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Переход на версию 0.3: изменение подхода к именованию сущностей, добавление, изменение и удаление ряда функций

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Andrey Pokidov 2026-01-30 19:37:49 +07:00
parent d33daf4e2d
commit f7e41645fe
87 changed files with 4580 additions and 4051 deletions
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2
Geometry.workspace
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@ -4,9 +4,9 @@
<Project filename="basic-geometry-dev/basic-geometry-dev.cbp"> <Project filename="basic-geometry-dev/basic-geometry-dev.cbp">
<Depends filename="basic-geometry/basic-geometry.cbp" /> <Depends filename="basic-geometry/basic-geometry.cbp" />
</Project> </Project>
<Project filename="basic-geometry/basic-geometry.cbp" />
<Project filename="basic-geometry-test/basic-geometry-test.cbp"> <Project filename="basic-geometry-test/basic-geometry-test.cbp">
<Depends filename="basic-geometry/basic-geometry.cbp" /> <Depends filename="basic-geometry/basic-geometry.cbp" />
</Project> </Project>
<Project filename="basic-geometry/basic-geometry.cbp" />
</Workspace> </Workspace>
</CodeBlocks_workspace_file> </CodeBlocks_workspace_file>

2
README-Eng.md
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@ -8,7 +8,7 @@
Programming language: C (C99) Programming language: C (C99)
Version: 0.2.0-dev Version: 0.3.0-dev
License: Apache-2.0 License: Apache-2.0

2
README.md
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@ -10,7 +10,7 @@
Язык программирования: Си (C99) Язык программирования: Си (C99)
Версия: 0.2.0-dev Версия: 0.3.0-dev
Лицензия: Apache-2.0 Лицензия: Apache-2.0

32
basic-geometry-dev/affine3.c
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@ -9,16 +9,16 @@
#include <time.h> #include <time.h>
#endif // _WINDOWS_ #endif // _WINDOWS_
BgcAffine3FP32* _create_bgc_affine3_list(int affine_amount) BGC_FP32_Affine3* _create_bgc_affine3_list(int affine_amount)
{ {
BgcAffine3FP32* affines = malloc(affine_amount * sizeof(BgcAffine3FP32)); BGC_FP32_Affine3* affines = malloc(affine_amount * sizeof(BGC_FP32_Affine3));
if (affines == 0) { if (affines == 0) {
return 0; return 0;
} }
for (int i = 0; i < affine_amount; i++) { for (int i = 0; i < affine_amount; i++) {
bgc_affine3_reset_fp32(&affines[i]); bgc_fp32_affine3_reset(&affines[i]);
} }
return affines; return affines;
@ -29,18 +29,18 @@ float get_random_value_fp32()
return rand() * (2.0f / RAND_MAX) - 1.0f; return rand() * (2.0f / RAND_MAX) - 1.0f;
} }
BgcAffine3FP32* _create_bgc_affine3_random_list(int affine_amount) BGC_FP32_Affine3* _create_bgc_affine3_random_list(int affine_amount)
{ {
BgcAffine3FP32* affines = malloc(affine_amount * sizeof(BgcAffine3FP32)); BGC_FP32_Affine3* affines = malloc(affine_amount * sizeof(BGC_FP32_Affine3));
if (affines == 0) { if (affines == 0) {
return 0; return 0;
} }
BgcPosition3FP32 position; BGC_FP32_Position3 position;
for (int i = 0; i < affine_amount; i++) { for (int i = 0; i < affine_amount; i++) {
bgc_versor_set_values_fp32( bgc_fp32_versor_make(
get_random_value_fp32(), get_random_value_fp32(),
get_random_value_fp32(), get_random_value_fp32(),
get_random_value_fp32(), get_random_value_fp32(),
@ -52,20 +52,20 @@ BgcAffine3FP32* _create_bgc_affine3_random_list(int affine_amount)
position.shift.x2 = get_random_value_fp32(); position.shift.x2 = get_random_value_fp32();
position.shift.x3 = get_random_value_fp32(); position.shift.x3 = get_random_value_fp32();
bgc_position3_get_outward_affine_fp32(&position, &affines[i]); bgc_fp32_position3_get_outward_affine(&position, &affines[i]);
} }
return affines; return affines;
} }
BgcVector3FP32* _create_bgc_vector3_list(int amount) BGC_FP32_Vector3* _create_bgc_vector3_list(int amount)
{ {
return malloc(amount * sizeof(BgcVector3FP32)); return malloc(amount * sizeof(BGC_FP32_Vector3));
} }
BgcVector3FP32* _create_bgc_vector3_random_list(int amount) BGC_FP32_Vector3* _create_bgc_vector3_random_list(int amount)
{ {
BgcVector3FP32* vectors = _create_bgc_vector3_list(amount); BGC_FP32_Vector3* vectors = _create_bgc_vector3_list(amount);
if (vectors == 0) { if (vectors == 0) {
return 0; return 0;
@ -82,9 +82,9 @@ BgcVector3FP32* _create_bgc_vector3_random_list(int amount)
float test_bgc_affine3_performance(int affine_amount, int vector_per_affine) float test_bgc_affine3_performance(int affine_amount, int vector_per_affine)
{ {
BgcAffine3FP32* affines; BGC_FP32_Affine3* affines;
BgcVector3FP32* source_vectors; BGC_FP32_Vector3* source_vectors;
BgcVector3FP32* result_vectors; BGC_FP32_Vector3* result_vectors;
int vector_index = 0; int vector_index = 0;
float time = -1.0f; float time = -1.0f;
@ -131,7 +131,7 @@ float test_bgc_affine3_performance(int affine_amount, int vector_per_affine)
for (int i = 0; i < affine_amount; i++) for (int i = 0; i < affine_amount; i++)
{ {
for (int j = 0; j < vector_per_affine; j++) { for (int j = 0; j < vector_per_affine; j++) {
bgc_affine3_transform_point_fp32(&affines[i], &source_vectors[vector_index], &result_vectors[vector_index]); bgc_fp32_affine3_transform_point(&affines[i], &source_vectors[vector_index], &result_vectors[vector_index]);
vector_index++; vector_index++;
} }
} }

312
basic-geometry-dev/main.c
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@ -10,7 +10,7 @@
#endif // _WINDOWS_ #endif // _WINDOWS_
typedef struct { typedef struct {
BgcVersorFP32 versor1, versor2, result; BGC_FP32_Versor versor1, versor2, result;
} structure_fp32_t; } structure_fp32_t;
structure_fp32_t* allocate_structures(const unsigned int amount) structure_fp32_t* allocate_structures(const unsigned int amount)
@ -29,7 +29,7 @@ structure_fp32_t* make_structures(const unsigned int amount)
const float multiplier = 2.0f / RAND_MAX; const float multiplier = 2.0f / RAND_MAX;
for (unsigned int i = 0; i < amount; i++) { for (unsigned int i = 0; i < amount; i++) {
bgc_versor_set_values_fp32( bgc_fp32_versor_make(
rand() * multiplier - 1.0f, rand() * multiplier - 1.0f,
rand() * multiplier - 1.0f, rand() * multiplier - 1.0f,
rand() * multiplier - 1.0f, rand() * multiplier - 1.0f,
@ -37,7 +37,7 @@ structure_fp32_t* make_structures(const unsigned int amount)
&list[i].versor1 &list[i].versor1
); );
bgc_versor_set_values_fp32( bgc_fp32_versor_make(
rand() * multiplier - 1.0f, rand() * multiplier - 1.0f,
rand() * multiplier - 1.0f, rand() * multiplier - 1.0f,
rand() * multiplier - 1.0f, rand() * multiplier - 1.0f,
@ -45,37 +45,37 @@ structure_fp32_t* make_structures(const unsigned int amount)
&list[i].versor2 &list[i].versor2
); );
bgc_versor_reset_fp32(&list[i].result); bgc_fp32_versor_reset(&list[i].result);
} }
return list; return list;
} }
void print_versor_fp32(const BgcVersorFP32* versor) void print_versor_fp32(const BGC_FP32_Versor* versor)
{ {
printf("Versor (s0 = %0.12f, x1 = %0.12f, x2 = %0.12f, x3 = %0.12f)\n", versor->_s0, versor->_x1, versor->_x2, versor->_x3); printf("Versor (s0 = %0.12f, x1 = %0.12f, x2 = %0.12f, x3 = %0.12f)\n", versor->_s0, versor->_x1, versor->_x2, versor->_x3);
} }
void print_versor_fp64(const BgcVersorFP64* versor) void print_versor_fp64(const BGC_FP64_Versor* versor)
{ {
printf("Versor (s0 = %0.20f, x1 = %0.20f, x2 = %0.20f, x3 = %0.20f)\n", versor->_s0, versor->_x1, versor->_x2, versor->_x3); printf("Versor (s0 = %0.20f, x1 = %0.20f, x2 = %0.20f, x3 = %0.20f)\n", versor->_s0, versor->_x1, versor->_x2, versor->_x3);
} }
void print_vector_fp32(const BgcVector3FP32* vector) void print_vector_fp32(const BGC_FP32_Vector3* vector)
{ {
printf("(%f, %f, %f) / %f\n", vector->x1, vector->x2, vector->x3, bgc_vector3_get_modulus_fp32(vector)); printf("(%f, %f, %f) / %f\n", vector->x1, vector->x2, vector->x3, bgc_fp32_vector3_get_modulus(vector));
} }
void print_vector_fp64(const BgcVector3FP64* vector) void print_vector_fp64(const BGC_FP64_Vector3* vector)
{ {
printf("(%lf, %lf, %lf) / %lf\n", vector->x1, vector->x2, vector->x3, bgc_vector3_get_modulus_fp64(vector)); printf("(%lf, %lf, %lf) / %lf\n", vector->x1, vector->x2, vector->x3, bgc_fp64_vector3_get_modulus(vector));
} }
void list_work(const uint_fast32_t amount, structure_fp32_t* list) void list_work(const uint_fast32_t amount, structure_fp32_t* list)
{ {
for (uint_fast32_t j = 0; j < 1000; j++) { for (uint_fast32_t j = 0; j < 1000; j++) {
for (uint_fast32_t i = 0; i < amount; i++) { for (uint_fast32_t i = 0; i < amount; i++) {
bgc_versor_combine_fp32(&list[i].versor1, &list[i].versor1, &list[i].result); bgc_fp32_versor_combine(&list[i].versor1, &list[i].versor1, &list[i].result);
} }
} }
} }
@ -125,13 +125,13 @@ int main()
/* /*
int main() { int main() {
BgcComplexFP32 complex, exponent, result; BGC_FP32_Complex complex, exponent, result;
bgc_complex_set_values_fp32(0, 1, &complex); bgc_fp32_complex_make(0, 1, &complex);
bgc_complex_set_values_fp32(4, 0, &exponent); bgc_fp32_complex_make(4, 0, &exponent);
bgc_complex_get_exponation_fp32(&complex, exponent.real, exponent.imaginary, &result); bgc_fp32_complex_get_exponation(&complex, exponent.real, exponent.imaginary, &result);
printf("(%f, %f) ^ (%f, %f) = (%f, %f)\n", complex.real, complex.imaginary, exponent.real, exponent.imaginary, result.real, result.imaginary); printf("(%f, %f) ^ (%f, %f) = (%f, %f)\n", complex.real, complex.imaginary, exponent.real, exponent.imaginary, result.real, result.imaginary);
@ -140,10 +140,10 @@ int main() {
*/ */
/* /*
int main() { int main() {
BgcVersorFP32 start = { 1.0f, 0.0f, 0.0f, 0.0f }; BGC_FP32_Versor start = { 1.0f, 0.0f, 0.0f, 0.0f };
BgcVersorFP32 end = { 0.0f, 1.0f, 0.0f, 0.0f }; BGC_FP32_Versor end = { 0.0f, 1.0f, 0.0f, 0.0f };
BgcVersorFP32 result; BGC_FP32_Versor result;
bgc_versor_spherical_interpolation_fp32(&start, &end, 0.5f, &result); bgc_fp32_versor_spherical_interpolation(&start, &end, 0.5f, &result);
printf("Result: %0.12f, %0.12f, %0.12f, %0.12f\n", result.s0, result.x1, result.x2, result.x3); printf("Result: %0.12f, %0.12f, %0.12f, %0.12f\n", result.s0, result.x1, result.x2, result.x3);
return 0; return 0;
} }
@ -152,79 +152,79 @@ int main() {
void test_basis_difference_fp32() void test_basis_difference_fp32()
{ {
BgcVector3FP32 initial_primary, initial_auxiliary; BGC_FP32_Vector3 initial_primary, initial_auxiliary;
BgcVector3FP32 final_primary, final_auxiliary; BGC_FP32_Vector3 final_primary, final_auxiliary;
BgcVersorFP32 turn; BGC_FP32_Versor turn;
// No turn // No turn
bgc_vector3_set_values_fp32(1.0f, 0.0f, 0.0f, &initial_primary); bgc_fp32_vector3_make(1.0f, 0.0f, 0.0f, &initial_primary);
bgc_vector3_set_values_fp32(0.0f, 1.0f, 0.0f, &initial_auxiliary); bgc_fp32_vector3_make(0.0f, 1.0f, 0.0f, &initial_auxiliary);
bgc_vector3_set_values_fp32(1.0f, 0.0f, 0.0f, &final_primary); bgc_fp32_vector3_make(1.0f, 0.0f, 0.0f, &final_primary);
bgc_vector3_set_values_fp32(0.0f, 1.0f, 0.0f, &final_auxiliary); bgc_fp32_vector3_make(0.0f, 1.0f, 0.0f, &final_auxiliary);
bgc_versor_make_basis_difference_fp32(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp32_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\nNo turn:\n"); printf("\nNo turn:\n");
print_versor_fp32(&turn); print_versor_fp32(&turn);
// Turn around (1, 1, 0) axis on 180 degrees // Turn around (1, 1, 0) axis on 180 degrees
bgc_vector3_set_values_fp32(1.0f, 0.0f, 0.0f, &initial_primary); bgc_fp32_vector3_make(1.0f, 0.0f, 0.0f, &initial_primary);
bgc_vector3_set_values_fp32(0.0f, 1.0f, 0.0f, &initial_auxiliary); bgc_fp32_vector3_make(0.0f, 1.0f, 0.0f, &initial_auxiliary);
bgc_vector3_set_values_fp32(0.0f, 1.0f, 0.0f, &final_primary); bgc_fp32_vector3_make(0.0f, 1.0f, 0.0f, &final_primary);
bgc_vector3_set_values_fp32(1.0f, 0.0f, 0.0f, &final_auxiliary); bgc_fp32_vector3_make(1.0f, 0.0f, 0.0f, &final_auxiliary);
bgc_versor_make_basis_difference_fp32(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp32_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\nTurn around (1, 1, 0) axis on 180 degrees:\n"); printf("\nTurn around (1, 1, 0) axis on 180 degrees:\n");
print_versor_fp32(&turn); print_versor_fp32(&turn);
// 180 degree turn // 180 degree turn
bgc_vector3_set_values_fp32(1.0f, 0.0f, 0.0f, &initial_primary); bgc_fp32_vector3_make(1.0f, 0.0f, 0.0f, &initial_primary);
bgc_vector3_set_values_fp32(0.0f, 1.0f, 0.0f, &initial_auxiliary); bgc_fp32_vector3_make(0.0f, 1.0f, 0.0f, &initial_auxiliary);
bgc_vector3_set_values_fp32(-1.0f, 0.0f, 0.0f, &final_primary); bgc_fp32_vector3_make(-1.0f, 0.0f, 0.0f, &final_primary);
bgc_vector3_set_values_fp32(0.0f, 1.0f, 0.0f, &final_auxiliary); bgc_fp32_vector3_make(0.0f, 1.0f, 0.0f, &final_auxiliary);
bgc_versor_make_basis_difference_fp32(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp32_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\n180 degree turn around (0, 1, 0):\n"); printf("\n180 degree turn around (0, 1, 0):\n");
print_versor_fp32(&turn); print_versor_fp32(&turn);
// 90 degree turn around x3 axis // 90 degree turn around x3 axis
bgc_vector3_set_values_fp32(2.0f, 0.0f, 0.0f, &initial_primary); bgc_fp32_vector3_make(2.0f, 0.0f, 0.0f, &initial_primary);
bgc_vector3_set_values_fp32(0.0f, 3.1f, 0.0f, &initial_auxiliary); bgc_fp32_vector3_make(0.0f, 3.1f, 0.0f, &initial_auxiliary);
bgc_vector3_set_values_fp32(0.0f, 10.0f, 0.0f, &final_primary); bgc_fp32_vector3_make(0.0f, 10.0f, 0.0f, &final_primary);
bgc_vector3_set_values_fp32(-1.0f, 0.0f, 0.0f, &final_auxiliary); bgc_fp32_vector3_make(-1.0f, 0.0f, 0.0f, &final_auxiliary);
bgc_versor_make_basis_difference_fp32(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp32_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\n90 degree turn around (0, 0, 1):\n"); printf("\n90 degree turn around (0, 0, 1):\n");
print_versor_fp32(&turn); print_versor_fp32(&turn);
// Unorthogonal pairs turn at 90 degrees around x3 axis // Unorthogonal pairs turn at 90 degrees around x3 axis
bgc_vector3_set_values_fp32(2.0f, 0.0f, 0.0f, &initial_primary); bgc_fp32_vector3_make(2.0f, 0.0f, 0.0f, &initial_primary);
bgc_vector3_set_values_fp32(-2.0f, 3.1f, 0.0f, &initial_auxiliary); bgc_fp32_vector3_make(-2.0f, 3.1f, 0.0f, &initial_auxiliary);
bgc_vector3_set_values_fp32(0.0f, 10.0f, 0.0f, &final_primary); bgc_fp32_vector3_make(0.0f, 10.0f, 0.0f, &final_primary);
bgc_vector3_set_values_fp32(-1.0f, 5.0f, 0.0f, &final_auxiliary); bgc_fp32_vector3_make(-1.0f, 5.0f, 0.0f, &final_auxiliary);
bgc_versor_make_basis_difference_fp32(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp32_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\nUnorthogonal pairs turn at 90 degrees around (0, 0, 1):\n"); printf("\nUnorthogonal pairs turn at 90 degrees around (0, 0, 1):\n");
print_versor_fp32(&turn); print_versor_fp32(&turn);
// Zero vectors // Zero vectors
bgc_vector3_set_values_fp32(0.0f, 0.0f, 0.0f, &initial_primary); bgc_fp32_vector3_make(0.0f, 0.0f, 0.0f, &initial_primary);
bgc_vector3_set_values_fp32(0.0f, 1.0f, 0.0f, &initial_auxiliary); bgc_fp32_vector3_make(0.0f, 1.0f, 0.0f, &initial_auxiliary);
bgc_vector3_set_values_fp32(1.0f, 0.0f, 0.0f, &final_primary); bgc_fp32_vector3_make(1.0f, 0.0f, 0.0f, &final_primary);
bgc_vector3_set_values_fp32(0.0f, 1.0f, 0.0f, &final_auxiliary); bgc_fp32_vector3_make(0.0f, 1.0f, 0.0f, &final_auxiliary);
int code; int code;
code = bgc_versor_make_basis_difference_fp32(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); code = bgc_fp32_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
if (code >= 0) { if (code >= 0) {
printf("\nZero vectors: this cannot be!\n"); printf("\nZero vectors: this cannot be!\n");
@ -235,12 +235,12 @@ void test_basis_difference_fp32()
} }
// Parallel vectors // Parallel vectors
bgc_vector3_set_values_fp32(1.0f, 0.0f, 0.0f, &initial_primary); bgc_fp32_vector3_make(1.0f, 0.0f, 0.0f, &initial_primary);
bgc_vector3_set_values_fp32(2.0f, 0.0f, 0.0f, &initial_auxiliary); bgc_fp32_vector3_make(2.0f, 0.0f, 0.0f, &initial_auxiliary);
bgc_vector3_set_values_fp32(1.0f, 0.0f, 0.0f, &final_primary); bgc_fp32_vector3_make(1.0f, 0.0f, 0.0f, &final_primary);
bgc_vector3_set_values_fp32(0.0f, 1.0f, 0.0f, &final_auxiliary); bgc_fp32_vector3_make(0.0f, 1.0f, 0.0f, &final_auxiliary);
code = bgc_versor_make_basis_difference_fp32(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); code = bgc_fp32_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
if (code >= 0) { if (code >= 0) {
printf("\nParallel vectors: this cannot be!\n"); printf("\nParallel vectors: this cannot be!\n");
@ -251,60 +251,60 @@ void test_basis_difference_fp32()
} }
// Small angle turn (about 1 degree): // Small angle turn (about 1 degree):
bgc_vector3_set_values_fp32(1.0f, 0.0f, 0.0f, &initial_primary); bgc_fp32_vector3_make(1.0f, 0.0f, 0.0f, &initial_primary);
bgc_vector3_set_values_fp32(0.0f, 1.0f, 0.0f, &initial_auxiliary); bgc_fp32_vector3_make(0.0f, 1.0f, 0.0f, &initial_auxiliary);
bgc_vector3_set_values_fp32(0.999848f, 0.017452f, 0.0f, &final_primary); bgc_fp32_vector3_make(0.999848f, 0.017452f, 0.0f, &final_primary);
bgc_vector3_set_values_fp32(-0.017452f, 0.999848f, 0.0f, &final_auxiliary); bgc_fp32_vector3_make(-0.017452f, 0.999848f, 0.0f, &final_auxiliary);
bgc_versor_make_basis_difference_fp32(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp32_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\nSmall angle turn (about 1 degree):\n"); printf("\nSmall angle turn (about 1 degree):\n");
print_versor_fp32(&turn); print_versor_fp32(&turn);
// About 179 degrees turn // About 179 degrees turn
bgc_vector3_set_values_fp32(1.0f, 0.0f, 0.0f, &initial_primary); bgc_fp32_vector3_make(1.0f, 0.0f, 0.0f, &initial_primary);
bgc_vector3_set_values_fp32(0.0f, 1.0f, 0.0f, &initial_auxiliary); bgc_fp32_vector3_make(0.0f, 1.0f, 0.0f, &initial_auxiliary);
bgc_vector3_set_values_fp32(-0.999848f, -0.017452f, 0.0f, &final_primary); bgc_fp32_vector3_make(-0.999848f, -0.017452f, 0.0f, &final_primary);
bgc_vector3_set_values_fp32(0.017452f, -0.999848f, 0.0f, &final_auxiliary); bgc_fp32_vector3_make(0.017452f, -0.999848f, 0.0f, &final_auxiliary);
bgc_versor_make_basis_difference_fp32(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp32_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\nAbout 179 degrees turn:\n"); printf("\nAbout 179 degrees turn:\n");
print_versor_fp32(&turn); print_versor_fp32(&turn);
// 120 degrees around (-1, -1, 1) // 120 degrees around (-1, -1, 1)
bgc_vector3_set_values_fp32(1.0f, 0.0f, 0.0f, &initial_primary); bgc_fp32_vector3_make(1.0f, 0.0f, 0.0f, &initial_primary);
bgc_vector3_set_values_fp32(0.0f, 1.0f, 0.0f, &initial_auxiliary); bgc_fp32_vector3_make(0.0f, 1.0f, 0.0f, &initial_auxiliary);
bgc_vector3_set_values_fp32(0.0f, 1.0f, 0.0f, &final_primary); bgc_fp32_vector3_make(0.0f, 1.0f, 0.0f, &final_primary);
bgc_vector3_set_values_fp32(0.0f, 0.0f, -1.0f, &final_auxiliary); bgc_fp32_vector3_make(0.0f, 0.0f, -1.0f, &final_auxiliary);
bgc_versor_make_basis_difference_fp32(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp32_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\n120 degees turn:\n"); printf("\n120 degees turn:\n");
print_versor_fp32(&turn); print_versor_fp32(&turn);
// About 1 degree turn difference between initial_primary and initial_auxiliary directions // About 1 degree turn difference between initial_primary and initial_auxiliary directions
bgc_vector3_set_values_fp32(1.0f, 0.0f, 0.0f, &initial_primary); bgc_fp32_vector3_make(1.0f, 0.0f, 0.0f, &initial_primary);
bgc_vector3_set_values_fp32(0.999848f, 0.017452f, 0.0f, &initial_auxiliary); bgc_fp32_vector3_make(0.999848f, 0.017452f, 0.0f, &initial_auxiliary);
bgc_vector3_set_values_fp32(0.0f, 1.0f, 0.0f, &final_primary); bgc_fp32_vector3_make(0.0f, 1.0f, 0.0f, &final_primary);
bgc_vector3_set_values_fp32(-1.0f, 0.0f, 0.0f, &final_auxiliary); bgc_fp32_vector3_make(-1.0f, 0.0f, 0.0f, &final_auxiliary);
bgc_versor_make_basis_difference_fp32(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp32_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\nAbout 1 degree turn difference between initial_primary and initial_auxiliary directions:\n"); printf("\nAbout 1 degree turn difference between initial_primary and initial_auxiliary directions:\n");
print_versor_fp32(&turn); print_versor_fp32(&turn);
// About 0.01 degree turn difference between initial_primary and initial_auxiliary directions // About 0.01 degree turn difference between initial_primary and initial_auxiliary directions
bgc_vector3_set_values_fp32(1.0f, 0.0f, 0.0f, &initial_primary); bgc_fp32_vector3_make(1.0f, 0.0f, 0.0f, &initial_primary);
bgc_vector3_set_values_fp32(1.0f, 0.000001f, 0.0f, &initial_auxiliary); bgc_fp32_vector3_make(1.0f, 0.000001f, 0.0f, &initial_auxiliary);
bgc_vector3_set_values_fp32(0.0f, -1.0f, 0.0f, &final_primary); bgc_fp32_vector3_make(0.0f, -1.0f, 0.0f, &final_primary);
bgc_vector3_set_values_fp32(1.0f, 0.0f, 0.0f, &final_auxiliary); bgc_fp32_vector3_make(1.0f, 0.0f, 0.0f, &final_auxiliary);
bgc_versor_make_basis_difference_fp32(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp32_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\nAbout 0.01 degree turn difference between initial_primary and initial_auxiliary directions:\n"); printf("\nAbout 0.01 degree turn difference between initial_primary and initial_auxiliary directions:\n");
print_versor_fp32(&turn); print_versor_fp32(&turn);
@ -313,77 +313,77 @@ void test_basis_difference_fp32()
void test_basis_difference_fp64() void test_basis_difference_fp64()
{ {
BgcVector3FP64 initial_primary, initial_auxiliary; BGC_FP64_Vector3 initial_primary, initial_auxiliary;
BgcVector3FP64 final_primary, final_auxiliary; BGC_FP64_Vector3 final_primary, final_auxiliary;
BgcVersorFP64 turn; BGC_FP64_Versor turn;
// No turn // No turn
bgc_vector3_set_values_fp64(1.0, 0.0, 0.0, &initial_primary); bgc_fp64_vector3_make(1.0, 0.0, 0.0, &initial_primary);
bgc_vector3_set_values_fp64(0.0, 1.0, 0.0, &initial_auxiliary); bgc_fp64_vector3_make(0.0, 1.0, 0.0, &initial_auxiliary);
bgc_vector3_set_values_fp64(1.0, 0.0, 0.0, &final_primary); bgc_fp64_vector3_make(1.0, 0.0, 0.0, &final_primary);
bgc_vector3_set_values_fp64(0.0, 1.0, 0.0, &final_auxiliary); bgc_fp64_vector3_make(0.0, 1.0, 0.0, &final_auxiliary);
bgc_versor_make_basis_difference_fp64(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp64_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\nNo turn:\n"); printf("\nNo turn:\n");
print_versor_fp64(&turn); print_versor_fp64(&turn);
// Turn around (1, 1, 0) axis on 180 degrees // Turn around (1, 1, 0) axis on 180 degrees
bgc_vector3_set_values_fp64(1.0, 0.0, 0.0, &initial_primary); bgc_fp64_vector3_make(1.0, 0.0, 0.0, &initial_primary);
bgc_vector3_set_values_fp64(0.0, 1.0, 0.0, &initial_auxiliary); bgc_fp64_vector3_make(0.0, 1.0, 0.0, &initial_auxiliary);
bgc_vector3_set_values_fp64(0.0, 1.0, 0.0, &final_primary); bgc_fp64_vector3_make(0.0, 1.0, 0.0, &final_primary);
bgc_vector3_set_values_fp64(1.0, 0.0, 0.0, &final_auxiliary); bgc_fp64_vector3_make(1.0, 0.0, 0.0, &final_auxiliary);
bgc_versor_make_basis_difference_fp64(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp64_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\nTurn around (1, 1, 0) axis on 180 degrees:\n"); printf("\nTurn around (1, 1, 0) axis on 180 degrees:\n");
print_versor_fp64(&turn); print_versor_fp64(&turn);
// 180 degree turn // 180 degree turn
bgc_vector3_set_values_fp64(1.0, 0.0, 0.0, &initial_primary); bgc_fp64_vector3_make(1.0, 0.0, 0.0, &initial_primary);
bgc_vector3_set_values_fp64(0.0, 1.0, 0.0, &initial_auxiliary); bgc_fp64_vector3_make(0.0, 1.0, 0.0, &initial_auxiliary);
bgc_vector3_set_values_fp64(-1.0, 0.0, 0.0, &final_primary); bgc_fp64_vector3_make(-1.0, 0.0, 0.0, &final_primary);
bgc_vector3_set_values_fp64(0.0, 1.0, 0.0, &final_auxiliary); bgc_fp64_vector3_make(0.0, 1.0, 0.0, &final_auxiliary);
bgc_versor_make_basis_difference_fp64(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp64_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\n180 degree turn around (0, 1, 0):\n"); printf("\n180 degree turn around (0, 1, 0):\n");
print_versor_fp64(&turn); print_versor_fp64(&turn);
// 90 degree turn around x3 axis // 90 degree turn around x3 axis
bgc_vector3_set_values_fp64(2.0, 0.0, 0.0, &initial_primary); bgc_fp64_vector3_make(2.0, 0.0, 0.0, &initial_primary);
bgc_vector3_set_values_fp64(0.0, 3.1, 0.0, &initial_auxiliary); bgc_fp64_vector3_make(0.0, 3.1, 0.0, &initial_auxiliary);
bgc_vector3_set_values_fp64(0.0, 10.0, 0.0, &final_primary); bgc_fp64_vector3_make(0.0, 10.0, 0.0, &final_primary);
bgc_vector3_set_values_fp64(-1.0, 0.0, 0.0, &final_auxiliary); bgc_fp64_vector3_make(-1.0, 0.0, 0.0, &final_auxiliary);
bgc_versor_make_basis_difference_fp64(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp64_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\n90 degree turn around (0, 0, 1):\n"); printf("\n90 degree turn around (0, 0, 1):\n");
print_versor_fp64(&turn); print_versor_fp64(&turn);
// Unorthogonal pairs turn at 90 degrees around x3 axis // Unorthogonal pairs turn at 90 degrees around x3 axis
bgc_vector3_set_values_fp64(2.0, 0.0, 0.0, &initial_primary); bgc_fp64_vector3_make(2.0, 0.0, 0.0, &initial_primary);
bgc_vector3_set_values_fp64(-2.0, 3.1, 0.0, &initial_auxiliary); bgc_fp64_vector3_make(-2.0, 3.1, 0.0, &initial_auxiliary);
bgc_vector3_set_values_fp64(0.0, 10.0, 0.0, &final_primary); bgc_fp64_vector3_make(0.0, 10.0, 0.0, &final_primary);
bgc_vector3_set_values_fp64(-1.0, 5.0, 0.0, &final_auxiliary); bgc_fp64_vector3_make(-1.0, 5.0, 0.0, &final_auxiliary);
bgc_versor_make_basis_difference_fp64(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp64_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\nUnorthogonal pairs turn at 90 degrees around (0, 0, 1):\n"); printf("\nUnorthogonal pairs turn at 90 degrees around (0, 0, 1):\n");
print_versor_fp64(&turn); print_versor_fp64(&turn);
// Zero vectors // Zero vectors
bgc_vector3_set_values_fp64(0.0, 0.0, 0.0, &initial_primary); bgc_fp64_vector3_make(0.0, 0.0, 0.0, &initial_primary);
bgc_vector3_set_values_fp64(0.0, 1.0, 0.0, &initial_auxiliary); bgc_fp64_vector3_make(0.0, 1.0, 0.0, &initial_auxiliary);
bgc_vector3_set_values_fp64(1.0, 0.0, 0.0, &final_primary); bgc_fp64_vector3_make(1.0, 0.0, 0.0, &final_primary);
bgc_vector3_set_values_fp64(0.0, 1.0, 0.0, &final_auxiliary); bgc_fp64_vector3_make(0.0, 1.0, 0.0, &final_auxiliary);
int code; int code;
code = bgc_versor_make_basis_difference_fp64(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); code = bgc_fp64_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
if (code >= 0) { if (code >= 0) {
printf("\nZero vectors: this cannot be!\n"); printf("\nZero vectors: this cannot be!\n");
@ -394,12 +394,12 @@ void test_basis_difference_fp64()
} }
// Parallel vectors // Parallel vectors
bgc_vector3_set_values_fp64(1.0, 0.0, 0.0, &initial_primary); bgc_fp64_vector3_make(1.0, 0.0, 0.0, &initial_primary);
bgc_vector3_set_values_fp64(2.0, 0.0, 0.0, &initial_auxiliary); bgc_fp64_vector3_make(2.0, 0.0, 0.0, &initial_auxiliary);
bgc_vector3_set_values_fp64(1.0, 0.0, 0.0, &final_primary); bgc_fp64_vector3_make(1.0, 0.0, 0.0, &final_primary);
bgc_vector3_set_values_fp64(0.0, 1.0, 0.0, &final_auxiliary); bgc_fp64_vector3_make(0.0, 1.0, 0.0, &final_auxiliary);
code = bgc_versor_make_basis_difference_fp64(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); code = bgc_fp64_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
if (code >= 0) { if (code >= 0) {
printf("\nParallel vectors: this cannot be!\n"); printf("\nParallel vectors: this cannot be!\n");
@ -410,60 +410,60 @@ void test_basis_difference_fp64()
} }
// Small angle turn (about 1 degree): // Small angle turn (about 1 degree):
bgc_vector3_set_values_fp64(1.0, 0.0, 0.0, &initial_primary); bgc_fp64_vector3_make(1.0, 0.0, 0.0, &initial_primary);
bgc_vector3_set_values_fp64(0.0, 1.0, 0.0, &initial_auxiliary); bgc_fp64_vector3_make(0.0, 1.0, 0.0, &initial_auxiliary);
bgc_vector3_set_values_fp64(0.999848, 0.017452, 0.0, &final_primary); bgc_fp64_vector3_make(0.999848, 0.017452, 0.0, &final_primary);
bgc_vector3_set_values_fp64(-0.017452, 0.999848, 0.0, &final_auxiliary); bgc_fp64_vector3_make(-0.017452, 0.999848, 0.0, &final_auxiliary);
bgc_versor_make_basis_difference_fp64(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp64_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\nSmall angle turn (about 1 degree):\n"); printf("\nSmall angle turn (about 1 degree):\n");
print_versor_fp64(&turn); print_versor_fp64(&turn);
// About 179 degrees turn // About 179 degrees turn
bgc_vector3_set_values_fp64(1.0, 0.0, 0.0, &initial_primary); bgc_fp64_vector3_make(1.0, 0.0, 0.0, &initial_primary);
bgc_vector3_set_values_fp64(0.0, 1.0, 0.0, &initial_auxiliary); bgc_fp64_vector3_make(0.0, 1.0, 0.0, &initial_auxiliary);
bgc_vector3_set_values_fp64(-0.999848, -0.017452, 0.0, &final_primary); bgc_fp64_vector3_make(-0.999848, -0.017452, 0.0, &final_primary);
bgc_vector3_set_values_fp64(0.017452, -0.999848, 0.0, &final_auxiliary); bgc_fp64_vector3_make(0.017452, -0.999848, 0.0, &final_auxiliary);
bgc_versor_make_basis_difference_fp64(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp64_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\nAbout 179 degrees turn:\n"); printf("\nAbout 179 degrees turn:\n");
print_versor_fp64(&turn); print_versor_fp64(&turn);
// 120 degrees around (-1, -1, 1) // 120 degrees around (-1, -1, 1)
bgc_vector3_set_values_fp64(1.0, 0.0, 0.0, &initial_primary); bgc_fp64_vector3_make(1.0, 0.0, 0.0, &initial_primary);
bgc_vector3_set_values_fp64(0.0, 1.0, 0.0, &initial_auxiliary); bgc_fp64_vector3_make(0.0, 1.0, 0.0, &initial_auxiliary);
bgc_vector3_set_values_fp64(0.0, 1.0, 0.0, &final_primary); bgc_fp64_vector3_make(0.0, 1.0, 0.0, &final_primary);
bgc_vector3_set_values_fp64(0.0, 0.0, -1.0, &final_auxiliary); bgc_fp64_vector3_make(0.0, 0.0, -1.0, &final_auxiliary);
bgc_versor_make_basis_difference_fp64(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp64_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\n120 degees turn:\n"); printf("\n120 degees turn:\n");
print_versor_fp64(&turn); print_versor_fp64(&turn);
// About 1 degree turn difference between initial_primary and initial_auxiliary directions // About 1 degree turn difference between initial_primary and initial_auxiliary directions
bgc_vector3_set_values_fp64(1.0, 0.0, 0.0, &initial_primary); bgc_fp64_vector3_make(1.0, 0.0, 0.0, &initial_primary);
bgc_vector3_set_values_fp64(0.999848, 0.017452, 0.0, &initial_auxiliary); bgc_fp64_vector3_make(0.999848, 0.017452, 0.0, &initial_auxiliary);
bgc_vector3_set_values_fp64(0.0, 1.0, 0.0, &final_primary); bgc_fp64_vector3_make(0.0, 1.0, 0.0, &final_primary);
bgc_vector3_set_values_fp64(-1.0, 0.0, 0.0, &final_auxiliary); bgc_fp64_vector3_make(-1.0, 0.0, 0.0, &final_auxiliary);
bgc_versor_make_basis_difference_fp64(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp64_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\nAbout 1 degree turn difference between initial_primary and initial_auxiliary directions:\n"); printf("\nAbout 1 degree turn difference between initial_primary and initial_auxiliary directions:\n");
print_versor_fp64(&turn); print_versor_fp64(&turn);
// About 0.001 degree turn difference between initial_primary and initial_auxiliary directions // About 0.001 degree turn difference between initial_primary and initial_auxiliary directions
bgc_vector3_set_values_fp64(1.0, 0.0, 0.0, &initial_primary); bgc_fp64_vector3_make(1.0, 0.0, 0.0, &initial_primary);
bgc_vector3_set_values_fp64(1.0, 0.000001, 0.0, &initial_auxiliary); bgc_fp64_vector3_make(1.0, 0.000001, 0.0, &initial_auxiliary);
bgc_vector3_set_values_fp64(0.0, -1.0, 0.0, &final_primary); bgc_fp64_vector3_make(0.0, -1.0, 0.0, &final_primary);
bgc_vector3_set_values_fp64(1.0, 0.0, 0.0, &final_auxiliary); bgc_fp64_vector3_make(1.0, 0.0, 0.0, &final_auxiliary);
bgc_versor_make_basis_difference_fp64(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn); bgc_fp64_versor_make_basis_difference(&initial_primary, &initial_auxiliary, &final_primary, &final_auxiliary, &turn);
printf("\nAbout 0.01 degree turn difference between initial_primary and initial_auxiliary directions:\n"); printf("\nAbout 0.01 degree turn difference between initial_primary and initial_auxiliary directions:\n");
print_versor_fp64(&turn); print_versor_fp64(&turn);
@ -473,15 +473,15 @@ void test_basis_difference_fp64()
int main() int main()
{ {
//BgcVersorFP32 start = { 1.0f, 0.0f, 0.0f, 0.0f }; //BGC_FP32_Versor start = { 1.0f, 0.0f, 0.0f, 0.0f };
//BgcVersorFP32 end = { 0.0f, 1.0f, 0.0f, 0.0f }; //BGC_FP32_Versor end = { 0.0f, 1.0f, 0.0f, 0.0f };
/* /*
BgcVersorFP32 start = { 1.0f, 0.0f, 0.0f, 0.0f }; BGC_FP32_Versor start = { 1.0f, 0.0f, 0.0f, 0.0f };
BgcVersorFP32 end = { 0.9999f, 0.01414f, 0.0f, 0.0f }; BGC_FP32_Versor end = { 0.9999f, 0.01414f, 0.0f, 0.0f };
BgcSlerpFP32 slerp; BGC_FP32_Slerp slerp;
BgcVersorFP32 result; BGC_FP32_Versor result;
bgc_slerp_make_full_fp32(&start, &end, &slerp); bgc_fp32_slerp_make_full(&start, &end, &slerp);
bgc_slerp_get_turn_for_phase_fp32(&slerp, 0.5f, &result); bgc_fp32_slerp_get_phase_versor(&slerp, 0.5f, &result);
print_versor_fp32(&result); print_versor_fp32(&result);
*/ */
@ -489,9 +489,9 @@ int main()
printf("Affine3 performance test: %f\n", test_bgc_affine3_performance(10000000, 10)); printf("Affine3 performance test: %f\n", test_bgc_affine3_performance(10000000, 10));
printf("sizeof(BgcAffine3FP32) = %zu\n", sizeof(BgcAffine3FP32)); printf("sizeof(BGC_FP32_Affine3) = %zu\n", sizeof(BGC_FP32_Affine3));
//printf("offsetof(shift) = %zu\n", offsetof(BgcAffine3FP32, shift)); //printf("offsetof(shift) = %zu\n", offsetof(BGC_FP32_Affine3, shift));
printf("sizeof(BgcMatrix3x3FP32) = %zu\n", sizeof(BgcMatrix3x3FP32)); printf("sizeof(BGC_FP32_Matrix3x3) = %zu\n", sizeof(BGC_FP32_Matrix3x3));
return 0; return 0;
} }

8
basic-geometry-test/helpers.h
View file

@ -25,19 +25,19 @@ typedef struct {
// =================== Versor =================== // // =================== Versor =================== //
typedef struct { typedef struct {
BgcVersorFP32 first, second; BGC_FP32_Versor first, second;
} TestVersorPairFP32; } TestVersorPairFP32;
typedef struct { typedef struct {
BgcVersorFP64 first, second; BGC_FP64_Versor first, second;
} TestVersorPairFP64; } TestVersorPairFP64;
typedef struct { typedef struct {
BgcVersorFP32 first, second, result; BGC_FP32_Versor first, second, result;
} TestVersorTripletFP32; } TestVersorTripletFP32;
typedef struct { typedef struct {
BgcVersorFP64 first, second, result; BGC_FP64_Versor first, second, result;
} TestVersorTripletFP64; } TestVersorTripletFP64;
// ================= Functions ================== // // ================= Functions ================== //

16
basic-geometry-test/tests/complex/complex_copy.c
View file

@ -7,7 +7,7 @@
// ==================== FP32 ==================== // // ==================== FP32 ==================== //
static const int _TEST_FP32_COMPLEX_AMOUNT = 4; static const int _TEST_FP32_COMPLEX_AMOUNT = 4;
static const BgcComplexFP32 _TEST_FP32_COMPLEX_LIST[] = { static const BGC_FP32_Complex _TEST_FP32_COMPLEX_LIST[] = {
{ 1.0f, 2.0f }, { 1.0f, 2.0f },
{ -4.0f, -3.0f }, { -4.0f, -3.0f },
{ -0.001f, 100.0f }, { -0.001f, 100.0f },
@ -16,13 +16,13 @@ static const BgcComplexFP32 _TEST_FP32_COMPLEX_LIST[] = {
void test_complex_copy_fp32() void test_complex_copy_fp32()
{ {
BgcComplexFP32 vector; BGC_FP32_Complex vector;
print_testing_name("bgc_complex_copy_fp32"); print_testing_name("bgc_fp32_complex_copy");
for (int i = 0; i < _TEST_FP32_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_COMPLEX_AMOUNT; i++) {
bgc_complex_copy_fp32(&_TEST_FP32_COMPLEX_LIST[i], &vector); bgc_fp32_complex_copy(&_TEST_FP32_COMPLEX_LIST[i], &vector);
if (vector.real != _TEST_FP32_COMPLEX_LIST[i].real || if (vector.real != _TEST_FP32_COMPLEX_LIST[i].real ||
vector.imaginary != _TEST_FP32_COMPLEX_LIST[i].imaginary) { vector.imaginary != _TEST_FP32_COMPLEX_LIST[i].imaginary) {
@ -37,7 +37,7 @@ void test_complex_copy_fp32()
// ==================== FP64 ==================== // // ==================== FP64 ==================== //
static const int _TEST_FP64_COMPLEX_AMOUNT = 4; static const int _TEST_FP64_COMPLEX_AMOUNT = 4;
static const BgcComplexFP64 _TEST_FP64_COMPLEX_LIST[] = { static const BGC_FP64_Complex _TEST_FP64_COMPLEX_LIST[] = {
{ 1.0, 2.0 }, { 1.0, 2.0 },
{ -4.0, -3.0 }, { -4.0, -3.0 },
{ -0.001, 100.0 }, { -0.001, 100.0 },
@ -46,13 +46,13 @@ static const BgcComplexFP64 _TEST_FP64_COMPLEX_LIST[] = {
void test_complex_copy_fp64() void test_complex_copy_fp64()
{ {
BgcComplexFP64 vector; BGC_FP64_Complex vector;
print_testing_name("bgc_complex_copy_fp64"); print_testing_name("bgc_fp64_complex_copy");
for (int i = 0; i < _TEST_FP64_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_COMPLEX_AMOUNT; i++) {
bgc_complex_copy_fp64(&_TEST_FP64_COMPLEX_LIST[i], &vector); bgc_fp64_complex_copy(&_TEST_FP64_COMPLEX_LIST[i], &vector);
if (vector.real != _TEST_FP64_COMPLEX_LIST[i].real || if (vector.real != _TEST_FP64_COMPLEX_LIST[i].real ||
vector.imaginary != _TEST_FP64_COMPLEX_LIST[i].imaginary) { vector.imaginary != _TEST_FP64_COMPLEX_LIST[i].imaginary) {

68
basic-geometry-test/tests/complex/complex_is_unit.c
View file

@ -7,35 +7,35 @@
static const int _TEST_FP32_UNIT_COMPLEX_AMOUNT = 10; static const int _TEST_FP32_UNIT_COMPLEX_AMOUNT = 10;
static const int _TEST_FP32_NONUNIT_COMPLEX_AMOUNT = 6; static const int _TEST_FP32_NONUNIT_COMPLEX_AMOUNT = 6;
static const BgcComplexFP32 _TEST_FP32_UNIT_COMPLEX_LIST[] = { static const BGC_FP32_Complex _TEST_FP32_UNIT_COMPLEX_LIST[] = {
{ 1.0f, 0.0f }, { 1.0f, 0.0f },
{ -1.0f, 0.0f }, { -1.0f, 0.0f },
{ 0.6f, -0.8f }, { 0.6f, -0.8f },
{ 1.0f + 0.75f * BGC_EPSYLON_FP32, 0.0f }, { 1.0f + 0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 1.0f - 0.75f * BGC_EPSYLON_FP32, 0.0f }, { 1.0f - 0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 1.0f + 0.75f * BGC_EPSYLON_FP32 }, { 0.0f, 1.0f + 0.75f * BGC_FP32_EPSYLON },
{ 0.0f, 1.0f - 0.75f * BGC_EPSYLON_FP32 }, { 0.0f, 1.0f - 0.75f * BGC_FP32_EPSYLON },
{ 0.7071067812f, 0.7071067812f }, { 0.7071067812f, 0.7071067812f },
{ 0.7071067812f + 0.75f * BGC_EPSYLON_FP32, 0.7071067812f }, { 0.7071067812f + 0.75f * BGC_FP32_EPSYLON, 0.7071067812f },
{ 0.7071067812f, 0.7071067812f - 0.75f * BGC_EPSYLON_FP32 } { 0.7071067812f, 0.7071067812f - 0.75f * BGC_FP32_EPSYLON }
}; };
static const BgcComplexFP32 _TEST_FP32_NONUNIT_QUATERION_LIST[] = { static const BGC_FP32_Complex _TEST_FP32_NONUNIT_QUATERION_LIST[] = {
{ 1.0f + 1.25f * BGC_EPSYLON_FP32, 0.0f }, { 1.0f + 1.25f * BGC_FP32_EPSYLON, 0.0f },
{ 1.0f - 1.25f * BGC_EPSYLON_FP32, 0.0f }, { 1.0f - 1.25f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 1.0f + 1.25f * BGC_EPSYLON_FP32 }, { 0.0f, 1.0f + 1.25f * BGC_FP32_EPSYLON },
{ 0.0f, 1.0f - 1.25f * BGC_EPSYLON_FP32 }, { 0.0f, 1.0f - 1.25f * BGC_FP32_EPSYLON },
{ 0.7071067812f + 1.25f * BGC_EPSYLON_FP32, 0.7071067812f + 1.25f * BGC_EPSYLON_FP32 }, { 0.7071067812f + 1.25f * BGC_FP32_EPSYLON, 0.7071067812f + 1.25f * BGC_FP32_EPSYLON },
{ 0.7071067812f - 1.25f * BGC_EPSYLON_FP32, 0.7071067812f - 1.25f * BGC_EPSYLON_FP32 } { 0.7071067812f - 1.25f * BGC_FP32_EPSYLON, 0.7071067812f - 1.25f * BGC_FP32_EPSYLON }
}; };
void test_complex_is_unit_fp32() void test_complex_is_unit_fp32()
{ {
print_testing_name("bgc_complex_is_unit_fp32"); print_testing_name("bgc_fp32_complex_is_unit");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP32_UNIT_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_UNIT_COMPLEX_AMOUNT; i++) {
if (!bgc_complex_is_unit_fp32(&_TEST_FP32_UNIT_COMPLEX_LIST[i])) { if (!bgc_fp32_complex_is_unit(&_TEST_FP32_UNIT_COMPLEX_LIST[i])) {
print_testing_error("A unit complex number was not recognized"); print_testing_error("A unit complex number was not recognized");
return; return;
} }
@ -43,7 +43,7 @@ void test_complex_is_unit_fp32()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP32_NONUNIT_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_NONUNIT_COMPLEX_AMOUNT; i++) {
if (bgc_complex_is_unit_fp32(&_TEST_FP32_NONUNIT_QUATERION_LIST[i])) { if (bgc_fp32_complex_is_unit(&_TEST_FP32_NONUNIT_QUATERION_LIST[i])) {
print_testing_error("A non-unit complex number was recognized a unit complex number"); print_testing_error("A non-unit complex number was recognized a unit complex number");
return; return;
} }
@ -57,35 +57,35 @@ void test_complex_is_unit_fp32()
static const int _TEST_FP64_UNIT_COMPLEX_AMOUNT = 10; static const int _TEST_FP64_UNIT_COMPLEX_AMOUNT = 10;
static const int _TEST_FP64_NONUNIT_COMPLEX_AMOUNT = 6; static const int _TEST_FP64_NONUNIT_COMPLEX_AMOUNT = 6;
static const BgcComplexFP64 _TEST_FP64_UNIT_COMPLEX_LIST[] = { static const BGC_FP64_Complex _TEST_FP64_UNIT_COMPLEX_LIST[] = {
{ 1.0, 0.0 }, { 1.0, 0.0 },
{ -1.0, 0.0 }, { -1.0, 0.0 },
{ -0.6, 0.8 }, { -0.6, 0.8 },
{ 1.0 + 0.75 * BGC_EPSYLON_FP64, 0.0 }, { 1.0 + 0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 1.0 - 0.75 * BGC_EPSYLON_FP64, 0.0 }, { 1.0 - 0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 1.0 + 0.75 * BGC_EPSYLON_FP64 }, { 0.0, 1.0 + 0.75 * BGC_FP64_EPSYLON },
{ 0.0, 1.0 - 0.75 * BGC_EPSYLON_FP64 }, { 0.0, 1.0 - 0.75 * BGC_FP64_EPSYLON },
{ 0.7071067811865475244, 0.7071067811865475244 }, { 0.7071067811865475244, 0.7071067811865475244 },
{ 0.7071067811865475244 + 0.75 * BGC_EPSYLON_FP64, 0.7071067811865475244 }, { 0.7071067811865475244 + 0.75 * BGC_FP64_EPSYLON, 0.7071067811865475244 },
{ 0.7071067811865475244, 0.7071067811865475244 - 0.75 * BGC_EPSYLON_FP64 } { 0.7071067811865475244, 0.7071067811865475244 - 0.75 * BGC_FP64_EPSYLON }
}; };
static const BgcComplexFP64 _TEST_FP64_NONUNIT_QUATERION_LIST[] = { static const BGC_FP64_Complex _TEST_FP64_NONUNIT_QUATERION_LIST[] = {
{ 1.0 + 1.25 * BGC_EPSYLON_FP64, 0.0 }, { 1.0 + 1.25 * BGC_FP64_EPSYLON, 0.0 },
{ 1.0 - 1.25 * BGC_EPSYLON_FP64, 0.0 }, { 1.0 - 1.25 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 1.0 + 1.25 * BGC_EPSYLON_FP64 }, { 0.0, 1.0 + 1.25 * BGC_FP64_EPSYLON },
{ 0.0, 1.0 - 1.25 * BGC_EPSYLON_FP64 }, { 0.0, 1.0 - 1.25 * BGC_FP64_EPSYLON },
{ 0.7071067811865475244 + 1.25 * BGC_EPSYLON_FP64, 0.7071067811865475244 + 1.25 * BGC_EPSYLON_FP64 }, { 0.7071067811865475244 + 1.25 * BGC_FP64_EPSYLON, 0.7071067811865475244 + 1.25 * BGC_FP64_EPSYLON },
{ 0.7071067811865475244 - 1.25 * BGC_EPSYLON_FP64, 0.7071067811865475244 - 1.25 * BGC_EPSYLON_FP64 } { 0.7071067811865475244 - 1.25 * BGC_FP64_EPSYLON, 0.7071067811865475244 - 1.25 * BGC_FP64_EPSYLON }
}; };
void test_complex_is_unit_fp64() void test_complex_is_unit_fp64()
{ {
print_testing_name("bgc_complex_is_unit_fp64"); print_testing_name("bgc_fp64_complex_is_unit");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP64_UNIT_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_UNIT_COMPLEX_AMOUNT; i++) {
if (!bgc_complex_is_unit_fp64(&_TEST_FP64_UNIT_COMPLEX_LIST[i])) { if (!bgc_fp64_complex_is_unit(&_TEST_FP64_UNIT_COMPLEX_LIST[i])) {
print_testing_error("A unit complex number was not recognized"); print_testing_error("A unit complex number was not recognized");
return; return;
} }
@ -93,7 +93,7 @@ void test_complex_is_unit_fp64()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP64_NONUNIT_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_NONUNIT_COMPLEX_AMOUNT; i++) {
if (bgc_complex_is_unit_fp64(&_TEST_FP64_NONUNIT_QUATERION_LIST[i])) { if (bgc_fp64_complex_is_unit(&_TEST_FP64_NONUNIT_QUATERION_LIST[i])) {
print_testing_error("A non-unit complex number was recognized a unit complex number"); print_testing_error("A non-unit complex number was recognized a unit complex number");
return; return;
} }

60
basic-geometry-test/tests/complex/complex_is_zero.c
View file

@ -7,31 +7,31 @@
static const int _TEST_FP32_ZERO_COMPLEX_AMOUNT = 4; static const int _TEST_FP32_ZERO_COMPLEX_AMOUNT = 4;
static const int _TEST_FP32_NONZERO_COMPLEX_AMOUNT = 7; static const int _TEST_FP32_NONZERO_COMPLEX_AMOUNT = 7;
static const BgcComplexFP32 _TEST_FP32_ZERO_COMPLEX_LIST[] = { static const BGC_FP32_Complex _TEST_FP32_ZERO_COMPLEX_LIST[] = {
{ 0.0f, 0.0f }, { 0.0f, 0.0f },
{ 0.75f * BGC_EPSYLON_FP32, 0.0f }, { 0.75f * BGC_FP32_EPSYLON, 0.0f },
{ -0.75f * BGC_EPSYLON_FP32, 0.0f }, { -0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 0.75f * BGC_EPSYLON_FP32 }, { 0.0f, 0.75f * BGC_FP32_EPSYLON },
{ 0.0f, -0.75f * BGC_EPSYLON_FP32 } { 0.0f, -0.75f * BGC_FP32_EPSYLON }
}; };
static const BgcComplexFP32 _TEST_FP32_NONZERO_QUATERION_LIST[] = { static const BGC_FP32_Complex _TEST_FP32_NONZERO_QUATERION_LIST[] = {
{ 0.0f, 1.0f }, { 0.0f, 1.0f },
{ 1.25f * BGC_EPSYLON_FP32 }, { 1.25f * BGC_FP32_EPSYLON },
{ -1.25f * BGC_EPSYLON_FP32 }, { -1.25f * BGC_FP32_EPSYLON },
{ 0.0f, 1.25f * BGC_EPSYLON_FP32 }, { 0.0f, 1.25f * BGC_FP32_EPSYLON },
{ 0.0f, -1.25f * BGC_EPSYLON_FP32 }, { 0.0f, -1.25f * BGC_FP32_EPSYLON },
{ 1.25f * BGC_EPSYLON_FP32, 1.25f * BGC_EPSYLON_FP32 }, { 1.25f * BGC_FP32_EPSYLON, 1.25f * BGC_FP32_EPSYLON },
{ -1.25f * BGC_EPSYLON_FP32, -1.25f * BGC_EPSYLON_FP32 } { -1.25f * BGC_FP32_EPSYLON, -1.25f * BGC_FP32_EPSYLON }
}; };
void test_complex_is_zero_fp32() void test_complex_is_zero_fp32()
{ {
print_testing_name("bgc_complex_is_zero_fp32"); print_testing_name("bgc_fp32_complex_is_zero");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP32_ZERO_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_ZERO_COMPLEX_AMOUNT; i++) {
if (!bgc_complex_is_zero_fp32(&_TEST_FP32_ZERO_COMPLEX_LIST[i])) { if (!bgc_fp32_complex_is_zero(&_TEST_FP32_ZERO_COMPLEX_LIST[i])) {
print_testing_error("A zero complex number was not recognized"); print_testing_error("A zero complex number was not recognized");
return; return;
} }
@ -39,7 +39,7 @@ void test_complex_is_zero_fp32()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP32_NONZERO_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_NONZERO_COMPLEX_AMOUNT; i++) {
if (bgc_complex_is_zero_fp32(&_TEST_FP32_NONZERO_QUATERION_LIST[i])) { if (bgc_fp32_complex_is_zero(&_TEST_FP32_NONZERO_QUATERION_LIST[i])) {
print_testing_error("A non-zero complex number was recognized as a zero complex number"); print_testing_error("A non-zero complex number was recognized as a zero complex number");
return; return;
} }
@ -53,31 +53,31 @@ void test_complex_is_zero_fp32()
static const int _TEST_FP64_ZERO_COMPLEX_AMOUNT = 4; static const int _TEST_FP64_ZERO_COMPLEX_AMOUNT = 4;
static const int _TEST_FP64_NONZERO_COMPLEX_AMOUNT = 7; static const int _TEST_FP64_NONZERO_COMPLEX_AMOUNT = 7;
static const BgcComplexFP64 _TEST_FP64_ZERO_COMPLEX_LIST[] = { static const BGC_FP64_Complex _TEST_FP64_ZERO_COMPLEX_LIST[] = {
{ 0.0, 0.0 }, { 0.0, 0.0 },
{ 0.75 * BGC_EPSYLON_FP64, 0.0 }, { 0.75 * BGC_FP64_EPSYLON, 0.0 },
{ -0.75 * BGC_EPSYLON_FP64, 0.0 }, { -0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 0.75 * BGC_EPSYLON_FP64 }, { 0.0, 0.75 * BGC_FP64_EPSYLON },
{ 0.0, -0.75 * BGC_EPSYLON_FP64 } { 0.0, -0.75 * BGC_FP64_EPSYLON }
}; };
static const BgcComplexFP64 _TEST_FP64_NONZERO_QUATERION_LIST[] = { static const BGC_FP64_Complex _TEST_FP64_NONZERO_QUATERION_LIST[] = {
{ 0.0, 1.0 }, { 0.0, 1.0 },
{ 1.25 * BGC_EPSYLON_FP64, 0.0 }, { 1.25 * BGC_FP64_EPSYLON, 0.0 },
{ -1.25 * BGC_EPSYLON_FP64, 0.0 }, { -1.25 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 1.25 * BGC_EPSYLON_FP64 }, { 0.0, 1.25 * BGC_FP64_EPSYLON },
{ 0.0, -1.25 * BGC_EPSYLON_FP64 }, { 0.0, -1.25 * BGC_FP64_EPSYLON },
{ 1.25 * BGC_EPSYLON_FP64, 1.25 * BGC_EPSYLON_FP64 }, { 1.25 * BGC_FP64_EPSYLON, 1.25 * BGC_FP64_EPSYLON },
{ -1.25 * BGC_EPSYLON_FP64, -1.25 * BGC_EPSYLON_FP64 } { -1.25 * BGC_FP64_EPSYLON, -1.25 * BGC_FP64_EPSYLON }
}; };
void test_complex_is_zero_fp64() void test_complex_is_zero_fp64()
{ {
print_testing_name("bgc_complex_is_zero_fp64"); print_testing_name("bgc_fp64_complex_is_zero");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP64_ZERO_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_ZERO_COMPLEX_AMOUNT; i++) {
if (!bgc_complex_is_zero_fp64(&_TEST_FP64_ZERO_COMPLEX_LIST[i])) { if (!bgc_fp64_complex_is_zero(&_TEST_FP64_ZERO_COMPLEX_LIST[i])) {
print_testing_error("A zero complex number was not recognized"); print_testing_error("A zero complex number was not recognized");
return; return;
} }
@ -85,7 +85,7 @@ void test_complex_is_zero_fp64()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP64_NONZERO_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_NONZERO_COMPLEX_AMOUNT; i++) {
if (bgc_complex_is_zero_fp64(&_TEST_FP64_NONZERO_QUATERION_LIST[i])) { if (bgc_fp64_complex_is_zero(&_TEST_FP64_NONZERO_QUATERION_LIST[i])) {
print_testing_error("A non-zero complex number was recognized as a zero complex number"); print_testing_error("A non-zero complex number was recognized as a zero complex number");
return; return;
} }

20
basic-geometry-test/tests/complex/complex_modulus.c
View file

@ -6,7 +6,7 @@
static const int _TEST_FP32_COMPLEX_AMOUNT = 4; static const int _TEST_FP32_COMPLEX_AMOUNT = 4;
static const BgcComplexFP32 _TEST_FP32_COMPLEX_LIST[] = { static const BGC_FP32_Complex _TEST_FP32_COMPLEX_LIST[] = {
{ 4.0f, 3.0f }, { 4.0f, 3.0f },
{ -1.0f, 1.0f }, { -1.0f, 1.0f },
{ 100.0f, -100.0f }, { 100.0f, -100.0f },
@ -29,10 +29,10 @@ static const float _TEST_FP32_MODULUS_LIST[] = {
void test_complex_square_modulus_fp32() void test_complex_square_modulus_fp32()
{ {
print_testing_name("bgc_complex_get_square_modulus_fp32"); print_testing_name("bgc_fp32_complex_get_square_modulus");
for (int i = 0; i < _TEST_FP32_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_COMPLEX_AMOUNT; i++) {
if (!bgc_are_close_fp32(bgc_complex_get_square_modulus_fp32(&_TEST_FP32_COMPLEX_LIST[i]), _TEST_FP32_SQUARE_MODULUS_LIST[i])) { if (!bgc_fp32_are_close(bgc_fp32_complex_get_square_modulus(&_TEST_FP32_COMPLEX_LIST[i]), _TEST_FP32_SQUARE_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }
@ -43,10 +43,10 @@ void test_complex_square_modulus_fp32()
void test_complex_modulus_fp32() void test_complex_modulus_fp32()
{ {
print_testing_name("bgc_complex_get_modulus_fp32"); print_testing_name("bgc_fp32_complex_get_modulus");
for (int i = 0; i < _TEST_FP32_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_COMPLEX_AMOUNT; i++) {
if (!bgc_are_close_fp32(bgc_complex_get_modulus_fp32(&_TEST_FP32_COMPLEX_LIST[i]), _TEST_FP32_MODULUS_LIST[i])) { if (!bgc_fp32_are_close(bgc_fp32_complex_get_modulus(&_TEST_FP32_COMPLEX_LIST[i]), _TEST_FP32_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }
@ -59,7 +59,7 @@ void test_complex_modulus_fp32()
static const int _TEST_FP64_COMPLEX_AMOUNT = 4; static const int _TEST_FP64_COMPLEX_AMOUNT = 4;
static const BgcComplexFP64 _TEST_FP64_COMPLEX_LIST[] = { static const BGC_FP64_Complex _TEST_FP64_COMPLEX_LIST[] = {
{ 4.0, 3.0 }, { 4.0, 3.0 },
{ -1.0, -1.0 }, { -1.0, -1.0 },
{ -100.0, 100.0 }, { -100.0, 100.0 },
@ -82,10 +82,10 @@ static const double _TEST_FP64_MODULUS_LIST[] = {
void test_complex_square_modulus_fp64() void test_complex_square_modulus_fp64()
{ {
print_testing_name("bgc_complex_get_square_modulus_fp64"); print_testing_name("bgc_fp64_complex_get_square_modulus");
for (int i = 0; i < _TEST_FP64_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_COMPLEX_AMOUNT; i++) {
if (!bgc_are_close_fp64(bgc_complex_get_square_modulus_fp64(&_TEST_FP64_COMPLEX_LIST[i]), _TEST_FP64_SQUARE_MODULUS_LIST[i])) { if (!bgc_fp64_are_close(bgc_fp64_complex_get_square_modulus(&_TEST_FP64_COMPLEX_LIST[i]), _TEST_FP64_SQUARE_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }
@ -96,10 +96,10 @@ void test_complex_square_modulus_fp64()
void test_complex_modulus_fp64() void test_complex_modulus_fp64()
{ {
print_testing_name("bgc_complex_get_modulus_fp64"); print_testing_name("bgc_fp64_complex_get_modulus");
for (int i = 0; i < _TEST_FP64_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_COMPLEX_AMOUNT; i++) {
if (!bgc_are_close_fp64(bgc_complex_get_modulus_fp64(&_TEST_FP64_COMPLEX_LIST[i]), _TEST_FP64_MODULUS_LIST[i])) { if (!bgc_fp64_are_close(bgc_fp64_complex_get_modulus(&_TEST_FP64_COMPLEX_LIST[i]), _TEST_FP64_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }

12
basic-geometry-test/tests/complex/complex_reset.c
View file

@ -4,11 +4,11 @@
void test_complex_reset_fp32() void test_complex_reset_fp32()
{ {
BgcComplexFP32 vector; BGC_FP32_Complex vector;
print_testing_name("bgc_complex_reset_fp32"); print_testing_name("bgc_fp32_complex_reset");
bgc_complex_reset_fp32(&vector); bgc_fp32_complex_reset(&vector);
if (vector.real != 0.0f || vector.imaginary != 0.0f) { if (vector.real != 0.0f || vector.imaginary != 0.0f) {
print_testing_failed(); print_testing_failed();
@ -20,11 +20,11 @@ void test_complex_reset_fp32()
void test_complex_reset_fp64() void test_complex_reset_fp64()
{ {
BgcComplexFP64 vector; BGC_FP64_Complex vector;
print_testing_name("bgc_complex_reset_fp64"); print_testing_name("bgc_fp64_complex_reset");
bgc_complex_reset_fp64(&vector); bgc_fp64_complex_reset(&vector);
if (vector.real != 0.0 || vector.imaginary != 0.0) { if (vector.real != 0.0 || vector.imaginary != 0.0) {
print_testing_failed(); print_testing_failed();

20
basic-geometry-test/tests/complex/complex_set_values.c
View file

@ -8,25 +8,25 @@
void test_complex_set_values_fp32() void test_complex_set_values_fp32()
{ {
BgcComplexFP32 vector; BGC_FP32_Complex vector;
print_testing_name("bgc_complex_set_values_fp32"); print_testing_name("bgc_fp32_complex_make");
bgc_complex_set_values_fp32(1.0f, 2.0f, &vector); bgc_fp32_complex_make(1.0f, 2.0f, &vector);
if (vector.real != 1.0f || vector.imaginary != 2.0f) { if (vector.real != 1.0f || vector.imaginary != 2.0f) {
print_testing_error("First step failed"); print_testing_error("First step failed");
return; return;
} }
bgc_complex_set_values_fp32(-1.0f, -3.0f, &vector); bgc_fp32_complex_make(-1.0f, -3.0f, &vector);
if (vector.real != -1.0f || vector.imaginary != -3.0f) { if (vector.real != -1.0f || vector.imaginary != -3.0f) {
print_testing_error("Second step failed"); print_testing_error("Second step failed");
return; return;
} }
bgc_complex_set_values_fp32(-8.0f, -2.0f, &vector); bgc_fp32_complex_make(-8.0f, -2.0f, &vector);
if (vector.real != -8.0f || vector.imaginary != -2.0f) { if (vector.real != -8.0f || vector.imaginary != -2.0f) {
print_testing_error("Third step failed"); print_testing_error("Third step failed");
@ -40,25 +40,25 @@ void test_complex_set_values_fp32()
void test_complex_set_values_fp64() void test_complex_set_values_fp64()
{ {
BgcComplexFP64 vector; BGC_FP64_Complex vector;
print_testing_name("bgc_complex_set_values_fp64"); print_testing_name("bgc_fp64_complex_make");
bgc_complex_set_values_fp64(1.0, 2.0, &vector); bgc_fp64_complex_make(1.0, 2.0, &vector);
if (vector.real != 1.0 || vector.imaginary != 2.0) { if (vector.real != 1.0 || vector.imaginary != 2.0) {
print_testing_error("First step failed"); print_testing_error("First step failed");
return; return;
} }
bgc_complex_set_values_fp64(-1.0, -3.0, &vector); bgc_fp64_complex_make(-1.0, -3.0, &vector);
if (vector.real != -1.0 || vector.imaginary != -3.0) { if (vector.real != -1.0 || vector.imaginary != -3.0) {
print_testing_error("Second step failed"); print_testing_error("Second step failed");
return; return;
} }
bgc_complex_set_values_fp64(-8.0, -2.0, &vector); bgc_fp64_complex_make(-8.0, -2.0, &vector);
if (vector.real != -8.0 || vector.imaginary != -2.0) { if (vector.real != -8.0 || vector.imaginary != -2.0) {
print_testing_error("Third step failed"); print_testing_error("Third step failed");

28
basic-geometry-test/tests/complex/complex_swap.c
View file

@ -8,14 +8,14 @@
static const int _TEST_FP32_COMPLEX_AMOUNT = 4; static const int _TEST_FP32_COMPLEX_AMOUNT = 4;
static const BgcComplexFP32 _TEST_FP32_COMPLEX_LIST1[] = { static const BGC_FP32_Complex _TEST_FP32_COMPLEX_LIST1[] = {
{ 3.0f, 4.0f }, { 3.0f, 4.0f },
{ -2.0f, -1.0f }, { -2.0f, -1.0f },
{ -244.8f, 100.0f }, { -244.8f, 100.0f },
{ 1000.32f, -100.1f } { 1000.32f, -100.1f }
}; };
static const BgcComplexFP32 _TEST_FP32_COMPLEX_LIST2[] = { static const BGC_FP32_Complex _TEST_FP32_COMPLEX_LIST2[] = {
{ 5.3f, 1003.28f }, { 5.3f, 1003.28f },
{ -0.0032f, 891.3f }, { -0.0032f, 891.3f },
{ 5.322f, 0.9275f }, { 5.322f, 0.9275f },
@ -24,15 +24,15 @@ static const BgcComplexFP32 _TEST_FP32_COMPLEX_LIST2[] = {
void test_complex_swap_fp32() void test_complex_swap_fp32()
{ {
BgcComplexFP32 compleimaginary, complex2; BGC_FP32_Complex compleimaginary, complex2;
print_testing_name("bgc_complex_swap_fp32"); print_testing_name("bgc_fp32_complex_swap");
for (int i = 0; i < _TEST_FP32_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_COMPLEX_AMOUNT; i++) {
bgc_complex_copy_fp32(&_TEST_FP32_COMPLEX_LIST1[i], &compleimaginary); bgc_fp32_complex_copy(&_TEST_FP32_COMPLEX_LIST1[i], &compleimaginary);
bgc_complex_copy_fp32(&_TEST_FP32_COMPLEX_LIST2[i], &complex2); bgc_fp32_complex_copy(&_TEST_FP32_COMPLEX_LIST2[i], &complex2);
bgc_complex_swap_fp32(&compleimaginary, &complex2); bgc_fp32_complex_swap(&compleimaginary, &complex2);
if (compleimaginary.real != _TEST_FP32_COMPLEX_LIST2[i].real || if (compleimaginary.real != _TEST_FP32_COMPLEX_LIST2[i].real ||
compleimaginary.imaginary != _TEST_FP32_COMPLEX_LIST2[i].imaginary || compleimaginary.imaginary != _TEST_FP32_COMPLEX_LIST2[i].imaginary ||
@ -50,14 +50,14 @@ void test_complex_swap_fp32()
static const int _TEST_FP64_COMPLEX_AMOUNT = 4; static const int _TEST_FP64_COMPLEX_AMOUNT = 4;
static const BgcComplexFP64 _TEST_FP64_COMPLEX_LIST1[] = { static const BGC_FP64_Complex _TEST_FP64_COMPLEX_LIST1[] = {
{ 1.0, 4.0 }, { 1.0, 4.0 },
{ -4.0, -3.0 }, { -4.0, -3.0 },
{ -244.8, 344.7 }, { -244.8, 344.7 },
{ 1000.32, -271.3 } { 1000.32, -271.3 }
}; };
static const BgcComplexFP64 _TEST_FP64_COMPLEX_LIST2[] = { static const BGC_FP64_Complex _TEST_FP64_COMPLEX_LIST2[] = {
{ -0.123, 1003.28 }, { -0.123, 1003.28 },
{ 204.07, -781.89 }, { 204.07, -781.89 },
{ 5.322, 0.9275 }, { 5.322, 0.9275 },
@ -66,15 +66,15 @@ static const BgcComplexFP64 _TEST_FP64_COMPLEX_LIST2[] = {
void test_complex_swap_fp64() void test_complex_swap_fp64()
{ {
BgcComplexFP64 compleimaginary, complex2; BGC_FP64_Complex compleimaginary, complex2;
print_testing_name("bgc_complex_swap_fp64"); print_testing_name("bgc_fp64_complex_swap");
for (int i = 0; i < _TEST_FP64_COMPLEX_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_COMPLEX_AMOUNT; i++) {
bgc_complex_copy_fp64(&_TEST_FP64_COMPLEX_LIST1[i], &compleimaginary); bgc_fp64_complex_copy(&_TEST_FP64_COMPLEX_LIST1[i], &compleimaginary);
bgc_complex_copy_fp64(&_TEST_FP64_COMPLEX_LIST2[i], &complex2); bgc_fp64_complex_copy(&_TEST_FP64_COMPLEX_LIST2[i], &complex2);
bgc_complex_swap_fp64(&compleimaginary, &complex2); bgc_fp64_complex_swap(&compleimaginary, &complex2);
if (compleimaginary.real != _TEST_FP64_COMPLEX_LIST2[i].real || if (compleimaginary.real != _TEST_FP64_COMPLEX_LIST2[i].real ||
compleimaginary.imaginary != _TEST_FP64_COMPLEX_LIST2[i].imaginary || compleimaginary.imaginary != _TEST_FP64_COMPLEX_LIST2[i].imaginary ||

16
basic-geometry-test/tests/quaternion/quaternion_copy.c
View file

@ -7,7 +7,7 @@
// ==================== FP32 ==================== // // ==================== FP32 ==================== //
static const int _TEST_FP32_QUATERNION_AMOUNT = 4; static const int _TEST_FP32_QUATERNION_AMOUNT = 4;
static const BgcQuaternionFP32 _TEST_FP32_QUATERNION_LIST[] = { static const BGC_FP32_Quaternion _TEST_FP32_QUATERNION_LIST[] = {
{ 1.0f, 2.0f, 3.0f, 4.0f }, { 1.0f, 2.0f, 3.0f, 4.0f },
{ -4.0f, -3.0f, -2.0f, -1.0f }, { -4.0f, -3.0f, -2.0f, -1.0f },
{ -0.001f, 100.0f, -100.0f, 0.001f }, { -0.001f, 100.0f, -100.0f, 0.001f },
@ -16,13 +16,13 @@ static const BgcQuaternionFP32 _TEST_FP32_QUATERNION_LIST[] = {
void test_quaternion_copy_fp32() void test_quaternion_copy_fp32()
{ {
BgcQuaternionFP32 vector; BGC_FP32_Quaternion vector;
print_testing_name("bgc_quaternion_copy_fp32"); print_testing_name("bgc_fp32_quaternion_copy");
for (int i = 0; i < _TEST_FP32_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_QUATERNION_AMOUNT; i++) {
bgc_quaternion_copy_fp32(&_TEST_FP32_QUATERNION_LIST[i], &vector); bgc_fp32_quaternion_copy(&_TEST_FP32_QUATERNION_LIST[i], &vector);
if (vector.s0 != _TEST_FP32_QUATERNION_LIST[i].s0 || if (vector.s0 != _TEST_FP32_QUATERNION_LIST[i].s0 ||
vector.x1 != _TEST_FP32_QUATERNION_LIST[i].x1 || vector.x1 != _TEST_FP32_QUATERNION_LIST[i].x1 ||
@ -39,7 +39,7 @@ void test_quaternion_copy_fp32()
// ==================== FP64 ==================== // // ==================== FP64 ==================== //
static const int _TEST_FP64_QUATERNION_AMOUNT = 4; static const int _TEST_FP64_QUATERNION_AMOUNT = 4;
static const BgcQuaternionFP64 _TEST_FP64_QUATERNION_LIST[] = { static const BGC_FP64_Quaternion _TEST_FP64_QUATERNION_LIST[] = {
{ 1.0, 2.0, 3.0, 4.0 }, { 1.0, 2.0, 3.0, 4.0 },
{ -4.0, -3.0, -2.0, -1.0 }, { -4.0, -3.0, -2.0, -1.0 },
{ -0.001, 100.0, -100.0, 0.001 }, { -0.001, 100.0, -100.0, 0.001 },
@ -48,13 +48,13 @@ static const BgcQuaternionFP64 _TEST_FP64_QUATERNION_LIST[] = {
void test_quaternion_copy_fp64() void test_quaternion_copy_fp64()
{ {
BgcQuaternionFP64 vector; BGC_FP64_Quaternion vector;
print_testing_name("bgc_quaternion_copy_fp64"); print_testing_name("bgc_fp64_quaternion_copy");
for (int i = 0; i < _TEST_FP64_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_QUATERNION_AMOUNT; i++) {
bgc_quaternion_copy_fp64(&_TEST_FP64_QUATERNION_LIST[i], &vector); bgc_fp64_quaternion_copy(&_TEST_FP64_QUATERNION_LIST[i], &vector);
if (vector.s0 != _TEST_FP64_QUATERNION_LIST[i].s0 || if (vector.s0 != _TEST_FP64_QUATERNION_LIST[i].s0 ||
vector.x1 != _TEST_FP64_QUATERNION_LIST[i].x1 || vector.x1 != _TEST_FP64_QUATERNION_LIST[i].x1 ||

108
basic-geometry-test/tests/quaternion/quaternion_is_unit.c
View file

@ -7,45 +7,45 @@
static const int _TEST_FP32_UNIT_QUATERNION_AMOUNT = 16; static const int _TEST_FP32_UNIT_QUATERNION_AMOUNT = 16;
static const int _TEST_FP32_NONUNIT_QUATERNION_AMOUNT = 10; static const int _TEST_FP32_NONUNIT_QUATERNION_AMOUNT = 10;
static const BgcQuaternionFP32 _TEST_FP32_UNIT_QUATERNION_LIST[] = { static const BGC_FP32_Quaternion _TEST_FP32_UNIT_QUATERNION_LIST[] = {
{ 1.0f, 0.0f, 0.0f, 0.0f }, { 1.0f, 0.0f, 0.0f, 0.0f },
{ -1.0f, 0.0f, 0.0f, 0.0f }, { -1.0f, 0.0f, 0.0f, 0.0f },
{ 0.0f, -0.8f, 0.6f, 0.0f }, { 0.0f, -0.8f, 0.6f, 0.0f },
{ 1.0f + 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f, 0.0f }, { 1.0f + 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f, 0.0f },
{ 1.0f - 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f, 0.0f }, { 1.0f - 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f, 0.0f },
{ 0.0f, 1.0f + 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 0.0f, 1.0f + 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 0.0f, 1.0f - 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 0.0f, 1.0f - 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 0.0f, 0.0f, 1.0f + 0.75f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, 0.0f, 1.0f + 0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 0.0f, 1.0f - 0.75f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, 0.0f, 1.0f - 0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 0.0f, 0.0f, 1.0f + 0.75f * BGC_EPSYLON_FP32 }, { 0.0f, 0.0f, 0.0f, 1.0f + 0.75f * BGC_FP32_EPSYLON },
{ 0.0f, 0.0f, 0.0f, 1.0f - 0.75f * BGC_EPSYLON_FP32 }, { 0.0f, 0.0f, 0.0f, 1.0f - 0.75f * BGC_FP32_EPSYLON },
{ 0.5f, 0.5f, 0.5f, 0.5f }, { 0.5f, 0.5f, 0.5f, 0.5f },
{ 0.5f + 0.75f * BGC_EPSYLON_FP32, 0.5f, 0.5f, 0.5f }, { 0.5f + 0.75f * BGC_FP32_EPSYLON, 0.5f, 0.5f, 0.5f },
{ 0.5f, 0.5f - 0.75f * BGC_EPSYLON_FP32, 0.5f, 0.5f }, { 0.5f, 0.5f - 0.75f * BGC_FP32_EPSYLON, 0.5f, 0.5f },
{ 0.5f, 0.5f, 0.5f + 0.75f * BGC_EPSYLON_FP32, 0.5f }, { 0.5f, 0.5f, 0.5f + 0.75f * BGC_FP32_EPSYLON, 0.5f },
{ 0.5f, 0.5f, 0.5f, 0.5f - 0.75f * BGC_EPSYLON_FP32 } { 0.5f, 0.5f, 0.5f, 0.5f - 0.75f * BGC_FP32_EPSYLON }
}; };
static const BgcQuaternionFP32 _TEST_FP32_NONUNIT_QUATERION_LIST[] = { static const BGC_FP32_Quaternion _TEST_FP32_NONUNIT_QUATERION_LIST[] = {
{ 1.0f + 1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f, 0.0f }, { 1.0f + 1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f, 0.0f },
{ 1.0f - 1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f, 0.0f }, { 1.0f - 1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f, 0.0f },
{ 0.0f, 1.0f + 1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 0.0f, 1.0f + 1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 0.0f, 1.0f - 1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 0.0f, 1.0f - 1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 0.0f, 0.0f, 1.0f + 1.25f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, 0.0f, 1.0f + 1.25f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 0.0f, 1.0f - 1.25f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, 0.0f, 1.0f - 1.25f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 0.0f, 0.0f, 1.0f + 1.25f * BGC_EPSYLON_FP32 }, { 0.0f, 0.0f, 0.0f, 1.0f + 1.25f * BGC_FP32_EPSYLON },
{ 0.0f, 0.0f, 0.0f, 1.0f - 1.25f * BGC_EPSYLON_FP32 }, { 0.0f, 0.0f, 0.0f, 1.0f - 1.25f * BGC_FP32_EPSYLON },
{ 0.5f + 1.25f * BGC_EPSYLON_FP32, 0.5f + 1.25f * BGC_EPSYLON_FP32, 0.5f, 0.5f }, { 0.5f + 1.25f * BGC_FP32_EPSYLON, 0.5f + 1.25f * BGC_FP32_EPSYLON, 0.5f, 0.5f },
{ 0.5f - 1.25f * BGC_EPSYLON_FP32, 0.5f - 1.25f * BGC_EPSYLON_FP32, 0.0f, 0.5f } { 0.5f - 1.25f * BGC_FP32_EPSYLON, 0.5f - 1.25f * BGC_FP32_EPSYLON, 0.0f, 0.5f }
}; };
void test_quaternion_is_unit_fp32() void test_quaternion_is_unit_fp32()
{ {
print_testing_name("bgc_quaternion_is_unit_fp32"); print_testing_name("bgc_fp32_quaternion_is_unit");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP32_UNIT_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_UNIT_QUATERNION_AMOUNT; i++) {
if (!bgc_quaternion_is_unit_fp32(&_TEST_FP32_UNIT_QUATERNION_LIST[i])) { if (!bgc_fp32_quaternion_is_unit(&_TEST_FP32_UNIT_QUATERNION_LIST[i])) {
print_testing_error("A unit quaternion was not recognized"); print_testing_error("A unit quaternion was not recognized");
return; return;
} }
@ -53,7 +53,7 @@ void test_quaternion_is_unit_fp32()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP32_NONUNIT_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_NONUNIT_QUATERNION_AMOUNT; i++) {
if (bgc_quaternion_is_unit_fp32(&_TEST_FP32_NONUNIT_QUATERION_LIST[i])) { if (bgc_fp32_quaternion_is_unit(&_TEST_FP32_NONUNIT_QUATERION_LIST[i])) {
print_testing_error("A non-unit quaternion was recognized a unit quaternion"); print_testing_error("A non-unit quaternion was recognized a unit quaternion");
return; return;
} }
@ -67,45 +67,45 @@ void test_quaternion_is_unit_fp32()
static const int _TEST_FP64_UNIT_QUATERNION_AMOUNT = 16; static const int _TEST_FP64_UNIT_QUATERNION_AMOUNT = 16;
static const int _TEST_FP64_NONUNIT_QUATERNION_AMOUNT = 10; static const int _TEST_FP64_NONUNIT_QUATERNION_AMOUNT = 10;
static const BgcQuaternionFP64 _TEST_FP64_UNIT_QUATERNION_LIST[] = { static const BGC_FP64_Quaternion _TEST_FP64_UNIT_QUATERNION_LIST[] = {
{ 1.0, 0.0, 0.0, 0.0 }, { 1.0, 0.0, 0.0, 0.0 },
{ -1.0, 0.0, 0.0, 0.0 }, { -1.0, 0.0, 0.0, 0.0 },
{ 0.0, -0.6, 0.8, 0.0 }, { 0.0, -0.6, 0.8, 0.0 },
{ 1.0 + 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0, 0.0 }, { 1.0 + 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0, 0.0 },
{ 1.0 - 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0, 0.0 }, { 1.0 - 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0, 0.0 },
{ 0.0, 1.0 + 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 0.0, 1.0 + 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 0.0, 1.0 - 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 0.0, 1.0 - 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 0.0, 0.0, 1.0 + 0.75 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, 0.0, 1.0 + 0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 0.0, 1.0 - 0.75 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, 0.0, 1.0 - 0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 0.0, 0.0, 1.0 + 0.75 * BGC_EPSYLON_FP64 }, { 0.0, 0.0, 0.0, 1.0 + 0.75 * BGC_FP64_EPSYLON },
{ 0.0, 0.0, 0.0, 1.0 - 0.75 * BGC_EPSYLON_FP64 }, { 0.0, 0.0, 0.0, 1.0 - 0.75 * BGC_FP64_EPSYLON },
{ 0.5, 0.5, 0.5, 0.5 }, { 0.5, 0.5, 0.5, 0.5 },
{ 0.5 + 0.75 * BGC_EPSYLON_FP64, 0.5, 0.5, 0.5 }, { 0.5 + 0.75 * BGC_FP64_EPSYLON, 0.5, 0.5, 0.5 },
{ 0.5, 0.5 - 0.75 * BGC_EPSYLON_FP64, 0.5, 0.5 }, { 0.5, 0.5 - 0.75 * BGC_FP64_EPSYLON, 0.5, 0.5 },
{ 0.5, 0.5, 0.5 + 0.75 * BGC_EPSYLON_FP64, 0.5 }, { 0.5, 0.5, 0.5 + 0.75 * BGC_FP64_EPSYLON, 0.5 },
{ 0.5, 0.5, 0.5, 0.5 - 0.75 * BGC_EPSYLON_FP64 } { 0.5, 0.5, 0.5, 0.5 - 0.75 * BGC_FP64_EPSYLON }
}; };
static const BgcQuaternionFP64 _TEST_FP64_NONUNIT_QUATERION_LIST[] = { static const BGC_FP64_Quaternion _TEST_FP64_NONUNIT_QUATERION_LIST[] = {
{ 1.0 + 1.25 * BGC_EPSYLON_FP64, 0.0, 0.0, 0.0 }, { 1.0 + 1.25 * BGC_FP64_EPSYLON, 0.0, 0.0, 0.0 },
{ 1.0 - 1.25 * BGC_EPSYLON_FP64, 0.0, 0.0, 0.0 }, { 1.0 - 1.25 * BGC_FP64_EPSYLON, 0.0, 0.0, 0.0 },
{ 0.0, 1.0 + 1.25 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 0.0, 1.0 + 1.25 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 0.0, 1.0 - 1.25 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 0.0, 1.0 - 1.25 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 0.0, 0.0, 1.0 + 1.25 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, 0.0, 1.0 + 1.25 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 0.0, 1.0 - 1.25 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, 0.0, 1.0 - 1.25 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 0.0, 0.0, 1.0 + 1.25 * BGC_EPSYLON_FP64 }, { 0.0, 0.0, 0.0, 1.0 + 1.25 * BGC_FP64_EPSYLON },
{ 0.0, 0.0, 0.0, 1.0 - 1.25 * BGC_EPSYLON_FP64 }, { 0.0, 0.0, 0.0, 1.0 - 1.25 * BGC_FP64_EPSYLON },
{ 0.5 + 1.25 * BGC_EPSYLON_FP64, 0.5 + 1.25 * BGC_EPSYLON_FP64, 0.5, 0.5 }, { 0.5 + 1.25 * BGC_FP64_EPSYLON, 0.5 + 1.25 * BGC_FP64_EPSYLON, 0.5, 0.5 },
{ 0.5 - 1.25 * BGC_EPSYLON_FP64, 0.5 - 1.25 * BGC_EPSYLON_FP64, 0.0, 0.5 } { 0.5 - 1.25 * BGC_FP64_EPSYLON, 0.5 - 1.25 * BGC_FP64_EPSYLON, 0.0, 0.5 }
}; };
void test_quaternion_is_unit_fp64() void test_quaternion_is_unit_fp64()
{ {
print_testing_name("bgc_quaternion_is_unit_fp64"); print_testing_name("bgc_fp64_quaternion_is_unit");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP64_UNIT_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_UNIT_QUATERNION_AMOUNT; i++) {
if (!bgc_quaternion_is_unit_fp64(&_TEST_FP64_UNIT_QUATERNION_LIST[i])) { if (!bgc_fp64_quaternion_is_unit(&_TEST_FP64_UNIT_QUATERNION_LIST[i])) {
print_testing_error("A unit quaternion was not recognized"); print_testing_error("A unit quaternion was not recognized");
return; return;
} }
@ -113,7 +113,7 @@ void test_quaternion_is_unit_fp64()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP64_NONUNIT_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_NONUNIT_QUATERNION_AMOUNT; i++) {
if (bgc_quaternion_is_unit_fp64(&_TEST_FP64_NONUNIT_QUATERION_LIST[i])) { if (bgc_fp64_quaternion_is_unit(&_TEST_FP64_NONUNIT_QUATERION_LIST[i])) {
print_testing_error("A non-unit quaternion was recognized a unit quaternion"); print_testing_error("A non-unit quaternion was recognized a unit quaternion");
return; return;
} }

92
basic-geometry-test/tests/quaternion/quaternion_is_zero.c
View file

@ -7,39 +7,39 @@
static const int _TEST_FP32_ZERO_QUATERNION_AMOUNT = 9; static const int _TEST_FP32_ZERO_QUATERNION_AMOUNT = 9;
static const int _TEST_FP32_NONZERO_QUATERNION_AMOUNT = 11; static const int _TEST_FP32_NONZERO_QUATERNION_AMOUNT = 11;
static const BgcQuaternionFP32 _TEST_FP32_ZERO_QUATERNION_LIST[] = { static const BGC_FP32_Quaternion _TEST_FP32_ZERO_QUATERNION_LIST[] = {
{ 0.0f, 0.0f, 0.0f, 0.0f }, { 0.0f, 0.0f, 0.0f, 0.0f },
{ 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f, 0.0f }, { 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f, 0.0f },
{ -0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f, 0.0f }, { -0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f, 0.0f },
{ 0.0f, 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 0.0f, 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 0.0f, -0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 0.0f, -0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 0.0f, 0.0f, 0.75f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, 0.0f, 0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 0.0f, -0.75f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, 0.0f, -0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 0.0f, 0.0f, 0.75f * BGC_EPSYLON_FP32 }, { 0.0f, 0.0f, 0.0f, 0.75f * BGC_FP32_EPSYLON },
{ 0.0f, 0.0f, 0.0f, -0.75f * BGC_EPSYLON_FP32 } { 0.0f, 0.0f, 0.0f, -0.75f * BGC_FP32_EPSYLON }
}; };
static const BgcQuaternionFP32 _TEST_FP32_NONZERO_QUATERION_LIST[] = { static const BGC_FP32_Quaternion _TEST_FP32_NONZERO_QUATERION_LIST[] = {
{ 0.0f, 1.0f, 0.0f, 0.0f }, { 0.0f, 1.0f, 0.0f, 0.0f },
{ 1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f, 0.0f }, { 1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f, 0.0f },
{ -1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f, 0.0f }, { -1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f, 0.0f },
{ 0.0f, 1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 0.0f, 1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 0.0f, -1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 0.0f, -1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 0.0f, 0.0f, 1.25f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, 0.0f, 1.25f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 0.0f, -1.25f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, 0.0f, -1.25f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 0.0f, 0.0f, 1.25f * BGC_EPSYLON_FP32 }, { 0.0f, 0.0f, 0.0f, 1.25f * BGC_FP32_EPSYLON },
{ 0.0f, 0.0f, 0.0f, -1.25f * BGC_EPSYLON_FP32 }, { 0.0f, 0.0f, 0.0f, -1.25f * BGC_FP32_EPSYLON },
{ 1.25f * BGC_EPSYLON_FP32, 1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 1.25f * BGC_FP32_EPSYLON, 1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ -1.25f * BGC_EPSYLON_FP32, -1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f } { -1.25f * BGC_FP32_EPSYLON, -1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f }
}; };
void test_quaternion_is_zero_fp32() void test_quaternion_is_zero_fp32()
{ {
print_testing_name("bgc_quaternion_is_zero_fp32"); print_testing_name("bgc_fp32_quaternion_is_zero");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP32_ZERO_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_ZERO_QUATERNION_AMOUNT; i++) {
if (!bgc_quaternion_is_zero_fp32(&_TEST_FP32_ZERO_QUATERNION_LIST[i])) { if (!bgc_fp32_quaternion_is_zero(&_TEST_FP32_ZERO_QUATERNION_LIST[i])) {
print_testing_error("A zero quaternion was not recognized"); print_testing_error("A zero quaternion was not recognized");
return; return;
} }
@ -47,7 +47,7 @@ void test_quaternion_is_zero_fp32()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP32_NONZERO_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_NONZERO_QUATERNION_AMOUNT; i++) {
if (bgc_quaternion_is_zero_fp32(&_TEST_FP32_NONZERO_QUATERION_LIST[i])) { if (bgc_fp32_quaternion_is_zero(&_TEST_FP32_NONZERO_QUATERION_LIST[i])) {
print_testing_error("A non-zero quaternion was recognized as a zero quaternion"); print_testing_error("A non-zero quaternion was recognized as a zero quaternion");
return; return;
} }
@ -61,39 +61,39 @@ void test_quaternion_is_zero_fp32()
static const int _TEST_FP64_ZERO_QUATERNION_AMOUNT = 9; static const int _TEST_FP64_ZERO_QUATERNION_AMOUNT = 9;
static const int _TEST_FP64_NONZERO_QUATERNION_AMOUNT = 11; static const int _TEST_FP64_NONZERO_QUATERNION_AMOUNT = 11;
static const BgcQuaternionFP64 _TEST_FP64_ZERO_QUATERNION_LIST[] = { static const BGC_FP64_Quaternion _TEST_FP64_ZERO_QUATERNION_LIST[] = {
{ 0.0, 0.0, 0.0, 0.0 }, { 0.0, 0.0, 0.0, 0.0 },
{ 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0, 0.0 }, { 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0, 0.0 },
{ -0.75 * BGC_EPSYLON_FP64, 0.0, 0.0, 0.0 }, { -0.75 * BGC_FP64_EPSYLON, 0.0, 0.0, 0.0 },
{ 0.0, 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 0.0, 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 0.0, -0.75 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 0.0, -0.75 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 0.0, 0.0, 0.75 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, 0.0, 0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 0.0, -0.75 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, 0.0, -0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 0.0, 0.0, 0.75 * BGC_EPSYLON_FP64 }, { 0.0, 0.0, 0.0, 0.75 * BGC_FP64_EPSYLON },
{ 0.0, 0.0, 0.0, -0.75 * BGC_EPSYLON_FP64 } { 0.0, 0.0, 0.0, -0.75 * BGC_FP64_EPSYLON }
}; };
static const BgcQuaternionFP64 _TEST_FP64_NONZERO_QUATERION_LIST[] = { static const BGC_FP64_Quaternion _TEST_FP64_NONZERO_QUATERION_LIST[] = {
{ 0.0, 1.0, 0.0, 0.0 }, { 0.0, 1.0, 0.0, 0.0 },
{ 1.25 * BGC_EPSYLON_FP64, 0.0, 0.0, 0.0 }, { 1.25 * BGC_FP64_EPSYLON, 0.0, 0.0, 0.0 },
{ -1.25 * BGC_EPSYLON_FP64, 0.0, 0.0, 0.0 }, { -1.25 * BGC_FP64_EPSYLON, 0.0, 0.0, 0.0 },
{ 0.0, 1.25 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 0.0, 1.25 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 0.0, -1.25 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 0.0, -1.25 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 0.0, 0.0, 1.25 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, 0.0, 1.25 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 0.0, -1.25 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, 0.0, -1.25 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 0.0, 0.0, 1.25 * BGC_EPSYLON_FP64 }, { 0.0, 0.0, 0.0, 1.25 * BGC_FP64_EPSYLON },
{ 0.0, 0.0, 0.0, -1.25 * BGC_EPSYLON_FP64 }, { 0.0, 0.0, 0.0, -1.25 * BGC_FP64_EPSYLON },
{ 1.25 * BGC_EPSYLON_FP64, 1.25 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 1.25 * BGC_FP64_EPSYLON, 1.25 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ -1.25 * BGC_EPSYLON_FP64, -1.25 * BGC_EPSYLON_FP64, 0.0, 0.0 } { -1.25 * BGC_FP64_EPSYLON, -1.25 * BGC_FP64_EPSYLON, 0.0, 0.0 }
}; };
void test_quaternion_is_zero_fp64() void test_quaternion_is_zero_fp64()
{ {
print_testing_name("bgc_quaternion_is_zero_fp64"); print_testing_name("bgc_fp64_quaternion_is_zero");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP64_ZERO_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_ZERO_QUATERNION_AMOUNT; i++) {
if (!bgc_quaternion_is_zero_fp64(&_TEST_FP64_ZERO_QUATERNION_LIST[i])) { if (!bgc_fp64_quaternion_is_zero(&_TEST_FP64_ZERO_QUATERNION_LIST[i])) {
print_testing_error("A zero quaternion was not recognized"); print_testing_error("A zero quaternion was not recognized");
return; return;
} }
@ -101,7 +101,7 @@ void test_quaternion_is_zero_fp64()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP64_NONZERO_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_NONZERO_QUATERNION_AMOUNT; i++) {
if (bgc_quaternion_is_zero_fp64(&_TEST_FP64_NONZERO_QUATERION_LIST[i])) { if (bgc_fp64_quaternion_is_zero(&_TEST_FP64_NONZERO_QUATERION_LIST[i])) {
print_testing_error("A non-zero quaternion was recognized as a zero quaternion"); print_testing_error("A non-zero quaternion was recognized as a zero quaternion");
return; return;
} }

20
basic-geometry-test/tests/quaternion/quaternion_modulus.c
View file

@ -6,7 +6,7 @@
static const int _TEST_FP32_QUATERNION_AMOUNT = 4; static const int _TEST_FP32_QUATERNION_AMOUNT = 4;
static const BgcQuaternionFP32 _TEST_FP32_QUATERNION_LIST[] = { static const BGC_FP32_Quaternion _TEST_FP32_QUATERNION_LIST[] = {
{ 0.0f, 4.0f, 3.0f, 0.0f }, { 0.0f, 4.0f, 3.0f, 0.0f },
{ -1.0f, 1.0f, -1.0f, 1.0f }, { -1.0f, 1.0f, -1.0f, 1.0f },
{ 100.0f, -100.0f, 0.0f, 100.0f }, { 100.0f, -100.0f, 0.0f, 100.0f },
@ -29,10 +29,10 @@ static const float _TEST_FP32_MODULUS_LIST[] = {
void test_quaternion_square_modulus_fp32() void test_quaternion_square_modulus_fp32()
{ {
print_testing_name("bgc_quaternion_get_square_modulus_fp32"); print_testing_name("bgc_fp32_quaternion_get_square_modulus");
for (int i = 0; i < _TEST_FP32_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_QUATERNION_AMOUNT; i++) {
if (!bgc_are_close_fp32(bgc_quaternion_get_square_modulus_fp32(&_TEST_FP32_QUATERNION_LIST[i]), _TEST_FP32_SQUARE_MODULUS_LIST[i])) { if (!bgc_fp32_are_close(bgc_fp32_quaternion_get_square_modulus(&_TEST_FP32_QUATERNION_LIST[i]), _TEST_FP32_SQUARE_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }
@ -43,10 +43,10 @@ void test_quaternion_square_modulus_fp32()
void test_quaternion_modulus_fp32() void test_quaternion_modulus_fp32()
{ {
print_testing_name("bgc_quaternion_get_modulus_fp32"); print_testing_name("bgc_fp32_quaternion_get_modulus");
for (int i = 0; i < _TEST_FP32_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_QUATERNION_AMOUNT; i++) {
if (!bgc_are_close_fp32(bgc_quaternion_get_modulus_fp32(&_TEST_FP32_QUATERNION_LIST[i]), _TEST_FP32_MODULUS_LIST[i])) { if (!bgc_fp32_are_close(bgc_fp32_quaternion_get_modulus(&_TEST_FP32_QUATERNION_LIST[i]), _TEST_FP32_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }
@ -59,7 +59,7 @@ void test_quaternion_modulus_fp32()
static const int _TEST_FP64_QUATERNION_AMOUNT = 4; static const int _TEST_FP64_QUATERNION_AMOUNT = 4;
static const BgcQuaternionFP64 _TEST_FP64_QUATERNION_LIST[] = { static const BGC_FP64_Quaternion _TEST_FP64_QUATERNION_LIST[] = {
{ 0.0, 4.0, 3.0, 0.0 }, { 0.0, 4.0, 3.0, 0.0 },
{ -1.0, 1.0, -1.0, 1.0 }, { -1.0, 1.0, -1.0, 1.0 },
{ 100.0, -100.0, 0.0, 100.0 }, { 100.0, -100.0, 0.0, 100.0 },
@ -82,10 +82,10 @@ static const double _TEST_FP64_MODULUS_LIST[] = {
void test_quaternion_square_modulus_fp64() void test_quaternion_square_modulus_fp64()
{ {
print_testing_name("bgc_quaternion_get_square_modulus_fp64"); print_testing_name("bgc_fp64_quaternion_get_square_modulus");
for (int i = 0; i < _TEST_FP64_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_QUATERNION_AMOUNT; i++) {
if (!bgc_are_close_fp64(bgc_quaternion_get_square_modulus_fp64(&_TEST_FP64_QUATERNION_LIST[i]), _TEST_FP64_SQUARE_MODULUS_LIST[i])) { if (!bgc_fp64_are_close(bgc_fp64_quaternion_get_square_modulus(&_TEST_FP64_QUATERNION_LIST[i]), _TEST_FP64_SQUARE_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }
@ -96,10 +96,10 @@ void test_quaternion_square_modulus_fp64()
void test_quaternion_modulus_fp64() void test_quaternion_modulus_fp64()
{ {
print_testing_name("bgc_quaternion_get_modulus_fp64"); print_testing_name("bgc_fp64_quaternion_get_modulus");
for (int i = 0; i < _TEST_FP64_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_QUATERNION_AMOUNT; i++) {
if (!bgc_are_close_fp64(bgc_quaternion_get_modulus_fp64(&_TEST_FP64_QUATERNION_LIST[i]), _TEST_FP64_MODULUS_LIST[i])) { if (!bgc_fp64_are_close(bgc_fp64_quaternion_get_modulus(&_TEST_FP64_QUATERNION_LIST[i]), _TEST_FP64_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }

12
basic-geometry-test/tests/quaternion/quaternion_reset.c
View file

@ -4,11 +4,11 @@
void test_quaternion_reset_fp32() void test_quaternion_reset_fp32()
{ {
BgcQuaternionFP32 vector; BGC_FP32_Quaternion vector;
print_testing_name("bgc_quaternion_reset_fp32"); print_testing_name("bgc_fp32_quaternion_reset");
bgc_quaternion_reset_fp32(&vector); bgc_fp32_quaternion_reset(&vector);
if (vector.s0 != 0.0f || vector.x1 != 0.0f || vector.x2 != 0.0f || vector.x3 != 0.0f) { if (vector.s0 != 0.0f || vector.x1 != 0.0f || vector.x2 != 0.0f || vector.x3 != 0.0f) {
print_testing_failed(); print_testing_failed();
@ -20,11 +20,11 @@ void test_quaternion_reset_fp32()
void test_quaternion_reset_fp64() void test_quaternion_reset_fp64()
{ {
BgcQuaternionFP64 vector; BGC_FP64_Quaternion vector;
print_testing_name("bgc_quaternion_reset_fp64"); print_testing_name("bgc_fp64_quaternion_reset");
bgc_quaternion_reset_fp64(&vector); bgc_fp64_quaternion_reset(&vector);
if (vector.s0 != 0.0 || vector.x1 != 0.0 || vector.x2 != 0.0 || vector.x3 != 0.0) { if (vector.s0 != 0.0 || vector.x1 != 0.0 || vector.x2 != 0.0 || vector.x3 != 0.0) {
print_testing_failed(); print_testing_failed();

20
basic-geometry-test/tests/quaternion/quaternion_set_to_identity.c
View file

@ -2,13 +2,13 @@
#include "./../../helpers.h" #include "./../../helpers.h"
void test_quaternion_set_to_identity_fp32() void test_quaternion_make_unit_fp32()
{ {
BgcQuaternionFP32 vector; BGC_FP32_Quaternion vector;
print_testing_name("bgc_quaternion_set_to_identity_fp32"); print_testing_name("bgc_fp32_quaternion_make_unit");
bgc_quaternion_make_unit_fp32(&vector); bgc_fp32_quaternion_make_unit(&vector);
if (vector.s0 != 1.0f || vector.x1 != 0.0f || vector.x2 != 0.0f || vector.x3 != 0.0f) { if (vector.s0 != 1.0f || vector.x1 != 0.0f || vector.x2 != 0.0f || vector.x3 != 0.0f) {
print_testing_failed(); print_testing_failed();
@ -18,13 +18,13 @@ void test_quaternion_set_to_identity_fp32()
print_testing_success(); print_testing_success();
} }
void test_quaternion_set_to_identity_fp64() void test_quaternion_make_unit_fp64()
{ {
BgcQuaternionFP64 vector; BGC_FP64_Quaternion vector;
print_testing_name("bgc_quaternion_set_to_identity_fp64"); print_testing_name("bgc_fp64_quaternion_make_unit");
bgc_quaternion_make_unit_fp64(&vector); bgc_fp64_quaternion_make_unit(&vector);
if (vector.s0 != 1.0 || vector.x1 != 0.0 || vector.x2 != 0.0 || vector.x3 != 0.0) { if (vector.s0 != 1.0 || vector.x1 != 0.0 || vector.x2 != 0.0 || vector.x3 != 0.0) {
print_testing_failed(); print_testing_failed();
@ -36,6 +36,6 @@ void test_quaternion_set_to_identity_fp64()
void test_quaternion_set_to_identity() void test_quaternion_set_to_identity()
{ {
test_quaternion_set_to_identity_fp32(); test_quaternion_make_unit_fp32();
test_quaternion_set_to_identity_fp64(); test_quaternion_make_unit_fp64();
} }

4
basic-geometry-test/tests/quaternion/quaternion_set_to_identity.h
View file

@ -1,9 +1,9 @@
#ifndef _TEST_QUATERNION_SET_TO_IDENTITY_H_ #ifndef _TEST_QUATERNION_SET_TO_IDENTITY_H_
#define _TEST_QUATERNION_SET_TO_IDENTITY_H_ #define _TEST_QUATERNION_SET_TO_IDENTITY_H_
void test_quaternion_set_to_identity_fp32(); void test_quaternion_make_unit_fp32();
void test_quaternion_set_to_identity_fp64(); void test_quaternion_make_unit_fp64();
void test_quaternion_set_to_identity(); void test_quaternion_set_to_identity();

20
basic-geometry-test/tests/quaternion/quaternion_set_values.c
View file

@ -8,25 +8,25 @@
void test_quaternion_set_values_fp32() void test_quaternion_set_values_fp32()
{ {
BgcQuaternionFP32 vector; BGC_FP32_Quaternion vector;
print_testing_name("bgc_quaternion_set_values_fp32"); print_testing_name("bgc_fp32_quaternion_make");
bgc_quaternion_set_values_fp32(1.0f, 2.0f, 3.0f, 4.0f, &vector); bgc_fp32_quaternion_make(1.0f, 2.0f, 3.0f, 4.0f, &vector);
if (vector.s0 != 1.0f || vector.x1 != 2.0f || vector.x2 != 3.0f || vector.x3 != 4.0f) { if (vector.s0 != 1.0f || vector.x1 != 2.0f || vector.x2 != 3.0f || vector.x3 != 4.0f) {
print_testing_error("First step failed"); print_testing_error("First step failed");
return; return;
} }
bgc_quaternion_set_values_fp32(-1.0f, -3.0f, -5.0f, -7.0f, &vector); bgc_fp32_quaternion_make(-1.0f, -3.0f, -5.0f, -7.0f, &vector);
if (vector.s0 != -1.0f || vector.x1 != -3.0f || vector.x2 != -5.0f || vector.x3 != -7.0f) { if (vector.s0 != -1.0f || vector.x1 != -3.0f || vector.x2 != -5.0f || vector.x3 != -7.0f) {
print_testing_error("Second step failed"); print_testing_error("Second step failed");
return; return;
} }
bgc_quaternion_set_values_fp32(-8.0f, -2.0f, 2.0f, 4.0f, &vector); bgc_fp32_quaternion_make(-8.0f, -2.0f, 2.0f, 4.0f, &vector);
if (vector.s0 != -8.0f || vector.x1 != -2.0f || vector.x2 != 2.0f || vector.x3 != 4.0f) { if (vector.s0 != -8.0f || vector.x1 != -2.0f || vector.x2 != 2.0f || vector.x3 != 4.0f) {
print_testing_error("Third step failed"); print_testing_error("Third step failed");
@ -40,25 +40,25 @@ void test_quaternion_set_values_fp32()
void test_quaternion_set_values_fp64() void test_quaternion_set_values_fp64()
{ {
BgcQuaternionFP64 vector; BGC_FP64_Quaternion vector;
print_testing_name("bgc_quaternion_set_values_fp64"); print_testing_name("bgc_fp64_quaternion_make");
bgc_quaternion_set_values_fp64(1.0, 2.0, 3.0, 4.0, &vector); bgc_fp64_quaternion_make(1.0, 2.0, 3.0, 4.0, &vector);
if (vector.s0 != 1.0 || vector.x1 != 2.0 || vector.x2 != 3.0 || vector.x3 != 4.0) { if (vector.s0 != 1.0 || vector.x1 != 2.0 || vector.x2 != 3.0 || vector.x3 != 4.0) {
print_testing_error("First step failed"); print_testing_error("First step failed");
return; return;
} }
bgc_quaternion_set_values_fp64(-1.0, -3.0, -5.0, -7.0, &vector); bgc_fp64_quaternion_make(-1.0, -3.0, -5.0, -7.0, &vector);
if (vector.s0 != -1.0 || vector.x1 != -3.0 || vector.x2 != -5.0 || vector.x3 != -7.0) { if (vector.s0 != -1.0 || vector.x1 != -3.0 || vector.x2 != -5.0 || vector.x3 != -7.0) {
print_testing_error("Second step failed"); print_testing_error("Second step failed");
return; return;
} }
bgc_quaternion_set_values_fp64(-8.0, -2.0, 2.0, 4.0, &vector); bgc_fp64_quaternion_make(-8.0, -2.0, 2.0, 4.0, &vector);
if (vector.s0 != -8.0 || vector.x1 != -2.0 || vector.x2 != 2.0 || vector.x3 != 4.0) { if (vector.s0 != -8.0 || vector.x1 != -2.0 || vector.x2 != 2.0 || vector.x3 != 4.0) {
print_testing_error("Third step failed"); print_testing_error("Third step failed");

28
basic-geometry-test/tests/quaternion/quaternion_swap.c
View file

@ -8,14 +8,14 @@
static const int _TEST_FP32_QUATERNION_AMOUNT = 4; static const int _TEST_FP32_QUATERNION_AMOUNT = 4;
static const BgcQuaternionFP32 _TEST_FP32_QUATERNION_LIST1[] = { static const BGC_FP32_Quaternion _TEST_FP32_QUATERNION_LIST1[] = {
{ 1.0f, 2.0f, 3.0f, 4.0f }, { 1.0f, 2.0f, 3.0f, 4.0f },
{ -4.0f, -3.0f, -2.0f, -1.0f }, { -4.0f, -3.0f, -2.0f, -1.0f },
{ -244.8f, 100.0f, -100.0f, 344.7f }, { -244.8f, 100.0f, -100.0f, 344.7f },
{ 1000.32f, -100.1f, 100.2f, -271.3f } { 1000.32f, -100.1f, 100.2f, -271.3f }
}; };
static const BgcQuaternionFP32 _TEST_FP32_QUATERNION_LIST2[] = { static const BGC_FP32_Quaternion _TEST_FP32_QUATERNION_LIST2[] = {
{ 3.6f, -0.123f, 5.3f, 1003.28f }, { 3.6f, -0.123f, 5.3f, 1003.28f },
{ 204.07f, -781.89f, -0.0032f, 891.3f }, { 204.07f, -781.89f, -0.0032f, 891.3f },
{ -20.02f, -1.0003f, 5.322f, 0.9275f }, { -20.02f, -1.0003f, 5.322f, 0.9275f },
@ -24,15 +24,15 @@ static const BgcQuaternionFP32 _TEST_FP32_QUATERNION_LIST2[] = {
void test_quaternion_swap_fp32() void test_quaternion_swap_fp32()
{ {
BgcQuaternionFP32 quaternion1, quaternion2; BGC_FP32_Quaternion quaternion1, quaternion2;
print_testing_name("bgc_quaternion_swap_fp32"); print_testing_name("bgc_fp32_quaternion_swap");
for (int i = 0; i < _TEST_FP32_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_QUATERNION_AMOUNT; i++) {
bgc_quaternion_copy_fp32(&_TEST_FP32_QUATERNION_LIST1[i], &quaternion1); bgc_fp32_quaternion_copy(&_TEST_FP32_QUATERNION_LIST1[i], &quaternion1);
bgc_quaternion_copy_fp32(&_TEST_FP32_QUATERNION_LIST2[i], &quaternion2); bgc_fp32_quaternion_copy(&_TEST_FP32_QUATERNION_LIST2[i], &quaternion2);
bgc_quaternion_swap_fp32(&quaternion1, &quaternion2); bgc_fp32_quaternion_swap(&quaternion1, &quaternion2);
if (quaternion1.s0 != _TEST_FP32_QUATERNION_LIST2[i].s0 || if (quaternion1.s0 != _TEST_FP32_QUATERNION_LIST2[i].s0 ||
quaternion1.x1 != _TEST_FP32_QUATERNION_LIST2[i].x1 || quaternion1.x1 != _TEST_FP32_QUATERNION_LIST2[i].x1 ||
@ -54,14 +54,14 @@ void test_quaternion_swap_fp32()
static const int _TEST_FP64_QUATERNION_AMOUNT = 4; static const int _TEST_FP64_QUATERNION_AMOUNT = 4;
static const BgcQuaternionFP64 _TEST_FP64_QUATERNION_LIST1[] = { static const BGC_FP64_Quaternion _TEST_FP64_QUATERNION_LIST1[] = {
{ 1.0, 2.0, 3.0, 4.0 }, { 1.0, 2.0, 3.0, 4.0 },
{ -4.0, -3.0, -2.0, -1.0 }, { -4.0, -3.0, -2.0, -1.0 },
{ -244.8, 100.0, -100.0, 344.7 }, { -244.8, 100.0, -100.0, 344.7 },
{ 1000.32, -100.1, 100.2, -271.3 } { 1000.32, -100.1, 100.2, -271.3 }
}; };
static const BgcQuaternionFP64 _TEST_FP64_QUATERNION_LIST2[] = { static const BGC_FP64_Quaternion _TEST_FP64_QUATERNION_LIST2[] = {
{ 3.6, -0.123, 5.3, 1003.28 }, { 3.6, -0.123, 5.3, 1003.28 },
{ 204.07, -781.89, -0.0032, 891.3 }, { 204.07, -781.89, -0.0032, 891.3 },
{ -20.02, -1.0003, 5.322, 0.9275 }, { -20.02, -1.0003, 5.322, 0.9275 },
@ -70,15 +70,15 @@ static const BgcQuaternionFP64 _TEST_FP64_QUATERNION_LIST2[] = {
void test_quaternion_swap_fp64() void test_quaternion_swap_fp64()
{ {
BgcQuaternionFP64 quaternion1, quaternion2; BGC_FP64_Quaternion quaternion1, quaternion2;
print_testing_name("bgc_quaternion_swap_fp64"); print_testing_name("bgc_fp64_quaternion_swap");
for (int i = 0; i < _TEST_FP64_QUATERNION_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_QUATERNION_AMOUNT; i++) {
bgc_quaternion_copy_fp64(&_TEST_FP64_QUATERNION_LIST1[i], &quaternion1); bgc_fp64_quaternion_copy(&_TEST_FP64_QUATERNION_LIST1[i], &quaternion1);
bgc_quaternion_copy_fp64(&_TEST_FP64_QUATERNION_LIST2[i], &quaternion2); bgc_fp64_quaternion_copy(&_TEST_FP64_QUATERNION_LIST2[i], &quaternion2);
bgc_quaternion_swap_fp64(&quaternion1, &quaternion2); bgc_fp64_quaternion_swap(&quaternion1, &quaternion2);
if (quaternion1.s0 != _TEST_FP64_QUATERNION_LIST2[i].s0 || if (quaternion1.s0 != _TEST_FP64_QUATERNION_LIST2[i].s0 ||
quaternion1.x1 != _TEST_FP64_QUATERNION_LIST2[i].x1 || quaternion1.x1 != _TEST_FP64_QUATERNION_LIST2[i].x1 ||

116
basic-geometry-test/tests/utilities/are_close.c
View file

@ -12,22 +12,22 @@ static const TestNumberPairFP32 _TEST_FP32_DATA_CLOSE[] = {
{1.0f, 1.0f}, {1.0f, 1.0f},
{-1.0f, -1.0f}, {-1.0f, -1.0f},
{-0.4f * BGC_EPSYLON_FP32, 0.4f * BGC_EPSYLON_FP32}, {-0.4f * BGC_FP32_EPSYLON, 0.4f * BGC_FP32_EPSYLON},
{1.0f, 1.0f + 0.75f * BGC_EPSYLON_FP32}, {1.0f, 1.0f + 0.75f * BGC_FP32_EPSYLON},
{1.0f, 1.0f - 0.75f * BGC_EPSYLON_FP32}, {1.0f, 1.0f - 0.75f * BGC_FP32_EPSYLON},
{1.0f + 0.75f * BGC_EPSYLON_FP32, 1.0f}, {1.0f + 0.75f * BGC_FP32_EPSYLON, 1.0f},
{1.0f - 0.75f * BGC_EPSYLON_FP32, 1.0f}, {1.0f - 0.75f * BGC_FP32_EPSYLON, 1.0f},
{-1.0f, -1.0f + 0.75f * BGC_EPSYLON_FP32}, {-1.0f, -1.0f + 0.75f * BGC_FP32_EPSYLON},
{-1.0f, -1.0f - 0.75f * BGC_EPSYLON_FP32}, {-1.0f, -1.0f - 0.75f * BGC_FP32_EPSYLON},
{-1.0f + 0.75f * BGC_EPSYLON_FP32, -1.0f}, {-1.0f + 0.75f * BGC_FP32_EPSYLON, -1.0f},
{-1.0f - 0.75f * BGC_EPSYLON_FP32, -1.0f}, {-1.0f - 0.75f * BGC_FP32_EPSYLON, -1.0f},
{100.0f, 100.0f * (1.0f + 0.75f * BGC_EPSYLON_FP32)}, {100.0f, 100.0f * (1.0f + 0.75f * BGC_FP32_EPSYLON)},
{100.0f, 100.0f * (1.0f - 0.75f * BGC_EPSYLON_FP32)}, {100.0f, 100.0f * (1.0f - 0.75f * BGC_FP32_EPSYLON)},
{-100.0f, -100.0f * (1.0f + 0.75f * BGC_EPSYLON_FP32)}, {-100.0f, -100.0f * (1.0f + 0.75f * BGC_FP32_EPSYLON)},
{-100.0f, -100.0f * (1.0f - 0.75f * BGC_EPSYLON_FP32)} {-100.0f, -100.0f * (1.0f - 0.75f * BGC_FP32_EPSYLON)}
}; };
static const TestNumberPairFP32 _TEST_FP32_DATA_DIFFERENT[] = { static const TestNumberPairFP32 _TEST_FP32_DATA_DIFFERENT[] = {
@ -35,31 +35,31 @@ static const TestNumberPairFP32 _TEST_FP32_DATA_DIFFERENT[] = {
{1.0f, 0.999f}, {1.0f, 0.999f},
{-1.0f, -0.999f}, {-1.0f, -0.999f},
{-0.6f * BGC_EPSYLON_FP32, 0.6f * BGC_EPSYLON_FP32}, {-0.6f * BGC_FP32_EPSYLON, 0.6f * BGC_FP32_EPSYLON},
{1.0f, 1.0f + 1.25f * BGC_EPSYLON_FP32}, {1.0f, 1.0f + 1.25f * BGC_FP32_EPSYLON},
{1.0f, 1.0f - 1.25f * BGC_EPSYLON_FP32}, {1.0f, 1.0f - 1.25f * BGC_FP32_EPSYLON},
{1.0f + 1.25f * BGC_EPSYLON_FP32, 1.0f}, {1.0f + 1.25f * BGC_FP32_EPSYLON, 1.0f},
{1.0f - 1.25f * BGC_EPSYLON_FP32, 1.0f}, {1.0f - 1.25f * BGC_FP32_EPSYLON, 1.0f},
{-1.0f, -1.0f + 1.25f * BGC_EPSYLON_FP32}, {-1.0f, -1.0f + 1.25f * BGC_FP32_EPSYLON},
{-1.0f, -1.0f - 1.25f * BGC_EPSYLON_FP32}, {-1.0f, -1.0f - 1.25f * BGC_FP32_EPSYLON},
{-1.0f + 1.25f * BGC_EPSYLON_FP32, -1.0f}, {-1.0f + 1.25f * BGC_FP32_EPSYLON, -1.0f},
{-1.0f - 1.25f * BGC_EPSYLON_FP32, -1.0f}, {-1.0f - 1.25f * BGC_FP32_EPSYLON, -1.0f},
{100.0f, 100.0f * (1.0f + 1.25f * BGC_EPSYLON_FP32)}, {100.0f, 100.0f * (1.0f + 1.25f * BGC_FP32_EPSYLON)},
{100.0f, 100.0f * (1.0f - 1.25f * BGC_EPSYLON_FP32)}, {100.0f, 100.0f * (1.0f - 1.25f * BGC_FP32_EPSYLON)},
{-100.0f, -100.0f * (1.0f + 1.25f * BGC_EPSYLON_FP32)}, {-100.0f, -100.0f * (1.0f + 1.25f * BGC_FP32_EPSYLON)},
{-100.0f, -100.0f * (1.0f - 1.25f * BGC_EPSYLON_FP32)} {-100.0f, -100.0f * (1.0f - 1.25f * BGC_FP32_EPSYLON)}
}; };
void test_are_close_fp32() void test_are_close_fp32()
{ {
print_testing_name("bgc_are_close_fp32"); print_testing_name("bgc_fp32_are_close");
// Testing close pairs of values: // Testing close pairs of values:
for (int i = 0; i < _TEST_FP32_CLOSE_NUMBERS_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_CLOSE_NUMBERS_AMOUNT; i++) {
if (!bgc_are_close_fp32(_TEST_FP32_DATA_CLOSE[i].number1, _TEST_FP32_DATA_CLOSE[i].number2)) { if (!bgc_fp32_are_close(_TEST_FP32_DATA_CLOSE[i].number1, _TEST_FP32_DATA_CLOSE[i].number2)) {
print_testing_error("A pair of close numbers was not recognized"); print_testing_error("A pair of close numbers was not recognized");
return; return;
} }
@ -67,7 +67,7 @@ void test_are_close_fp32()
// Testing different pairs of values: // Testing different pairs of values:
for (int i = 0; i < _TEST_FP32_DIFFERENT_NUMBERS_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_DIFFERENT_NUMBERS_AMOUNT; i++) {
if (bgc_are_close_fp32(_TEST_FP32_DATA_DIFFERENT[i].number1, _TEST_FP32_DATA_DIFFERENT[i].number2)) { if (bgc_fp32_are_close(_TEST_FP32_DATA_DIFFERENT[i].number1, _TEST_FP32_DATA_DIFFERENT[i].number2)) {
print_testing_error("A pair of close numbers was not recognized"); print_testing_error("A pair of close numbers was not recognized");
return; return;
} }
@ -86,22 +86,22 @@ static const TestNumberPairFP64 _TEST_FP64_DATA_CLOSE[] = {
{1.0, 1.0}, {1.0, 1.0},
{-1.0, -1.0}, {-1.0, -1.0},
{-0.4 * BGC_EPSYLON_FP64, 0.4 * BGC_EPSYLON_FP64}, {-0.4 * BGC_FP64_EPSYLON, 0.4 * BGC_FP64_EPSYLON},
{1.0, 1.0 + 0.75 * BGC_EPSYLON_FP64}, {1.0, 1.0 + 0.75 * BGC_FP64_EPSYLON},
{1.0, 1.0 - 0.75 * BGC_EPSYLON_FP64}, {1.0, 1.0 - 0.75 * BGC_FP64_EPSYLON},
{1.0 + 0.75 * BGC_EPSYLON_FP64, 1.0}, {1.0 + 0.75 * BGC_FP64_EPSYLON, 1.0},
{1.0 - 0.75 * BGC_EPSYLON_FP64, 1.0}, {1.0 - 0.75 * BGC_FP64_EPSYLON, 1.0},
{-1.0, -1.0 + 0.75 * BGC_EPSYLON_FP64}, {-1.0, -1.0 + 0.75 * BGC_FP64_EPSYLON},
{-1.0, -1.0 - 0.75 * BGC_EPSYLON_FP64}, {-1.0, -1.0 - 0.75 * BGC_FP64_EPSYLON},
{-1.0 + 0.75 * BGC_EPSYLON_FP64, -1.0}, {-1.0 + 0.75 * BGC_FP64_EPSYLON, -1.0},
{-1.0 - 0.75 * BGC_EPSYLON_FP64, -1.0}, {-1.0 - 0.75 * BGC_FP64_EPSYLON, -1.0},
{100.0, 100.0 * (1.0 + 0.75 * BGC_EPSYLON_FP64)}, {100.0, 100.0 * (1.0 + 0.75 * BGC_FP64_EPSYLON)},
{100.0, 100.0 * (1.0 - 0.75 * BGC_EPSYLON_FP64)}, {100.0, 100.0 * (1.0 - 0.75 * BGC_FP64_EPSYLON)},
{-100.0, -100.0 * (1.0 + 0.75 * BGC_EPSYLON_FP64)}, {-100.0, -100.0 * (1.0 + 0.75 * BGC_FP64_EPSYLON)},
{-100.0, -100.0 * (1.0 - 0.75 * BGC_EPSYLON_FP64)} {-100.0, -100.0 * (1.0 - 0.75 * BGC_FP64_EPSYLON)}
}; };
static const TestNumberPairFP64 _TEST_FP64_DATA_DIFFERENT[] = { static const TestNumberPairFP64 _TEST_FP64_DATA_DIFFERENT[] = {
@ -109,31 +109,31 @@ static const TestNumberPairFP64 _TEST_FP64_DATA_DIFFERENT[] = {
{1.0, 0.999999}, {1.0, 0.999999},
{-1.0, -0.999999}, {-1.0, -0.999999},
{-0.6 * BGC_EPSYLON_FP64, 0.6 * BGC_EPSYLON_FP64}, {-0.6 * BGC_FP64_EPSYLON, 0.6 * BGC_FP64_EPSYLON},
{1.0, 1.0 + 1.25 * BGC_EPSYLON_FP64}, {1.0, 1.0 + 1.25 * BGC_FP64_EPSYLON},
{1.0, 1.0 - 1.25 * BGC_EPSYLON_FP64}, {1.0, 1.0 - 1.25 * BGC_FP64_EPSYLON},
{1.0 + 1.25 * BGC_EPSYLON_FP64, 1.0}, {1.0 + 1.25 * BGC_FP64_EPSYLON, 1.0},
{1.0 - 1.25 * BGC_EPSYLON_FP64, 1.0}, {1.0 - 1.25 * BGC_FP64_EPSYLON, 1.0},
{-1.0, -1.0 + 1.25 * BGC_EPSYLON_FP64}, {-1.0, -1.0 + 1.25 * BGC_FP64_EPSYLON},
{-1.0, -1.0 - 1.25 * BGC_EPSYLON_FP64}, {-1.0, -1.0 - 1.25 * BGC_FP64_EPSYLON},
{-1.0 + 1.25 * BGC_EPSYLON_FP64, -1.0}, {-1.0 + 1.25 * BGC_FP64_EPSYLON, -1.0},
{-1.0 - 1.25 * BGC_EPSYLON_FP64, -1.0}, {-1.0 - 1.25 * BGC_FP64_EPSYLON, -1.0},
{100.0, 100.0 * (1.0 + 1.25 * BGC_EPSYLON_FP64)}, {100.0, 100.0 * (1.0 + 1.25 * BGC_FP64_EPSYLON)},
{100.0, 100.0 * (1.0 - 1.25 * BGC_EPSYLON_FP64)}, {100.0, 100.0 * (1.0 - 1.25 * BGC_FP64_EPSYLON)},
{-100.0, -100.0 * (1.0 + 1.25 * BGC_EPSYLON_FP64)}, {-100.0, -100.0 * (1.0 + 1.25 * BGC_FP64_EPSYLON)},
{-100.0, -100.0 * (1.0 - 1.25 * BGC_EPSYLON_FP64)} {-100.0, -100.0 * (1.0 - 1.25 * BGC_FP64_EPSYLON)}
}; };
void test_are_close_fp64() void test_are_close_fp64()
{ {
print_testing_name("bgc_are_close_fp64"); print_testing_name("bgc_fp64_are_close");
// Testing close pairs of values: // Testing close pairs of values:
for (int i = 0; i < _TEST_FP64_CLOSE_NUMBERS_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_CLOSE_NUMBERS_AMOUNT; i++) {
if (!bgc_are_close_fp64(_TEST_FP64_DATA_CLOSE[i].number1, _TEST_FP64_DATA_CLOSE[i].number2)) { if (!bgc_fp64_are_close(_TEST_FP64_DATA_CLOSE[i].number1, _TEST_FP64_DATA_CLOSE[i].number2)) {
print_testing_error("A pair of close numbers was not recognized"); print_testing_error("A pair of close numbers was not recognized");
return; return;
} }
@ -141,7 +141,7 @@ void test_are_close_fp64()
// Testing different pairs of values: // Testing different pairs of values:
for (int i = 0; i < _TEST_FP64_DIFFERENT_NUMBERS_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_DIFFERENT_NUMBERS_AMOUNT; i++) {
if (bgc_are_close_fp64(_TEST_FP64_DATA_DIFFERENT[i].number1, _TEST_FP64_DATA_DIFFERENT[i].number2)) { if (bgc_fp64_are_close(_TEST_FP64_DATA_DIFFERENT[i].number1, _TEST_FP64_DATA_DIFFERENT[i].number2)) {
print_testing_error("A pair of different numbers was recognized as close numbers"); print_testing_error("A pair of different numbers was recognized as close numbers");
return; return;
} }

64
basic-geometry-test/tests/utilities/is_unit.c
View file

@ -9,24 +9,24 @@ static const int _TEST_FP32_NONUNIT_NUMBERS_AMOUNT = 4;
static const float _TEST_FP32_UNIT_NUMBERS[] = { static const float _TEST_FP32_UNIT_NUMBERS[] = {
1.0f, 1.0f,
1.0f + 0.75f * BGC_EPSYLON_FP32, 1.0f + 0.75f * BGC_FP32_EPSYLON,
1.0f - 0.75f * BGC_EPSYLON_FP32 1.0f - 0.75f * BGC_FP32_EPSYLON
}; };
static const float _TEST_FP32_NONUNIT_NUMBERS[] = { static const float _TEST_FP32_NONUNIT_NUMBERS[] = {
0.0f, 0.0f,
-1.0f, -1.0f,
1.0f + 1.25f * BGC_EPSYLON_FP32, 1.0f + 1.25f * BGC_FP32_EPSYLON,
1.0f - 1.25f * BGC_EPSYLON_FP32 1.0f - 1.25f * BGC_FP32_EPSYLON
}; };
void test_is_unit_fp32() void test_is_unit_fp32()
{ {
print_testing_name("bgc_is_unit_fp32"); print_testing_name("bgc_fp32_is_unit");
// Testing unit values: // Testing unit values:
for (int i = 0; i < _TEST_FP32_UNIT_NUMBERS_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_UNIT_NUMBERS_AMOUNT; i++) {
if (!bgc_is_unit_fp32(_TEST_FP32_UNIT_NUMBERS[i])) { if (!bgc_fp32_is_unit(_TEST_FP32_UNIT_NUMBERS[i])) {
print_testing_error("A unit value was not recognized"); print_testing_error("A unit value was not recognized");
return; return;
} }
@ -34,7 +34,7 @@ void test_is_unit_fp32()
// Testing non-unit values: // Testing non-unit values:
for (int i = 0; i < _TEST_FP32_NONUNIT_NUMBERS_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_NONUNIT_NUMBERS_AMOUNT; i++) {
if (bgc_is_unit_fp32(_TEST_FP32_NONUNIT_NUMBERS[i])) { if (bgc_fp32_is_unit(_TEST_FP32_NONUNIT_NUMBERS[i])) {
print_testing_error("A non-unit value was recognized as a unit value"); print_testing_error("A non-unit value was recognized as a unit value");
return; return;
} }
@ -50,24 +50,24 @@ static const int _TEST_FP64_NONUNIT_NUMBERS_AMOUNT = 4;
static const double _TEST_FP64_UNIT_NUMBERS[] = { static const double _TEST_FP64_UNIT_NUMBERS[] = {
1.0, 1.0,
1.0 + 0.75 * BGC_EPSYLON_FP64, 1.0 + 0.75 * BGC_FP64_EPSYLON,
1.0 - 0.75 * BGC_EPSYLON_FP64 1.0 - 0.75 * BGC_FP64_EPSYLON
}; };
static const double _TEST_FP64_NONUNIT_NUMBERS[] = { static const double _TEST_FP64_NONUNIT_NUMBERS[] = {
0.0, 0.0,
-1.0, -1.0,
1.0 + 1.25 * BGC_EPSYLON_FP64, 1.0 + 1.25 * BGC_FP64_EPSYLON,
1.0 - 1.25 * BGC_EPSYLON_FP64 1.0 - 1.25 * BGC_FP64_EPSYLON
}; };
void test_is_unit_fp64() void test_is_unit_fp64()
{ {
print_testing_name("bgc_is_unit_fp64"); print_testing_name("bgc_fp64_is_unit");
// Testing unit values: // Testing unit values:
for (int i = 0; i < _TEST_FP64_UNIT_NUMBERS_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_UNIT_NUMBERS_AMOUNT; i++) {
if (!bgc_is_unit_fp64(_TEST_FP64_UNIT_NUMBERS[i])) { if (!bgc_fp64_is_unit(_TEST_FP64_UNIT_NUMBERS[i])) {
print_testing_error("A unit value was not recognized"); print_testing_error("A unit value was not recognized");
return; return;
} }
@ -75,7 +75,7 @@ void test_is_unit_fp64()
// Testing non-unit values: // Testing non-unit values:
for (int i = 0; i < _TEST_FP64_NONUNIT_NUMBERS_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_NONUNIT_NUMBERS_AMOUNT; i++) {
if (bgc_is_unit_fp64(_TEST_FP64_NONUNIT_NUMBERS[i])) { if (bgc_fp64_is_unit(_TEST_FP64_NONUNIT_NUMBERS[i])) {
print_testing_error("A non-unit value was recognized as a unit value"); print_testing_error("A non-unit value was recognized as a unit value");
return; return;
} }
@ -91,24 +91,24 @@ static const int _TEST_FP32_DATA_SQUARE_NONUNIT_AMOUNT = 4;
static const float _TEST_FP32_DATA_SQUARE_UNIT[] = { static const float _TEST_FP32_DATA_SQUARE_UNIT[] = {
1.0f, 1.0f,
1.0f + 1.75f * BGC_EPSYLON_FP32, 1.0f + 1.75f * BGC_FP32_EPSYLON,
1.0f - 1.75f * BGC_EPSYLON_FP32 1.0f - 1.75f * BGC_FP32_EPSYLON
}; };
static const float _TEST_FP32_DATA_SQUARE_NONUNIT[] = { static const float _TEST_FP32_DATA_SQUARE_NONUNIT[] = {
0.0f, 0.0f,
-1.0f, -1.0f,
1.0f + 2.25f * BGC_EPSYLON_FP32, 1.0f + 2.25f * BGC_FP32_EPSYLON,
1.0f - 2.25f * BGC_EPSYLON_FP32 1.0f - 2.25f * BGC_FP32_EPSYLON
}; };
void test_is_sqare_unit_fp32() void test_is_square_unit_fp32()
{ {
print_testing_name("bgc_is_sqare_unit_fp32"); print_testing_name("bgc_fp32_is_square_unit");
// Testing unit values: // Testing unit values:
for (int i = 0; i < _TEST_FP32_DATA_SQUARE_UNIT_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_DATA_SQUARE_UNIT_AMOUNT; i++) {
if (!bgc_is_sqare_unit_fp32(_TEST_FP32_DATA_SQUARE_UNIT[i])) { if (!bgc_fp32_is_square_unit(_TEST_FP32_DATA_SQUARE_UNIT[i])) {
print_testing_error("A square unit value was not recognized"); print_testing_error("A square unit value was not recognized");
return; return;
} }
@ -116,7 +116,7 @@ void test_is_sqare_unit_fp32()
// Testing non-unit values: // Testing non-unit values:
for (int i = 0; i < _TEST_FP32_DATA_SQUARE_NONUNIT_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_DATA_SQUARE_NONUNIT_AMOUNT; i++) {
if (bgc_is_sqare_unit_fp32(_TEST_FP32_DATA_SQUARE_NONUNIT[i])) { if (bgc_fp32_is_square_unit(_TEST_FP32_DATA_SQUARE_NONUNIT[i])) {
print_testing_error("A non-unit value was recognized as a square unit value"); print_testing_error("A non-unit value was recognized as a square unit value");
return; return;
} }
@ -132,24 +132,24 @@ static const int _TEST_FP64_DATA_SQUARE_NONUNIT_AMOUNT = 4;
static const double _TEST_FP64_DATA_SQUARE_UNIT[] = { static const double _TEST_FP64_DATA_SQUARE_UNIT[] = {
1.0, 1.0,
1.0 + 1.75 * BGC_EPSYLON_FP64, 1.0 + 1.75 * BGC_FP64_EPSYLON,
1.0 - 1.75 * BGC_EPSYLON_FP64 1.0 - 1.75 * BGC_FP64_EPSYLON
}; };
static const double _TEST_FP64_DATA_SQUARE_NONUNIT[] = { static const double _TEST_FP64_DATA_SQUARE_NONUNIT[] = {
0.0, 0.0,
-1.0, -1.0,
1.0 + 2.25 * BGC_EPSYLON_FP64, 1.0 + 2.25 * BGC_FP64_EPSYLON,
1.0 - 2.25 * BGC_EPSYLON_FP64 1.0 - 2.25 * BGC_FP64_EPSYLON
}; };
void test_is_sqare_unit_fp64() void test_is_square_unit_fp64()
{ {
print_testing_name("bgc_is_sqare_unit_fp64"); print_testing_name("bgc_fp64_is_square_unit");
// Testing unit values: // Testing unit values:
for (int i = 0; i < _TEST_FP64_DATA_SQUARE_UNIT_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_DATA_SQUARE_UNIT_AMOUNT; i++) {
if (!bgc_is_sqare_unit_fp64(_TEST_FP64_DATA_SQUARE_UNIT[i])) { if (!bgc_fp64_is_square_unit(_TEST_FP64_DATA_SQUARE_UNIT[i])) {
print_testing_error("A square unit value was not recognized"); print_testing_error("A square unit value was not recognized");
return; return;
} }
@ -157,7 +157,7 @@ void test_is_sqare_unit_fp64()
// Testing non-unit values: // Testing non-unit values:
for (int i = 0; i < _TEST_FP64_DATA_SQUARE_NONUNIT_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_DATA_SQUARE_NONUNIT_AMOUNT; i++) {
if (bgc_is_sqare_unit_fp64(_TEST_FP64_DATA_SQUARE_NONUNIT[i])) { if (bgc_fp64_is_square_unit(_TEST_FP64_DATA_SQUARE_NONUNIT[i])) {
print_testing_error("A non-unit value was recognized as a square unit value"); print_testing_error("A non-unit value was recognized as a square unit value");
return; return;
} }
@ -171,6 +171,6 @@ void test_is_unit()
test_is_unit_fp32(); test_is_unit_fp32();
test_is_unit_fp64(); test_is_unit_fp64();
test_is_sqare_unit_fp32(); test_is_square_unit_fp32();
test_is_sqare_unit_fp64(); test_is_square_unit_fp64();
} }

4
basic-geometry-test/tests/utilities/is_unit.h
View file

@ -5,9 +5,9 @@ void test_is_unit_fp32();
void test_is_unit_fp64(); void test_is_unit_fp64();
void test_is_sqare_unit_fp32(); void test_is_square_unit_fp32();
void test_is_sqare_unit_fp64(); void test_is_square_unit_fp64();
void test_is_unit(); void test_is_unit();

28
basic-geometry-test/tests/utilities/is_zero.c
View file

@ -9,24 +9,24 @@ static const int _TEST_FP32_NONZERO_NUMBERS_AMOUNT = 4;
static const float _TEST_FP32_ZERO_NUMBERS[] = { static const float _TEST_FP32_ZERO_NUMBERS[] = {
0.0f, 0.0f,
0.75f * BGC_EPSYLON_FP32, 0.75f * BGC_FP32_EPSYLON,
-0.75f * BGC_EPSYLON_FP32 -0.75f * BGC_FP32_EPSYLON
}; };
static const float _TEST_FP32_NONZERO_NUMBERS[] = { static const float _TEST_FP32_NONZERO_NUMBERS[] = {
1.0f, 1.0f,
-1.0f, -1.0f,
1.25f * BGC_EPSYLON_FP32, 1.25f * BGC_FP32_EPSYLON,
-1.25f * BGC_EPSYLON_FP32 -1.25f * BGC_FP32_EPSYLON
}; };
void test_is_zero_fp32() void test_is_zero_fp32()
{ {
print_testing_name("bgc_is_zero_fp32"); print_testing_name("bgc_fp32_is_zero");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP32_ZERO_NUMBERS_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_ZERO_NUMBERS_AMOUNT; i++) {
if (!bgc_is_zero_fp32(_TEST_FP32_ZERO_NUMBERS[i])) { if (!bgc_fp32_is_zero(_TEST_FP32_ZERO_NUMBERS[i])) {
print_testing_error("A zero value was not recognized"); print_testing_error("A zero value was not recognized");
return; return;
} }
@ -34,7 +34,7 @@ void test_is_zero_fp32()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP32_NONZERO_NUMBERS_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_NONZERO_NUMBERS_AMOUNT; i++) {
if (bgc_is_zero_fp32(_TEST_FP32_NONZERO_NUMBERS[i])) { if (bgc_fp32_is_zero(_TEST_FP32_NONZERO_NUMBERS[i])) {
print_testing_error("A non-zero value was recognized as a zero value"); print_testing_error("A non-zero value was recognized as a zero value");
return; return;
} }
@ -50,24 +50,24 @@ static const int _TEST_FP64_NONZERO_NUMBERS_AMOUNT = 4;
static const double _TEST_FP64_ZERO_NUMBERS[] = { static const double _TEST_FP64_ZERO_NUMBERS[] = {
0.0, 0.0,
0.75 * BGC_EPSYLON_FP64, 0.75 * BGC_FP64_EPSYLON,
-0.75 * BGC_EPSYLON_FP64 -0.75 * BGC_FP64_EPSYLON
}; };
static const double _TEST_FP64_NONZERO_NUMBERS[] = { static const double _TEST_FP64_NONZERO_NUMBERS[] = {
1.0, 1.0,
-1.0, -1.0,
1.25 * BGC_EPSYLON_FP64, 1.25 * BGC_FP64_EPSYLON,
-1.25 * BGC_EPSYLON_FP64 -1.25 * BGC_FP64_EPSYLON
}; };
void test_is_zero_fp64() void test_is_zero_fp64()
{ {
print_testing_name("bgc_is_zero_fp64"); print_testing_name("bgc_fp64_is_zero");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP64_ZERO_NUMBERS_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_ZERO_NUMBERS_AMOUNT; i++) {
if (!bgc_is_zero_fp64(_TEST_FP64_ZERO_NUMBERS[i])) { if (!bgc_fp64_is_zero(_TEST_FP64_ZERO_NUMBERS[i])) {
print_testing_error("A zero value was not recognized"); print_testing_error("A zero value was not recognized");
return; return;
} }
@ -75,7 +75,7 @@ void test_is_zero_fp64()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP64_NONZERO_NUMBERS_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_NONZERO_NUMBERS_AMOUNT; i++) {
if (bgc_is_zero_fp64(_TEST_FP64_NONZERO_NUMBERS[i])) { if (bgc_fp64_is_zero(_TEST_FP64_NONZERO_NUMBERS[i])) {
print_testing_error("A non-zero value was recognized as a zero value"); print_testing_error("A non-zero value was recognized as a zero value");
return; return;
} }

20
basic-geometry-test/tests/vector2.c
View file

@ -22,7 +22,7 @@ void test_vector2()
const int TEST_FP32_VECTOR2_AMOUNT_1 = 5; const int TEST_FP32_VECTOR2_AMOUNT_1 = 5;
const BgcVector2FP32 TEST_FP32_VECTOR2_COMMON_1[] = { const BGC_FP32_Vector2 TEST_FP32_VECTOR2_COMMON_1[] = {
{ 3.0f, 4.0f }, { 3.0f, 4.0f },
{ -3.0f, -4.0f }, { -3.0f, -4.0f },
{ 10000.0f, -20000.0f }, { 10000.0f, -20000.0f },
@ -30,7 +30,7 @@ const BgcVector2FP32 TEST_FP32_VECTOR2_COMMON_1[] = {
{ -123.5f, 3.7283f } { -123.5f, 3.7283f }
}; };
const BgcVector2FP32 TEST_FP32_VECTOR2_COMMON_2[] = { const BGC_FP32_Vector2 TEST_FP32_VECTOR2_COMMON_2[] = {
{ -3.0f, -4.0f }, { -3.0f, -4.0f },
{ -3.0f, -4.0f }, { -3.0f, -4.0f },
{ 0.002f, -0.05f }, { 0.002f, -0.05f },
@ -49,7 +49,7 @@ int test_vector2_fp32_square_modulus()
float square_modulus; float square_modulus;
for (int i = 0; i < TEST_FP32_VECTOR2_AMOUNT_1; i++) { for (int i = 0; i < TEST_FP32_VECTOR2_AMOUNT_1; i++) {
square_modulus = bgc_vector2_get_square_modulus_fp32(&TEST_FP32_VECTOR2_COMMON_1[i]); square_modulus = bgc_fp32_vector2_get_square_modulus(&TEST_FP32_VECTOR2_COMMON_1[i]);
if (!test_are_equal_fp32(square_modulus, FP32_VECTOR2_SQUARE_MODULUS_1[i])) { if (!test_are_equal_fp32(square_modulus, FP32_VECTOR2_SQUARE_MODULUS_1[i])) {
print_testing_failed(); print_testing_failed();
@ -72,7 +72,7 @@ int test_vector2_fp32_modulus()
float square_modulus; float square_modulus;
for (int i = 0; i < TEST_FP32_VECTOR2_AMOUNT_1; i++) { for (int i = 0; i < TEST_FP32_VECTOR2_AMOUNT_1; i++) {
square_modulus = bgc_vector2_get_modulus_fp32(&TEST_FP32_VECTOR2_COMMON_1[i]); square_modulus = bgc_fp32_vector2_get_modulus(&TEST_FP32_VECTOR2_COMMON_1[i]);
if (!test_are_equal_fp32(square_modulus, FP32_VECTOR2_MODULUS_1[i])) { if (!test_are_equal_fp32(square_modulus, FP32_VECTOR2_MODULUS_1[i])) {
print_testing_failed(); print_testing_failed();
@ -86,7 +86,7 @@ int test_vector2_fp32_modulus()
// ===================== Add ==================== // // ===================== Add ==================== //
const BgcVector2FP32 TEST_FP32_VECTOR2_COMMON_1_2_SUM[] = { const BGC_FP32_Vector2 TEST_FP32_VECTOR2_COMMON_1_2_SUM[] = {
{ 0.0f, 0.0f }, { 0.0f, 0.0f },
{ -6.0f, -8.0f }, { -6.0f, -8.0f },
{ 10000.002f, -20000.05f }, { 10000.002f, -20000.05f },
@ -98,10 +98,10 @@ int test_vector2_add_fp32()
{ {
print_testing_name("vector2_fp32_t add"); print_testing_name("vector2_fp32_t add");
BgcVector2FP32 vector; BGC_FP32_Vector2 vector;
for (int i = 0; i < TEST_FP32_VECTOR2_AMOUNT_1; i++) { for (int i = 0; i < TEST_FP32_VECTOR2_AMOUNT_1; i++) {
bgc_vector2_add_fp32(&TEST_FP32_VECTOR2_COMMON_1[i], &TEST_FP32_VECTOR2_COMMON_2[i], &vector); bgc_fp32_vector2_add(&TEST_FP32_VECTOR2_COMMON_1[i], &TEST_FP32_VECTOR2_COMMON_2[i], &vector);
if (!test_are_equal_fp32(vector.x1, TEST_FP32_VECTOR2_COMMON_1_2_SUM[i].x1) || if (!test_are_equal_fp32(vector.x1, TEST_FP32_VECTOR2_COMMON_1_2_SUM[i].x1) ||
!test_are_equal_fp32(vector.x2, TEST_FP32_VECTOR2_COMMON_1_2_SUM[i].x2)) { !test_are_equal_fp32(vector.x2, TEST_FP32_VECTOR2_COMMON_1_2_SUM[i].x2)) {
@ -116,7 +116,7 @@ int test_vector2_add_fp32()
// ================== Subtract ================== // // ================== Subtract ================== //
const BgcVector2FP32 TEST_FP32_VECTOR2_COMMON_1_2_DIFF[] = { const BGC_FP32_Vector2 TEST_FP32_VECTOR2_COMMON_1_2_DIFF[] = {
{ 6.0f, 8.0f }, { 6.0f, 8.0f },
{ 0.0f, 0.0f }, { 0.0f, 0.0f },
{ 9999.998f, -19999.95f }, { 9999.998f, -19999.95f },
@ -128,10 +128,10 @@ int test_vector2_subtract_fp32()
{ {
print_testing_name("vector2_fp32_t subtract"); print_testing_name("vector2_fp32_t subtract");
BgcVector2FP32 vector; BGC_FP32_Vector2 vector;
for (int i = 0; i < TEST_FP32_VECTOR2_AMOUNT_1; i++) { for (int i = 0; i < TEST_FP32_VECTOR2_AMOUNT_1; i++) {
bgc_vector2_subtract_fp32(&TEST_FP32_VECTOR2_COMMON_1[i], &TEST_FP32_VECTOR2_COMMON_2[i], &vector); bgc_fp32_vector2_subtract(&TEST_FP32_VECTOR2_COMMON_1[i], &TEST_FP32_VECTOR2_COMMON_2[i], &vector);
if (!test_are_equal_fp32(vector.x1, TEST_FP32_VECTOR2_COMMON_1_2_DIFF[i].x1) || if (!test_are_equal_fp32(vector.x1, TEST_FP32_VECTOR2_COMMON_1_2_DIFF[i].x1) ||
!test_are_equal_fp32(vector.x2, TEST_FP32_VECTOR2_COMMON_1_2_DIFF[i].x2)) { !test_are_equal_fp32(vector.x2, TEST_FP32_VECTOR2_COMMON_1_2_DIFF[i].x2)) {

16
basic-geometry-test/tests/vector2/vector2_copy.c
View file

@ -7,7 +7,7 @@
// ==================== FP32 ==================== // // ==================== FP32 ==================== //
static const int _TEST_FP32_VECTOR2_AMOUNT = 4; static const int _TEST_FP32_VECTOR2_AMOUNT = 4;
static const BgcVector2FP32 _TEST_FP32_VECTOR2_LIST[] = { static const BGC_FP32_Vector2 _TEST_FP32_VECTOR2_LIST[] = {
{ 1.0f, 2.0f }, { 1.0f, 2.0f },
{ -2.0f, -1.0f }, { -2.0f, -1.0f },
{ 100.0f, -100.0f }, { 100.0f, -100.0f },
@ -16,13 +16,13 @@ static const BgcVector2FP32 _TEST_FP32_VECTOR2_LIST[] = {
void test_vector2_copy_fp32() void test_vector2_copy_fp32()
{ {
BgcVector2FP32 vector; BGC_FP32_Vector2 vector;
print_testing_name("bgc_vector2_copy_fp32"); print_testing_name("bgc_fp32_vector2_copy");
for (int i = 0; i < _TEST_FP32_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_VECTOR2_AMOUNT; i++) {
bgc_vector2_copy_fp32(&_TEST_FP32_VECTOR2_LIST[i], &vector); bgc_fp32_vector2_copy(&_TEST_FP32_VECTOR2_LIST[i], &vector);
if (vector.x1 != _TEST_FP32_VECTOR2_LIST[i].x1 || vector.x2 != _TEST_FP32_VECTOR2_LIST[i].x2) { if (vector.x1 != _TEST_FP32_VECTOR2_LIST[i].x1 || vector.x2 != _TEST_FP32_VECTOR2_LIST[i].x2) {
print_testing_failed(); print_testing_failed();
@ -36,7 +36,7 @@ void test_vector2_copy_fp32()
// ==================== FP64 ==================== // // ==================== FP64 ==================== //
static const int _TEST_FP64_VECTOR2_AMOUNT = 4; static const int _TEST_FP64_VECTOR2_AMOUNT = 4;
static const BgcVector2FP64 _TEST_FP64_VECTOR2_LIST[] = { static const BGC_FP64_Vector2 _TEST_FP64_VECTOR2_LIST[] = {
{ 1.0, 2.0 }, { 1.0, 2.0 },
{ -2.0, -1.0 }, { -2.0, -1.0 },
{ 100.0, -100.0 }, { 100.0, -100.0 },
@ -45,13 +45,13 @@ static const BgcVector2FP64 _TEST_FP64_VECTOR2_LIST[] = {
void test_vector2_copy_fp64() void test_vector2_copy_fp64()
{ {
BgcVector2FP64 vector; BGC_FP64_Vector2 vector;
print_testing_name("bgc_vector2_copy_fp64"); print_testing_name("bgc_fp64_vector2_copy");
for (int i = 0; i < _TEST_FP64_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_VECTOR2_AMOUNT; i++) {
bgc_vector2_copy_fp64(&_TEST_FP64_VECTOR2_LIST[i], &vector); bgc_fp64_vector2_copy(&_TEST_FP64_VECTOR2_LIST[i], &vector);
if (vector.x1 != _TEST_FP64_VECTOR2_LIST[i].x1 || vector.x2 != _TEST_FP64_VECTOR2_LIST[i].x2) { if (vector.x1 != _TEST_FP64_VECTOR2_LIST[i].x1 || vector.x2 != _TEST_FP64_VECTOR2_LIST[i].x2) {
print_testing_failed(); print_testing_failed();

60
basic-geometry-test/tests/vector2/vector2_is_unit.c
View file

@ -7,32 +7,32 @@
static const int _TEST_FP32_UNIT_VECTOR2_AMOUNT = 6; static const int _TEST_FP32_UNIT_VECTOR2_AMOUNT = 6;
static const int _TEST_FP32_NONUNIT_VECTOR2_AMOUNT = 7; static const int _TEST_FP32_NONUNIT_VECTOR2_AMOUNT = 7;
static const BgcVector2FP32 _TEST_FP32_UNIT_VECTOR2_LIST[] = { static const BGC_FP32_Vector2 _TEST_FP32_UNIT_VECTOR2_LIST[] = {
{ 1.0f, 0.0f }, { 1.0f, 0.0f },
{ 0.0f, -1.0f }, { 0.0f, -1.0f },
{ 1.0f + 0.75f * BGC_EPSYLON_FP32, 0.0f }, { 1.0f + 0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 1.0f - 0.75f * BGC_EPSYLON_FP32, 0.0f }, { 1.0f - 0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 1.0f + 0.75f * BGC_EPSYLON_FP32 }, { 0.0f, 1.0f + 0.75f * BGC_FP32_EPSYLON },
{ 0.0f, 1.0f - 0.75f * BGC_EPSYLON_FP32 } { 0.0f, 1.0f - 0.75f * BGC_FP32_EPSYLON }
}; };
static const BgcVector2FP32 _TEST_FP32_NONUNIT_VECTOR2_LIST[] = { static const BGC_FP32_Vector2 _TEST_FP32_NONUNIT_VECTOR2_LIST[] = {
{ 0.0f, 0.0f }, { 0.0f, 0.0f },
{ 1.0f + 1.25f * BGC_EPSYLON_FP32, 0.0f }, { 1.0f + 1.25f * BGC_FP32_EPSYLON, 0.0f },
{ 1.0f - 1.25f * BGC_EPSYLON_FP32, 0.0f }, { 1.0f - 1.25f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 1.0f + 1.25f * BGC_EPSYLON_FP32 }, { 0.0f, 1.0f + 1.25f * BGC_FP32_EPSYLON },
{ 0.0f, 1.0f - 1.25f * BGC_EPSYLON_FP32 }, { 0.0f, 1.0f - 1.25f * BGC_FP32_EPSYLON },
{ 0.8f + 1.25f * BGC_EPSYLON_FP32, 0.6f + 1.25f * BGC_EPSYLON_FP32 }, { 0.8f + 1.25f * BGC_FP32_EPSYLON, 0.6f + 1.25f * BGC_FP32_EPSYLON },
{ 0.6f - 1.25f * BGC_EPSYLON_FP32, 0.8f - 1.25f * BGC_EPSYLON_FP32 } { 0.6f - 1.25f * BGC_FP32_EPSYLON, 0.8f - 1.25f * BGC_FP32_EPSYLON }
}; };
void test_vector2_is_unit_fp32() void test_vector2_is_unit_fp32()
{ {
print_testing_name("bgc_vector2_is_unit_fp32"); print_testing_name("bgc_fp32_vector2_is_unit");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP32_UNIT_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_UNIT_VECTOR2_AMOUNT; i++) {
if (!bgc_vector2_is_unit_fp32(&_TEST_FP32_UNIT_VECTOR2_LIST[i])) { if (!bgc_fp32_vector2_is_unit(&_TEST_FP32_UNIT_VECTOR2_LIST[i])) {
print_testing_error("A unit vector was not recognized"); print_testing_error("A unit vector was not recognized");
return; return;
} }
@ -40,7 +40,7 @@ void test_vector2_is_unit_fp32()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP32_NONUNIT_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_NONUNIT_VECTOR2_AMOUNT; i++) {
if (bgc_vector2_is_unit_fp32(&_TEST_FP32_NONUNIT_VECTOR2_LIST[i])) { if (bgc_fp32_vector2_is_unit(&_TEST_FP32_NONUNIT_VECTOR2_LIST[i])) {
print_testing_error("A non-unit vector was recognized as a unit vector"); print_testing_error("A non-unit vector was recognized as a unit vector");
return; return;
} }
@ -54,32 +54,32 @@ void test_vector2_is_unit_fp32()
static const int _TEST_FP64_UNIT_VECTOR2_AMOUNT = 6; static const int _TEST_FP64_UNIT_VECTOR2_AMOUNT = 6;
static const int _TEST_FP64_NONUNIT_VECTOR2_AMOUNT = 7; static const int _TEST_FP64_NONUNIT_VECTOR2_AMOUNT = 7;
static const BgcVector2FP64 _TEST_FP64_UNIT_VECTOR2_LIST[] = { static const BGC_FP64_Vector2 _TEST_FP64_UNIT_VECTOR2_LIST[] = {
{ -1.0, 0.0 }, { -1.0, 0.0 },
{ 0.0, 1.0 }, { 0.0, 1.0 },
{ 1.0 + 0.75 * BGC_EPSYLON_FP64, 0.0 }, { 1.0 + 0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 1.0 - 0.75 * BGC_EPSYLON_FP64, 0.0 }, { 1.0 - 0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 1.0 + 0.75 * BGC_EPSYLON_FP64 }, { 0.0, 1.0 + 0.75 * BGC_FP64_EPSYLON },
{ 0.0, 1.0 - 0.75 * BGC_EPSYLON_FP64 } { 0.0, 1.0 - 0.75 * BGC_FP64_EPSYLON }
}; };
static const BgcVector2FP64 _TEST_FP64_NONUNIT_VECTOR2_LIST[] = { static const BGC_FP64_Vector2 _TEST_FP64_NONUNIT_VECTOR2_LIST[] = {
{ 0.0, 0.0 }, { 0.0, 0.0 },
{ 1.0 + 1.25 * BGC_EPSYLON_FP64, 0.0 }, { 1.0 + 1.25 * BGC_FP64_EPSYLON, 0.0 },
{ 1.0 - 1.25 * BGC_EPSYLON_FP64, 0.0 }, { 1.0 - 1.25 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 1.0 + 1.25 * BGC_EPSYLON_FP64 }, { 0.0, 1.0 + 1.25 * BGC_FP64_EPSYLON },
{ 0.0, 1.0 - 1.25 * BGC_EPSYLON_FP64 }, { 0.0, 1.0 - 1.25 * BGC_FP64_EPSYLON },
{ 0.6 + 1.25 * BGC_EPSYLON_FP64, 0.8 + 1.25 * BGC_EPSYLON_FP64 }, { 0.6 + 1.25 * BGC_FP64_EPSYLON, 0.8 + 1.25 * BGC_FP64_EPSYLON },
{ 0.8 - 1.25 * BGC_EPSYLON_FP64, 0.6 - 1.25 * BGC_EPSYLON_FP64 } { 0.8 - 1.25 * BGC_FP64_EPSYLON, 0.6 - 1.25 * BGC_FP64_EPSYLON }
}; };
void test_vector2_is_unit_fp64() void test_vector2_is_unit_fp64()
{ {
print_testing_name("bgc_vector2_is_unit_fp64"); print_testing_name("bgc_fp64_vector2_is_unit");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP64_UNIT_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_UNIT_VECTOR2_AMOUNT; i++) {
if (!bgc_vector2_is_unit_fp64(&_TEST_FP64_UNIT_VECTOR2_LIST[i])) { if (!bgc_fp64_vector2_is_unit(&_TEST_FP64_UNIT_VECTOR2_LIST[i])) {
print_testing_error("A unit vector was not recognized"); print_testing_error("A unit vector was not recognized");
return; return;
} }
@ -87,7 +87,7 @@ void test_vector2_is_unit_fp64()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP64_NONUNIT_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_NONUNIT_VECTOR2_AMOUNT; i++) {
if (bgc_vector2_is_unit_fp64(&_TEST_FP64_NONUNIT_VECTOR2_LIST[i])) { if (bgc_fp64_vector2_is_unit(&_TEST_FP64_NONUNIT_VECTOR2_LIST[i])) {
print_testing_error("A non-unit vector was recognized as a unit vector"); print_testing_error("A non-unit vector was recognized as a unit vector");
return; return;
} }

60
basic-geometry-test/tests/vector2/vector2_is_zero.c
View file

@ -7,31 +7,31 @@
static const int _TEST_FP32_ZERO_VECTOR2_AMOUNT = 5; static const int _TEST_FP32_ZERO_VECTOR2_AMOUNT = 5;
static const int _TEST_FP32_NONZERO_VECTOR2_AMOUNT = 7; static const int _TEST_FP32_NONZERO_VECTOR2_AMOUNT = 7;
static const BgcVector2FP32 _TEST_FP32_ZERO_VECTOR2_LIST[] = { static const BGC_FP32_Vector2 _TEST_FP32_ZERO_VECTOR2_LIST[] = {
{ 0.0f, 0.0f }, { 0.0f, 0.0f },
{ 0.75f * BGC_EPSYLON_FP32, 0.0f }, { 0.75f * BGC_FP32_EPSYLON, 0.0f },
{ -0.75f * BGC_EPSYLON_FP32, 0.0f }, { -0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 0.75f * BGC_EPSYLON_FP32 }, { 0.0f, 0.75f * BGC_FP32_EPSYLON },
{ 0.0f, -0.75f * BGC_EPSYLON_FP32 } { 0.0f, -0.75f * BGC_FP32_EPSYLON }
}; };
static const BgcVector2FP32 _TEST_FP32_NONZERO_VECTOR2_LIST[] = { static const BGC_FP32_Vector2 _TEST_FP32_NONZERO_VECTOR2_LIST[] = {
{ 0.0f, 1.0f }, { 0.0f, 1.0f },
{ 1.25f * BGC_EPSYLON_FP32, 0.0f }, { 1.25f * BGC_FP32_EPSYLON, 0.0f },
{ -1.25f * BGC_EPSYLON_FP32, 0.0f }, { -1.25f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 1.25f * BGC_EPSYLON_FP32 }, { 0.0f, 1.25f * BGC_FP32_EPSYLON },
{ 0.0f, -1.25f * BGC_EPSYLON_FP32 }, { 0.0f, -1.25f * BGC_FP32_EPSYLON },
{ 1.25f * BGC_EPSYLON_FP32, 1.25f * BGC_EPSYLON_FP32 }, { 1.25f * BGC_FP32_EPSYLON, 1.25f * BGC_FP32_EPSYLON },
{ -1.25f * BGC_EPSYLON_FP32, -1.25f * BGC_EPSYLON_FP32 } { -1.25f * BGC_FP32_EPSYLON, -1.25f * BGC_FP32_EPSYLON }
}; };
void test_vector2_is_zero_fp32() void test_vector2_is_zero_fp32()
{ {
print_testing_name("bgc_vector2_is_zero_fp32"); print_testing_name("bgc_fp32_vector2_is_zero");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP32_ZERO_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_ZERO_VECTOR2_AMOUNT; i++) {
if (!bgc_vector2_is_zero_fp32(&_TEST_FP32_ZERO_VECTOR2_LIST[i])) { if (!bgc_fp32_vector2_is_zero(&_TEST_FP32_ZERO_VECTOR2_LIST[i])) {
print_testing_error("A zero vector was not recongized"); print_testing_error("A zero vector was not recongized");
return; return;
} }
@ -39,7 +39,7 @@ void test_vector2_is_zero_fp32()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP32_NONZERO_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_NONZERO_VECTOR2_AMOUNT; i++) {
if (bgc_vector2_is_zero_fp32(&_TEST_FP32_NONZERO_VECTOR2_LIST[i])) { if (bgc_fp32_vector2_is_zero(&_TEST_FP32_NONZERO_VECTOR2_LIST[i])) {
print_testing_error("A non-zero vector was recongized as a zero vector"); print_testing_error("A non-zero vector was recongized as a zero vector");
return; return;
} }
@ -53,31 +53,31 @@ void test_vector2_is_zero_fp32()
static const int _TEST_FP64_ZERO_VECTOR2_AMOUNT = 5; static const int _TEST_FP64_ZERO_VECTOR2_AMOUNT = 5;
static const int _TEST_FP64_NONZERO_VECTOR2_AMOUNT = 7; static const int _TEST_FP64_NONZERO_VECTOR2_AMOUNT = 7;
static const BgcVector2FP64 _TEST_FP64_ZERO_VECTOR2_LIST[] = { static const BGC_FP64_Vector2 _TEST_FP64_ZERO_VECTOR2_LIST[] = {
{ 0.0, 0.0 }, { 0.0, 0.0 },
{ 0.75 * BGC_EPSYLON_FP64, 0.0 }, { 0.75 * BGC_FP64_EPSYLON, 0.0 },
{ -0.75 * BGC_EPSYLON_FP64, 0.0 }, { -0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 0.75 * BGC_EPSYLON_FP64 }, { 0.0, 0.75 * BGC_FP64_EPSYLON },
{ 0.0, -0.75 * BGC_EPSYLON_FP64 } { 0.0, -0.75 * BGC_FP64_EPSYLON }
}; };
static const BgcVector2FP64 _TEST_FP64_NONZERO_VECTOR2_LIST[] = { static const BGC_FP64_Vector2 _TEST_FP64_NONZERO_VECTOR2_LIST[] = {
{ 0.0, 1.0 }, { 0.0, 1.0 },
{ 1.25 * BGC_EPSYLON_FP64, 0.0 }, { 1.25 * BGC_FP64_EPSYLON, 0.0 },
{ -1.25 * BGC_EPSYLON_FP64, 0.0 }, { -1.25 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 1.25 * BGC_EPSYLON_FP64 }, { 0.0, 1.25 * BGC_FP64_EPSYLON },
{ 0.0, -1.25 * BGC_EPSYLON_FP64 }, { 0.0, -1.25 * BGC_FP64_EPSYLON },
{ 1.25 * BGC_EPSYLON_FP64, 1.25 * BGC_EPSYLON_FP64 }, { 1.25 * BGC_FP64_EPSYLON, 1.25 * BGC_FP64_EPSYLON },
{ -1.25 * BGC_EPSYLON_FP64, -1.25 * BGC_EPSYLON_FP64 } { -1.25 * BGC_FP64_EPSYLON, -1.25 * BGC_FP64_EPSYLON }
}; };
void test_vector2_is_zero_fp64() void test_vector2_is_zero_fp64()
{ {
print_testing_name("bgc_vector2_is_zero_fp64"); print_testing_name("bgc_fp64_vector2_is_zero");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP64_ZERO_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_ZERO_VECTOR2_AMOUNT; i++) {
if (!bgc_vector2_is_zero_fp64(&_TEST_FP64_ZERO_VECTOR2_LIST[i])) { if (!bgc_fp64_vector2_is_zero(&_TEST_FP64_ZERO_VECTOR2_LIST[i])) {
print_testing_error("A zero vector was not recongized"); print_testing_error("A zero vector was not recongized");
return; return;
} }
@ -85,7 +85,7 @@ void test_vector2_is_zero_fp64()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP64_NONZERO_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_NONZERO_VECTOR2_AMOUNT; i++) {
if (bgc_vector2_is_zero_fp64(&_TEST_FP64_NONZERO_VECTOR2_LIST[i])) { if (bgc_fp64_vector2_is_zero(&_TEST_FP64_NONZERO_VECTOR2_LIST[i])) {
print_testing_error("A non-zero vector was recongized as a zero vector"); print_testing_error("A non-zero vector was recongized as a zero vector");
return; return;
} }

20
basic-geometry-test/tests/vector2/vector2_modulus.c
View file

@ -6,7 +6,7 @@
static const int _TEST_FP32_VECTOR2_AMOUNT = 4; static const int _TEST_FP32_VECTOR2_AMOUNT = 4;
static const BgcVector2FP32 _TEST_FP32_VECTOR2_LIST[] = { static const BGC_FP32_Vector2 _TEST_FP32_VECTOR2_LIST[] = {
{ 4.0f, 3.0f }, { 4.0f, 3.0f },
{ -3.0f, -4.0f }, { -3.0f, -4.0f },
{ 100.0f, -100.0f }, { 100.0f, -100.0f },
@ -29,10 +29,10 @@ static const float _TEST_FP32_MODULUS_LIST[] = {
void test_vector2_square_modulus_fp32() void test_vector2_square_modulus_fp32()
{ {
print_testing_name("bgc_vector2_get_square_modulus_fp32"); print_testing_name("bgc_fp32_vector2_get_square_modulus");
for (int i = 0; i < _TEST_FP32_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_VECTOR2_AMOUNT; i++) {
if (!bgc_are_close_fp32(bgc_vector2_get_square_modulus_fp32(&_TEST_FP32_VECTOR2_LIST[i]), _TEST_FP32_SQUARE_MODULUS_LIST[i])) { if (!bgc_fp32_are_close(bgc_fp32_vector2_get_square_modulus(&_TEST_FP32_VECTOR2_LIST[i]), _TEST_FP32_SQUARE_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }
@ -43,10 +43,10 @@ void test_vector2_square_modulus_fp32()
void test_vector2_modulus_fp32() void test_vector2_modulus_fp32()
{ {
print_testing_name("bgc_vector2_get_modulus_fp32"); print_testing_name("bgc_fp32_vector2_get_modulus");
for (int i = 0; i < _TEST_FP32_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_VECTOR2_AMOUNT; i++) {
if (!bgc_are_close_fp32(bgc_vector2_get_modulus_fp32(&_TEST_FP32_VECTOR2_LIST[i]), _TEST_FP32_MODULUS_LIST[i])) { if (!bgc_fp32_are_close(bgc_fp32_vector2_get_modulus(&_TEST_FP32_VECTOR2_LIST[i]), _TEST_FP32_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }
@ -59,7 +59,7 @@ void test_vector2_modulus_fp32()
static const int _TEST_FP64_VECTOR2_AMOUNT = 4; static const int _TEST_FP64_VECTOR2_AMOUNT = 4;
static const BgcVector2FP64 _TEST_FP64_VECTOR2_LIST[] = { static const BGC_FP64_Vector2 _TEST_FP64_VECTOR2_LIST[] = {
{ 4.0, 3.0 }, { 4.0, 3.0 },
{ -3.0, -4.0 }, { -3.0, -4.0 },
{ 100.0, -100.0 }, { 100.0, -100.0 },
@ -82,10 +82,10 @@ static const double _TEST_FP64_MODULUS_LIST[] = {
void test_vector2_square_modulus_fp64() void test_vector2_square_modulus_fp64()
{ {
print_testing_name("bgc_vector2_get_square_modulus_fp64"); print_testing_name("bgc_fp64_vector2_get_square_modulus");
for (int i = 0; i < _TEST_FP64_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_VECTOR2_AMOUNT; i++) {
if (!bgc_are_close_fp64(bgc_vector2_get_square_modulus_fp64(&_TEST_FP64_VECTOR2_LIST[i]), _TEST_FP64_SQUARE_MODULUS_LIST[i])) { if (!bgc_fp64_are_close(bgc_fp64_vector2_get_square_modulus(&_TEST_FP64_VECTOR2_LIST[i]), _TEST_FP64_SQUARE_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }
@ -96,10 +96,10 @@ void test_vector2_square_modulus_fp64()
void test_vector2_modulus_fp64() void test_vector2_modulus_fp64()
{ {
print_testing_name("bgc_vector2_get_modulus_fp64"); print_testing_name("bgc_fp64_vector2_get_modulus");
for (int i = 0; i < _TEST_FP64_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_VECTOR2_AMOUNT; i++) {
if (!bgc_are_close_fp64(bgc_vector2_get_modulus_fp64(&_TEST_FP64_VECTOR2_LIST[i]), _TEST_FP64_MODULUS_LIST[i])) { if (!bgc_fp64_are_close(bgc_fp64_vector2_get_modulus(&_TEST_FP64_VECTOR2_LIST[i]), _TEST_FP64_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }

12
basic-geometry-test/tests/vector2/vector2_reset.c
View file

@ -4,11 +4,11 @@
void test_vector2_reset_fp32() void test_vector2_reset_fp32()
{ {
BgcVector2FP32 vector; BGC_FP32_Vector2 vector;
print_testing_name("bgc_vector2_reset_fp32"); print_testing_name("bgc_fp32_vector2_reset");
bgc_vector2_reset_fp32(&vector); bgc_fp32_vector2_reset(&vector);
if (vector.x1 != 0.0f || vector.x2 != 0.0f) { if (vector.x1 != 0.0f || vector.x2 != 0.0f) {
print_testing_failed(); print_testing_failed();
@ -20,11 +20,11 @@ void test_vector2_reset_fp32()
void test_vector2_reset_fp64() void test_vector2_reset_fp64()
{ {
BgcVector2FP64 vector; BGC_FP64_Vector2 vector;
print_testing_name("bgc_vector2_reset_fp64"); print_testing_name("bgc_fp64_vector2_reset");
bgc_vector2_reset_fp64(&vector); bgc_fp64_vector2_reset(&vector);
if (vector.x1 != 0.0 || vector.x2 != 0.0) { if (vector.x1 != 0.0 || vector.x2 != 0.0) {
print_testing_failed(); print_testing_failed();

20
basic-geometry-test/tests/vector2/vector2_set_values.c
View file

@ -8,25 +8,25 @@
void test_vector2_set_values_fp32() void test_vector2_set_values_fp32()
{ {
BgcVector2FP32 vector; BGC_FP32_Vector2 vector;
print_testing_name("bgc_vector2_set_values_fp32"); print_testing_name("bgc_fp32_vector2_make");
bgc_vector2_set_values_fp32(1.0f, 2.0f, &vector); bgc_fp32_vector2_make(1.0f, 2.0f, &vector);
if (vector.x1 != 1.0f || vector.x2 != 2.0f) { if (vector.x1 != 1.0f || vector.x2 != 2.0f) {
print_testing_error("First step failed"); print_testing_error("First step failed");
return; return;
} }
bgc_vector2_set_values_fp32(-3.0f, -5.0f, &vector); bgc_fp32_vector2_make(-3.0f, -5.0f, &vector);
if (vector.x1 != -3.0f || vector.x2 != -5.0f) { if (vector.x1 != -3.0f || vector.x2 != -5.0f) {
print_testing_error("Second step failed"); print_testing_error("Second step failed");
return; return;
} }
bgc_vector2_set_values_fp32(-2.0f, 2.0f, &vector); bgc_fp32_vector2_make(-2.0f, 2.0f, &vector);
if (vector.x1 != -2.0f || vector.x2 != 2.0f) { if (vector.x1 != -2.0f || vector.x2 != 2.0f) {
print_testing_error("Third step failed"); print_testing_error("Third step failed");
@ -40,26 +40,26 @@ void test_vector2_set_values_fp32()
void test_vector2_set_values_fp64() void test_vector2_set_values_fp64()
{ {
BgcVector2FP64 vector; BGC_FP64_Vector2 vector;
print_testing_name("bgc_vector2_set_values_fp64"); print_testing_name("bgc_fp64_vector2_make");
bgc_vector2_set_values_fp64(1.0, 2.0, &vector); bgc_fp64_vector2_make(1.0, 2.0, &vector);
if (vector.x1 != 1.0 || vector.x2 != 2.0) { if (vector.x1 != 1.0 || vector.x2 != 2.0) {
print_testing_error("First step failed"); print_testing_error("First step failed");
return; return;
} }
bgc_vector2_set_values_fp64(-3.0, -5.0, &vector); bgc_fp64_vector2_make(-3.0, -5.0, &vector);
if (vector.x1 != -3.0 || vector.x2 != -5.0) { if (vector.x1 != -3.0 || vector.x2 != -5.0) {
print_testing_error("Second step failed"); print_testing_error("Second step failed");
return; return;
} }
bgc_vector2_set_values_fp64(-2.0, 2.0, &vector); bgc_fp64_vector2_make(-2.0, 2.0, &vector);
if (vector.x1 != -2.0 || vector.x2 != 2.0) { if (vector.x1 != -2.0 || vector.x2 != 2.0) {
print_testing_error("Third step failed"); print_testing_error("Third step failed");

28
basic-geometry-test/tests/vector2/vector2_swap.c
View file

@ -8,14 +8,14 @@
static const int _TEST_FP32_VECTOR2_AMOUNT = 4; static const int _TEST_FP32_VECTOR2_AMOUNT = 4;
static const BgcVector2FP32 _TEST_FP32_VECTOR2_LIST1[] = { static const BGC_FP32_Vector2 _TEST_FP32_VECTOR2_LIST1[] = {
{ 1.0f, 2.0f }, { 1.0f, 2.0f },
{ -2.0f, -1.0f }, { -2.0f, -1.0f },
{ 100.0f, -100.0f }, { 100.0f, -100.0f },
{ -100.1f, 100.2f } { -100.1f, 100.2f }
}; };
static const BgcVector2FP32 _TEST_FP32_VECTOR2_LIST2[] = { static const BGC_FP32_Vector2 _TEST_FP32_VECTOR2_LIST2[] = {
{ 3.6f, 5.3f }, { 3.6f, 5.3f },
{ 204.07f, -781.89f }, { 204.07f, -781.89f },
{ -20.02f, -1.0003f }, { -20.02f, -1.0003f },
@ -24,15 +24,15 @@ static const BgcVector2FP32 _TEST_FP32_VECTOR2_LIST2[] = {
void test_vector2_swap_fp32() void test_vector2_swap_fp32()
{ {
BgcVector2FP32 vector1, vector2; BGC_FP32_Vector2 vector1, vector2;
print_testing_name("bgc_vector2_swap_fp32"); print_testing_name("bgc_fp32_vector2_swap");
for (int i = 0; i < _TEST_FP32_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_VECTOR2_AMOUNT; i++) {
bgc_vector2_copy_fp32(&_TEST_FP32_VECTOR2_LIST1[i], &vector1); bgc_fp32_vector2_copy(&_TEST_FP32_VECTOR2_LIST1[i], &vector1);
bgc_vector2_copy_fp32(&_TEST_FP32_VECTOR2_LIST2[i], &vector2); bgc_fp32_vector2_copy(&_TEST_FP32_VECTOR2_LIST2[i], &vector2);
bgc_vector2_swap_fp32(&vector1, &vector2); bgc_fp32_vector2_swap(&vector1, &vector2);
if (vector1.x1 != _TEST_FP32_VECTOR2_LIST2[i].x1 || if (vector1.x1 != _TEST_FP32_VECTOR2_LIST2[i].x1 ||
vector1.x2 != _TEST_FP32_VECTOR2_LIST2[i].x2 || vector1.x2 != _TEST_FP32_VECTOR2_LIST2[i].x2 ||
@ -50,14 +50,14 @@ void test_vector2_swap_fp32()
static const int _TEST_FP64_VECTOR2_AMOUNT = 4; static const int _TEST_FP64_VECTOR2_AMOUNT = 4;
static const BgcVector2FP64 _TEST_FP64_VECTOR2_LIST1[] = { static const BGC_FP64_Vector2 _TEST_FP64_VECTOR2_LIST1[] = {
{ 1.0, 2.0 }, { 1.0, 2.0 },
{ -2.0, -1.0 }, { -2.0, -1.0 },
{ 100.0, -100.0 }, { 100.0, -100.0 },
{ -100.1, 100.2 } { -100.1, 100.2 }
}; };
static const BgcVector2FP64 _TEST_FP64_VECTOR2_LIST2[] = { static const BGC_FP64_Vector2 _TEST_FP64_VECTOR2_LIST2[] = {
{ 3.6, 5.3 }, { 3.6, 5.3 },
{ 204.07, -781.89 }, { 204.07, -781.89 },
{ -20.02, -1.0003 }, { -20.02, -1.0003 },
@ -66,15 +66,15 @@ static const BgcVector2FP64 _TEST_FP64_VECTOR2_LIST2[] = {
void test_vector2_swap_fp64() void test_vector2_swap_fp64()
{ {
BgcVector2FP64 vector1, vector2; BGC_FP64_Vector2 vector1, vector2;
print_testing_name("bgc_vector2_swap_fp64"); print_testing_name("bgc_fp64_vector2_swap");
for (int i = 0; i < _TEST_FP64_VECTOR2_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_VECTOR2_AMOUNT; i++) {
bgc_vector2_copy_fp64(&_TEST_FP64_VECTOR2_LIST1[i], &vector1); bgc_fp64_vector2_copy(&_TEST_FP64_VECTOR2_LIST1[i], &vector1);
bgc_vector2_copy_fp64(&_TEST_FP64_VECTOR2_LIST2[i], &vector2); bgc_fp64_vector2_copy(&_TEST_FP64_VECTOR2_LIST2[i], &vector2);
bgc_vector2_swap_fp64(&vector1, &vector2); bgc_fp64_vector2_swap(&vector1, &vector2);
if (vector1.x1 != _TEST_FP64_VECTOR2_LIST2[i].x1 || if (vector1.x1 != _TEST_FP64_VECTOR2_LIST2[i].x1 ||
vector1.x2 != _TEST_FP64_VECTOR2_LIST2[i].x2 || vector1.x2 != _TEST_FP64_VECTOR2_LIST2[i].x2 ||

16
basic-geometry-test/tests/vector3/vector3_copy.c
View file

@ -7,7 +7,7 @@
// ==================== FP32 ==================== // // ==================== FP32 ==================== //
static const int _TEST_FP32_VECTOR3_AMOUNT = 4; static const int _TEST_FP32_VECTOR3_AMOUNT = 4;
static const BgcVector3FP32 _TEST_FP32_VECTOR3_LIST[] = { static const BGC_FP32_Vector3 _TEST_FP32_VECTOR3_LIST[] = {
{ 1.0f, 2.0f, 3.0f }, { 1.0f, 2.0f, 3.0f },
{ -3.0f, -2.0f, -1.0f }, { -3.0f, -2.0f, -1.0f },
{ 100.0f, -100.0f, 0.001f }, { 100.0f, -100.0f, 0.001f },
@ -16,13 +16,13 @@ static const BgcVector3FP32 _TEST_FP32_VECTOR3_LIST[] = {
void test_vector3_copy_fp32() void test_vector3_copy_fp32()
{ {
BgcVector3FP32 vector; BGC_FP32_Vector3 vector;
print_testing_name("bgc_vector3_copy_fp32"); print_testing_name("bgc_fp32_vector3_copy");
for (int i = 0; i < _TEST_FP32_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_VECTOR3_AMOUNT; i++) {
bgc_vector3_copy_fp32(&_TEST_FP32_VECTOR3_LIST[i], &vector); bgc_fp32_vector3_copy(&_TEST_FP32_VECTOR3_LIST[i], &vector);
if (vector.x1 != _TEST_FP32_VECTOR3_LIST[i].x1 || if (vector.x1 != _TEST_FP32_VECTOR3_LIST[i].x1 ||
vector.x2 != _TEST_FP32_VECTOR3_LIST[i].x2 || vector.x2 != _TEST_FP32_VECTOR3_LIST[i].x2 ||
@ -38,7 +38,7 @@ void test_vector3_copy_fp32()
// ==================== FP64 ==================== // // ==================== FP64 ==================== //
static const int _TEST_FP64_VECTOR3_AMOUNT = 4; static const int _TEST_FP64_VECTOR3_AMOUNT = 4;
static const BgcVector3FP64 _TEST_FP64_VECTOR3_LIST[] = { static const BGC_FP64_Vector3 _TEST_FP64_VECTOR3_LIST[] = {
{ 1.0, 2.0, 3.0 }, { 1.0, 2.0, 3.0 },
{ -3.0, -2.0, -1.0 }, { -3.0, -2.0, -1.0 },
{ 100.0, -100.0, 0.001 }, { 100.0, -100.0, 0.001 },
@ -47,13 +47,13 @@ static const BgcVector3FP64 _TEST_FP64_VECTOR3_LIST[] = {
void test_vector3_copy_fp64() void test_vector3_copy_fp64()
{ {
BgcVector3FP64 vector; BGC_FP64_Vector3 vector;
print_testing_name("bgc_vector3_copy_fp64"); print_testing_name("bgc_fp64_vector3_copy");
for (int i = 0; i < _TEST_FP64_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_VECTOR3_AMOUNT; i++) {
bgc_vector3_copy_fp64(&_TEST_FP64_VECTOR3_LIST[i], &vector); bgc_fp64_vector3_copy(&_TEST_FP64_VECTOR3_LIST[i], &vector);
if (vector.x1 != _TEST_FP64_VECTOR3_LIST[i].x1 || if (vector.x1 != _TEST_FP64_VECTOR3_LIST[i].x1 ||
vector.x2 != _TEST_FP64_VECTOR3_LIST[i].x2 || vector.x2 != _TEST_FP64_VECTOR3_LIST[i].x2 ||

76
basic-geometry-test/tests/vector3/vector3_is_unit.c
View file

@ -7,38 +7,38 @@
static const int _TEST_FP32_UNIT_VECTOR3_AMOUNT = 10; static const int _TEST_FP32_UNIT_VECTOR3_AMOUNT = 10;
static const int _TEST_FP32_NONUNIT_VECTOR3_AMOUNT = 9; static const int _TEST_FP32_NONUNIT_VECTOR3_AMOUNT = 9;
static const BgcVector3FP32 _TEST_FP32_UNIT_VECTOR3_LIST[] = { static const BGC_FP32_Vector3 _TEST_FP32_UNIT_VECTOR3_LIST[] = {
{ 1.0f, 0.0f, 0.0f }, { 1.0f, 0.0f, 0.0f },
{ 0.0f, -1.0f, 0.0f }, { 0.0f, -1.0f, 0.0f },
{ 0.0f, -0.8f, 0.6f }, { 0.0f, -0.8f, 0.6f },
{ -0.6f, 0.0f, 0.8f }, { -0.6f, 0.0f, 0.8f },
{ 1.0f + 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 1.0f + 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 1.0f - 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 1.0f - 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 0.0f, -1.0f + 0.75f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, -1.0f + 0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, -1.0f - 0.75f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, -1.0f - 0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 0.0f, 1.0f + 0.75f * BGC_EPSYLON_FP32 }, { 0.0f, 0.0f, 1.0f + 0.75f * BGC_FP32_EPSYLON },
{ 0.0f, 0.0f, 1.0f - 0.75f * BGC_EPSYLON_FP32 } { 0.0f, 0.0f, 1.0f - 0.75f * BGC_FP32_EPSYLON }
}; };
static const BgcVector3FP32 _TEST_FP32_NONUNIT_VECTOR3_LIST[] = { static const BGC_FP32_Vector3 _TEST_FP32_NONUNIT_VECTOR3_LIST[] = {
{ 0.0f, 0.0f, 0.0f }, { 0.0f, 0.0f, 0.0f },
{ 1.0f + 1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 1.0f + 1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 1.0f - 1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 1.0f - 1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 0.0f, 1.0f + 1.25f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, 1.0f + 1.25f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 1.0f - 1.25f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, 1.0f - 1.25f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 0.0f, 1.0f + 1.25f * BGC_EPSYLON_FP32 }, { 0.0f, 0.0f, 1.0f + 1.25f * BGC_FP32_EPSYLON },
{ 0.0f, 0.0f, 1.0f - 1.25f * BGC_EPSYLON_FP32 }, { 0.0f, 0.0f, 1.0f - 1.25f * BGC_FP32_EPSYLON },
{ 0.8f + 1.25f * BGC_EPSYLON_FP32, -0.6f - 1.25f * BGC_EPSYLON_FP32, 0.0f }, { 0.8f + 1.25f * BGC_FP32_EPSYLON, -0.6f - 1.25f * BGC_FP32_EPSYLON, 0.0f },
{ 0.6f - 1.25f * BGC_EPSYLON_FP32, -0.8f + 1.25f * BGC_EPSYLON_FP32, 0.0f } { 0.6f - 1.25f * BGC_FP32_EPSYLON, -0.8f + 1.25f * BGC_FP32_EPSYLON, 0.0f }
}; };
void test_vector3_is_unit_fp32() void test_vector3_is_unit_fp32()
{ {
print_testing_name("bgc_vector3_is_unit_fp32"); print_testing_name("bgc_fp32_vector3_is_unit");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP32_UNIT_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_UNIT_VECTOR3_AMOUNT; i++) {
if (!bgc_vector3_is_unit_fp32(&_TEST_FP32_UNIT_VECTOR3_LIST[i])) { if (!bgc_fp32_vector3_is_unit(&_TEST_FP32_UNIT_VECTOR3_LIST[i])) {
print_testing_error("A unit vector was not recognized"); print_testing_error("A unit vector was not recognized");
return; return;
} }
@ -46,7 +46,7 @@ void test_vector3_is_unit_fp32()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP32_NONUNIT_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_NONUNIT_VECTOR3_AMOUNT; i++) {
if (bgc_vector3_is_unit_fp32(&_TEST_FP32_NONUNIT_VECTOR3_LIST[i])) { if (bgc_fp32_vector3_is_unit(&_TEST_FP32_NONUNIT_VECTOR3_LIST[i])) {
print_testing_error("A non-unit vector was recognized as a unit vector"); print_testing_error("A non-unit vector was recognized as a unit vector");
return; return;
} }
@ -60,38 +60,38 @@ void test_vector3_is_unit_fp32()
static const int _TEST_FP64_UNIT_VECTOR3_AMOUNT = 10; static const int _TEST_FP64_UNIT_VECTOR3_AMOUNT = 10;
static const int _TEST_FP64_NONUNIT_VECTOR3_AMOUNT = 9; static const int _TEST_FP64_NONUNIT_VECTOR3_AMOUNT = 9;
static const BgcVector3FP64 _TEST_FP64_UNIT_VECTOR3_LIST[] = { static const BGC_FP64_Vector3 _TEST_FP64_UNIT_VECTOR3_LIST[] = {
{ 1.0, 0.0, 0.0 }, { 1.0, 0.0, 0.0 },
{ 0.0, -1.0, 0.0 }, { 0.0, -1.0, 0.0 },
{ 0.0, -0.8, 0.6 }, { 0.0, -0.8, 0.6 },
{ -0.6, 0.0, 0.8 }, { -0.6, 0.0, 0.8 },
{ 1.0 + 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 1.0 + 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 1.0 - 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 1.0 - 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 0.0, -1.0 + 0.75 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, -1.0 + 0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, -1.0 - 0.75 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, -1.0 - 0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 0.0, 1.0 + 0.75 * BGC_EPSYLON_FP64 }, { 0.0, 0.0, 1.0 + 0.75 * BGC_FP64_EPSYLON },
{ 0.0, 0.0, 1.0 - 0.75 * BGC_EPSYLON_FP64 } { 0.0, 0.0, 1.0 - 0.75 * BGC_FP64_EPSYLON }
}; };
static const BgcVector3FP64 _TEST_FP64_NONUNIT_VECTOR3_LIST[] = { static const BGC_FP64_Vector3 _TEST_FP64_NONUNIT_VECTOR3_LIST[] = {
{ 0.0, 0.0, 0.0 }, { 0.0, 0.0, 0.0 },
{ 1.0 + 1.25 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 1.0 + 1.25 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 1.0 - 1.25 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 1.0 - 1.25 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 0.0, 1.0 + 1.25 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, 1.0 + 1.25 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 1.0 - 1.25 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, 1.0 - 1.25 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 0.0, 1.0 + 1.25 * BGC_EPSYLON_FP64 }, { 0.0, 0.0, 1.0 + 1.25 * BGC_FP64_EPSYLON },
{ 0.0, 0.0, 1.0 - 1.25 * BGC_EPSYLON_FP64 }, { 0.0, 0.0, 1.0 - 1.25 * BGC_FP64_EPSYLON },
{ 0.8 + 1.25 * BGC_EPSYLON_FP64, -0.6 - 1.25 * BGC_EPSYLON_FP64, 0.0 }, { 0.8 + 1.25 * BGC_FP64_EPSYLON, -0.6 - 1.25 * BGC_FP64_EPSYLON, 0.0 },
{ 0.6 - 1.25 * BGC_EPSYLON_FP64, -0.8 + 1.25 * BGC_EPSYLON_FP64, 0.0 } { 0.6 - 1.25 * BGC_FP64_EPSYLON, -0.8 + 1.25 * BGC_FP64_EPSYLON, 0.0 }
}; };
void test_vector3_is_unit_fp64() void test_vector3_is_unit_fp64()
{ {
print_testing_name("bgc_vector3_is_unit_fp64"); print_testing_name("bgc_fp64_vector3_is_unit");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP64_UNIT_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_UNIT_VECTOR3_AMOUNT; i++) {
if (!bgc_vector3_is_unit_fp64(&_TEST_FP64_UNIT_VECTOR3_LIST[i])) { if (!bgc_fp64_vector3_is_unit(&_TEST_FP64_UNIT_VECTOR3_LIST[i])) {
print_testing_error("A unit vector was not recognized"); print_testing_error("A unit vector was not recognized");
return; return;
} }
@ -99,7 +99,7 @@ void test_vector3_is_unit_fp64()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP64_NONUNIT_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_NONUNIT_VECTOR3_AMOUNT; i++) {
if (bgc_vector3_is_unit_fp64(&_TEST_FP64_NONUNIT_VECTOR3_LIST[i])) { if (bgc_fp64_vector3_is_unit(&_TEST_FP64_NONUNIT_VECTOR3_LIST[i])) {
print_testing_error("A non-unit vector was recognized as a unit vector"); print_testing_error("A non-unit vector was recognized as a unit vector");
return; return;
} }

76
basic-geometry-test/tests/vector3/vector3_is_zero.c
View file

@ -7,35 +7,35 @@
static const int _TEST_FP32_ZERO_VECTOR3_AMOUNT = 7; static const int _TEST_FP32_ZERO_VECTOR3_AMOUNT = 7;
static const int _TEST_FP32_NONZERO_VECTOR3_AMOUNT = 9; static const int _TEST_FP32_NONZERO_VECTOR3_AMOUNT = 9;
static const BgcVector3FP32 _TEST_FP32_ZERO_VECTOR3_LIST[] = { static const BGC_FP32_Vector3 _TEST_FP32_ZERO_VECTOR3_LIST[] = {
{ 0.0f, 0.0f, 0.0f }, { 0.0f, 0.0f, 0.0f },
{ 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ -0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { -0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 0.0f, 0.75f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, 0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, -0.75f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, -0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 0.0f, 0.75f * BGC_EPSYLON_FP32 }, { 0.0f, 0.0f, 0.75f * BGC_FP32_EPSYLON },
{ 0.0f, 0.0f, -0.75f * BGC_EPSYLON_FP32 } { 0.0f, 0.0f, -0.75f * BGC_FP32_EPSYLON }
}; };
static const BgcVector3FP32 _TEST_FP32_NONZERO_VECTOR3_LIST[] = { static const BGC_FP32_Vector3 _TEST_FP32_NONZERO_VECTOR3_LIST[] = {
{ 0.0f, 1.0f, 0.0f }, { 0.0f, 1.0f, 0.0f },
{ 1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ -1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { -1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 0.0f, 1.25f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, 1.25f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, -1.25f * BGC_EPSYLON_FP32, 0.0f }, { 0.0f, -1.25f * BGC_FP32_EPSYLON, 0.0f },
{ 0.0f, 0.0f, 1.25f * BGC_EPSYLON_FP32 }, { 0.0f, 0.0f, 1.25f * BGC_FP32_EPSYLON },
{ 0.0f, 0.0f, -1.25f * BGC_EPSYLON_FP32 }, { 0.0f, 0.0f, -1.25f * BGC_FP32_EPSYLON },
{ 1.25f * BGC_EPSYLON_FP32, 1.25f * BGC_EPSYLON_FP32, 0.0f }, { 1.25f * BGC_FP32_EPSYLON, 1.25f * BGC_FP32_EPSYLON, 0.0f },
{ -1.25f * BGC_EPSYLON_FP32, -1.25f * BGC_EPSYLON_FP32, 0.0f } { -1.25f * BGC_FP32_EPSYLON, -1.25f * BGC_FP32_EPSYLON, 0.0f }
}; };
void test_vector3_is_zero_fp32() void test_vector3_is_zero_fp32()
{ {
print_testing_name("bgc_vector3_is_zero_fp32"); print_testing_name("bgc_fp32_vector3_is_zero");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP32_ZERO_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_ZERO_VECTOR3_AMOUNT; i++) {
if (!bgc_vector3_is_zero_fp32(&_TEST_FP32_ZERO_VECTOR3_LIST[i])) { if (!bgc_fp32_vector3_is_zero(&_TEST_FP32_ZERO_VECTOR3_LIST[i])) {
print_testing_error("A zero vector was not recongized"); print_testing_error("A zero vector was not recongized");
return; return;
} }
@ -43,7 +43,7 @@ void test_vector3_is_zero_fp32()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP32_NONZERO_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_NONZERO_VECTOR3_AMOUNT; i++) {
if (bgc_vector3_is_zero_fp32(&_TEST_FP32_NONZERO_VECTOR3_LIST[i])) { if (bgc_fp32_vector3_is_zero(&_TEST_FP32_NONZERO_VECTOR3_LIST[i])) {
print_testing_error("A non-zero vector was recongized as a zero vector"); print_testing_error("A non-zero vector was recongized as a zero vector");
return; return;
} }
@ -57,35 +57,35 @@ void test_vector3_is_zero_fp32()
static const int _TEST_FP64_ZERO_VECTOR3_AMOUNT = 7; static const int _TEST_FP64_ZERO_VECTOR3_AMOUNT = 7;
static const int _TEST_FP64_NONZERO_VECTOR3_AMOUNT = 9; static const int _TEST_FP64_NONZERO_VECTOR3_AMOUNT = 9;
static const BgcVector3FP64 _TEST_FP64_ZERO_VECTOR3_LIST[] = { static const BGC_FP64_Vector3 _TEST_FP64_ZERO_VECTOR3_LIST[] = {
{ 0.0, 0.0, 0.0 }, { 0.0, 0.0, 0.0 },
{ 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ -0.75 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { -0.75 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 0.0, 0.75 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, 0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, -0.75 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, -0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 0.0, 0.75 * BGC_EPSYLON_FP64 }, { 0.0, 0.0, 0.75 * BGC_FP64_EPSYLON },
{ 0.0, 0.0, -0.75 * BGC_EPSYLON_FP64 } { 0.0, 0.0, -0.75 * BGC_FP64_EPSYLON }
}; };
static const BgcVector3FP64 _TEST_FP64_NONZERO_VECTOR3_LIST[] = { static const BGC_FP64_Vector3 _TEST_FP64_NONZERO_VECTOR3_LIST[] = {
{ 0.0, 1.0, 0.0 }, { 0.0, 1.0, 0.0 },
{ 1.25 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 1.25 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ -1.25 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { -1.25 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 0.0, 1.25 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, 1.25 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, -1.25 * BGC_EPSYLON_FP64, 0.0 }, { 0.0, -1.25 * BGC_FP64_EPSYLON, 0.0 },
{ 0.0, 0.0, 1.25 * BGC_EPSYLON_FP64 }, { 0.0, 0.0, 1.25 * BGC_FP64_EPSYLON },
{ 0.0, 0.0, -1.25 * BGC_EPSYLON_FP64 }, { 0.0, 0.0, -1.25 * BGC_FP64_EPSYLON },
{ 1.25 * BGC_EPSYLON_FP64, 1.25 * BGC_EPSYLON_FP64, 0.0 }, { 1.25 * BGC_FP64_EPSYLON, 1.25 * BGC_FP64_EPSYLON, 0.0 },
{ -BGC_EPSYLON_FP64, -BGC_EPSYLON_FP64, 0.0 } { -BGC_FP64_EPSYLON, -BGC_FP64_EPSYLON, 0.0 }
}; };
void test_vector3_is_zero_fp64() void test_vector3_is_zero_fp64()
{ {
print_testing_name("bgc_vector3_is_zero_fp64"); print_testing_name("bgc_fp64_vector3_is_zero");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP64_ZERO_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_ZERO_VECTOR3_AMOUNT; i++) {
if (!bgc_vector3_is_zero_fp64(&_TEST_FP64_ZERO_VECTOR3_LIST[i])) { if (!bgc_fp64_vector3_is_zero(&_TEST_FP64_ZERO_VECTOR3_LIST[i])) {
print_testing_error("A zero vector was not recongized"); print_testing_error("A zero vector was not recongized");
return; return;
} }
@ -93,7 +93,7 @@ void test_vector3_is_zero_fp64()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP64_NONZERO_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_NONZERO_VECTOR3_AMOUNT; i++) {
if (bgc_vector3_is_zero_fp64(&_TEST_FP64_NONZERO_VECTOR3_LIST[i])) { if (bgc_fp64_vector3_is_zero(&_TEST_FP64_NONZERO_VECTOR3_LIST[i])) {
print_testing_error("A non-zero vector was recongized as a zero vector"); print_testing_error("A non-zero vector was recongized as a zero vector");
return; return;
} }

20
basic-geometry-test/tests/vector3/vector3_modulus.c
View file

@ -6,7 +6,7 @@
static const int _TEST_FP32_VECTOR3_AMOUNT = 4; static const int _TEST_FP32_VECTOR3_AMOUNT = 4;
static const BgcVector3FP32 _TEST_FP32_VECTOR3_LIST[] = { static const BGC_FP32_Vector3 _TEST_FP32_VECTOR3_LIST[] = {
{ 4.0f, 3.0f, 0.0f }, { 4.0f, 3.0f, 0.0f },
{ 0.0f, -3.0f, -4.0f }, { 0.0f, -3.0f, -4.0f },
{ 100.0f, -100.0f, 100.0f }, { 100.0f, -100.0f, 100.0f },
@ -29,10 +29,10 @@ static const float _TEST_FP32_MODULUS_LIST[] = {
void test_vector3_square_modulus_fp32() void test_vector3_square_modulus_fp32()
{ {
print_testing_name("bgc_vector3_get_square_modulus_fp32"); print_testing_name("bgc_fp32_vector3_get_square_modulus");
for (int i = 0; i < _TEST_FP32_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_VECTOR3_AMOUNT; i++) {
if (!bgc_are_close_fp32(bgc_vector3_get_square_modulus_fp32(&_TEST_FP32_VECTOR3_LIST[i]), _TEST_FP32_SQUARE_MODULUS_LIST[i])) { if (!bgc_fp32_are_close(bgc_fp32_vector3_get_square_modulus(&_TEST_FP32_VECTOR3_LIST[i]), _TEST_FP32_SQUARE_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }
@ -43,10 +43,10 @@ void test_vector3_square_modulus_fp32()
void test_vector3_modulus_fp32() void test_vector3_modulus_fp32()
{ {
print_testing_name("bgc_vector3_get_modulus_fp32"); print_testing_name("bgc_fp32_vector3_get_modulus");
for (int i = 0; i < _TEST_FP32_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_VECTOR3_AMOUNT; i++) {
if (!bgc_are_close_fp32(bgc_vector3_get_modulus_fp32(&_TEST_FP32_VECTOR3_LIST[i]), _TEST_FP32_MODULUS_LIST[i])) { if (!bgc_fp32_are_close(bgc_fp32_vector3_get_modulus(&_TEST_FP32_VECTOR3_LIST[i]), _TEST_FP32_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }
@ -59,7 +59,7 @@ void test_vector3_modulus_fp32()
static const int _TEST_FP64_VECTOR3_AMOUNT = 4; static const int _TEST_FP64_VECTOR3_AMOUNT = 4;
static const BgcVector3FP64 _TEST_FP64_VECTOR3_LIST[] = { static const BGC_FP64_Vector3 _TEST_FP64_VECTOR3_LIST[] = {
{ 0.0, 4.0, 3.0 }, { 0.0, 4.0, 3.0 },
{ -3.0, 0.0, -4.0 }, { -3.0, 0.0, -4.0 },
{ 100.0, -100.0, 100.0 }, { 100.0, -100.0, 100.0 },
@ -82,10 +82,10 @@ static const double _TEST_FP64_MODULUS_LIST[] = {
void test_vector3_square_modulus_fp64() void test_vector3_square_modulus_fp64()
{ {
print_testing_name("bgc_vector3_get_square_modulus_fp64"); print_testing_name("bgc_fp64_vector3_get_square_modulus");
for (int i = 0; i < _TEST_FP64_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_VECTOR3_AMOUNT; i++) {
if (!bgc_are_close_fp64(bgc_vector3_get_square_modulus_fp64(&_TEST_FP64_VECTOR3_LIST[i]), _TEST_FP64_SQUARE_MODULUS_LIST[i])) { if (!bgc_fp64_are_close(bgc_fp64_vector3_get_square_modulus(&_TEST_FP64_VECTOR3_LIST[i]), _TEST_FP64_SQUARE_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }
@ -96,10 +96,10 @@ void test_vector3_square_modulus_fp64()
void test_vector3_modulus_fp64() void test_vector3_modulus_fp64()
{ {
print_testing_name("bgc_vector3_get_modulus_fp64"); print_testing_name("bgc_fp64_vector3_get_modulus");
for (int i = 0; i < _TEST_FP64_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_VECTOR3_AMOUNT; i++) {
if (!bgc_are_close_fp64(bgc_vector3_get_modulus_fp64(&_TEST_FP64_VECTOR3_LIST[i]), _TEST_FP64_MODULUS_LIST[i])) { if (!bgc_fp64_are_close(bgc_fp64_vector3_get_modulus(&_TEST_FP64_VECTOR3_LIST[i]), _TEST_FP64_MODULUS_LIST[i])) {
print_testing_failed(); print_testing_failed();
return; return;
} }

12
basic-geometry-test/tests/vector3/vector3_reset.c
View file

@ -4,11 +4,11 @@
void test_vector3_reset_fp32() void test_vector3_reset_fp32()
{ {
BgcVector3FP32 vector; BGC_FP32_Vector3 vector;
print_testing_name("bgc_vector3_reset_fp32"); print_testing_name("bgc_fp32_vector3_reset");
bgc_vector3_reset_fp32(&vector); bgc_fp32_vector3_reset(&vector);
if (vector.x1 != 0.0f || vector.x2 != 0.0f || vector.x3 != 0.0f) { if (vector.x1 != 0.0f || vector.x2 != 0.0f || vector.x3 != 0.0f) {
print_testing_failed(); print_testing_failed();
@ -20,11 +20,11 @@ void test_vector3_reset_fp32()
void test_vector3_reset_fp64() void test_vector3_reset_fp64()
{ {
BgcVector3FP64 vector; BGC_FP64_Vector3 vector;
print_testing_name("bgc_vector3_reset_fp64"); print_testing_name("bgc_fp64_vector3_reset");
bgc_vector3_reset_fp64(&vector); bgc_fp64_vector3_reset(&vector);
if (vector.x1 != 0.0 || vector.x2 != 0.0 || vector.x3 != 0.0) { if (vector.x1 != 0.0 || vector.x2 != 0.0 || vector.x3 != 0.0) {
print_testing_failed(); print_testing_failed();

20
basic-geometry-test/tests/vector3/vector3_set_values.c
View file

@ -8,25 +8,25 @@
void test_vector3_set_values_fp32() void test_vector3_set_values_fp32()
{ {
BgcVector3FP32 vector; BGC_FP32_Vector3 vector;
print_testing_name("bgc_vector3_set_values_fp32"); print_testing_name("bgc_fp32_vector3_make");
bgc_vector3_set_values_fp32(1.0f, 2.0f, 3.0f, &vector); bgc_fp32_vector3_make(1.0f, 2.0f, 3.0f, &vector);
if (vector.x1 != 1.0f || vector.x2 != 2.0f || vector.x3 != 3.0f) { if (vector.x1 != 1.0f || vector.x2 != 2.0f || vector.x3 != 3.0f) {
print_testing_error("First step failed"); print_testing_error("First step failed");
return; return;
} }
bgc_vector3_set_values_fp32(-3.0f, -5.0f, -7.0f, &vector); bgc_fp32_vector3_make(-3.0f, -5.0f, -7.0f, &vector);
if (vector.x1 != -3.0f || vector.x2 != -5.0f || vector.x3 != -7.0f) { if (vector.x1 != -3.0f || vector.x2 != -5.0f || vector.x3 != -7.0f) {
print_testing_error("Second step failed"); print_testing_error("Second step failed");
return; return;
} }
bgc_vector3_set_values_fp32(-2.0f, 2.0f, 4.0f, &vector); bgc_fp32_vector3_make(-2.0f, 2.0f, 4.0f, &vector);
if (vector.x1 != -2.0f || vector.x2 != 2.0f || vector.x3 != 4.0f) { if (vector.x1 != -2.0f || vector.x2 != 2.0f || vector.x3 != 4.0f) {
print_testing_error("Third step failed"); print_testing_error("Third step failed");
@ -40,26 +40,26 @@ void test_vector3_set_values_fp32()
void test_vector3_set_values_fp64() void test_vector3_set_values_fp64()
{ {
BgcVector3FP64 vector; BGC_FP64_Vector3 vector;
print_testing_name("bgc_vector3_set_values_fp64"); print_testing_name("bgc_fp64_vector3_make");
bgc_vector3_set_values_fp64(1.0, 2.0, 3.0, &vector); bgc_fp64_vector3_make(1.0, 2.0, 3.0, &vector);
if (vector.x1 != 1.0 || vector.x2 != 2.0 || vector.x3 != 3.0) { if (vector.x1 != 1.0 || vector.x2 != 2.0 || vector.x3 != 3.0) {
print_testing_error("First step failed"); print_testing_error("First step failed");
return; return;
} }
bgc_vector3_set_values_fp64(-3.0, -5.0, -7.0, &vector); bgc_fp64_vector3_make(-3.0, -5.0, -7.0, &vector);
if (vector.x1 != -3.0 || vector.x2 != -5.0 || vector.x3 != -7.0) { if (vector.x1 != -3.0 || vector.x2 != -5.0 || vector.x3 != -7.0) {
print_testing_error("Second step failed"); print_testing_error("Second step failed");
return; return;
} }
bgc_vector3_set_values_fp64(-2.0, 2.0, 4.0, &vector); bgc_fp64_vector3_make(-2.0, 2.0, 4.0, &vector);
if (vector.x1 != -2.0 || vector.x2 != 2.0 || vector.x3 != 4.0) { if (vector.x1 != -2.0 || vector.x2 != 2.0 || vector.x3 != 4.0) {
print_testing_error("Third step failed"); print_testing_error("Third step failed");

28
basic-geometry-test/tests/vector3/vector3_swap.c
View file

@ -8,14 +8,14 @@
static const int _TEST_FP32_VECTOR3_AMOUNT = 4; static const int _TEST_FP32_VECTOR3_AMOUNT = 4;
static const BgcVector3FP32 _TEST_FP32_VECTOR3_LIST1[] = { static const BGC_FP32_Vector3 _TEST_FP32_VECTOR3_LIST1[] = {
{ 1.0f, 2.0f, 3.0f }, { 1.0f, 2.0f, 3.0f },
{ -3.0f, -2.0f, -1.0f }, { -3.0f, -2.0f, -1.0f },
{ 100.0f, -100.0f, 344.7f }, { 100.0f, -100.0f, 344.7f },
{ -100.1f, 100.2f, -271.3f } { -100.1f, 100.2f, -271.3f }
}; };
static const BgcVector3FP32 _TEST_FP32_VECTOR3_LIST2[] = { static const BGC_FP32_Vector3 _TEST_FP32_VECTOR3_LIST2[] = {
{ 3.6f, 5.3f, -0.123f }, { 3.6f, 5.3f, -0.123f },
{ 204.07f, -781.89f, 891.3f }, { 204.07f, -781.89f, 891.3f },
{ -20.02f, -1.0003f, 0.9275f }, { -20.02f, -1.0003f, 0.9275f },
@ -24,15 +24,15 @@ static const BgcVector3FP32 _TEST_FP32_VECTOR3_LIST2[] = {
void test_vector3_swap_fp32() void test_vector3_swap_fp32()
{ {
BgcVector3FP32 vector1, vector2; BGC_FP32_Vector3 vector1, vector2;
print_testing_name("bgc_vector3_swap_fp32"); print_testing_name("bgc_fp32_vector3_swap");
for (int i = 0; i < _TEST_FP32_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_VECTOR3_AMOUNT; i++) {
bgc_vector3_copy_fp32(&_TEST_FP32_VECTOR3_LIST1[i], &vector1); bgc_fp32_vector3_copy(&_TEST_FP32_VECTOR3_LIST1[i], &vector1);
bgc_vector3_copy_fp32(&_TEST_FP32_VECTOR3_LIST2[i], &vector2); bgc_fp32_vector3_copy(&_TEST_FP32_VECTOR3_LIST2[i], &vector2);
bgc_vector3_swap_fp32(&vector1, &vector2); bgc_fp32_vector3_swap(&vector1, &vector2);
if (vector1.x1 != _TEST_FP32_VECTOR3_LIST2[i].x1 || if (vector1.x1 != _TEST_FP32_VECTOR3_LIST2[i].x1 ||
vector1.x2 != _TEST_FP32_VECTOR3_LIST2[i].x2 || vector1.x2 != _TEST_FP32_VECTOR3_LIST2[i].x2 ||
@ -52,14 +52,14 @@ void test_vector3_swap_fp32()
static const int _TEST_FP64_VECTOR3_AMOUNT = 4; static const int _TEST_FP64_VECTOR3_AMOUNT = 4;
static const BgcVector3FP64 _TEST_FP64_VECTOR3_LIST1[] = { static const BGC_FP64_Vector3 _TEST_FP64_VECTOR3_LIST1[] = {
{ 1.0, 2.0, 3.0 }, { 1.0, 2.0, 3.0 },
{ -3.0, -2.0, -1.0 }, { -3.0, -2.0, -1.0 },
{ 100.0, -100.0, 344.7 }, { 100.0, -100.0, 344.7 },
{ -100.1, 100.2, -271.3 } { -100.1, 100.2, -271.3 }
}; };
static const BgcVector3FP64 _TEST_FP64_VECTOR3_LIST2[] = { static const BGC_FP64_Vector3 _TEST_FP64_VECTOR3_LIST2[] = {
{ 3.6, 5.3, -0.123 }, { 3.6, 5.3, -0.123 },
{ 204.07, -781.89, 891.3 }, { 204.07, -781.89, 891.3 },
{ -20.02, -1.0003, 0.9275 }, { -20.02, -1.0003, 0.9275 },
@ -68,15 +68,15 @@ static const BgcVector3FP64 _TEST_FP64_VECTOR3_LIST2[] = {
void test_vector3_swap_fp64() void test_vector3_swap_fp64()
{ {
BgcVector3FP64 vector1, vector2; BGC_FP64_Vector3 vector1, vector2;
print_testing_name("bgc_vector3_swap_fp64"); print_testing_name("bgc_fp64_vector3_swap");
for (int i = 0; i < _TEST_FP64_VECTOR3_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_VECTOR3_AMOUNT; i++) {
bgc_vector3_copy_fp64(&_TEST_FP64_VECTOR3_LIST1[i], &vector1); bgc_fp64_vector3_copy(&_TEST_FP64_VECTOR3_LIST1[i], &vector1);
bgc_vector3_copy_fp64(&_TEST_FP64_VECTOR3_LIST2[i], &vector2); bgc_fp64_vector3_copy(&_TEST_FP64_VECTOR3_LIST2[i], &vector2);
bgc_vector3_swap_fp64(&vector1, &vector2); bgc_fp64_vector3_swap(&vector1, &vector2);
if (vector1.x1 != _TEST_FP64_VECTOR3_LIST2[i].x1 || if (vector1.x1 != _TEST_FP64_VECTOR3_LIST2[i].x1 ||
vector1.x2 != _TEST_FP64_VECTOR3_LIST2[i].x2 || vector1.x2 != _TEST_FP64_VECTOR3_LIST2[i].x2 ||

76
basic-geometry-test/tests/versor/versor_are_close.c
View file

@ -9,35 +9,35 @@ static const int _TEST_FP32_CLOSE_VERSOR_PAIR_AMOUNT = 10;
static const TestVersorPairFP32 _TEST_FP32_CLOSE_VERSOR_PAIR_LIST[] = { static const TestVersorPairFP32 _TEST_FP32_CLOSE_VERSOR_PAIR_LIST[] = {
{ {
{ 1.0f, 0.0f, 0.0f, 0.0f }, { 1.0f, 0.0f, 0.0f, 0.0f },
{ 1.0f + 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f, 0.0f } { 1.0f + 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f, 0.0f }
}, },
{ {
{ 1.0f, 0.0f, 0.0f, 0.0f }, { 1.0f, 0.0f, 0.0f, 0.0f },
{ 1.0f - 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f, 0.0f } { 1.0f - 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f, 0.0f }
}, },
{ {
{ 0.0f, 1.0f, 0.0f, 0.0f }, { 0.0f, 1.0f, 0.0f, 0.0f },
{ 0.0f, 1.0f + 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f } { 0.0f, 1.0f + 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f }
}, },
{ {
{ 0.0f, 1.0f, 0.0f, 0.0f }, { 0.0f, 1.0f, 0.0f, 0.0f },
{ 0.0f, 1.0f - 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f } { 0.0f, 1.0f - 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f }
}, },
{ {
{ 0.0f, 0.0f, 1.0f, 0.0f }, { 0.0f, 0.0f, 1.0f, 0.0f },
{ 0.0f, 0.0f, 1.0f + 0.75f * BGC_EPSYLON_FP32, 0.0f } { 0.0f, 0.0f, 1.0f + 0.75f * BGC_FP32_EPSYLON, 0.0f }
}, },
{ {
{ 0.0f, 0.0f, 1.0f, 0.0f }, { 0.0f, 0.0f, 1.0f, 0.0f },
{ 0.0f, 0.0f, 1.0f - 0.75f * BGC_EPSYLON_FP32, 0.0f } { 0.0f, 0.0f, 1.0f - 0.75f * BGC_FP32_EPSYLON, 0.0f }
}, },
{ {
{ 0.0f, 0.0f, 0.0f, 1.0f }, { 0.0f, 0.0f, 0.0f, 1.0f },
{ 0.0f, 0.0f, 0.0f, 1.0f + 0.75f * BGC_EPSYLON_FP32 } { 0.0f, 0.0f, 0.0f, 1.0f + 0.75f * BGC_FP32_EPSYLON }
}, },
{ {
{ 0.0f, 0.0f, 0.0f, 1.0f }, { 0.0f, 0.0f, 0.0f, 1.0f },
{ 0.0f, 0.0f, 0.0f, 1.0f - 0.75f * BGC_EPSYLON_FP32 } { 0.0f, 0.0f, 0.0f, 1.0f - 0.75f * BGC_FP32_EPSYLON }
}, },
{ {
{ 0.70710678f, 0.0f, 0.70710675f, 0.0f }, { 0.70710678f, 0.0f, 0.70710675f, 0.0f },
@ -54,35 +54,35 @@ static const int _TEST_FP32_DIFFERENT_VERSOR_PAIR_AMOUNT = 10;
static const TestVersorPairFP32 _TEST_FP32_DIFFERENT_VERSOR_PAIR_LIST[] = { static const TestVersorPairFP32 _TEST_FP32_DIFFERENT_VERSOR_PAIR_LIST[] = {
{ {
{ 1.0f, 0.0f, 0.0f, 0.0f }, { 1.0f, 0.0f, 0.0f, 0.0f },
{ 1.0f + 1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f, 0.0f } { 1.0f + 1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f, 0.0f }
}, },
{ {
{ 1.0f, 0.0f, 0.0f, 0.0f }, { 1.0f, 0.0f, 0.0f, 0.0f },
{ 1.0f - 1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f, 0.0f } { 1.0f - 1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f, 0.0f }
}, },
{ {
{ 0.0f, 1.0f, 0.0f, 0.0f }, { 0.0f, 1.0f, 0.0f, 0.0f },
{ 0.0f, 1.0f + 1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f } { 0.0f, 1.0f + 1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f }
}, },
{ {
{ 0.0f, 1.0f, 0.0f, 0.0f }, { 0.0f, 1.0f, 0.0f, 0.0f },
{ 0.0f, 1.0f - 1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f } { 0.0f, 1.0f - 1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f }
}, },
{ {
{ 0.0f, 0.0f, 1.0f, 0.0f }, { 0.0f, 0.0f, 1.0f, 0.0f },
{ 0.0f, 0.0f, 1.0f + 1.25f * BGC_EPSYLON_FP32, 0.0f } { 0.0f, 0.0f, 1.0f + 1.25f * BGC_FP32_EPSYLON, 0.0f }
}, },
{ {
{ 0.0f, 0.0f, 1.0f, 0.0f }, { 0.0f, 0.0f, 1.0f, 0.0f },
{ 0.0f, 0.0f, 1.0f - 1.25f * BGC_EPSYLON_FP32, 0.0f } { 0.0f, 0.0f, 1.0f - 1.25f * BGC_FP32_EPSYLON, 0.0f }
}, },
{ {
{ 0.0f, 0.0f, 0.0f, 1.0f }, { 0.0f, 0.0f, 0.0f, 1.0f },
{ 0.0f, 0.0f, 0.0f, 1.0f + 1.25f * BGC_EPSYLON_FP32 } { 0.0f, 0.0f, 0.0f, 1.0f + 1.25f * BGC_FP32_EPSYLON }
}, },
{ {
{ 0.0f, 0.0f, 0.0f, 1.0f }, { 0.0f, 0.0f, 0.0f, 1.0f },
{ 0.0f, 0.0f, 0.0f, 1.0f - 1.25f * BGC_EPSYLON_FP32 } { 0.0f, 0.0f, 0.0f, 1.0f - 1.25f * BGC_FP32_EPSYLON }
}, },
{ {
{ 0.707106f, 0.0f, 0.707107f, 0.0f }, { 0.707106f, 0.0f, 0.707107f, 0.0f },
@ -96,11 +96,11 @@ static const TestVersorPairFP32 _TEST_FP32_DIFFERENT_VERSOR_PAIR_LIST[] = {
void test_versor_are_close_fp32() void test_versor_are_close_fp32()
{ {
print_testing_name("bgc_versor_are_close_fp32"); print_testing_name("bgc_fp32_versor_are_close");
// Testing close pairs of versors: // Testing close pairs of versors:
for (int i = 0; i < _TEST_FP32_CLOSE_VERSOR_PAIR_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_CLOSE_VERSOR_PAIR_AMOUNT; i++) {
if (!bgc_versor_are_close_fp32(&_TEST_FP32_CLOSE_VERSOR_PAIR_LIST[i].first, &_TEST_FP32_CLOSE_VERSOR_PAIR_LIST[i].second)) { if (!bgc_fp32_versor_are_close(&_TEST_FP32_CLOSE_VERSOR_PAIR_LIST[i].first, &_TEST_FP32_CLOSE_VERSOR_PAIR_LIST[i].second)) {
print_testing_error("A pair of close versors was not recognized"); print_testing_error("A pair of close versors was not recognized");
return; return;
} }
@ -108,7 +108,7 @@ void test_versor_are_close_fp32()
// Testing different pairs of versors: // Testing different pairs of versors:
for (int i = 0; i < _TEST_FP32_DIFFERENT_VERSOR_PAIR_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_DIFFERENT_VERSOR_PAIR_AMOUNT; i++) {
if (bgc_versor_are_close_fp32(&_TEST_FP32_DIFFERENT_VERSOR_PAIR_LIST[i].first, &_TEST_FP32_DIFFERENT_VERSOR_PAIR_LIST[i].second)) { if (bgc_fp32_versor_are_close(&_TEST_FP32_DIFFERENT_VERSOR_PAIR_LIST[i].first, &_TEST_FP32_DIFFERENT_VERSOR_PAIR_LIST[i].second)) {
print_testing_error("A pair of different versors was recognized as close versors"); print_testing_error("A pair of different versors was recognized as close versors");
return; return;
} }
@ -125,35 +125,35 @@ static const int _TEST_FP64_CLOSE_VERSOR_PAIR_AMOUNT = 10;
static const TestVersorPairFP64 _TEST_FP64_CLOSE_VERSOR_PAIR_LIST[] = { static const TestVersorPairFP64 _TEST_FP64_CLOSE_VERSOR_PAIR_LIST[] = {
{ {
{ 1.0, 0.0, 0.0, 0.0 }, { 1.0, 0.0, 0.0, 0.0 },
{ 1.0 + 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0, 0.0 } { 1.0 + 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0, 0.0 }
}, },
{ {
{ 1.0, 0.0, 0.0, 0.0 }, { 1.0, 0.0, 0.0, 0.0 },
{ 1.0 - 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0, 0.0 } { 1.0 - 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0, 0.0 }
}, },
{ {
{ 0.0, 1.0, 0.0, 0.0 }, { 0.0, 1.0, 0.0, 0.0 },
{ 0.0, 1.0 + 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0 } { 0.0, 1.0 + 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0 }
}, },
{ {
{ 0.0, 1.0, 0.0, 0.0 }, { 0.0, 1.0, 0.0, 0.0 },
{ 0.0, 1.0 - 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0 } { 0.0, 1.0 - 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0 }
}, },
{ {
{ 0.0, 0.0, 1.0, 0.0 }, { 0.0, 0.0, 1.0, 0.0 },
{ 0.0, 0.0, 1.0 + 0.75 * BGC_EPSYLON_FP64, 0.0 } { 0.0, 0.0, 1.0 + 0.75 * BGC_FP64_EPSYLON, 0.0 }
}, },
{ {
{ 0.0, 0.0, 1.0, 0.0 }, { 0.0, 0.0, 1.0, 0.0 },
{ 0.0, 0.0, 1.0 - 0.75 * BGC_EPSYLON_FP64, 0.0 } { 0.0, 0.0, 1.0 - 0.75 * BGC_FP64_EPSYLON, 0.0 }
}, },
{ {
{ 0.0, 0.0, 0.0, 1.0 }, { 0.0, 0.0, 0.0, 1.0 },
{ 0.0, 0.0, 0.0, 1.0 + 0.75 * BGC_EPSYLON_FP64 } { 0.0, 0.0, 0.0, 1.0 + 0.75 * BGC_FP64_EPSYLON }
}, },
{ {
{ 0.0, 0.0, 0.0, 1.0 }, { 0.0, 0.0, 0.0, 1.0 },
{ 0.0, 0.0, 0.0, 1.0 - 0.75 * BGC_EPSYLON_FP64 } { 0.0, 0.0, 0.0, 1.0 - 0.75 * BGC_FP64_EPSYLON }
}, },
{ {
{ 0.7071067811865475244, 0.0, 0.7071067811865465244, 0.0 }, { 0.7071067811865475244, 0.0, 0.7071067811865465244, 0.0 },
@ -170,35 +170,35 @@ static const int _TEST_FP64_DIFFERENT_VERSOR_PAIR_AMOUNT = 10;
static const TestVersorPairFP64 _TEST_FP64_DIFFERENT_VERSOR_PAIR_LIST[] = { static const TestVersorPairFP64 _TEST_FP64_DIFFERENT_VERSOR_PAIR_LIST[] = {
{ {
{ 1.0, 0.0, 0.0, 0.0 }, { 1.0, 0.0, 0.0, 0.0 },
{ 1.0 + 1.25 * BGC_EPSYLON_FP64, 0.0, 0.0, 0.0 } { 1.0 + 1.25 * BGC_FP64_EPSYLON, 0.0, 0.0, 0.0 }
}, },
{ {
{ 1.0, 0.0, 0.0, 0.0 }, { 1.0, 0.0, 0.0, 0.0 },
{ 1.0 - 1.25 * BGC_EPSYLON_FP64, 0.0, 0.0, 0.0 } { 1.0 - 1.25 * BGC_FP64_EPSYLON, 0.0, 0.0, 0.0 }
}, },
{ {
{ 0.0, 1.0, 0.0, 0.0 }, { 0.0, 1.0, 0.0, 0.0 },
{ 0.0, 1.0 + 1.25 * BGC_EPSYLON_FP64, 0.0, 0.0 } { 0.0, 1.0 + 1.25 * BGC_FP64_EPSYLON, 0.0, 0.0 }
}, },
{ {
{ 0.0, 1.0, 0.0, 0.0 }, { 0.0, 1.0, 0.0, 0.0 },
{ 0.0, 1.0 - 1.25 * BGC_EPSYLON_FP64, 0.0, 0.0 } { 0.0, 1.0 - 1.25 * BGC_FP64_EPSYLON, 0.0, 0.0 }
}, },
{ {
{ 0.0, 0.0, 1.0, 0.0 }, { 0.0, 0.0, 1.0, 0.0 },
{ 0.0, 0.0, 1.0 + 1.25 * BGC_EPSYLON_FP64, 0.0 } { 0.0, 0.0, 1.0 + 1.25 * BGC_FP64_EPSYLON, 0.0 }
}, },
{ {
{ 0.0, 0.0, 1.0, 0.0 }, { 0.0, 0.0, 1.0, 0.0 },
{ 0.0, 0.0, 1.0 - 1.25 * BGC_EPSYLON_FP64, 0.0 } { 0.0, 0.0, 1.0 - 1.25 * BGC_FP64_EPSYLON, 0.0 }
}, },
{ {
{ 0.0, 0.0, 0.0, 1.0 }, { 0.0, 0.0, 0.0, 1.0 },
{ 0.0, 0.0, 0.0, 1.0 + 1.25 * BGC_EPSYLON_FP64 } { 0.0, 0.0, 0.0, 1.0 + 1.25 * BGC_FP64_EPSYLON }
}, },
{ {
{ 0.0, 0.0, 0.0, 1.0 }, { 0.0, 0.0, 0.0, 1.0 },
{ 0.0, 0.0, 0.0, 1.0 - 1.25 * BGC_EPSYLON_FP64 } { 0.0, 0.0, 0.0, 1.0 - 1.25 * BGC_FP64_EPSYLON }
}, },
{ {
{ 0.7071067811866, 0.0, 0.7071067811865, 0.0 }, { 0.7071067811866, 0.0, 0.7071067811865, 0.0 },
@ -212,11 +212,11 @@ static const TestVersorPairFP64 _TEST_FP64_DIFFERENT_VERSOR_PAIR_LIST[] = {
void test_versor_are_close_fp64() void test_versor_are_close_fp64()
{ {
print_testing_name("bgc_versor_are_close_fp64"); print_testing_name("bgc_fp64_versor_are_close");
// Testing close pairs of versors: // Testing close pairs of versors:
for (int i = 0; i < _TEST_FP64_CLOSE_VERSOR_PAIR_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_CLOSE_VERSOR_PAIR_AMOUNT; i++) {
if (!bgc_versor_are_close_fp64(&_TEST_FP64_CLOSE_VERSOR_PAIR_LIST[i].first, &_TEST_FP64_CLOSE_VERSOR_PAIR_LIST[i].second)) { if (!bgc_fp64_versor_are_close(&_TEST_FP64_CLOSE_VERSOR_PAIR_LIST[i].first, &_TEST_FP64_CLOSE_VERSOR_PAIR_LIST[i].second)) {
print_testing_error("A pair of close versors was not recognized"); print_testing_error("A pair of close versors was not recognized");
return; return;
} }
@ -224,7 +224,7 @@ void test_versor_are_close_fp64()
// Testing different pairs of versors: // Testing different pairs of versors:
for (int i = 0; i < _TEST_FP64_DIFFERENT_VERSOR_PAIR_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_DIFFERENT_VERSOR_PAIR_AMOUNT; i++) {
if (bgc_versor_are_close_fp64(&_TEST_FP64_DIFFERENT_VERSOR_PAIR_LIST[i].first, &_TEST_FP64_DIFFERENT_VERSOR_PAIR_LIST[i].second)) { if (bgc_fp64_versor_are_close(&_TEST_FP64_DIFFERENT_VERSOR_PAIR_LIST[i].first, &_TEST_FP64_DIFFERENT_VERSOR_PAIR_LIST[i].second)) {
print_testing_error("A pair of different versors was recognized as close versors"); print_testing_error("A pair of different versors was recognized as close versors");
return; return;
} }

16
basic-geometry-test/tests/versor/versor_combine.c
View file

@ -38,14 +38,14 @@ static const TestVersorTripletFP32 _TEST_FP32_VERSOR_TRIPLET_LIST[] = {
void test_versor_combine_fp32() void test_versor_combine_fp32()
{ {
BgcVersorFP32 versor; BGC_FP32_Versor versor;
print_testing_name("bgc_versor_combine_fp32"); print_testing_name("bgc_fp32_versor_combine");
for (int i = 0; i < _TEST_FP32_VERSOR_TRIPLET_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_VERSOR_TRIPLET_AMOUNT; i++) {
bgc_versor_combine_fp32(&_TEST_FP32_VERSOR_TRIPLET_LIST[i].first, &_TEST_FP32_VERSOR_TRIPLET_LIST[i].second, &versor); bgc_fp32_versor_combine(&_TEST_FP32_VERSOR_TRIPLET_LIST[i].first, &_TEST_FP32_VERSOR_TRIPLET_LIST[i].second, &versor);
if (!bgc_versor_are_close_fp32(&versor, &_TEST_FP32_VERSOR_TRIPLET_LIST[i].result)) { if (!bgc_fp32_versor_are_close(&versor, &_TEST_FP32_VERSOR_TRIPLET_LIST[i].result)) {
print_testing_failed(); print_testing_failed();
return; return;
} }
@ -88,14 +88,14 @@ static const TestVersorTripletFP64 _TEST_FP64_VERSOR_TRIPLET_LIST[] = {
void test_versor_combine_fp64() void test_versor_combine_fp64()
{ {
BgcVersorFP64 versor; BGC_FP64_Versor versor;
print_testing_name("bgc_versor_combine_fp64"); print_testing_name("bgc_fp64_versor_combine");
for (int i = 0; i < _TEST_FP64_VERSOR_TRIPLET_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_VERSOR_TRIPLET_AMOUNT; i++) {
bgc_versor_combine_fp64(&_TEST_FP64_VERSOR_TRIPLET_LIST[i].first, &_TEST_FP64_VERSOR_TRIPLET_LIST[i].second, &versor); bgc_fp64_versor_combine(&_TEST_FP64_VERSOR_TRIPLET_LIST[i].first, &_TEST_FP64_VERSOR_TRIPLET_LIST[i].second, &versor);
if (!bgc_versor_are_close_fp64(&versor, &_TEST_FP64_VERSOR_TRIPLET_LIST[i].result)) { if (!bgc_fp64_versor_are_close(&versor, &_TEST_FP64_VERSOR_TRIPLET_LIST[i].result)) {
print_testing_failed(); print_testing_failed();
return; return;
} }

16
basic-geometry-test/tests/versor/versor_copy.c
View file

@ -7,7 +7,7 @@
// ==================== FP32 ==================== // // ==================== FP32 ==================== //
static const int _TEST_FP32_VERSOR_AMOUNT = 8; static const int _TEST_FP32_VERSOR_AMOUNT = 8;
static const BgcVersorFP32 _TEST_FP32_VERSOR_LIST[] = { static const BGC_FP32_Versor _TEST_FP32_VERSOR_LIST[] = {
{ 1.0f, 0.0f, 0.0f, 0.0f }, { 1.0f, 0.0f, 0.0f, 0.0f },
{ -1.0f, 0.0f, 0.0f, 0.0f }, { -1.0f, 0.0f, 0.0f, 0.0f },
{ 0.182574185835f, 0.36514837167f, 0.54772255751f, 0.73029674334f }, { 0.182574185835f, 0.36514837167f, 0.54772255751f, 0.73029674334f },
@ -20,13 +20,13 @@ static const BgcVersorFP32 _TEST_FP32_VERSOR_LIST[] = {
void test_versor_copy_fp32() void test_versor_copy_fp32()
{ {
BgcVersorFP32 versor; BGC_FP32_Versor versor;
print_testing_name("bgc_versor_copy_fp32"); print_testing_name("bgc_fp32_versor_copy");
for (int i = 0; i < _TEST_FP32_VERSOR_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_VERSOR_AMOUNT; i++) {
bgc_versor_copy_fp32(&_TEST_FP32_VERSOR_LIST[i], &versor); bgc_fp32_versor_copy(&_TEST_FP32_VERSOR_LIST[i], &versor);
if (versor._s0 != _TEST_FP32_VERSOR_LIST[i]._s0 || if (versor._s0 != _TEST_FP32_VERSOR_LIST[i]._s0 ||
versor._x1 != _TEST_FP32_VERSOR_LIST[i]._x1 || versor._x1 != _TEST_FP32_VERSOR_LIST[i]._x1 ||
@ -43,7 +43,7 @@ void test_versor_copy_fp32()
// ==================== FP64 ==================== // // ==================== FP64 ==================== //
static const int _TEST_FP64_VERSOR_AMOUNT = 8; static const int _TEST_FP64_VERSOR_AMOUNT = 8;
static const BgcVersorFP64 _TEST_FP64_VERSOR_LIST[] = { static const BGC_FP64_Versor _TEST_FP64_VERSOR_LIST[] = {
{ 1.0f, 0.0f, 0.0f, 0.0f }, { 1.0f, 0.0f, 0.0f, 0.0f },
{ -1.0f, 0.0f, 0.0f, 0.0f }, { -1.0f, 0.0f, 0.0f, 0.0f },
{ 0.1825741858350553712, 0.3651483716701107423, 0.5477225575051661135, 0.7302967433402214846 }, { 0.1825741858350553712, 0.3651483716701107423, 0.5477225575051661135, 0.7302967433402214846 },
@ -56,13 +56,13 @@ static const BgcVersorFP64 _TEST_FP64_VERSOR_LIST[] = {
void test_versor_copy_fp64() void test_versor_copy_fp64()
{ {
BgcVersorFP64 versor; BGC_FP64_Versor versor;
print_testing_name("bgc_versor_copy_fp64"); print_testing_name("bgc_fp64_versor_copy");
for (int i = 0; i < _TEST_FP64_VERSOR_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_VERSOR_AMOUNT; i++) {
bgc_versor_copy_fp64(&_TEST_FP64_VERSOR_LIST[i], &versor); bgc_fp64_versor_copy(&_TEST_FP64_VERSOR_LIST[i], &versor);
if (versor._s0 != _TEST_FP64_VERSOR_LIST[i]._s0 || if (versor._s0 != _TEST_FP64_VERSOR_LIST[i]._s0 ||
versor._x1 != _TEST_FP64_VERSOR_LIST[i]._x1 || versor._x1 != _TEST_FP64_VERSOR_LIST[i]._x1 ||

56
basic-geometry-test/tests/versor/versor_is_identity.c
View file

@ -7,33 +7,33 @@
static const int _TEST_FP32_IDENTIYTY_VERSOR_AMOUNT = 9; static const int _TEST_FP32_IDENTIYTY_VERSOR_AMOUNT = 9;
static const int _TEST_FP32_NON_IDENTIYTY_VERSOR_AMOUNT = 5; static const int _TEST_FP32_NON_IDENTIYTY_VERSOR_AMOUNT = 5;
static const BgcVersorFP32 _TEST_FP32_IDENTIYTY_VERSOR_LIST[] = { static const BGC_FP32_Versor _TEST_FP32_IDENTIYTY_VERSOR_LIST[] = {
{ 1.0f, 0.0f, 0.0f, 0.0f }, { 1.0f, 0.0f, 0.0f, 0.0f },
{ 1.0f + 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f, 0.0f }, { 1.0f + 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f, 0.0f },
{ 1.0f - 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f, 0.0f }, { 1.0f - 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f, 0.0f },
{ 1.0f, 0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 1.0f, 0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 1.0f, -0.75f * BGC_EPSYLON_FP32, 0.0f, 0.0f }, { 1.0f, -0.75f * BGC_FP32_EPSYLON, 0.0f, 0.0f },
{ 1.0f, 0.0f, 0.75f * BGC_EPSYLON_FP32, 0.0f }, { 1.0f, 0.0f, 0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 1.0f, 0.0f, -0.75f * BGC_EPSYLON_FP32, 0.0f }, { 1.0f, 0.0f, -0.75f * BGC_FP32_EPSYLON, 0.0f },
{ 1.0f, 0.0f, 0.0f, 0.75f * BGC_EPSYLON_FP32 }, { 1.0f, 0.0f, 0.0f, 0.75f * BGC_FP32_EPSYLON },
{ 1.0f, 0.0f, 0.0f, -0.75f * BGC_EPSYLON_FP32 } { 1.0f, 0.0f, 0.0f, -0.75f * BGC_FP32_EPSYLON }
}; };
static const BgcVersorFP32 _TEST_FP32_NON_IDENTIYTY_VERSOR_LIST[] = { static const BGC_FP32_Versor _TEST_FP32_NON_IDENTIYTY_VERSOR_LIST[] = {
{ 0.0f, 1.0f, 0.0f, 0.0f }, { 0.0f, 1.0f, 0.0f, 0.0f },
{ 0.0f, 0.0f, 1.0f, 0.0f }, { 0.0f, 0.0f, 1.0f, 0.0f },
{ 0.0f, 0.0f, 0.0f, 1.0f }, { 0.0f, 0.0f, 0.0f, 1.0f },
{ 0.5f, 0.5f, 0.5f, 0.5f }, { 0.5f, 0.5f, 0.5f, 0.5f },
{ 1.0f, -1.25f * BGC_EPSYLON_FP32, 0.0f, 0.0f } { 1.0f, -1.25f * BGC_FP32_EPSYLON, 0.0f, 0.0f }
}; };
void test_versor_is_identity_fp32() void test_versor_is_identity_fp32()
{ {
print_testing_name("bgc_versor_is_identity_fp32"); print_testing_name("bgc_fp32_versor_is_idle");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP32_IDENTIYTY_VERSOR_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_IDENTIYTY_VERSOR_AMOUNT; i++) {
if (!bgc_versor_is_identity_fp32(&_TEST_FP32_IDENTIYTY_VERSOR_LIST[i])) { if (!bgc_fp32_versor_is_idle(&_TEST_FP32_IDENTIYTY_VERSOR_LIST[i])) {
print_testing_error("An identity versor was not recognized"); print_testing_error("An identity versor was not recognized");
return; return;
} }
@ -41,7 +41,7 @@ void test_versor_is_identity_fp32()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP32_NON_IDENTIYTY_VERSOR_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_NON_IDENTIYTY_VERSOR_AMOUNT; i++) {
if (bgc_versor_is_identity_fp32(&_TEST_FP32_NON_IDENTIYTY_VERSOR_LIST[i])) { if (bgc_fp32_versor_is_idle(&_TEST_FP32_NON_IDENTIYTY_VERSOR_LIST[i])) {
print_testing_error("A non-identity versor was recognized as an identity versor"); print_testing_error("A non-identity versor was recognized as an identity versor");
return; return;
} }
@ -55,33 +55,33 @@ void test_versor_is_identity_fp32()
static const int _TEST_FP64_IDENTIYTY_VERSOR_AMOUNT = 9; static const int _TEST_FP64_IDENTIYTY_VERSOR_AMOUNT = 9;
static const int _TEST_FP64_NON_IDENTIYTY_VERSOR_AMOUNT = 5; static const int _TEST_FP64_NON_IDENTIYTY_VERSOR_AMOUNT = 5;
static const BgcVersorFP64 _TEST_FP64_IDENTIYTY_VERSOR_LIST[] = { static const BGC_FP64_Versor _TEST_FP64_IDENTIYTY_VERSOR_LIST[] = {
{ 1.0, 0.0, 0.0, 0.0 }, { 1.0, 0.0, 0.0, 0.0 },
{ 1.0 + 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0, 0.0 }, { 1.0 + 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0, 0.0 },
{ 1.0 - 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0, 0.0 }, { 1.0 - 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0, 0.0 },
{ 1.0, -0.75 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 1.0, -0.75 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 1.0, 0.75 * BGC_EPSYLON_FP64, 0.0, 0.0 }, { 1.0, 0.75 * BGC_FP64_EPSYLON, 0.0, 0.0 },
{ 1.0, 0.0, 0.75 * BGC_EPSYLON_FP64, 0.0 }, { 1.0, 0.0, 0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 1.0, 0.0, -0.75 * BGC_EPSYLON_FP64, 0.0 }, { 1.0, 0.0, -0.75 * BGC_FP64_EPSYLON, 0.0 },
{ 1.0, 0.0, 0.0, 0.75 * BGC_EPSYLON_FP64 }, { 1.0, 0.0, 0.0, 0.75 * BGC_FP64_EPSYLON },
{ 1.0, 0.0, 0.0, -0.75 * BGC_EPSYLON_FP64 } { 1.0, 0.0, 0.0, -0.75 * BGC_FP64_EPSYLON }
}; };
static const BgcVersorFP64 _TEST_FP64_NON_IDENTIYTY_VERSOR_LIST[] = { static const BGC_FP64_Versor _TEST_FP64_NON_IDENTIYTY_VERSOR_LIST[] = {
{ 0.0, 1.0, 0.0, 0.0 }, { 0.0, 1.0, 0.0, 0.0 },
{ 0.0, 0.0, 1.0, 0.0 }, { 0.0, 0.0, 1.0, 0.0 },
{ 0.0, 0.0, 0.0, 1.0 }, { 0.0, 0.0, 0.0, 1.0 },
{ 0.5, 0.5, 0.5, 0.5 }, { 0.5, 0.5, 0.5, 0.5 },
{ 1.0, 0.0, 1.25 * BGC_EPSYLON_FP64, 0.0 } { 1.0, 0.0, 1.25 * BGC_FP64_EPSYLON, 0.0 }
}; };
void test_versor_is_identity_fp64() void test_versor_is_identity_fp64()
{ {
print_testing_name("bgc_versor_is_identity_fp64"); print_testing_name("bgc_fp64_versor_is_idle");
// Testing zero values: // Testing zero values:
for (int i = 0; i < _TEST_FP64_IDENTIYTY_VERSOR_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_IDENTIYTY_VERSOR_AMOUNT; i++) {
if (!bgc_versor_is_identity_fp64(&_TEST_FP64_IDENTIYTY_VERSOR_LIST[i])) { if (!bgc_fp64_versor_is_idle(&_TEST_FP64_IDENTIYTY_VERSOR_LIST[i])) {
print_testing_error("An identity versor was not recognized"); print_testing_error("An identity versor was not recognized");
return; return;
} }
@ -89,7 +89,7 @@ void test_versor_is_identity_fp64()
// Testing non-zero values: // Testing non-zero values:
for (int i = 0; i < _TEST_FP64_NON_IDENTIYTY_VERSOR_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_NON_IDENTIYTY_VERSOR_AMOUNT; i++) {
if (bgc_versor_is_identity_fp64(&_TEST_FP64_NON_IDENTIYTY_VERSOR_LIST[i])) { if (bgc_fp64_versor_is_idle(&_TEST_FP64_NON_IDENTIYTY_VERSOR_LIST[i])) {
print_testing_error("A non-identity versor was recognized as an identity versor"); print_testing_error("A non-identity versor was recognized as an identity versor");
return; return;
} }

12
basic-geometry-test/tests/versor/versor_reset.c
View file

@ -4,11 +4,11 @@
void test_versor_reset_fp32() void test_versor_reset_fp32()
{ {
BgcVersorFP32 versor; BGC_FP32_Versor versor;
print_testing_name("bgc_versor_reset_fp32"); print_testing_name("bgc_fp32_versor_reset");
bgc_versor_reset_fp32(&versor); bgc_fp32_versor_reset(&versor);
if (versor._s0 != 1.0f || versor._x1 != 0.0f || versor._x2 != 0.0f || versor._x3 != 0.0f) { if (versor._s0 != 1.0f || versor._x1 != 0.0f || versor._x2 != 0.0f || versor._x3 != 0.0f) {
print_testing_failed(); print_testing_failed();
@ -20,11 +20,11 @@ void test_versor_reset_fp32()
void test_versor_reset_fp64() void test_versor_reset_fp64()
{ {
BgcVersorFP64 versor; BGC_FP64_Versor versor;
print_testing_name("bgc_versor_reset_fp64"); print_testing_name("bgc_fp64_versor_reset");
bgc_versor_reset_fp64(&versor); bgc_fp64_versor_reset(&versor);
if (versor._s0 != 1.0 || versor._x1 != 0.0 || versor._x2 != 0.0 || versor._x3 != 0.0) { if (versor._s0 != 1.0 || versor._x1 != 0.0 || versor._x2 != 0.0 || versor._x3 != 0.0) {
print_testing_failed(); print_testing_failed();

36
basic-geometry-test/tests/versor/versor_set_values.c
View file

@ -7,7 +7,7 @@
// ==================== FP32 ==================== // // ==================== FP32 ==================== //
static const int _TEST_FP32_VERSOR_DATA_AMOUNT = 4; static const int _TEST_FP32_VERSOR_DATA_AMOUNT = 4;
static const BgcQuaternionFP32 _TEST_FP32_VERSOR_DATA_LIST[] = { static const BGC_FP32_Quaternion _TEST_FP32_VERSOR_DATA_LIST[] = {
{ 1.0f, 2.0f, 3.0f, 4.0f }, { 1.0f, 2.0f, 3.0f, 4.0f },
{ 4.0f, 3.0f, 2.0f, 1.0f }, { 4.0f, 3.0f, 2.0f, 1.0f },
{ -1.0f, 0.0f, 0.0f, 0.0f }, { -1.0f, 0.0f, 0.0f, 0.0f },
@ -17,12 +17,12 @@ static const BgcQuaternionFP32 _TEST_FP32_VERSOR_DATA_LIST[] = {
void test_versor_set_values_fp32() void test_versor_set_values_fp32()
{ {
float versor_module, ratio; float versor_module, ratio;
BgcVersorFP32 versor; BGC_FP32_Versor versor;
print_testing_name("bgc_versor_set_values_fp32"); print_testing_name("bgc_fp32_versor_make");
for (int i = 0; i < _TEST_FP32_VERSOR_DATA_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_VERSOR_DATA_AMOUNT; i++) {
bgc_versor_set_values_fp32( bgc_fp32_versor_make(
_TEST_FP32_VERSOR_DATA_LIST[i].s0, _TEST_FP32_VERSOR_DATA_LIST[i].s0,
_TEST_FP32_VERSOR_DATA_LIST[i].x1, _TEST_FP32_VERSOR_DATA_LIST[i].x1,
_TEST_FP32_VERSOR_DATA_LIST[i].x2, _TEST_FP32_VERSOR_DATA_LIST[i].x2,
@ -32,28 +32,28 @@ void test_versor_set_values_fp32()
versor_module = sqrtf(versor._s0 * versor._s0 + versor._x1 * versor._x1 + versor._x2 * versor._x2 + versor._x3 * versor._x3); versor_module = sqrtf(versor._s0 * versor._s0 + versor._x1 * versor._x1 + versor._x2 * versor._x2 + versor._x3 * versor._x3);
if (!bgc_is_unit_fp32(versor_module)) { if (!bgc_fp32_is_unit(versor_module)) {
print_testing_error("Versor module is not equal to one."); print_testing_error("Versor module is not equal to one.");
return; return;
} }
if (bgc_is_zero_fp32(_TEST_FP32_VERSOR_DATA_LIST[i].s0)) { if (bgc_fp32_is_zero(_TEST_FP32_VERSOR_DATA_LIST[i].s0)) {
continue; continue;
} }
ratio = _TEST_FP32_VERSOR_DATA_LIST[i].s0 / versor._s0; ratio = _TEST_FP32_VERSOR_DATA_LIST[i].s0 / versor._s0;
if (!bgc_is_zero_fp32(_TEST_FP32_VERSOR_DATA_LIST[i].x1) && !bgc_are_close_fp32(ratio, _TEST_FP32_VERSOR_DATA_LIST[i].x1 / versor._x1)) { if (!bgc_fp32_is_zero(_TEST_FP32_VERSOR_DATA_LIST[i].x1) && !bgc_fp32_are_close(ratio, _TEST_FP32_VERSOR_DATA_LIST[i].x1 / versor._x1)) {
print_testing_error("Versor was not normalized proportionally (x1)."); print_testing_error("Versor was not normalized proportionally (x1).");
return; return;
} }
if (!bgc_is_zero_fp32(_TEST_FP32_VERSOR_DATA_LIST[i].x2) && !bgc_are_close_fp32(ratio, _TEST_FP32_VERSOR_DATA_LIST[i].x2 / versor._x2)) { if (!bgc_fp32_is_zero(_TEST_FP32_VERSOR_DATA_LIST[i].x2) && !bgc_fp32_are_close(ratio, _TEST_FP32_VERSOR_DATA_LIST[i].x2 / versor._x2)) {
print_testing_error("Versor was not normalized proportionally (x2)."); print_testing_error("Versor was not normalized proportionally (x2).");
return; return;
} }
if (!bgc_is_zero_fp32(_TEST_FP32_VERSOR_DATA_LIST[i].x3) && !bgc_are_close_fp32(ratio, _TEST_FP32_VERSOR_DATA_LIST[i].x3 / versor._x3)) { if (!bgc_fp32_is_zero(_TEST_FP32_VERSOR_DATA_LIST[i].x3) && !bgc_fp32_are_close(ratio, _TEST_FP32_VERSOR_DATA_LIST[i].x3 / versor._x3)) {
print_testing_error("Versor was not normalized proportionally (x3)."); print_testing_error("Versor was not normalized proportionally (x3).");
return; return;
} }
@ -65,7 +65,7 @@ void test_versor_set_values_fp32()
// ==================== FP64 ==================== // // ==================== FP64 ==================== //
static const int _TEST_FP64_VERSOR_DATA_AMOUNT = 4; static const int _TEST_FP64_VERSOR_DATA_AMOUNT = 4;
static const BgcQuaternionFP64 _TEST_FP64_VERSOR_DATA_LIST[] = { static const BGC_FP64_Quaternion _TEST_FP64_VERSOR_DATA_LIST[] = {
{ 1.0, 2.0, 3.0, 4.0 }, { 1.0, 2.0, 3.0, 4.0 },
{ 4.0, 3.0, 2.0, 1.0 }, { 4.0, 3.0, 2.0, 1.0 },
{ -1.0, 0.0, 0.0, 0.0 }, { -1.0, 0.0, 0.0, 0.0 },
@ -75,12 +75,12 @@ static const BgcQuaternionFP64 _TEST_FP64_VERSOR_DATA_LIST[] = {
void test_versor_set_values_fp64() void test_versor_set_values_fp64()
{ {
double versor_module, ratio; double versor_module, ratio;
BgcVersorFP64 versor; BGC_FP64_Versor versor;
print_testing_name("bgc_versor_set_values_fp64"); print_testing_name("bgc_fp64_versor_make");
for (int i = 0; i < _TEST_FP64_VERSOR_DATA_AMOUNT; i++) { for (int i = 0; i < _TEST_FP64_VERSOR_DATA_AMOUNT; i++) {
bgc_versor_set_values_fp64( bgc_fp64_versor_make(
_TEST_FP64_VERSOR_DATA_LIST[i].s0, _TEST_FP64_VERSOR_DATA_LIST[i].s0,
_TEST_FP64_VERSOR_DATA_LIST[i].x1, _TEST_FP64_VERSOR_DATA_LIST[i].x1,
_TEST_FP64_VERSOR_DATA_LIST[i].x2, _TEST_FP64_VERSOR_DATA_LIST[i].x2,
@ -90,28 +90,28 @@ void test_versor_set_values_fp64()
versor_module = sqrt(versor._s0 * versor._s0 + versor._x1 * versor._x1 + versor._x2 * versor._x2 + versor._x3 * versor._x3); versor_module = sqrt(versor._s0 * versor._s0 + versor._x1 * versor._x1 + versor._x2 * versor._x2 + versor._x3 * versor._x3);
if (!bgc_is_unit_fp64(versor_module)) { if (!bgc_fp64_is_unit(versor_module)) {
print_testing_error("Versor module is not equal to one."); print_testing_error("Versor module is not equal to one.");
return; return;
} }
if (bgc_is_zero_fp64(_TEST_FP64_VERSOR_DATA_LIST[i].s0)) { if (bgc_fp64_is_zero(_TEST_FP64_VERSOR_DATA_LIST[i].s0)) {
continue; continue;
} }
ratio = _TEST_FP64_VERSOR_DATA_LIST[i].s0 / versor._s0; ratio = _TEST_FP64_VERSOR_DATA_LIST[i].s0 / versor._s0;
if (!bgc_is_zero_fp64(_TEST_FP64_VERSOR_DATA_LIST[i].x1) && !bgc_are_close_fp64(ratio, _TEST_FP64_VERSOR_DATA_LIST[i].x1 / versor._x1)) { if (!bgc_fp64_is_zero(_TEST_FP64_VERSOR_DATA_LIST[i].x1) && !bgc_fp64_are_close(ratio, _TEST_FP64_VERSOR_DATA_LIST[i].x1 / versor._x1)) {
print_testing_error("Versor was not normalized proportionally (x1)."); print_testing_error("Versor was not normalized proportionally (x1).");
return; return;
} }
if (!bgc_is_zero_fp64(_TEST_FP64_VERSOR_DATA_LIST[i].x2) && !bgc_are_close_fp64(ratio, _TEST_FP64_VERSOR_DATA_LIST[i].x2 / versor._x2)) { if (!bgc_fp64_is_zero(_TEST_FP64_VERSOR_DATA_LIST[i].x2) && !bgc_fp64_are_close(ratio, _TEST_FP64_VERSOR_DATA_LIST[i].x2 / versor._x2)) {
print_testing_error("Versor was not normalized proportionally (x2)."); print_testing_error("Versor was not normalized proportionally (x2).");
return; return;
} }
if (!bgc_is_zero_fp64(_TEST_FP64_VERSOR_DATA_LIST[i].x3) && !bgc_are_close_fp64(ratio, _TEST_FP64_VERSOR_DATA_LIST[i].x3 / versor._x3)) { if (!bgc_fp64_is_zero(_TEST_FP64_VERSOR_DATA_LIST[i].x3) && !bgc_fp64_are_close(ratio, _TEST_FP64_VERSOR_DATA_LIST[i].x3 / versor._x3)) {
print_testing_error("Versor was not normalized proportionally (x3)."); print_testing_error("Versor was not normalized proportionally (x3).");
return; return;
} }

32
basic-geometry-test/tests/versor/versor_swap.c
View file

@ -8,13 +8,13 @@
static const int _TEST_FP32_VERSOR_AMOUNT = 3; static const int _TEST_FP32_VERSOR_AMOUNT = 3;
static const BgcQuaternionFP32 _TEST_FP32_VERSOR_LIST1[] = { static const BGC_FP32_Quaternion _TEST_FP32_VERSOR_LIST1[] = {
{ 1.0f, 2.0f, 3.0f, 4.0f }, { 1.0f, 2.0f, 3.0f, 4.0f },
{ -4.0f, -3.0f, -2.0f, -1.0f }, { -4.0f, -3.0f, -2.0f, -1.0f },
{ 0.5f, -0.5f, -0.5f, -0.5f } { 0.5f, -0.5f, -0.5f, -0.5f }
}; };
static const BgcQuaternionFP32 _TEST_FP32_VERSOR_LIST2[] = { static const BGC_FP32_Quaternion _TEST_FP32_VERSOR_LIST2[] = {
{ -0.5f, 0.5f, 0.5f, 0.5f }, { -0.5f, 0.5f, 0.5f, 0.5f },
{ -1.0f, -2.0f, -3.0f, -4.0f }, { -1.0f, -2.0f, -3.0f, -4.0f },
{ 4.0f, 3.0f, 2.0f, 1.0f } { 4.0f, 3.0f, 2.0f, 1.0f }
@ -22,12 +22,12 @@ static const BgcQuaternionFP32 _TEST_FP32_VERSOR_LIST2[] = {
void test_versor_swap_fp32() void test_versor_swap_fp32()
{ {
BgcVersorFP32 versor1a, versor2a, versor1b, versor2b; BGC_FP32_Versor versor1a, versor2a, versor1b, versor2b;
print_testing_name("bgc_versor_swap_fp32"); print_testing_name("bgc_fp32_versor_swap");
for (int i = 0; i < _TEST_FP32_VERSOR_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_VERSOR_AMOUNT; i++) {
bgc_versor_set_values_fp32( bgc_fp32_versor_make(
_TEST_FP32_VERSOR_LIST1[i].s0, _TEST_FP32_VERSOR_LIST1[i].s0,
_TEST_FP32_VERSOR_LIST1[i].x1, _TEST_FP32_VERSOR_LIST1[i].x1,
_TEST_FP32_VERSOR_LIST1[i].x2, _TEST_FP32_VERSOR_LIST1[i].x2,
@ -35,7 +35,7 @@ void test_versor_swap_fp32()
&versor1a &versor1a
); );
bgc_versor_set_values_fp32( bgc_fp32_versor_make(
_TEST_FP32_VERSOR_LIST2[i].s0, _TEST_FP32_VERSOR_LIST2[i].s0,
_TEST_FP32_VERSOR_LIST2[i].x1, _TEST_FP32_VERSOR_LIST2[i].x1,
_TEST_FP32_VERSOR_LIST2[i].x2, _TEST_FP32_VERSOR_LIST2[i].x2,
@ -43,10 +43,10 @@ void test_versor_swap_fp32()
&versor2a &versor2a
); );
bgc_versor_copy_fp32(&versor1a, &versor1b); bgc_fp32_versor_copy(&versor1a, &versor1b);
bgc_versor_copy_fp32(&versor2a, &versor2b); bgc_fp32_versor_copy(&versor2a, &versor2b);
bgc_versor_swap_fp32(&versor1b, &versor2b); bgc_fp32_versor_swap(&versor1b, &versor2b);
if (versor1a._s0 != versor2b._s0 || versor1a._x1 != versor2b._x1 || versor1a._x2 != versor2b._x2 || versor1a._x3 != versor2b._x3 || if (versor1a._s0 != versor2b._s0 || versor1a._x1 != versor2b._x1 || versor1a._x2 != versor2b._x2 || versor1a._x3 != versor2b._x3 ||
versor2a._s0 != versor1b._s0 || versor2a._x1 != versor1b._x1 || versor2a._x2 != versor1b._x2 || versor2a._x3 != versor1b._x3) { versor2a._s0 != versor1b._s0 || versor2a._x1 != versor1b._x1 || versor2a._x2 != versor1b._x2 || versor2a._x3 != versor1b._x3) {
@ -62,12 +62,12 @@ void test_versor_swap_fp32()
void test_versor_swap_fp64() void test_versor_swap_fp64()
{ {
BgcVersorFP64 versor1a, versor2a, versor1b, versor2b; BGC_FP64_Versor versor1a, versor2a, versor1b, versor2b;
print_testing_name("bgc_versor_swap_fp64"); print_testing_name("bgc_fp64_versor_swap");
for (int i = 0; i < _TEST_FP32_VERSOR_AMOUNT; i++) { for (int i = 0; i < _TEST_FP32_VERSOR_AMOUNT; i++) {
bgc_versor_set_values_fp64( bgc_fp64_versor_make(
_TEST_FP32_VERSOR_LIST1[i].s0, _TEST_FP32_VERSOR_LIST1[i].s0,
_TEST_FP32_VERSOR_LIST1[i].x1, _TEST_FP32_VERSOR_LIST1[i].x1,
_TEST_FP32_VERSOR_LIST1[i].x2, _TEST_FP32_VERSOR_LIST1[i].x2,
@ -75,7 +75,7 @@ void test_versor_swap_fp64()
&versor1a &versor1a
); );
bgc_versor_set_values_fp64( bgc_fp64_versor_make(
_TEST_FP32_VERSOR_LIST2[i].s0, _TEST_FP32_VERSOR_LIST2[i].s0,
_TEST_FP32_VERSOR_LIST2[i].x1, _TEST_FP32_VERSOR_LIST2[i].x1,
_TEST_FP32_VERSOR_LIST2[i].x2, _TEST_FP32_VERSOR_LIST2[i].x2,
@ -83,10 +83,10 @@ void test_versor_swap_fp64()
&versor2a &versor2a
); );
bgc_versor_copy_fp64(&versor1a, &versor1b); bgc_fp64_versor_copy(&versor1a, &versor1b);
bgc_versor_copy_fp64(&versor2a, &versor2b); bgc_fp64_versor_copy(&versor2a, &versor2b);
bgc_versor_swap_fp64(&versor1b, &versor2b); bgc_fp64_versor_swap(&versor1b, &versor2b);
if (versor1a._s0 != versor2b._s0 || versor1a._x1 != versor2b._x1 || versor1a._x2 != versor2b._x2 || versor1a._x3 != versor2b._x3 || if (versor1a._s0 != versor2b._s0 || versor1a._x1 != versor2b._x1 || versor1a._x2 != versor2b._x2 || versor1a._x3 != versor2b._x3 ||
versor2a._s0 != versor1b._s0 || versor2a._x1 != versor1b._x1 || versor2a._x2 != versor1b._x2 || versor2a._x3 != versor1b._x3) { versor2a._s0 != versor1b._s0 || versor2a._x1 != versor1b._x1 || versor2a._x2 != versor1b._x2 || versor2a._x3 != versor1b._x3) {

39
basic-geometry/affine2.c
View file

@ -1,28 +1,31 @@
#include "affine2.h" #include "affine2.h"
extern inline void bgc_affine2_reset_fp32(BgcAffine2FP32 * affine); extern inline void bgc_fp32_affine2_reset(BGC_FP32_Affine2 * affine);
extern inline void bgc_affine2_reset_fp64(BgcAffine2FP64 * affine); extern inline void bgc_fp64_affine2_reset(BGC_FP64_Affine2 * affine);
extern inline void bgc_affine2_make_fp32(const BgcMatrix2x2FP32 * distortion, const BgcVector2FP32 * shift, BgcAffine2FP32 * affine); extern inline void bgc_fp32_affine2_make(const BGC_FP32_Matrix2x2 * distortion, const BGC_FP32_Vector2 * shift, BGC_FP32_Affine2 * affine);
extern inline void bgc_affine2_make_fp64(const BgcMatrix2x2FP64 * distortion, const BgcVector2FP64 * shift, BgcAffine2FP64 * affine); extern inline void bgc_fp64_affine2_make(const BGC_FP64_Matrix2x2 * distortion, const BGC_FP64_Vector2 * shift, BGC_FP64_Affine2 * affine);
extern inline void bgc_affine2_copy_fp32(const BgcAffine2FP32 * source, BgcAffine2FP32 * destination); extern inline void bgc_fp32_affine2_copy(const BGC_FP32_Affine2 * source, BGC_FP32_Affine2 * destination);
extern inline void bgc_affine2_copy_fp64(const BgcAffine2FP64 * source, BgcAffine2FP64 * destination); extern inline void bgc_fp64_affine2_copy(const BGC_FP64_Affine2 * source, BGC_FP64_Affine2 * destination);
extern inline void bgc_affine2_convert_fp64_to_fp32(const BgcAffine2FP64 * source, BgcAffine2FP32 * destination); extern inline void bgc_fp32_affine2_swap(BGC_FP32_Affine2 * first, BGC_FP32_Affine2 * second);
extern inline void bgc_affine2_convert_fp32_to_fp64(const BgcAffine2FP32 * source, BgcAffine2FP64 * destination); extern inline void bgc_fp64_affine2_swap(BGC_FP64_Affine2 * first, BGC_FP64_Affine2 * second);
extern inline int bgc_affine2_invert_fp32(BgcAffine2FP32 * affine); extern inline void bgc_fp64_affine2_convert_to_fp32(const BGC_FP64_Affine2 * source, BGC_FP32_Affine2 * destination);
extern inline int bgc_affine2_invert_fp64(BgcAffine2FP64 * affine); extern inline void bgc_fp32_affine2_convert_to_fp64(const BGC_FP32_Affine2 * source, BGC_FP64_Affine2 * destination);
extern inline int bgc_affine2_get_inverse_fp32(const BgcAffine2FP32 * source, BgcAffine2FP32 * destination); extern inline int bgc_fp32_affine2_invert(BGC_FP32_Affine2 * affine);
extern inline int bgc_affine2_get_inverse_fp64(const BgcAffine2FP64 * source, BgcAffine2FP64 * destination); extern inline int bgc_fp64_affine2_invert(BGC_FP64_Affine2 * affine);
extern inline void bgc_affine2_combine_fp32(const BgcAffine2FP32 * first, const BgcAffine2FP32 * second, BgcAffine2FP32 * combination); extern inline int bgc_fp32_affine2_get_inverse(const BGC_FP32_Affine2 * source, BGC_FP32_Affine2 * destination);
extern inline void bgc_affine2_combine_fp64(const BgcAffine2FP64 * first, const BgcAffine2FP64 * second, BgcAffine2FP64 * combination); extern inline int bgc_fp64_affine2_get_inverse(const BGC_FP64_Affine2 * source, BGC_FP64_Affine2 * destination);
extern inline void bgc_affine2_transform_point_fp32(const BgcAffine2FP32 * affine, const BgcVector2FP32 * initial_point, BgcVector2FP32 * transformed_point); extern inline void bgc_fp32_affine2_combine(const BGC_FP32_Affine2 * first, const BGC_FP32_Affine2 * second, BGC_FP32_Affine2 * combination);
extern inline void bgc_affine2_transform_point_fp64(const BgcAffine2FP64 * affine, const BgcVector2FP64 * initial_point, BgcVector2FP64 * transformed_point); extern inline void bgc_fp64_affine2_combine(const BGC_FP64_Affine2 * first, const BGC_FP64_Affine2 * second, BGC_FP64_Affine2 * combination);
extern inline void bgc_affine2_transform_vector_fp32(const BgcAffine2FP32 * affine, const BgcVector2FP32 * initial_vector, BgcVector2FP32 * transformed_vector); extern inline void bgc_fp32_affine2_transform_point(const BGC_FP32_Affine2 * affine, const BGC_FP32_Vector2 * initial_point, BGC_FP32_Vector2 * transformed_point);
extern inline void bgc_affine2_transform_vector_fp64(const BgcAffine2FP64 * affine, const BgcVector2FP64 * initial_vector, BgcVector2FP64 * transformed_vector); extern inline void bgc_fp64_affine2_transform_point(const BGC_FP64_Affine2 * affine, const BGC_FP64_Vector2 * initial_point, BGC_FP64_Vector2 * transformed_point);
extern inline void bgc_fp32_affine2_transform_vector(const BGC_FP32_Affine2 * affine, const BGC_FP32_Vector2 * initial_vector, BGC_FP32_Vector2 * transformed_vector);
extern inline void bgc_fp64_affine2_transform_vector(const BGC_FP64_Affine2 * affine, const BGC_FP64_Vector2 * initial_vector, BGC_FP64_Vector2 * transformed_vector);

150
basic-geometry/affine2.h
View file

@ -8,168 +8,182 @@
// ==================== Types ==================== // // ==================== Types ==================== //
typedef struct { typedef struct {
BgcMatrix2x2FP32 distortion; BGC_FP32_Matrix2x2 distortion;
BgcVector2FP32 shift; BGC_FP32_Vector2 shift;
} BgcAffine2FP32; } BGC_FP32_Affine2;
typedef struct { typedef struct {
BgcMatrix2x2FP64 distortion; BGC_FP64_Matrix2x2 distortion;
BgcVector2FP64 shift; BGC_FP64_Vector2 shift;
} BgcAffine2FP64; } BGC_FP64_Affine2;
// ==================== Reset ==================== // // ==================== Reset ==================== //
inline void bgc_affine2_reset_fp32(BgcAffine2FP32 * affine) inline void bgc_fp32_affine2_reset(BGC_FP32_Affine2 * affine)
{ {
bgc_matrix2x2_set_to_identity_fp32(&affine->distortion); bgc_fp32_matrix2x2_make_identity(&affine->distortion);
bgc_vector2_reset_fp32(&affine->shift); bgc_fp32_vector2_reset(&affine->shift);
} }
inline void bgc_affine2_reset_fp64(BgcAffine2FP64 * affine) inline void bgc_fp64_affine2_reset(BGC_FP64_Affine2 * affine)
{ {
bgc_matrix2x2_set_to_identity_fp64(&affine->distortion); bgc_fp64_matrix2x2_make_identity(&affine->distortion);
bgc_vector2_reset_fp64(&affine->shift); bgc_fp64_vector2_reset(&affine->shift);
} }
// ==================== Make ===================== // // ==================== Make ===================== //
inline void bgc_affine2_make_fp32(const BgcMatrix2x2FP32 * distortion, const BgcVector2FP32 * shift, BgcAffine2FP32 * affine) inline void bgc_fp32_affine2_make(const BGC_FP32_Matrix2x2 * distortion, const BGC_FP32_Vector2 * shift, BGC_FP32_Affine2 * affine)
{ {
bgc_matrix2x2_copy_fp32(distortion, &affine->distortion); bgc_fp32_matrix2x2_copy(distortion, &affine->distortion);
bgc_vector2_copy_fp32(shift, &affine->shift); bgc_fp32_vector2_copy(shift, &affine->shift);
} }
inline void bgc_affine2_make_fp64(const BgcMatrix2x2FP64 * distortion, const BgcVector2FP64 * shift, BgcAffine2FP64 * affine) inline void bgc_fp64_affine2_make(const BGC_FP64_Matrix2x2 * distortion, const BGC_FP64_Vector2 * shift, BGC_FP64_Affine2 * affine)
{ {
bgc_matrix2x2_copy_fp64(distortion, &affine->distortion); bgc_fp64_matrix2x2_copy(distortion, &affine->distortion);
bgc_vector2_copy_fp64(shift, &affine->shift); bgc_fp64_vector2_copy(shift, &affine->shift);
} }
// ==================== Copy ===================== // // ==================== Copy ===================== //
inline void bgc_affine2_copy_fp32(const BgcAffine2FP32 * source, BgcAffine2FP32 * destination) inline void bgc_fp32_affine2_copy(const BGC_FP32_Affine2 * source, BGC_FP32_Affine2 * destination)
{ {
bgc_matrix2x2_copy_fp32(&source->distortion, &destination->distortion); bgc_fp32_matrix2x2_copy(&source->distortion, &destination->distortion);
bgc_vector2_copy_fp32(&source->shift, &destination->shift); bgc_fp32_vector2_copy(&source->shift, &destination->shift);
} }
inline void bgc_affine2_copy_fp64(const BgcAffine2FP64 * source, BgcAffine2FP64 * destination) inline void bgc_fp64_affine2_copy(const BGC_FP64_Affine2 * source, BGC_FP64_Affine2 * destination)
{ {
bgc_matrix2x2_copy_fp64(&source->distortion, &destination->distortion); bgc_fp64_matrix2x2_copy(&source->distortion, &destination->distortion);
bgc_vector2_copy_fp64(&source->shift, &destination->shift); bgc_fp64_vector2_copy(&source->shift, &destination->shift);
}
// ==================== Swap ===================== //
inline void bgc_fp32_affine2_swap(BGC_FP32_Affine2 * first, BGC_FP32_Affine2 * second)
{
bgc_fp32_matrix2x2_swap(&first->distortion, &second->distortion);
bgc_fp32_vector2_swap(&first->shift, &second->shift);
}
inline void bgc_fp64_affine2_swap(BGC_FP64_Affine2 * first, BGC_FP64_Affine2 * second)
{
bgc_fp64_matrix2x2_swap(&first->distortion, &second->distortion);
bgc_fp64_vector2_swap(&first->shift, &second->shift);
} }
// =================== Convert =================== // // =================== Convert =================== //
inline void bgc_affine2_convert_fp64_to_fp32(const BgcAffine2FP64 * source, BgcAffine2FP32 * destination) inline void bgc_fp64_affine2_convert_to_fp32(const BGC_FP64_Affine2 * source, BGC_FP32_Affine2 * destination)
{ {
bgc_matrix2x2_convert_fp64_to_fp32(&source->distortion, &destination->distortion); bgc_fp64_matrix2x2_convert_to_fp32(&source->distortion, &destination->distortion);
bgc_vector2_convert_fp64_to_fp32(&source->shift, &destination->shift); bgc_fp64_vector2_convert_to_fp32(&source->shift, &destination->shift);
} }
inline void bgc_affine2_convert_fp32_to_fp64(const BgcAffine2FP32 * source, BgcAffine2FP64 * destination) inline void bgc_fp32_affine2_convert_to_fp64(const BGC_FP32_Affine2 * source, BGC_FP64_Affine2 * destination)
{ {
bgc_matrix2x2_convert_fp32_to_fp64(&source->distortion, &destination->distortion); bgc_fp32_matrix2x2_convert_to_fp64(&source->distortion, &destination->distortion);
bgc_vector2_convert_fp32_to_fp64(&source->shift, &destination->shift); bgc_fp32_vector2_convert_to_fp64(&source->shift, &destination->shift);
} }
// =================== Invert ==================== // // =================== Invert ==================== //
inline int bgc_affine2_invert_fp32(BgcAffine2FP32 * affine) inline int bgc_fp32_affine2_invert(BGC_FP32_Affine2 * affine)
{ {
if (!bgc_matrix2x2_invert_fp32(&affine->distortion, &affine->distortion)) { if (!bgc_fp32_matrix2x2_invert(&affine->distortion)) {
return 0; return 0;
} }
bgc_matrix2x2_get_right_product_fp32(&affine->distortion, &affine->shift, &affine->shift); bgc_fp32_multiply_matrix2x2_by_vector2(&affine->distortion, &affine->shift, &affine->shift);
bgc_vector2_make_opposite_fp32(&affine->shift); bgc_fp32_vector2_revert(&affine->shift);
return 1; return 1;
} }
inline int bgc_affine2_invert_fp64(BgcAffine2FP64 * affine) inline int bgc_fp64_affine2_invert(BGC_FP64_Affine2 * affine)
{ {
if (!bgc_matrix2x2_invert_fp64(&affine->distortion, &affine->distortion)) { if (!bgc_fp64_matrix2x2_invert(&affine->distortion)) {
return 0; return 0;
} }
bgc_matrix2x2_get_right_product_fp64(&affine->distortion, &affine->shift, &affine->shift); bgc_fp64_multiply_matrix2x2_by_vector2(&affine->distortion, &affine->shift, &affine->shift);
bgc_vector2_make_opposite_fp64(&affine->shift); bgc_fp64_vector2_revert(&affine->shift);
return 1; return 1;
} }
// ================= Get Inverse ================= // // ================= Get Inverse ================= //
inline int bgc_affine2_get_inverse_fp32(const BgcAffine2FP32 * source, BgcAffine2FP32 * destination) inline int bgc_fp32_affine2_get_inverse(const BGC_FP32_Affine2 * source, BGC_FP32_Affine2 * destination)
{ {
if (!bgc_matrix2x2_invert_fp32(&source->distortion, &destination->distortion)) { if (!bgc_fp32_matrix2x2_get_inverse(&source->distortion, &destination->distortion)) {
return 0; return 0;
} }
bgc_matrix2x2_get_right_product_fp32(&destination->distortion, &source->shift, &destination->shift); bgc_fp32_multiply_matrix2x2_by_vector2(&destination->distortion, &source->shift, &destination->shift);
bgc_vector2_make_opposite_fp32(&destination->shift); bgc_fp32_vector2_revert(&destination->shift);
return 1; return 1;
} }
inline int bgc_affine2_get_inverse_fp64(const BgcAffine2FP64 * source, BgcAffine2FP64 * destination) inline int bgc_fp64_affine2_get_inverse(const BGC_FP64_Affine2 * source, BGC_FP64_Affine2 * destination)
{ {
if (!bgc_matrix2x2_invert_fp64(&source->distortion, &destination->distortion)) { if (!bgc_fp64_matrix2x2_get_inverse(&source->distortion, &destination->distortion)) {
return 0; return 0;
} }
bgc_matrix2x2_get_right_product_fp64(&destination->distortion, &source->shift, &destination->shift); bgc_fp64_multiply_matrix2x2_by_vector2(&destination->distortion, &source->shift, &destination->shift);
bgc_vector2_make_opposite_fp64(&destination->shift); bgc_fp64_vector2_revert(&destination->shift);
return 1; return 1;
} }
// =================== Combine =================== // // =================== Combine =================== //
inline void bgc_affine2_combine_fp32(const BgcAffine2FP32 * first, const BgcAffine2FP32 * second, BgcAffine2FP32 * combination) inline void bgc_fp32_affine2_combine(const BGC_FP32_Affine2 * first, const BGC_FP32_Affine2 * second, BGC_FP32_Affine2 * combination)
{ {
BgcVector2FP32 first_shift; BGC_FP32_Vector2 first_shift;
bgc_matrix2x2_get_right_product_fp32(&second->distortion, &first->shift, &first_shift); bgc_fp32_multiply_matrix2x2_by_vector2(&second->distortion, &first->shift, &first_shift);
bgc_matrix_product_2x2_at_2x2_fp32(&second->distortion, &first->distortion, &combination->distortion); bgc_fp32_multiply_matrix2x2_by_matrix2x2(&second->distortion, &first->distortion, &combination->distortion);
bgc_vector2_add_fp32(&first_shift, &second->shift, &combination->shift); bgc_fp32_vector2_add(&first_shift, &second->shift, &combination->shift);
} }
inline void bgc_affine2_combine_fp64(const BgcAffine2FP64 * first, const BgcAffine2FP64 * second, BgcAffine2FP64 * combination) inline void bgc_fp64_affine2_combine(const BGC_FP64_Affine2 * first, const BGC_FP64_Affine2 * second, BGC_FP64_Affine2 * combination)
{ {
BgcVector2FP64 first_shift; BGC_FP64_Vector2 first_shift;
bgc_matrix2x2_get_right_product_fp64(&second->distortion, &first->shift, &first_shift); bgc_fp64_multiply_matrix2x2_by_vector2(&second->distortion, &first->shift, &first_shift);
bgc_matrix_product_2x2_at_2x2_fp64(&second->distortion, &first->distortion, &combination->distortion); bgc_fp64_multiply_matrix2x2_by_matrix2x2(&second->distortion, &first->distortion, &combination->distortion);
bgc_vector2_add_fp64(&first_shift, &second->shift, &combination->shift); bgc_fp64_vector2_add(&first_shift, &second->shift, &combination->shift);
} }
// =============== Transform Point =============== // // =============== Transform Point =============== //
inline void bgc_affine2_transform_point_fp32(const BgcAffine2FP32 * affine, const BgcVector2FP32 * initial_point, BgcVector2FP32 * transformed_point) inline void bgc_fp32_affine2_transform_point(const BGC_FP32_Affine2 * affine, const BGC_FP32_Vector2 * initial_point, BGC_FP32_Vector2 * transformed_point)
{ {
BgcVector2FP32 distorted; BGC_FP32_Vector2 distorted;
bgc_matrix2x2_get_right_product_fp32(&affine->distortion, initial_point, &distorted); bgc_fp32_multiply_matrix2x2_by_vector2(&affine->distortion, initial_point, &distorted);
bgc_vector2_add_fp32(&affine->shift, &distorted, transformed_point); bgc_fp32_vector2_add(&affine->shift, &distorted, transformed_point);
} }
inline void bgc_affine2_transform_point_fp64(const BgcAffine2FP64 * affine, const BgcVector2FP64 * initial_point, BgcVector2FP64 * transformed_point) inline void bgc_fp64_affine2_transform_point(const BGC_FP64_Affine2 * affine, const BGC_FP64_Vector2 * initial_point, BGC_FP64_Vector2 * transformed_point)
{ {
BgcVector2FP64 distorted; BGC_FP64_Vector2 distorted;
bgc_matrix2x2_get_right_product_fp64(&affine->distortion, initial_point, &distorted); bgc_fp64_multiply_matrix2x2_by_vector2(&affine->distortion, initial_point, &distorted);
bgc_vector2_add_fp64(&affine->shift, &distorted, transformed_point); bgc_fp64_vector2_add(&affine->shift, &distorted, transformed_point);
} }
// ============== Transform Vector =============== // // ============== Transform Vector =============== //
inline void bgc_affine2_transform_vector_fp32(const BgcAffine2FP32 * affine, const BgcVector2FP32 * initial_vector, BgcVector2FP32 * transformed_vector) inline void bgc_fp32_affine2_transform_vector(const BGC_FP32_Affine2 * affine, const BGC_FP32_Vector2 * initial_vector, BGC_FP32_Vector2 * transformed_vector)
{ {
bgc_matrix2x2_get_right_product_fp32(&affine->distortion, initial_vector, transformed_vector); bgc_fp32_multiply_matrix2x2_by_vector2(&affine->distortion, initial_vector, transformed_vector);
} }
inline void bgc_affine2_transform_vector_fp64(const BgcAffine2FP64 * affine, const BgcVector2FP64 * initial_vector, BgcVector2FP64 * transformed_vector) inline void bgc_fp64_affine2_transform_vector(const BGC_FP64_Affine2 * affine, const BGC_FP64_Vector2 * initial_vector, BGC_FP64_Vector2 * transformed_vector)
{ {
bgc_matrix2x2_get_right_product_fp64(&affine->distortion, initial_vector, transformed_vector); bgc_fp64_multiply_matrix2x2_by_vector2(&affine->distortion, initial_vector, transformed_vector);
} }
#endif #endif

39
basic-geometry/affine3.c
View file

@ -1,28 +1,31 @@
#include "affine3.h" #include "affine3.h"
extern inline void bgc_affine3_reset_fp32(BgcAffine3FP32 * affine); extern inline void bgc_fp32_affine3_reset(BGC_FP32_Affine3 * affine);
extern inline void bgc_affine3_reset_fp64(BgcAffine3FP64 * affine); extern inline void bgc_fp64_affine3_reset(BGC_FP64_Affine3 * affine);
extern inline void bgc_affine3_make_fp32(const BgcMatrix3x3FP32 * distortion, const BgcVector3FP32 * shift, BgcAffine3FP32 * affine); extern inline void bgc_fp32_affine3_make(const BGC_FP32_Matrix3x3 * distortion, const BGC_FP32_Vector3 * shift, BGC_FP32_Affine3 * affine);
extern inline void bgc_affine3_make_fp64(const BgcMatrix3x3FP64 * distortion, const BgcVector3FP64 * shift, BgcAffine3FP64 * affine); extern inline void bgc_fp64_affine3_make(const BGC_FP64_Matrix3x3 * distortion, const BGC_FP64_Vector3 * shift, BGC_FP64_Affine3 * affine);
extern inline void bgc_affine3_copy_fp32(const BgcAffine3FP32 * source, BgcAffine3FP32 * destination); extern inline void bgc_fp32_affine3_copy(const BGC_FP32_Affine3 * source, BGC_FP32_Affine3 * destination);
extern inline void bgc_affine3_copy_fp64(const BgcAffine3FP64 * source, BgcAffine3FP64 * destination); extern inline void bgc_fp64_affine3_copy(const BGC_FP64_Affine3 * source, BGC_FP64_Affine3 * destination);
extern inline void bgc_affine3_convert_fp64_to_fp32(const BgcAffine3FP64 * source, BgcAffine3FP32 * destination); extern inline void bgc_fp32_affine3_swap(BGC_FP32_Affine3 * first, BGC_FP32_Affine3 * second);
extern inline void bgc_affine3_convert_fp32_to_fp64(const BgcAffine3FP32 * source, BgcAffine3FP64 * destination); extern inline void bgc_fp64_affine3_swap(BGC_FP64_Affine3 * first, BGC_FP64_Affine3 * second);
extern inline int bgc_affine3_invert_fp32(BgcAffine3FP32 * affine); extern inline void bgc_fp64_affine3_convert_to_fp32(const BGC_FP64_Affine3 * source, BGC_FP32_Affine3 * destination);
extern inline int bgc_affine3_invert_fp64(BgcAffine3FP64 * affine); extern inline void bgc_fp32_affine3_convert_to_fp64(const BGC_FP32_Affine3 * source, BGC_FP64_Affine3 * destination);
extern inline int bgc_affine3_get_inverse_fp32(const BgcAffine3FP32 * source, BgcAffine3FP32 * destination); extern inline int bgc_fp32_affine3_invert(BGC_FP32_Affine3 * affine);
extern inline int bgc_affine3_get_inverse_fp64(const BgcAffine3FP64 * source, BgcAffine3FP64 * destination); extern inline int bgc_fp64_affine3_invert(BGC_FP64_Affine3 * affine);
extern inline void bgc_affine3_combine_fp32(const BgcAffine3FP32 * first, const BgcAffine3FP32 * second, BgcAffine3FP32 * combination); extern inline int bgc_fp32_affine3_get_inverse(const BGC_FP32_Affine3 * source, BGC_FP32_Affine3 * destination);
extern inline void bgc_affine3_combine_fp64(const BgcAffine3FP64 * first, const BgcAffine3FP64 * second, BgcAffine3FP64 * combination); extern inline int bgc_fp64_affine3_get_inverse(const BGC_FP64_Affine3 * source, BGC_FP64_Affine3 * destination);
extern inline void bgc_affine3_transform_point_fp32(const BgcAffine3FP32 * affine, const BgcVector3FP32 * initial_point, BgcVector3FP32 * transformed_point); extern inline void bgc_fp32_affine3_combine(const BGC_FP32_Affine3 * first, const BGC_FP32_Affine3 * second, BGC_FP32_Affine3 * combination);
extern inline void bgc_affine3_transform_point_fp64(const BgcAffine3FP64 * affine, const BgcVector3FP64 * initial_point, BgcVector3FP64 * transformed_point); extern inline void bgc_fp64_affine3_combine(const BGC_FP64_Affine3 * first, const BGC_FP64_Affine3 * second, BGC_FP64_Affine3 * combination);
extern inline void bgc_affine3_transform_vector_fp32(const BgcAffine3FP32 * affine, const BgcVector3FP32 * initial_vector, BgcVector3FP32 * transformed_vector); extern inline void bgc_fp32_affine3_transform_point(const BGC_FP32_Affine3 * affine, const BGC_FP32_Vector3 * initial_point, BGC_FP32_Vector3 * transformed_point);
extern inline void bgc_affine3_transform_vector_fp64(const BgcAffine3FP64 * affine, const BgcVector3FP64 * initial_vector, BgcVector3FP64 * transformed_vector); extern inline void bgc_fp64_affine3_transform_point(const BGC_FP64_Affine3 * affine, const BGC_FP64_Vector3 * initial_point, BGC_FP64_Vector3 * transformed_point);
extern inline void bgc_fp32_affine3_transform_vector(const BGC_FP32_Affine3 * affine, const BGC_FP32_Vector3 * initial_vector, BGC_FP32_Vector3 * transformed_vector);
extern inline void bgc_fp64_affine3_transform_vector(const BGC_FP64_Affine3 * affine, const BGC_FP64_Vector3 * initial_vector, BGC_FP64_Vector3 * transformed_vector);

150
basic-geometry/affine3.h
View file

@ -8,167 +8,181 @@
// ==================== Types ==================== // // ==================== Types ==================== //
typedef struct { typedef struct {
BgcMatrix3x3FP32 distortion; BGC_FP32_Matrix3x3 distortion;
BgcVector3FP32 shift; BGC_FP32_Vector3 shift;
} BgcAffine3FP32; } BGC_FP32_Affine3;
typedef struct { typedef struct {
BgcMatrix3x3FP64 distortion; BGC_FP64_Matrix3x3 distortion;
BgcVector3FP64 shift; BGC_FP64_Vector3 shift;
} BgcAffine3FP64; } BGC_FP64_Affine3;
// ==================== Reset ==================== // // ==================== Reset ==================== //
inline void bgc_affine3_reset_fp32(BgcAffine3FP32 * affine) inline void bgc_fp32_affine3_reset(BGC_FP32_Affine3 * affine)
{ {
bgc_matrix3x3_set_to_identity_fp32(&affine->distortion); bgc_fp32_matrix3x3_make_identity(&affine->distortion);
bgc_vector3_reset_fp32(&affine->shift); bgc_fp32_vector3_reset(&affine->shift);
} }
inline void bgc_affine3_reset_fp64(BgcAffine3FP64 * affine) inline void bgc_fp64_affine3_reset(BGC_FP64_Affine3 * affine)
{ {
bgc_matrix3x3_set_to_identity_fp64(&affine->distortion); bgc_fp64_matrix3x3_make_identity(&affine->distortion);
bgc_vector3_reset_fp64(&affine->shift); bgc_fp64_vector3_reset(&affine->shift);
} }
// ==================== Make ===================== // // ==================== Make ===================== //
inline void bgc_affine3_make_fp32(const BgcMatrix3x3FP32 * distortion, const BgcVector3FP32 * shift, BgcAffine3FP32 * affine) inline void bgc_fp32_affine3_make(const BGC_FP32_Matrix3x3 * distortion, const BGC_FP32_Vector3 * shift, BGC_FP32_Affine3 * affine)
{ {
bgc_matrix3x3_copy_fp32(distortion, &affine->distortion); bgc_fp32_matrix3x3_copy(distortion, &affine->distortion);
bgc_vector3_copy_fp32(shift, &affine->shift); bgc_fp32_vector3_copy(shift, &affine->shift);
} }
inline void bgc_affine3_make_fp64(const BgcMatrix3x3FP64 * distortion, const BgcVector3FP64 * shift, BgcAffine3FP64 * affine) inline void bgc_fp64_affine3_make(const BGC_FP64_Matrix3x3 * distortion, const BGC_FP64_Vector3 * shift, BGC_FP64_Affine3 * affine)
{ {
bgc_matrix3x3_copy_fp64(distortion, &affine->distortion); bgc_fp64_matrix3x3_copy(distortion, &affine->distortion);
bgc_vector3_copy_fp64(shift, &affine->shift); bgc_fp64_vector3_copy(shift, &affine->shift);
} }
// ==================== Copy ===================== // // ==================== Copy ===================== //
inline void bgc_affine3_copy_fp32(const BgcAffine3FP32 * source, BgcAffine3FP32 * destination) inline void bgc_fp32_affine3_copy(const BGC_FP32_Affine3 * source, BGC_FP32_Affine3 * destination)
{ {
bgc_matrix3x3_copy_fp32(&source->distortion, &destination->distortion); bgc_fp32_matrix3x3_copy(&source->distortion, &destination->distortion);
bgc_vector3_copy_fp32(&source->shift, &destination->shift); bgc_fp32_vector3_copy(&source->shift, &destination->shift);
} }
inline void bgc_affine3_copy_fp64(const BgcAffine3FP64 * source, BgcAffine3FP64 * destination) inline void bgc_fp64_affine3_copy(const BGC_FP64_Affine3 * source, BGC_FP64_Affine3 * destination)
{ {
bgc_matrix3x3_copy_fp64(&source->distortion, &destination->distortion); bgc_fp64_matrix3x3_copy(&source->distortion, &destination->distortion);
bgc_vector3_copy_fp64(&source->shift, &destination->shift); bgc_fp64_vector3_copy(&source->shift, &destination->shift);
}
// ==================== Swap ===================== //
inline void bgc_fp32_affine3_swap(BGC_FP32_Affine3 * first, BGC_FP32_Affine3 * second)
{
bgc_fp32_matrix3x3_copy(&first->distortion, &second->distortion);
bgc_fp32_vector3_copy(&first->shift, &second->shift);
}
inline void bgc_fp64_affine3_swap(BGC_FP64_Affine3 * first, BGC_FP64_Affine3 * second)
{
bgc_fp64_matrix3x3_copy(&first->distortion, &second->distortion);
bgc_fp64_vector3_copy(&first->shift, &second->shift);
} }
// =================== Convert =================== // // =================== Convert =================== //
inline void bgc_affine3_convert_fp64_to_fp32(const BgcAffine3FP64 * source, BgcAffine3FP32 * destination) inline void bgc_fp64_affine3_convert_to_fp32(const BGC_FP64_Affine3 * source, BGC_FP32_Affine3 * destination)
{ {
bgc_matrix3x3_convert_fp64_to_fp32(&source->distortion, &destination->distortion); bgc_fp64_matrix3x3_convert_to_fp32(&source->distortion, &destination->distortion);
bgc_vector3_convert_fp64_to_fp32(&source->shift, &destination->shift); bgc_fp64_vector3_convert_to_fp32(&source->shift, &destination->shift);
} }
inline void bgc_affine3_convert_fp32_to_fp64(const BgcAffine3FP32 * source, BgcAffine3FP64 * destination) inline void bgc_fp32_affine3_convert_to_fp64(const BGC_FP32_Affine3 * source, BGC_FP64_Affine3 * destination)
{ {
bgc_matrix3x3_convert_fp32_to_fp64(&source->distortion, &destination->distortion); bgc_fp32_matrix3x3_convert_to_fp64(&source->distortion, &destination->distortion);
bgc_vector3_convert_fp32_to_fp64(&source->shift, &destination->shift); bgc_fp32_vector3_convert_to_fp64(&source->shift, &destination->shift);
} }
// =================== Invert ==================== // // =================== Invert ==================== //
inline int bgc_affine3_invert_fp32(BgcAffine3FP32 * affine) inline int bgc_fp32_affine3_invert(BGC_FP32_Affine3 * affine)
{ {
if (!bgc_matrix3x3_invert_fp32(&affine->distortion, &affine->distortion)) { if (!bgc_fp32_matrix3x3_invert(&affine->distortion)) {
return 0; return 0;
} }
bgc_matrix3x3_get_right_product_fp32(&affine->distortion, &affine->shift, &affine->shift); bgc_fp32_multiply_matrix3x3_by_vector3(&affine->distortion, &affine->shift, &affine->shift);
bgc_vector3_make_opposite_fp32(&affine->shift); bgc_fp32_vector3_revert(&affine->shift);
return 1; return 1;
} }
inline int bgc_affine3_invert_fp64(BgcAffine3FP64 * affine) inline int bgc_fp64_affine3_invert(BGC_FP64_Affine3 * affine)
{ {
if (!bgc_matrix3x3_invert_fp64(&affine->distortion, &affine->distortion)) { if (!bgc_fp64_matrix3x3_invert(&affine->distortion)) {
return 0; return 0;
} }
bgc_matrix3x3_get_right_product_fp64(&affine->distortion, &affine->shift, &affine->shift); bgc_fp64_multiply_matrix3x3_by_vector3(&affine->distortion, &affine->shift, &affine->shift);
bgc_vector3_make_opposite_fp64(&affine->shift); bgc_fp64_vector3_revert(&affine->shift);
return 1; return 1;
} }
// ================= Get Inverse ================= // // ================= Get Inverse ================= //
inline int bgc_affine3_get_inverse_fp32(const BgcAffine3FP32 * source, BgcAffine3FP32 * destination) inline int bgc_fp32_affine3_get_inverse(const BGC_FP32_Affine3 * source, BGC_FP32_Affine3 * destination)
{ {
if (!bgc_matrix3x3_invert_fp32(&source->distortion, &destination->distortion)) { if (!bgc_fp32_matrix3x3_get_inverse(&source->distortion, &destination->distortion)) {
return 0; return 0;
} }
bgc_matrix3x3_get_right_product_fp32(&destination->distortion, &source->shift, &destination->shift); bgc_fp32_multiply_matrix3x3_by_vector3(&destination->distortion, &source->shift, &destination->shift);
bgc_vector3_make_opposite_fp32(&destination->shift); bgc_fp32_vector3_revert(&destination->shift);
return 1; return 1;
} }
inline int bgc_affine3_get_inverse_fp64(const BgcAffine3FP64 * source, BgcAffine3FP64 * destination) inline int bgc_fp64_affine3_get_inverse(const BGC_FP64_Affine3 * source, BGC_FP64_Affine3 * destination)
{ {
if (!bgc_matrix3x3_invert_fp64(&source->distortion, &destination->distortion)) { if (!bgc_fp64_matrix3x3_get_inverse(&source->distortion, &destination->distortion)) {
return 0; return 0;
} }
bgc_matrix3x3_get_right_product_fp64(&destination->distortion, &source->shift, &destination->shift); bgc_fp64_multiply_matrix3x3_by_vector3(&destination->distortion, &source->shift, &destination->shift);
bgc_vector3_make_opposite_fp64(&destination->shift); bgc_fp64_vector3_revert(&destination->shift);
return 1; return 1;
} }
// =================== Combine =================== // // =================== Combine =================== //
inline void bgc_affine3_combine_fp32(const BgcAffine3FP32 * first, const BgcAffine3FP32 * second, BgcAffine3FP32 * combination) inline void bgc_fp32_affine3_combine(const BGC_FP32_Affine3 * first, const BGC_FP32_Affine3 * second, BGC_FP32_Affine3 * combination)
{ {
BgcVector3FP32 first_shift; BGC_FP32_Vector3 first_shift;
bgc_matrix3x3_get_right_product_fp32(&second->distortion, &first->shift, &first_shift); bgc_fp32_multiply_matrix3x3_by_vector3(&second->distortion, &first->shift, &first_shift);
bgc_matrix_product_3x3_at_3x3_fp32(&second->distortion, &first->distortion, &combination->distortion); bgc_fp32_multiply_matrix3x3_by_matrix3x3(&second->distortion, &first->distortion, &combination->distortion);
bgc_vector3_add_fp32(&first_shift, &second->shift, &combination->shift); bgc_fp32_vector3_add(&first_shift, &second->shift, &combination->shift);
} }
inline void bgc_affine3_combine_fp64(const BgcAffine3FP64 * first, const BgcAffine3FP64 * second, BgcAffine3FP64 * combination) inline void bgc_fp64_affine3_combine(const BGC_FP64_Affine3 * first, const BGC_FP64_Affine3 * second, BGC_FP64_Affine3 * combination)
{ {
BgcVector3FP64 first_shift; BGC_FP64_Vector3 first_shift;
bgc_matrix3x3_get_right_product_fp64(&second->distortion, &first->shift, &first_shift); bgc_fp64_multiply_matrix3x3_by_vector3(&second->distortion, &first->shift, &first_shift);
bgc_matrix_product_3x3_at_3x3_fp64(&second->distortion, &first->distortion, &combination->distortion); bgc_fp64_multiply_matrix3x3_by_matrix3x3(&second->distortion, &first->distortion, &combination->distortion);
bgc_vector3_add_fp64(&first_shift, &second->shift, &combination->shift); bgc_fp64_vector3_add(&first_shift, &second->shift, &combination->shift);
} }
// =============== Transform Point =============== // // =============== Transform Point =============== //
inline void bgc_affine3_transform_point_fp32(const BgcAffine3FP32 * affine, const BgcVector3FP32 * initial_point, BgcVector3FP32 * transformed_point) inline void bgc_fp32_affine3_transform_point(const BGC_FP32_Affine3 * affine, const BGC_FP32_Vector3 * initial_point, BGC_FP32_Vector3 * transformed_point)
{ {
BgcVector3FP32 distorted; BGC_FP32_Vector3 distorted;
bgc_matrix3x3_get_right_product_fp32(&affine->distortion, initial_point, &distorted); bgc_fp32_multiply_matrix3x3_by_vector3(&affine->distortion, initial_point, &distorted);
bgc_vector3_add_fp32(&affine->shift, &distorted, transformed_point); bgc_fp32_vector3_add(&affine->shift, &distorted, transformed_point);
} }
inline void bgc_affine3_transform_point_fp64(const BgcAffine3FP64 * affine, const BgcVector3FP64 * initial_point, BgcVector3FP64 * transformed_point) inline void bgc_fp64_affine3_transform_point(const BGC_FP64_Affine3 * affine, const BGC_FP64_Vector3 * initial_point, BGC_FP64_Vector3 * transformed_point)
{ {
BgcVector3FP64 distorted; BGC_FP64_Vector3 distorted;
bgc_matrix3x3_get_right_product_fp64(&affine->distortion, initial_point, &distorted); bgc_fp64_multiply_matrix3x3_by_vector3(&affine->distortion, initial_point, &distorted);
bgc_vector3_add_fp64(&affine->shift, &distorted, transformed_point); bgc_fp64_vector3_add(&affine->shift, &distorted, transformed_point);
} }
// ============== Transform Vector =============== // // ============== Transform Vector =============== //
inline void bgc_affine3_transform_vector_fp32(const BgcAffine3FP32 * affine, const BgcVector3FP32 * initial_vector, BgcVector3FP32 * transformed_vector) inline void bgc_fp32_affine3_transform_vector(const BGC_FP32_Affine3 * affine, const BGC_FP32_Vector3 * initial_vector, BGC_FP32_Vector3 * transformed_vector)
{ {
bgc_matrix3x3_get_right_product_fp32(&affine->distortion, initial_vector, transformed_vector); bgc_fp32_multiply_matrix3x3_by_vector3(&affine->distortion, initial_vector, transformed_vector);
} }
inline void bgc_affine3_transform_vector_fp64(const BgcAffine3FP64 * affine, const BgcVector3FP64 * initial_vector, BgcVector3FP64 * transformed_vector) inline void bgc_fp64_affine3_transform_vector(const BGC_FP64_Affine3 * affine, const BGC_FP64_Vector3 * initial_vector, BGC_FP64_Vector3 * transformed_vector)
{ {
bgc_matrix3x3_get_right_product_fp64(&affine->distortion, initial_vector, transformed_vector); bgc_fp64_multiply_matrix3x3_by_vector3(&affine->distortion, initial_vector, transformed_vector);
} }
#endif #endif

74
basic-geometry/angle.c
View file

@ -3,65 +3,59 @@
// !================= Radians ==================! // // !================= Radians ==================! //
extern inline float bgc_radians_to_degrees_fp32(const float radians); extern inline float bgc_fp32_radians_to_degrees(const float radians);
extern inline double bgc_radians_to_degrees_fp64(const double radians); extern inline double bgc_fp64_radians_to_degrees(const double radians);
extern inline float bgc_radians_to_turns_fp32(const float radians); extern inline float bgc_fp32_radians_to_turns(const float radians);
extern inline double bgc_radians_to_turns_fp64(const double radians); extern inline double bgc_fp64_radians_to_turns(const double radians);
extern inline float bgc_radians_to_units_fp32(const float radians, const BgcAngleUnitEnum to_unit); extern inline float bgc_fp32_radians_to_units(const float radians, const int angle_unit);
extern inline double bgc_radians_to_units_fp64(const double radians, const BgcAngleUnitEnum to_unit); extern inline double bgc_fp64_radians_to_units(const double radians, const int angle_unit);
extern inline float bgc_radians_normalize_fp32(const float radians, const BgcAngleRangeEnum range); extern inline float bgc_fp32_normalize_radians(const float radians, const int angle_range);
extern inline double bgc_radians_normalize_fp64(const double radians, const BgcAngleRangeEnum range); extern inline double bgc_fp64_normalize_radians(const double radians, const int angle_range);
// !================= Degrees ==================! // // !================= Degrees ==================! //
extern inline float bgc_degrees_to_radians_fp32(const float degrees); extern inline float bgc_fp32_degrees_to_radians(const float degrees);
extern inline double bgc_degrees_to_radians_fp64(const double degrees); extern inline double bgc_fp64_degrees_to_radians(const double degrees);
extern inline float bgc_degrees_to_turns_fp32(const float radians); extern inline float bgc_fp32_degrees_to_turns(const float radians);
extern inline double bgc_degrees_to_turns_fp64(const double radians); extern inline double bgc_fp64_degrees_to_turns(const double radians);
extern inline float bgc_degrees_to_units_fp32(const float degrees, const BgcAngleUnitEnum to_unit); extern inline float bgc_fp32_degrees_to_units(const float degrees, const int angle_unit);
extern inline double bgc_degrees_to_units_fp64(const double degrees, const BgcAngleUnitEnum to_unit); extern inline double bgc_fp64_degrees_to_units(const double degrees, const int angle_unit);
extern inline float bgc_degrees_normalize_fp32(const float degrees, const BgcAngleRangeEnum range); extern inline float bgc_fp32_normalize_degrees(const float degrees, const int angle_range);
extern inline double bgc_degrees_normalize_fp64(const double degrees, const BgcAngleRangeEnum range); extern inline double bgc_fp64_degrees_normalize(const double degrees, const int angle_range);
// !================== Turns ===================! // // !================== Turns ===================! //
extern inline float bgc_turns_to_radians_fp32(const float turns); extern inline float bgc_fp32_turns_to_radians(const float turns);
extern inline double bgc_turns_to_radians_fp64(const double turns); extern inline double bgc_fp64_turns_to_radians(const double turns);
extern inline float bgc_turns_to_degrees_fp32(const float turns); extern inline float bgc_fp32_turns_to_degrees(const float turns);
extern inline double bgc_turns_to_degrees_fp64(const double turns); extern inline double bgc_fp64_turns_to_degrees(const double turns);
extern inline float bgc_turns_to_units_fp32(const float turns, const BgcAngleUnitEnum to_unit); extern inline float bgc_fp32_turns_to_units(const float turns, const int angle_unit);
extern inline double bgc_turns_to_units_fp64(const double turns, const BgcAngleUnitEnum to_unit); extern inline double bgc_fp64_turns_to_units(const double turns, const int angle_unit);
extern inline float bgc_turns_normalize_fp32(const float turns, const BgcAngleRangeEnum range); extern inline float bgc_fp32_normalize_turns(const float turns, const int angle_range);
extern inline double bgc_turns_normalize_fp64(const double turns, const BgcAngleRangeEnum range); extern inline double bgc_fp64_normalize_turns(const double turns, const int angle_range);
// !================== Angle ===================! // // !================== Angle ===================! //
extern inline float bgc_angle_to_radians_fp32(const float angle, const BgcAngleUnitEnum unit); extern inline float bgc_fp32_angle_to_radians(const float angle, const int angle_unit);
extern inline double bgc_angle_to_radians_fp64(const double angle, const BgcAngleUnitEnum unit); extern inline double bgc_fp64_angle_to_radians(const double angle, const int angle_unit);
extern inline float bgc_angle_to_degrees_fp32(const float angle, const BgcAngleUnitEnum unit); extern inline float bgc_fp32_angle_to_degrees(const float angle, const int angle_unit);
extern inline double bgc_angle_to_degrees_fp64(const double angle, const BgcAngleUnitEnum unit); extern inline double bgc_fp64_angle_to_degrees(const double angle, const int angle_unit);
extern inline float bgc_angle_to_turns_fp32(const float angle, const BgcAngleUnitEnum unit); extern inline float bgc_fp32_angle_to_turns(const float angle, const int angle_unit);
extern inline double bgc_angle_to_turns_fp64(const double angle, const BgcAngleUnitEnum unit); extern inline double bgc_fp64_angle_to_turns(const double angle, const int angle_unit);
extern inline float bgc_angle_get_full_circle_fp32(const BgcAngleUnitEnum unit); extern inline float bgc_fp32_full_circle(const int angle_unit);
extern inline double bgc_angle_get_full_circle_fp64(const BgcAngleUnitEnum unit); extern inline double bgc_fp64_full_circle(const int angle_unit);
extern inline float bgc_angle_get_half_circle_fp32(const BgcAngleUnitEnum unit); extern inline float bgc_fp32_normalize_angle(const float angle, const int angle_unit, const int angle_range);
extern inline double bgc_angle_get_half_circle_fp64(const BgcAngleUnitEnum unit); extern inline double bgc_fp64_normalize_angle(const double angle, const int angle_unit, const int angle_range);
extern inline float bgc_angle_get_quater_circle_fp32(const BgcAngleUnitEnum unit);
extern inline double bgc_angle_get_quater_circle_fp64(const BgcAngleUnitEnum unit);
extern inline float bgc_angle_normalize_fp32(const float angle, const BgcAngleUnitEnum unit, const BgcAngleRangeEnum range);
extern inline double bgc_angle_normalize_fp64(const double angle, const BgcAngleUnitEnum unit, const BgcAngleRangeEnum range);

364
basic-geometry/angle.h
View file

@ -4,99 +4,95 @@
#include <math.h> #include <math.h>
#include "utilities.h" #include "utilities.h"
#define BGC_PI_FP32 3.1415926536f #define BGC_FP32_PI 3.1415926536f
#define BGC_TWO_PI_FP32 6.2831853072f #define BGC_FP32_TWO_PI 6.2831853072f
#define BGC_HALF_OF_PI_FP32 1.5707963268f #define BGC_FP32_HALF_OF_PI 1.5707963268f
#define BGC_THIRD_OF_PI_FP32 1.0471975512f #define BGC_FP32_ONE_THIRD_OF_PI 1.0471975512f
#define BGC_FOURTH_OF_PI_FP32 0.7853981634f #define BGC_FP32_ONE_FOURTH_OF_PI 0.7853981634f
#define BGC_SIXTH_OF_PI_FP32 0.5235987756f #define BGC_FP32_ONE_SIXTH_OF_PI 0.5235987756f
#define BGC_DEGREES_IN_RADIAN_FP32 57.295779513f #define BGC_FP32_DEGREES_IN_RADIAN 57.295779513f
#define BGC_TURNS_IN_RADIAN_FP32 0.1591549431f #define BGC_FP32_TURNS_IN_RADIAN 0.1591549431f
#define BGC_RADIANS_IN_DEGREE_FP32 1.745329252E-2f #define BGC_FP32_RADIANS_IN_DEGREE 1.745329252E-2f
#define BGC_TURNS_IN_DEGREE_FP32 2.7777777778E-3f #define BGC_FP32_TURNS_IN_DEGREE 2.7777777778E-3f
#define BGC_PI_FP64 3.14159265358979324 #define BGC_FP64_PI 3.14159265358979324
#define BGC_TWO_PI_FP64 6.28318530717958648 #define BGC_FP64_TWO_PI 6.28318530717958648
#define BGC_HALF_OF_PI_FP64 1.57079632679489662 #define BGC_FP64_HALF_OF_PI 1.57079632679489662
#define BGC_THIRD_OF_PI_FP64 1.04719755119659775 #define BGC_FP64_ONE_THIRD_OF_PI 1.04719755119659775
#define BGC_FOURTH_OF_PI_FP64 0.78539816339744831 #define BGC_FP64_ONE_FOURTH_OF_PI 0.78539816339744831
#define BGC_SIXTH_OF_PI_FP64 0.523598775598298873 #define BGC_FP64_ONE_SIXTH_OF_PI 0.523598775598298873
#define BGC_DEGREES_IN_RADIAN_FP64 57.2957795130823209 #define BGC_FP64_DEGREES_IN_RADIAN 57.2957795130823209
#define BGC_TURNS_IN_RADIAN_FP64 0.159154943091895336 #define BGC_FP64_TURNS_IN_RADIAN 0.159154943091895336
#define BGC_RADIANS_IN_DEGREE_FP64 1.74532925199432958E-2 #define BGC_FP64_RADIANS_IN_DEGREE 1.74532925199432958E-2
#define BGC_TURNS_IN_DEGREE_FP64 2.77777777777777778E-3 #define BGC_FP64_TURNS_IN_DEGREE 2.77777777777777778E-3
typedef enum { #define BGC_ANGLE_UNIT_RADIANS 1
BGC_ANGLE_UNIT_RADIANS = 1, #define BGC_ANGLE_UNIT_DEGREES 2
BGC_ANGLE_UNIT_DEGREES = 2, #define BGC_ANGLE_UNIT_TURNS 3
BGC_ANGLE_UNIT_TURNS = 3
} BgcAngleUnitEnum;
typedef enum {
/** /**
* The measure of an angle with a range of: * The measure of an angle with a range of:
* [0, 360) degrees, [0, 2xPI) radians, [0, 1) turns, [0, 400) gradians * [0, 360) degrees, [0, 2xPI) radians, [0, 1) turns, [0, 400) gradians
*/ */
BGC_ANGLE_RANGE_UNSIGNED = 1, #define BGC_ANGLE_RANGE_UNSIGNED 1
/** /**
* The measure of an angle with a range of: * The measure of an angle with a range of:
* (-180, 180] degrees, (-PI, PI] radians, (-0.5, 0.5] turns, (-200, 200] gradians * (-180, 180] degrees, (-PI, PI] radians, (-0.5, 0.5] turns, (-200, 200] gradians
*/ */
BGC_ANGLE_RANGE_SIGNED = 2 #define BGC_ANGLE_RANGE_SIGNED 2
} BgcAngleRangeEnum;
// !================= Radians ==================! // // !================= Radians ==================! //
// ========= Convert radians to degrees ========= // // ========= Convert radians to degrees ========= //
inline float bgc_radians_to_degrees_fp32(const float radians) inline float bgc_fp32_radians_to_degrees(const float radians)
{ {
return radians * BGC_DEGREES_IN_RADIAN_FP32; return radians * BGC_FP32_DEGREES_IN_RADIAN;
} }
inline double bgc_radians_to_degrees_fp64(const double radians) inline double bgc_fp64_radians_to_degrees(const double radians)
{ {
return radians * BGC_DEGREES_IN_RADIAN_FP64; return radians * BGC_FP64_DEGREES_IN_RADIAN;
} }
// ========== Convert radians to turns ========== // // ========== Convert radians to turns ========== //
inline float bgc_radians_to_turns_fp32(const float radians) inline float bgc_fp32_radians_to_turns(const float radians)
{ {
return radians * BGC_TURNS_IN_RADIAN_FP32; return radians * BGC_FP32_TURNS_IN_RADIAN;
} }
inline double bgc_radians_to_turns_fp64(const double radians) inline double bgc_fp64_radians_to_turns(const double radians)
{ {
return radians * BGC_TURNS_IN_RADIAN_FP64; return radians * BGC_FP64_TURNS_IN_RADIAN;
} }
// ========= Convert radians to any unit ======== // // ========= Convert radians to any unit ======== //
inline float bgc_radians_to_units_fp32(const float radians, const BgcAngleUnitEnum to_unit) inline float bgc_fp32_radians_to_units(const float radians, const int angle_unit)
{ {
if (to_unit == BGC_ANGLE_UNIT_DEGREES) { if (angle_unit == BGC_ANGLE_UNIT_DEGREES) {
return radians * BGC_DEGREES_IN_RADIAN_FP32; return radians * BGC_FP32_DEGREES_IN_RADIAN;
} }
if (to_unit == BGC_ANGLE_UNIT_TURNS) { if (angle_unit == BGC_ANGLE_UNIT_TURNS) {
return radians * BGC_TURNS_IN_RADIAN_FP32; return radians * BGC_FP32_TURNS_IN_RADIAN;
} }
return radians; return radians;
} }
inline double bgc_radians_to_units_fp64(const double radians, const BgcAngleUnitEnum to_unit) inline double bgc_fp64_radians_to_units(const double radians, const int angle_unit)
{ {
if (to_unit == BGC_ANGLE_UNIT_DEGREES) { if (angle_unit == BGC_ANGLE_UNIT_DEGREES) {
return radians * BGC_DEGREES_IN_RADIAN_FP64; return radians * BGC_FP64_DEGREES_IN_RADIAN;
} }
if (to_unit == BGC_ANGLE_UNIT_TURNS) { if (angle_unit == BGC_ANGLE_UNIT_TURNS) {
return radians * BGC_TURNS_IN_RADIAN_FP64; return radians * BGC_FP64_TURNS_IN_RADIAN;
} }
return radians; return radians;
@ -104,103 +100,103 @@ inline double bgc_radians_to_units_fp64(const double radians, const BgcAngleUnit
// ============ Normalize radians ============= // // ============ Normalize radians ============= //
inline float bgc_radians_normalize_fp32(const float radians, const BgcAngleRangeEnum range) inline float bgc_fp32_normalize_radians(const float radians, const int angle_range)
{ {
if (range == BGC_ANGLE_RANGE_UNSIGNED) { if (angle_range == BGC_ANGLE_RANGE_UNSIGNED) {
if (0.0f <= radians && radians < BGC_TWO_PI_FP32) { if (0.0f <= radians && radians < BGC_FP32_TWO_PI) {
return radians; return radians;
} }
} }
else { else {
if (-BGC_PI_FP32 < radians && radians <= BGC_PI_FP32) { if (-BGC_FP32_PI < radians && radians <= BGC_FP32_PI) {
return radians; return radians;
} }
} }
float turns = radians * BGC_TURNS_IN_RADIAN_FP32; float turns = radians * BGC_FP32_TURNS_IN_RADIAN;
turns -= floorf(turns); turns -= floorf(turns);
if (range == BGC_ANGLE_RANGE_SIGNED && turns > 0.5f) { if (angle_range == BGC_ANGLE_RANGE_SIGNED && turns > 0.5f) {
turns -= 1.0f; turns -= 1.0f;
} }
return turns * BGC_TWO_PI_FP32; return turns * BGC_FP32_TWO_PI;
} }
inline double bgc_radians_normalize_fp64(const double radians, const BgcAngleRangeEnum range) inline double bgc_fp64_normalize_radians(const double radians, const int angle_range)
{ {
if (range == BGC_ANGLE_RANGE_UNSIGNED) { if (angle_range == BGC_ANGLE_RANGE_UNSIGNED) {
if (0.0 <= radians && radians < BGC_TWO_PI_FP64) { if (0.0 <= radians && radians < BGC_FP64_TWO_PI) {
return radians; return radians;
} }
} }
else { else {
if (-BGC_PI_FP64 < radians && radians <= BGC_PI_FP64) { if (-BGC_FP64_PI < radians && radians <= BGC_FP64_PI) {
return radians; return radians;
} }
} }
double turns = radians * BGC_TURNS_IN_RADIAN_FP64; double turns = radians * BGC_FP64_TURNS_IN_RADIAN;
turns -= floor(turns); turns -= floor(turns);
if (range == BGC_ANGLE_RANGE_SIGNED && turns > 0.5) { if (angle_range == BGC_ANGLE_RANGE_SIGNED && turns > 0.5) {
turns -= 1.0; turns -= 1.0;
} }
return turns * BGC_TWO_PI_FP64; return turns * BGC_FP64_TWO_PI;
} }
// !================= Degrees ==================! // // !================= Degrees ==================! //
// ========= Convert degrees to radians ========= // // ========= Convert degrees to radians ========= //
inline float bgc_degrees_to_radians_fp32(const float degrees) inline float bgc_fp32_degrees_to_radians(const float degrees)
{ {
return degrees * BGC_RADIANS_IN_DEGREE_FP32; return degrees * BGC_FP32_RADIANS_IN_DEGREE;
} }
inline double bgc_degrees_to_radians_fp64(const double degrees) inline double bgc_fp64_degrees_to_radians(const double degrees)
{ {
return degrees * BGC_RADIANS_IN_DEGREE_FP64; return degrees * BGC_FP64_RADIANS_IN_DEGREE;
} }
// ========== Convert degrees to turns ========== // // ========== Convert degrees to turns ========== //
inline float bgc_degrees_to_turns_fp32(const float radians) inline float bgc_fp32_degrees_to_turns(const float radians)
{ {
return radians * BGC_TURNS_IN_DEGREE_FP32; return radians * BGC_FP32_TURNS_IN_DEGREE;
} }
inline double bgc_degrees_to_turns_fp64(const double radians) inline double bgc_fp64_degrees_to_turns(const double radians)
{ {
return radians * BGC_TURNS_IN_DEGREE_FP64; return radians * BGC_FP64_TURNS_IN_DEGREE;
} }
// ========= Convert degreess to any unit ======== // // ========= Convert degreess to any unit ======== //
inline float bgc_degrees_to_units_fp32(const float degrees, const BgcAngleUnitEnum to_unit) inline float bgc_fp32_degrees_to_units(const float degrees, const int angle_unit)
{ {
if (to_unit == BGC_ANGLE_UNIT_RADIANS) { if (angle_unit == BGC_ANGLE_UNIT_RADIANS) {
return degrees * BGC_RADIANS_IN_DEGREE_FP32; return degrees * BGC_FP32_RADIANS_IN_DEGREE;
} }
if (to_unit == BGC_ANGLE_UNIT_TURNS) { if (angle_unit == BGC_ANGLE_UNIT_TURNS) {
return degrees * BGC_TURNS_IN_DEGREE_FP32; return degrees * BGC_FP32_TURNS_IN_DEGREE;
} }
return degrees; return degrees;
} }
inline double bgc_degrees_to_units_fp64(const double degrees, const BgcAngleUnitEnum to_unit) inline double bgc_fp64_degrees_to_units(const double degrees, const int angle_unit)
{ {
if (to_unit == BGC_ANGLE_UNIT_RADIANS) { if (angle_unit == BGC_ANGLE_UNIT_RADIANS) {
return degrees * BGC_RADIANS_IN_DEGREE_FP64; return degrees * BGC_FP64_RADIANS_IN_DEGREE;
} }
if (to_unit == BGC_ANGLE_UNIT_TURNS) { if (angle_unit == BGC_ANGLE_UNIT_TURNS) {
return degrees * BGC_TURNS_IN_DEGREE_FP64; return degrees * BGC_FP64_TURNS_IN_DEGREE;
} }
return degrees; return degrees;
@ -208,9 +204,9 @@ inline double bgc_degrees_to_units_fp64(const double degrees, const BgcAngleUnit
// ============ Normalize degrees ============= // // ============ Normalize degrees ============= //
inline float bgc_degrees_normalize_fp32(const float degrees, const BgcAngleRangeEnum range) inline float bgc_fp32_normalize_degrees(const float degrees, const int angle_range)
{ {
if (range == BGC_ANGLE_RANGE_UNSIGNED) { if (angle_range == BGC_ANGLE_RANGE_UNSIGNED) {
if (0.0f <= degrees && degrees < 360.0f) { if (0.0f <= degrees && degrees < 360.0f) {
return degrees; return degrees;
} }
@ -221,20 +217,20 @@ inline float bgc_degrees_normalize_fp32(const float degrees, const BgcAngleRange
} }
} }
float turns = degrees * BGC_TURNS_IN_DEGREE_FP32; float turns = degrees * BGC_FP32_TURNS_IN_DEGREE;
turns -= floorf(turns); turns -= floorf(turns);
if (range == BGC_ANGLE_RANGE_SIGNED && turns > 0.5f) { if (angle_range == BGC_ANGLE_RANGE_SIGNED && turns > 0.5f) {
turns -= 1.0f; turns -= 1.0f;
} }
return turns * 360.0f; return turns * 360.0f;
} }
inline double bgc_degrees_normalize_fp64(const double degrees, const BgcAngleRangeEnum range) inline double bgc_fp64_degrees_normalize(const double degrees, const int angle_range)
{ {
if (range == BGC_ANGLE_RANGE_UNSIGNED) { if (angle_range == BGC_ANGLE_RANGE_UNSIGNED) {
if (0.0 <= degrees && degrees < 360.0) { if (0.0 <= degrees && degrees < 360.0) {
return degrees; return degrees;
} }
@ -245,11 +241,11 @@ inline double bgc_degrees_normalize_fp64(const double degrees, const BgcAngleRan
} }
} }
double turns = degrees * BGC_TURNS_IN_DEGREE_FP64; double turns = degrees * BGC_FP64_TURNS_IN_DEGREE;
turns -= floor(turns); turns -= floor(turns);
if (range == BGC_ANGLE_RANGE_SIGNED && turns > 0.5) { if (angle_range == BGC_ANGLE_RANGE_SIGNED && turns > 0.5) {
turns -= 1.0; turns -= 1.0;
} }
@ -260,50 +256,50 @@ inline double bgc_degrees_normalize_fp64(const double degrees, const BgcAngleRan
// ========== Convert turns to radians ========== // // ========== Convert turns to radians ========== //
inline float bgc_turns_to_radians_fp32(const float turns) inline float bgc_fp32_turns_to_radians(const float turns)
{ {
return turns * BGC_TWO_PI_FP32; return turns * BGC_FP32_TWO_PI;
} }
inline double bgc_turns_to_radians_fp64(const double turns) inline double bgc_fp64_turns_to_radians(const double turns)
{ {
return turns * BGC_TWO_PI_FP64; return turns * BGC_FP64_TWO_PI;
} }
// ========== Convert turns to degrees ========== // // ========== Convert turns to degrees ========== //
inline float bgc_turns_to_degrees_fp32(const float turns) inline float bgc_fp32_turns_to_degrees(const float turns)
{ {
return turns * 360.0f; return turns * 360.0f;
} }
inline double bgc_turns_to_degrees_fp64(const double turns) inline double bgc_fp64_turns_to_degrees(const double turns)
{ {
return turns * 360.0; return turns * 360.0;
} }
// ========= Convert turns to any unit ======== // // ========= Convert turns to any unit ======== //
inline float bgc_turns_to_units_fp32(const float turns, const BgcAngleUnitEnum to_unit) inline float bgc_fp32_turns_to_units(const float turns, const int angle_unit)
{ {
if (to_unit == BGC_ANGLE_UNIT_RADIANS) { if (angle_unit == BGC_ANGLE_UNIT_RADIANS) {
return turns * BGC_TWO_PI_FP32; return turns * BGC_FP32_TWO_PI;
} }
if (to_unit == BGC_ANGLE_UNIT_DEGREES) { if (angle_unit == BGC_ANGLE_UNIT_DEGREES) {
return turns * 360.0f; return turns * 360.0f;
} }
return turns; return turns;
} }
inline double bgc_turns_to_units_fp64(const double turns, const BgcAngleUnitEnum to_unit) inline double bgc_fp64_turns_to_units(const double turns, const int angle_unit)
{ {
if (to_unit == BGC_ANGLE_UNIT_RADIANS) { if (angle_unit == BGC_ANGLE_UNIT_RADIANS) {
return turns * BGC_TWO_PI_FP64; return turns * BGC_FP64_TWO_PI;
} }
if (to_unit == BGC_ANGLE_UNIT_DEGREES) { if (angle_unit == BGC_ANGLE_UNIT_DEGREES) {
return turns * 360.0; return turns * 360.0;
} }
@ -312,9 +308,9 @@ inline double bgc_turns_to_units_fp64(const double turns, const BgcAngleUnitEnum
// ============= Normalize turns ============== // // ============= Normalize turns ============== //
inline float bgc_turns_normalize_fp32(const float turns, const BgcAngleRangeEnum range) inline float bgc_fp32_normalize_turns(const float turns, const int angle_range)
{ {
if (range == BGC_ANGLE_RANGE_UNSIGNED) { if (angle_range == BGC_ANGLE_RANGE_UNSIGNED) {
if (0.0f <= turns && turns < 1.0f) { if (0.0f <= turns && turns < 1.0f) {
return turns; return turns;
} }
@ -327,16 +323,16 @@ inline float bgc_turns_normalize_fp32(const float turns, const BgcAngleRangeEnum
float rest = turns - floorf(turns); float rest = turns - floorf(turns);
if (range == BGC_ANGLE_RANGE_SIGNED && rest > 0.5f) { if (angle_range == BGC_ANGLE_RANGE_SIGNED && rest > 0.5f) {
return rest - 1.0f; return rest - 1.0f;
} }
return rest; return rest;
} }
inline double bgc_turns_normalize_fp64(const double turns, const BgcAngleRangeEnum range) inline double bgc_fp64_normalize_turns(const double turns, const int angle_range)
{ {
if (range == BGC_ANGLE_RANGE_UNSIGNED) { if (angle_range == BGC_ANGLE_RANGE_UNSIGNED) {
if (0.0 <= turns && turns < 1.0) { if (0.0 <= turns && turns < 1.0) {
return turns; return turns;
} }
@ -349,7 +345,7 @@ inline double bgc_turns_normalize_fp64(const double turns, const BgcAngleRangeEn
double rest = turns - floor(turns); double rest = turns - floor(turns);
if (range == BGC_ANGLE_RANGE_SIGNED && rest > 0.5) { if (angle_range == BGC_ANGLE_RANGE_SIGNED && rest > 0.5) {
return rest - 1.0; return rest - 1.0;
} }
@ -360,27 +356,27 @@ inline double bgc_turns_normalize_fp64(const double turns, const BgcAngleRangeEn
// ========= Convert any unit to radians ======== // // ========= Convert any unit to radians ======== //
inline float bgc_angle_to_radians_fp32(const float angle, const BgcAngleUnitEnum unit) inline float bgc_fp32_angle_to_radians(const float angle, const int angle_unit)
{ {
if (unit == BGC_ANGLE_UNIT_DEGREES) { if (angle_unit == BGC_ANGLE_UNIT_DEGREES) {
return angle * BGC_RADIANS_IN_DEGREE_FP32; return angle * BGC_FP32_RADIANS_IN_DEGREE;
} }
if (unit == BGC_ANGLE_UNIT_TURNS) { if (angle_unit == BGC_ANGLE_UNIT_TURNS) {
return angle * BGC_TWO_PI_FP32; return angle * BGC_FP32_TWO_PI;
} }
return angle; return angle;
} }
inline double bgc_angle_to_radians_fp64(const double angle, const BgcAngleUnitEnum unit) inline double bgc_fp64_angle_to_radians(const double angle, const int angle_unit)
{ {
if (unit == BGC_ANGLE_UNIT_DEGREES) { if (angle_unit == BGC_ANGLE_UNIT_DEGREES) {
return angle * BGC_RADIANS_IN_DEGREE_FP64; return angle * BGC_FP64_RADIANS_IN_DEGREE;
} }
if (unit == BGC_ANGLE_UNIT_TURNS) { if (angle_unit == BGC_ANGLE_UNIT_TURNS) {
return angle * BGC_TWO_PI_FP64; return angle * BGC_FP64_TWO_PI;
} }
return angle; return angle;
@ -388,26 +384,26 @@ inline double bgc_angle_to_radians_fp64(const double angle, const BgcAngleUnitEn
// ========= Convert any unit to degreess ======== // // ========= Convert any unit to degreess ======== //
inline float bgc_angle_to_degrees_fp32(const float angle, const BgcAngleUnitEnum unit) inline float bgc_fp32_angle_to_degrees(const float angle, const int angle_unit)
{ {
if (unit == BGC_ANGLE_UNIT_RADIANS) { if (angle_unit == BGC_ANGLE_UNIT_RADIANS) {
return angle * BGC_DEGREES_IN_RADIAN_FP32; return angle * BGC_FP32_DEGREES_IN_RADIAN;
} }
if (unit == BGC_ANGLE_UNIT_TURNS) { if (angle_unit == BGC_ANGLE_UNIT_TURNS) {
return angle * 360.0f; return angle * 360.0f;
} }
return angle; return angle;
} }
inline double bgc_angle_to_degrees_fp64(const double angle, const BgcAngleUnitEnum unit) inline double bgc_fp64_angle_to_degrees(const double angle, const int angle_unit)
{ {
if (unit == BGC_ANGLE_UNIT_RADIANS) { if (angle_unit == BGC_ANGLE_UNIT_RADIANS) {
return angle * BGC_DEGREES_IN_RADIAN_FP64; return angle * BGC_FP64_DEGREES_IN_RADIAN;
} }
if (unit == BGC_ANGLE_UNIT_TURNS) { if (angle_unit == BGC_ANGLE_UNIT_TURNS) {
return angle * 360.0; return angle * 360.0;
} }
@ -416,27 +412,27 @@ inline double bgc_angle_to_degrees_fp64(const double angle, const BgcAngleUnitEn
// ========= Convert any unit to turns ======== // // ========= Convert any unit to turns ======== //
inline float bgc_angle_to_turns_fp32(const float angle, const BgcAngleUnitEnum unit) inline float bgc_fp32_angle_to_turns(const float angle, const int angle_unit)
{ {
if (unit == BGC_ANGLE_UNIT_RADIANS) { if (angle_unit == BGC_ANGLE_UNIT_RADIANS) {
return angle * BGC_TURNS_IN_RADIAN_FP32; return angle * BGC_FP32_TURNS_IN_RADIAN;
} }
if (unit == BGC_ANGLE_UNIT_DEGREES) { if (angle_unit == BGC_ANGLE_UNIT_DEGREES) {
return angle * BGC_TURNS_IN_DEGREE_FP32; return angle * BGC_FP32_TURNS_IN_DEGREE;
} }
return angle; return angle;
} }
inline double bgc_angle_to_turns_fp64(const double angle, const BgcAngleUnitEnum unit) inline double bgc_fp64_angle_to_turns(const double angle, const int angle_unit)
{ {
if (unit == BGC_ANGLE_UNIT_RADIANS) { if (angle_unit == BGC_ANGLE_UNIT_RADIANS) {
return angle * BGC_TURNS_IN_RADIAN_FP64; return angle * BGC_FP64_TURNS_IN_RADIAN;
} }
if (unit == BGC_ANGLE_UNIT_DEGREES) { if (angle_unit == BGC_ANGLE_UNIT_DEGREES) {
return angle * BGC_TURNS_IN_DEGREE_FP64; return angle * BGC_FP64_TURNS_IN_DEGREE;
} }
return angle; return angle;
@ -444,114 +440,58 @@ inline double bgc_angle_to_turns_fp64(const double angle, const BgcAngleUnitEnum
// ============= Get Full Circle ============== // // ============= Get Full Circle ============== //
inline float bgc_angle_get_full_circle_fp32(const BgcAngleUnitEnum unit) inline float bgc_fp32_full_circle(const int angle_unit)
{ {
if (unit == BGC_ANGLE_UNIT_DEGREES) { if (angle_unit == BGC_ANGLE_UNIT_DEGREES) {
return 360.0f; return 360.0f;
} }
if (unit == BGC_ANGLE_UNIT_TURNS) { if (angle_unit == BGC_ANGLE_UNIT_TURNS) {
return 1.0f; return 1.0f;
} }
return BGC_TWO_PI_FP32; return BGC_FP32_TWO_PI;
} }
inline double bgc_angle_get_full_circle_fp64(const BgcAngleUnitEnum unit) inline double bgc_fp64_full_circle(const int angle_unit)
{ {
if (unit == BGC_ANGLE_UNIT_DEGREES) { if (angle_unit == BGC_ANGLE_UNIT_DEGREES) {
return 360.0; return 360.0;
} }
if (unit == BGC_ANGLE_UNIT_TURNS) { if (angle_unit == BGC_ANGLE_UNIT_TURNS) {
return 1.0; return 1.0;
} }
return BGC_TWO_PI_FP64; return BGC_FP64_TWO_PI;
}
// ============= Get Half Circle ============== //
inline float bgc_angle_get_half_circle_fp32(const BgcAngleUnitEnum unit)
{
if (unit == BGC_ANGLE_UNIT_DEGREES) {
return 180.0f;
}
if (unit == BGC_ANGLE_UNIT_TURNS) {
return 0.5f;
}
return BGC_PI_FP32;
}
inline double bgc_angle_get_half_circle_fp64(const BgcAngleUnitEnum unit)
{
if (unit == BGC_ANGLE_UNIT_DEGREES) {
return 180.0;
}
if (unit == BGC_ANGLE_UNIT_TURNS) {
return 0.5;
}
return BGC_PI_FP64;
}
// ============= Get Half Circle ============== //
inline float bgc_angle_get_quater_circle_fp32(const BgcAngleUnitEnum unit)
{
if (unit == BGC_ANGLE_UNIT_DEGREES) {
return 90.0f;
}
if (unit == BGC_ANGLE_UNIT_TURNS) {
return 0.25f;
}
return BGC_HALF_OF_PI_FP32;
}
inline double bgc_angle_get_quater_circle_fp64(const BgcAngleUnitEnum unit)
{
if (unit == BGC_ANGLE_UNIT_DEGREES) {
return 90.0;
}
if (unit == BGC_ANGLE_UNIT_TURNS) {
return 0.25;
}
return BGC_HALF_OF_PI_FP64;
} }
// ================ Normalize ================= // // ================ Normalize ================= //
inline float bgc_angle_normalize_fp32(const float angle, const BgcAngleUnitEnum unit, const BgcAngleRangeEnum range) inline float bgc_fp32_normalize_angle(const float angle, const int angle_unit, const int angle_range)
{ {
if (unit == BGC_ANGLE_UNIT_DEGREES) { if (angle_unit == BGC_ANGLE_UNIT_DEGREES) {
return bgc_degrees_normalize_fp32(angle, range); return bgc_fp32_normalize_degrees(angle, angle_range);
} }
if (unit == BGC_ANGLE_UNIT_TURNS) { if (angle_unit == BGC_ANGLE_UNIT_TURNS) {
return bgc_turns_normalize_fp32(angle, range); return bgc_fp32_normalize_turns(angle, angle_range);
} }
return bgc_radians_normalize_fp32(angle, range); return bgc_fp32_normalize_radians(angle, angle_range);
} }
inline double bgc_angle_normalize_fp64(const double angle, const BgcAngleUnitEnum unit, const BgcAngleRangeEnum range) inline double bgc_fp64_normalize_angle(const double angle, const int angle_unit, const int angle_range)
{ {
if (unit == BGC_ANGLE_UNIT_DEGREES) { if (angle_unit == BGC_ANGLE_UNIT_DEGREES) {
return bgc_degrees_normalize_fp64(angle, range); return bgc_fp64_degrees_normalize(angle, angle_range);
} }
if (unit == BGC_ANGLE_UNIT_TURNS) { if (angle_unit == BGC_ANGLE_UNIT_TURNS) {
return bgc_turns_normalize_fp64(angle, range); return bgc_fp64_normalize_turns(angle, angle_range);
} }
return bgc_radians_normalize_fp64(angle, range); return bgc_fp64_normalize_radians(angle, angle_range);
} }
#endif #endif

4
basic-geometry/basic-geometry.cbp
View file

@ -100,6 +100,10 @@
<Option compilerVar="CC" /> <Option compilerVar="CC" />
</Unit> </Unit>
<Unit filename="rotation3.h" /> <Unit filename="rotation3.h" />
<Unit filename="slerp.c">
<Option compilerVar="CC" />
</Unit>
<Unit filename="slerp.h" />
<Unit filename="utilities.c"> <Unit filename="utilities.c">
<Option compilerVar="CC" /> <Option compilerVar="CC" />
</Unit> </Unit>

124
basic-geometry/complex.c
View file

@ -1,96 +1,96 @@
#include "./complex.h" #include "./complex.h"
extern inline void bgc_complex_reset_fp32(BgcComplexFP32* complex); extern inline void bgc_fp32_complex_reset(BGC_FP32_Complex* complex);
extern inline void bgc_complex_reset_fp64(BgcComplexFP64* complex); extern inline void bgc_fp64_complex_reset(BGC_FP64_Complex* complex);
extern inline void bgc_complex_set_values_fp32(const float real, const float imaginary, BgcComplexFP32* destination); extern inline void bgc_fp32_complex_make(const float real, const float imaginary, BGC_FP32_Complex* complex);
extern inline void bgc_complex_set_values_fp64(const double real, const double imaginary, BgcComplexFP64* destination); extern inline void bgc_fp64_complex_make(const double real, const double imaginary, BGC_FP64_Complex* complex);
extern inline float bgc_complex_get_square_modulus_fp32(const BgcComplexFP32* number); extern inline float bgc_fp32_complex_get_square_modulus(const BGC_FP32_Complex* number);
extern inline double bgc_complex_get_square_modulus_fp64(const BgcComplexFP64* number); extern inline double bgc_fp64_complex_get_square_modulus(const BGC_FP64_Complex* number);
extern inline float bgc_complex_get_modulus_fp32(const BgcComplexFP32* number); extern inline float bgc_fp32_complex_get_modulus(const BGC_FP32_Complex* number);
extern inline double bgc_complex_get_modulus_fp64(const BgcComplexFP64* number); extern inline double bgc_fp64_complex_get_modulus(const BGC_FP64_Complex* number);
extern inline int bgc_complex_is_zero_fp32(const BgcComplexFP32* number); extern inline int bgc_fp32_complex_is_zero(const BGC_FP32_Complex* number);
extern inline int bgc_complex_is_zero_fp64(const BgcComplexFP64* number); extern inline int bgc_fp64_complex_is_zero(const BGC_FP64_Complex* number);
extern inline int bgc_complex_is_unit_fp32(const BgcComplexFP32* number); extern inline int bgc_fp32_complex_is_unit(const BGC_FP32_Complex* number);
extern inline int bgc_complex_is_unit_fp64(const BgcComplexFP64* number); extern inline int bgc_fp64_complex_is_unit(const BGC_FP64_Complex* number);
extern inline void bgc_complex_copy_fp32(const BgcComplexFP32* source, BgcComplexFP32* destination); extern inline void bgc_fp32_complex_copy(const BGC_FP32_Complex* source, BGC_FP32_Complex* destination);
extern inline void bgc_complex_copy_fp64(const BgcComplexFP64* source, BgcComplexFP64* destination); extern inline void bgc_fp64_complex_copy(const BGC_FP64_Complex* source, BGC_FP64_Complex* destination);
extern inline void bgc_complex_swap_fp32(BgcComplexFP32* number1, BgcComplexFP32* number2); extern inline void bgc_fp32_complex_swap(BGC_FP32_Complex* number1, BGC_FP32_Complex* number2);
extern inline void bgc_complex_swap_fp64(BgcComplexFP64* number1, BgcComplexFP64* number2); extern inline void bgc_fp64_complex_swap(BGC_FP64_Complex* number1, BGC_FP64_Complex* number2);
extern inline void bgc_complex_convert_fp64_to_fp32(const BgcComplexFP64* source, BgcComplexFP32* destination); extern inline void bgc_fp64_complex_convert_to_fp32(const BGC_FP64_Complex* source, BGC_FP32_Complex* destination);
extern inline void bgc_complex_convert_fp32_to_fp64(const BgcComplexFP32* source, BgcComplexFP64* destination); extern inline void bgc_fp32_complex_convert_to_fp64(const BGC_FP32_Complex* source, BGC_FP64_Complex* destination);
extern inline void bgc_complex_make_opposite_fp32(BgcComplexFP32* number); extern inline void bgc_fp32_complex_revert(BGC_FP32_Complex* number);
extern inline void bgc_complex_make_opposite_fp64(BgcComplexFP64* number); extern inline void bgc_fp64_complex_revert(BGC_FP64_Complex* number);
extern inline void bgc_complex_get_opposite_fp32(const BgcComplexFP32* number, BgcComplexFP32* opposite); extern inline void bgc_fp32_complex_get_reverse(const BGC_FP32_Complex* number, BGC_FP32_Complex* opposite);
extern inline void bgc_complex_get_opposite_fp64(const BgcComplexFP64* number, BgcComplexFP64* opposite); extern inline void bgc_fp64_complex_get_reverse(const BGC_FP64_Complex* number, BGC_FP64_Complex* opposite);
extern inline int bgc_complex_normalize_fp32(BgcComplexFP32* number); extern inline int bgc_fp32_complex_normalize(BGC_FP32_Complex* number);
extern inline int bgc_complex_normalize_fp64(BgcComplexFP64* number); extern inline int bgc_fp64_complex_normalize(BGC_FP64_Complex* number);
extern inline int bgc_complex_get_normalized_fp32(const BgcComplexFP32* number, BgcComplexFP32* normalized); extern inline int bgc_fp32_complex_get_normalized(const BGC_FP32_Complex* number, BGC_FP32_Complex* normalized);
extern inline int bgc_complex_get_normalized_fp64(const BgcComplexFP64* number, BgcComplexFP64* normalized); extern inline int bgc_fp64_complex_get_normalized(const BGC_FP64_Complex* number, BGC_FP64_Complex* normalized);
extern inline void bgc_complex_conjugate_fp32(BgcComplexFP32* number); extern inline void bgc_fp32_complex_conjugate(BGC_FP32_Complex* number);
extern inline void bgc_complex_conjugate_fp64(BgcComplexFP64* number); extern inline void bgc_fp64_complex_conjugate(BGC_FP64_Complex* number);
extern inline void bgc_complex_get_conjugate_fp32(const BgcComplexFP32* number, BgcComplexFP32* conjugate); extern inline void bgc_fp32_complex_get_conjugate(const BGC_FP32_Complex* number, BGC_FP32_Complex* conjugate);
extern inline void bgc_complex_get_conjugate_fp64(const BgcComplexFP64* number, BgcComplexFP64* conjugate); extern inline void bgc_fp64_complex_get_conjugate(const BGC_FP64_Complex* number, BGC_FP64_Complex* conjugate);
extern inline int bgc_complex_invert_fp32(BgcComplexFP32* number); extern inline int bgc_fp32_complex_invert(BGC_FP32_Complex* number);
extern inline int bgc_complex_invert_fp64(BgcComplexFP64* number); extern inline int bgc_fp64_complex_invert(BGC_FP64_Complex* number);
extern inline int bgc_complex_get_inverse_fp32(const BgcComplexFP32* number, BgcComplexFP32* inverse); extern inline int bgc_fp32_complex_get_inverse(const BGC_FP32_Complex* number, BGC_FP32_Complex* inverse);
extern inline int bgc_complex_get_inverse_fp64(const BgcComplexFP64* number, BgcComplexFP64* inverse); extern inline int bgc_fp64_complex_get_inverse(const BGC_FP64_Complex* number, BGC_FP64_Complex* inverse);
extern inline void bgc_complex_multiply_fp32(const BgcComplexFP32* number1, const BgcComplexFP32* number2, BgcComplexFP32* result); extern inline void bgc_fp32_complex_get_product(const BGC_FP32_Complex* number1, const BGC_FP32_Complex* number2, BGC_FP32_Complex* product);
extern inline void bgc_complex_multiply_fp64(const BgcComplexFP64* number1, const BgcComplexFP64* number2, BgcComplexFP64* result); extern inline void bgc_fp64_complex_get_product(const BGC_FP64_Complex* number1, const BGC_FP64_Complex* number2, BGC_FP64_Complex* product);
extern inline int bgc_complex_devide_fp32(const BgcComplexFP32* divident, const BgcComplexFP32* divisor, BgcComplexFP32* quotient); extern inline int bgc_fp32_complex_get_ratio(const BGC_FP32_Complex* divident, const BGC_FP32_Complex* divisor, BGC_FP32_Complex* quotient);
extern inline int bgc_complex_devide_fp64(const BgcComplexFP64* divident, const BgcComplexFP64* divisor, BgcComplexFP64* quotient); extern inline int bgc_fp64_complex_get_ratio(const BGC_FP64_Complex* divident, const BGC_FP64_Complex* divisor, BGC_FP64_Complex* quotient);
extern inline void bgc_complex_add_fp32(const BgcComplexFP32* number1, const BgcComplexFP32* number2, BgcComplexFP32* sum); extern inline void bgc_fp32_complex_add(const BGC_FP32_Complex* number1, const BGC_FP32_Complex* number2, BGC_FP32_Complex* sum);
extern inline void bgc_complex_add_fp64(const BgcComplexFP64* number1, const BgcComplexFP64* number2, BgcComplexFP64* sum); extern inline void bgc_fp64_complex_add(const BGC_FP64_Complex* number1, const BGC_FP64_Complex* number2, BGC_FP64_Complex* sum);
extern inline void bgc_complex_add_scaled_fp32(const BgcComplexFP32* basic_number, const BgcComplexFP32* scalable_number, const float scale, BgcComplexFP32* sum); extern inline void bgc_fp32_complex_add_scaled(const BGC_FP32_Complex* basic_number, const BGC_FP32_Complex* scalable_number, const float scale, BGC_FP32_Complex* sum);
extern inline void bgc_complex_add_scaled_fp64(const BgcComplexFP64* basic_number, const BgcComplexFP64* scalable_number, const double scale, BgcComplexFP64* sum); extern inline void bgc_fp64_complex_add_scaled(const BGC_FP64_Complex* basic_number, const BGC_FP64_Complex* scalable_number, const double scale, BGC_FP64_Complex* sum);
extern inline void bgc_complex_subtract_fp32(const BgcComplexFP32* minuend, const BgcComplexFP32* subtrahend, BgcComplexFP32* difference); extern inline void bgc_fp32_complex_subtract(const BGC_FP32_Complex* minuend, const BGC_FP32_Complex* subtrahend, BGC_FP32_Complex* difference);
extern inline void bgc_complex_subtract_fp64(const BgcComplexFP64* minuend, const BgcComplexFP64* subtrahend, BgcComplexFP64* difference); extern inline void bgc_fp64_complex_subtract(const BGC_FP64_Complex* minuend, const BGC_FP64_Complex* subtrahend, BGC_FP64_Complex* difference);
extern inline void bgc_complex_multiply_by_number_fp32(const BgcComplexFP32* multiplicand, const float multiplier, BgcComplexFP32* product); extern inline void bgc_fp32_complex_multiply(const BGC_FP32_Complex* multiplicand, const float multiplier, BGC_FP32_Complex* product);
extern inline void bgc_complex_multiply_by_number_fp64(const BgcComplexFP64* multiplicand, const double multiplier, BgcComplexFP64* product); extern inline void bgc_fp64_complex_multiply(const BGC_FP64_Complex* multiplicand, const double multiplier, BGC_FP64_Complex* product);
extern inline void bgc_complex_divide_by_number_fp32(const BgcComplexFP32* dividend, const float divisor, BgcComplexFP32* quotient); extern inline void bgc_fp32_complex_divide(const BGC_FP32_Complex* dividend, const float divisor, BGC_FP32_Complex* quotient);
extern inline void bgc_complex_divide_by_number_fp64(const BgcComplexFP64* dividend, const double divisor, BgcComplexFP64* quotient); extern inline void bgc_fp64_complex_divide(const BGC_FP64_Complex* dividend, const double divisor, BGC_FP64_Complex* quotient);
extern inline void bgc_complex_get_mean_of_two_fp32(const BgcComplexFP32* number1, const BgcComplexFP32* number2, BgcComplexFP32* mean); extern inline void bgc_fp32_complex_get_mean2(const BGC_FP32_Complex* number1, const BGC_FP32_Complex* number2, BGC_FP32_Complex* mean);
extern inline void bgc_complex_get_mean_of_two_fp64(const BgcComplexFP64* number1, const BgcComplexFP64* number2, BgcComplexFP64* mean); extern inline void bgc_fp64_complex_get_mean2(const BGC_FP64_Complex* number1, const BGC_FP64_Complex* number2, BGC_FP64_Complex* mean);
extern inline void bgc_complex_get_mean_of_three_fp32(const BgcComplexFP32* number1, const BgcComplexFP32* number2, const BgcComplexFP32* number3, BgcComplexFP32* mean); extern inline void bgc_fp32_complex_get_mean3(const BGC_FP32_Complex* number1, const BGC_FP32_Complex* number2, const BGC_FP32_Complex* number3, BGC_FP32_Complex* mean);
extern inline void bgc_complex_get_mean_of_three_fp64(const BgcComplexFP64* number1, const BgcComplexFP64* number2, const BgcComplexFP64* number3, BgcComplexFP64* mean); extern inline void bgc_fp64_complex_get_mean3(const BGC_FP64_Complex* number1, const BGC_FP64_Complex* number2, const BGC_FP64_Complex* number3, BGC_FP64_Complex* mean);
extern inline void bgc_complex_interpolate_fp32(const BgcComplexFP32* number1, const BgcComplexFP32* number2, const float phase, BgcComplexFP32* interpolation); extern inline void bgc_fp32_complex_interpolate(const BGC_FP32_Complex* number1, const BGC_FP32_Complex* number2, const float phase, BGC_FP32_Complex* interpolation);
extern inline void bgc_complex_interpolate_fp64(const BgcComplexFP64* number1, const BgcComplexFP64* number2, const double phase, BgcComplexFP64* interpolation); extern inline void bgc_fp64_complex_interpolate(const BGC_FP64_Complex* number1, const BGC_FP64_Complex* number2, const double phase, BGC_FP64_Complex* interpolation);
extern inline int bgc_complex_are_close_fp32(const BgcComplexFP32* number1, const BgcComplexFP32* number2); extern inline int bgc_fp32_complex_are_close(const BGC_FP32_Complex* number1, const BGC_FP32_Complex* number2);
extern inline int bgc_complex_are_close_fp64(const BgcComplexFP64* number1, const BgcComplexFP64* number2); extern inline int bgc_fp64_complex_are_close(const BGC_FP64_Complex* number1, const BGC_FP64_Complex* number2);
// =============== Get Exponation =============== // // =============== Get Exponation =============== //
void bgc_complex_get_exponation_fp32(const BgcComplexFP32* base, const float real_exponent, const float imaginary_exponent, BgcComplexFP32* power) void bgc_fp32_complex_get_exponation(const BGC_FP32_Complex* base, const float real_exponent, const float imaginary_exponent, BGC_FP32_Complex* power)
{ {
const float square_modulus = bgc_complex_get_square_modulus_fp32(base); const float square_modulus = bgc_fp32_complex_get_square_modulus(base);
if (square_modulus <= BGC_SQUARE_EPSYLON_FP32) { if (square_modulus <= BGC_FP32_SQUARE_EPSYLON) {
power->real = 0.0f; power->real = 0.0f;
power->imaginary = 0.0f; power->imaginary = 0.0f;
return; return;
@ -106,11 +106,11 @@ void bgc_complex_get_exponation_fp32(const BgcComplexFP32* base, const float rea
power->imaginary = power_modulus * sinf(power_angle); power->imaginary = power_modulus * sinf(power_angle);
} }
void bgc_complex_get_exponation_fp64(const BgcComplexFP64* base, const double real_exponent, const double imaginary_exponent, BgcComplexFP64* power) void bgc_fp64_complex_get_exponation(const BGC_FP64_Complex* base, const double real_exponent, const double imaginary_exponent, BGC_FP64_Complex* power)
{ {
const double square_modulus = bgc_complex_get_square_modulus_fp64(base); const double square_modulus = bgc_fp64_complex_get_square_modulus(base);
if (square_modulus <= BGC_SQUARE_EPSYLON_FP64) { if (square_modulus <= BGC_FP64_SQUARE_EPSYLON) {
power->real = 0.0; power->real = 0.0;
power->imaginary = 0.0; power->imaginary = 0.0;
return; return;

228
basic-geometry/complex.h
View file

@ -9,22 +9,22 @@
typedef struct typedef struct
{ {
float real, imaginary; float real, imaginary;
} BgcComplexFP32; } BGC_FP32_Complex;
typedef struct typedef struct
{ {
double real, imaginary; double real, imaginary;
} BgcComplexFP64; } BGC_FP64_Complex;
// =================== Reset ==================== // // =================== Reset ==================== //
inline void bgc_complex_reset_fp32(BgcComplexFP32* complex) inline void bgc_fp32_complex_reset(BGC_FP32_Complex* complex)
{ {
complex->real = 0.0f; complex->real = 0.0f;
complex->imaginary = 0.0f; complex->imaginary = 0.0f;
} }
inline void bgc_complex_reset_fp64(BgcComplexFP64* complex) inline void bgc_fp64_complex_reset(BGC_FP64_Complex* complex)
{ {
complex->real = 0.0; complex->real = 0.0;
complex->imaginary = 0.0; complex->imaginary = 0.0;
@ -32,71 +32,71 @@ inline void bgc_complex_reset_fp64(BgcComplexFP64* complex)
// ==================== Set ===================== // // ==================== Set ===================== //
inline void bgc_complex_set_values_fp32(const float real, const float imaginary, BgcComplexFP32* destination) inline void bgc_fp32_complex_make(const float real, const float imaginary, BGC_FP32_Complex* complex)
{ {
destination->real = real; complex->real = real;
destination->imaginary = imaginary; complex->imaginary = imaginary;
} }
inline void bgc_complex_set_values_fp64(const double real, const double imaginary, BgcComplexFP64* destination) inline void bgc_fp64_complex_make(const double real, const double imaginary, BGC_FP64_Complex* complex)
{ {
destination->real = real; complex->real = real;
destination->imaginary = imaginary; complex->imaginary = imaginary;
} }
// ================== Modulus =================== // // ================== Modulus =================== //
inline float bgc_complex_get_square_modulus_fp32(const BgcComplexFP32* number) inline float bgc_fp32_complex_get_square_modulus(const BGC_FP32_Complex* number)
{ {
return number->real * number->real + number->imaginary * number->imaginary; return number->real * number->real + number->imaginary * number->imaginary;
} }
inline double bgc_complex_get_square_modulus_fp64(const BgcComplexFP64* number) inline double bgc_fp64_complex_get_square_modulus(const BGC_FP64_Complex* number)
{ {
return number->real * number->real + number->imaginary * number->imaginary; return number->real * number->real + number->imaginary * number->imaginary;
} }
inline float bgc_complex_get_modulus_fp32(const BgcComplexFP32* number) inline float bgc_fp32_complex_get_modulus(const BGC_FP32_Complex* number)
{ {
return sqrtf(bgc_complex_get_square_modulus_fp32(number)); return sqrtf(bgc_fp32_complex_get_square_modulus(number));
} }
inline double bgc_complex_get_modulus_fp64(const BgcComplexFP64* number) inline double bgc_fp64_complex_get_modulus(const BGC_FP64_Complex* number)
{ {
return sqrt(bgc_complex_get_square_modulus_fp64(number)); return sqrt(bgc_fp64_complex_get_square_modulus(number));
} }
// ================= Comparison ================= // // ================= Comparison ================= //
inline int bgc_complex_is_zero_fp32(const BgcComplexFP32* number) inline int bgc_fp32_complex_is_zero(const BGC_FP32_Complex* number)
{ {
return bgc_complex_get_square_modulus_fp32(number) <= BGC_SQUARE_EPSYLON_FP32; return bgc_fp32_complex_get_square_modulus(number) <= BGC_FP32_SQUARE_EPSYLON;
} }
inline int bgc_complex_is_zero_fp64(const BgcComplexFP64* number) inline int bgc_fp64_complex_is_zero(const BGC_FP64_Complex* number)
{ {
return bgc_complex_get_square_modulus_fp64(number) <= BGC_SQUARE_EPSYLON_FP64; return bgc_fp64_complex_get_square_modulus(number) <= BGC_FP64_SQUARE_EPSYLON;
} }
inline int bgc_complex_is_unit_fp32(const BgcComplexFP32* number) inline int bgc_fp32_complex_is_unit(const BGC_FP32_Complex* number)
{ {
return bgc_is_sqare_unit_fp32(bgc_complex_get_square_modulus_fp32(number)); return bgc_fp32_is_square_unit(bgc_fp32_complex_get_square_modulus(number));
} }
inline int bgc_complex_is_unit_fp64(const BgcComplexFP64* number) inline int bgc_fp64_complex_is_unit(const BGC_FP64_Complex* number)
{ {
return bgc_is_sqare_unit_fp64(bgc_complex_get_square_modulus_fp64(number)); return bgc_fp64_is_square_unit(bgc_fp64_complex_get_square_modulus(number));
} }
// ==================== Copy ==================== // // ==================== Copy ==================== //
inline void bgc_complex_copy_fp32(const BgcComplexFP32* source, BgcComplexFP32* destination) inline void bgc_fp32_complex_copy(const BGC_FP32_Complex* source, BGC_FP32_Complex* destination)
{ {
destination->real = source->real; destination->real = source->real;
destination->imaginary = source->imaginary; destination->imaginary = source->imaginary;
} }
inline void bgc_complex_copy_fp64(const BgcComplexFP64* source, BgcComplexFP64* destination) inline void bgc_fp64_complex_copy(const BGC_FP64_Complex* source, BGC_FP64_Complex* destination)
{ {
destination->real = source->real; destination->real = source->real;
destination->imaginary = source->imaginary; destination->imaginary = source->imaginary;
@ -104,7 +104,7 @@ inline void bgc_complex_copy_fp64(const BgcComplexFP64* source, BgcComplexFP64*
// ==================== Swap ==================== // // ==================== Swap ==================== //
inline void bgc_complex_swap_fp32(BgcComplexFP32* number1, BgcComplexFP32* number2) inline void bgc_fp32_complex_swap(BGC_FP32_Complex* number1, BGC_FP32_Complex* number2)
{ {
const float real = number2->real; const float real = number2->real;
const float imaginary = number2->imaginary; const float imaginary = number2->imaginary;
@ -116,7 +116,7 @@ inline void bgc_complex_swap_fp32(BgcComplexFP32* number1, BgcComplexFP32* numbe
number1->imaginary = imaginary; number1->imaginary = imaginary;
} }
inline void bgc_complex_swap_fp64(BgcComplexFP64* number1, BgcComplexFP64* number2) inline void bgc_fp64_complex_swap(BGC_FP64_Complex* number1, BGC_FP64_Complex* number2)
{ {
const double real = number2->real; const double real = number2->real;
const double imaginary = number2->imaginary; const double imaginary = number2->imaginary;
@ -130,13 +130,13 @@ inline void bgc_complex_swap_fp64(BgcComplexFP64* number1, BgcComplexFP64* numbe
// ================== Convert =================== // // ================== Convert =================== //
inline void bgc_complex_convert_fp64_to_fp32(const BgcComplexFP64* source, BgcComplexFP32* destination) inline void bgc_fp64_complex_convert_to_fp32(const BGC_FP64_Complex* source, BGC_FP32_Complex* destination)
{ {
destination->real = (float)source->real; destination->real = (float)source->real;
destination->imaginary = (float)source->imaginary; destination->imaginary = (float)source->imaginary;
} }
inline void bgc_complex_convert_fp32_to_fp64(const BgcComplexFP32* source, BgcComplexFP64* destination) inline void bgc_fp32_complex_convert_to_fp64(const BGC_FP32_Complex* source, BGC_FP64_Complex* destination)
{ {
destination->real = source->real; destination->real = source->real;
destination->imaginary = source->imaginary; destination->imaginary = source->imaginary;
@ -144,25 +144,25 @@ inline void bgc_complex_convert_fp32_to_fp64(const BgcComplexFP32* source, BgcCo
// ================== Negative ================== // // ================== Negative ================== //
inline void bgc_complex_make_opposite_fp32(BgcComplexFP32* number) inline void bgc_fp32_complex_revert(BGC_FP32_Complex* number)
{ {
number->real = -number->real; number->real = -number->real;
number->imaginary = -number->imaginary; number->imaginary = -number->imaginary;
} }
inline void bgc_complex_make_opposite_fp64(BgcComplexFP64* number) inline void bgc_fp64_complex_revert(BGC_FP64_Complex* number)
{ {
number->real = -number->real; number->real = -number->real;
number->imaginary = -number->imaginary; number->imaginary = -number->imaginary;
} }
inline void bgc_complex_get_opposite_fp32(const BgcComplexFP32* number, BgcComplexFP32* opposite) inline void bgc_fp32_complex_get_reverse(const BGC_FP32_Complex* number, BGC_FP32_Complex* opposite)
{ {
opposite->real = -number->real; opposite->real = -number->real;
opposite->imaginary = -number->imaginary; opposite->imaginary = -number->imaginary;
} }
inline void bgc_complex_get_opposite_fp64(const BgcComplexFP64* number, BgcComplexFP64* opposite) inline void bgc_fp64_complex_get_reverse(const BGC_FP64_Complex* number, BGC_FP64_Complex* opposite)
{ {
opposite->real = -number->real; opposite->real = -number->real;
opposite->imaginary = -number->imaginary; opposite->imaginary = -number->imaginary;
@ -170,15 +170,15 @@ inline void bgc_complex_get_opposite_fp64(const BgcComplexFP64* number, BgcCompl
// ================= Normalize ================== // // ================= Normalize ================== //
inline int bgc_complex_normalize_fp32(BgcComplexFP32* number) inline int bgc_fp32_complex_normalize(BGC_FP32_Complex* number)
{ {
const float square_modulus = bgc_complex_get_square_modulus_fp32(number); const float square_modulus = bgc_fp32_complex_get_square_modulus(number);
if (bgc_is_sqare_unit_fp32(square_modulus)) { if (bgc_fp32_is_square_unit(square_modulus)) {
return 1; return 1;
} }
if (square_modulus <= BGC_SQUARE_EPSYLON_FP32 || square_modulus != square_modulus) { if (square_modulus <= BGC_FP32_SQUARE_EPSYLON || isnan(square_modulus)) {
return 0; return 0;
} }
@ -190,15 +190,15 @@ inline int bgc_complex_normalize_fp32(BgcComplexFP32* number)
return 1; return 1;
} }
inline int bgc_complex_normalize_fp64(BgcComplexFP64* number) inline int bgc_fp64_complex_normalize(BGC_FP64_Complex* number)
{ {
const double square_modulus = bgc_complex_get_square_modulus_fp64(number); const double square_modulus = bgc_fp64_complex_get_square_modulus(number);
if (bgc_is_sqare_unit_fp64(square_modulus)) { if (bgc_fp64_is_square_unit(square_modulus)) {
return 1; return 1;
} }
if (square_modulus <= BGC_SQUARE_EPSYLON_FP64 || square_modulus != square_modulus) { if (square_modulus <= BGC_FP64_SQUARE_EPSYLON || isnan(square_modulus)) {
return 0; return 0;
} }
@ -210,17 +210,17 @@ inline int bgc_complex_normalize_fp64(BgcComplexFP64* number)
return 1; return 1;
} }
inline int bgc_complex_get_normalized_fp32(const BgcComplexFP32* number, BgcComplexFP32* normalized) inline int bgc_fp32_complex_get_normalized(const BGC_FP32_Complex* number, BGC_FP32_Complex* normalized)
{ {
const float square_modulus = bgc_complex_get_square_modulus_fp32(number); const float square_modulus = bgc_fp32_complex_get_square_modulus(number);
if (bgc_is_sqare_unit_fp32(square_modulus)) { if (bgc_fp32_is_square_unit(square_modulus)) {
normalized->real = number->real; normalized->real = number->real;
normalized->imaginary = number->imaginary; normalized->imaginary = number->imaginary;
return 1; return 1;
} }
if (square_modulus <= BGC_SQUARE_EPSYLON_FP32 || square_modulus != square_modulus) { if (square_modulus <= BGC_FP32_SQUARE_EPSYLON || isnan(square_modulus)) {
normalized->real = 0.0f; normalized->real = 0.0f;
normalized->imaginary = 0.0f; normalized->imaginary = 0.0f;
return 0; return 0;
@ -234,17 +234,17 @@ inline int bgc_complex_get_normalized_fp32(const BgcComplexFP32* number, BgcComp
return 1; return 1;
} }
inline int bgc_complex_get_normalized_fp64(const BgcComplexFP64* number, BgcComplexFP64* normalized) inline int bgc_fp64_complex_get_normalized(const BGC_FP64_Complex* number, BGC_FP64_Complex* normalized)
{ {
const double square_modulus = bgc_complex_get_square_modulus_fp64(number); const double square_modulus = bgc_fp64_complex_get_square_modulus(number);
if (bgc_is_sqare_unit_fp64(square_modulus)) { if (bgc_fp64_is_square_unit(square_modulus)) {
normalized->real = number->real; normalized->real = number->real;
normalized->imaginary = number->imaginary; normalized->imaginary = number->imaginary;
return 1; return 1;
} }
if (square_modulus <= BGC_SQUARE_EPSYLON_FP64 || square_modulus != square_modulus) { if (square_modulus <= BGC_FP64_SQUARE_EPSYLON || isnan(square_modulus)) {
normalized->real = 0.0; normalized->real = 0.0;
normalized->imaginary = 0.0; normalized->imaginary = 0.0;
return 0; return 0;
@ -260,23 +260,23 @@ inline int bgc_complex_get_normalized_fp64(const BgcComplexFP64* number, BgcComp
// ================= Conjugate ================== // // ================= Conjugate ================== //
inline void bgc_complex_conjugate_fp32(BgcComplexFP32* number) inline void bgc_fp32_complex_conjugate(BGC_FP32_Complex* number)
{ {
number->imaginary = -number->imaginary; number->imaginary = -number->imaginary;
} }
inline void bgc_complex_conjugate_fp64(BgcComplexFP64* number) inline void bgc_fp64_complex_conjugate(BGC_FP64_Complex* number)
{ {
number->imaginary = -number->imaginary; number->imaginary = -number->imaginary;
} }
inline void bgc_complex_get_conjugate_fp32(const BgcComplexFP32* number, BgcComplexFP32* conjugate) inline void bgc_fp32_complex_get_conjugate(const BGC_FP32_Complex* number, BGC_FP32_Complex* conjugate)
{ {
conjugate->real = number->real; conjugate->real = number->real;
conjugate->imaginary = -number->imaginary; conjugate->imaginary = -number->imaginary;
} }
inline void bgc_complex_get_conjugate_fp64(const BgcComplexFP64* number, BgcComplexFP64* conjugate) inline void bgc_fp64_complex_get_conjugate(const BGC_FP64_Complex* number, BGC_FP64_Complex* conjugate)
{ {
conjugate->real = number->real; conjugate->real = number->real;
conjugate->imaginary = -number->imaginary; conjugate->imaginary = -number->imaginary;
@ -284,11 +284,11 @@ inline void bgc_complex_get_conjugate_fp64(const BgcComplexFP64* number, BgcComp
// =================== Invert =================== // // =================== Invert =================== //
inline int bgc_complex_get_inverse_fp32(const BgcComplexFP32* number, BgcComplexFP32* inverse) inline int bgc_fp32_complex_get_inverse(const BGC_FP32_Complex* number, BGC_FP32_Complex* inverse)
{ {
const float square_modulus = bgc_complex_get_square_modulus_fp32(number); const float square_modulus = bgc_fp32_complex_get_square_modulus(number);
if (square_modulus <= BGC_SQUARE_EPSYLON_FP32 || square_modulus != square_modulus) { if (square_modulus <= BGC_FP32_SQUARE_EPSYLON || isnan(square_modulus)) {
return 0; return 0;
} }
@ -300,11 +300,11 @@ inline int bgc_complex_get_inverse_fp32(const BgcComplexFP32* number, BgcComplex
return 1; return 1;
} }
inline int bgc_complex_get_inverse_fp64(const BgcComplexFP64* number, BgcComplexFP64* inverse) inline int bgc_fp64_complex_get_inverse(const BGC_FP64_Complex* number, BGC_FP64_Complex* inverse)
{ {
const double square_modulus = bgc_complex_get_square_modulus_fp64(number); const double square_modulus = bgc_fp64_complex_get_square_modulus(number);
if (square_modulus <= BGC_SQUARE_EPSYLON_FP64 || square_modulus != square_modulus) { if (square_modulus <= BGC_FP64_SQUARE_EPSYLON || isnan(square_modulus)) {
return 0; return 0;
} }
@ -316,31 +316,31 @@ inline int bgc_complex_get_inverse_fp64(const BgcComplexFP64* number, BgcComplex
return 1; return 1;
} }
inline int bgc_complex_invert_fp32(BgcComplexFP32* number) inline int bgc_fp32_complex_invert(BGC_FP32_Complex* number)
{ {
return bgc_complex_get_inverse_fp32(number, number); return bgc_fp32_complex_get_inverse(number, number);
} }
inline int bgc_complex_invert_fp64(BgcComplexFP64* number) inline int bgc_fp64_complex_invert(BGC_FP64_Complex* number)
{ {
return bgc_complex_get_inverse_fp64(number, number); return bgc_fp64_complex_get_inverse(number, number);
} }
// =============== Get Exponation =============== // // =============== Get Exponation =============== //
void bgc_complex_get_exponation_fp32(const BgcComplexFP32* base, const float real_exponent, const float imaginary_exponent, BgcComplexFP32* power); void bgc_fp32_complex_get_exponation(const BGC_FP32_Complex* base, const float real_exponent, const float imaginary_exponent, BGC_FP32_Complex* power);
void bgc_complex_get_exponation_fp64(const BgcComplexFP64* base, const double real_exponent, const double imaginary_exponent, BgcComplexFP64* power); void bgc_fp64_complex_get_exponation(const BGC_FP64_Complex* base, const double real_exponent, const double imaginary_exponent, BGC_FP64_Complex* power);
// ==================== Add ===================== // // ==================== Add ===================== //
inline void bgc_complex_add_fp32(const BgcComplexFP32* number1, const BgcComplexFP32* number2, BgcComplexFP32* sum) inline void bgc_fp32_complex_add(const BGC_FP32_Complex* number1, const BGC_FP32_Complex* number2, BGC_FP32_Complex* sum)
{ {
sum->real = number1->real + number2->real; sum->real = number1->real + number2->real;
sum->imaginary = number1->imaginary + number2->imaginary; sum->imaginary = number1->imaginary + number2->imaginary;
} }
inline void bgc_complex_add_fp64(const BgcComplexFP64* number1, const BgcComplexFP64* number2, BgcComplexFP64* sum) inline void bgc_fp64_complex_add(const BGC_FP64_Complex* number1, const BGC_FP64_Complex* number2, BGC_FP64_Complex* sum)
{ {
sum->real = number1->real + number2->real; sum->real = number1->real + number2->real;
sum->imaginary = number1->imaginary + number2->imaginary; sum->imaginary = number1->imaginary + number2->imaginary;
@ -348,13 +348,13 @@ inline void bgc_complex_add_fp64(const BgcComplexFP64* number1, const BgcComplex
// ================= Add scaled ================= // // ================= Add scaled ================= //
inline void bgc_complex_add_scaled_fp32(const BgcComplexFP32* basic_number, const BgcComplexFP32* scalable_number, const float scale, BgcComplexFP32* sum) inline void bgc_fp32_complex_add_scaled(const BGC_FP32_Complex* basic_number, const BGC_FP32_Complex* scalable_number, const float scale, BGC_FP32_Complex* sum)
{ {
sum->real = basic_number->real + scalable_number->real * scale; sum->real = basic_number->real + scalable_number->real * scale;
sum->imaginary = basic_number->imaginary + scalable_number->imaginary * scale; sum->imaginary = basic_number->imaginary + scalable_number->imaginary * scale;
} }
inline void bgc_complex_add_scaled_fp64(const BgcComplexFP64* basic_number, const BgcComplexFP64* scalable_number, const double scale, BgcComplexFP64* sum) inline void bgc_fp64_complex_add_scaled(const BGC_FP64_Complex* basic_number, const BGC_FP64_Complex* scalable_number, const double scale, BGC_FP64_Complex* sum)
{ {
sum->real = basic_number->real + scalable_number->real * scale; sum->real = basic_number->real + scalable_number->real * scale;
sum->imaginary = basic_number->imaginary + scalable_number->imaginary * scale; sum->imaginary = basic_number->imaginary + scalable_number->imaginary * scale;
@ -362,13 +362,13 @@ inline void bgc_complex_add_scaled_fp64(const BgcComplexFP64* basic_number, cons
// ================== Subtract ================== // // ================== Subtract ================== //
inline void bgc_complex_subtract_fp32(const BgcComplexFP32* minuend, const BgcComplexFP32* subtrahend, BgcComplexFP32* difference) inline void bgc_fp32_complex_subtract(const BGC_FP32_Complex* minuend, const BGC_FP32_Complex* subtrahend, BGC_FP32_Complex* difference)
{ {
difference->real = minuend->real - subtrahend->real; difference->real = minuend->real - subtrahend->real;
difference->imaginary = minuend->imaginary - subtrahend->imaginary; difference->imaginary = minuend->imaginary - subtrahend->imaginary;
} }
inline void bgc_complex_subtract_fp64(const BgcComplexFP64* minuend, const BgcComplexFP64* subtrahend, BgcComplexFP64* difference) inline void bgc_fp64_complex_subtract(const BGC_FP64_Complex* minuend, const BGC_FP64_Complex* subtrahend, BGC_FP64_Complex* difference)
{ {
difference->real = minuend->real - subtrahend->real; difference->real = minuend->real - subtrahend->real;
difference->imaginary = minuend->imaginary - subtrahend->imaginary; difference->imaginary = minuend->imaginary - subtrahend->imaginary;
@ -376,7 +376,7 @@ inline void bgc_complex_subtract_fp64(const BgcComplexFP64* minuend, const BgcCo
// ================== Multiply ================== // // ================== Multiply ================== //
inline void bgc_complex_multiply_fp32(const BgcComplexFP32* number1, const BgcComplexFP32* number2, BgcComplexFP32* product) inline void bgc_fp32_complex_get_product(const BGC_FP32_Complex* number1, const BGC_FP32_Complex* number2, BGC_FP32_Complex* product)
{ {
const float real = number1->real * number2->real - number1->imaginary * number2->imaginary; const float real = number1->real * number2->real - number1->imaginary * number2->imaginary;
const float imaginary = number1->real * number2->imaginary + number1->imaginary * number2->real; const float imaginary = number1->real * number2->imaginary + number1->imaginary * number2->real;
@ -385,7 +385,7 @@ inline void bgc_complex_multiply_fp32(const BgcComplexFP32* number1, const BgcCo
product->imaginary = imaginary; product->imaginary = imaginary;
} }
inline void bgc_complex_multiply_fp64(const BgcComplexFP64* number1, const BgcComplexFP64* number2, BgcComplexFP64* product) inline void bgc_fp64_complex_get_product(const BGC_FP64_Complex* number1, const BGC_FP64_Complex* number2, BGC_FP64_Complex* product)
{ {
const double real = number1->real * number2->real - number1->imaginary * number2->imaginary; const double real = number1->real * number2->real - number1->imaginary * number2->imaginary;
const double imaginary = number1->real * number2->imaginary + number1->imaginary * number2->real; const double imaginary = number1->real * number2->imaginary + number1->imaginary * number2->real;
@ -396,13 +396,13 @@ inline void bgc_complex_multiply_fp64(const BgcComplexFP64* number1, const BgcCo
// ============= Multiply By Number ============= // // ============= Multiply By Number ============= //
inline void bgc_complex_multiply_by_number_fp32(const BgcComplexFP32* multiplicand, const float multiplier, BgcComplexFP32* product) inline void bgc_fp32_complex_multiply(const BGC_FP32_Complex* multiplicand, const float multiplier, BGC_FP32_Complex* product)
{ {
product->real = multiplicand->real * multiplier; product->real = multiplicand->real * multiplier;
product->imaginary = multiplicand->imaginary * multiplier; product->imaginary = multiplicand->imaginary * multiplier;
} }
inline void bgc_complex_multiply_by_number_fp64(const BgcComplexFP64* multiplicand, const double multiplier, BgcComplexFP64* product) inline void bgc_fp64_complex_multiply(const BGC_FP64_Complex* multiplicand, const double multiplier, BGC_FP64_Complex* product)
{ {
product->real = multiplicand->real * multiplier; product->real = multiplicand->real * multiplier;
product->imaginary = multiplicand->imaginary * multiplier; product->imaginary = multiplicand->imaginary * multiplier;
@ -410,11 +410,11 @@ inline void bgc_complex_multiply_by_number_fp64(const BgcComplexFP64* multiplica
// =================== Divide =================== // // =================== Divide =================== //
inline int bgc_complex_devide_fp32(const BgcComplexFP32* divident, const BgcComplexFP32* divisor, BgcComplexFP32* quotient) inline int bgc_fp32_complex_get_ratio(const BGC_FP32_Complex* divident, const BGC_FP32_Complex* divisor, BGC_FP32_Complex* quotient)
{ {
const float square_modulus = bgc_complex_get_square_modulus_fp32(divisor); const float square_modulus = bgc_fp32_complex_get_square_modulus(divisor);
if (square_modulus <= BGC_SQUARE_EPSYLON_FP32) { if (square_modulus <= BGC_FP32_SQUARE_EPSYLON) {
return 0; return 0;
} }
@ -429,11 +429,11 @@ inline int bgc_complex_devide_fp32(const BgcComplexFP32* divident, const BgcComp
return 1; return 1;
} }
inline int bgc_complex_devide_fp64(const BgcComplexFP64* divident, const BgcComplexFP64* divisor, BgcComplexFP64* quotient) inline int bgc_fp64_complex_get_ratio(const BGC_FP64_Complex* divident, const BGC_FP64_Complex* divisor, BGC_FP64_Complex* quotient)
{ {
const double square_modulus = bgc_complex_get_square_modulus_fp64(divisor); const double square_modulus = bgc_fp64_complex_get_square_modulus(divisor);
if (square_modulus <= BGC_SQUARE_EPSYLON_FP64) { if (square_modulus <= BGC_FP64_SQUARE_EPSYLON) {
return 0; return 0;
} }
@ -450,25 +450,25 @@ inline int bgc_complex_devide_fp64(const BgcComplexFP64* divident, const BgcComp
// ============== Divide By Number ============== // // ============== Divide By Number ============== //
inline void bgc_complex_divide_by_number_fp32(const BgcComplexFP32* dividend, const float divisor, BgcComplexFP32* quotient) inline void bgc_fp32_complex_divide(const BGC_FP32_Complex* dividend, const float divisor, BGC_FP32_Complex* quotient)
{ {
bgc_complex_multiply_by_number_fp32(dividend, 1.0f / divisor, quotient); bgc_fp32_complex_multiply(dividend, 1.0f / divisor, quotient);
} }
inline void bgc_complex_divide_by_number_fp64(const BgcComplexFP64* dividend, const double divisor, BgcComplexFP64* quotient) inline void bgc_fp64_complex_divide(const BGC_FP64_Complex* dividend, const double divisor, BGC_FP64_Complex* quotient)
{ {
bgc_complex_multiply_by_number_fp64(dividend, 1.0 / divisor, quotient); bgc_fp64_complex_multiply(dividend, 1.0 / divisor, quotient);
} }
// ================== Average2 ================== // // ================== Average2 ================== //
inline void bgc_complex_get_mean_of_two_fp32(const BgcComplexFP32* number1, const BgcComplexFP32* number2, BgcComplexFP32* mean) inline void bgc_fp32_complex_get_mean2(const BGC_FP32_Complex* number1, const BGC_FP32_Complex* number2, BGC_FP32_Complex* mean)
{ {
mean->real = (number1->real + number2->real) * 0.5f; mean->real = (number1->real + number2->real) * 0.5f;
mean->imaginary = (number1->imaginary + number2->imaginary) * 0.5f; mean->imaginary = (number1->imaginary + number2->imaginary) * 0.5f;
} }
inline void bgc_complex_get_mean_of_two_fp64(const BgcComplexFP64* number1, const BgcComplexFP64* number2, BgcComplexFP64* mean) inline void bgc_fp64_complex_get_mean2(const BGC_FP64_Complex* number1, const BGC_FP64_Complex* number2, BGC_FP64_Complex* mean)
{ {
mean->real = (number1->real + number2->real) * 0.5; mean->real = (number1->real + number2->real) * 0.5;
mean->imaginary = (number1->imaginary + number2->imaginary) * 0.5; mean->imaginary = (number1->imaginary + number2->imaginary) * 0.5;
@ -476,70 +476,70 @@ inline void bgc_complex_get_mean_of_two_fp64(const BgcComplexFP64* number1, cons
// ================== Average3 ================== // // ================== Average3 ================== //
inline void bgc_complex_get_mean_of_three_fp32(const BgcComplexFP32* number1, const BgcComplexFP32* number2, const BgcComplexFP32* number3, BgcComplexFP32* mean) inline void bgc_fp32_complex_get_mean3(const BGC_FP32_Complex* number1, const BGC_FP32_Complex* number2, const BGC_FP32_Complex* number3, BGC_FP32_Complex* mean)
{ {
mean->real = (number1->real + number2->real + number3->real) * BGC_ONE_THIRD_FP32; mean->real = (number1->real + number2->real + number3->real) * BGC_FP32_ONE_THIRD;
mean->imaginary = (number1->imaginary + number2->imaginary + number3->imaginary) * BGC_ONE_THIRD_FP32; mean->imaginary = (number1->imaginary + number2->imaginary + number3->imaginary) * BGC_FP32_ONE_THIRD;
} }
inline void bgc_complex_get_mean_of_three_fp64(const BgcComplexFP64* number1, const BgcComplexFP64* number2, const BgcComplexFP64* number3, BgcComplexFP64* mean) inline void bgc_fp64_complex_get_mean3(const BGC_FP64_Complex* number1, const BGC_FP64_Complex* number2, const BGC_FP64_Complex* number3, BGC_FP64_Complex* mean)
{ {
mean->real = (number1->real + number2->real + number3->real) * BGC_ONE_THIRD_FP64; mean->real = (number1->real + number2->real + number3->real) * BGC_FP64_ONE_THIRD;
mean->imaginary = (number1->imaginary + number2->imaginary + number3->imaginary) * BGC_ONE_THIRD_FP64; mean->imaginary = (number1->imaginary + number2->imaginary + number3->imaginary) * BGC_FP64_ONE_THIRD;
} }
// =================== Linear =================== // // =================== Linear =================== //
inline void bgc_complex_interpolate_fp32(const BgcComplexFP32* number1, const BgcComplexFP32* number2, const float phase, BgcComplexFP32* interpolation) inline void bgc_fp32_complex_interpolate(const BGC_FP32_Complex* number1, const BGC_FP32_Complex* number2, const float phase, BGC_FP32_Complex* interpolation)
{ {
const float counterphase = 1.0f - phase; const float counter_phase = 1.0f - phase;
interpolation->real = number1->real * counterphase + number2->real * phase; interpolation->real = number1->real * counter_phase + number2->real * phase;
interpolation->imaginary = number1->imaginary * counterphase + number2->imaginary * phase; interpolation->imaginary = number1->imaginary * counter_phase + number2->imaginary * phase;
} }
inline void bgc_complex_interpolate_fp64(const BgcComplexFP64* number1, const BgcComplexFP64* number2, const double phase, BgcComplexFP64* interpolation) inline void bgc_fp64_complex_interpolate(const BGC_FP64_Complex* number1, const BGC_FP64_Complex* number2, const double phase, BGC_FP64_Complex* interpolation)
{ {
const double counterphase = 1.0 - phase; const double counter_phase = 1.0 - phase;
interpolation->real = number1->real * counterphase + number2->real * phase; interpolation->real = number1->real * counter_phase + number2->real * phase;
interpolation->imaginary = number1->imaginary * counterphase + number2->imaginary * phase; interpolation->imaginary = number1->imaginary * counter_phase + number2->imaginary * phase;
} }
// ================== Are Close ================= // // ================== Are Close ================= //
inline int bgc_complex_are_close_fp32(const BgcComplexFP32* number1, const BgcComplexFP32* number2) inline int bgc_fp32_complex_are_close(const BGC_FP32_Complex* number1, const BGC_FP32_Complex* number2)
{ {
const float square_modulus1 = bgc_complex_get_square_modulus_fp32(number1); const float square_modulus1 = bgc_fp32_complex_get_square_modulus(number1);
const float square_modulus2 = bgc_complex_get_square_modulus_fp32(number2); const float square_modulus2 = bgc_fp32_complex_get_square_modulus(number2);
const float d_real = number1->real - number2->real; const float d_real = number1->real - number2->real;
const float d_imaginary = number1->imaginary - number2->imaginary; const float d_imaginary = number1->imaginary - number2->imaginary;
const float square_distance = d_real * d_real + d_imaginary * d_imaginary; const float square_distance = d_real * d_real + d_imaginary * d_imaginary;
if (square_modulus1 <= BGC_EPSYLON_EFFECTIVENESS_LIMIT_FP32 || square_modulus2 <= BGC_EPSYLON_EFFECTIVENESS_LIMIT_FP32) { if (square_modulus1 <= BGC_FP32_EPSYLON_EFFECTIVENESS_LIMIT || square_modulus2 <= BGC_FP32_EPSYLON_EFFECTIVENESS_LIMIT) {
return square_distance <= BGC_SQUARE_EPSYLON_FP32; return square_distance <= BGC_FP32_SQUARE_EPSYLON;
} }
return square_distance <= BGC_SQUARE_EPSYLON_FP32 * square_modulus1 && square_distance <= BGC_SQUARE_EPSYLON_FP32 * square_modulus2; return square_distance <= BGC_FP32_SQUARE_EPSYLON * square_modulus1 && square_distance <= BGC_FP32_SQUARE_EPSYLON * square_modulus2;
} }
inline int bgc_complex_are_close_fp64(const BgcComplexFP64* number1, const BgcComplexFP64* number2) inline int bgc_fp64_complex_are_close(const BGC_FP64_Complex* number1, const BGC_FP64_Complex* number2)
{ {
const double square_modulus1 = bgc_complex_get_square_modulus_fp64(number1); const double square_modulus1 = bgc_fp64_complex_get_square_modulus(number1);
const double square_modulus2 = bgc_complex_get_square_modulus_fp64(number2); const double square_modulus2 = bgc_fp64_complex_get_square_modulus(number2);
const double d_real = number1->real - number2->real; const double d_real = number1->real - number2->real;
const double d_imaginary = number1->imaginary - number2->imaginary; const double d_imaginary = number1->imaginary - number2->imaginary;
const double square_distance = d_real * d_real + d_imaginary * d_imaginary; const double square_distance = d_real * d_real + d_imaginary * d_imaginary;
if (square_modulus1 <= BGC_EPSYLON_EFFECTIVENESS_LIMIT_FP64 || square_modulus2 <= BGC_EPSYLON_EFFECTIVENESS_LIMIT_FP64) { if (square_modulus1 <= BGC_FP64_EPSYLON_EFFECTIVENESS_LIMIT || square_modulus2 <= BGC_FP64_EPSYLON_EFFECTIVENESS_LIMIT) {
return square_distance <= BGC_SQUARE_EPSYLON_FP64; return square_distance <= BGC_FP64_SQUARE_EPSYLON;
} }
return square_distance <= BGC_SQUARE_EPSYLON_FP64 * square_modulus1 && square_distance <= BGC_SQUARE_EPSYLON_FP64 * square_modulus2; return square_distance <= BGC_FP64_SQUARE_EPSYLON * square_modulus1 && square_distance <= BGC_FP64_SQUARE_EPSYLON * square_modulus2;
} }
#endif #endif

91
basic-geometry/cotes-number.c
View file

Internal server error - Personal Git Server: Beyond coding. We Forge.

500

Internal server error

Forgejo version: 11.0.1+gitea-1.22.0

 @ -1,71 +1,68 @@
#include "./cotes-number.h" #include "./cotes-number.h"
const BgcCotesNumberFP32 BGC_IDLE_COTES_NUMBER_FP32 = { 1.0f, 0.0f }; const BGC_FP32_CotesNumber BGC_FP32_IDLE_COTES_NUMBER = { 1.0f, 0.0f };
const BgcCotesNumberFP64 BGC_IDLE_COTES_NUMBER_FP64 = { 1.0, 0.0 }; const BGC_FP64_CotesNumber BGC_FP64_IDLE_COTES_NUMBER = { 1.0, 0.0 };
extern inline void bgc_cotes_number_reset_fp32(BgcCotesNumberFP32* number); extern inline void bgc_fp32_cotes_number_reset(BGC_FP32_CotesNumber* number);
extern inline void bgc_cotes_number_reset_fp64(BgcCotesNumberFP64* number); extern inline void bgc_fp64_cotes_number_reset(BGC_FP64_CotesNumber* number);
extern inline void bgc_cotes_number_set_values_fp32(const float x1, const float x2, BgcCotesNumberFP32* number); extern inline void bgc_fp32_cotes_number_make(const float x1, const float x2, BGC_FP32_CotesNumber* number);
extern inline void bgc_cotes_number_set_values_fp64(const double x1, const double x2, BgcCotesNumberFP64* number); extern inline void bgc_fp64_cotes_number_make(const double x1, const double x2, BGC_FP64_CotesNumber* number);
extern inline void bgc_cotes_number_set_turn_fp32(const float angle, const BgcAngleUnitEnum unit, BgcCotesNumberFP32* number); extern inline void bgc_fp32_cotes_number_make_for_angle(const float angle, const int angle_unit, BGC_FP32_CotesNumber* number);
extern inline void bgc_cotes_number_set_turn_fp64(const double angle, const BgcAngleUnitEnum unit, BgcCotesNumberFP64* number); extern inline void bgc_fp64_cotes_number_make_for_angle(const double angle, const int angle_unit, BGC_FP64_CotesNumber* number);
extern inline float bgc_cotes_number_get_angle_fp32(const BgcCotesNumberFP32* number, const BgcAngleUnitEnum unit); extern inline int bgc_fp32_cotes_number_is_idle(const BGC_FP32_CotesNumber* number);
extern inline double bgc_cotes_number_get_angle_fp64(const BgcCotesNumberFP64* number, const BgcAngleUnitEnum unit); extern inline int bgc_fp64_cotes_number_is_idle(const BGC_FP64_CotesNumber* number);
extern inline void bgc_cotes_number_copy_fp32(const BgcCotesNumberFP32* source, BgcCotesNumberFP32* destination); extern inline float bgc_fp32_cotes_number_get_angle(const BGC_FP32_CotesNumber* number, const int angle_unit);
extern inline void bgc_cotes_number_copy_fp64(const BgcCotesNumberFP64* source, BgcCotesNumberFP64* destination); extern inline double bgc_fp64_cotes_number_get_angle(const BGC_FP64_CotesNumber* number, const int angle_unit);
extern inline void bgc_cotes_number_swap_fp32(BgcCotesNumberFP32* number1, BgcCotesNumberFP32* number2); extern inline void bgc_fp32_cotes_number_copy(const BGC_FP32_CotesNumber* source, BGC_FP32_CotesNumber* destination);
extern inline void bgc_cotes_number_swap_fp64(BgcCotesNumberFP64* number1, BgcCotesNumberFP64* number2); extern inline void bgc_fp64_cotes_number_copy(const BGC_FP64_CotesNumber* source, BGC_FP64_CotesNumber* destination);
extern inline void bgc_cotes_number_convert_fp64_to_fp32(const BgcCotesNumberFP64* source, BgcCotesNumberFP32* destination); extern inline void bgc_fp32_cotes_number_swap(BGC_FP32_CotesNumber* number1, BGC_FP32_CotesNumber* number2);
extern inline void bgc_cotes_number_convert_fp32_to_fp64(const BgcCotesNumberFP32* source, BgcCotesNumberFP64* destination); extern inline void bgc_fp64_cotes_number_swap(BGC_FP64_CotesNumber* number1, BGC_FP64_CotesNumber* number2);
extern inline void bgc_cotes_number_make_opposite_fp32(BgcCotesNumberFP32* number); extern inline void bgc_fp64_cotes_number_convert_to_fp32(const BGC_FP64_CotesNumber* source, BGC_FP32_CotesNumber* destination);
extern inline void bgc_cotes_number_make_opposite_fp64(BgcCotesNumberFP64* number); extern inline void bgc_fp32_cotes_number_convert_to_fp64(const BGC_FP32_CotesNumber* source, BGC_FP64_CotesNumber* destination);
extern inline void bgc_cotes_number_get_opposite_fp32(const BgcCotesNumberFP32* number, BgcCotesNumberFP32* opposite); extern inline void bgc_fp32_cotes_number_revert(BGC_FP32_CotesNumber* number);
extern inline void bgc_cotes_number_get_opposite_fp64(const BgcCotesNumberFP64* number, BgcCotesNumberFP64* opposite); extern inline void bgc_fp64_cotes_number_revert(BGC_FP64_CotesNumber* number);
extern inline void bgc_cotes_number_invert_fp32(BgcCotesNumberFP32* number); extern inline void bgc_fp32_cotes_number_get_reverse(const BGC_FP32_CotesNumber* number, BGC_FP32_CotesNumber* inverse);
extern inline void bgc_cotes_number_invert_fp64(BgcCotesNumberFP64* number); extern inline void bgc_fp64_cotes_number_get_inverse(const BGC_FP64_CotesNumber* number, BGC_FP64_CotesNumber* inverse);
extern inline void bgc_cotes_number_get_inverse_fp32(const BgcCotesNumberFP32* number, BgcCotesNumberFP32* inverse); extern inline void bgc_fp32_cotes_number_get_exponation(const BGC_FP32_CotesNumber* base, const float exponent, BGC_FP32_CotesNumber* power);