}}; } void negint8_callback(void *_CBOR_UNUSED(_context), uint8_t actual) { assert_true(current().expectation == NEGINT8_EQ); assert_true(current().data.int8 == actual); current_expectation++; } void assert_negint16_eq(uint16_t actual) { assertions_queue[queue_size++] = (struct test_assertion){ NEGINT16_EQ, (union test_expectation_data){.int16 = actual}}; } void negint16_callback(void *_CBOR_UNUSED(_context), uint16_t actual) { assert_true(current().expectation == NEGINT16_EQ); assert_true(current().data.int16 == actual); current_expectation++; } void assert_negint32_eq(uint32_t actual) { assertions_queue[queue_size++] = (struct test_assertion){ NEGINT32_EQ, (union test_expectation_data){.int32 = actual}}; } void negint32_callback(void *_CBOR_UNUSED(_context), uint32_t actual) { assert_true(current().expectation == NEGINT32_EQ); assert_true(current().data.int32 == actual); current_expectation++; } void assert_negint64_eq(uint64_t actual) { assertions_queue[queue_size++] = (struct test_assertion){ NEGINT64_EQ, (union test_expectation_data){.int64 = actual}}; } void negint64_callback(void *_CBOR_UNUSED(_context), uint64_t actual) { assert_true(current().expectation == NEGINT64_EQ); assert_true(current().data.int64 == actual); current_expectation++; } void assert_bstring_mem_eq(cbor_data address, size_t length) { assertions_queue[queue_size++] = (struct test_assertion){ BSTRING_MEM_EQ, (union test_expectation_data){.string = {address, length}}}; } void byte_string_callback(void *_CBOR_UNUSED(_context), cbor_data address, uint64_t length) { assert_true(current().expectation == BSTRING_MEM_EQ); assert_true(current().data.string.address == address); assert_true(current().data.string.length == length); current_expectation++; } void assert_bstring_indef_start(void) { assertions_queue[queue_size++] = (struct test_assertion){.expectation = BSTRING_INDEF_START}; } void byte_string_start_callback(void *_CBOR_UNUSED(_context)) { assert_true(current().expectation == BSTRING_INDEF_START); current_expectation++; } void assert_string_mem_eq(cbor_data address, size_t length) { assertions_queue[queue_size++] = (struct test_assertion){ STRING_MEM_EQ, (union test_expectation_data){.string = {address, length}}}; } void string_callback(void *_CBOR_UNUSED(_context), cbor_data address, uint64_t length) { assert_true(current().expectation == STRING_MEM_EQ); assert_true(current().data.string.address == address); assert_true(current().data.string.length == length); current_expectation++; } void assert_string_indef_start(void) { assertions_queue[queue_size++] = (struct test_assertion){.expectation = STRING_INDEF_START}; } void string_start_callback(void *_CBOR_UNUSED(_context)) { assert_true(current().expectation == STRING_INDEF_START); current_expectation++; } void assert_indef_break(void) { assertions_queue[queue_size++] = (struct test_assertion){.expectation = INDEF_BREAK}; } void indef_break_callback(void *_CBOR_UNUSED(_context)) { assert_true(current().expectation == INDEF_BREAK); current_expectation++; } void assert_array_start(size_t length) { assertions_queue[queue_size++] = (struct test_assertion){ARRAY_START, {.length = length}}; } void array_start_callback(void *_CBOR_UNUSED(_context), uint64_t length) { assert_true(current().expectation == ARRAY_START); assert_true(current().data.length == length); current_expectation++; } void assert_indef_array_start(void) { assertions_queue[queue_size++] = (struct test_assertion){.expectation = ARRAY_INDEF_START}; } void indef_array_start_callback(void *_CBOR_UNUSED(_context)) { assert_true(current().expectation == ARRAY_INDEF_START); current_expectation++; } void assert_map_start(size_t length) { assertions_queue[queue_size++] = (struct test_assertion){MAP_START, {.length = length}}; } void map_start_callback(void *_CBOR_UNUSED(_context), uint64_t length) { assert_true(current().expectation == MAP_START); assert_true(current().data.length == length); current_expectation++; } void assert_indef_map_start(void) { assertions_queue[queue_size++] = (struct test_assertion){.expectation = MAP_INDEF_START}; } void indef_map_start_callback(void *_CBOR_UNUSED(_context)) { assert_true(current().expectation == MAP_INDEF_START); current_expectation++; } void assert_tag_eq(uint64_t value) { assertions_queue[queue_size++] = (struct test_assertion){TAG_EQ, {.int64 = value}}; } void tag_callback(void *_CBOR_UNUSED(_context), uint64_t value) { assert_true(current().expectation == TAG_EQ); assert_true(current().data.int64 == value); current_expectation++; } void assert_half(float value) { assertions_queue[queue_size++] = (struct test_assertion){HALF_EQ, {.float2 = value}}; } void half_callback(void *_CBOR_UNUSED(_context), float actual) { assert_true(current().expectation == HALF_EQ); assert_true(current().data.float2 == actual); current_expectation++; } void assert_float(float value) { assertions_queue[queue_size++] = (struct test_assertion){FLOAT_EQ, {.float4 = value}}; } void float_callback(void *_CBOR_UNUSED(_context), float actual) { assert_true(current().expectation == FLOAT_EQ); assert_true(current().data.float4 == actual); current_expectation++; } void assert_double(double value) { assertions_queue[queue_size++] = (struct test_assertion){DOUBLE_EQ, {.float8 = value}}; } void double_callback(void *_CBOR_UNUSED(_context), double actual) { assert_true(current().expectation == DOUBLE_EQ); assert_true(current().data.float8 == actual); current_expectation++; } void assert_bool(bool value) { assertions_queue[queue_size++] = (struct test_assertion){BOOL_EQ, {.boolean = value}}; } void assert_nil(void) { assertions_queue[queue_size++] = (struct test_assertion){.expectation = NIL}; } void assert_undef(void) { assertions_queue[queue_size++] = (struct test_assertion){.expectation = UNDEF}; } void bool_callback(void *_CBOR_UNUSED(_context), bool actual) { assert_true(current().expectation == BOOL_EQ); assert_true(current().data.boolean == actual); current_expectation++; } void null_callback(void *_CBOR_UNUSED(_context)) { assert_true(current().expectation == NIL); current_expectation++; } void undef_callback(void *_CBOR_UNUSED(_context)) { assert_true(current().expectation == UNDEF); current_expectation++; } const struct cbor_callbacks asserting_callbacks = { .uint8 = &uint8_callback, .uint16 = &uint16_callback, .uint32 = &uint32_callback, .uint64 = &uint64_callback, .negint8 = &negint8_callback, .negint16 = &negint16_callback, .negint32 = &negint32_callback, .negint64 = &negint64_callback, .byte_string = &byte_string_callback, .byte_string_start = &byte_string_start_callback, .string = &string_callback, .string_start = &string_start_callback, .array_start = &array_start_callback, .indef_array_start = &indef_array_start_callback, .map_start = &map_start_callback, .indef_map_start = &indef_map_start_callback, .tag = &tag_callback, .float2 = &half_callback, .float4 = &float_callback, .float8 = &double_callback, .undefined = &undef_callback, .boolean = &bool_callback, .null = &null_callback, .indef_break = &indef_break_callback}; struct cbor_decoder_result decode(cbor_data source, size_t source_size) { int last_expectation = current_expectation; struct cbor_decoder_result result = cbor_stream_decode(source, source_size, &asserting_callbacks, NULL); if (result.status == CBOR_DECODER_FINISHED) { // Check that we have matched an expectation from the queue assert_true(last_expectation + 1 == current_expectation); } return result; }