src/runtime/mklockrank.go - go - Git at Google

 // Copyright 2022 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 ignore

 // mklockrank records the static rank graph of the locks in the
 // runtime and generates the rank checking structures in lockrank.go.
 package main

 import (
 	"bytes"
 	"flag"
 	"fmt"
 	"go/format"
 	"internal/dag"
 	"io"
 	"log"
 	"os"
 	"strings"
 )

 // ranks describes the lock rank graph. See "go doc internal/dag" for
 // the syntax.
 //
 // "a < b" means a must be acquired before b if both are held
 // (or, if b is held, a cannot be acquired).
 //
 // "NONE < a" means no locks may be held when a is acquired.
 //
 // If a lock is not given a rank, then it is assumed to be a leaf
 // lock, which means no other lock can be acquired while it is held.
 // Therefore, leaf locks do not need to be given an explicit rank.
 //
 // Ranks in all caps are pseudo-nodes that help define order, but do
 // not actually define a rank.
 //
 // TODO: It's often hard to correlate rank names to locks. Change
 // these to be more consistent with the locks they label.
 const ranks = `
 # Sysmon
 NONE
 < sysmon
 < scavenge, forcegc;

 # Defer
 NONE < defer;

 # GC
 NONE <
   sweepWaiters,
   assistQueue,
   sweep;

 # Scheduler, timers, netpoll
 NONE < pollDesc, cpuprof;
 assistQueue,
   cpuprof,
   forcegc,
   pollDesc, # pollDesc can interact with timers, which can lock sched.
   scavenge,
   sweep,
   sweepWaiters
 < sched;
 sched < allg, allp;
 allp < timers;
 timers < netpollInit;

 # Channels
 scavenge, sweep < hchan;
 NONE < notifyList;
 hchan, notifyList < sudog;

 # RWMutex
 NONE < rwmutexW;
 rwmutexW, sysmon < rwmutexR;

 # Semaphores
 NONE < root;

 # Itabs
 NONE
 < itab
 < reflectOffs;

 # User arena state
 NONE < userArenaState;

 # Tracing without a P uses a global trace buffer.
 scavenge
 # Above TRACEGLOBAL can emit a trace event without a P.
 < TRACEGLOBAL
 # Below TRACEGLOBAL manages the global tracing buffer.
 # Note that traceBuf eventually chains to MALLOC, but we never get that far
 # in the situation where there's no P.
 < traceBuf;
 # Starting/stopping tracing traces strings.
 traceBuf < traceStrings;

 # Malloc
 allg,
   hchan,
   notifyList,
   reflectOffs,
   timers,
   traceStrings,
   userArenaState
 # Above MALLOC are things that can allocate memory.
 < MALLOC
 # Below MALLOC is the malloc implementation.
 < fin,
   gcBitsArenas,
   mheapSpecial,
   mspanSpecial,
   spanSetSpine,
   MPROF;

 # Memory profiling
 MPROF < profInsert, profBlock, profMemActive;
 profMemActive < profMemFuture;

 # Stack allocation and copying
 gcBitsArenas,
   netpollInit,
   profBlock,
   profInsert,
   profMemFuture,
   spanSetSpine,
   fin,
   root
 # Anything that can grow the stack can acquire STACKGROW.
 # (Most higher layers imply STACKGROW, like MALLOC.)
 < STACKGROW
 # Below STACKGROW is the stack allocator/copying implementation.
 < gscan;
 gscan, rwmutexR < stackpool;
 gscan < stackLarge;
 # Generally, hchan must be acquired before gscan. But in one case,
 # where we suspend a G and then shrink its stack, syncadjustsudogs
 # can acquire hchan locks while holding gscan. To allow this case,
 # we use hchanLeaf instead of hchan.
 gscan < hchanLeaf;

 # Write barrier
 defer,
   gscan,
   mspanSpecial,
   sudog
 # Anything that can have write barriers can acquire WB.
 # Above WB, we can have write barriers.
 < WB
 # Below WB is the write barrier implementation.
 < wbufSpans;

 # Span allocator
 stackLarge,
   stackpool,
   wbufSpans
 # Above mheap is anything that can call the span allocator.
 < mheap;
 # Below mheap is the span allocator implementation.
 mheap, mheapSpecial < globalAlloc;

 # Execution tracer events (with a P)
 hchan,
   mheap,
   root,
   sched,
   traceStrings,
   notifyList,
   fin
 # Above TRACE is anything that can create a trace event
 < TRACE
 < trace
 < traceStackTab;

 # panic is handled specially. It is implicitly below all other locks.
 NONE < panic;
 # deadlock is not acquired while holding panic, but it also needs to be
 # below all other locks.
 panic < deadlock;
 `

 // cyclicRanks lists lock ranks that allow multiple locks of the same
 // rank to be acquired simultaneously. The runtime enforces ordering
 // within these ranks using a separate mechanism.
 var cyclicRanks = map[string]bool{
 	// Multiple timers are locked simultaneously in destroy().
 	"timers": true,
 	// Multiple hchans are acquired in hchan.sortkey() order in
 	// select.
 	"hchan": true,
 	// Multiple hchanLeafs are acquired in hchan.sortkey() order in
 	// syncadjustsudogs().
 	"hchanLeaf": true,
 	// The point of the deadlock lock is to deadlock.
 	"deadlock": true,
 }

 func main() {
 	flagO := flag.String("o", "", "write to `file` instead of stdout")
 	flagDot := flag.Bool("dot", false, "emit graphviz output instead of Go")
 	flag.Parse()
 	if flag.NArg() != 0 {
 		fmt.Fprintf(os.Stderr, "too many arguments")
 		os.Exit(2)
 	}

 	g, err := dag.Parse(ranks)
 	if err != nil {
 		log.Fatal(err)
 	}

 	var out []byte
 	if *flagDot {
 		var b bytes.Buffer
 		g.TransitiveReduction()
 		// Add cyclic edges for visualization.
 		for k := range cyclicRanks {
 			g.AddEdge(k, k)
 		}
 		// Reverse the graph. It's much easier to read this as
 		// a "<" partial order than a ">" partial order. This
 		// ways, locks are acquired from the top going down
 		// and time moves forward over the edges instead of
 		// backward.
 		g.Transpose()
 		generateDot(&b, g)
 		out = b.Bytes()
 	} else {
 		var b bytes.Buffer
 		generateGo(&b, g)
 		out, err = format.Source(b.Bytes())
 		if err != nil {
 			log.Fatal(err)
 		}
 	}

 	if *flagO != "" {
 		err = os.WriteFile(*flagO, out, 0666)
 	} else {
 		_, err = os.Stdout.Write(out)
 	}
 	if err != nil {
 		log.Fatal(err)
 	}
 }

 func generateGo(w io.Writer, g *dag.Graph) {
 	fmt.Fprintf(w, `// Code generated by mklockrank.go; DO NOT EDIT.

 package runtime

 type lockRank int

 `)

 	// Create numeric ranks.
 	topo := g.Topo()
 	for i, j := 0, len(topo)-1; i < j; i, j = i+1, j-1 {
 		topo[i], topo[j] = topo[j], topo[i]
 	}
 	fmt.Fprintf(w, `
 // Constants representing the ranks of all non-leaf runtime locks, in rank order.
 // Locks with lower rank must be taken before locks with higher rank,
 // in addition to satisfying the partial order in lockPartialOrder.
 // A few ranks allow self-cycles, which are specified in lockPartialOrder.
 const (
 	lockRankUnknown lockRank = iota

 `)
 	for _, rank := range topo {
 		if isPseudo(rank) {
 			fmt.Fprintf(w, "\t// %s\n", rank)
 		} else {
 			fmt.Fprintf(w, "\t%s\n", cname(rank))
 		}
 	}
 	fmt.Fprintf(w, `)

 // lockRankLeafRank is the rank of lock that does not have a declared rank,
 // and hence is a leaf lock.
 const lockRankLeafRank lockRank = 1000
 `)

 	// Create string table.
 	fmt.Fprintf(w, `
 // lockNames gives the names associated with each of the above ranks.
 var lockNames = []string{
 `)
 	for _, rank := range topo {
 		if !isPseudo(rank) {
 			fmt.Fprintf(w, "\t%s: %q,\n", cname(rank), rank)
 		}
 	}
 	fmt.Fprintf(w, `}

 func (rank lockRank) String() string {
 	if rank == 0 {
 		return "UNKNOWN"
 	}
 	if rank == lockRankLeafRank {
 		return "LEAF"
 	}
 	if rank < 0 || int(rank) >= len(lockNames) {
 		return "BAD RANK"
 	}
 	return lockNames[rank]
 }
 `)

 	// Create partial order structure.
 	fmt.Fprintf(w, `
 // lockPartialOrder is the transitive closure of the lock rank graph.
 // An entry for rank X lists all of the ranks that can already be held
 // when rank X is acquired.
 //
 // Lock ranks that allow self-cycles list themselves.
 var lockPartialOrder [][]lockRank = [][]lockRank{
 `)
 	for _, rank := range topo {
 		if isPseudo(rank) {
 			continue
 		}
 		list := []string{}
 		for _, before := range g.Edges(rank) {
 			if !isPseudo(before) {
 				list = append(list, cname(before))
 			}
 		}
 		if cyclicRanks[rank] {
 			list = append(list, cname(rank))
 		}

 		fmt.Fprintf(w, "\t%s: {%s},\n", cname(rank), strings.Join(list, ", "))
 	}
 	fmt.Fprintf(w, "}\n")
 }

 // cname returns the Go const name for the given lock rank label.
 func cname(label string) string {
 	return "lockRank" + strings.ToUpper(label[:1]) + label[1:]
 }

 func isPseudo(label string) bool {
 	return strings.ToUpper(label) == label
 }

 // generateDot emits a Graphviz dot representation of g to w.
 func generateDot(w io.Writer, g *dag.Graph) {
 	fmt.Fprintf(w, "digraph g {\n")

 	// Define all nodes.
 	for _, node := range g.Nodes {
 		fmt.Fprintf(w, "%q;\n", node)
 	}

 	// Create edges.
 	for _, node := range g.Nodes {
 		for _, to := range g.Edges(node) {
 			fmt.Fprintf(w, "%q -> %q;\n", node, to)
 		}
 	}

 	fmt.Fprintf(w, "}\n")
 }
	// Copyright 2022 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 ignore

	// mklockrank records the static rank graph of the locks in the
	// runtime and generates the rank checking structures in lockrank.go.
	package main

	import (
	"bytes"
	"flag"
	"fmt"
	"go/format"
	"internal/dag"
	"io"
	"log"
	"os"
	"strings"
	)

	// ranks describes the lock rank graph. See "go doc internal/dag" for
	// the syntax.
	//
	// "a < b" means a must be acquired before b if both are held
	// (or, if b is held, a cannot be acquired).
	//
	// "NONE < a" means no locks may be held when a is acquired.
	//
	// If a lock is not given a rank, then it is assumed to be a leaf
	// lock, which means no other lock can be acquired while it is held.
	// Therefore, leaf locks do not need to be given an explicit rank.
	//
	// Ranks in all caps are pseudo-nodes that help define order, but do
	// not actually define a rank.
	//
	// TODO: It's often hard to correlate rank names to locks. Change
	// these to be more consistent with the locks they label.
	const ranks = `
	# Sysmon
	NONE
	< sysmon
	< scavenge, forcegc;

	# Defer
	NONE < defer;

	# GC
	NONE <
	sweepWaiters,
	assistQueue,
	sweep;

	# Scheduler, timers, netpoll
	NONE < pollDesc, cpuprof;
	assistQueue,
	cpuprof,
	forcegc,
	pollDesc, # pollDesc can interact with timers, which can lock sched.
	scavenge,
	sweep,
	sweepWaiters
	< sched;
	sched < allg, allp;
	allp < timers;
	timers < netpollInit;

	# Channels
	scavenge, sweep < hchan;
	NONE < notifyList;
	hchan, notifyList < sudog;

	# RWMutex
	NONE < rwmutexW;
	rwmutexW, sysmon < rwmutexR;

	# Semaphores
	NONE < root;

	# Itabs
	NONE
	< itab
	< reflectOffs;

	# User arena state
	NONE < userArenaState;

	# Tracing without a P uses a global trace buffer.
	scavenge
	# Above TRACEGLOBAL can emit a trace event without a P.
	< TRACEGLOBAL
	# Below TRACEGLOBAL manages the global tracing buffer.
	# Note that traceBuf eventually chains to MALLOC, but we never get that far
	# in the situation where there's no P.
	< traceBuf;
	# Starting/stopping tracing traces strings.
	traceBuf < traceStrings;

	# Malloc
	allg,
	hchan,
	notifyList,
	reflectOffs,
	timers,
	traceStrings,
	userArenaState
	# Above MALLOC are things that can allocate memory.
	< MALLOC
	# Below MALLOC is the malloc implementation.
	< fin,
	gcBitsArenas,
	mheapSpecial,
	mspanSpecial,
	spanSetSpine,
	MPROF;

	# Memory profiling
	MPROF < profInsert, profBlock, profMemActive;
	profMemActive < profMemFuture;

	# Stack allocation and copying
	gcBitsArenas,
	netpollInit,
	profBlock,
	profInsert,
	profMemFuture,
	spanSetSpine,
	fin,
	root
	# Anything that can grow the stack can acquire STACKGROW.
	# (Most higher layers imply STACKGROW, like MALLOC.)
	< STACKGROW
	# Below STACKGROW is the stack allocator/copying implementation.
	< gscan;
	gscan, rwmutexR < stackpool;
	gscan < stackLarge;
	# Generally, hchan must be acquired before gscan. But in one case,
	# where we suspend a G and then shrink its stack, syncadjustsudogs
	# can acquire hchan locks while holding gscan. To allow this case,
	# we use hchanLeaf instead of hchan.
	gscan < hchanLeaf;

	# Write barrier
	defer,
	gscan,
	mspanSpecial,
	sudog
	# Anything that can have write barriers can acquire WB.
	# Above WB, we can have write barriers.
	< WB
	# Below WB is the write barrier implementation.
	< wbufSpans;

	# Span allocator
	stackLarge,
	stackpool,
	wbufSpans
	# Above mheap is anything that can call the span allocator.
	< mheap;
	# Below mheap is the span allocator implementation.
	mheap, mheapSpecial < globalAlloc;

	# Execution tracer events (with a P)
	hchan,
	mheap,
	root,
	sched,
	traceStrings,
	notifyList,
	fin
	# Above TRACE is anything that can create a trace event
	< TRACE
	< trace
	< traceStackTab;

	# panic is handled specially. It is implicitly below all other locks.
	NONE < panic;
	# deadlock is not acquired while holding panic, but it also needs to be
	# below all other locks.
	panic < deadlock;
	`

	// cyclicRanks lists lock ranks that allow multiple locks of the same
	// rank to be acquired simultaneously. The runtime enforces ordering
	// within these ranks using a separate mechanism.
	var cyclicRanks = map[string]bool{
	// Multiple timers are locked simultaneously in destroy().
	"timers": true,
	// Multiple hchans are acquired in hchan.sortkey() order in
	// select.
	"hchan": true,
	// Multiple hchanLeafs are acquired in hchan.sortkey() order in
	// syncadjustsudogs().
	"hchanLeaf": true,
	// The point of the deadlock lock is to deadlock.
	"deadlock": true,
	}

	func main() {
	flagO := flag.String("o", "", "write to `file` instead of stdout")
	flagDot := flag.Bool("dot", false, "emit graphviz output instead of Go")
	flag.Parse()
	if flag.NArg() != 0 {
	fmt.Fprintf(os.Stderr, "too many arguments")
	os.Exit(2)
	}

	g, err := dag.Parse(ranks)
	if err != nil {
	log.Fatal(err)
	}

	var out []byte
	if *flagDot {
	var b bytes.Buffer
	g.TransitiveReduction()
	// Add cyclic edges for visualization.
	for k := range cyclicRanks {
	g.AddEdge(k, k)
	}
	// Reverse the graph. It's much easier to read this as
	// a "<" partial order than a ">" partial order. This
	// ways, locks are acquired from the top going down
	// and time moves forward over the edges instead of
	// backward.
	g.Transpose()
	generateDot(&b, g)
	out = b.Bytes()
	} else {
	var b bytes.Buffer
	generateGo(&b, g)
	out, err = format.Source(b.Bytes())
	if err != nil {
	log.Fatal(err)
	}
	}

	if *flagO != "" {
	err = os.WriteFile(*flagO, out, 0666)
	} else {
	_, err = os.Stdout.Write(out)
	}
	if err != nil {
	log.Fatal(err)
	}
	}

	func generateGo(w io.Writer, g *dag.Graph) {
	fmt.Fprintf(w, `// Code generated by mklockrank.go; DO NOT EDIT.

	package runtime

	type lockRank int

	`)

	// Create numeric ranks.
	topo := g.Topo()
	for i, j := 0, len(topo)-1; i < j; i, j = i+1, j-1 {
	topo[i], topo[j] = topo[j], topo[i]
	}
	fmt.Fprintf(w, `
	// Constants representing the ranks of all non-leaf runtime locks, in rank order.
	// Locks with lower rank must be taken before locks with higher rank,
	// in addition to satisfying the partial order in lockPartialOrder.
	// A few ranks allow self-cycles, which are specified in lockPartialOrder.
	const (
	lockRankUnknown lockRank = iota

	`)
	for _, rank := range topo {
	if isPseudo(rank) {
	fmt.Fprintf(w, "\t// %s\n", rank)
	} else {
	fmt.Fprintf(w, "\t%s\n", cname(rank))
	}
	}
	fmt.Fprintf(w, `)

	// lockRankLeafRank is the rank of lock that does not have a declared rank,
	// and hence is a leaf lock.
	const lockRankLeafRank lockRank = 1000
	`)

	// Create string table.
	fmt.Fprintf(w, `
	// lockNames gives the names associated with each of the above ranks.
	var lockNames = []string{
	`)
	for _, rank := range topo {
	if !isPseudo(rank) {
	fmt.Fprintf(w, "\t%s: %q,\n", cname(rank), rank)
	}
	}
	fmt.Fprintf(w, `}

	func (rank lockRank) String() string {
	if rank == 0 {
	return "UNKNOWN"
	}
	if rank == lockRankLeafRank {
	return "LEAF"
	}
	if rank < 0 \|\| int(rank) >= len(lockNames) {
	return "BAD RANK"
	}
	return lockNames[rank]
	}
	`)

	// Create partial order structure.
	fmt.Fprintf(w, `
	// lockPartialOrder is the transitive closure of the lock rank graph.
	// An entry for rank X lists all of the ranks that can already be held
	// when rank X is acquired.
	//
	// Lock ranks that allow self-cycles list themselves.
	var lockPartialOrder [][]lockRank = [][]lockRank{
	`)
	for _, rank := range topo {
	if isPseudo(rank) {
	continue
	}
	list := []string{}
	for _, before := range g.Edges(rank) {
	if !isPseudo(before) {
	list = append(list, cname(before))
	}
	}
	if cyclicRanks[rank] {
	list = append(list, cname(rank))
	}

	fmt.Fprintf(w, "\t%s: {%s},\n", cname(rank), strings.Join(list, ", "))
	}
	fmt.Fprintf(w, "}\n")
	}

	// cname returns the Go const name for the given lock rank label.
	func cname(label string) string {
	return "lockRank" + strings.ToUpper(label[:1]) + label[1:]
	}

	func isPseudo(label string) bool {
	return strings.ToUpper(label) == label
	}

	// generateDot emits a Graphviz dot representation of g to w.
	func generateDot(w io.Writer, g *dag.Graph) {
	fmt.Fprintf(w, "digraph g {\n")

	// Define all nodes.
	for _, node := range g.Nodes {
	fmt.Fprintf(w, "%q;\n", node)
	}

	// Create edges.
	for _, node := range g.Nodes {
	for _, to := range g.Edges(node) {
	fmt.Fprintf(w, "%q -> %q;\n", node, to)
	}
	}

	fmt.Fprintf(w, "}\n")
	}