#define DQN_IMPLEMENTATION #include "dqn.h" #include "stdio.h" void dqn_strings_test() { { // Char Checks DQN_ASSERT(dqn_char_is_alpha('a') == true); DQN_ASSERT(dqn_char_is_alpha('A') == true); DQN_ASSERT(dqn_char_is_alpha('0') == false); DQN_ASSERT(dqn_char_is_alpha('@') == false); DQN_ASSERT(dqn_char_is_alpha(' ') == false); DQN_ASSERT(dqn_char_is_alpha('\n') == false); DQN_ASSERT(dqn_char_is_digit('1') == true); DQN_ASSERT(dqn_char_is_digit('n') == false); DQN_ASSERT(dqn_char_is_digit('N') == false); DQN_ASSERT(dqn_char_is_digit('*') == false); DQN_ASSERT(dqn_char_is_digit(' ') == false); DQN_ASSERT(dqn_char_is_digit('\n') == false); DQN_ASSERT(dqn_char_is_alphanum('1') == true); DQN_ASSERT(dqn_char_is_alphanum('a') == true); DQN_ASSERT(dqn_char_is_alphanum('A') == true); DQN_ASSERT(dqn_char_is_alphanum('*') == false); DQN_ASSERT(dqn_char_is_alphanum(' ') == false); DQN_ASSERT(dqn_char_is_alphanum('\n') == false); printf("dqn_strings_test(): char_checks: Completed successfully\n"); } // String Checks { // strcmp { char *a = "str_a"; // Check simple compares { DQN_ASSERT(dqn_strcmp(a, "str_a") == +0); DQN_ASSERT(dqn_strcmp(a, "str_b") == -1); DQN_ASSERT(dqn_strcmp("str_b", a) == +1); DQN_ASSERT(dqn_strcmp(a, "") == +1); DQN_ASSERT(dqn_strcmp("", "") == 0); // NOTE: Check that the string has not been trashed. DQN_ASSERT(dqn_strcmp(a, "str_a") == +0); } // Check ops against null { DQN_ASSERT(dqn_strcmp(NULL, NULL) != +0); DQN_ASSERT(dqn_strcmp(a, NULL) != +0); DQN_ASSERT(dqn_strcmp(NULL, a) != +0); } printf("dqn_strings_test(): strcmp: Completed successfully\n"); } // strlen { char *a = "str_a"; DQN_ASSERT(dqn_strlen(a) == 5); DQN_ASSERT(dqn_strlen("") == 0); DQN_ASSERT(dqn_strlen(" a ") == 6); DQN_ASSERT(dqn_strlen("a\n") == 2); // NOTE: Check that the string has not been trashed. DQN_ASSERT(dqn_strcmp(a, "str_a") == 0); DQN_ASSERT(dqn_strlen(NULL) == 0); printf("dqn_strings_test(): strlen: Completed successfully\n"); } // strncpy { { char *a = "str_a"; char b[10] = {}; // Check copy into empty array { char *result = dqn_strncpy(b, a, dqn_strlen(a)); DQN_ASSERT(dqn_strcmp(b, "str_a") == 0); DQN_ASSERT(dqn_strcmp(a, "str_a") == 0); DQN_ASSERT(dqn_strcmp(result, "str_a") == 0); DQN_ASSERT(dqn_strlen(result) == 5); } // Check copy into array offset, overlap with old results { char *newResult = dqn_strncpy(&b[1], a, dqn_strlen(a)); DQN_ASSERT(dqn_strcmp(newResult, "str_a") == 0); DQN_ASSERT(dqn_strlen(newResult) == 5); DQN_ASSERT(dqn_strcmp(a, "str_a") == 0); DQN_ASSERT(dqn_strlen(a) == 5); DQN_ASSERT(dqn_strcmp(b, "sstr_a") == 0); DQN_ASSERT(dqn_strlen(b) == 6); } } // Check strncpy with NULL pointers { DQN_ASSERT(dqn_strncpy(NULL, NULL, 5) == NULL); char *a = "str"; char *result = dqn_strncpy(a, NULL, 5); DQN_ASSERT(dqn_strcmp(a, "str") == 0); DQN_ASSERT(dqn_strcmp(result, "str") == 0); DQN_ASSERT(dqn_strcmp(result, a) == 0); } // Check strncpy with 0 chars to copy { char *a = "str"; char *b = "ing"; char *result = dqn_strncpy(a, b, 0); DQN_ASSERT(dqn_strcmp(a, "str") == 0); DQN_ASSERT(dqn_strcmp(b, "ing") == 0); DQN_ASSERT(dqn_strcmp(result, "str") == 0); } printf("dqn_strings_test(): strncpy: Completed successfully\n"); } // str_reverse { // Basic reverse operations { char a[] = "aba"; DQN_ASSERT(dqn_str_reverse(a, dqn_strlen(a)) == true); DQN_ASSERT(dqn_strcmp(a, "aba") == 0); DQN_ASSERT(dqn_str_reverse(a, 2) == true); DQN_ASSERT(dqn_strcmp(a, "baa") == 0); DQN_ASSERT(dqn_str_reverse(a, dqn_strlen(a)) == true); DQN_ASSERT(dqn_strcmp(a, "aab") == 0); DQN_ASSERT(dqn_str_reverse(&a[1], 2) == true); DQN_ASSERT(dqn_strcmp(a, "aba") == 0); DQN_ASSERT(dqn_str_reverse(a, 0) == true); DQN_ASSERT(dqn_strcmp(a, "aba") == 0); } // Try reverse empty string { char a[] = ""; DQN_ASSERT(dqn_str_reverse(a, dqn_strlen(a)) == true); DQN_ASSERT(dqn_strcmp(a, "") == 0); } // Try reverse single char string { char a[] = "a"; DQN_ASSERT(dqn_str_reverse(a, dqn_strlen(a)) == true); DQN_ASSERT(dqn_strcmp(a, "a") == 0); DQN_ASSERT(dqn_str_reverse(a, 0) == true); DQN_ASSERT(dqn_strcmp(a, "a") == 0); } printf( "dqn_strings_test(): str_reverse: Completed successfully\n"); } // str_to_i32 { char *a = "123"; DQN_ASSERT(dqn_str_to_i32(a, dqn_strlen(a)) == 123); char *b = "-123"; DQN_ASSERT(dqn_str_to_i32(b, dqn_strlen(b)) == -123); DQN_ASSERT(dqn_str_to_i32(b, 1) == 0); DQN_ASSERT(dqn_str_to_i32(&b[1], dqn_strlen(&b[1])) == 123); char *c = "-0"; DQN_ASSERT(dqn_str_to_i32(c, dqn_strlen(c)) == 0); char *d = "+123"; DQN_ASSERT(dqn_str_to_i32(d, dqn_strlen(d)) == 123); DQN_ASSERT(dqn_str_to_i32(&d[1], dqn_strlen(&d[1])) == 123); printf("dqn_strings_test(): str_to_i32: Completed successfully\n"); } // i32_to_str { char a[DQN_I32_TO_STR_MAX_BUF_SIZE] = {}; dqn_i32_to_str(+100, a, DQN_ARRAY_COUNT(a)); DQN_ASSERT(dqn_strcmp(a, "100") == 0); char b[DQN_I32_TO_STR_MAX_BUF_SIZE] = {}; dqn_i32_to_str(-100, b, DQN_ARRAY_COUNT(b)); DQN_ASSERT(dqn_strcmp(b, "-100") == 0); char c[DQN_I32_TO_STR_MAX_BUF_SIZE] = {}; dqn_i32_to_str(0, c, DQN_ARRAY_COUNT(c)); DQN_ASSERT(dqn_strcmp(c, "0") == 0); printf("dqn_strings_test(): str_to_i32: Completed successfully\n"); } } // UCS <-> UTF8 Checks { // Test ascii characters { u32 codepoint = '@'; u32 string[1] = {}; u32 bytesUsed = dqn_ucs_to_utf8(&string[0], codepoint); DQN_ASSERT(bytesUsed == 1); DQN_ASSERT(string[0] == '@'); bytesUsed = dqn_utf8_to_ucs(&string[0], codepoint); DQN_ASSERT(string[0] >= 0 && string[0] < 0x80); DQN_ASSERT(bytesUsed == 1); } // Test 2 byte characters { u32 codepoint = 0x278; u32 string[1] = {}; u32 bytesUsed = dqn_ucs_to_utf8(&string[0], codepoint); DQN_ASSERT(bytesUsed == 2); DQN_ASSERT(string[0] == 0xC9B8); bytesUsed = dqn_utf8_to_ucs(&string[0], string[0]); DQN_ASSERT(string[0] == codepoint); DQN_ASSERT(bytesUsed == 2); } // Test 3 byte characters { u32 codepoint = 0x0A0A; u32 string[1] = {}; u32 bytesUsed = dqn_ucs_to_utf8(&string[0], codepoint); DQN_ASSERT(bytesUsed == 3); DQN_ASSERT(string[0] == 0xE0A88A); bytesUsed = dqn_utf8_to_ucs(&string[0], string[0]); DQN_ASSERT(string[0] == codepoint); DQN_ASSERT(bytesUsed == 3); } // Test 4 byte characters { u32 codepoint = 0x10912; u32 string[1] = {}; u32 bytesUsed = dqn_ucs_to_utf8(&string[0], codepoint); DQN_ASSERT(bytesUsed == 4); DQN_ASSERT(string[0] == 0xF090A492); bytesUsed = dqn_utf8_to_ucs(&string[0], string[0]); DQN_ASSERT(string[0] == codepoint); DQN_ASSERT(bytesUsed == 4); } { u32 codepoint = 0x10912; u32 bytesUsed = dqn_ucs_to_utf8(NULL, codepoint); DQN_ASSERT(bytesUsed == 0); bytesUsed = dqn_utf8_to_ucs(NULL, codepoint); DQN_ASSERT(bytesUsed == 0); } printf("dqn_strings_test(): ucs <-> utf8: Completed successfully\n"); } printf("dqn_strings_test(): Completed successfully\n"); } #include "Windows.h" #define WIN32_LEAN_AND_MEAN void dqn_other_test() { { // Test Win32 Sleep // NOTE: Win32 Sleep is not granular to a certain point so sleep excessively u32 sleepInMs = 1000; f64 startInMs = dqn_time_now_in_ms(); Sleep(sleepInMs); f64 endInMs = dqn_time_now_in_ms(); DQN_ASSERT(startInMs < endInMs); printf("dqn_other_test(): time_now: Completed successfully\n"); } printf("dqn_other_test(): Completed successfully\n"); } void dqn_random_test() { DqnRandPCGState pcg; dqn_rnd_pcg_init(&pcg); for (i32 i = 0; i < 10; i++) { i32 min = -100; i32 max = 100000; i32 result = dqn_rnd_pcg_range(&pcg, min, max); DQN_ASSERT(result >= min && result <= max) f32 randF32 = dqn_rnd_pcg_nextf(&pcg); DQN_ASSERT(randF32 >= 0.0f && randF32 <= 1.0f); printf("dqn_random_test(): rnd_pcg: Completed successfully\n"); } printf("dqn_random_test(): Completed successfully\n"); } void dqn_math_test() { { // Lerp { f32 start = 10; f32 t = 0.5f; f32 end = 20; DQN_ASSERT(dqn_math_lerp(start, t, end) == 15); } { f32 start = 10; f32 t = 2.0f; f32 end = 20; DQN_ASSERT(dqn_math_lerp(start, t, end) == 30); } printf("dqn_math_test(): lerp: Completed successfully\n"); } { // sqrtf DQN_ASSERT(dqn_math_sqrtf(4.0f) == 2.0f); printf("dqn_math_test(): sqrtf: Completed successfully\n"); } printf("dqn_math_test(): Completed successfully\n"); } void dqn_vec_test() { { // V2 // V2 Creating { DqnV2 vec = dqn_v2(5.5f, 5.0f); DQN_ASSERT(vec.x == 5.5f && vec.y == 5.0f); DQN_ASSERT(vec.w == 5.5f && vec.h == 5.0f); } // V2i Creating { DqnV2 vec = dqn_v2i(3, 5); DQN_ASSERT(vec.x == 3 && vec.y == 5.0f); DQN_ASSERT(vec.w == 3 && vec.h == 5.0f); } // V2 Arithmetic { DqnV2 vecA = dqn_v2(5, 10); DqnV2 vecB = dqn_v2i(2, 3); DQN_ASSERT(dqn_v2_equals(vecA, vecB) == false); DQN_ASSERT(dqn_v2_equals(vecA, dqn_v2(5, 10)) == true); DQN_ASSERT(dqn_v2_equals(vecB, dqn_v2(2, 3)) == true); DqnV2 result = dqn_v2_add(vecA, dqn_v2(5, 10)); DQN_ASSERT(dqn_v2_equals(result, dqn_v2(10, 20)) == true); result = dqn_v2_sub(result, dqn_v2(5, 10)); DQN_ASSERT(dqn_v2_equals(result, dqn_v2(5, 10)) == true); result = dqn_v2_scale(result, 5); DQN_ASSERT(dqn_v2_equals(result, dqn_v2(25, 50)) == true); result = dqn_v2_hadamard(result, dqn_v2(10, 0.5f)); DQN_ASSERT(dqn_v2_equals(result, dqn_v2(250, 25)) == true); f32 dotResult = dqn_v2_dot(dqn_v2(5, 10), dqn_v2(3, 4)); DQN_ASSERT(dotResult == 55); } // V2 Properties { DqnV2 a = dqn_v2(0, 0); DqnV2 b = dqn_v2(3, 4); f32 lengthSq = dqn_v2_length_squared(a, b); DQN_ASSERT(lengthSq == 25); f32 length = dqn_v2_length(a, b); DQN_ASSERT(length == 5); DqnV2 normalised = dqn_v2_normalise(b); DQN_ASSERT(normalised.x == (b.x / 5.0f)); DQN_ASSERT(normalised.y == (b.y / 5.0f)); DqnV2 c = dqn_v2(3.5f, 8.0f); DQN_ASSERT(dqn_v2_overlaps(b, c) == true); DQN_ASSERT(dqn_v2_overlaps(b, a) == false); DqnV2 d = dqn_v2_perpendicular(c); DQN_ASSERT(dqn_v2_dot(c, d) == 0); } { // constrain_to_ratio DqnV2 ratio = dqn_v2(16, 9); DqnV2 dim = dqn_v2(2000, 1080); DqnV2 result = dqn_v2_constrain_to_ratio(dim, ratio); DQN_ASSERT(result.w == 1920 && result.h == 1080); } printf("dqn_vec_test(): vec2: Completed successfully\n"); } { // V3 // V3i Creating { DqnV3 vec = dqn_v3(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 { DqnV3 vec = dqn_v3i(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 { DqnV3 vecA = dqn_v3(5, 10, 15); DqnV3 vecB = dqn_v3(2, 3, 6); DQN_ASSERT(dqn_v3_equals(vecA, vecB) == false); DQN_ASSERT(dqn_v3_equals(vecA, dqn_v3(5, 10, 15)) == true); DQN_ASSERT(dqn_v3_equals(vecB, dqn_v3(2, 3, 6)) == true); DqnV3 result = dqn_v3_add(vecA, dqn_v3(5, 10, 15)); DQN_ASSERT(dqn_v3_equals(result, dqn_v3(10, 20, 30)) == true); result = dqn_v3_sub(result, dqn_v3(5, 10, 15)); DQN_ASSERT(dqn_v3_equals(result, dqn_v3(5, 10, 15)) == true); result = dqn_v3_scale(result, 5); DQN_ASSERT(dqn_v3_equals(result, dqn_v3(25, 50, 75)) == true); result = dqn_v3_hadamard(result, dqn_v3(10.0f, 0.5f, 10.0f)); DQN_ASSERT(dqn_v3_equals(result, dqn_v3(250, 25, 750)) == true); f32 dotResult = dqn_v3_dot(dqn_v3(5, 10, 2), dqn_v3(3, 4, 6)); DQN_ASSERT(dotResult == 67); DqnV3 cross = dqn_v3_cross(vecA, vecB); DQN_ASSERT(dqn_v3_equals(cross, dqn_v3(15, 0, -5)) == true); } printf("dqn_vec_test(): vec3: Completed successfully\n"); } { // V4 // V4 Creating { DqnV4 vec = dqn_v4(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 { DqnV4 vec = dqn_v4i(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 { DqnV4 vecA = dqn_v4(5, 10, 15, 20); DqnV4 vecB = dqn_v4i(2, 3, 6, 8); DQN_ASSERT(dqn_v4_equals(vecA, vecB) == false); DQN_ASSERT(dqn_v4_equals(vecA, dqn_v4(5, 10, 15, 20)) == true); DQN_ASSERT(dqn_v4_equals(vecB, dqn_v4(2, 3, 6, 8)) == true); DqnV4 result = dqn_v4_add(vecA, dqn_v4(5, 10, 15, 20)); DQN_ASSERT(dqn_v4_equals(result, dqn_v4(10, 20, 30, 40)) == true); result = dqn_v4_sub(result, dqn_v4(5, 10, 15, 20)); DQN_ASSERT(dqn_v4_equals(result, dqn_v4(5, 10, 15, 20)) == true); result = dqn_v4_scale(result, 5); DQN_ASSERT(dqn_v4_equals(result, dqn_v4(25, 50, 75, 100)) == true); result = dqn_v4_hadamard(result, dqn_v4(10, 0.5f, 10, 0.25f)); DQN_ASSERT(dqn_v4_equals(result, dqn_v4(250, 25, 750, 25)) == true); f32 dotResult = dqn_v4_dot(dqn_v4(5, 10, 2, 8), dqn_v4(3, 4, 6, 5)); DQN_ASSERT(dotResult == 107); } printf("dqn_vec_test(): vec4: Completed successfully\n"); } // Rect { DqnRect rect = dqn_rect(dqn_v2(-10, -10), dqn_v2(20, 20)); DQN_ASSERT(dqn_v2_equals(rect.min, dqn_v2(-10, -10))); DQN_ASSERT(dqn_v2_equals(rect.max, dqn_v2(10, 10))); f32 width, height; dqn_rect_get_size_2f(rect, &width, &height); DQN_ASSERT(width == 20); DQN_ASSERT(height == 20); DqnV2 dim = dqn_rect_get_size_v2(rect); DQN_ASSERT(dqn_v2_equals(dim, dqn_v2(20, 20))); DqnV2 rectCenter = dqn_rect_get_centre(rect); DQN_ASSERT(dqn_v2_equals(rectCenter, dqn_v2(0, 0))); // Test shifting rect DqnRect shiftedRect = dqn_rect_move(rect, dqn_v2(10, 0)); DQN_ASSERT(dqn_v2_equals(shiftedRect.min, dqn_v2(0, -10))); DQN_ASSERT(dqn_v2_equals(shiftedRect.max, dqn_v2(20, 10))); dqn_rect_get_size_2f(shiftedRect, &width, &height); DQN_ASSERT(width == 20); DQN_ASSERT(height == 20); dim = dqn_rect_get_size_v2(shiftedRect); DQN_ASSERT(dqn_v2_equals(dim, dqn_v2(20, 20))); // Test rect contains p DqnV2 inP = dqn_v2(5, 5); DqnV2 outP = dqn_v2(100, 100); DQN_ASSERT(dqn_rect_contains_p(shiftedRect, inP)); DQN_ASSERT(!dqn_rect_contains_p(shiftedRect, outP)); printf("dqn_vec_test(): rect: Completed successfully\n"); } printf("dqn_vec_test(): Completed successfully\n"); } void dqn_darray_test() { { DqnV2 *vecDArray = DQN_DARRAY_INIT(DqnV2, 1); DQN_ASSERT(vecDArray); DQN_ASSERT(dqn_darray_get_capacity(vecDArray) == 1); DQN_ASSERT(dqn_darray_get_num_items(vecDArray) == 0); // Test basic insert { DqnV2 va = dqn_v2(5, 10); DQN_DARRAY_PUSH(&vecDArray, va); DqnV2 vb = vecDArray[0]; DQN_ASSERT(dqn_v2_equals(va, vb)); DQN_ASSERT(dqn_darray_get_capacity(vecDArray) == 1); DQN_ASSERT(dqn_darray_get_num_items(vecDArray) == 1); } // Test array resizing and freeing { DqnV2 va = dqn_v2(10, 15); DQN_DARRAY_PUSH(&vecDArray, va); DqnV2 vb = vecDArray[0]; DQN_ASSERT(dqn_v2_equals(va, vb) == false); vb = vecDArray[1]; DQN_ASSERT(dqn_v2_equals(va, vb) == true); DQN_ASSERT(dqn_darray_get_capacity(vecDArray) == 2); DQN_ASSERT(dqn_darray_get_num_items(vecDArray) == 2); DQN_DARRAY_PUSH(&vecDArray, va); DQN_ASSERT(dqn_darray_get_capacity(vecDArray) == 3); DQN_ASSERT(dqn_darray_get_num_items(vecDArray) == 3); DQN_DARRAY_PUSH(&vecDArray, va); DQN_ASSERT(dqn_darray_get_capacity(vecDArray) == 4); DQN_ASSERT(dqn_darray_get_num_items(vecDArray) == 4); DQN_DARRAY_PUSH(&vecDArray, va); DQN_ASSERT(dqn_darray_get_capacity(vecDArray) == 5); DQN_ASSERT(dqn_darray_get_num_items(vecDArray) == 5); DQN_DARRAY_PUSH(&vecDArray, va); DQN_ASSERT(dqn_darray_get_capacity(vecDArray) == 6); DQN_ASSERT(dqn_darray_get_num_items(vecDArray) == 6); DQN_DARRAY_PUSH(&vecDArray, va); DQN_ASSERT(dqn_darray_get_capacity(vecDArray) == 7); DQN_ASSERT(dqn_darray_get_num_items(vecDArray) == 7); DQN_DARRAY_PUSH(&vecDArray, va); DQN_ASSERT(dqn_darray_get_capacity(vecDArray) == 8); DQN_ASSERT(dqn_darray_get_num_items(vecDArray) == 8); DQN_DARRAY_PUSH(&vecDArray, va); DQN_ASSERT(dqn_darray_get_capacity(vecDArray) == 9); DQN_ASSERT(dqn_darray_get_num_items(vecDArray) == 9); DQN_DARRAY_PUSH(&vecDArray, va); DQN_ASSERT(dqn_darray_get_capacity(vecDArray) == 10); DQN_ASSERT(dqn_darray_get_num_items(vecDArray) == 10); DQN_DARRAY_PUSH(&vecDArray, va); DQN_ASSERT(dqn_darray_get_capacity(vecDArray) == 12); DQN_ASSERT(dqn_darray_get_num_items(vecDArray) == 11); DqnV2 vc = dqn_v2(90, 100); DQN_DARRAY_PUSH(&vecDArray, vc); DQN_ASSERT(dqn_darray_get_capacity(vecDArray) == 12); DQN_ASSERT(dqn_darray_get_num_items(vecDArray) == 12); DQN_ASSERT(dqn_v2_equals(vc, vecDArray[11])); DQN_ASSERT(dqn_darray_free(vecDArray) == true); } } { f32 *array = DQN_DARRAY_INIT(f32, 1); DQN_ASSERT(array); DQN_ASSERT(dqn_darray_get_capacity(array) == 1); DQN_ASSERT(dqn_darray_get_num_items(array) == 0); dqn_darray_free(array); } { DqnV2 a = dqn_v2(1, 2); DqnV2 b = dqn_v2(3, 4); DqnV2 c = dqn_v2(5, 6); DqnV2 d = dqn_v2(7, 8); DqnV2 *array = DQN_DARRAY_INIT(DqnV2, 16); DQN_ASSERT(array); DQN_ASSERT(dqn_darray_remove(array, 0) == false); DQN_ASSERT(dqn_darray_get_capacity(array) == 16); DQN_ASSERT(dqn_darray_get_num_items(array) == 0); DQN_ASSERT(dqn_darray_clear(array)); DQN_ASSERT(dqn_darray_get_capacity(array) == 16); DQN_ASSERT(dqn_darray_get_num_items(array) == 0); DQN_DARRAY_PUSH(&array, a); DQN_DARRAY_PUSH(&array, b); DQN_DARRAY_PUSH(&array, c); DQN_DARRAY_PUSH(&array, d); DQN_ASSERT(dqn_darray_get_capacity(array) == 16); DQN_ASSERT(dqn_darray_get_num_items(array) == 4); DQN_ASSERT(dqn_darray_remove(array, 0)); DQN_ASSERT(dqn_v2_equals(array[0], d)); DQN_ASSERT(dqn_v2_equals(array[1], b)); DQN_ASSERT(dqn_v2_equals(array[2], c)); DQN_ASSERT(dqn_darray_get_capacity(array) == 16); DQN_ASSERT(dqn_darray_get_num_items(array) == 3); DQN_ASSERT(dqn_darray_remove(array, 2)); DQN_ASSERT(dqn_v2_equals(array[0], d)); DQN_ASSERT(dqn_v2_equals(array[1], b)); DQN_ASSERT(dqn_darray_get_capacity(array) == 16); DQN_ASSERT(dqn_darray_get_num_items(array) == 2); DQN_ASSERT(dqn_darray_remove(array, 100) == false); DQN_ASSERT(dqn_v2_equals(array[0], d)); DQN_ASSERT(dqn_v2_equals(array[1], b)); DQN_ASSERT(dqn_darray_get_capacity(array) == 16); DQN_ASSERT(dqn_darray_get_num_items(array) == 2); DQN_ASSERT(dqn_darray_clear(array)); DQN_ASSERT(dqn_darray_get_capacity(array) == 16); DQN_ASSERT(dqn_darray_get_num_items(array) == 0); dqn_darray_free(array); } { DqnV2 a = dqn_v2(1, 2); DqnV2 b = dqn_v2(3, 4); DqnV2 c = dqn_v2(5, 6); DqnV2 d = dqn_v2(7, 8); DqnV2 *array = DQN_DARRAY_INIT(DqnV2, 16); DQN_ASSERT(array); DQN_DARRAY_PUSH(&array, a); DQN_DARRAY_PUSH(&array, b); DQN_DARRAY_PUSH(&array, c); DQN_DARRAY_PUSH(&array, d); DQN_ASSERT(dqn_darray_get_capacity(array) == 16); DQN_ASSERT(dqn_darray_get_num_items(array) == 4); dqn_darray_remove_stable(array, 0); DQN_ASSERT(dqn_v2_equals(array[0], b)); DQN_ASSERT(dqn_v2_equals(array[1], c)); DQN_ASSERT(dqn_v2_equals(array[2], d)); DQN_ASSERT(dqn_darray_get_capacity(array) == 16); DQN_ASSERT(dqn_darray_get_num_items(array) == 3); dqn_darray_remove_stable(array, 1); DQN_ASSERT(dqn_v2_equals(array[0], b)); DQN_ASSERT(dqn_v2_equals(array[1], d)); DQN_ASSERT(dqn_darray_get_capacity(array) == 16); DQN_ASSERT(dqn_darray_get_num_items(array) == 2); dqn_darray_remove_stable(array, 1); DQN_ASSERT(dqn_v2_equals(array[0], b)); DQN_ASSERT(dqn_darray_get_capacity(array) == 16); DQN_ASSERT(dqn_darray_get_num_items(array) == 1); dqn_darray_free(array); } { DQN_ASSERT(dqn_darray_clear(NULL) == false); DQN_ASSERT(dqn_darray_clear(NULL) == false); DQN_ASSERT(dqn_darray_free(NULL) == false); } printf("dqn_darray_test(): Completed successfully\n"); } void dqn_file_test() { // File i/o { DqnFile file = {}; DQN_ASSERT(dqn_file_open(".clang-format", &file)); DQN_ASSERT(file.size == 1320); u8 *buffer = (u8 *)calloc(1, (size_t)file.size * sizeof(u8)); DQN_ASSERT(dqn_file_read(file, buffer, (u32)file.size) == file.size); free(buffer); dqn_file_close(&file); DQN_ASSERT(!file.handle && file.size == 0); printf("dqn_file_test(): file_io: Completed successfully\n"); } { u32 numFiles; char **filelist = dqn_dir_read("*", &numFiles); printf("dqn_file_test(): dir_read: Display read files\n"); for (u32 i = 0; i < numFiles; i++) printf("dqn_file_test(): dir_read: %s\n", filelist[i]); dqn_dir_read_free(filelist, numFiles); printf("dqn_file_test(): dir_read: Completed successfully\n"); } printf("dqn_file_test(): Completed successfully\n"); } int main(void) { dqn_strings_test(); dqn_random_test(); dqn_math_test(); dqn_vec_test(); dqn_other_test(); dqn_darray_test(); dqn_file_test(); printf("\nPress 'Enter' Key to Exit\n"); getchar(); return 0; }