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go/src/runtime/mem_linux.go
Austin Clements 6dda7b2f5f runtime: don't hard-code physical page size
Now that the runtime fetches the true physical page size from the OS,
make the physical page size used by heap growth a variable instead of
a constant. This isn't used in any performance-critical paths, so it
shouldn't be an issue.

sys.PhysPageSize is also renamed to sys.DefaultPhysPageSize to make it
clear that it's not necessarily the true page size. There are no uses
of this constant any more, but we'll keep it around for now.

Updates #12480 and #10180.

Change-Id: I6c23b9df860db309c38c8287a703c53817754f03
Reviewed-on: https://go-review.googlesource.com/25022
Run-TryBot: Austin Clements <austin@google.com>
TryBot-Result: Gobot Gobot <gobot@golang.org>
Reviewed-by: Rick Hudson <rlh@golang.org>
2016-09-06 21:05:53 +00:00

233 lines
7.4 KiB
Go

// Copyright 2010 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 runtime
import (
"runtime/internal/sys"
"unsafe"
)
const (
_EACCES = 13
_EINVAL = 22
)
// NOTE: vec must be just 1 byte long here.
// Mincore returns ENOMEM if any of the pages are unmapped,
// but we want to know that all of the pages are unmapped.
// To make these the same, we can only ask about one page
// at a time. See golang.org/issue/7476.
var addrspace_vec [1]byte
func addrspace_free(v unsafe.Pointer, n uintptr) bool {
for off := uintptr(0); off < n; off += physPageSize {
// Use a length of 1 byte, which the kernel will round
// up to one physical page regardless of the true
// physical page size.
errval := mincore(unsafe.Pointer(uintptr(v)+off), 1, &addrspace_vec[0])
if errval == -_EINVAL {
// Address is not a multiple of the physical
// page size. Shouldn't happen, but just ignore it.
continue
}
// ENOMEM means unmapped, which is what we want.
// Anything else we assume means the pages are mapped.
if errval != -_ENOMEM {
return false
}
}
return true
}
func mmap_fixed(v unsafe.Pointer, n uintptr, prot, flags, fd int32, offset uint32) unsafe.Pointer {
p := mmap(v, n, prot, flags, fd, offset)
// On some systems, mmap ignores v without
// MAP_FIXED, so retry if the address space is free.
if p != v && addrspace_free(v, n) {
if uintptr(p) > 4096 {
munmap(p, n)
}
p = mmap(v, n, prot, flags|_MAP_FIXED, fd, offset)
}
return p
}
// Don't split the stack as this method may be invoked without a valid G, which
// prevents us from allocating more stack.
//go:nosplit
func sysAlloc(n uintptr, sysStat *uint64) unsafe.Pointer {
p := mmap(nil, n, _PROT_READ|_PROT_WRITE, _MAP_ANON|_MAP_PRIVATE, -1, 0)
if uintptr(p) < 4096 {
if uintptr(p) == _EACCES {
print("runtime: mmap: access denied\n")
exit(2)
}
if uintptr(p) == _EAGAIN {
print("runtime: mmap: too much locked memory (check 'ulimit -l').\n")
exit(2)
}
return nil
}
mSysStatInc(sysStat, n)
return p
}
func sysUnused(v unsafe.Pointer, n uintptr) {
// By default, Linux's "transparent huge page" support will
// merge pages into a huge page if there's even a single
// present regular page, undoing the effects of the DONTNEED
// below. On amd64, that means khugepaged can turn a single
// 4KB page to 2MB, bloating the process's RSS by as much as
// 512X. (See issue #8832 and Linux kernel bug
// https://bugzilla.kernel.org/show_bug.cgi?id=93111)
//
// To work around this, we explicitly disable transparent huge
// pages when we release pages of the heap. However, we have
// to do this carefully because changing this flag tends to
// split the VMA (memory mapping) containing v in to three
// VMAs in order to track the different values of the
// MADV_NOHUGEPAGE flag in the different regions. There's a
// default limit of 65530 VMAs per address space (sysctl
// vm.max_map_count), so we must be careful not to create too
// many VMAs (see issue #12233).
//
// Since huge pages are huge, there's little use in adjusting
// the MADV_NOHUGEPAGE flag on a fine granularity, so we avoid
// exploding the number of VMAs by only adjusting the
// MADV_NOHUGEPAGE flag on a large granularity. This still
// gets most of the benefit of huge pages while keeping the
// number of VMAs under control. With hugePageSize = 2MB, even
// a pessimal heap can reach 128GB before running out of VMAs.
if sys.HugePageSize != 0 {
var s uintptr = sys.HugePageSize // division by constant 0 is a compile-time error :(
// If it's a large allocation, we want to leave huge
// pages enabled. Hence, we only adjust the huge page
// flag on the huge pages containing v and v+n-1, and
// only if those aren't aligned.
var head, tail uintptr
if uintptr(v)%s != 0 {
// Compute huge page containing v.
head = uintptr(v) &^ (s - 1)
}
if (uintptr(v)+n)%s != 0 {
// Compute huge page containing v+n-1.
tail = (uintptr(v) + n - 1) &^ (s - 1)
}
// Note that madvise will return EINVAL if the flag is
// already set, which is quite likely. We ignore
// errors.
if head != 0 && head+sys.HugePageSize == tail {
// head and tail are different but adjacent,
// so do this in one call.
madvise(unsafe.Pointer(head), 2*sys.HugePageSize, _MADV_NOHUGEPAGE)
} else {
// Advise the huge pages containing v and v+n-1.
if head != 0 {
madvise(unsafe.Pointer(head), sys.HugePageSize, _MADV_NOHUGEPAGE)
}
if tail != 0 && tail != head {
madvise(unsafe.Pointer(tail), sys.HugePageSize, _MADV_NOHUGEPAGE)
}
}
}
if uintptr(v)&(physPageSize-1) != 0 || n&(physPageSize-1) != 0 {
// madvise will round this to any physical page
// *covered* by this range, so an unaligned madvise
// will release more memory than intended.
throw("unaligned sysUnused")
}
madvise(v, n, _MADV_DONTNEED)
}
func sysUsed(v unsafe.Pointer, n uintptr) {
if sys.HugePageSize != 0 {
// Partially undo the NOHUGEPAGE marks from sysUnused
// for whole huge pages between v and v+n. This may
// leave huge pages off at the end points v and v+n
// even though allocations may cover these entire huge
// pages. We could detect this and undo NOHUGEPAGE on
// the end points as well, but it's probably not worth
// the cost because when neighboring allocations are
// freed sysUnused will just set NOHUGEPAGE again.
var s uintptr = sys.HugePageSize
// Round v up to a huge page boundary.
beg := (uintptr(v) + (s - 1)) &^ (s - 1)
// Round v+n down to a huge page boundary.
end := (uintptr(v) + n) &^ (s - 1)
if beg < end {
madvise(unsafe.Pointer(beg), end-beg, _MADV_HUGEPAGE)
}
}
}
// Don't split the stack as this function may be invoked without a valid G,
// which prevents us from allocating more stack.
//go:nosplit
func sysFree(v unsafe.Pointer, n uintptr, sysStat *uint64) {
mSysStatDec(sysStat, n)
munmap(v, n)
}
func sysFault(v unsafe.Pointer, n uintptr) {
mmap(v, n, _PROT_NONE, _MAP_ANON|_MAP_PRIVATE|_MAP_FIXED, -1, 0)
}
func sysReserve(v unsafe.Pointer, n uintptr, reserved *bool) unsafe.Pointer {
// On 64-bit, people with ulimit -v set complain if we reserve too
// much address space. Instead, assume that the reservation is okay
// if we can reserve at least 64K and check the assumption in SysMap.
// Only user-mode Linux (UML) rejects these requests.
if sys.PtrSize == 8 && uint64(n) > 1<<32 {
p := mmap_fixed(v, 64<<10, _PROT_NONE, _MAP_ANON|_MAP_PRIVATE, -1, 0)
if p != v {
if uintptr(p) >= 4096 {
munmap(p, 64<<10)
}
return nil
}
munmap(p, 64<<10)
*reserved = false
return v
}
p := mmap(v, n, _PROT_NONE, _MAP_ANON|_MAP_PRIVATE, -1, 0)
if uintptr(p) < 4096 {
return nil
}
*reserved = true
return p
}
func sysMap(v unsafe.Pointer, n uintptr, reserved bool, sysStat *uint64) {
mSysStatInc(sysStat, n)
// On 64-bit, we don't actually have v reserved, so tread carefully.
if !reserved {
p := mmap_fixed(v, n, _PROT_READ|_PROT_WRITE, _MAP_ANON|_MAP_PRIVATE, -1, 0)
if uintptr(p) == _ENOMEM {
throw("runtime: out of memory")
}
if p != v {
print("runtime: address space conflict: map(", v, ") = ", p, "\n")
throw("runtime: address space conflict")
}
return
}
p := mmap(v, n, _PROT_READ|_PROT_WRITE, _MAP_ANON|_MAP_FIXED|_MAP_PRIVATE, -1, 0)
if uintptr(p) == _ENOMEM {
throw("runtime: out of memory")
}
if p != v {
throw("runtime: cannot map pages in arena address space")
}
}