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go/test/bench/go1/fasta_test.go
Dave Cheney 166dab6993 test/bench/go1: reduce fasta data size for linux/arm
As discussed on golang-dev, reduce the size of the fasta
dataset to make it possible to run the go1 benchmarks on
small ARM systems.

Also, remove the 25m suffix from fasta data and Revcomp.

linux/arm: pandaboard OMAP4

BenchmarkBinaryTree17          1        70892426000 ns/op
BenchmarkFannkuch11            1        35712066000 ns/op
BenchmarkGobDecode            10         137146000 ns/op           5.60 MB/s
BenchmarkGobEncode            50          64953000 ns/op          11.82 MB/s
BenchmarkGzip          1        5675690000 ns/op           3.42 MB/s
BenchmarkGunzip        1        1207001000 ns/op          16.08 MB/s
BenchmarkJSONEncode            5         860424800 ns/op           2.26 MB/s
BenchmarkJSONDecode            1        3321839000 ns/op           0.58 MB/s
BenchmarkMandelbrot200        50          45893560 ns/op
BenchmarkRevcomp              10         135220300 ns/op          18.80 MB/s
BenchmarkTemplate              1        6385681000 ns/op           0.30 MB/s

R=rsc, minux.ma, dsymonds
CC=golang-dev
https://golang.org/cl/6278048
2012-06-06 07:49:58 +10:00

180 lines
3.6 KiB
Go

// Copyright 2011 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.
package go1
import "runtime"
// Not a benchmark; input for revcomp.
var fastabytes = makefasta()
func makefasta() []byte {
var n int = 25e6
if runtime.GOARCH == "arm" {
// TODO(dfc) remove this limitation after precise gc.
// A value of 25e6 consumes 465mb of heap on 32bit
// platforms, which is too much for most ARM systems.
// A value of 25e5 produces a memory layout that
// confuses the gc on 32bit platforms. So 25e4 it is.
n = 25e4
}
return fasta(n)
}
func fasta(n int) []byte {
out := make(fastaBuffer, 0, 11*n)
iub := []fastaAcid{
{prob: 0.27, sym: 'a'},
{prob: 0.12, sym: 'c'},
{prob: 0.12, sym: 'g'},
{prob: 0.27, sym: 't'},
{prob: 0.02, sym: 'B'},
{prob: 0.02, sym: 'D'},
{prob: 0.02, sym: 'H'},
{prob: 0.02, sym: 'K'},
{prob: 0.02, sym: 'M'},
{prob: 0.02, sym: 'N'},
{prob: 0.02, sym: 'R'},
{prob: 0.02, sym: 'S'},
{prob: 0.02, sym: 'V'},
{prob: 0.02, sym: 'W'},
{prob: 0.02, sym: 'Y'},
}
homosapiens := []fastaAcid{
{prob: 0.3029549426680, sym: 'a'},
{prob: 0.1979883004921, sym: 'c'},
{prob: 0.1975473066391, sym: 'g'},
{prob: 0.3015094502008, sym: 't'},
}
alu := []byte(
"GGCCGGGCGCGGTGGCTCACGCCTGTAATCCCAGCACTTTGG" +
"GAGGCCGAGGCGGGCGGATCACCTGAGGTCAGGAGTTCGAGA" +
"CCAGCCTGGCCAACATGGTGAAACCCCGTCTCTACTAAAAAT" +
"ACAAAAATTAGCCGGGCGTGGTGGCGCGCGCCTGTAATCCCA" +
"GCTACTCGGGAGGCTGAGGCAGGAGAATCGCTTGAACCCGGG" +
"AGGCGGAGGTTGCAGTGAGCCGAGATCGCGCCACTGCACTCC" +
"AGCCTGGGCGACAGAGCGAGACTCCGTCTCAAAAA")
out.WriteString(">ONE Homo sapiens alu\n")
fastaRepeat(&out, alu, 2*n)
out.WriteString(">TWO IUB ambiguity codes\n")
fastaRandom(&out, iub, 3*n)
out.WriteString(">THREE Homo sapiens frequency\n")
fastaRandom(&out, homosapiens, 5*n)
return out
}
type fastaBuffer []byte
func (b *fastaBuffer) Flush() {
panic("flush")
}
func (b *fastaBuffer) WriteString(s string) {
p := b.NextWrite(len(s))
copy(p, s)
}
func (b *fastaBuffer) NextWrite(n int) []byte {
p := *b
if len(p)+n > cap(p) {
b.Flush()
p = *b
}
out := p[len(p) : len(p)+n]
*b = p[:len(p)+n]
return out
}
const fastaLine = 60
func fastaRepeat(out *fastaBuffer, alu []byte, n int) {
buf := append(alu, alu...)
off := 0
for n > 0 {
m := n
if m > fastaLine {
m = fastaLine
}
buf1 := out.NextWrite(m + 1)
copy(buf1, buf[off:])
buf1[m] = '\n'
if off += m; off >= len(alu) {
off -= len(alu)
}
n -= m
}
}
const (
fastaLookupSize = 4096
fastaLookupScale float64 = fastaLookupSize - 1
)
var fastaRand uint32 = 42
type fastaAcid struct {
sym byte
prob float64
cprob float64
next *fastaAcid
}
func fastaComputeLookup(acid []fastaAcid) *[fastaLookupSize]*fastaAcid {
var lookup [fastaLookupSize]*fastaAcid
var p float64
for i := range acid {
p += acid[i].prob
acid[i].cprob = p * fastaLookupScale
if i > 0 {
acid[i-1].next = &acid[i]
}
}
acid[len(acid)-1].cprob = 1.0 * fastaLookupScale
j := 0
for i := range lookup {
for acid[j].cprob < float64(i) {
j++
}
lookup[i] = &acid[j]
}
return &lookup
}
func fastaRandom(out *fastaBuffer, acid []fastaAcid, n int) {
const (
IM = 139968
IA = 3877
IC = 29573
)
lookup := fastaComputeLookup(acid)
for n > 0 {
m := n
if m > fastaLine {
m = fastaLine
}
buf := out.NextWrite(m + 1)
f := fastaLookupScale / IM
myrand := fastaRand
for i := 0; i < m; i++ {
myrand = (myrand*IA + IC) % IM
r := float64(int(myrand)) * f
a := lookup[int(r)]
for a.cprob < r {
a = a.next
}
buf[i] = a.sym
}
fastaRand = myrand
buf[m] = '\n'
n -= m
}
}