#if (defined(_WIN32) || defined(_WIN64)) #define DQN_WIN32_IMPLEMENTATION #include #endif #if defined(__linux__) #define DQN_UNIX_IMPLEMENTATION #define HANDMADE_MATH_NO_SSE #endif #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wfree-nonheap-object" #endif #define DQN_PLATFORM_HEADER #define DQN_IMPLEMENTATION #include "dqn.h" #define HANDMADE_MATH_IMPLEMENTATION #define HANDMADE_MATH_CPP_MODE #include "tests/HandmadeMath.h" #include #include FILE_SCOPE void PrintHeader(const char *const header) { DQN_ASSERT_HARD(header); char buf[1024] = {}; DQN_ASSERT(Dqn_sprintf(buf, "// %s", header) < (i32)DQN_ARRAY_COUNT(buf)); printf("//////////////////////////////////////////////////////////////////\n"); printf("%s\n", buf); printf("//////////////////////////////////////////////////////////////////\n"); } void HandmadeMathVerifyMat4(DqnMat4 dqnMat, hmm_mat4 hmmMat) { f32 *hmmMatf = (f32 *)&hmmMat; f32 *dqnMatf = (f32 *)&dqnMat; const u32 EXPECTED_SIZE = 16; u32 totalSize = DQN_ARRAY_COUNT(dqnMat.e) * DQN_ARRAY_COUNT(dqnMat.e[0]); DQN_ASSERT(totalSize == EXPECTED_SIZE); DQN_ASSERT(totalSize == (DQN_ARRAY_COUNT(hmmMat.Elements) * DQN_ARRAY_COUNT(hmmMat.Elements[0]))); for (u32 i = 0; i < EXPECTED_SIZE; i++) { const f32 EPSILON = 0.001f; f32 diff = hmmMatf[i] - dqnMatf[i]; diff = DQN_ABS(diff); DQN_ASSERT_MSG(diff < EPSILON, "hmmMatf[%d]: %f, dqnMatf[%d]: %f\n", i, hmmMatf[i], i, dqnMatf[i]); } } void HandmadeMathTest() { PrintHeader("DqnMath vs HandmadeMath Test"); // Test Perspective/Projection matrix values if (1) { f32 aspectRatio = 1; DqnMat4 dqnPerspective = DqnMat4_Perspective(90, aspectRatio, 100, 1000); hmm_mat4 hmmPerspective = HMM_Perspective(90, aspectRatio, 100, 1000); HandmadeMathVerifyMat4(dqnPerspective, hmmPerspective); printf("HandmadeMathTest(): Perspective: Completed successfully\n"); } // Test Mat4 translate * scale if (1) { hmm_vec3 hmmVec = HMM_Vec3i(1, 2, 3); DqnV3 dqnVec = DqnV3_3i(1, 2, 3); DqnMat4 dqnTranslate = DqnMat4_Translate3f(dqnVec.x, dqnVec.y, dqnVec.z); hmm_mat4 hmmTranslate = HMM_Translate(hmmVec); HandmadeMathVerifyMat4(dqnTranslate, hmmTranslate); hmm_vec3 hmmAxis = HMM_Vec3(0.5f, 0.2f, 0.7f); DqnV3 dqnAxis = DqnV3_3f(0.5f, 0.2f, 0.7f); f32 rotationInDegrees = 80.0f; DqnMat4 dqnRotate = DqnMat4_Rotate(DQN_DEGREES_TO_RADIANS(rotationInDegrees), dqnAxis.x, dqnAxis.y, dqnAxis.z); hmm_mat4 hmmRotate = HMM_Rotate(rotationInDegrees, hmmAxis); HandmadeMathVerifyMat4(dqnRotate, hmmRotate); dqnVec *= 2; hmmVec *= 2; DqnMat4 dqnScale = DqnMat4_Scale(dqnVec.x, dqnVec.y, dqnVec.z); hmm_mat4 hmmScale = HMM_Scale(hmmVec); HandmadeMathVerifyMat4(dqnScale, hmmScale); DqnMat4 dqnTSMatrix = DqnMat4_Mul(dqnTranslate, dqnScale); hmm_mat4 hmmTSMatrix = HMM_MultiplyMat4(hmmTranslate, hmmScale); HandmadeMathVerifyMat4(dqnTSMatrix, hmmTSMatrix); // Test Mat4 * MulV4 if (1) { DqnV4 dqnV4 = DqnV4_4f(1, 2, 3, 4); hmm_vec4 hmmV4 = HMM_Vec4(1, 2, 3, 4); DqnV4 dqnResult = DqnMat4_MulV4(dqnTSMatrix, dqnV4); hmm_vec4 hmmResult = HMM_MultiplyMat4ByVec4(hmmTSMatrix, hmmV4); DQN_ASSERT(dqnResult.x == hmmResult.X); DQN_ASSERT(dqnResult.y == hmmResult.Y); DQN_ASSERT(dqnResult.z == hmmResult.Z); DQN_ASSERT(dqnResult.w == hmmResult.W); printf("HandmadeMathTest(): Mat4 * MulV4: Completed successfully\n"); } printf("HandmadeMathTest(): Translate/Scale/Rotate Mat4_Mul: Completed successfully\n"); } } void StringsTest() { PrintHeader("Strings Test"); // Char Checks if (1) { DQN_ASSERT(DqnChar_IsAlpha('a') == true); DQN_ASSERT(DqnChar_IsAlpha('A') == true); DQN_ASSERT(DqnChar_IsAlpha('0') == false); DQN_ASSERT(DqnChar_IsAlpha('@') == false); DQN_ASSERT(DqnChar_IsAlpha(' ') == false); DQN_ASSERT(DqnChar_IsAlpha('\n') == false); DQN_ASSERT(DqnChar_IsDigit('1') == true); DQN_ASSERT(DqnChar_IsDigit('n') == false); DQN_ASSERT(DqnChar_IsDigit('N') == false); DQN_ASSERT(DqnChar_IsDigit('*') == false); DQN_ASSERT(DqnChar_IsDigit(' ') == false); DQN_ASSERT(DqnChar_IsDigit('\n') == false); DQN_ASSERT(DqnChar_IsAlphaNum('1') == true); DQN_ASSERT(DqnChar_IsAlphaNum('a') == true); DQN_ASSERT(DqnChar_IsAlphaNum('A') == true); DQN_ASSERT(DqnChar_IsAlphaNum('*') == false); DQN_ASSERT(DqnChar_IsAlphaNum(' ') == false); DQN_ASSERT(DqnChar_IsAlphaNum('\n') == false); DQN_ASSERT(DqnChar_ToLower(L'A') == L'a'); DQN_ASSERT(DqnChar_ToLower(L'a') == L'a'); DQN_ASSERT(DqnChar_ToLower(L' ') == L' '); DQN_ASSERT(DqnChar_ToUpper(L'A') == L'A'); DQN_ASSERT(DqnChar_ToUpper(L'a') == L'A'); DQN_ASSERT(DqnChar_ToUpper(L' ') == L' '); printf("StringsTest(): CharChecks: Completed successfully\n"); } // String Checks if (1) { // strcmp if (1) { const char *const a = "str_a"; // Check simple compares if (1) { DQN_ASSERT(DqnStr_Cmp(a, "str_a") == +0); DQN_ASSERT(DqnStr_Cmp(a, "str_b") == -1); DQN_ASSERT(DqnStr_Cmp("str_b", a) == +1); DQN_ASSERT(DqnStr_Cmp(a, "") == +1); DQN_ASSERT(DqnStr_Cmp("", "") == 0); // NOTE: Check that the string has not been trashed. DQN_ASSERT(DqnStr_Cmp(a, "str_a") == +0); } // Check ops against null if (1) { DQN_ASSERT(DqnStr_Cmp(NULL, NULL) != +0); DQN_ASSERT(DqnStr_Cmp(a, NULL) != +0); DQN_ASSERT(DqnStr_Cmp(NULL, a) != +0); } printf("StringsTest(): strcmp: Completed successfully\n"); } // strlen if (1) { const char *const a = "str_a"; DQN_ASSERT(DqnStr_Len(a) == 5); DQN_ASSERT(DqnStr_Len("") == 0); DQN_ASSERT(DqnStr_Len(" a ") == 6); DQN_ASSERT(DqnStr_Len("a\n") == 2); // NOTE: Check that the string has not been trashed. DQN_ASSERT(DqnStr_Cmp(a, "str_a") == 0); DQN_ASSERT(DqnStr_Len(NULL) == 0); printf("StringsTest(): strlen: Completed successfully\n"); } // strncpy if (1) { if (1) { const char *const a = "str_a"; char b[10] = {}; // Check copy into empty array if (1) { char *result = DqnStr_Copy(b, a, DqnStr_Len(a)); DQN_ASSERT(DqnStr_Cmp(b, "str_a") == 0); DQN_ASSERT(DqnStr_Cmp(a, "str_a") == 0); DQN_ASSERT(DqnStr_Cmp(result, "str_a") == 0); DQN_ASSERT(DqnStr_Len(result) == 5); } // Check copy into array offset, overlap with old results if (1) { char *newResult = DqnStr_Copy(&b[1], a, DqnStr_Len(a)); DQN_ASSERT(DqnStr_Cmp(newResult, "str_a") == 0); DQN_ASSERT(DqnStr_Len(newResult) == 5); DQN_ASSERT(DqnStr_Cmp(a, "str_a") == 0); DQN_ASSERT(DqnStr_Len(a) == 5); DQN_ASSERT(DqnStr_Cmp(b, "sstr_a") == 0); DQN_ASSERT(DqnStr_Len(b) == 6); } } } // StrReverse if (1) { // Basic reverse operations if (1) { char a[] = "aba"; DQN_ASSERT(DqnStr_Reverse(a, DqnStr_Len(a)) == true); DQN_ASSERT(DqnStr_Cmp(a, "aba") == 0); DQN_ASSERT(DqnStr_Reverse(a, 2) == true); DQN_ASSERT(DqnStr_Cmp(a, "baa") == 0); DQN_ASSERT(DqnStr_Reverse(a, DqnStr_Len(a)) == true); DQN_ASSERT(DqnStr_Cmp(a, "aab") == 0); DQN_ASSERT(DqnStr_Reverse(&a[1], 2) == true); DQN_ASSERT(DqnStr_Cmp(a, "aba") == 0); DQN_ASSERT(DqnStr_Reverse(a, 0) == true); DQN_ASSERT(DqnStr_Cmp(a, "aba") == 0); } // Try reverse empty string if (1) { char a[] = ""; DQN_ASSERT(DqnStr_Reverse(a, DqnStr_Len(a)) == true); DQN_ASSERT(DqnStr_Cmp(a, "") == 0); } // Try reverse single char string if (1) { char a[] = "a"; DQN_ASSERT(DqnStr_Reverse(a, DqnStr_Len(a)) == true); DQN_ASSERT(DqnStr_Cmp(a, "a") == 0); DQN_ASSERT(DqnStr_Reverse(a, 0) == true); DQN_ASSERT(DqnStr_Cmp(a, "a") == 0); } printf("StringsTest(): StrReverse: Completed successfully\n"); } // const u64 LARGEST_NUM = (u64)-1; const i64 SMALLEST_NUM = LLONG_MIN; // StrToI64 if (1) { const char *const a = "123"; DQN_ASSERT(Dqn_StrToI64(a, DqnStr_Len(a)) == 123); const char *const b = "-123"; DQN_ASSERT(Dqn_StrToI64(b, DqnStr_Len(b)) == -123); DQN_ASSERT(Dqn_StrToI64(b, 1) == 0); const char *const c = "-0"; DQN_ASSERT(Dqn_StrToI64(c, DqnStr_Len(c)) == 0); const char *const d = "+123"; DQN_ASSERT(Dqn_StrToI64(d, DqnStr_Len(d)) == 123); // TODO(doyle): Unsigned conversion #if 0 char *e = "18446744073709551615"; DQN_ASSERT((u64)(Dqn_StrToI64(e, DqnStr_Len(e))) == LARGEST_NUM); #endif const char *const f = "-9223372036854775808"; DQN_ASSERT(Dqn_StrToI64(f, DqnStr_Len(f)) == SMALLEST_NUM); printf("StringsTest(): StrToI64: Completed successfully\n"); } // i64 to str if (1) { char a[DQN_64BIT_NUM_MAX_STR_SIZE] = {}; Dqn_I64ToStr(+100, a, DQN_ARRAY_COUNT(a)); DQN_ASSERT(DqnStr_Cmp(a, "100") == 0); char b[DQN_64BIT_NUM_MAX_STR_SIZE] = {}; Dqn_I64ToStr(-100, b, DQN_ARRAY_COUNT(b)); DQN_ASSERT(DqnStr_Cmp(b, "-100") == 0); char c[DQN_64BIT_NUM_MAX_STR_SIZE] = {}; Dqn_I64ToStr(0, c, DQN_ARRAY_COUNT(c)); DQN_ASSERT(DqnStr_Cmp(c, "0") == 0); #if 0 char d[DQN_64BIT_NUM_MAX_STR_SIZE] = {}; Dqn_I64ToStr(LARGEST_NUM, d, DQN_ARRAY_COUNT(d)); DQN_ASSERT(DqnStr_Cmp(d, "18446744073709551615") == 0); #endif if (sizeof(size_t) == sizeof(u64)) { char e[DQN_64BIT_NUM_MAX_STR_SIZE] = {}; Dqn_I64ToStr(SMALLEST_NUM, e, DQN_ARRAY_COUNT(e)); DQN_ASSERT_MSG(DqnStr_Cmp(e, "-9223372036854775808") == 0, "e: %s", e); } printf("StringsTest(): I64ToStr: Completed successfully\n"); } } // StrToF32 if (1) { const f32 EPSILON = 0.001f; const char a[] = "-0.66248"; f32 vA = Dqn_StrToF32(a, DQN_ARRAY_COUNT(a)); DQN_ASSERT(DQN_ABS(vA) - DQN_ABS(-0.66248f) < EPSILON); const char b[] = "-0.632053"; f32 vB = Dqn_StrToF32(b, DQN_ARRAY_COUNT(b)); DQN_ASSERT(DQN_ABS(vB) - DQN_ABS(-0.632053f) < EPSILON); const char c[] = "-0.244271"; f32 vC = Dqn_StrToF32(c, DQN_ARRAY_COUNT(c)); DQN_ASSERT(DQN_ABS(vC) - DQN_ABS(-0.244271f) < EPSILON); const char d[] = "-0.511812"; f32 vD = Dqn_StrToF32(d, DQN_ARRAY_COUNT(d)); DQN_ASSERT(DQN_ABS(vD) - DQN_ABS(-0.511812f) < EPSILON); const char e[] = "-0.845392"; f32 vE = Dqn_StrToF32(e, DQN_ARRAY_COUNT(e)); DQN_ASSERT(DQN_ABS(vE) - DQN_ABS(-0.845392f) < EPSILON); const char f[] = "0.127809"; f32 vF = Dqn_StrToF32(f, DQN_ARRAY_COUNT(f)); DQN_ASSERT(DQN_ABS(vF) - DQN_ABS(-0.127809f) < EPSILON); const char g[] = "0.532"; f32 vG = Dqn_StrToF32(g, DQN_ARRAY_COUNT(g)); DQN_ASSERT(DQN_ABS(vG) - DQN_ABS(-0.532f) < EPSILON); const char h[] = "0.923"; f32 vH = Dqn_StrToF32(h, DQN_ARRAY_COUNT(h)); DQN_ASSERT(DQN_ABS(vH) - DQN_ABS(-0.923f) < EPSILON); const char i[] = "0.000"; f32 vI = Dqn_StrToF32(i, DQN_ARRAY_COUNT(i)); DQN_ASSERT(DQN_ABS(vI) - DQN_ABS(-0.000f) < EPSILON); const char j[] = "0.000283538"; f32 vJ = Dqn_StrToF32(j, DQN_ARRAY_COUNT(j)); DQN_ASSERT(DQN_ABS(vJ) - DQN_ABS(-0.000283538f) < EPSILON); const char k[] = "-1.25"; f32 vK = Dqn_StrToF32(k, DQN_ARRAY_COUNT(k)); DQN_ASSERT(DQN_ABS(vK) - DQN_ABS(-1.25f) < EPSILON); const char l[] = "0.286843"; f32 vL = Dqn_StrToF32(l, DQN_ARRAY_COUNT(l)); DQN_ASSERT(DQN_ABS(vL) - DQN_ABS(-0.286843f) < EPSILON); const char m[] = "-0.406"; f32 vM = Dqn_StrToF32(m, DQN_ARRAY_COUNT(m)); DQN_ASSERT(DQN_ABS(vM) - DQN_ABS(-0.406f) < EPSILON); const char n[] = "-0.892"; f32 vN = Dqn_StrToF32(n, DQN_ARRAY_COUNT(n)); DQN_ASSERT(DQN_ABS(vN) - DQN_ABS(-0.892f) < EPSILON); const char o[] = "0.201"; f32 vO = Dqn_StrToF32(o, DQN_ARRAY_COUNT(o)); DQN_ASSERT(DQN_ABS(vO) - DQN_ABS(-0.201f) < EPSILON); const char p[] = "1.25"; f32 vP = Dqn_StrToF32(p, DQN_ARRAY_COUNT(p)); DQN_ASSERT(DQN_ABS(vP) - DQN_ABS(1.25f) < EPSILON); const char q[] = "9.64635e-05"; f32 vQ = Dqn_StrToF32(q, DQN_ARRAY_COUNT(q)); DQN_ASSERT(DQN_ABS(vQ) - DQN_ABS(9.64635e-05) < EPSILON); const char r[] = "9.64635e+05"; f32 vR = Dqn_StrToF32(r, DQN_ARRAY_COUNT(r)); DQN_ASSERT(DQN_ABS(vR) - DQN_ABS(9.64635e+05) < EPSILON); printf("StringsTest(): StrToF32: Completed successfully\n"); } if (1) { if (1) { const char *const a = "Microsoft"; const char *const b = "icro"; i32 lenA = DqnStr_Len(a); i32 lenB = DqnStr_Len(b); DQN_ASSERT(DqnStr_HasSubstring(a, lenA, b, lenB) == true); DQN_ASSERT(DqnStr_HasSubstring(a, lenA, "iro", DqnStr_Len("iro")) == false); DQN_ASSERT(DqnStr_HasSubstring(b, lenB, a, lenA) == false); DQN_ASSERT(DqnStr_HasSubstring("iro", DqnStr_Len("iro"), a, lenA) == false); DQN_ASSERT(DqnStr_HasSubstring("", 0, "iro", 4) == false); DQN_ASSERT(DqnStr_HasSubstring("", 0, "", 0) == false); DQN_ASSERT(DqnStr_HasSubstring(NULL, 0, NULL, 0) == false); } if (1) { const char *const a = "Micro"; const char *const b = "irob"; i32 lenA = DqnStr_Len(a); i32 lenB = DqnStr_Len(b); DQN_ASSERT(DqnStr_HasSubstring(a, lenA, b, lenB) == false); DQN_ASSERT(DqnStr_HasSubstring(b, lenB, a, lenA) == false); } printf("StringsTest(): StrHasSubstring: Completed successfully\n"); } // UCS <-> UTF8 Checks if (1) { // Test ascii characters if (1) { u32 codepoint = '@'; u32 string[1] = {}; u32 bytesUsed = Dqn_UCSToUTF8(&string[0], codepoint); DQN_ASSERT(bytesUsed == 1); DQN_ASSERT(string[0] == '@'); bytesUsed = Dqn_UTF8ToUCS(&string[0], codepoint); DQN_ASSERT(string[0] >= 0 && string[0] < 0x80); DQN_ASSERT(bytesUsed == 1); } // Test 2 byte characters if (1) { u32 codepoint = 0x278; u32 string[1] = {}; u32 bytesUsed = Dqn_UCSToUTF8(&string[0], codepoint); DQN_ASSERT(bytesUsed == 2); DQN_ASSERT(string[0] == 0xC9B8); bytesUsed = Dqn_UTF8ToUCS(&string[0], string[0]); DQN_ASSERT(string[0] == codepoint); DQN_ASSERT(bytesUsed == 2); } // Test 3 byte characters if (1) { u32 codepoint = 0x0A0A; u32 string[1] = {}; u32 bytesUsed = Dqn_UCSToUTF8(&string[0], codepoint); DQN_ASSERT(bytesUsed == 3); DQN_ASSERT(string[0] == 0xE0A88A); bytesUsed = Dqn_UTF8ToUCS(&string[0], string[0]); DQN_ASSERT(string[0] == codepoint); DQN_ASSERT(bytesUsed == 3); } // Test 4 byte characters if (1) { u32 codepoint = 0x10912; u32 string[1] = {}; u32 bytesUsed = Dqn_UCSToUTF8(&string[0], codepoint); DQN_ASSERT(bytesUsed == 4); DQN_ASSERT(string[0] == 0xF090A492); bytesUsed = Dqn_UTF8ToUCS(&string[0], string[0]); DQN_ASSERT(string[0] == codepoint); DQN_ASSERT(bytesUsed == 4); } if (1) { u32 codepoint = 0x10912; u32 bytesUsed = Dqn_UCSToUTF8(NULL, codepoint); DQN_ASSERT(bytesUsed == 0); bytesUsed = Dqn_UTF8ToUCS(NULL, codepoint); DQN_ASSERT(bytesUsed == 0); } printf("StringsTest(): ucs <-> utf8: Completed successfully\n"); } printf("StringsTest(): Completed successfully\n"); } void OtherTest() { PrintHeader("Other Test"); if (1) { #if defined(DQN_UNIX_PLATFORM) f64 startInS = DqnTimer_NowInS(); u32 sleepTimeInS = 1; sleep(sleepTimeInS); f64 endInS = DqnTimer_NowInS(); printf("start: %f, end: %f\n", startInS, endInS); DQN_ASSERT((startInS + sleepTimeInS) <= endInS); #elif defined(DQN_WIN32_PLATFORM) f64 startInMs = DqnTimer_NowInMs(); u32 sleepTimeInMs = 1000; Sleep(sleepTimeInMs); f64 endInMs = DqnTimer_NowInMs(); printf("start: %f, end: %f\n", startInMs, endInMs); DQN_ASSERT((startInMs + sleepTimeInMs) <= endInMs); #endif printf("OtherTest(): TimeNow: Completed successfully\n"); } printf("OtherTest(): Completed successfully\n"); } void RandomTest() { PrintHeader("Random Number Generator Test"); DqnRandPCGState pcg; DqnRnd_PCGInit(&pcg); for (i32 i = 0; i < 1000000; i++) { i32 min = -100; i32 max = 1000000000; i32 result = DqnRnd_PCGRange(&pcg, min, max); DQN_ASSERT(result >= min && result <= max); f32 randF32 = DqnRnd_PCGNextf(&pcg); DQN_ASSERT(randF32 >= 0.0f && randF32 <= 1.0f); } printf("RandomTest(): RndPCG: Completed successfully\n"); printf("RandomTest(): Completed successfully\n"); } void MathTest() { PrintHeader("Math Test"); if (1) { // Lerp if (1) { f32 start = 10; f32 t = 0.5f; f32 end = 20; DQN_ASSERT(DqnMath_Lerp(start, t, end) == 15); } if (1) { f32 start = 10; f32 t = 2.0f; f32 end = 20; DQN_ASSERT(DqnMath_Lerp(start, t, end) == 30); } printf("MathTest(): Lerp: Completed successfully\n"); } if (1) { // sqrtf DQN_ASSERT(DqnMath_Sqrtf(4.0f) == 2.0f); printf("MathTest(): Sqrtf: Completed successfully\n"); } printf("MathTest(): Completed successfully\n"); } void VecTest() { PrintHeader("Math Vector Test"); if (1) { // V2 // V2 Creating if (1) { DqnV2 vec = DqnV2_2f(5.5f, 5.0f); DQN_ASSERT(vec.x == 5.5f && vec.y == 5.0f); DQN_ASSERT(vec.w == 5.5f && vec.h == 5.0f); } // V2 with 2 integers if (1) { DqnV2 vec = DqnV2_2i(3, 5); DQN_ASSERT(vec.x == 3 && vec.y == 5.0f); DQN_ASSERT(vec.w == 3 && vec.h == 5.0f); } // V2 Arithmetic if (1) { DqnV2 vecA = DqnV2_2f(5, 10); DqnV2 vecB = DqnV2_2i(2, 3); DQN_ASSERT(DqnV2_Equals(vecA, vecB) == false); DQN_ASSERT(DqnV2_Equals(vecA, DqnV2_2f(5, 10)) == true); DQN_ASSERT(DqnV2_Equals(vecB, DqnV2_2f(2, 3)) == true); DqnV2 result = DqnV2_Add(vecA, DqnV2_2f(5, 10)); DQN_ASSERT(DqnV2_Equals(result, DqnV2_2f(10, 20)) == true); result = DqnV2_Sub(result, DqnV2_2f(5, 10)); DQN_ASSERT(DqnV2_Equals(result, DqnV2_2f(5, 10)) == true); result = DqnV2_Scalef(result, 5); DQN_ASSERT(DqnV2_Equals(result, DqnV2_2f(25, 50)) == true); result = DqnV2_Hadamard(result, DqnV2_2f(10, 0.5f)); DQN_ASSERT(DqnV2_Equals(result, DqnV2_2f(250, 25)) == true); f32 dotResult = DqnV2_Dot(DqnV2_2f(5, 10), DqnV2_2f(3, 4)); DQN_ASSERT(dotResult == 55); } // Test operator overloading if (1) { DqnV2 vecA = DqnV2_2f(5, 10); DqnV2 vecB = DqnV2_2i(2, 3); DQN_ASSERT((vecA == vecB) == false); DQN_ASSERT((vecA == DqnV2_2f(5, 10)) == true); DQN_ASSERT((vecB == DqnV2_2f(2, 3)) == true); DqnV2 result = vecA + DqnV2_2f(5, 10); DQN_ASSERT((result == DqnV2_2f(10, 20)) == true); result -= DqnV2_2f(5, 10); DQN_ASSERT((result == DqnV2_2f(5, 10)) == true); result *= 5; DQN_ASSERT((result == DqnV2_2f(25, 50)) == true); result = result * DqnV2_2f(10, 0.5f); DQN_ASSERT((result == DqnV2_2f(250, 25)) == true); result += DqnV2_2f(1, 1); DQN_ASSERT((result == DqnV2_2f(251, 26)) == true); result = result - DqnV2_2f(1, 1); DQN_ASSERT((result == DqnV2_2f(250, 25)) == true); } // V2 Properties if (1) { const f32 EPSILON = 0.001f; DqnV2 a = DqnV2_2f(0, 0); DqnV2 b = DqnV2_2f(3, 4); f32 lengthSq = DqnV2_LengthSquared(a, b); DQN_ASSERT(lengthSq == 25); f32 length = DqnV2_Length(a, b); DQN_ASSERT(length == 5); DqnV2 normalised = DqnV2_Normalise(b); f32 normX = b.x / 5.0f; f32 normY = b.y / 5.0f; f32 diffNormX = normalised.x - normX; f32 diffNormY = normalised.y - normY; DQN_ASSERT_MSG(diffNormX < EPSILON, "normalised.x: %f, normX: %f\n", normalised.x, normX); DQN_ASSERT_MSG(diffNormY < EPSILON, "normalised.y: %f, normY: %f\n", normalised.y, normY); DqnV2 c = DqnV2_2f(3.5f, 8.0f); DQN_ASSERT(DqnV2_Overlaps(b, c) == true); DQN_ASSERT(DqnV2_Overlaps(b, a) == false); DqnV2 d = DqnV2_Perpendicular(c); DQN_ASSERT(DqnV2_Dot(c, d) == 0); } if (1) { // constrain_to_ratio DqnV2 ratio = DqnV2_2f(16, 9); DqnV2 dim = DqnV2_2f(2000, 1080); DqnV2 result = DqnV2_ConstrainToRatio(dim, ratio); DQN_ASSERT(result.w == 1920 && result.h == 1080); } printf("VecTest(): Vec2: Completed successfully\n"); } if (1) { // V3 // V3i Creating if (1) { DqnV3 vec = DqnV3_3f(5.5f, 5.0f, 5.875f); DQN_ASSERT(vec.x == 5.5f && vec.y == 5.0f && vec.z == 5.875f); DQN_ASSERT(vec.r == 5.5f && vec.g == 5.0f && vec.b == 5.875f); } // V3i Creating if (1) { DqnV3 vec = DqnV3_3i(3, 4, 5); DQN_ASSERT(vec.x == 3 && vec.y == 4 && vec.z == 5); DQN_ASSERT(vec.r == 3 && vec.g == 4 && vec.b == 5); } // V3 Arithmetic if (1) { DqnV3 vecA = DqnV3_3f(5, 10, 15); DqnV3 vecB = DqnV3_3f(2, 3, 6); DQN_ASSERT(DqnV3_Equals(vecA, vecB) == false); DQN_ASSERT(DqnV3_Equals(vecA, DqnV3_3f(5, 10, 15)) == true); DQN_ASSERT(DqnV3_Equals(vecB, DqnV3_3f(2, 3, 6)) == true); DqnV3 result = DqnV3_Add(vecA, DqnV3_3f(5, 10, 15)); DQN_ASSERT(DqnV3_Equals(result, DqnV3_3f(10, 20, 30)) == true); result = DqnV3_Sub(result, DqnV3_3f(5, 10, 15)); DQN_ASSERT(DqnV3_Equals(result, DqnV3_3f(5, 10, 15)) == true); result = DqnV3_Scalef(result, 5); DQN_ASSERT(DqnV3_Equals(result, DqnV3_3f(25, 50, 75)) == true); result = DqnV3_Hadamard(result, DqnV3_3f(10.0f, 0.5f, 10.0f)); DQN_ASSERT(DqnV3_Equals(result, DqnV3_3f(250, 25, 750)) == true); f32 dotResult = DqnV3_Dot(DqnV3_3f(5, 10, 2), DqnV3_3f(3, 4, 6)); DQN_ASSERT(dotResult == 67); DqnV3 cross = DqnV3_Cross(vecA, vecB); DQN_ASSERT(DqnV3_Equals(cross, DqnV3_3f(15, 0, -5)) == true); } if (1) { DqnV3 vecA = DqnV3_3f(5, 10, 15); DqnV3 vecB = DqnV3_3f(2, 3, 6); DQN_ASSERT((vecA == vecB) == false); DQN_ASSERT((vecA == DqnV3_3f(5, 10, 15)) == true); DQN_ASSERT((vecB == DqnV3_3f(2, 3, 6)) == true); DqnV3 result = vecA + DqnV3_3f(5, 10, 15); DQN_ASSERT((result == DqnV3_3f(10, 20, 30)) == true); result -= DqnV3_3f(5, 10, 15); DQN_ASSERT((result == DqnV3_3f(5, 10, 15)) == true); result = result * 5; DQN_ASSERT((result == DqnV3_3f(25, 50, 75)) == true); result *= DqnV3_3f(10.0f, 0.5f, 10.0f); DQN_ASSERT((result == DqnV3_3f(250, 25, 750)) == true); result = result - DqnV3_3f(1, 1, 1); DQN_ASSERT((result == DqnV3_3f(249, 24, 749)) == true); result += DqnV3_3f(1, 1, 1); DQN_ASSERT((result == DqnV3_3f(250, 25, 750)) == true); } printf("VecTest(): Vec3: Completed successfully\n"); } if (1) { // V4 // V4 Creating if (1) { DqnV4 vec = DqnV4_4f(5.5f, 5.0f, 5.875f, 5.928f); DQN_ASSERT(vec.x == 5.5f && vec.y == 5.0f && vec.z == 5.875f && vec.w == 5.928f); DQN_ASSERT(vec.r == 5.5f && vec.g == 5.0f && vec.b == 5.875f && vec.a == 5.928f); } // V4i Creating if (1) { DqnV4 vec = DqnV4_4i(3, 4, 5, 6); DQN_ASSERT(vec.x == 3 && vec.y == 4 && vec.z == 5 && vec.w == 6); DQN_ASSERT(vec.r == 3 && vec.g == 4 && vec.b == 5 && vec.a == 6); } // V4 Arithmetic if (1) { DqnV4 vecA = DqnV4_4f(5, 10, 15, 20); DqnV4 vecB = DqnV4_4i(2, 3, 6, 8); DQN_ASSERT(DqnV4_Equals(vecA, vecB) == false); DQN_ASSERT(DqnV4_Equals(vecA, DqnV4_4f(5, 10, 15, 20)) == true); DQN_ASSERT(DqnV4_Equals(vecB, DqnV4_4f(2, 3, 6, 8)) == true); DqnV4 result = DqnV4_Add(vecA, DqnV4_4f(5, 10, 15, 20)); DQN_ASSERT(DqnV4_Equals(result, DqnV4_4f(10, 20, 30, 40)) == true); result = DqnV4_Sub(result, DqnV4_4f(5, 10, 15, 20)); DQN_ASSERT(DqnV4_Equals(result, DqnV4_4f(5, 10, 15, 20)) == true); result = DqnV4_Scalef(result, 5); DQN_ASSERT(DqnV4_Equals(result, DqnV4_4f(25, 50, 75, 100)) == true); result = DqnV4_Hadamard(result, DqnV4_4f(10, 0.5f, 10, 0.25f)); DQN_ASSERT(DqnV4_Equals(result, DqnV4_4f(250, 25, 750, 25)) == true); f32 dotResult = DqnV4_Dot(DqnV4_4f(5, 10, 2, 8), DqnV4_4f(3, 4, 6, 5)); DQN_ASSERT(dotResult == 107); } if (1) { DqnV4 vecA = DqnV4_4f(5, 10, 15, 20); DqnV4 vecB = DqnV4_4i(2, 3, 6, 8); DQN_ASSERT((vecA == vecB) == false); DQN_ASSERT((vecA == DqnV4_4f(5, 10, 15, 20)) == true); DQN_ASSERT((vecB == DqnV4_4f(2, 3, 6, 8)) == true); DqnV4 result = vecA + DqnV4_4f(5, 10, 15, 20); DQN_ASSERT((result == DqnV4_4f(10, 20, 30, 40)) == true); result = result - DqnV4_4f(5, 10, 15, 20); DQN_ASSERT((result == DqnV4_4f(5, 10, 15, 20)) == true); result = result * 5; DQN_ASSERT((result == DqnV4_4f(25, 50, 75, 100)) == true); result *= DqnV4_4f(10, 0.5f, 10, 0.25f); DQN_ASSERT((result == DqnV4_4f(250, 25, 750, 25)) == true); result += DqnV4_4f(1, 1, 1, 1); DQN_ASSERT((result == DqnV4_4f(251, 26, 751, 26)) == true); result -= DqnV4_4f(1, 1, 1, 1); DQN_ASSERT((result == DqnV4_4f(250, 25, 750, 25)) == true); } printf("VecTest(): Vec4: Completed successfully\n"); } // Rect if (1) { // Test rect init functions if (1) { DqnRect rect4f = DqnRect_4f(1.1f, 2.2f, 3.3f, 4.4f); DqnRect rect4i = DqnRect_4i(1, 2, 3, 4); DQN_ASSERT(rect4i.min.x == 1 && rect4i.min.y == 2); DQN_ASSERT(rect4i.max.x == 3 && rect4i.max.y == 4); DQN_ASSERT(rect4f.min.x == 1.1f && rect4f.min.y == 2.2f); DQN_ASSERT(rect4f.max.x == 3.3f && rect4f.max.y == 4.4f); DqnRect rect = DqnRect_Init(DqnV2_2f(-10, -10), DqnV2_2f(20, 20)); DQN_ASSERT(DqnV2_Equals(rect.min, DqnV2_2f(-10, -10))); DQN_ASSERT(DqnV2_Equals(rect.max, DqnV2_2f(10, 10))); } // Test rect get size function if (1) { // Test float rect if (1) { DqnRect rect = DqnRect_Init(DqnV2_2f(-10, -10), DqnV2_2f(20, 20)); f32 width, height; DqnRect_GetSize2f(rect, &width, &height); DQN_ASSERT(width == 20); DQN_ASSERT(height == 20); DqnV2 dim = DqnRect_GetSizeV2(rect); DQN_ASSERT(DqnV2_Equals(dim, DqnV2_2f(20, 20))); } // Test rect with float values and GetSize as 2 integers if (1) { DqnRect rect = DqnRect_Init(DqnV2_2f(-10.5f, -10.5f), DqnV2_2f(20.5f, 20.5f)); i32 width, height; DqnRect_GetSize2i(rect, &width, &height); DQN_ASSERT(width == 20); DQN_ASSERT(height == 20); } } // Test rect get centre DqnRect rect = DqnRect_Init(DqnV2_2f(-10, -10), DqnV2_2f(20, 20)); DqnV2 rectCenter = DqnRect_GetCentre(rect); DQN_ASSERT(DqnV2_Equals(rectCenter, DqnV2_2f(0, 0))); // Test clipping rect get centre DqnRect clipRect = DqnRect_4i(-15, -15, 10, 10); DqnRect clipResult = DqnRect_ClipRect(rect, clipRect); DQN_ASSERT(clipResult.min.x == -10 && clipResult.min.y == -10); DQN_ASSERT(clipResult.max.x == 10 && clipResult.max.y == 10); // Test shifting rect if (1) { DqnRect shiftedRect = DqnRect_Move(rect, DqnV2_2f(10, 0)); DQN_ASSERT(DqnV2_Equals(shiftedRect.min, DqnV2_2f(0, -10))); DQN_ASSERT(DqnV2_Equals(shiftedRect.max, DqnV2_2f(20, 10))); // Ensure dimensions have remained the same if (1) { f32 width, height; DqnRect_GetSize2f(shiftedRect, &width, &height); DQN_ASSERT(width == 20); DQN_ASSERT(height == 20); DqnV2 dim = DqnRect_GetSizeV2(shiftedRect); DQN_ASSERT(DqnV2_Equals(dim, DqnV2_2f(20, 20))); } // Test rect contains p if (1) { DqnV2 inP = DqnV2_2f(5, 5); DqnV2 outP = DqnV2_2f(100, 100); DQN_ASSERT(DqnRect_ContainsP(shiftedRect, inP)); DQN_ASSERT(!DqnRect_ContainsP(shiftedRect, outP)); } } printf("VecTest(): Rect: Completed successfully\n"); } printf("VecTest(): Completed successfully\n"); } void ArrayTestMemAPIInternal(DqnArray *array, DqnMemAPI memAPI) { PrintHeader("Array with Default Mem API Test"); if (1) { DQN_ASSERT(DqnArray_Init(array, 1, memAPI)); DQN_ASSERT(array->capacity == 1); DQN_ASSERT(array->count == 0); // Test basic insert if (1) { DqnV2 va = DqnV2_2f(5, 10); DQN_ASSERT(DqnArray_Push(array, va)); DqnV2 vb = array->data[0]; DQN_ASSERT(DqnV2_Equals(va, vb)); DQN_ASSERT(array->capacity == 1); DQN_ASSERT(array->count == 1); } // Test array resizing and freeing if (1) { DqnV2 va = DqnV2_2f(10, 15); DQN_ASSERT(DqnArray_Push(array, va)); DqnV2 vb = array->data[0]; DQN_ASSERT(DqnV2_Equals(va, vb) == false); vb = array->data[1]; DQN_ASSERT(DqnV2_Equals(va, vb) == true); DQN_ASSERT(array->capacity == 2); DQN_ASSERT(array->count == 2); DQN_ASSERT(DqnArray_Push(array, va)); DQN_ASSERT(array->capacity == 3); DQN_ASSERT(array->count == 3); DQN_ASSERT(DqnArray_Push(array, va)); DQN_ASSERT(array->capacity == 4); DQN_ASSERT(array->count == 4); DQN_ASSERT(DqnArray_Push(array, va)); DQN_ASSERT(array->capacity == 5); DQN_ASSERT(array->count == 5); DQN_ASSERT(DqnArray_Push(array, va)); DQN_ASSERT(array->capacity == 6); DQN_ASSERT(array->count == 6); DQN_ASSERT(DqnArray_Push(array, va)); DQN_ASSERT(array->capacity == 7); DQN_ASSERT(array->count == 7); DQN_ASSERT(DqnArray_Push(array, va)); DQN_ASSERT(array->capacity == 8); DQN_ASSERT(array->count == 8); DQN_ASSERT(DqnArray_Push(array, va)); DQN_ASSERT(array->capacity == 9); DQN_ASSERT(array->count == 9); DQN_ASSERT(DqnArray_Push(array, va)); DQN_ASSERT(array->capacity == 10); DQN_ASSERT(array->count == 10); DQN_ASSERT(DqnArray_Push(array, va)); DQN_ASSERT(array->capacity == 12); DQN_ASSERT(array->count == 11); DqnV2 vc = DqnV2_2f(90, 100); DQN_ASSERT(DqnArray_Push(array, vc)); DQN_ASSERT(array->capacity == 12); DQN_ASSERT(array->count == 12); DQN_ASSERT(DqnV2_Equals(vc, array->data[11])); } } DQN_ASSERT(DqnArray_Free(array)); if (1) { DQN_ASSERT(DqnArray_Init(array, 1, memAPI)); DQN_ASSERT(array->capacity == 1); DQN_ASSERT(array->count == 0); } DQN_ASSERT(DqnArray_Free(array)); if (1) { DqnV2 a = DqnV2_2f(1, 2); DqnV2 b = DqnV2_2f(3, 4); DqnV2 c = DqnV2_2f(5, 6); DqnV2 d = DqnV2_2f(7, 8); DQN_ASSERT(DqnArray_Init(array, 16, memAPI)); DQN_ASSERT(DqnArray_Remove(array, 0) == false); DQN_ASSERT(array->capacity == 16); DQN_ASSERT(array->count == 0); DQN_ASSERT(DqnArray_Clear(array)); DQN_ASSERT(array->capacity == 16); DQN_ASSERT(array->count == 0); DQN_ASSERT(DqnArray_Push(array, a)); DQN_ASSERT(DqnArray_Push(array, b)); DQN_ASSERT(DqnArray_Push(array, c)); DQN_ASSERT(DqnArray_Push(array, d)); DQN_ASSERT(array->capacity == 16); DQN_ASSERT(array->count == 4); DQN_ASSERT(DqnArray_Remove(array, 0)); DQN_ASSERT(DqnV2_Equals(array->data[0], d)); DQN_ASSERT(DqnV2_Equals(array->data[1], b)); DQN_ASSERT(DqnV2_Equals(array->data[2], c)); DQN_ASSERT(array->capacity == 16); DQN_ASSERT(array->count == 3); DQN_ASSERT(DqnArray_Remove(array, 2)); DQN_ASSERT(DqnV2_Equals(array->data[0], d)); DQN_ASSERT(DqnV2_Equals(array->data[1], b)); DQN_ASSERT(array->capacity == 16); DQN_ASSERT(array->count == 2); DQN_ASSERT(DqnArray_Remove(array, 100) == false); DQN_ASSERT(DqnV2_Equals(array->data[0], d)); DQN_ASSERT(DqnV2_Equals(array->data[1], b)); DQN_ASSERT(array->capacity == 16); DQN_ASSERT(array->count == 2); DQN_ASSERT(DqnArray_Clear(array)); DQN_ASSERT(array->capacity == 16); DQN_ASSERT(array->count == 0); } DQN_ASSERT(DqnArray_Free(array)); if (1) { DqnV2 a = DqnV2_2f(1, 2); DqnV2 b = DqnV2_2f(3, 4); DqnV2 c = DqnV2_2f(5, 6); DqnV2 d = DqnV2_2f(7, 8); DQN_ASSERT(DqnArray_Init(array, 16, memAPI)); DQN_ASSERT(DqnArray_Push(array, a)); DQN_ASSERT(DqnArray_Push(array, b)); DQN_ASSERT(DqnArray_Push(array, c)); DQN_ASSERT(DqnArray_Push(array, d)); DQN_ASSERT(array->capacity == 16); DQN_ASSERT(array->count == 4); DqnArray_RemoveStable(array, 0); DQN_ASSERT(DqnV2_Equals(array->data[0], b)); DQN_ASSERT(DqnV2_Equals(array->data[1], c)); DQN_ASSERT(DqnV2_Equals(array->data[2], d)); DQN_ASSERT(array->capacity == 16); DQN_ASSERT(array->count == 3); DqnArray_RemoveStable(array, 1); DQN_ASSERT(DqnV2_Equals(array->data[0], b)); DQN_ASSERT(DqnV2_Equals(array->data[1], d)); DQN_ASSERT(array->capacity == 16); DQN_ASSERT(array->count == 2); DqnArray_RemoveStable(array, 1); DQN_ASSERT(DqnV2_Equals(array->data[0], b)); DQN_ASSERT(array->capacity == 16); DQN_ASSERT(array->count == 1); } DQN_ASSERT(DqnArray_Free(array)); printf("ArrayTestMemAPIInternal(): Completed successfully\n"); } void ArrayTest() { PrintHeader("Array Test"); DqnArray array = {}; ArrayTestMemAPIInternal(&array, DqnMemAPI_DefaultUseCalloc()); printf("ArrayTest(): Completed successfully\n"); } void MemStackTest() { PrintHeader("MemStack Test"); // Test over allocation, alignments, temp regions if (1) { size_t allocSize = DQN_KILOBYTE(1); DqnMemStack stack = {}; const u32 ALIGNMENT = 4; DqnMemStack_Init(&stack, allocSize, false, ALIGNMENT); DQN_ASSERT(stack.block && stack.block->memory); DQN_ASSERT(stack.block->size == allocSize); DQN_ASSERT(stack.block->used == 0); DQN_ASSERT(stack.byteAlign == ALIGNMENT); // Alocate A size_t sizeA = (size_t)(allocSize * 0.5f); void *resultA = DqnMemStack_Push(&stack, sizeA); u64 resultAddrA = *((u64 *)resultA); DQN_ASSERT(resultAddrA % ALIGNMENT == 0); DQN_ASSERT(stack.block && stack.block->memory); DQN_ASSERT(stack.block->size == allocSize); DQN_ASSERT(stack.block->used >= sizeA + 0 && stack.block->used <= sizeA + 3); DQN_ASSERT(stack.byteAlign == ALIGNMENT); DQN_ASSERT(resultA); u8 *ptrA = (u8 *)resultA; for (u32 i = 0; i < sizeA; i++) ptrA[i] = 1; DqnMemStackBlock *blockA = stack.block; // Alocate B size_t sizeB = (size_t)(allocSize * 2.0f); void *resultB = DqnMemStack_Push(&stack, sizeB); u64 resultAddrB = *((u64 *)resultB); DQN_ASSERT(resultAddrB % ALIGNMENT == 0); DQN_ASSERT(stack.block && stack.block->memory); DQN_ASSERT(stack.block->size == DQN_KILOBYTE(2)); // Since we alignment the pointers we return they can be within 0-3 // bytes of what we expect and since this is in a new block as well used // will reflect just this allocation. DQN_ASSERT(stack.block->used >= sizeB + 0 && stack.block->used <= sizeB + 3); DQN_ASSERT(resultB); u8 *ptrB = (u8 *)resultB; for (u32 i = 0; i < sizeB; i++) ptrB[i] = 2; // Check that a new block was created since there wasn't enough space DQN_ASSERT(stack.block->prevBlock == blockA); DQN_ASSERT(stack.block != blockA); DQN_ASSERT(stack.byteAlign == ALIGNMENT); DQN_ASSERT(blockA->used == sizeA); DqnMemStackBlock *blockB = stack.block; // Check temp regions work DqnMemStackTempRegion tempBuffer; DQN_ASSERT(DqnMemStackTempRegion_Begin(&tempBuffer, &stack)); size_t sizeC = 1024 + 1; void *resultC = DqnMemStack_Push(tempBuffer.stack, sizeC); u64 resultAddrC = *((u64 *)resultC); DQN_ASSERT(resultAddrC % ALIGNMENT == 0); DQN_ASSERT(stack.block != blockB && stack.block != blockA); DQN_ASSERT(stack.block->used >= sizeC + 0 && stack.block->used <= sizeC + 3); DQN_ASSERT(stack.tempRegionCount == 1); DQN_ASSERT(stack.byteAlign == ALIGNMENT); // NOTE: Allocation should be aligned to 4 byte boundary DQN_ASSERT(tempBuffer.stack->block->size == 2048); u8 *ptrC = (u8 *)resultC; for (u32 i = 0; i < sizeC; i++) ptrC[i] = 3; // Check that a new block was created since there wasn't enough space DQN_ASSERT(stack.block->prevBlock == blockB); DQN_ASSERT(stack.block != blockB); DQN_ASSERT(stack.byteAlign == ALIGNMENT); for (u32 i = 0; i < sizeA; i++) DQN_ASSERT(ptrA[i] == 1); for (u32 i = 0; i < sizeB; i++) DQN_ASSERT(ptrB[i] == 2); for (u32 i = 0; i < sizeC; i++) DQN_ASSERT(ptrC[i] == 3); // End temp region which should revert back to 2 linked stacks, A and B DqnMemStackTempRegion_End(tempBuffer); DQN_ASSERT(stack.block && stack.block->memory); DQN_ASSERT(stack.block->size == sizeB); DQN_ASSERT(stack.block->used >= sizeB + 0 && stack.block->used <= sizeB + 3); DQN_ASSERT(stack.tempRegionCount == 0); DQN_ASSERT(resultB); DQN_ASSERT(stack.block->prevBlock == blockA); DQN_ASSERT(stack.block != blockA); DQN_ASSERT(blockA->used == sizeA); DQN_ASSERT(stack.byteAlign == ALIGNMENT); // Release the last linked stack from the push stack DqnMemStack_FreeLastBlock(&stack); // Which should return back to the 1st allocation DQN_ASSERT(stack.block == blockA); DQN_ASSERT(stack.block->memory); DQN_ASSERT(stack.block->size == allocSize); DQN_ASSERT(stack.block->used == sizeA); DQN_ASSERT(stack.byteAlign == ALIGNMENT); DQN_ASSERT(!stack.block->prevBlock); // Free once more to release stack A memory DqnMemStack_FreeLastBlock(&stack); DQN_ASSERT(!stack.block); DQN_ASSERT(stack.byteAlign == ALIGNMENT); DQN_ASSERT(stack.tempRegionCount == 0); } // Test stack with fixed memory does not allocate more if (1) { u8 memory[DQN_KILOBYTE(1)] = {}; DqnMemStack stack = {}; const u32 ALIGNMENT = 4; DqnMemStack_InitWithFixedMem(&stack, memory, DQN_ARRAY_COUNT(memory), ALIGNMENT); DQN_ASSERT(stack.block && stack.block->memory); DQN_ASSERT(stack.block->size == DQN_ARRAY_COUNT(memory) - sizeof(DqnMemStackBlock)); DQN_ASSERT(stack.block->used == 0); DQN_ASSERT(stack.byteAlign == ALIGNMENT); // Allocation larger than stack mem size should fail DQN_ASSERT(!DqnMemStack_Push(&stack, DQN_ARRAY_COUNT(memory) * 2)); // Check free does nothing DqnMemStack_Free(&stack); DqnMemStack_FreeLastBlock(&stack); DQN_ASSERT(stack.block && stack.block->memory); DQN_ASSERT(stack.block->size == DQN_ARRAY_COUNT(memory) - sizeof(DqnMemStackBlock)); DQN_ASSERT(stack.block->used == 0); DQN_ASSERT(stack.byteAlign == ALIGNMENT); } // Test stack with fixed size, allocates once from platform but does not // grow further if (1) { size_t allocSize = DQN_KILOBYTE(1); DqnMemStack stack = {}; const u32 ALIGNMENT = 4; DqnMemStack_InitWithFixedSize(&stack, allocSize, false, ALIGNMENT); DQN_ASSERT(stack.block && stack.block->memory); DQN_ASSERT(stack.block->size == allocSize); DQN_ASSERT(stack.block->used == 0); DQN_ASSERT(stack.byteAlign == ALIGNMENT); void *result = DqnMemStack_Push(&stack, (size_t)(0.5f * allocSize)); DQN_ASSERT(result); // Allocating more should fail DQN_ASSERT(!DqnMemStack_Push(&stack, allocSize)); // Freeing should work DqnMemStack_Free(&stack); DQN_ASSERT(!stack.block); } // Test freeing/clear block and alignment if (1) { size_t firstBlockSize = DQN_KILOBYTE(1); DqnMemStack stack = {}; const u32 ALIGNMENT = 16; DqnMemStack_Init(&stack, firstBlockSize, false, ALIGNMENT); DqnMemStackBlock *firstBlock = stack.block; u8 *first = NULL; { u32 allocate40Bytes = 40; u8 *data = (u8 *)DqnMemStack_Push(&stack, allocate40Bytes); // Test that the allocation got aligned to 16 byte boundary DQN_ASSERT(data); DQN_ASSERT(stack.block->size == firstBlockSize); DQN_ASSERT((size_t)data % ALIGNMENT == 0); for (u32 i = 0; i < allocate40Bytes; i++) data[i] = 'a'; // Clear the block, but don't zero it out DqnMemStack_ClearCurrBlock(&stack, false); for (u32 i = 0; i < allocate40Bytes; i++) DQN_ASSERT(data[i] == 'a'); // Test clear reverted the use pointer DQN_ASSERT(stack.block->used == 0); DQN_ASSERT(stack.block->size == firstBlockSize); // Reallocate the data data = (u8 *)DqnMemStack_Push(&stack, firstBlockSize); DQN_ASSERT(stack.block->size == firstBlockSize); DQN_ASSERT((size_t)data % ALIGNMENT == 0); // Fill with 'b's for (u32 i = 0; i < firstBlockSize; i++) data[i] = 'b'; // Clear block and zero it out DqnMemStack_ClearCurrBlock(&stack, true); for (u32 i = 0; i < firstBlockSize; i++) DQN_ASSERT(data[i] == 0); // General Check stack struct contains the values we expect from // initialisation DQN_ASSERT(stack.flags == 0); DQN_ASSERT(stack.tempRegionCount == 0); DQN_ASSERT(stack.byteAlign == ALIGNMENT); DQN_ASSERT(stack.block->size == firstBlockSize); // Write out data to current block data = (u8 *)DqnMemStack_Push(&stack, firstBlockSize); for (u32 i = 0; i < firstBlockSize; i++) data[i] = 'c'; first = data; } // Force it to allocate three new blocks and write out data to each size_t secondBlockSize = DQN_KILOBYTE(2); u8 *second = (u8 *)DqnMemStack_Push(&stack, secondBlockSize); DqnMemStackBlock *secondBlock = stack.block; for (u32 i = 0; i < secondBlockSize; i++) second[i] = 'd'; size_t thirdBlockSize = DQN_KILOBYTE(3); u8 *third = (u8 *)DqnMemStack_Push(&stack, thirdBlockSize); DqnMemStackBlock *thirdBlock = stack.block; for (u32 i = 0; i < thirdBlockSize; i++) third[i] = 'e'; size_t fourthBlockSize = DQN_KILOBYTE(4); u8 *fourth = (u8 *)DqnMemStack_Push(&stack, fourthBlockSize); DqnMemStackBlock *fourthBlock = stack.block; for (u32 i = 0; i < fourthBlockSize; i++) fourth[i] = 'f'; DQN_ASSERT((firstBlock != secondBlock) && (secondBlock != thirdBlock) && (thirdBlock != fourthBlock)); DQN_ASSERT(firstBlock->prevBlock == NULL); DQN_ASSERT(secondBlock->prevBlock == firstBlock); DQN_ASSERT(thirdBlock->prevBlock == secondBlock); DQN_ASSERT(fourthBlock->prevBlock == thirdBlock); // NOTE: Making blocks manually is not really recommended .. // Try and free an invalid block by mocking a fake block u8 fakeBlockMem[DQN_KILOBYTE(3)] = {}; DqnMemStackBlock fakeBlock = {}; fakeBlock.memory = fakeBlockMem; fakeBlock.size = DQN_ARRAY_COUNT(fakeBlockMem); fakeBlock.used = 0; DQN_ASSERT(!DqnMemStack_FreeMemBlock(&stack, &fakeBlock)); // Ensure that the actual blocks are still valid and freeing did nothing DQN_ASSERT(firstBlock->size == firstBlockSize); DQN_ASSERT(secondBlock->size == secondBlockSize); DQN_ASSERT(thirdBlock->size == thirdBlockSize); DQN_ASSERT(fourthBlock->size == fourthBlockSize); DQN_ASSERT(firstBlock->used == firstBlockSize); DQN_ASSERT(secondBlock->used == secondBlockSize); DQN_ASSERT(thirdBlock->used == thirdBlockSize); DQN_ASSERT(fourthBlock->used == fourthBlockSize); DQN_ASSERT((firstBlock != secondBlock) && (secondBlock != thirdBlock) && (thirdBlock != fourthBlock)); DQN_ASSERT(firstBlock->prevBlock == NULL); DQN_ASSERT(secondBlock->prevBlock == firstBlock); DQN_ASSERT(thirdBlock->prevBlock == secondBlock); DQN_ASSERT(fourthBlock->prevBlock == thirdBlock); for (u32 i = 0; i < firstBlockSize; i++) DQN_ASSERT(first[i] == 'c'); for (u32 i = 0; i < secondBlockSize; i++) DQN_ASSERT(second[i] == 'd'); for (u32 i = 0; i < thirdBlockSize; i++) DQN_ASSERT(third[i] == 'e'); for (u32 i = 0; i < fourthBlockSize; i++) DQN_ASSERT(fourth[i] == 'f'); // Free the first block DqnMemStack_FreeMemBlock(&stack, firstBlock); // Revalidate state DQN_ASSERT(secondBlock->size == secondBlockSize); DQN_ASSERT(thirdBlock->size == thirdBlockSize); DQN_ASSERT(fourthBlock->size == fourthBlockSize); DQN_ASSERT(secondBlock->used == secondBlockSize); DQN_ASSERT(thirdBlock->used == thirdBlockSize); DQN_ASSERT(fourthBlock->used == fourthBlockSize); DQN_ASSERT((secondBlock != thirdBlock) && (thirdBlock != fourthBlock)); DQN_ASSERT(secondBlock->prevBlock == NULL); DQN_ASSERT(thirdBlock->prevBlock == secondBlock); DQN_ASSERT(fourthBlock->prevBlock == thirdBlock); for (u32 i = 0; i < secondBlockSize; i++) DQN_ASSERT(second[i] == 'd'); for (u32 i = 0; i < thirdBlockSize; i++) DQN_ASSERT(third[i] == 'e'); for (u32 i = 0; i < fourthBlockSize; i++) DQN_ASSERT(fourth[i] == 'f'); // Free the third block DqnMemStack_FreeMemBlock(&stack, thirdBlock); // Revalidate state DQN_ASSERT(secondBlock->size == secondBlockSize); DQN_ASSERT(fourthBlock->size == fourthBlockSize); DQN_ASSERT(secondBlock->used == secondBlockSize); DQN_ASSERT(fourthBlock->used == fourthBlockSize); DQN_ASSERT(secondBlock != fourthBlock); DQN_ASSERT(secondBlock->prevBlock == NULL); DQN_ASSERT(fourthBlock->prevBlock == secondBlock); for (u32 i = 0; i < secondBlockSize; i++) DQN_ASSERT(second[i] == 'd'); for (u32 i = 0; i < fourthBlockSize; i++) DQN_ASSERT(fourth[i] == 'f'); // Free the second block DqnMemStack_FreeMemBlock(&stack, secondBlock); // Revalidate state DQN_ASSERT(fourthBlock->size == fourthBlockSize); DQN_ASSERT(fourthBlock->used == fourthBlockSize); DQN_ASSERT(fourthBlock->prevBlock == NULL); for (u32 i = 0; i < fourthBlockSize; i++) DQN_ASSERT(fourth[i] == 'f'); // Free the stack DqnMemStack_Free(&stack); DQN_ASSERT(!stack.block); } // Test pop if (1) { // Test aligned pop if (1) { DqnMemStack stack = {}; DqnMemStack_Init(&stack, DQN_KILOBYTE(1), true); size_t allocSize = 512; void *alloc = DqnMemStack_Push(&stack, allocSize); DQN_ASSERT(stack.block->used == allocSize); DQN_ASSERT(DqnMemStack_Pop(&stack, alloc, allocSize)); DQN_ASSERT(stack.block->used == 0); DqnMemStack_Free(&stack); } // Test pop on a non-byte aligned allocation. This checks to see if // Pop() doesn't naiively forget to re-byte align the passed in size. if (1) { DqnMemStack stack = {}; DqnMemStack_Init(&stack, DQN_KILOBYTE(1), true); size_t allocSize = 1; void *alloc = DqnMemStack_Push(&stack, allocSize); DQN_ASSERT(stack.block->used == DQN_ALIGN_POW_N(allocSize, stack.byteAlign)); DQN_ASSERT(DqnMemStack_Pop(&stack, alloc, allocSize)); DQN_ASSERT(stack.block->used == 0); DqnMemStack_Free(&stack); } } } #ifdef DQN_XPLATFORM_LAYER void FileTest() { PrintHeader("File Test"); // File i/o if (1) { printf("start file tests"); // Test file open if (1) { const char *const FILE_TO_OPEN = ".clang-format"; u32 expectedSize = 0; #if defined(DQN_UNIX_IMPLEMENTATION) { struct stat fileStat = {0}; DQN_ASSERT(stat(FILE_TO_OPEN, &fileStat) == 0); expectedSize = fileStat.st_size; } if (1) { // NOTE: cpuinfo is generated when queried, so a normal 'stat' // should give us zero, but we fall back to manual byte checking // which should give us the proper size. size_t size = 0; DQN_ASSERT(DqnFile_GetFileSize("/proc/cpuinfo", &size)); DQN_ASSERT(size > 0); } #elif defined(DQN_WIN32_IMPLEMENTATION) { HANDLE handle = CreateFile(FILE_TO_OPEN, GENERIC_READ, 0, NULL, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL, NULL); if (handle == INVALID_HANDLE_VALUE) { DqnWin32_DisplayLastError("CreateFile() failed"); } DQN_ASSERT(handle != INVALID_HANDLE_VALUE); LARGE_INTEGER size; DQN_ASSERT(GetFileSizeEx(handle, &size)); CloseHandle(handle); expectedSize = size.LowPart; } #endif if (1) { size_t size = 0; DQN_ASSERT_HARD(DqnFile_GetFileSize(FILE_TO_OPEN, &size)); DQN_ASSERT_HARD(size == expectedSize); } DqnFile file = {}; DQN_ASSERT(DqnFile_Open(".clang-format", &file, (DqnFilePermissionFlag_Write | DqnFilePermissionFlag_Read), DqnFileAction_OpenOnly)); DQN_ASSERT_MSG(file.size == expectedSize, "DqnFileOpen() failed: file.size: %d, expected:%d\n", file.size, expectedSize); u8 *buffer = (u8 *)calloc(1, (size_t)file.size * sizeof(u8)); DQN_ASSERT(DqnFile_Read(&file, buffer, (u32)file.size) == file.size); free(buffer); DqnFile_Close(&file); DQN_ASSERT(!file.handle && file.size == 0 && file.permissionFlags == 0); if (1) { DqnFile raiiFile = DqnFile(true); if (raiiFile.Open(FILE_TO_OPEN, DqnFilePermissionFlag_Write | DqnFilePermissionFlag_Read, DqnFileAction_OpenOnly)) { i32 breakHereToTestRaii = 0; (void)breakHereToTestRaii; } } } // Test invalid file if (1) { DqnFile file = {}; DQN_ASSERT(!DqnFile_Open("asdljasdnel;kajdf", &file, (DqnFilePermissionFlag_Write | DqnFilePermissionFlag_Read), DqnFileAction_OpenOnly)); DQN_ASSERT(file.size == 0); DQN_ASSERT(file.permissionFlags == 0); DQN_ASSERT(!file.handle); printf("FileTest(): FileIO: Completed successfully\n"); } } //////////////////////////////////////////////////////////////////////////// // Write Test //////////////////////////////////////////////////////////////////////////// if (1) { const char *fileNames[] = {"dqn_1", "dqn_2", "dqn_3", "dqn_4", "dqn_5"}; const char *writeData[] = {"1234", "2468", "36912", "481216", "5101520"}; DqnFile files[DQN_ARRAY_COUNT(fileNames)] = {}; // Write data out to some files for (u32 i = 0; i < DQN_ARRAY_COUNT(fileNames); i++) { u32 permissions = DqnFilePermissionFlag_Read | DqnFilePermissionFlag_Write; if (!DqnFile_Open(fileNames[i], files + i, permissions, DqnFileAction_ClearIfExist)) { bool result = DqnFile_Open(fileNames[i], files + i, permissions, DqnFileAction_CreateIfNotExist); DQN_ASSERT(result); } size_t bytesToWrite = DqnStr_Len(writeData[i]); u8 *dataToWrite = (u8 *)(writeData[i]); size_t bytesWritten = DqnFile_Write(files + i, dataToWrite, bytesToWrite, 0); DQN_ASSERT(bytesWritten == bytesToWrite); DqnFile_Close(&files[i]); } DqnMemStack memStack = {}; DQN_ASSERT(DqnMemStack_Init(&memStack, DQN_MEGABYTE(1), true)); // Read data back in for (u32 i = 0; i < DQN_ARRAY_COUNT(fileNames); i++) { // Manual read the file contents { u32 permissions = DqnFilePermissionFlag_Read; DqnFile *file = files + i; bool result = DqnFile_Open(fileNames[i], file, permissions, DqnFileAction_OpenOnly); DQN_ASSERT(result); u8 *buffer = (u8 *)DqnMemStack_Push(&memStack, file->size); DQN_ASSERT(buffer); size_t bytesRead = DqnFile_Read(&files[i], buffer, file->size); DQN_ASSERT(bytesRead == file->size); // Verify the data is the same as we wrote out DQN_ASSERT(DqnStr_Cmp((char *)buffer, (writeData[i])) == 0); // Delete when we're done with it DQN_ASSERT(DqnMemStack_Pop(&memStack, buffer, file->size)); DqnFile_Close(file); } // Read using the ReadEntireFile api which doesn't need a file handle as an argument { size_t reqSize = 0; DQN_ASSERT(DqnFile_GetFileSize(fileNames[i], &reqSize)); u8 *buffer = (u8 *)DqnMemStack_Push(&memStack, reqSize); DQN_ASSERT(buffer); size_t bytesRead = 0; DQN_ASSERT(DqnFile_ReadEntireFile(fileNames[i], buffer, reqSize, &bytesRead)); DQN_ASSERT(bytesRead == reqSize); // Verify the data is the same as we wrote out DQN_ASSERT(DqnStr_Cmp((char *)buffer, (writeData[i])) == 0); DQN_ASSERT(DqnMemStack_Pop(&memStack, buffer, reqSize)); } DQN_ASSERT(DqnFile_Delete(fileNames[i])); } // Then check delete actually worked, files should not exist. for (u32 i = 0; i < DQN_ARRAY_COUNT(fileNames); i++) { DqnFile dummy = {}; u32 permissions = DqnFilePermissionFlag_Read; bool fileExists = DqnFile_Open(fileNames[i], &dummy, permissions, DqnFileAction_OpenOnly); DQN_ASSERT(!fileExists); } DqnMemStack_Free(&memStack); } //////////////////////////////////////////////////////////////////////////// // Test directory listing //////////////////////////////////////////////////////////////////////////// if (1) { u32 numFiles; #if defined(DQN_UNIX_IMPLEMENTATION) char **filelist = DqnDir_Read(".", &numFiles); #elif defined(DQN_WIN32_IMPLEMENTATION) char **filelist = DqnDir_Read("*", &numFiles); #endif printf("FileTest(): DirRead: Display read files\n"); for (u32 i = 0; i < numFiles; i++) printf("FileTest(): DirRead: %s\n", filelist[i]); DqnDir_ReadFree(filelist, numFiles); printf("FileTest(): DirRead: Completed successfully\n"); } printf("FileTest(): Completed successfully\n"); } #endif FILE_SCOPE u32 volatile globalDebugCounter; FILE_SCOPE DqnLock globalJobQueueLock; const u32 QUEUE_SIZE = 256; FILE_SCOPE void JobQueueDebugCallbackIncrementCounter(DqnJobQueue *const queue, void *const userData) { (void)userData; DQN_ASSERT(queue->size == QUEUE_SIZE); { DqnLockGuard guard = globalJobQueueLock.LockGuard(); globalDebugCounter++; #if 0 u32 number = globalDebugCounter; #if defined(DQN_WIN32_IMPLEMENTATION) printf("JobQueueDebugCallbackIncrementCounter(): Thread %d: Incrementing Number: %d\n", GetCurrentThreadId(), number); #elif defined(DQN_UNIX_IMPLEMENTATION) printf("JobQueueDebugCallbackIncrementCounter(): Thread unix: Incrementing Number: %d\n", number); #endif #endif } } FILE_SCOPE void JobQueueTest() { PrintHeader("Job Queue Multithreading Test"); globalDebugCounter = 0; DqnMemStack memStack = {}; DQN_ASSERT_HARD(memStack.Init(DQN_MEGABYTE(1), true)); u32 numThreads, numCores; DqnPlatform_GetNumThreadsAndCores(&numCores, &numThreads); DQN_ASSERT(numThreads > 0 && numCores > 0); u32 totalThreads = (numCores - 1) * numThreads; if (totalThreads == 0) totalThreads = 1; DqnJobQueue jobQueue = {}; DqnJob *jobList = (DqnJob *)memStack.Push(sizeof(*jobQueue.jobList) * QUEUE_SIZE); DQN_ASSERT(DqnJobQueue_Init(&jobQueue, jobList, QUEUE_SIZE, totalThreads)); const u32 WORK_ENTRIES = 2048; DQN_ASSERT(DqnLock_Init(&globalJobQueueLock)); for (u32 i = 0; i < WORK_ENTRIES; i++) { DqnJob job = {}; job.callback = JobQueueDebugCallbackIncrementCounter; while (!DqnJobQueue_AddJob(&jobQueue, job)) { DqnJobQueue_TryExecuteNextJob(&jobQueue); } } DqnJobQueue_BlockAndCompleteAllJobs(&jobQueue); printf("JobQueueTest(): Final incremented value: %d\n", globalDebugCounter); DQN_ASSERT(globalDebugCounter == WORK_ENTRIES); DqnLock_Delete(&globalJobQueueLock); } FILE_SCOPE inline bool Dqn_QuickSortLessThanU32(const void *const val1, const void *const val2) { const u32 *const a = (u32 *)val1; const u32 *const b = (u32 *)val2; return (*a) < (*b); } FILE_SCOPE inline void Dqn_QuickSortSwapU32(void *const val1, void *const val2) { u32 *a = (u32 *)val1; u32 *b = (u32 *)val2; DQN_SWAP(u32, *a, *b); } #include void SortTest() { { u32 array[] = {4, 8, 7, 5, 2, 3, 6}; Dqn_QuickSortC(array, sizeof(array[0]), DQN_ARRAY_COUNT(array), Dqn_QuickSortLessThanU32, Dqn_QuickSortSwapU32); for (u32 i = 0; i < DQN_ARRAY_COUNT(array) - 1; i++) { DQN_ASSERT(array[i] <= array[i + 1]); } } PrintHeader("DqnSort vs std::Sort"); DqnRandPCGState state = {}; DqnRnd_PCGInit(&state); if (1) { DqnMemStack stack = {}; DQN_ASSERT(stack.Init(DQN_KILOBYTE(1), false)); // Create array of ints u32 numInts = 1000000; u32 sizeInBytes = sizeof(u32) * numInts; u32 *dqnCArray = (u32 *)stack.Push(sizeInBytes); u32 *dqnCPPArray = (u32 *)stack.Push(sizeInBytes); u32 *stdArray = (u32 *)stack.Push(sizeInBytes); DQN_ASSERT(dqnCArray && dqnCPPArray && stdArray); f64 dqnCTimings[10] = {}; f64 dqnCPPTimings[DQN_ARRAY_COUNT(dqnCTimings)] = {}; f64 stdTimings[DQN_ARRAY_COUNT(dqnCTimings)] = {}; f64 dqnCAverage = 0; f64 dqnCPPAverage = 0; f64 stdAverage = 0; for (u32 timingsIndex = 0; timingsIndex < DQN_ARRAY_COUNT(dqnCTimings); timingsIndex++) { // Populate with random numbers for (u32 i = 0; i < numInts; i++) { dqnCArray[i] = DqnRnd_PCGNext(&state); dqnCPPArray[i] = dqnCArray[i]; stdArray[i] = dqnCPPArray[i]; } // Time Dqn_QuickSortC { f64 start = DqnTimer_NowInS(); Dqn_QuickSortC(dqnCArray, sizeof(dqnCArray[0]), numInts, Dqn_QuickSortLessThanU32, Dqn_QuickSortSwapU32); f64 duration = DqnTimer_NowInS() - start; dqnCTimings[timingsIndex] = duration; dqnCAverage += duration; printf("[%02d]Dqn_QuickSortC: %f vs ", timingsIndex, dqnCTimings[timingsIndex]); } // Time Dqn_QuickSortC { f64 start = DqnTimer_NowInS(); Dqn_QuickSort(dqnCPPArray, numInts, Dqn_QuickSortLessThanU32); f64 duration = DqnTimer_NowInS() - start; dqnCPPTimings[timingsIndex] = duration; dqnCPPAverage += duration; printf("Dqn_QuickSort: %f vs ", dqnCPPTimings[timingsIndex]); } // Time std::sort { f64 start = DqnTimer_NowInS(); std::sort(stdArray, stdArray + numInts); f64 duration = DqnTimer_NowInS() - start; stdTimings[timingsIndex] = duration; stdAverage += duration; printf("std::sort: %f\n", stdTimings[timingsIndex]); } for (u32 i = 0; i < numInts; i++) { DQN_ASSERT_MSG(dqnCArray[i] == stdArray[i], "DqnArray[%d]: %d, stdArray[%d]: %d", i, dqnCArray[i], stdArray[i], i); } } // Print averages if (1) { dqnCAverage /= (f64)DQN_ARRAY_COUNT(dqnCTimings); dqnCPPAverage /= (f64)DQN_ARRAY_COUNT(dqnCPPTimings); stdAverage /= (f64)DQN_ARRAY_COUNT(stdTimings); printf("\n- Average Timings\n"); printf(" Dqn_QuickSortC: %f vs Dqn_QuickSort: %f vs std::sort: %f\n\n", dqnCAverage, dqnCPPAverage, stdAverage); } stack.Pop(stdArray, sizeInBytes); stack.Pop(dqnCPPArray, sizeInBytes); stack.Pop(dqnCArray, sizeInBytes); stack.Free(); } } int main(void) { StringsTest(); RandomTest(); MathTest(); HandmadeMathTest(); VecTest(); ArrayTest(); MemStackTest(); SortTest(); #ifdef DQN_XPLATFORM_LAYER FileTest(); OtherTest(); JobQueueTest(); #endif printf("\nPress 'Enter' Key to Exit\n"); getchar(); return 0; } #if defined(__GNUC__) #pragma GCC diagnostic pop #endif