src/internal/dag/parse.go - platform/prebuilts/go/darwin-x86 - 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.

 // Package dag implements a language for expressing directed acyclic
 // graphs.
 //
 // The general syntax of a rule is:
 //
 //	a, b < c, d;
 //
 // which means c and d come after a and b in the partial order
 // (that is, there are edges from c and d to a and b),
 // but doesn't provide a relative order between a vs b or c vs d.
 //
 // The rules can chain together, as in:
 //
 //	e < f, g < h;
 //
 // which is equivalent to
 //
 //	e < f, g;
 //	f, g < h;
 //
 // Except for the special bottom element "NONE", each name
 // must appear exactly once on the right-hand side of any rule.
 // That rule serves as the definition of the allowed successor
 // for that name. The definition must appear before any uses
 // of the name on the left-hand side of a rule. (That is, the
 // rules themselves must be ordered according to the partial
 // order, for easier reading by people.)
 //
 // Negative assertions double-check the partial order:
 //
 //	i !< j
 //
 // means that it must NOT be the case that i < j.
 // Negative assertions may appear anywhere in the rules,
 // even before i and j have been defined.
 //
 // Comments begin with #.
 package dag

 import (
 	"fmt"
 	"sort"
 	"strings"
 )

 type Graph struct {
 	Nodes   []string
 	byLabel map[string]int
 	edges   map[string]map[string]bool
 }

 func newGraph() *Graph {
 	return &Graph{byLabel: map[string]int{}, edges: map[string]map[string]bool{}}
 }

 func (g *Graph) addNode(label string) bool {
 	if _, ok := g.byLabel[label]; ok {
 		return false
 	}
 	g.byLabel[label] = len(g.Nodes)
 	g.Nodes = append(g.Nodes, label)
 	g.edges[label] = map[string]bool{}
 	return true
 }

 func (g *Graph) AddEdge(from, to string) {
 	g.edges[from][to] = true
 }

 func (g *Graph) DelEdge(from, to string) {
 	delete(g.edges[from], to)
 }

 func (g *Graph) HasEdge(from, to string) bool {
 	return g.edges[from] != nil && g.edges[from][to]
 }

 func (g *Graph) Edges(from string) []string {
 	edges := make([]string, 0, 16)
 	for k := range g.edges[from] {
 		edges = append(edges, k)
 	}
 	sort.Slice(edges, func(i, j int) bool { return g.byLabel[edges[i]] < g.byLabel[edges[j]] })
 	return edges
 }

 // Parse parses the DAG language and returns the transitive closure of
 // the described graph. In the returned graph, there is an edge from "b"
 // to "a" if b < a (or a > b) in the partial order.
 func Parse(dag string) (*Graph, error) {
 	g := newGraph()
 	disallowed := []rule{}

 	rules, err := parseRules(dag)
 	if err != nil {
 		return nil, err
 	}

 	// TODO: Add line numbers to errors.
 	var errors []string
 	errorf := func(format string, a ...any) {
 		errors = append(errors, fmt.Sprintf(format, a...))
 	}
 	for _, r := range rules {
 		if r.op == "!<" {
 			disallowed = append(disallowed, r)
 			continue
 		}
 		for _, def := range r.def {
 			if def == "NONE" {
 				errorf("NONE cannot be a predecessor")
 				continue
 			}
 			if !g.addNode(def) {
 				errorf("multiple definitions for %s", def)
 			}
 			for _, less := range r.less {
 				if less == "NONE" {
 					continue
 				}
 				if _, ok := g.byLabel[less]; !ok {
 					errorf("use of %s before its definition", less)
 				} else {
 					g.AddEdge(def, less)
 				}
 			}
 		}
 	}

 	// Check for missing definition.
 	for _, tos := range g.edges {
 		for to := range tos {
 			if g.edges[to] == nil {
 				errorf("missing definition for %s", to)
 			}
 		}
 	}

 	// Complete transitive closure.
 	for _, k := range g.Nodes {
 		for _, i := range g.Nodes {
 			for _, j := range g.Nodes {
 				if i != k && k != j && g.HasEdge(i, k) && g.HasEdge(k, j) {
 					if i == j {
 						// Can only happen along with a "use of X before deps" error above,
 						// but this error is more specific - it makes clear that reordering the
 						// rules will not be enough to fix the problem.
 						errorf("graph cycle: %s < %s < %s", j, k, i)
 					}
 					g.AddEdge(i, j)
 				}
 			}
 		}
 	}

 	// Check negative assertions against completed allowed graph.
 	for _, bad := range disallowed {
 		for _, less := range bad.less {
 			for _, def := range bad.def {
 				if g.HasEdge(def, less) {
 					errorf("graph edge assertion failed: %s !< %s", less, def)
 				}
 			}
 		}
 	}

 	if len(errors) > 0 {
 		return nil, fmt.Errorf("%s", strings.Join(errors, "\n"))
 	}

 	return g, nil
 }

 // A rule is a line in the DAG language where "less < def" or "less !< def".
 type rule struct {
 	less []string
 	op   string // Either "<" or "!<"
 	def  []string
 }

 type syntaxError string

 func (e syntaxError) Error() string {
 	return string(e)
 }

 // parseRules parses the rules of a DAG.
 func parseRules(rules string) (out []rule, err error) {
 	defer func() {
 		e := recover()
 		switch e := e.(type) {
 		case nil:
 			return
 		case syntaxError:
 			err = e
 		default:
 			panic(e)
 		}
 	}()
 	p := &rulesParser{lineno: 1, text: rules}

 	var prev []string
 	var op string
 	for {
 		list, tok := p.nextList()
 		if tok == "" {
 			if prev == nil {
 				break
 			}
 			p.syntaxError("unexpected EOF")
 		}
 		if prev != nil {
 			out = append(out, rule{prev, op, list})
 		}
 		prev = list
 		if tok == ";" {
 			prev = nil
 			op = ""
 			continue
 		}
 		if tok != "<" && tok != "!<" {
 			p.syntaxError("missing <")
 		}
 		op = tok
 	}

 	return out, err
 }

 // A rulesParser parses the depsRules syntax described above.
 type rulesParser struct {
 	lineno   int
 	lastWord string
 	text     string
 }

 // syntaxError reports a parsing error.
 func (p *rulesParser) syntaxError(msg string) {
 	panic(syntaxError(fmt.Sprintf("parsing graph: line %d: syntax error: %s near %s", p.lineno, msg, p.lastWord)))
 }

 // nextList parses and returns a comma-separated list of names.
 func (p *rulesParser) nextList() (list []string, token string) {
 	for {
 		tok := p.nextToken()
 		switch tok {
 		case "":
 			if len(list) == 0 {
 				return nil, ""
 			}
 			fallthrough
 		case ",", "<", "!<", ";":
 			p.syntaxError("bad list syntax")
 		}
 		list = append(list, tok)

 		tok = p.nextToken()
 		if tok != "," {
 			return list, tok
 		}
 	}
 }

 // nextToken returns the next token in the deps rules,
 // one of ";" "," "<" "!<" or a name.
 func (p *rulesParser) nextToken() string {
 	for {
 		if p.text == "" {
 			return ""
 		}
 		switch p.text[0] {
 		case ';', ',', '<':
 			t := p.text[:1]
 			p.text = p.text[1:]
 			return t

 		case '!':
 			if len(p.text) < 2 || p.text[1] != '<' {
 				p.syntaxError("unexpected token !")
 			}
 			p.text = p.text[2:]
 			return "!<"

 		case '#':
 			i := strings.Index(p.text, "\n")
 			if i < 0 {
 				i = len(p.text)
 			}
 			p.text = p.text[i:]
 			continue

 		case '\n':
 			p.lineno++
 			fallthrough
 		case ' ', '\t':
 			p.text = p.text[1:]
 			continue

 		default:
 			i := strings.IndexAny(p.text, "!;,<#\n \t")
 			if i < 0 {
 				i = len(p.text)
 			}
 			t := p.text[:i]
 			p.text = p.text[i:]
 			p.lastWord = t
 			return t
 		}
 	}
 }
	// 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.

	// Package dag implements a language for expressing directed acyclic
	// graphs.
	//
	// The general syntax of a rule is:
	//
	// a, b < c, d;
	//
	// which means c and d come after a and b in the partial order
	// (that is, there are edges from c and d to a and b),
	// but doesn't provide a relative order between a vs b or c vs d.
	//
	// The rules can chain together, as in:
	//
	// e < f, g < h;
	//
	// which is equivalent to
	//
	// e < f, g;
	// f, g < h;
	//
	// Except for the special bottom element "NONE", each name
	// must appear exactly once on the right-hand side of any rule.
	// That rule serves as the definition of the allowed successor
	// for that name. The definition must appear before any uses
	// of the name on the left-hand side of a rule. (That is, the
	// rules themselves must be ordered according to the partial
	// order, for easier reading by people.)
	//
	// Negative assertions double-check the partial order:
	//
	// i !< j
	//
	// means that it must NOT be the case that i < j.
	// Negative assertions may appear anywhere in the rules,
	// even before i and j have been defined.
	//
	// Comments begin with #.
	package dag

	import (
	"fmt"
	"sort"
	"strings"
	)

	type Graph struct {
	Nodes []string
	byLabel map[string]int
	edges map[string]map[string]bool
	}

	func newGraph() *Graph {
	return &Graph{byLabel: map[string]int{}, edges: map[string]map[string]bool{}}
	}

	func (g *Graph) addNode(label string) bool {
	if _, ok := g.byLabel[label]; ok {
	return false
	}
	g.byLabel[label] = len(g.Nodes)
	g.Nodes = append(g.Nodes, label)
	g.edges[label] = map[string]bool{}
	return true
	}

	func (g *Graph) AddEdge(from, to string) {
	g.edges[from][to] = true
	}

	func (g *Graph) DelEdge(from, to string) {
	delete(g.edges[from], to)
	}

	func (g *Graph) HasEdge(from, to string) bool {
	return g.edges[from] != nil && g.edges[from][to]
	}

	func (g *Graph) Edges(from string) []string {
	edges := make([]string, 0, 16)
	for k := range g.edges[from] {
	edges = append(edges, k)
	}
	sort.Slice(edges, func(i, j int) bool { return g.byLabel[edges[i]] < g.byLabel[edges[j]] })
	return edges
	}

	// Parse parses the DAG language and returns the transitive closure of
	// the described graph. In the returned graph, there is an edge from "b"
	// to "a" if b < a (or a > b) in the partial order.
	func Parse(dag string) (*Graph, error) {
	g := newGraph()
	disallowed := []rule{}

	rules, err := parseRules(dag)
	if err != nil {
	return nil, err
	}

	// TODO: Add line numbers to errors.
	var errors []string
	errorf := func(format string, a ...any) {
	errors = append(errors, fmt.Sprintf(format, a...))
	}
	for _, r := range rules {
	if r.op == "!<" {
	disallowed = append(disallowed, r)
	continue
	}
	for _, def := range r.def {
	if def == "NONE" {
	errorf("NONE cannot be a predecessor")
	continue
	}
	if !g.addNode(def) {
	errorf("multiple definitions for %s", def)
	}
	for _, less := range r.less {
	if less == "NONE" {
	continue
	}
	if _, ok := g.byLabel[less]; !ok {
	errorf("use of %s before its definition", less)
	} else {
	g.AddEdge(def, less)
	}
	}
	}
	}

	// Check for missing definition.
	for _, tos := range g.edges {
	for to := range tos {
	if g.edges[to] == nil {
	errorf("missing definition for %s", to)
	}
	}
	}

	// Complete transitive closure.
	for _, k := range g.Nodes {
	for _, i := range g.Nodes {
	for _, j := range g.Nodes {
	if i != k && k != j && g.HasEdge(i, k) && g.HasEdge(k, j) {
	if i == j {
	// Can only happen along with a "use of X before deps" error above,
	// but this error is more specific - it makes clear that reordering the
	// rules will not be enough to fix the problem.
	errorf("graph cycle: %s < %s < %s", j, k, i)
	}
	g.AddEdge(i, j)
	}
	}
	}
	}

	// Check negative assertions against completed allowed graph.
	for _, bad := range disallowed {
	for _, less := range bad.less {
	for _, def := range bad.def {
	if g.HasEdge(def, less) {
	errorf("graph edge assertion failed: %s !< %s", less, def)
	}
	}
	}
	}

	if len(errors) > 0 {
	return nil, fmt.Errorf("%s", strings.Join(errors, "\n"))
	}

	return g, nil
	}

	// A rule is a line in the DAG language where "less < def" or "less !< def".
	type rule struct {
	less []string
	op string // Either "<" or "!<"
	def []string
	}

	type syntaxError string

	func (e syntaxError) Error() string {
	return string(e)
	}

	// parseRules parses the rules of a DAG.
	func parseRules(rules string) (out []rule, err error) {
	defer func() {
	e := recover()
	switch e := e.(type) {
	case nil:
	return
	case syntaxError:
	err = e
	default:
	panic(e)
	}
	}()
	p := &rulesParser{lineno: 1, text: rules}

	var prev []string
	var op string
	for {
	list, tok := p.nextList()
	if tok == "" {
	if prev == nil {
	break
	}
	p.syntaxError("unexpected EOF")
	}
	if prev != nil {
	out = append(out, rule{prev, op, list})
	}
	prev = list
	if tok == ";" {
	prev = nil
	op = ""
	continue
	}
	if tok != "<" && tok != "!<" {
	p.syntaxError("missing <")
	}
	op = tok
	}

	return out, err
	}

	// A rulesParser parses the depsRules syntax described above.
	type rulesParser struct {
	lineno int
	lastWord string
	text string
	}

	// syntaxError reports a parsing error.
	func (p *rulesParser) syntaxError(msg string) {
	panic(syntaxError(fmt.Sprintf("parsing graph: line %d: syntax error: %s near %s", p.lineno, msg, p.lastWord)))
	}

	// nextList parses and returns a comma-separated list of names.
	func (p *rulesParser) nextList() (list []string, token string) {
	for {
	tok := p.nextToken()
	switch tok {
	case "":
	if len(list) == 0 {
	return nil, ""
	}
	fallthrough
	case ",", "<", "!<", ";":
	p.syntaxError("bad list syntax")
	}
	list = append(list, tok)

	tok = p.nextToken()
	if tok != "," {
	return list, tok
	}
	}
	}

	// nextToken returns the next token in the deps rules,
	// one of ";" "," "<" "!<" or a name.
	func (p *rulesParser) nextToken() string {
	for {
	if p.text == "" {
	return ""
	}
	switch p.text[0] {
	case ';', ',', '<':
	t := p.text[:1]
	p.text = p.text[1:]
	return t

	case '!':
	if len(p.text) < 2 \|\| p.text[1] != '<' {
	p.syntaxError("unexpected token !")
	}
	p.text = p.text[2:]
	return "!<"

	case '#':
	i := strings.Index(p.text, "\n")
	if i < 0 {
	i = len(p.text)
	}
	p.text = p.text[i:]
	continue

	case '\n':
	p.lineno++
	fallthrough
	case ' ', '\t':
	p.text = p.text[1:]
	continue

	default:
	i := strings.IndexAny(p.text, "!;,<#\n \t")
	if i < 0 {
	i = len(p.text)
	}
	t := p.text[:i]
	p.text = p.text[i:]
	p.lastWord = t
	return t
	}
	}
	}