const std = @import("std"); const math = std.math; const expect = std.testing.expect; const Complex = @import("./mulc3.zig").Complex; const __mulhc3 = @import("./mulhc3.zig").__mulhc3; const __mulsc3 = @import("./mulsc3.zig").__mulsc3; const __muldc3 = @import("./muldc3.zig").__muldc3; const __mulxc3 = @import("./mulxc3.zig").__mulxc3; const __multc3 = @import("./multc3.zig").__multc3; test { try testMul(f16, __mulhc3); try testMul(f32, __mulsc3); try testMul(f64, __muldc3); try testMul(f80, __mulxc3); try testMul(f128, __multc3); } fn testMul(comptime T: type, comptime f: fn (T, T, T, T) callconv(.C) Complex(T)) !void { { var a: T = 1.0; var b: T = 0.0; var c: T = -1.0; var d: T = 0.0; const result = f(a, b, c, d); try expect(result.real == -1.0); try expect(result.imag == 0.0); } { var a: T = 1.0; var b: T = 0.0; var c: T = -4.0; var d: T = 0.0; const result = f(a, b, c, d); try expect(result.real == -4.0); try expect(result.imag == 0.0); } { // if one operand is an infinity and the other operand is a nonzero finite number or an infinity, // then the result of the * operator is an infinity; var a: T = math.inf(T); var b: T = -math.inf(T); var c: T = 1.0; var d: T = 0.0; const result = f(a, b, c, d); try expect(result.real == math.inf(T)); try expect(result.imag == -math.inf(T)); } { // if one operand is an infinity and the other operand is a nonzero finite number or an infinity, // then the result of the * operator is an infinity; var a: T = math.inf(T); var b: T = -1.0; var c: T = 1.0; var d: T = math.inf(T); const result = f(a, b, c, d); try expect(result.real == math.inf(T)); try expect(result.imag == math.inf(T)); } }