mirror of
https://github.com/tailscale/tailscale.git
synced 2024-11-29 21:15:39 +00:00
e92adfe5e4
Values are still turned into pointers internally to maintain the invariants of strideTable, but from the user's perspective it's now possible to tbl.Insert(pfx, true) rather than tbl.Insert(pfx, ptr.To(true)). Updates #7781 Signed-off-by: David Anderson <danderson@tailscale.com>
642 lines
23 KiB
Go
642 lines
23 KiB
Go
// Copyright (c) Tailscale Inc & AUTHORS
|
|
// SPDX-License-Identifier: BSD-3-Clause
|
|
|
|
// Package art provides a routing table that implements the Allotment Routing
|
|
// Table (ART) algorithm by Donald Knuth, as described in the paper by Yoichi
|
|
// Hariguchi.
|
|
//
|
|
// ART outperforms the traditional radix tree implementations for route lookups,
|
|
// insertions, and deletions.
|
|
//
|
|
// For more information, see Yoichi Hariguchi's paper:
|
|
// https://cseweb.ucsd.edu//~varghese/TEACH/cs228/artlookup.pdf
|
|
package art
|
|
|
|
import (
|
|
"bytes"
|
|
"encoding/binary"
|
|
"fmt"
|
|
"io"
|
|
"math/bits"
|
|
"net/netip"
|
|
"strings"
|
|
"sync"
|
|
)
|
|
|
|
const (
|
|
debugInsert = false
|
|
debugDelete = false
|
|
)
|
|
|
|
// Table is an IPv4 and IPv6 routing table.
|
|
type Table[T any] struct {
|
|
v4 strideTable[T]
|
|
v6 strideTable[T]
|
|
initOnce sync.Once
|
|
}
|
|
|
|
func (t *Table[T]) init() {
|
|
t.initOnce.Do(func() {
|
|
t.v4.prefix = netip.PrefixFrom(netip.IPv4Unspecified(), 0)
|
|
t.v6.prefix = netip.PrefixFrom(netip.IPv6Unspecified(), 0)
|
|
})
|
|
}
|
|
|
|
func (t *Table[T]) tableForAddr(addr netip.Addr) *strideTable[T] {
|
|
if addr.Is6() {
|
|
return &t.v6
|
|
}
|
|
return &t.v4
|
|
}
|
|
|
|
// Get does a route lookup for addr and returns the associated value, or nil if
|
|
// no route matched.
|
|
func (t *Table[T]) Get(addr netip.Addr) (ret T, ok bool) {
|
|
t.init()
|
|
|
|
// Ideally we would use addr.AsSlice here, but AsSlice is just
|
|
// barely complex enough that it can't be inlined, and that in
|
|
// turn causes the slice to escape to the heap. Using As16 and
|
|
// manual slicing here helps the compiler keep Get alloc-free.
|
|
st := t.tableForAddr(addr)
|
|
rawAddr := addr.As16()
|
|
bs := rawAddr[:]
|
|
if addr.Is4() {
|
|
bs = bs[12:]
|
|
}
|
|
|
|
i := 0
|
|
// With path compression, we might skip over some address bits while walking
|
|
// to a strideTable leaf. This means the leaf answer we find might not be
|
|
// correct, because path compression took us down the wrong subtree. When
|
|
// that happens, we have to backtrack and figure out which most specific
|
|
// route further up the tree is relevant to addr, and return that.
|
|
//
|
|
// So, as we walk down the stride tables, each time we find a non-nil route
|
|
// result, we have to remember it and the associated strideTable prefix.
|
|
//
|
|
// We could also deal with this edge case of path compression by checking
|
|
// the strideTable prefix on each table as we descend, but that means we
|
|
// have to pay N prefix.Contains checks on every route lookup (where N is
|
|
// the number of strideTables in the path), rather than only paying M prefix
|
|
// comparisons in the edge case (where M is the number of strideTables in
|
|
// the path with a non-nil route of their own).
|
|
const maxDepth = 16
|
|
type prefixAndRoute struct {
|
|
prefix netip.Prefix
|
|
route T
|
|
}
|
|
strideMatch := make([]prefixAndRoute, 0, maxDepth)
|
|
findLeaf:
|
|
for {
|
|
rt, rtOK, child := st.getValAndChild(bs[i])
|
|
if rtOK {
|
|
// This strideTable contains a route that may be relevant to our
|
|
// search, remember it.
|
|
strideMatch = append(strideMatch, prefixAndRoute{st.prefix, rt})
|
|
}
|
|
if child == nil {
|
|
// No sub-routes further down, the last thing we recorded
|
|
// in strideRoutes is tentatively the result, barring
|
|
// misdirection from path compression.
|
|
break findLeaf
|
|
}
|
|
st = child
|
|
// Path compression means we may be skipping over some intermediate
|
|
// tables. We have to skip forward to whatever depth st now references.
|
|
i = st.prefix.Bits() / 8
|
|
}
|
|
|
|
// Walk backwards through the hits we recorded in strideRoutes and
|
|
// stridePrefixes, returning the first one whose subtree matches addr.
|
|
//
|
|
// In the common case where path compression did not mislead us, we'll
|
|
// return on the first loop iteration because the last route we recorded was
|
|
// the correct most-specific route.
|
|
for i := len(strideMatch) - 1; i >= 0; i-- {
|
|
if m := strideMatch[i]; m.prefix.Contains(addr) {
|
|
return m.route, true
|
|
}
|
|
}
|
|
|
|
// We either found no route hits at all (both previous loops terminated
|
|
// immediately), or we went on a wild goose chase down a compressed path for
|
|
// the wrong prefix, and also found no usable routes on the way back up to
|
|
// the root. This is a miss.
|
|
return ret, false
|
|
}
|
|
|
|
// Insert adds pfx to the table, with value val.
|
|
// If pfx is already present in the table, its value is set to val.
|
|
func (t *Table[T]) Insert(pfx netip.Prefix, val T) {
|
|
t.init()
|
|
|
|
// The standard library doesn't enforce normalized prefixes (where
|
|
// the non-prefix bits are all zero). These algorithms require
|
|
// normalized prefixes, so do it upfront.
|
|
pfx = pfx.Masked()
|
|
|
|
if debugInsert {
|
|
defer func() {
|
|
fmt.Printf("%s", t.debugSummary())
|
|
}()
|
|
fmt.Printf("\ninsert: start pfx=%s\n", pfx)
|
|
}
|
|
|
|
st := t.tableForAddr(pfx.Addr())
|
|
|
|
// This algorithm is full of off-by-one headaches that boil down
|
|
// to the fact that pfx.Bits() has (2^n)+1 values, rather than
|
|
// just 2^n. For example, an IPv4 prefix length can be 0 through
|
|
// 32, which is 33 values.
|
|
//
|
|
// This extra possible value creates a lot of problems as we do
|
|
// bits and bytes math to traverse strideTables below. So, we
|
|
// treat the default route 0/0 specially here, that way the rest
|
|
// of the logic goes back to having 2^n values to reason about,
|
|
// which can be done in a nice and regular fashion with no edge
|
|
// cases.
|
|
if pfx.Bits() == 0 {
|
|
if debugInsert {
|
|
fmt.Printf("insert: default route\n")
|
|
}
|
|
st.insert(0, 0, val)
|
|
return
|
|
}
|
|
|
|
// No matter what we do as we traverse strideTables, our final
|
|
// action will be to insert the last 1-8 bits of pfx into a
|
|
// strideTable somewhere.
|
|
//
|
|
// We calculate upfront the byte position of the end of the
|
|
// prefix; the number of bits within that byte that contain prefix
|
|
// data; and the prefix of the strideTable into which we'll
|
|
// eventually insert.
|
|
//
|
|
// We need this in a couple different branches of the code below,
|
|
// and because the possible values are 1-indexed (1 through 32 for
|
|
// ipv4, 1 through 128 for ipv6), the math is very slightly
|
|
// unusual to account for the off-by-one indexing. Do it once up
|
|
// here, with this large comment, rather than reproduce the subtle
|
|
// math in multiple places further down.
|
|
finalByteIdx := (pfx.Bits() - 1) / 8
|
|
finalBits := pfx.Bits() - (finalByteIdx * 8)
|
|
finalStridePrefix, err := pfx.Addr().Prefix(finalByteIdx * 8)
|
|
if err != nil {
|
|
panic(fmt.Sprintf("invalid prefix requested: %s/%d", pfx.Addr(), finalByteIdx*8))
|
|
}
|
|
if debugInsert {
|
|
fmt.Printf("insert: finalByteIdx=%d finalBits=%d finalStridePrefix=%s\n", finalByteIdx, finalBits, finalStridePrefix)
|
|
}
|
|
|
|
// The strideTable we want to insert into is potentially at the
|
|
// end of a chain of strideTables, each one encoding 8 bits of the
|
|
// prefix.
|
|
//
|
|
// We're expecting to walk down a path of tables, although with
|
|
// prefix compression we may end up skipping some links in the
|
|
// chain, or taking wrong turns and having to course correct.
|
|
//
|
|
// As we walk down the tree, byteIdx is the byte of bs we're
|
|
// currently examining to choose our next step, and numBits is the
|
|
// number of bits that remain in pfx, starting with the byte at
|
|
// byteIdx inclusive.
|
|
bs := pfx.Addr().AsSlice()
|
|
byteIdx := 0
|
|
numBits := pfx.Bits()
|
|
for {
|
|
if debugInsert {
|
|
fmt.Printf("insert: loop byteIdx=%d numBits=%d st.prefix=%s\n", byteIdx, numBits, st.prefix)
|
|
}
|
|
if numBits <= 8 {
|
|
if debugInsert {
|
|
fmt.Printf("insert: existing leaf st.prefix=%s addr=%d/%d\n", st.prefix, bs[finalByteIdx], finalBits)
|
|
}
|
|
// We've reached the end of the prefix, whichever
|
|
// strideTable we're looking at now is the place where we
|
|
// need to insert.
|
|
st.insert(bs[finalByteIdx], finalBits, val)
|
|
return
|
|
}
|
|
|
|
// Otherwise, we need to go down at least one more level of
|
|
// strideTables. With prefix compression, each level of
|
|
// descent can have one of three outcomes: we find a place
|
|
// where prefix compression is possible; a place where prefix
|
|
// compression made us take a "wrong turn"; or a point along
|
|
// our intended path that we have to keep following.
|
|
child, created := st.getOrCreateChild(bs[byteIdx])
|
|
switch {
|
|
case created:
|
|
// The subtree we need for pfx doesn't exist yet. The rest
|
|
// of the path, if we were to create it, will consist of a
|
|
// bunch of strideTables with a single child each. We can
|
|
// use path compression to elide those intermediates, and
|
|
// jump straight to the final strideTable that hosts this
|
|
// prefix.
|
|
child.prefix = finalStridePrefix
|
|
child.insert(bs[finalByteIdx], finalBits, val)
|
|
if debugInsert {
|
|
fmt.Printf("insert: new leaf st.prefix=%s child.prefix=%s addr=%d/%d\n", st.prefix, child.prefix, bs[finalByteIdx], finalBits)
|
|
}
|
|
return
|
|
case !prefixStrictlyContains(child.prefix, pfx):
|
|
// child already exists, but its prefix does not contain
|
|
// our destination. This means that the path between st
|
|
// and child was compressed by a previous insertion, and
|
|
// somewhere in the (implicit) compressed path we took a
|
|
// wrong turn, into the wrong part of st's subtree.
|
|
//
|
|
// This is okay, because pfx and child.prefix must have a
|
|
// common ancestor node somewhere between st and child. We
|
|
// can figure out what node that is, and materialize it.
|
|
//
|
|
// Once we've done that, we can immediately complete the
|
|
// remainder of the insertion in one of two ways, without
|
|
// further traversal. See a little further down for what
|
|
// those are.
|
|
if debugInsert {
|
|
fmt.Printf("insert: wrong turn, pfx=%s child.prefix=%s\n", pfx, child.prefix)
|
|
}
|
|
intermediatePrefix, addrOfExisting, addrOfNew := computePrefixSplit(child.prefix, pfx)
|
|
intermediate := &strideTable[T]{prefix: intermediatePrefix} // TODO: make this whole thing be st.AddIntermediate or something?
|
|
st.setChild(bs[byteIdx], intermediate)
|
|
intermediate.setChild(addrOfExisting, child)
|
|
|
|
if debugInsert {
|
|
fmt.Printf("insert: new intermediate st.prefix=%s intermediate.prefix=%s child.prefix=%s\n", st.prefix, intermediate.prefix, child.prefix)
|
|
}
|
|
|
|
// Now, we have a chain of st -> intermediate -> child.
|
|
//
|
|
// pfx either lives in a different child of intermediate,
|
|
// or in intermediate itself. For example, if we created
|
|
// the intermediate 1.2.0.0/16, pfx=1.2.3.4/32 would have
|
|
// to go into a new child of intermediate, but
|
|
// pfx=1.2.0.0/18 would go into intermediate directly.
|
|
if remain := pfx.Bits() - intermediate.prefix.Bits(); remain <= 8 {
|
|
// pfx lives in intermediate.
|
|
if debugInsert {
|
|
fmt.Printf("insert: into intermediate intermediate.prefix=%s addr=%d/%d\n", intermediate.prefix, bs[finalByteIdx], finalBits)
|
|
}
|
|
intermediate.insert(bs[finalByteIdx], finalBits, val)
|
|
} else {
|
|
// pfx lives in a different child subtree of
|
|
// intermediate. By definition this subtree doesn't
|
|
// exist at all, otherwise we'd never have entered
|
|
// this entire "wrong turn" codepath in the first
|
|
// place.
|
|
//
|
|
// This means we can apply prefix compression as we
|
|
// create this new child, and we're done.
|
|
st, created = intermediate.getOrCreateChild(addrOfNew)
|
|
if !created {
|
|
panic("new child path unexpectedly exists during path decompression")
|
|
}
|
|
st.prefix = finalStridePrefix
|
|
st.insert(bs[finalByteIdx], finalBits, val)
|
|
if debugInsert {
|
|
fmt.Printf("insert: new child st.prefix=%s addr=%d/%d\n", st.prefix, bs[finalByteIdx], finalBits)
|
|
}
|
|
}
|
|
|
|
return
|
|
default:
|
|
// An expected child table exists along pfx's
|
|
// path. Continue traversing downwards.
|
|
st = child
|
|
byteIdx = child.prefix.Bits() / 8
|
|
numBits = pfx.Bits() - child.prefix.Bits()
|
|
if debugInsert {
|
|
fmt.Printf("insert: descend st.prefix=%s\n", st.prefix)
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
// Delete removes pfx from the table, if it is present.
|
|
func (t *Table[T]) Delete(pfx netip.Prefix) {
|
|
t.init()
|
|
|
|
// The standard library doesn't enforce normalized prefixes (where
|
|
// the non-prefix bits are all zero). These algorithms require
|
|
// normalized prefixes, so do it upfront.
|
|
pfx = pfx.Masked()
|
|
|
|
if debugDelete {
|
|
defer func() {
|
|
fmt.Printf("%s", t.debugSummary())
|
|
}()
|
|
fmt.Printf("\ndelete: start pfx=%s table:\n%s", pfx, t.debugSummary())
|
|
}
|
|
|
|
st := t.tableForAddr(pfx.Addr())
|
|
|
|
// This algorithm is full of off-by-one headaches, just like
|
|
// Insert. See the comment in Insert for more details. Bottom
|
|
// line: we handle the default route as a special case, and that
|
|
// simplifies the rest of the code slightly.
|
|
if pfx.Bits() == 0 {
|
|
if debugDelete {
|
|
fmt.Printf("delete: default route\n")
|
|
}
|
|
st.delete(0, 0)
|
|
return
|
|
}
|
|
|
|
// Deletion may drive the refcount of some strideTables down to
|
|
// zero. We need to clean up these dangling tables, so we have to
|
|
// keep track of which tables we touch on the way down, and which
|
|
// strideEntry index each child is registered in.
|
|
//
|
|
// Note that the strideIndex and strideTables entries are off-by-one.
|
|
// The child table pointer is recorded at i+1, but it is referenced by a
|
|
// particular index in the parent table, at index i.
|
|
//
|
|
// In other words: entry number strideIndexes[0] in
|
|
// strideTables[0] is the same pointer as strideTables[1].
|
|
//
|
|
// This results in some slightly odd array accesses further down
|
|
// in this code, because in a single loop iteration we have to
|
|
// write to strideTables[N] and strideIndexes[N-1].
|
|
strideIdx := 0
|
|
strideTables := [16]*strideTable[T]{st}
|
|
strideIndexes := [15]uint8{}
|
|
|
|
// Similar to Insert, navigate down the tree of strideTables,
|
|
// looking for the one that houses this prefix. This part is
|
|
// easier than with insertion, since we can bail if the path ends
|
|
// early or takes an unexpected detour. However, unlike
|
|
// insertion, there's a whole post-deletion cleanup phase later
|
|
// on.
|
|
//
|
|
// As we walk down the tree, byteIdx is the byte of bs we're
|
|
// currently examining to choose our next step, and numBits is the
|
|
// number of bits that remain in pfx, starting with the byte at
|
|
// byteIdx inclusive.
|
|
bs := pfx.Addr().AsSlice()
|
|
byteIdx := 0
|
|
numBits := pfx.Bits()
|
|
for numBits > 8 {
|
|
if debugDelete {
|
|
fmt.Printf("delete: loop byteIdx=%d numBits=%d st.prefix=%s\n", byteIdx, numBits, st.prefix)
|
|
}
|
|
child := st.getChild(bs[byteIdx])
|
|
if child == nil {
|
|
// Prefix can't exist in the table, because one of the
|
|
// necessary strideTables doesn't exist.
|
|
if debugDelete {
|
|
fmt.Printf("delete: missing necessary child pfx=%s\n", pfx)
|
|
}
|
|
return
|
|
}
|
|
strideIndexes[strideIdx] = bs[byteIdx]
|
|
strideTables[strideIdx+1] = child
|
|
strideIdx++
|
|
|
|
// Path compression means byteIdx can jump forwards
|
|
// unpredictably. Recompute the next byte to look at from the
|
|
// child we just found.
|
|
byteIdx = child.prefix.Bits() / 8
|
|
numBits = pfx.Bits() - child.prefix.Bits()
|
|
st = child
|
|
|
|
if debugDelete {
|
|
fmt.Printf("delete: descend st.prefix=%s\n", st.prefix)
|
|
}
|
|
}
|
|
|
|
// We reached a leaf stride table that seems to be in the right
|
|
// spot. But path compression might have led us to the wrong
|
|
// table.
|
|
if !prefixStrictlyContains(st.prefix, pfx) {
|
|
// Wrong table, the requested prefix can't exist since its
|
|
// path led us to the wrong place.
|
|
if debugDelete {
|
|
fmt.Printf("delete: wrong leaf table pfx=%s\n", pfx)
|
|
}
|
|
return
|
|
}
|
|
if debugDelete {
|
|
fmt.Printf("delete: delete from st.prefix=%s addr=%d/%d\n", st.prefix, bs[byteIdx], numBits)
|
|
}
|
|
if routeExisted := st.delete(bs[byteIdx], numBits); !routeExisted {
|
|
// We're in the right strideTable, but pfx wasn't in
|
|
// it. Refcounts haven't changed, so we can skip cleanup.
|
|
if debugDelete {
|
|
fmt.Printf("delete: prefix not present pfx=%s\n", pfx)
|
|
}
|
|
return
|
|
}
|
|
|
|
// st.delete reduced st's refcount by one. This table may now be
|
|
// reclaimable, and depending on how we can reclaim it, the parent
|
|
// tables may also need to be reclaimed. This loop ends as soon as
|
|
// an iteration takes no action, or takes an action that doesn't
|
|
// alter the parent table's refcounts.
|
|
//
|
|
// We start our walk back at strideTables[strideIdx], which
|
|
// contains st.
|
|
for strideIdx > 0 {
|
|
cur := strideTables[strideIdx]
|
|
if debugDelete {
|
|
fmt.Printf("delete: GC? strideIdx=%d st.prefix=%s\n", strideIdx, cur.prefix)
|
|
}
|
|
if cur.routeRefs > 0 {
|
|
// the strideTable has other route entries, it cannot be
|
|
// deleted or compacted.
|
|
if debugDelete {
|
|
fmt.Printf("delete: has other routes st.prefix=%s\n", cur.prefix)
|
|
}
|
|
return
|
|
}
|
|
switch cur.childRefs {
|
|
case 0:
|
|
// no routeRefs and no childRefs, this table can be
|
|
// deleted. This will alter the parent table's refcount,
|
|
// so we'll have to look at it as well (in the next loop
|
|
// iteration).
|
|
if debugDelete {
|
|
fmt.Printf("delete: remove st.prefix=%s\n", cur.prefix)
|
|
}
|
|
strideTables[strideIdx-1].deleteChild(strideIndexes[strideIdx-1])
|
|
strideIdx--
|
|
case 1:
|
|
// This table has no routes, and a single child. Compact
|
|
// this table out of existence by making the parent point
|
|
// directly at the one child. This does not affect the
|
|
// parent's refcounts, so the parent can't be eligible for
|
|
// deletion or compaction, and we can stop.
|
|
child := strideTables[strideIdx].findFirstChild() // only 1 child exists, by definition
|
|
parent := strideTables[strideIdx-1]
|
|
if debugDelete {
|
|
fmt.Printf("delete: compact parent.prefix=%s st.prefix=%s child.prefix=%s\n", parent.prefix, cur.prefix, child.prefix)
|
|
}
|
|
strideTables[strideIdx-1].setChild(strideIndexes[strideIdx-1], child)
|
|
return
|
|
default:
|
|
// This table has two or more children, so it's acting as a "fork in
|
|
// the road" between two prefix subtrees. It cannot be deleted, and
|
|
// thus no further cleanups are possible.
|
|
if debugDelete {
|
|
fmt.Printf("delete: fork table st.prefix=%s\n", cur.prefix)
|
|
}
|
|
return
|
|
}
|
|
}
|
|
}
|
|
|
|
// debugSummary prints the tree of allocated strideTables in t, with each
|
|
// strideTable's refcount.
|
|
func (t *Table[T]) debugSummary() string {
|
|
t.init()
|
|
var ret bytes.Buffer
|
|
fmt.Fprintf(&ret, "v4: ")
|
|
strideSummary(&ret, &t.v4, 4)
|
|
fmt.Fprintf(&ret, "v6: ")
|
|
strideSummary(&ret, &t.v6, 4)
|
|
return ret.String()
|
|
}
|
|
|
|
func strideSummary[T any](w io.Writer, st *strideTable[T], indent int) {
|
|
fmt.Fprintf(w, "%s: %d routes, %d children\n", st.prefix, st.routeRefs, st.childRefs)
|
|
indent += 4
|
|
st.treeDebugStringRec(w, 1, indent)
|
|
for addr, child := range st.children {
|
|
if child == nil {
|
|
continue
|
|
}
|
|
fmt.Fprintf(w, "%s%d/8 (%02x/8): ", strings.Repeat(" ", indent), addr, addr)
|
|
strideSummary(w, child, indent)
|
|
}
|
|
}
|
|
|
|
// prefixStrictlyContains reports whether child is a prefix within
|
|
// parent, but not parent itself.
|
|
func prefixStrictlyContains(parent, child netip.Prefix) bool {
|
|
return parent.Overlaps(child) && parent.Bits() < child.Bits()
|
|
}
|
|
|
|
// computePrefixSplit returns the smallest common prefix that contains
|
|
// both a and b. lastCommon is 8-bit aligned, with aStride and bStride
|
|
// indicating the value of the 8-bit stride immediately following
|
|
// lastCommon.
|
|
//
|
|
// computePrefixSplit is used in constructing an intermediate
|
|
// strideTable when a new prefix needs to be inserted in a compressed
|
|
// table. It can be read as: given that a is already in the table, and
|
|
// b is being inserted, what is the prefix of the new intermediate
|
|
// strideTable that needs to be created, and at what addresses in that
|
|
// new strideTable should a and b's subsequent strideTables be
|
|
// attached?
|
|
//
|
|
// Note as a special case, this can be called with a==b. An example of
|
|
// when this happens:
|
|
// - We want to insert the prefix 1.2.0.0/16
|
|
// - A strideTable exists for 1.2.0.0/16, because another child
|
|
// prefix already exists (e.g. 1.2.3.4/32)
|
|
// - The 1.0.0.0/8 strideTable does not exist, because path
|
|
// compression removed it.
|
|
//
|
|
// In this scenario, the caller of computePrefixSplit ends up making a
|
|
// "wrong turn" while traversing strideTables: it was looking for the
|
|
// 1.0.0.0/8 table, but ended up at the 1.2.0.0/16 table. When this
|
|
// happens, it will invoke computePrefixSplit(1.2.0.0/16, 1.2.0.0/16),
|
|
// and we return 1.0.0.0/8 as the missing intermediate.
|
|
func computePrefixSplit(a, b netip.Prefix) (lastCommon netip.Prefix, aStride, bStride uint8) {
|
|
a = a.Masked()
|
|
b = b.Masked()
|
|
if a.Bits() == 0 || b.Bits() == 0 {
|
|
panic("computePrefixSplit called with a default route")
|
|
}
|
|
if a.Addr().Is4() != b.Addr().Is4() {
|
|
panic("computePrefixSplit called with mismatched address families")
|
|
}
|
|
|
|
minPrefixLen := a.Bits()
|
|
if b.Bits() < minPrefixLen {
|
|
minPrefixLen = b.Bits()
|
|
}
|
|
|
|
commonBits := commonBits(a.Addr(), b.Addr(), minPrefixLen)
|
|
// We want to know how many 8-bit strides are shared between a and
|
|
// b. Naively, this would be commonBits/8, but this introduces an
|
|
// off-by-one error. This is due to the way our ART stores
|
|
// prefixes whose length falls exactly on a stride boundary.
|
|
//
|
|
// Consider 192.168.1.0/24 and 192.168.0.0/16. commonBits
|
|
// correctly reports that these prefixes have their first 16 bits
|
|
// in common. However, in the ART they only share 1 common stride:
|
|
// they both use the 192.0.0.0/8 strideTable, but 192.168.0.0/16
|
|
// is stored as 168/8 within that table, and not as 0/0 in the
|
|
// 192.168.0.0/16 table.
|
|
//
|
|
// So, when commonBits matches the length of one of the inputs and
|
|
// falls on a boundary between strides, the strideTable one
|
|
// further up from commonBits/8 is the one we need to create,
|
|
// which means we have to adjust the stride count down by one.
|
|
if commonBits == minPrefixLen {
|
|
commonBits--
|
|
}
|
|
commonStrides := commonBits / 8
|
|
lastCommon, err := a.Addr().Prefix(commonStrides * 8)
|
|
if err != nil {
|
|
panic(fmt.Sprintf("computePrefixSplit constructing common prefix: %v", err))
|
|
}
|
|
if a.Addr().Is4() {
|
|
aStride = a.Addr().As4()[commonStrides]
|
|
bStride = b.Addr().As4()[commonStrides]
|
|
} else {
|
|
aStride = a.Addr().As16()[commonStrides]
|
|
bStride = b.Addr().As16()[commonStrides]
|
|
}
|
|
return lastCommon, aStride, bStride
|
|
}
|
|
|
|
// commonBits returns the number of common leading bits of a and b.
|
|
// If the number of common bits exceeds maxBits, it returns maxBits
|
|
// instead.
|
|
func commonBits(a, b netip.Addr, maxBits int) int {
|
|
if a.Is4() != b.Is4() {
|
|
panic("commonStrides called with mismatched address families")
|
|
}
|
|
var common int
|
|
// The following implements an old bit-twiddling trick to compute
|
|
// the number of common leading bits: if you XOR two numbers
|
|
// together, equal bits become 0 and unequal bits become 1. You
|
|
// can then count the number of leading zeros (which is a single
|
|
// instruction on modern CPUs) to get the answer.
|
|
//
|
|
// This code is a little more complex than just XOR + count
|
|
// leading zeros, because IPv4 and IPv6 are different sizes, and
|
|
// for IPv6 we have to do the math in two 64-bit chunks because Go
|
|
// lacks a uint128 type.
|
|
if a.Is4() {
|
|
aNum, bNum := ipv4AsUint(a), ipv4AsUint(b)
|
|
common = bits.LeadingZeros32(aNum ^ bNum)
|
|
} else {
|
|
aNumHi, aNumLo := ipv6AsUint(a)
|
|
bNumHi, bNumLo := ipv6AsUint(b)
|
|
common = bits.LeadingZeros64(aNumHi ^ bNumHi)
|
|
if common == 64 {
|
|
common += bits.LeadingZeros64(aNumLo ^ bNumLo)
|
|
}
|
|
}
|
|
if common > maxBits {
|
|
common = maxBits
|
|
}
|
|
return common
|
|
}
|
|
|
|
// ipv4AsUint returns ip as a uint32.
|
|
func ipv4AsUint(ip netip.Addr) uint32 {
|
|
bs := ip.As4()
|
|
return binary.BigEndian.Uint32(bs[:])
|
|
}
|
|
|
|
// ipv6AsUint returns ip as a pair of uint64s.
|
|
func ipv6AsUint(ip netip.Addr) (uint64, uint64) {
|
|
bs := ip.As16()
|
|
return binary.BigEndian.Uint64(bs[:8]), binary.BigEndian.Uint64(bs[8:])
|
|
}
|