zig/lib/compiler_rt/fmax.zig
mlugg 0fe3fd01dd
std: update std.builtin.Type fields to follow naming conventions
The compiler actually doesn't need any functional changes for this: Sema
does reification based on the tag indices of `std.builtin.Type` already!
So, no zig1.wasm update is necessary.

This change is necessary to disallow name clashes between fields and
decls on a type, which is a prerequisite of #9938.
2024-08-28 08:39:59 +01:00

72 lines
2.4 KiB
Zig

const std = @import("std");
const builtin = @import("builtin");
const math = std.math;
const arch = builtin.cpu.arch;
const common = @import("common.zig");
pub const panic = common.panic;
comptime {
@export(&__fmaxh, .{ .name = "__fmaxh", .linkage = common.linkage, .visibility = common.visibility });
@export(&fmaxf, .{ .name = "fmaxf", .linkage = common.linkage, .visibility = common.visibility });
@export(&fmax, .{ .name = "fmax", .linkage = common.linkage, .visibility = common.visibility });
@export(&__fmaxx, .{ .name = "__fmaxx", .linkage = common.linkage, .visibility = common.visibility });
if (common.want_ppc_abi) {
@export(&fmaxq, .{ .name = "fmaxf128", .linkage = common.linkage, .visibility = common.visibility });
}
@export(&fmaxq, .{ .name = "fmaxq", .linkage = common.linkage, .visibility = common.visibility });
@export(&fmaxl, .{ .name = "fmaxl", .linkage = common.linkage, .visibility = common.visibility });
}
pub fn __fmaxh(x: f16, y: f16) callconv(.C) f16 {
return generic_fmax(f16, x, y);
}
pub fn fmaxf(x: f32, y: f32) callconv(.C) f32 {
return generic_fmax(f32, x, y);
}
pub fn fmax(x: f64, y: f64) callconv(.C) f64 {
return generic_fmax(f64, x, y);
}
pub fn __fmaxx(x: f80, y: f80) callconv(.C) f80 {
return generic_fmax(f80, x, y);
}
pub fn fmaxq(x: f128, y: f128) callconv(.C) f128 {
return generic_fmax(f128, x, y);
}
pub fn fmaxl(x: c_longdouble, y: c_longdouble) callconv(.C) c_longdouble {
switch (@typeInfo(c_longdouble).float.bits) {
16 => return __fmaxh(x, y),
32 => return fmaxf(x, y),
64 => return fmax(x, y),
80 => return __fmaxx(x, y),
128 => return fmaxq(x, y),
else => @compileError("unreachable"),
}
}
inline fn generic_fmax(comptime T: type, x: T, y: T) T {
if (math.isNan(x))
return y;
if (math.isNan(y))
return x;
return if (x < y) y else x;
}
test "generic_fmax" {
inline for ([_]type{ f32, f64, c_longdouble, f80, f128 }) |T| {
const nan_val = math.nan(T);
try std.testing.expect(math.isNan(generic_fmax(T, nan_val, nan_val)));
try std.testing.expectEqual(@as(T, 1.0), generic_fmax(T, nan_val, 1.0));
try std.testing.expectEqual(@as(T, 1.0), generic_fmax(T, 1.0, nan_val));
try std.testing.expectEqual(@as(T, 10.0), generic_fmax(T, 1.0, 10.0));
try std.testing.expectEqual(@as(T, 1.0), generic_fmax(T, 1.0, -1.0));
}
}