8dc2499aa6
gotools/ * Makefile.am (go_cmd_cgo_files): Add ast_go118.go (check-go-tool): Copy golang.org/x/tools directories. * Makefile.in: Regenerate. Reviewed-on: https://go-review.googlesource.com/c/gofrontend/+/384695
346 lines
9.3 KiB
Go
346 lines
9.3 KiB
Go
// Copyright 2016 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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//go:build ignore
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// Generate tables for small malloc size classes.
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//
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// See malloc.go for overview.
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//
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// The size classes are chosen so that rounding an allocation
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// request up to the next size class wastes at most 12.5% (1.125x).
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//
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// Each size class has its own page count that gets allocated
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// and chopped up when new objects of the size class are needed.
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// That page count is chosen so that chopping up the run of
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// pages into objects of the given size wastes at most 12.5% (1.125x)
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// of the memory. It is not necessary that the cutoff here be
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// the same as above.
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//
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// The two sources of waste multiply, so the worst possible case
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// for the above constraints would be that allocations of some
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// size might have a 26.6% (1.266x) overhead.
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// In practice, only one of the wastes comes into play for a
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// given size (sizes < 512 waste mainly on the round-up,
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// sizes > 512 waste mainly on the page chopping).
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// For really small sizes, alignment constraints force the
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// overhead higher.
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package main
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import (
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"bytes"
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"flag"
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"fmt"
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"go/format"
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"io"
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"log"
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"math"
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"math/bits"
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"os"
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)
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// Generate msize.go
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var stdout = flag.Bool("stdout", false, "write to stdout instead of sizeclasses.go")
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func main() {
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flag.Parse()
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var b bytes.Buffer
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fmt.Fprintln(&b, "// Code generated by mksizeclasses.go; DO NOT EDIT.")
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fmt.Fprintln(&b, "//go:generate go run mksizeclasses.go")
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fmt.Fprintln(&b)
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fmt.Fprintln(&b, "package runtime")
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classes := makeClasses()
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printComment(&b, classes)
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printClasses(&b, classes)
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out, err := format.Source(b.Bytes())
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if err != nil {
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log.Fatal(err)
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}
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if *stdout {
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_, err = os.Stdout.Write(out)
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} else {
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err = os.WriteFile("sizeclasses.go", out, 0666)
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}
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if err != nil {
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log.Fatal(err)
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}
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}
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const (
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// Constants that we use and will transfer to the runtime.
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maxSmallSize = 32 << 10
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smallSizeDiv = 8
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smallSizeMax = 1024
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largeSizeDiv = 128
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pageShift = 13
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// Derived constants.
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pageSize = 1 << pageShift
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)
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type class struct {
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size int // max size
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npages int // number of pages
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}
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func powerOfTwo(x int) bool {
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return x != 0 && x&(x-1) == 0
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}
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func makeClasses() []class {
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var classes []class
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classes = append(classes, class{}) // class #0 is a dummy entry
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align := 8
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for size := align; size <= maxSmallSize; size += align {
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if powerOfTwo(size) { // bump alignment once in a while
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if size >= 2048 {
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align = 256
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} else if size >= 128 {
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align = size / 8
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} else if size >= 32 {
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align = 16 // heap bitmaps assume 16 byte alignment for allocations >= 32 bytes.
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}
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}
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if !powerOfTwo(align) {
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panic("incorrect alignment")
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}
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// Make the allocnpages big enough that
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// the leftover is less than 1/8 of the total,
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// so wasted space is at most 12.5%.
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allocsize := pageSize
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for allocsize%size > allocsize/8 {
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allocsize += pageSize
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}
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npages := allocsize / pageSize
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// If the previous sizeclass chose the same
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// allocation size and fit the same number of
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// objects into the page, we might as well
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// use just this size instead of having two
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// different sizes.
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if len(classes) > 1 && npages == classes[len(classes)-1].npages && allocsize/size == allocsize/classes[len(classes)-1].size {
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classes[len(classes)-1].size = size
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continue
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}
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classes = append(classes, class{size: size, npages: npages})
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}
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// Increase object sizes if we can fit the same number of larger objects
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// into the same number of pages. For example, we choose size 8448 above
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// with 6 objects in 7 pages. But we can well use object size 9472,
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// which is also 6 objects in 7 pages but +1024 bytes (+12.12%).
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// We need to preserve at least largeSizeDiv alignment otherwise
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// sizeToClass won't work.
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for i := range classes {
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if i == 0 {
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continue
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}
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c := &classes[i]
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psize := c.npages * pageSize
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new_size := (psize / (psize / c.size)) &^ (largeSizeDiv - 1)
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if new_size > c.size {
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c.size = new_size
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}
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}
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if len(classes) != 68 {
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panic("number of size classes has changed")
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}
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for i := range classes {
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computeDivMagic(&classes[i])
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}
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return classes
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}
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// computeDivMagic checks that the division required to compute object
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// index from span offset can be computed using 32-bit multiplication.
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// n / c.size is implemented as (n * (^uint32(0)/uint32(c.size) + 1)) >> 32
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// for all 0 <= n <= c.npages * pageSize
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func computeDivMagic(c *class) {
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// divisor
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d := c.size
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if d == 0 {
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return
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}
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// maximum input value for which the formula needs to work.
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max := c.npages * pageSize
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// As reported in [1], if n and d are unsigned N-bit integers, we
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// can compute n / d as ⌊n * c / 2^F⌋, where c is ⌈2^F / d⌉ and F is
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// computed with:
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//
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// Algorithm 2: Algorithm to select the number of fractional bits
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// and the scaled approximate reciprocal in the case of unsigned
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// integers.
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//
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// if d is a power of two then
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// Let F ← log₂(d) and c = 1.
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// else
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// Let F ← N + L where L is the smallest integer
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// such that d ≤ (2^(N+L) mod d) + 2^L.
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// end if
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//
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// [1] "Faster Remainder by Direct Computation: Applications to
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// Compilers and Software Libraries" Daniel Lemire, Owen Kaser,
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// Nathan Kurz arXiv:1902.01961
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//
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// To minimize the risk of introducing errors, we implement the
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// algorithm exactly as stated, rather than trying to adapt it to
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// fit typical Go idioms.
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N := bits.Len(uint(max))
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var F int
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if powerOfTwo(d) {
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F = int(math.Log2(float64(d)))
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if d != 1<<F {
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panic("imprecise log2")
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}
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} else {
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for L := 0; ; L++ {
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if d <= ((1<<(N+L))%d)+(1<<L) {
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F = N + L
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break
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}
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}
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}
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// Also, noted in the paper, F is the smallest number of fractional
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// bits required. We use 32 bits, because it works for all size
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// classes and is fast on all CPU architectures that we support.
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if F > 32 {
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fmt.Printf("d=%d max=%d N=%d F=%d\n", c.size, max, N, F)
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panic("size class requires more than 32 bits of precision")
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}
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// Brute force double-check with the exact computation that will be
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// done by the runtime.
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m := ^uint32(0)/uint32(c.size) + 1
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for n := 0; n <= max; n++ {
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if uint32((uint64(n)*uint64(m))>>32) != uint32(n/c.size) {
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fmt.Printf("d=%d max=%d m=%d n=%d\n", d, max, m, n)
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panic("bad 32-bit multiply magic")
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}
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}
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}
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func printComment(w io.Writer, classes []class) {
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fmt.Fprintf(w, "// %-5s %-9s %-10s %-7s %-10s %-9s %-9s\n", "class", "bytes/obj", "bytes/span", "objects", "tail waste", "max waste", "min align")
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prevSize := 0
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var minAligns [pageShift + 1]int
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for i, c := range classes {
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if i == 0 {
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continue
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}
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spanSize := c.npages * pageSize
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objects := spanSize / c.size
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tailWaste := spanSize - c.size*(spanSize/c.size)
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maxWaste := float64((c.size-prevSize-1)*objects+tailWaste) / float64(spanSize)
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alignBits := bits.TrailingZeros(uint(c.size))
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if alignBits > pageShift {
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// object alignment is capped at page alignment
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alignBits = pageShift
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}
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for i := range minAligns {
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if i > alignBits {
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minAligns[i] = 0
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} else if minAligns[i] == 0 {
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minAligns[i] = c.size
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}
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}
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prevSize = c.size
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fmt.Fprintf(w, "// %5d %9d %10d %7d %10d %8.2f%% %9d\n", i, c.size, spanSize, objects, tailWaste, 100*maxWaste, 1<<alignBits)
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}
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fmt.Fprintf(w, "\n")
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fmt.Fprintf(w, "// %-9s %-4s %-12s\n", "alignment", "bits", "min obj size")
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for bits, size := range minAligns {
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if size == 0 {
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break
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}
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if bits+1 < len(minAligns) && size == minAligns[bits+1] {
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continue
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}
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fmt.Fprintf(w, "// %9d %4d %12d\n", 1<<bits, bits, size)
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}
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fmt.Fprintf(w, "\n")
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}
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func printClasses(w io.Writer, classes []class) {
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fmt.Fprintln(w, "const (")
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fmt.Fprintf(w, "_MaxSmallSize = %d\n", maxSmallSize)
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fmt.Fprintf(w, "smallSizeDiv = %d\n", smallSizeDiv)
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fmt.Fprintf(w, "smallSizeMax = %d\n", smallSizeMax)
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fmt.Fprintf(w, "largeSizeDiv = %d\n", largeSizeDiv)
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fmt.Fprintf(w, "_NumSizeClasses = %d\n", len(classes))
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fmt.Fprintf(w, "_PageShift = %d\n", pageShift)
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fmt.Fprintln(w, ")")
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fmt.Fprint(w, "var class_to_size = [_NumSizeClasses]uint16 {")
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for _, c := range classes {
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fmt.Fprintf(w, "%d,", c.size)
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}
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fmt.Fprintln(w, "}")
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fmt.Fprint(w, "var class_to_allocnpages = [_NumSizeClasses]uint8 {")
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for _, c := range classes {
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fmt.Fprintf(w, "%d,", c.npages)
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}
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fmt.Fprintln(w, "}")
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fmt.Fprint(w, "var class_to_divmagic = [_NumSizeClasses]uint32 {")
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for _, c := range classes {
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if c.size == 0 {
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fmt.Fprintf(w, "0,")
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continue
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}
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fmt.Fprintf(w, "^uint32(0)/%d+1,", c.size)
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}
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fmt.Fprintln(w, "}")
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// map from size to size class, for small sizes.
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sc := make([]int, smallSizeMax/smallSizeDiv+1)
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for i := range sc {
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size := i * smallSizeDiv
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for j, c := range classes {
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if c.size >= size {
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sc[i] = j
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break
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}
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}
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}
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fmt.Fprint(w, "var size_to_class8 = [smallSizeMax/smallSizeDiv+1]uint8 {")
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for _, v := range sc {
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fmt.Fprintf(w, "%d,", v)
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}
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fmt.Fprintln(w, "}")
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// map from size to size class, for large sizes.
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sc = make([]int, (maxSmallSize-smallSizeMax)/largeSizeDiv+1)
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for i := range sc {
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size := smallSizeMax + i*largeSizeDiv
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for j, c := range classes {
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if c.size >= size {
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sc[i] = j
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break
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}
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}
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}
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fmt.Fprint(w, "var size_to_class128 = [(_MaxSmallSize-smallSizeMax)/largeSizeDiv+1]uint8 {")
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for _, v := range sc {
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fmt.Fprintf(w, "%d,", v)
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}
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fmt.Fprintln(w, "}")
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}
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