| // Copyright 2019 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:build amd64 || (!ios && arm64) || mips64 || mips64le || ppc64 || ppc64le || riscv64 || s390x || arm64be || alpha || sparc64 || ia64 |
| // +build amd64 !ios,arm64 mips64 mips64le ppc64 ppc64le riscv64 s390x arm64be alpha sparc64 ia64 |
| |
| // See mpagealloc_32bit.go for why ios/arm64 is excluded here. |
| |
| package runtime |
| |
| import "unsafe" |
| |
| const ( |
| // The number of levels in the radix tree. |
| summaryLevels = 5 |
| |
| // Constants for testing. |
| pageAlloc32Bit = 0 |
| pageAlloc64Bit = 1 |
| |
| // Number of bits needed to represent all indices into the L1 of the |
| // chunks map. |
| // |
| // See (*pageAlloc).chunks for more details. Update the documentation |
| // there should this number change. |
| pallocChunksL1Bits = 13 |
| ) |
| |
| // levelBits is the number of bits in the radix for a given level in the super summary |
| // structure. |
| // |
| // The sum of all the entries of levelBits should equal heapAddrBits. |
| var levelBits = [summaryLevels]uint{ |
| summaryL0Bits, |
| summaryLevelBits, |
| summaryLevelBits, |
| summaryLevelBits, |
| summaryLevelBits, |
| } |
| |
| // levelShift is the number of bits to shift to acquire the radix for a given level |
| // in the super summary structure. |
| // |
| // With levelShift, one can compute the index of the summary at level l related to a |
| // pointer p by doing: |
| // p >> levelShift[l] |
| var levelShift = [summaryLevels]uint{ |
| heapAddrBits - summaryL0Bits, |
| heapAddrBits - summaryL0Bits - 1*summaryLevelBits, |
| heapAddrBits - summaryL0Bits - 2*summaryLevelBits, |
| heapAddrBits - summaryL0Bits - 3*summaryLevelBits, |
| heapAddrBits - summaryL0Bits - 4*summaryLevelBits, |
| } |
| |
| // levelLogPages is log2 the maximum number of runtime pages in the address space |
| // a summary in the given level represents. |
| // |
| // The leaf level always represents exactly log2 of 1 chunk's worth of pages. |
| var levelLogPages = [summaryLevels]uint{ |
| logPallocChunkPages + 4*summaryLevelBits, |
| logPallocChunkPages + 3*summaryLevelBits, |
| logPallocChunkPages + 2*summaryLevelBits, |
| logPallocChunkPages + 1*summaryLevelBits, |
| logPallocChunkPages, |
| } |
| |
| // sysInit performs architecture-dependent initialization of fields |
| // in pageAlloc. pageAlloc should be uninitialized except for sysStat |
| // if any runtime statistic should be updated. |
| func (p *pageAlloc) sysInit() { |
| // Reserve memory for each level. This will get mapped in |
| // as R/W by setArenas. |
| for l, shift := range levelShift { |
| entries := 1 << (heapAddrBits - shift) |
| |
| // Reserve b bytes of memory anywhere in the address space. |
| b := alignUp(uintptr(entries)*pallocSumBytes, physPageSize) |
| r := sysReserve(nil, b) |
| if r == nil { |
| throw("failed to reserve page summary memory") |
| } |
| |
| // Put this reservation into a slice. |
| sl := notInHeapSlice{(*notInHeap)(r), 0, entries} |
| p.summary[l] = *(*[]pallocSum)(unsafe.Pointer(&sl)) |
| } |
| } |
| |
| // sysGrow performs architecture-dependent operations on heap |
| // growth for the page allocator, such as mapping in new memory |
| // for summaries. It also updates the length of the slices in |
| // [.summary. |
| // |
| // base is the base of the newly-added heap memory and limit is |
| // the first address past the end of the newly-added heap memory. |
| // Both must be aligned to pallocChunkBytes. |
| // |
| // The caller must update p.start and p.end after calling sysGrow. |
| func (p *pageAlloc) sysGrow(base, limit uintptr) { |
| if base%pallocChunkBytes != 0 || limit%pallocChunkBytes != 0 { |
| print("runtime: base = ", hex(base), ", limit = ", hex(limit), "\n") |
| throw("sysGrow bounds not aligned to pallocChunkBytes") |
| } |
| |
| // addrRangeToSummaryRange converts a range of addresses into a range |
| // of summary indices which must be mapped to support those addresses |
| // in the summary range. |
| addrRangeToSummaryRange := func(level int, r addrRange) (int, int) { |
| sumIdxBase, sumIdxLimit := addrsToSummaryRange(level, r.base.addr(), r.limit.addr()) |
| return blockAlignSummaryRange(level, sumIdxBase, sumIdxLimit) |
| } |
| |
| // summaryRangeToSumAddrRange converts a range of indices in any |
| // level of p.summary into page-aligned addresses which cover that |
| // range of indices. |
| summaryRangeToSumAddrRange := func(level, sumIdxBase, sumIdxLimit int) addrRange { |
| baseOffset := alignDown(uintptr(sumIdxBase)*pallocSumBytes, physPageSize) |
| limitOffset := alignUp(uintptr(sumIdxLimit)*pallocSumBytes, physPageSize) |
| base := unsafe.Pointer(&p.summary[level][0]) |
| return addrRange{ |
| offAddr{uintptr(add(base, baseOffset))}, |
| offAddr{uintptr(add(base, limitOffset))}, |
| } |
| } |
| |
| // addrRangeToSumAddrRange is a convienience function that converts |
| // an address range r to the address range of the given summary level |
| // that stores the summaries for r. |
| addrRangeToSumAddrRange := func(level int, r addrRange) addrRange { |
| sumIdxBase, sumIdxLimit := addrRangeToSummaryRange(level, r) |
| return summaryRangeToSumAddrRange(level, sumIdxBase, sumIdxLimit) |
| } |
| |
| // Find the first inUse index which is strictly greater than base. |
| // |
| // Because this function will never be asked remap the same memory |
| // twice, this index is effectively the index at which we would insert |
| // this new growth, and base will never overlap/be contained within |
| // any existing range. |
| // |
| // This will be used to look at what memory in the summary array is already |
| // mapped before and after this new range. |
| inUseIndex := p.inUse.findSucc(base) |
| |
| // Walk up the radix tree and map summaries in as needed. |
| for l := range p.summary { |
| // Figure out what part of the summary array this new address space needs. |
| needIdxBase, needIdxLimit := addrRangeToSummaryRange(l, makeAddrRange(base, limit)) |
| |
| // Update the summary slices with a new upper-bound. This ensures |
| // we get tight bounds checks on at least the top bound. |
| // |
| // We must do this regardless of whether we map new memory. |
| if needIdxLimit > len(p.summary[l]) { |
| p.summary[l] = p.summary[l][:needIdxLimit] |
| } |
| |
| // Compute the needed address range in the summary array for level l. |
| need := summaryRangeToSumAddrRange(l, needIdxBase, needIdxLimit) |
| |
| // Prune need down to what needs to be newly mapped. Some parts of it may |
| // already be mapped by what inUse describes due to page alignment requirements |
| // for mapping. prune's invariants are guaranteed by the fact that this |
| // function will never be asked to remap the same memory twice. |
| if inUseIndex > 0 { |
| need = need.subtract(addrRangeToSumAddrRange(l, p.inUse.ranges[inUseIndex-1])) |
| } |
| if inUseIndex < len(p.inUse.ranges) { |
| need = need.subtract(addrRangeToSumAddrRange(l, p.inUse.ranges[inUseIndex])) |
| } |
| // It's possible that after our pruning above, there's nothing new to map. |
| if need.size() == 0 { |
| continue |
| } |
| |
| // Map and commit need. |
| sysMap(unsafe.Pointer(need.base.addr()), need.size(), p.sysStat) |
| sysUsed(unsafe.Pointer(need.base.addr()), need.size()) |
| } |
| } |