// Copyright 2014 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. //go:generate go run gen.go -output table.go // Package f32 implements some linear algebra and GL helpers for float32s. // // Types defined in this package have methods implementing common // mathematical operations. The common form for these functions is // // func (dst *T) Op(lhs, rhs *T) // // which reads in traditional mathematical notation as // // dst = lhs op rhs. // // It is safe to use the destination address as the left-hand side, // that is, dst *= rhs is dst.Mul(dst, rhs). // // WARNING // // The interface to this package is not stable. It will change considerably. // Only use functions that provide package documentation. Semantics are // non-obvious. Be prepared for the package name to change. package f32 // import "golang.org/x/mobile/f32" import ( "encoding/binary" "fmt" "math" ) type Radian float32 func Cos(x float32) float32 { const n = sinTableLen i := uint32(int32(x * (n / math.Pi))) i += n / 2 i &= 2*n - 1 if i >= n { return -sinTable[i&(n-1)] } return sinTable[i&(n-1)] } func Sin(x float32) float32 { const n = sinTableLen i := uint32(int32(x * (n / math.Pi))) i &= 2*n - 1 if i >= n { return -sinTable[i&(n-1)] } return sinTable[i&(n-1)] } func Sqrt(x float32) float32 { return float32(math.Sqrt(float64(x))) // TODO(crawshaw): implement } func Tan(x float32) float32 { return float32(math.Tan(float64(x))) // TODO(crawshaw): fast version } // Bytes returns the byte representation of float32 values in the given byte // order. byteOrder must be either binary.BigEndian or binary.LittleEndian. func Bytes(byteOrder binary.ByteOrder, values ...float32) []byte { le := false switch byteOrder { case binary.BigEndian: case binary.LittleEndian: le = true default: panic(fmt.Sprintf("invalid byte order %v", byteOrder)) } b := make([]byte, 4*len(values)) for i, v := range values { u := math.Float32bits(v) if le { b[4*i+0] = byte(u >> 0) b[4*i+1] = byte(u >> 8) b[4*i+2] = byte(u >> 16) b[4*i+3] = byte(u >> 24) } else { b[4*i+0] = byte(u >> 24) b[4*i+1] = byte(u >> 16) b[4*i+2] = byte(u >> 8) b[4*i+3] = byte(u >> 0) } } return b }