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Diffstat (limited to 'src/go/build/constraint/expr.go')
-rw-r--r-- | src/go/build/constraint/expr.go | 577 |
1 files changed, 577 insertions, 0 deletions
diff --git a/src/go/build/constraint/expr.go b/src/go/build/constraint/expr.go new file mode 100644 index 0000000..957eb9b --- /dev/null +++ b/src/go/build/constraint/expr.go @@ -0,0 +1,577 @@ +// Copyright 2020 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 constraint implements parsing and evaluation of build constraint lines. +// See https://golang.org/cmd/go/#hdr-Build_constraints for documentation about build constraints themselves. +// +// This package parses both the original “// +build” syntax and the “//go:build” syntax that will be added in Go 1.17. +// The parser is being included in Go 1.16 to allow tools that need to process Go 1.17 source code +// to still be built against the Go 1.16 release. +// See https://golang.org/design/draft-gobuild for details about the “//go:build” syntax. +package constraint + +import ( + "errors" + "strings" + "unicode" + "unicode/utf8" +) + +// An Expr is a build tag constraint expression. +// The underlying concrete type is *AndExpr, *OrExpr, *NotExpr, or *TagExpr. +type Expr interface { + // String returns the string form of the expression, + // using the boolean syntax used in //go:build lines. + String() string + + // Eval reports whether the expression evaluates to true. + // It calls ok(tag) as needed to find out whether a given build tag + // is satisfied by the current build configuration. + Eval(ok func(tag string) bool) bool + + // The presence of an isExpr method explicitly marks the type as an Expr. + // Only implementations in this package should be used as Exprs. + isExpr() +} + +// A TagExpr is an Expr for the single tag Tag. +type TagExpr struct { + Tag string // for example, “linux” or “cgo” +} + +func (x *TagExpr) isExpr() {} + +func (x *TagExpr) Eval(ok func(tag string) bool) bool { + return ok(x.Tag) +} + +func (x *TagExpr) String() string { + return x.Tag +} + +func tag(tag string) Expr { return &TagExpr{tag} } + +// A NotExpr represents the expression !X (the negation of X). +type NotExpr struct { + X Expr +} + +func (x *NotExpr) isExpr() {} + +func (x *NotExpr) Eval(ok func(tag string) bool) bool { + return !x.X.Eval(ok) +} + +func (x *NotExpr) String() string { + s := x.X.String() + switch x.X.(type) { + case *AndExpr, *OrExpr: + s = "(" + s + ")" + } + return "!" + s +} + +func not(x Expr) Expr { return &NotExpr{x} } + +// An AndExpr represents the expression X && Y. +type AndExpr struct { + X, Y Expr +} + +func (x *AndExpr) isExpr() {} + +func (x *AndExpr) Eval(ok func(tag string) bool) bool { + // Note: Eval both, to make sure ok func observes all tags. + xok := x.X.Eval(ok) + yok := x.Y.Eval(ok) + return xok && yok +} + +func (x *AndExpr) String() string { + return andArg(x.X) + " && " + andArg(x.Y) +} + +func andArg(x Expr) string { + s := x.String() + if _, ok := x.(*OrExpr); ok { + s = "(" + s + ")" + } + return s +} + +func and(x, y Expr) Expr { + return &AndExpr{x, y} +} + +// An OrExpr represents the expression X || Y. +type OrExpr struct { + X, Y Expr +} + +func (x *OrExpr) isExpr() {} + +func (x *OrExpr) Eval(ok func(tag string) bool) bool { + // Note: Eval both, to make sure ok func observes all tags. + xok := x.X.Eval(ok) + yok := x.Y.Eval(ok) + return xok || yok +} + +func (x *OrExpr) String() string { + return orArg(x.X) + " || " + orArg(x.Y) +} + +func orArg(x Expr) string { + s := x.String() + if _, ok := x.(*AndExpr); ok { + s = "(" + s + ")" + } + return s +} + +func or(x, y Expr) Expr { + return &OrExpr{x, y} +} + +// A SyntaxError reports a syntax error in a parsed build expression. +type SyntaxError struct { + Offset int // byte offset in input where error was detected + Err string // description of error +} + +func (e *SyntaxError) Error() string { + return e.Err +} + +var errNotConstraint = errors.New("not a build constraint") + +// Parse parses a single build constraint line of the form “//go:build ...” or “// +build ...” +// and returns the corresponding boolean expression. +func Parse(line string) (Expr, error) { + if text, ok := splitGoBuild(line); ok { + return parseExpr(text) + } + if text, ok := splitPlusBuild(line); ok { + return parsePlusBuildExpr(text), nil + } + return nil, errNotConstraint +} + +// IsGoBuild reports whether the line of text is a “//go:build” constraint. +// It only checks the prefix of the text, not that the expression itself parses. +func IsGoBuild(line string) bool { + _, ok := splitGoBuild(line) + return ok +} + +// splitGoBuild splits apart the leading //go:build prefix in line from the build expression itself. +// It returns "", false if the input is not a //go:build line or if the input contains multiple lines. +func splitGoBuild(line string) (expr string, ok bool) { + // A single trailing newline is OK; otherwise multiple lines are not. + if len(line) > 0 && line[len(line)-1] == '\n' { + line = line[:len(line)-1] + } + if strings.Contains(line, "\n") { + return "", false + } + + if !strings.HasPrefix(line, "//go:build") { + return "", false + } + + line = strings.TrimSpace(line) + line = line[len("//go:build"):] + + // If strings.TrimSpace finds more to trim after removing the //go:build prefix, + // it means that the prefix was followed by a space, making this a //go:build line + // (as opposed to a //go:buildsomethingelse line). + // If line is empty, we had "//go:build" by itself, which also counts. + trim := strings.TrimSpace(line) + if len(line) == len(trim) && line != "" { + return "", false + } + + return trim, true +} + +// An exprParser holds state for parsing a build expression. +type exprParser struct { + s string // input string + i int // next read location in s + + tok string // last token read + isTag bool + pos int // position (start) of last token +} + +// parseExpr parses a boolean build tag expression. +func parseExpr(text string) (x Expr, err error) { + defer func() { + if e := recover(); e != nil { + if e, ok := e.(*SyntaxError); ok { + err = e + return + } + panic(e) // unreachable unless parser has a bug + } + }() + + p := &exprParser{s: text} + x = p.or() + if p.tok != "" { + panic(&SyntaxError{Offset: p.pos, Err: "unexpected token " + p.tok}) + } + return x, nil +} + +// or parses a sequence of || expressions. +// On entry, the next input token has not yet been lexed. +// On exit, the next input token has been lexed and is in p.tok. +func (p *exprParser) or() Expr { + x := p.and() + for p.tok == "||" { + x = or(x, p.and()) + } + return x +} + +// and parses a sequence of && expressions. +// On entry, the next input token has not yet been lexed. +// On exit, the next input token has been lexed and is in p.tok. +func (p *exprParser) and() Expr { + x := p.not() + for p.tok == "&&" { + x = and(x, p.not()) + } + return x +} + +// not parses a ! expression. +// On entry, the next input token has not yet been lexed. +// On exit, the next input token has been lexed and is in p.tok. +func (p *exprParser) not() Expr { + p.lex() + if p.tok == "!" { + p.lex() + if p.tok == "!" { + panic(&SyntaxError{Offset: p.pos, Err: "double negation not allowed"}) + } + return not(p.atom()) + } + return p.atom() +} + +// atom parses a tag or a parenthesized expression. +// On entry, the next input token HAS been lexed. +// On exit, the next input token has been lexed and is in p.tok. +func (p *exprParser) atom() Expr { + // first token already in p.tok + if p.tok == "(" { + pos := p.pos + defer func() { + if e := recover(); e != nil { + if e, ok := e.(*SyntaxError); ok && e.Err == "unexpected end of expression" { + e.Err = "missing close paren" + } + panic(e) + } + }() + x := p.or() + if p.tok != ")" { + panic(&SyntaxError{Offset: pos, Err: "missing close paren"}) + } + p.lex() + return x + } + + if !p.isTag { + if p.tok == "" { + panic(&SyntaxError{Offset: p.pos, Err: "unexpected end of expression"}) + } + panic(&SyntaxError{Offset: p.pos, Err: "unexpected token " + p.tok}) + } + tok := p.tok + p.lex() + return tag(tok) +} + +// lex finds and consumes the next token in the input stream. +// On return, p.tok is set to the token text, +// p.isTag reports whether the token was a tag, +// and p.pos records the byte offset of the start of the token in the input stream. +// If lex reaches the end of the input, p.tok is set to the empty string. +// For any other syntax error, lex panics with a SyntaxError. +func (p *exprParser) lex() { + p.isTag = false + for p.i < len(p.s) && (p.s[p.i] == ' ' || p.s[p.i] == '\t') { + p.i++ + } + if p.i >= len(p.s) { + p.tok = "" + p.pos = p.i + return + } + switch p.s[p.i] { + case '(', ')', '!': + p.pos = p.i + p.i++ + p.tok = p.s[p.pos:p.i] + return + + case '&', '|': + if p.i+1 >= len(p.s) || p.s[p.i+1] != p.s[p.i] { + panic(&SyntaxError{Offset: p.i, Err: "invalid syntax at " + string(rune(p.s[p.i]))}) + } + p.pos = p.i + p.i += 2 + p.tok = p.s[p.pos:p.i] + return + } + + tag := p.s[p.i:] + for i, c := range tag { + if !unicode.IsLetter(c) && !unicode.IsDigit(c) && c != '_' && c != '.' { + tag = tag[:i] + break + } + } + if tag == "" { + c, _ := utf8.DecodeRuneInString(p.s[p.i:]) + panic(&SyntaxError{Offset: p.i, Err: "invalid syntax at " + string(c)}) + } + + p.pos = p.i + p.i += len(tag) + p.tok = p.s[p.pos:p.i] + p.isTag = true + return +} + +// IsPlusBuild reports whether the line of text is a “// +build” constraint. +// It only checks the prefix of the text, not that the expression itself parses. +func IsPlusBuild(line string) bool { + _, ok := splitPlusBuild(line) + return ok +} + +// splitPlusBuild splits apart the leading // +build prefix in line from the build expression itself. +// It returns "", false if the input is not a // +build line or if the input contains multiple lines. +func splitPlusBuild(line string) (expr string, ok bool) { + // A single trailing newline is OK; otherwise multiple lines are not. + if len(line) > 0 && line[len(line)-1] == '\n' { + line = line[:len(line)-1] + } + if strings.Contains(line, "\n") { + return "", false + } + + if !strings.HasPrefix(line, "//") { + return "", false + } + line = line[len("//"):] + // Note the space is optional; "//+build" is recognized too. + line = strings.TrimSpace(line) + + if !strings.HasPrefix(line, "+build") { + return "", false + } + line = line[len("+build"):] + + // If strings.TrimSpace finds more to trim after removing the +build prefix, + // it means that the prefix was followed by a space, making this a +build line + // (as opposed to a +buildsomethingelse line). + // If line is empty, we had "// +build" by itself, which also counts. + trim := strings.TrimSpace(line) + if len(line) == len(trim) && line != "" { + return "", false + } + + return trim, true +} + +// parsePlusBuildExpr parses a legacy build tag expression (as used with “// +build”). +func parsePlusBuildExpr(text string) Expr { + var x Expr + for _, clause := range strings.Fields(text) { + var y Expr + for _, lit := range strings.Split(clause, ",") { + var z Expr + var neg bool + if strings.HasPrefix(lit, "!!") || lit == "!" { + z = tag("ignore") + } else { + if strings.HasPrefix(lit, "!") { + neg = true + lit = lit[len("!"):] + } + if isValidTag(lit) { + z = tag(lit) + } else { + z = tag("ignore") + } + if neg { + z = not(z) + } + } + if y == nil { + y = z + } else { + y = and(y, z) + } + } + if x == nil { + x = y + } else { + x = or(x, y) + } + } + if x == nil { + x = tag("ignore") + } + return x +} + +// isValidTag reports whether the word is a valid build tag. +// Tags must be letters, digits, underscores or dots. +// Unlike in Go identifiers, all digits are fine (e.g., "386"). +func isValidTag(word string) bool { + if word == "" { + return false + } + for _, c := range word { + if !unicode.IsLetter(c) && !unicode.IsDigit(c) && c != '_' && c != '.' { + return false + } + } + return true +} + +var errComplex = errors.New("expression too complex for // +build lines") + +// PlusBuildLines returns a sequence of “// +build” lines that evaluate to the build expression x. +// If the expression is too complex to convert directly to “// +build” lines, PlusBuildLines returns an error. +func PlusBuildLines(x Expr) ([]string, error) { + // Push all NOTs to the expression leaves, so that //go:build !(x && y) can be treated as !x || !y. + // This rewrite is both efficient and commonly needed, so it's worth doing. + // Essentially all other possible rewrites are too expensive and too rarely needed. + x = pushNot(x, false) + + // Split into AND of ORs of ANDs of literals (tag or NOT tag). + var split [][][]Expr + for _, or := range appendSplitAnd(nil, x) { + var ands [][]Expr + for _, and := range appendSplitOr(nil, or) { + var lits []Expr + for _, lit := range appendSplitAnd(nil, and) { + switch lit.(type) { + case *TagExpr, *NotExpr: + lits = append(lits, lit) + default: + return nil, errComplex + } + } + ands = append(ands, lits) + } + split = append(split, ands) + } + + // If all the ORs have length 1 (no actual OR'ing going on), + // push the top-level ANDs to the bottom level, so that we get + // one // +build line instead of many. + maxOr := 0 + for _, or := range split { + if maxOr < len(or) { + maxOr = len(or) + } + } + if maxOr == 1 { + var lits []Expr + for _, or := range split { + lits = append(lits, or[0]...) + } + split = [][][]Expr{{lits}} + } + + // Prepare the +build lines. + var lines []string + for _, or := range split { + line := "// +build" + for _, and := range or { + clause := "" + for i, lit := range and { + if i > 0 { + clause += "," + } + clause += lit.String() + } + line += " " + clause + } + lines = append(lines, line) + } + + return lines, nil +} + +// pushNot applies DeMorgan's law to push negations down the expression, +// so that only tags are negated in the result. +// (It applies the rewrites !(X && Y) => (!X || !Y) and !(X || Y) => (!X && !Y).) +func pushNot(x Expr, not bool) Expr { + switch x := x.(type) { + default: + // unreachable + return x + case *NotExpr: + if _, ok := x.X.(*TagExpr); ok && !not { + return x + } + return pushNot(x.X, !not) + case *TagExpr: + if not { + return &NotExpr{X: x} + } + return x + case *AndExpr: + x1 := pushNot(x.X, not) + y1 := pushNot(x.Y, not) + if not { + return or(x1, y1) + } + if x1 == x.X && y1 == x.Y { + return x + } + return and(x1, y1) + case *OrExpr: + x1 := pushNot(x.X, not) + y1 := pushNot(x.Y, not) + if not { + return and(x1, y1) + } + if x1 == x.X && y1 == x.Y { + return x + } + return or(x1, y1) + } +} + +// appendSplitAnd appends x to list while splitting apart any top-level && expressions. +// For example, appendSplitAnd({W}, X && Y && Z) = {W, X, Y, Z}. +func appendSplitAnd(list []Expr, x Expr) []Expr { + if x, ok := x.(*AndExpr); ok { + list = appendSplitAnd(list, x.X) + list = appendSplitAnd(list, x.Y) + return list + } + return append(list, x) +} + +// appendSplitOr appends x to list while splitting apart any top-level || expressions. +// For example, appendSplitOr({W}, X || Y || Z) = {W, X, Y, Z}. +func appendSplitOr(list []Expr, x Expr) []Expr { + if x, ok := x.(*OrExpr); ok { + list = appendSplitOr(list, x.X) + list = appendSplitOr(list, x.Y) + return list + } + return append(list, x) +} |