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zig/lib/std/special/compiler_rt/truncXfYf2_test.zig
Andrew Kelley d29871977f remove redundant license headers from zig standard library 
We already have a LICENSE file that covers the Zig Standard Library. We
no longer need to remind everyone that the license is MIT in every single
file.

Previously this was introduced to clarify the situation for a fork of
Zig that made Zig's LICENSE file harder to find, and replaced it with
their own license that required annual payments to their company.
However that fork now appears to be dead. So there is no need to
reinforce the copyright notice in every single file.
2021-08-24 12:25:09 -07:00

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const __truncsfhf2 = @import("truncXfYf2.zig").__truncsfhf2;
fn test__truncsfhf2(a: u32, expected: u16) !void {
const actual = __truncsfhf2(@bitCast(f32, a));
if (actual == expected) {
return;
}
return error.TestFailure;
}
test "truncsfhf2" {
try test__truncsfhf2(0x7fc00000, 0x7e00); // qNaN
try test__truncsfhf2(0x7fe00000, 0x7f00); // sNaN
try test__truncsfhf2(0, 0); // 0
try test__truncsfhf2(0x80000000, 0x8000); // -0
try test__truncsfhf2(0x7f800000, 0x7c00); // inf
try test__truncsfhf2(0xff800000, 0xfc00); // -inf
try test__truncsfhf2(0x477ff000, 0x7c00); // 65520 -> inf
try test__truncsfhf2(0xc77ff000, 0xfc00); // -65520 -> -inf
try test__truncsfhf2(0x71cc3892, 0x7c00); // 0x1.987124876876324p+100 -> inf
try test__truncsfhf2(0xf1cc3892, 0xfc00); // -0x1.987124876876324p+100 -> -inf
try test__truncsfhf2(0x38800000, 0x0400); // normal (min), 2**-14
try test__truncsfhf2(0xb8800000, 0x8400); // normal (min), -2**-14
try test__truncsfhf2(0x477fe000, 0x7bff); // normal (max), 65504
try test__truncsfhf2(0xc77fe000, 0xfbff); // normal (max), -65504
try test__truncsfhf2(0x477fe100, 0x7bff); // normal, 65505 -> 65504
try test__truncsfhf2(0xc77fe100, 0xfbff); // normal, -65505 -> -65504
try test__truncsfhf2(0x477fef00, 0x7bff); // normal, 65519 -> 65504
try test__truncsfhf2(0xc77fef00, 0xfbff); // normal, -65519 -> -65504
try test__truncsfhf2(0x3f802000, 0x3c01); // normal, 1 + 2**-10
try test__truncsfhf2(0xbf802000, 0xbc01); // normal, -1 - 2**-10
try test__truncsfhf2(0x3eaaa000, 0x3555); // normal, approx. 1/3
try test__truncsfhf2(0xbeaaa000, 0xb555); // normal, approx. -1/3
try test__truncsfhf2(0x40490fdb, 0x4248); // normal, 3.1415926535
try test__truncsfhf2(0xc0490fdb, 0xc248); // normal, -3.1415926535
try test__truncsfhf2(0x45cc3892, 0x6e62); // normal, 0x1.987124876876324p+12
try test__truncsfhf2(0x3f800000, 0x3c00); // normal, 1
try test__truncsfhf2(0x38800000, 0x0400); // normal, 0x1.0p-14
try test__truncsfhf2(0x33800000, 0x0001); // denormal (min), 2**-24
try test__truncsfhf2(0xb3800000, 0x8001); // denormal (min), -2**-24
try test__truncsfhf2(0x387fc000, 0x03ff); // denormal (max), 2**-14 - 2**-24
try test__truncsfhf2(0xb87fc000, 0x83ff); // denormal (max), -2**-14 + 2**-24
try test__truncsfhf2(0x35800000, 0x0010); // denormal, 0x1.0p-20
try test__truncsfhf2(0x33280000, 0x0001); // denormal, 0x1.5p-25 -> 0x1.0p-24
try test__truncsfhf2(0x33000000, 0x0000); // 0x1.0p-25 -> zero
}
const __truncdfhf2 = @import("truncXfYf2.zig").__truncdfhf2;
fn test__truncdfhf2(a: f64, expected: u16) void {
const rep = @bitCast(u16, __truncdfhf2(a));
if (rep == expected) {
return;
}
// test other possible NaN representation(signal NaN)
else if (expected == 0x7e00) {
if ((rep & 0x7c00) == 0x7c00 and (rep & 0x3ff) > 0) {
return;
}
}
@panic("__truncdfhf2 test failure");
}
fn test__truncdfhf2_raw(a: u64, expected: u16) void {
const actual = __truncdfhf2(@bitCast(f64, a));
if (actual == expected) {
return;
}
@panic("__truncdfhf2 test failure");
}
test "truncdfhf2" {
test__truncdfhf2_raw(0x7ff8000000000000, 0x7e00); // qNaN
test__truncdfhf2_raw(0x7ff0000000008000, 0x7e00); // NaN
test__truncdfhf2_raw(0x7ff0000000000000, 0x7c00); //inf
test__truncdfhf2_raw(0xfff0000000000000, 0xfc00); // -inf
test__truncdfhf2(0.0, 0x0); // zero
test__truncdfhf2_raw(0x80000000 << 32, 0x8000); // -zero
test__truncdfhf2(3.1415926535, 0x4248);
test__truncdfhf2(-3.1415926535, 0xc248);
test__truncdfhf2(0x1.987124876876324p+1000, 0x7c00);
test__truncdfhf2(0x1.987124876876324p+12, 0x6e62);
test__truncdfhf2(0x1.0p+0, 0x3c00);
test__truncdfhf2(0x1.0p-14, 0x0400);
// denormal
test__truncdfhf2(0x1.0p-20, 0x0010);
test__truncdfhf2(0x1.0p-24, 0x0001);
test__truncdfhf2(-0x1.0p-24, 0x8001);
test__truncdfhf2(0x1.5p-25, 0x0001);
// and back to zero
test__truncdfhf2(0x1.0p-25, 0x0000);
test__truncdfhf2(-0x1.0p-25, 0x8000);
// max (precise)
test__truncdfhf2(65504.0, 0x7bff);
// max (rounded)
test__truncdfhf2(65519.0, 0x7bff);
// max (to +inf)
test__truncdfhf2(65520.0, 0x7c00);
test__truncdfhf2(-65520.0, 0xfc00);
test__truncdfhf2(65536.0, 0x7c00);
}
const __trunctfsf2 = @import("truncXfYf2.zig").__trunctfsf2;
fn test__trunctfsf2(a: f128, expected: u32) void {
const x = __trunctfsf2(a);
const rep = @bitCast(u32, x);
if (rep == expected) {
return;
}
// test other possible NaN representation(signal NaN)
else if (expected == 0x7fc00000) {
if ((rep & 0x7f800000) == 0x7f800000 and (rep & 0x7fffff) > 0) {
return;
}
}
@panic("__trunctfsf2 test failure");
}
test "trunctfsf2" {
// qnan
test__trunctfsf2(@bitCast(f128, @as(u128, 0x7fff800000000000 << 64)), 0x7fc00000);
// nan
test__trunctfsf2(@bitCast(f128, @as(u128, (0x7fff000000000000 | (0x810000000000 & 0xffffffffffff)) << 64)), 0x7fc08000);
// inf
test__trunctfsf2(@bitCast(f128, @as(u128, 0x7fff000000000000 << 64)), 0x7f800000);
// zero
test__trunctfsf2(0.0, 0x0);
test__trunctfsf2(0x1.23a2abb4a2ddee355f36789abcdep+5, 0x4211d156);
test__trunctfsf2(0x1.e3d3c45bd3abfd98b76a54cc321fp-9, 0x3b71e9e2);
test__trunctfsf2(0x1.234eebb5faa678f4488693abcdefp+4534, 0x7f800000);
test__trunctfsf2(0x1.edcba9bb8c76a5a43dd21f334634p-435, 0x0);
}
const __trunctfdf2 = @import("truncXfYf2.zig").__trunctfdf2;
fn test__trunctfdf2(a: f128, expected: u64) void {
const x = __trunctfdf2(a);
const rep = @bitCast(u64, x);
if (rep == expected) {
return;
}
// test other possible NaN representation(signal NaN)
else if (expected == 0x7ff8000000000000) {
if ((rep & 0x7ff0000000000000) == 0x7ff0000000000000 and (rep & 0xfffffffffffff) > 0) {
return;
}
}
@panic("__trunctfsf2 test failure");
}
test "trunctfdf2" {
// qnan
test__trunctfdf2(@bitCast(f128, @as(u128, 0x7fff800000000000 << 64)), 0x7ff8000000000000);
// nan
test__trunctfdf2(@bitCast(f128, @as(u128, (0x7fff000000000000 | (0x810000000000 & 0xffffffffffff)) << 64)), 0x7ff8100000000000);
// inf
test__trunctfdf2(@bitCast(f128, @as(u128, 0x7fff000000000000 << 64)), 0x7ff0000000000000);
// zero
test__trunctfdf2(0.0, 0x0);
test__trunctfdf2(0x1.af23456789bbaaab347645365cdep+5, 0x404af23456789bbb);
test__trunctfdf2(0x1.dedafcff354b6ae9758763545432p-9, 0x3f6dedafcff354b7);
test__trunctfdf2(0x1.2f34dd5f437e849b4baab754cdefp+4534, 0x7ff0000000000000);
test__trunctfdf2(0x1.edcbff8ad76ab5bf46463233214fp-435, 0x24cedcbff8ad76ab);
}
const __truncdfsf2 = @import("truncXfYf2.zig").__truncdfsf2;
fn test__truncdfsf2(a: f64, expected: u32) void {
const x = __truncdfsf2(a);
const rep = @bitCast(u32, x);
if (rep == expected) {
return;
}
// test other possible NaN representation(signal NaN)
else if (expected == 0x7fc00000) {
if ((rep & 0x7f800000) == 0x7f800000 and (rep & 0x7fffff) > 0) {
return;
}
}
@import("std").debug.warn("got 0x{x} wanted 0x{x}\n", .{ rep, expected });
@panic("__trunctfsf2 test failure");
}
test "truncdfsf2" {
// nan & qnan
test__truncdfsf2(@bitCast(f64, @as(u64, 0x7ff8000000000000)), 0x7fc00000);
test__truncdfsf2(@bitCast(f64, @as(u64, 0x7ff0000000000001)), 0x7fc00000);
// inf
test__truncdfsf2(@bitCast(f64, @as(u64, 0x7ff0000000000000)), 0x7f800000);
test__truncdfsf2(@bitCast(f64, @as(u64, 0xfff0000000000000)), 0xff800000);
test__truncdfsf2(0.0, 0x0);
test__truncdfsf2(1.0, 0x3f800000);
test__truncdfsf2(-1.0, 0xbf800000);
// huge number becomes inf
test__truncdfsf2(340282366920938463463374607431768211456.0, 0x7f800000);
}
const __trunctfhf2 = @import("truncXfYf2.zig").__trunctfhf2;
fn test__trunctfhf2(a: f128, expected: u16) void {
const x = __trunctfhf2(a);
const rep = @bitCast(u16, x);
if (rep == expected) {
return;
}
@import("std").debug.warn("got 0x{x} wanted 0x{x}\n", .{ rep, expected });
@panic("__trunctfhf2 test failure");
}
test "trunctfhf2" {
// qNaN
test__trunctfhf2(@bitCast(f128, @as(u128, 0x7fff8000000000000000000000000000)), 0x7e00);
// NaN
test__trunctfhf2(@bitCast(f128, @as(u128, 0x7fff0000000000000000000000000001)), 0x7e00);
// inf
test__trunctfhf2(@bitCast(f128, @as(u128, 0x7fff0000000000000000000000000000)), 0x7c00);
test__trunctfhf2(-@bitCast(f128, @as(u128, 0x7fff0000000000000000000000000000)), 0xfc00);
// zero
test__trunctfhf2(0.0, 0x0);
test__trunctfhf2(-0.0, 0x8000);
test__trunctfhf2(3.1415926535, 0x4248);
test__trunctfhf2(-3.1415926535, 0xc248);
test__trunctfhf2(0x1.987124876876324p+100, 0x7c00);
test__trunctfhf2(0x1.987124876876324p+12, 0x6e62);
test__trunctfhf2(0x1.0p+0, 0x3c00);
test__trunctfhf2(0x1.0p-14, 0x0400);
// denormal
test__trunctfhf2(0x1.0p-20, 0x0010);
test__trunctfhf2(0x1.0p-24, 0x0001);
test__trunctfhf2(-0x1.0p-24, 0x8001);
test__trunctfhf2(0x1.5p-25, 0x0001);
// and back to zero
test__trunctfhf2(0x1.0p-25, 0x0000);
test__trunctfhf2(-0x1.0p-25, 0x8000);
// max (precise)
test__trunctfhf2(65504.0, 0x7bff);
// max (rounded)
test__trunctfhf2(65519.0, 0x7bff);
// max (to +inf)
test__trunctfhf2(65520.0, 0x7c00);
test__trunctfhf2(65536.0, 0x7c00);
test__trunctfhf2(-65520.0, 0xfc00);
test__trunctfhf2(0x1.23a2abb4a2ddee355f36789abcdep+5, 0x508f);
test__trunctfhf2(0x1.e3d3c45bd3abfd98b76a54cc321fp-9, 0x1b8f);
test__trunctfhf2(0x1.234eebb5faa678f4488693abcdefp+453, 0x7c00);
test__trunctfhf2(0x1.edcba9bb8c76a5a43dd21f334634p-43, 0x0);
}
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