/* ========================================== Unity Project - A Test Framework for C Copyright (c) 2007 Mike Karlesky, Mark VanderVoord, Greg Williams [Released under MIT License. Please refer to license.txt for details] ========================================== */ #include "unity.h" #include #include #define UNITY_FAIL_AND_BAIL { Unity.CurrentTestFailed = 1; UNITY_OUTPUT_CHAR('\n'); longjmp(Unity.AbortFrame, 1); } #define UNITY_IGNORE_AND_BAIL { Unity.CurrentTestIgnored = 1; UNITY_OUTPUT_CHAR('\n'); longjmp(Unity.AbortFrame, 1); } /// return prematurely if we are already in failure or ignore state #define UNITY_SKIP_EXECUTION { if ((Unity.CurrentTestFailed != 0) || (Unity.CurrentTestIgnored != 0)) {return;} } #define UNITY_PRINT_EOL { UNITY_OUTPUT_CHAR('\n'); } struct _Unity Unity = { 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , { 0 } }; const char* UnityStrNull = "NULL"; const char* UnityStrSpacer = ". "; const char* UnityStrExpected = " Expected "; const char* UnityStrWas = " Was "; const char* UnityStrTo = " To "; const char* UnityStrElement = " Element "; const char* UnityStrByte = " Byte "; const char* UnityStrMemory = " Memory Mismatch."; const char* UnityStrDelta = " Values Not Within Delta "; const char* UnityStrPointless= " You Asked Me To Compare Nothing, Which Was Pointless."; const char* UnityStrNullPointerForExpected= " Expected pointer to be NULL"; const char* UnityStrNullPointerForActual = " Actual pointer was NULL"; const char* UnityStrInf = "Infinity"; const char* UnityStrNegInf = "Negative Infinity"; const char* UnityStrNaN = "NaN"; // compiler-generic print formatting masks const _U_UINT UnitySizeMask[] = { 255u, // 0xFF 65535u, // 0xFFFF 65535u, 4294967295u, // 0xFFFFFFFF 4294967295u, 4294967295u, 4294967295u #ifdef UNITY_SUPPORT_64 ,0xFFFFFFFFFFFFFFFF #endif }; void UnityPrintFail(void); void UnityPrintOk(void); //----------------------------------------------- // Pretty Printers & Test Result Output Handlers //----------------------------------------------- void UnityPrint(const char* string) { const char* pch = string; if (pch != NULL) { while (*pch) { // printable characters plus CR & LF are printed if ((*pch <= 126) && (*pch >= 32)) { UNITY_OUTPUT_CHAR(*pch); } //write escaped carriage returns else if (*pch == 13) { UNITY_OUTPUT_CHAR('\\'); UNITY_OUTPUT_CHAR('r'); } //write escaped line feeds else if (*pch == 10) { UNITY_OUTPUT_CHAR('\\'); UNITY_OUTPUT_CHAR('n'); } // unprintable characters are shown as codes else { UNITY_OUTPUT_CHAR('\\'); UnityPrintNumberHex((_U_SINT)*pch, 2); } pch++; } } } //----------------------------------------------- void UnityPrintNumberByStyle(const _U_SINT number, const UNITY_DISPLAY_STYLE_T style) { if ((style & UNITY_DISPLAY_RANGE_INT) == UNITY_DISPLAY_RANGE_INT) { UnityPrintNumber(number); } else if ((style & UNITY_DISPLAY_RANGE_UINT) == UNITY_DISPLAY_RANGE_UINT) { UnityPrintNumberUnsigned( (_U_UINT)number & UnitySizeMask[((_U_UINT)style & (_U_UINT)0x0F) - 1] ); } else { UnityPrintNumberHex((_U_UINT)number, (style & 0x000F) << 1); } } //----------------------------------------------- /// basically do an itoa using as little ram as possible void UnityPrintNumber(const _U_SINT number_to_print) { _U_SINT divisor = 1; _U_SINT next_divisor; _U_SINT number = number_to_print; if (number < 0) { UNITY_OUTPUT_CHAR('-'); number = -number; } // figure out initial divisor while (number / divisor > 9) { next_divisor = divisor * 10; if (next_divisor > divisor) divisor = next_divisor; else break; } // now mod and print, then divide divisor do { UNITY_OUTPUT_CHAR((char)('0' + (number / divisor % 10))); divisor /= 10; } while (divisor > 0); } //----------------------------------------------- /// basically do an itoa using as little ram as possible void UnityPrintNumberUnsigned(const _U_UINT number) { _U_UINT divisor = 1; _U_UINT next_divisor; // figure out initial divisor while (number / divisor > 9) { next_divisor = divisor * 10; if (next_divisor > divisor) divisor = next_divisor; else break; } // now mod and print, then divide divisor do { UNITY_OUTPUT_CHAR((char)('0' + (number / divisor % 10))); divisor /= 10; } while (divisor > 0); } //----------------------------------------------- void UnityPrintNumberHex(const _U_UINT number, const char nibbles_to_print) { _U_UINT nibble; char nibbles = nibbles_to_print; UNITY_OUTPUT_CHAR('0'); UNITY_OUTPUT_CHAR('x'); while (nibbles > 0) { nibble = (number >> (--nibbles << 2)) & 0x0000000F; if (nibble <= 9) { UNITY_OUTPUT_CHAR((char)('0' + nibble)); } else { UNITY_OUTPUT_CHAR((char)('A' - 10 + nibble)); } } } //----------------------------------------------- void UnityPrintMask(const _U_UINT mask, const _U_UINT number) { _U_UINT current_bit = (_U_UINT)1 << (UNITY_INT_WIDTH - 1); _US32 i; for (i = 0; i < UNITY_INT_WIDTH; i++) { if (current_bit & mask) { if (current_bit & number) { UNITY_OUTPUT_CHAR('1'); } else { UNITY_OUTPUT_CHAR('0'); } } else { UNITY_OUTPUT_CHAR('X'); } current_bit = current_bit >> 1; } } //----------------------------------------------- #ifdef UNITY_FLOAT_VERBOSE void UnityPrintFloat(_UF number) { char TempBuffer[32]; sprintf(TempBuffer, "%.6f", number); UnityPrint(TempBuffer); } #endif //----------------------------------------------- void UnityPrintFail(void) { UnityPrint("FAIL"); } void UnityPrintOk(void) { UnityPrint("OK"); } //----------------------------------------------- void UnityTestResultsBegin(const char* file, const UNITY_LINE_TYPE line) { UnityPrint(file); UNITY_OUTPUT_CHAR(':'); UnityPrintNumber(line); UNITY_OUTPUT_CHAR(':'); UnityPrint(Unity.CurrentTestName); UNITY_OUTPUT_CHAR(':'); } //----------------------------------------------- void UnityTestResultsFailBegin(const UNITY_LINE_TYPE line) { UnityTestResultsBegin(Unity.TestFile, line); UnityPrint("FAIL:"); } //----------------------------------------------- void UnityConcludeTest(void) { if (Unity.CurrentTestIgnored) { Unity.TestIgnores++; } else if (!Unity.CurrentTestFailed) { UnityTestResultsBegin(Unity.TestFile, Unity.CurrentTestLineNumber); UnityPrint("PASS"); UNITY_PRINT_EOL; } else { Unity.TestFailures++; } Unity.CurrentTestFailed = 0; Unity.CurrentTestIgnored = 0; } //----------------------------------------------- void UnityAddMsgIfSpecified(const char* msg) { if (msg) { UnityPrint(UnityStrSpacer); UnityPrint(msg); } } //----------------------------------------------- void UnityPrintExpectedAndActualStrings(const char* expected, const char* actual) { UnityPrint(UnityStrExpected); if (expected != NULL) { UNITY_OUTPUT_CHAR('\''); UnityPrint(expected); UNITY_OUTPUT_CHAR('\''); } else { UnityPrint(UnityStrNull); } UnityPrint(UnityStrWas); if (actual != NULL) { UNITY_OUTPUT_CHAR('\''); UnityPrint(actual); UNITY_OUTPUT_CHAR('\''); } else { UnityPrint(UnityStrNull); } } //----------------------------------------------- // Assertion & Control Helpers //----------------------------------------------- int UnityCheckArraysForNull(const void* expected, const void* actual, const UNITY_LINE_TYPE lineNumber, const char* msg) { //return true if they are both NULL if ((expected == NULL) && (actual == NULL)) return 1; //throw error if just expected is NULL if (expected == NULL) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrNullPointerForExpected); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } //throw error if just actual is NULL if (actual == NULL) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrNullPointerForActual); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } //return false if neither is NULL return 0; } //----------------------------------------------- // Assertion Functions //----------------------------------------------- void UnityAssertBits(const _U_SINT mask, const _U_SINT expected, const _U_SINT actual, const char* msg, const UNITY_LINE_TYPE lineNumber) { UNITY_SKIP_EXECUTION; if ((mask & expected) != (mask & actual)) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrExpected); UnityPrintMask(mask, expected); UnityPrint(UnityStrWas); UnityPrintMask(mask, actual); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } } //----------------------------------------------- void UnityAssertEqualNumber(const _U_SINT expected, const _U_SINT actual, const char* msg, const UNITY_LINE_TYPE lineNumber, const UNITY_DISPLAY_STYLE_T style) { UNITY_SKIP_EXECUTION; if (expected != actual) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrExpected); UnityPrintNumberByStyle(expected, style); UnityPrint(UnityStrWas); UnityPrintNumberByStyle(actual, style); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } } //----------------------------------------------- void UnityAssertEqualIntArray(const _U_SINT* expected, const _U_SINT* actual, const _UU32 num_elements, const char* msg, const UNITY_LINE_TYPE lineNumber, const UNITY_DISPLAY_STYLE_T style) { _UU32 elements = num_elements; const _US8* ptr_exp = (_US8*)expected; const _US8* ptr_act = (_US8*)actual; UNITY_SKIP_EXECUTION; if (elements == 0) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrPointless); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } if (UnityCheckArraysForNull((void*)expected, (void*)actual, lineNumber, msg) == 1) return; switch(style) { case UNITY_DISPLAY_STYLE_HEX8: case UNITY_DISPLAY_STYLE_INT8: case UNITY_DISPLAY_STYLE_UINT8: while (elements--) { if (*ptr_exp != *ptr_act) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrElement); UnityPrintNumberByStyle((num_elements - elements - 1), UNITY_DISPLAY_STYLE_UINT); UnityPrint(UnityStrExpected); UnityPrintNumberByStyle(*ptr_exp, style); UnityPrint(UnityStrWas); UnityPrintNumberByStyle(*ptr_act, style); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } ptr_exp += 1; ptr_act += 1; } break; case UNITY_DISPLAY_STYLE_HEX16: case UNITY_DISPLAY_STYLE_INT16: case UNITY_DISPLAY_STYLE_UINT16: while (elements--) { if (*(_US16*)ptr_exp != *(_US16*)ptr_act) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrElement); UnityPrintNumberByStyle((num_elements - elements - 1), UNITY_DISPLAY_STYLE_UINT); UnityPrint(UnityStrExpected); UnityPrintNumberByStyle(*(_US16*)ptr_exp, style); UnityPrint(UnityStrWas); UnityPrintNumberByStyle(*(_US16*)ptr_act, style); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } ptr_exp += 2; ptr_act += 2; } break; #ifdef UNITY_SUPPORT_64 case UNITY_DISPLAY_STYLE_HEX64: case UNITY_DISPLAY_STYLE_INT64: case UNITY_DISPLAY_STYLE_UINT64: while (elements--) { if (*(_US64*)ptr_exp != *(_US64*)ptr_act) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrElement); UnityPrintNumberByStyle((num_elements - elements - 1), UNITY_DISPLAY_STYLE_UINT); UnityPrint(UnityStrExpected); UnityPrintNumberByStyle(*(_US64*)ptr_exp, style); UnityPrint(UnityStrWas); UnityPrintNumberByStyle(*(_US64*)ptr_act, style); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } ptr_exp += 8; ptr_act += 8; } break; #endif default: while (elements--) { if (*(_US32*)ptr_exp != *(_US32*)ptr_act) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrElement); UnityPrintNumberByStyle((num_elements - elements - 1), UNITY_DISPLAY_STYLE_UINT); UnityPrint(UnityStrExpected); UnityPrintNumberByStyle(*(_US32*)ptr_exp, style); UnityPrint(UnityStrWas); UnityPrintNumberByStyle(*(_US32*)ptr_act, style); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } ptr_exp += 4; ptr_act += 4; } break; } } //----------------------------------------------- #ifndef UNITY_EXCLUDE_FLOAT void UnityAssertEqualFloatArray(const _UF* expected, const _UF* actual, const _UU32 num_elements, const char* msg, const UNITY_LINE_TYPE lineNumber) { _UU32 elements = num_elements; const _UF* ptr_expected = expected; const _UF* ptr_actual = actual; _UF diff, tol; UNITY_SKIP_EXECUTION; if (elements == 0) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrPointless); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } if (UnityCheckArraysForNull((void*)expected, (void*)actual, lineNumber, msg) == 1) return; while (elements--) { diff = *ptr_expected - *ptr_actual; if (diff < 0.0) diff = 0.0 - diff; tol = UNITY_FLOAT_PRECISION * *ptr_expected; if (tol < 0.0) tol = 0.0 - tol; //This first part of this condition will catch any NaN or Infinite values if ((diff * 0.0f != 0.0f) || (diff > tol)) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrElement); UnityPrintNumberByStyle((num_elements - elements - 1), UNITY_DISPLAY_STYLE_UINT); #ifdef UNITY_FLOAT_VERBOSE UnityPrint(UnityStrExpected); UnityPrintFloat(*ptr_expected); UnityPrint(UnityStrWas); UnityPrintFloat(*ptr_actual); #else UnityPrint(UnityStrDelta); #endif UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } ptr_expected++; ptr_actual++; } } //----------------------------------------------- void UnityAssertFloatsWithin(const _UF delta, const _UF expected, const _UF actual, const char* msg, const UNITY_LINE_TYPE lineNumber) { _UF diff = actual - expected; _UF pos_delta = delta; UNITY_SKIP_EXECUTION; if (diff < 0) { diff = 0.0f - diff; } if (pos_delta < 0) { pos_delta = 0.0f - pos_delta; } //This first part of this condition will catch any NaN or Infinite values if ((diff * 0.0f != 0.0f) || (pos_delta < diff)) { UnityTestResultsFailBegin(lineNumber); #ifdef UNITY_FLOAT_VERBOSE UnityPrint(UnityStrExpected); UnityPrintFloat(expected); UnityPrint(UnityStrWas); UnityPrintFloat(actual); #else UnityPrint(UnityStrDelta); #endif UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } } //----------------------------------------------- void UnityAssertFloatIsInf(const _UF actual, const char* msg, const UNITY_LINE_TYPE lineNumber) { UNITY_SKIP_EXECUTION; if ((1.0f / 0.0f) != actual) { UnityTestResultsFailBegin(lineNumber); #ifdef UNITY_FLOAT_VERBOSE UnityPrint(UnityStrExpected); UnityPrint(UnityStrInf); UnityPrint(UnityStrWas); UnityPrintFloat(actual); #else UnityPrint(UnityStrDelta); #endif UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } } //----------------------------------------------- void UnityAssertFloatIsNegInf(const _UF actual, const char* msg, const UNITY_LINE_TYPE lineNumber) { UNITY_SKIP_EXECUTION; if ((-1.0f / 0.0f) != actual) { UnityTestResultsFailBegin(lineNumber); #ifdef UNITY_FLOAT_VERBOSE UnityPrint(UnityStrExpected); UnityPrint(UnityStrNegInf); UnityPrint(UnityStrWas); UnityPrintFloat(actual); #else UnityPrint(UnityStrDelta); #endif UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } } //----------------------------------------------- void UnityAssertFloatIsNaN(const _UF actual, const char* msg, const UNITY_LINE_TYPE lineNumber) { UNITY_SKIP_EXECUTION; if (actual == actual) { UnityTestResultsFailBegin(lineNumber); #ifdef UNITY_FLOAT_VERBOSE UnityPrint(UnityStrExpected); UnityPrint(UnityStrNaN); UnityPrint(UnityStrWas); UnityPrintFloat(actual); #else UnityPrint(UnityStrDelta); #endif UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } } #endif //not UNITY_EXCLUDE_FLOAT //----------------------------------------------- #ifndef UNITY_EXCLUDE_DOUBLE void UnityAssertEqualDoubleArray(const _UD* expected, const _UD* actual, const _UU32 num_elements, const char* msg, const UNITY_LINE_TYPE lineNumber) { _UU32 elements = num_elements; const _UD* ptr_expected = expected; const _UD* ptr_actual = actual; _UD diff, tol; UNITY_SKIP_EXECUTION; if (elements == 0) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrPointless); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } if (UnityCheckArraysForNull((void*)expected, (void*)actual, lineNumber, msg) == 1) return; while (elements--) { diff = *ptr_expected - *ptr_actual; if (diff < 0.0) diff = 0.0 - diff; tol = UNITY_DOUBLE_PRECISION * *ptr_expected; if (tol < 0.0) tol = 0.0 - tol; //This first part of this condition will catch any NaN or Infinite values if ((diff * 0.0f != 0.0f) || (diff > tol)) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrElement); UnityPrintNumberByStyle((num_elements - elements - 1), UNITY_DISPLAY_STYLE_UINT); #ifdef UNITY_DOUBLE_VERBOSE UnityPrint(UnityStrExpected); UnityPrintFloat((float)(*ptr_expected)); UnityPrint(UnityStrWas); UnityPrintFloat((float)(*ptr_actual)); #else UnityPrint(UnityStrDelta); #endif UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } ptr_expected++; ptr_actual++; } } //----------------------------------------------- void UnityAssertDoublesWithin(const _UD delta, const _UD expected, const _UD actual, const char* msg, const UNITY_LINE_TYPE lineNumber) { _UD diff = actual - expected; _UD pos_delta = delta; UNITY_SKIP_EXECUTION; if (diff < 0) { diff = 0.0f - diff; } if (pos_delta < 0) { pos_delta = 0.0f - pos_delta; } //This first part of this condition will catch any NaN or Infinite values if ((diff * 0.0f != 0.0f) || (pos_delta < diff)) { UnityTestResultsFailBegin(lineNumber); #ifdef UNITY_DOUBLE_VERBOSE UnityPrint(UnityStrExpected); UnityPrintFloat((float)expected); UnityPrint(UnityStrWas); UnityPrintFloat((float)actual); #else UnityPrint(UnityStrDelta); #endif UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } } //----------------------------------------------- void UnityAssertDoubleIsInf(const _UD actual, const char* msg, const UNITY_LINE_TYPE lineNumber) { UNITY_SKIP_EXECUTION; if ((1.0 / 0.0) != actual) { UnityTestResultsFailBegin(lineNumber); #ifdef UNITY_DOUBLE_VERBOSE UnityPrint(UnityStrExpected); UnityPrint(UnityStrInf); UnityPrint(UnityStrWas); UnityPrintFloat((float)actual); #else UnityPrint(UnityStrDelta); #endif UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } } //----------------------------------------------- void UnityAssertDoubleIsNegInf(const _UD actual, const char* msg, const UNITY_LINE_TYPE lineNumber) { UNITY_SKIP_EXECUTION; if ((-1.0 / 0.0) != actual) { UnityTestResultsFailBegin(lineNumber); #ifdef UNITY_DOUBLE_VERBOSE UnityPrint(UnityStrExpected); UnityPrint(UnityStrNegInf); UnityPrint(UnityStrWas); UnityPrintFloat((float)actual); #else UnityPrint(UnityStrDelta); #endif UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } } //----------------------------------------------- void UnityAssertDoubleIsNaN(const _UD actual, const char* msg, const UNITY_LINE_TYPE lineNumber) { UNITY_SKIP_EXECUTION; if (actual == actual) { UnityTestResultsFailBegin(lineNumber); #ifdef UNITY_DOUBLE_VERBOSE UnityPrint(UnityStrExpected); UnityPrint(UnityStrNaN); UnityPrint(UnityStrWas); UnityPrintFloat((float)actual); #else UnityPrint(UnityStrDelta); #endif UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } } #endif // not UNITY_EXCLUDE_DOUBLE //----------------------------------------------- void UnityAssertNumbersWithin( const _U_SINT delta, const _U_SINT expected, const _U_SINT actual, const char* msg, const UNITY_LINE_TYPE lineNumber, const UNITY_DISPLAY_STYLE_T style) { UNITY_SKIP_EXECUTION; if ((style & UNITY_DISPLAY_RANGE_INT) == UNITY_DISPLAY_RANGE_INT) { if (actual > expected) Unity.CurrentTestFailed = ((actual - expected) > delta); else Unity.CurrentTestFailed = ((expected - actual) > delta); } else { if ((_U_UINT)actual > (_U_UINT)expected) Unity.CurrentTestFailed = ((_U_UINT)(actual - expected) > (_U_UINT)delta); else Unity.CurrentTestFailed = ((_U_UINT)(expected - actual) > (_U_UINT)delta); } if (Unity.CurrentTestFailed) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrDelta); UnityPrintNumberByStyle(delta, style); UnityPrint(UnityStrExpected); UnityPrintNumberByStyle(expected, style); UnityPrint(UnityStrWas); UnityPrintNumberByStyle(actual, style); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } } //----------------------------------------------- void UnityAssertEqualString(const char* expected, const char* actual, const char* msg, const UNITY_LINE_TYPE lineNumber) { _UU32 i; UNITY_SKIP_EXECUTION; // if both pointers not null compare the strings if (expected && actual) { for (i = 0; expected[i] || actual[i]; i++) { if (expected[i] != actual[i]) { Unity.CurrentTestFailed = 1; break; } } } else { // handle case of one pointers being null (if both null, test should pass) if (expected != actual) { Unity.CurrentTestFailed = 1; } } if (Unity.CurrentTestFailed) { UnityTestResultsFailBegin(lineNumber); UnityPrintExpectedAndActualStrings(expected, actual); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } } //----------------------------------------------- void UnityAssertEqualStringArray( const char** expected, const char** actual, const _UU32 num_elements, const char* msg, const UNITY_LINE_TYPE lineNumber) { _UU32 i, j = 0; UNITY_SKIP_EXECUTION; // if no elements, it's an error if (num_elements == 0) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrPointless); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } if (UnityCheckArraysForNull((void*)expected, (void*)actual, lineNumber, msg) == 1) return; do { // if both pointers not null compare the strings if (expected[j] && actual[j]) { for (i = 0; expected[j][i] || actual[j][i]; i++) { if (expected[j][i] != actual[j][i]) { Unity.CurrentTestFailed = 1; break; } } } else { // handle case of one pointers being null (if both null, test should pass) if (expected[j] != actual[j]) { Unity.CurrentTestFailed = 1; } } if (Unity.CurrentTestFailed) { UnityTestResultsFailBegin(lineNumber); if (num_elements > 1) { UnityPrint(UnityStrElement); UnityPrintNumberByStyle((num_elements - j - 1), UNITY_DISPLAY_STYLE_UINT); } UnityPrintExpectedAndActualStrings((const char*)(expected[j]), (const char*)(actual[j])); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } } while (++j < num_elements); } //----------------------------------------------- void UnityAssertEqualMemory( const void* expected, const void* actual, const _UU32 length, const _UU32 num_elements, const char* msg, const UNITY_LINE_TYPE lineNumber) { unsigned char* ptr_exp = (unsigned char*)expected; unsigned char* ptr_act = (unsigned char*)actual; _UU32 elements = num_elements; _UU32 bytes; UNITY_SKIP_EXECUTION; if ((elements == 0) || (length == 0)) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrPointless); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } if (UnityCheckArraysForNull((void*)expected, (void*)actual, lineNumber, msg) == 1) return; while (elements--) { ///////////////////////////////////// bytes = length; while (bytes--) { if (*ptr_exp != *ptr_act) { UnityTestResultsFailBegin(lineNumber); UnityPrint(UnityStrMemory); if (num_elements > 1) { UnityPrint(UnityStrElement); UnityPrintNumberByStyle((num_elements - elements - 1), UNITY_DISPLAY_STYLE_UINT); } UnityPrint(UnityStrByte); UnityPrintNumberByStyle((length - bytes - 1), UNITY_DISPLAY_STYLE_UINT); UnityPrint(UnityStrExpected); UnityPrintNumberByStyle(*ptr_exp, UNITY_DISPLAY_STYLE_HEX8); UnityPrint(UnityStrWas); UnityPrintNumberByStyle(*ptr_act, UNITY_DISPLAY_STYLE_HEX8); UnityAddMsgIfSpecified(msg); UNITY_FAIL_AND_BAIL; } ptr_exp += 1; ptr_act += 1; } ///////////////////////////////////// } } //----------------------------------------------- // Control Functions //----------------------------------------------- void UnityFail(const char* msg, const UNITY_LINE_TYPE line) { UNITY_SKIP_EXECUTION; UnityTestResultsBegin(Unity.TestFile, line); UnityPrintFail(); if (msg != NULL) { UNITY_OUTPUT_CHAR(':'); if (msg[0] != ' ') { UNITY_OUTPUT_CHAR(' '); } UnityPrint(msg); } UNITY_FAIL_AND_BAIL; } //----------------------------------------------- void UnityIgnore(const char* msg, const UNITY_LINE_TYPE line) { UNITY_SKIP_EXECUTION; UnityTestResultsBegin(Unity.TestFile, line); UnityPrint("IGNORE"); if (msg != NULL) { UNITY_OUTPUT_CHAR(':'); UNITY_OUTPUT_CHAR(' '); UnityPrint(msg); } UNITY_IGNORE_AND_BAIL; } //----------------------------------------------- void setUp(void); void tearDown(void); void UnityDefaultTestRun(UnityTestFunction Func, const char* FuncName, const int FuncLineNum) { Unity.CurrentTestName = FuncName; Unity.CurrentTestLineNumber = FuncLineNum; Unity.NumberOfTests++; if (TEST_PROTECT()) { setUp(); Func(); } if (TEST_PROTECT() && !(Unity.CurrentTestIgnored)) { tearDown(); } UnityConcludeTest(); } //----------------------------------------------- void UnityBegin(void) { Unity.NumberOfTests = 0; Unity.TestFailures = 0; Unity.TestIgnores = 0; Unity.CurrentTestFailed = 0; Unity.CurrentTestIgnored = 0; } //----------------------------------------------- int UnityEnd(void) { UnityPrint("-----------------------"); UNITY_PRINT_EOL; UnityPrintNumber(Unity.NumberOfTests); UnityPrint(" Tests "); UnityPrintNumber(Unity.TestFailures); UnityPrint(" Failures "); UnityPrintNumber(Unity.TestIgnores); UnityPrint(" Ignored"); UNITY_PRINT_EOL; if (Unity.TestFailures == 0U) { UnityPrintOk(); } else { UnityPrintFail(); } UNITY_PRINT_EOL; return Unity.TestFailures; }