264 lines
8.1 KiB
C++
264 lines
8.1 KiB
C++
#include "spec_helper.h"
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#include <iostream>
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using vectorial::vec3f;
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const int epsilon = 1;
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describe(vec3f, "constructing") {
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it("should have default constructor that does nothing..") {
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vec3f x;
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}
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it("should have constructor with element values") {
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vec3f x(10,20,30);
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// octave vec3f: [10,20,30]
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should_be_equal_vec3f(x, simd4f_create(10.000000000000000f, 20.000000000000000f, 30.000000000000000f, 0.0f), epsilon );
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}
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it("should have constructor that loads from a float array") {
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float ary[3] = { 1,2,3 };
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vec3f x(ary);
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// octave vec3f: [1,2,3]
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should_be_equal_vec3f(x, simd4f_create(1.000000000000000f, 2.000000000000000f, 3.000000000000000f, 0.0f), epsilon );
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}
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}
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describe(vec3f, "loads and stores") {
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it("should have method for loading from a float array") {
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float ary[3] = { 1,2,3 };
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vec3f x(-1, -1, -1 );
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x.load(ary);
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// octave vec3f: [1,2,3]
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should_be_equal_vec3f(x, simd4f_create(1.000000000000000f, 2.000000000000000f, 3.000000000000000f, 0.0f), epsilon );
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}
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it("should have method for storing to a float array") {
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float ary[3] = { -1, -1, -1 };
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vec3f x(1, 2, 3);
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x.store(ary);
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should_be_close_to(ary[0], 1, epsilon);
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should_be_close_to(ary[1], 2, epsilon);
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should_be_close_to(ary[2], 3, epsilon);
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}
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}
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describe(vec3f, "arithmetic with another vec3f") {
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it("should have operator+ for component-wise addition") {
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vec3f a(1,2,3);
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vec3f b(10,20,30);
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vec3f x = a + b;
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// octave vec3f: [1,2,3] + [10,20,30]
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should_be_equal_vec3f(x, simd4f_create(11.000000000000000f, 22.000000000000000f, 33.000000000000000f, 0.0f), epsilon );
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}
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it("should have operator- for component-wise subtraction") {
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vec3f a(1,2,3);
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vec3f b(10,20,30);
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vec3f x = b - a;
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// octave vec3f: [10,20,30] - [1,2,3]
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should_be_equal_vec3f(x, simd4f_create(9.000000000000000f, 18.000000000000000f, 27.000000000000000f, 0.0f), epsilon );
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}
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it("should have operator* for component-wise multiplication") {
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vec3f a(1,2,3);
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vec3f b(10,20,30);
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vec3f x = a * b;
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// octave vec3f: [1,2,3] .* [10,20,30]
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should_be_equal_vec3f(x, simd4f_create(10.000000000000000f, 40.000000000000000f, 90.000000000000000f, 0.0f), epsilon );
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}
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it("should have operator/ for component-wise division") {
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vec3f a(1,2,3);
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vec3f b(10,20,30);
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vec3f x = b / a;
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// octave vec3f: [10,20,30] ./ [1,2,3]
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should_be_equal_vec3f(x, simd4f_create(10.000000000000000f, 10.000000000000000f, 10.000000000000000f, 0.0f), epsilon );
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}
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it("should have operator+= for component-wise addition") {
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vec3f x(1,2,3);
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vec3f b(10,20,30);
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x += b;
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// octave vec3f: [1,2,3] + [10,20,30]
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should_be_equal_vec3f(x, simd4f_create(11.000000000000000f, 22.000000000000000f, 33.000000000000000f, 0.0f), epsilon );
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}
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it("should have operator-= for component-wise subtraction") {
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vec3f a(1,2,3);
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vec3f x(10,20,30);
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x -= a;
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// octave vec3f: [10,20,30] - [1,2,3]
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should_be_equal_vec3f(x, simd4f_create(9.000000000000000f, 18.000000000000000f, 27.000000000000000f, 0.0f), epsilon );
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}
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it("should have operator*= for component-wise multiplication") {
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vec3f x(1,2,3);
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vec3f b(10,20,30);
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x *= b;
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// octave vec3f: [1,2,3] .* [10,20,30]
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should_be_equal_vec3f(x, simd4f_create(10.000000000000000f, 40.000000000000000f, 90.000000000000000f, 0.0f), epsilon );
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}
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it("should have operator/= for component-wise division") {
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vec3f a(1,2,3);
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vec3f x(10,20,30);
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x /= a;
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// octave vec3f: [10,20,30] ./ [1,2,3]
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should_be_equal_vec3f(x, simd4f_create(10.000000000000000f, 10.000000000000000f, 10.000000000000000f, 0.0f), epsilon );
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}
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}
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describe(vec3f, "arithmetic with scalar") {
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it("should have operator+ for component-wise addition") {
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vec3f a(1,2,3);
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float b=10;
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vec3f x = a + b;
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// octave vec3f: [1,2,3] + 10
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should_be_equal_vec3f(x, simd4f_create(11.000000000000000f, 12.000000000000000f, 13.000000000000000f, 0.0f), epsilon );
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}
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it("should have operator- for component-wise subtraction") {
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float a=10;
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vec3f b(10,20,30);
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vec3f x = b - a;
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// octave vec3f: [10,20,30] - 10
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should_be_equal_vec3f(x, simd4f_create(0.000000000000000f, 10.000000000000000f, 20.000000000000000f, 0.0f), epsilon );
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}
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it("should have operator* for component-wise multiplication") {
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vec3f a(1,2,3);
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float b=10;
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vec3f x = a * b;
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// octave vec3f: [1,2,3] .* 10
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should_be_equal_vec3f(x, simd4f_create(10.000000000000000f, 20.000000000000000f, 30.000000000000000f, 0.0f), epsilon );
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}
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it("should have operator/ for component-wise division") {
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vec3f a(10,20,30);
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float b=10;
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vec3f x = a / b;
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// octave vec3f: [10,20,30] ./ 10
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should_be_equal_vec3f(x, simd4f_create(1.000000000000000f, 2.000000000000000f, 3.000000000000000f, 0.0f), epsilon );
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}
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it("should have operator+ for component-wise addition (float as lhs)") {
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vec3f b(1,2,3);
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float a=10;
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vec3f x = a + b;
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// octave vec3f: 10 + [1,2,3]
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should_be_equal_vec3f(x, simd4f_create(11.000000000000000f, 12.000000000000000f, 13.000000000000000f, 0.0f), epsilon );
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}
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it("should have operator- for component-wise subtraction (float as lhs)") {
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float b=50;
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vec3f a(10,20,30);
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vec3f x = b - a;
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// octave vec3f: 50 - [10,20,30]
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should_be_equal_vec3f(x, simd4f_create(40.000000000000000f, 30.000000000000000f, 20.000000000000000f, 0.0f), epsilon );
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}
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it("should have operator* for component-wise multiplication (float as lhs)") {
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vec3f b(1,2,3);
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float a=10;
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vec3f x = a * b;
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// octave vec3f: 10 .* [1,2,3]
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should_be_equal_vec3f(x, simd4f_create(10.000000000000000f, 20.000000000000000f, 30.000000000000000f, 0.0f), epsilon );
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}
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it("should have operator* for component-wise multiplication (float as lhs)") {
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vec3f b(10,20,30);
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float a=40;
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vec3f x = a / b;
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// octave vec3f: 40 ./ [10,20,30]
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should_be_equal_vec3f(x, simd4f_create(4.000000000000000f, 2.000000000000000f, 1.333333333333333f, 0.0f), epsilon );
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}
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}
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describe(vec3f, "vector math") {
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it("should have unary minus operator") {
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vec3f a(1,2,3);
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vec3f x = -a;
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// octave vec3f: -[1,2,3]
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should_be_equal_vec3f(x, simd4f_create(-1.000000000000000f, -2.000000000000000f, -3.000000000000000f, 0.0f), epsilon );
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}
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it("should have dot function") {
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vec3f a(1,2,3);
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vec3f b(6,7,8);
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float x = vectorial::dot(a,b);
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// octave vec3f: dot([1,2,3],[6,7,8])
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should_be_close_to(x, 44.000000000000000f, epsilon );
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}
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it("should have cross function") {
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vec3f a(1,2,3);
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vec3f b(6,7,8);
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vec3f x = vectorial::cross(a,b);
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// octave vec3f: cross([1,2,3],[6,7,8])
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should_be_equal_vec3f(x, simd4f_create(-5.000000000000000f, 10.000000000000000f, -5.000000000000000f, 0.0f), epsilon );
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}
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it("should have length_squared function") {
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vec3f a(1,2,3);
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float x = vectorial::length_squared(a);
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// octave vec3f: dot([1,2,3],[1,2,3])
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should_be_close_to(x, 14.000000000000000f, epsilon );
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}
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it("should have length function") {
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vec3f a(1,2,3);
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float x = vectorial::length(a);
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// octave vec3f: norm([1,2,3])
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should_be_close_to(x, 3.741657386773941f, epsilon );
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}
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it("should have normalize function") {
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vec3f a(1,2,3);
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vec3f x = vectorial::normalize(a);
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// octave vec3f: [1,2,3] / norm([1,2,3])
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should_be_equal_vec3f(x, simd4f_create(0.267261241912424f, 0.534522483824849f, 0.801783725737273f, 0.0f), epsilon );
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}
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}
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