91 lines
1.7 KiB
Plaintext
91 lines
1.7 KiB
Plaintext
#import "modules/std.sx";
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Vec :: struct($N: u32, $T:Type) {
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// <N x T> (LLVM Vector)
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// Vector is a Builtin Type
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data: Vector(N,T);
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}
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Complex :: ($T:Type) -> Type {
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return struct {
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value: T;
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//..inject
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count: u32;
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};
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}
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Vec3 :: Vec(3, f32);
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vec3 :: (x:f32, y:f32, z:f32) -> Vector(3,f32) {
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.[x, y, z];
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}
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Foo :: Complex(u32);
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main :: () {
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v1 := Vec3.{data = .[1,3,2]};
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print("v1: {}\n", v1);
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//stdout: Vec(3,f32){data: [1.0, 3.0, 2.0]}
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//
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v2 := vec3(1,3,2);
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print("v2: {}\n", v2);
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//stdout: [1.0, 3.0, 2.0]
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//
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// [N x T] (LLVM Array)
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buffer : [5]f32 = .[0, 2, 3.5, 4, 0];
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print("buff: {}\n", buffer);
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//stdout: [0.0, 2.0, 3.5, 4.0, 0.0]
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//
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comp : Foo = .{value = 42, count = 1};
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print("comp: {}\n", comp);
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//stdout: Foo{value: 42, count: 1}
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//
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// Vector arithmetic
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v3 := vec3(3,2,1);
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add := v2 + v3;
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print("add: {}\n", add);
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// Element access
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v2x := v2.x;
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print("v2.x: {}\n", v2x);
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// Index access
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v2i := v2[1];
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print("v2[1]: {}\n", v2i);
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// Scalar broadcast
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scaled := v2 * 2.0;
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print("scaled: {}\n", scaled);
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// Negation
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neg := -v2;
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print("neg: {}\n", neg);
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// sqrt
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s := sqrt(9.0);
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print("sqrt(9): {}\n", s);
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// inline generic type
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Sx :: (user: $T) -> Type {
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return enum {
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counter: s32;
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user: T;
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};
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}
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sx := Sx(f32).user(0.5);
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print("{}\n", sx);
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print("{}\n", size_of(f32));
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print("{}\n", size_of(Sx(f32)));
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print("{}\n", size_of(Foo));
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print("{}\n", size_of(Complex));
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size := size_of(Sx);
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print("{}\n", size);
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}
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