// Copyright 2009 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 printer implements printing of AST nodes. package printer import ( "fmt" "go/ast" "go/build/constraint" "go/token" "io" "os" "strings" "text/tabwriter" "unicode" ) const ( maxNewlines = 2 // max. number of newlines between source text debug = false // enable for debugging infinity = 1 << 30 ) type whiteSpace byte const ( ignore = whiteSpace(0) blank = whiteSpace(' ') vtab = whiteSpace('\v') newline = whiteSpace('\n') formfeed = whiteSpace('\f') indent = whiteSpace('>') unindent = whiteSpace('<') ) // A pmode value represents the current printer mode. type pmode int const ( noExtraBlank pmode = 1 << iota // disables extra blank after /*-style comment noExtraLinebreak // disables extra line break after /*-style comment ) type commentInfo struct { cindex int // current comment index comment *ast.CommentGroup // = printer.comments[cindex]; or nil commentOffset int // = printer.posFor(printer.comments[cindex].List[0].Pos()).Offset; or infinity commentNewline bool // true if the comment group contains newlines } type printer struct { // Configuration (does not change after initialization) Config fset *token.FileSet // Current state output []byte // raw printer result indent int // current indentation level int // level == 0: outside composite literal; level > 0: inside composite literal mode pmode // current printer mode endAlignment bool // if set, terminate alignment immediately impliedSemi bool // if set, a linebreak implies a semicolon lastTok token.Token // last token printed (token.ILLEGAL if it's whitespace) prevOpen token.Token // previous non-brace "open" token (, [, or token.ILLEGAL wsbuf []whiteSpace // delayed white space goBuild []int // start index of all //go:build comments in output plusBuild []int // start index of all // +build comments in output // Positions // The out position differs from the pos position when the result // formatting differs from the source formatting (in the amount of // white space). If there's a difference and SourcePos is set in // ConfigMode, //line directives are used in the output to restore // original source positions for a reader. pos token.Position // current position in AST (source) space out token.Position // current position in output space last token.Position // value of pos after calling writeString linePtr *int // if set, record out.Line for the next token in *linePtr // The list of all source comments, in order of appearance. comments []*ast.CommentGroup // may be nil useNodeComments bool // if not set, ignore lead and line comments of nodes // Information about p.comments[p.cindex]; set up by nextComment. commentInfo // Cache of already computed node sizes. nodeSizes map[ast.Node]int // Cache of most recently computed line position. cachedPos token.Pos cachedLine int // line corresponding to cachedPos } func (p *printer) init(cfg *Config, fset *token.FileSet, nodeSizes map[ast.Node]int) { p.Config = *cfg p.fset = fset p.pos = token.Position{Line: 1, Column: 1} p.out = token.Position{Line: 1, Column: 1} p.wsbuf = make([]whiteSpace, 0, 16) // whitespace sequences are short p.nodeSizes = nodeSizes p.cachedPos = -1 } func (p *printer) internalError(msg ...any) { if debug { fmt.Print(p.pos.String() + ": ") fmt.Println(msg...) panic("go/printer") } } // commentsHaveNewline reports whether a list of comments belonging to // an *ast.CommentGroup contains newlines. Because the position information // may only be partially correct, we also have to read the comment text. func (p *printer) commentsHaveNewline(list []*ast.Comment) bool { // len(list) > 0 line := p.lineFor(list[0].Pos()) for i, c := range list { if i > 0 && p.lineFor(list[i].Pos()) != line { // not all comments on the same line return true } if t := c.Text; len(t) >= 2 && (t[1] == '/' || strings.Contains(t, "\n")) { return true } } _ = line return false } func (p *printer) nextComment() { for p.cindex < len(p.comments) { c := p.comments[p.cindex] p.cindex++ if list := c.List; len(list) > 0 { p.comment = c p.commentOffset = p.posFor(list[0].Pos()).Offset p.commentNewline = p.commentsHaveNewline(list) return } // we should not reach here (correct ASTs don't have empty // ast.CommentGroup nodes), but be conservative and try again } // no more comments p.commentOffset = infinity } // commentBefore reports whether the current comment group occurs // before the next position in the source code and printing it does // not introduce implicit semicolons. // func (p *printer) commentBefore(next token.Position) bool { return p.commentOffset < next.Offset && (!p.impliedSemi || !p.commentNewline) } // commentSizeBefore returns the estimated size of the // comments on the same line before the next position. // func (p *printer) commentSizeBefore(next token.Position) int { // save/restore current p.commentInfo (p.nextComment() modifies it) defer func(info commentInfo) { p.commentInfo = info }(p.commentInfo) size := 0 for p.commentBefore(next) { for _, c := range p.comment.List { size += len(c.Text) } p.nextComment() } return size } // recordLine records the output line number for the next non-whitespace // token in *linePtr. It is used to compute an accurate line number for a // formatted construct, independent of pending (not yet emitted) whitespace // or comments. // func (p *printer) recordLine(linePtr *int) { p.linePtr = linePtr } // linesFrom returns the number of output lines between the current // output line and the line argument, ignoring any pending (not yet // emitted) whitespace or comments. It is used to compute an accurate // size (in number of lines) for a formatted construct. // func (p *printer) linesFrom(line int) int { return p.out.Line - line } func (p *printer) posFor(pos token.Pos) token.Position { // not used frequently enough to cache entire token.Position return p.fset.PositionFor(pos, false /* absolute position */) } func (p *printer) lineFor(pos token.Pos) int { if pos != p.cachedPos { p.cachedPos = pos p.cachedLine = p.fset.PositionFor(pos, false /* absolute position */).Line } return p.cachedLine } // writeLineDirective writes a //line directive if necessary. func (p *printer) writeLineDirective(pos token.Position) { if pos.IsValid() && (p.out.Line != pos.Line || p.out.Filename != pos.Filename) { p.output = append(p.output, tabwriter.Escape) // protect '\n' in //line from tabwriter interpretation p.output = append(p.output, fmt.Sprintf("//line %s:%d\n", pos.Filename, pos.Line)...) p.output = append(p.output, tabwriter.Escape) // p.out must match the //line directive p.out.Filename = pos.Filename p.out.Line = pos.Line } } // writeIndent writes indentation. func (p *printer) writeIndent() { // use "hard" htabs - indentation columns // must not be discarded by the tabwriter n := p.Config.Indent + p.indent // include base indentation for i := 0; i < n; i++ { p.output = append(p.output, '\t') } // update positions p.pos.Offset += n p.pos.Column += n p.out.Column += n } // writeByte writes ch n times to p.output and updates p.pos. // Only used to write formatting (white space) characters. func (p *printer) writeByte(ch byte, n int) { if p.endAlignment { // Ignore any alignment control character; // and at the end of the line, break with // a formfeed to indicate termination of // existing columns. switch ch { case '\t', '\v': ch = ' ' case '\n', '\f': ch = '\f' p.endAlignment = false } } if p.out.Column == 1 { // no need to write line directives before white space p.writeIndent() } for i := 0; i < n; i++ { p.output = append(p.output, ch) } // update positions p.pos.Offset += n if ch == '\n' || ch == '\f' { p.pos.Line += n p.out.Line += n p.pos.Column = 1 p.out.Column = 1 return } p.pos.Column += n p.out.Column += n } // writeString writes the string s to p.output and updates p.pos, p.out, // and p.last. If isLit is set, s is escaped w/ tabwriter.Escape characters // to protect s from being interpreted by the tabwriter. // // Note: writeString is only used to write Go tokens, literals, and // comments, all of which must be written literally. Thus, it is correct // to always set isLit = true. However, setting it explicitly only when // needed (i.e., when we don't know that s contains no tabs or line breaks) // avoids processing extra escape characters and reduces run time of the // printer benchmark by up to 10%. // func (p *printer) writeString(pos token.Position, s string, isLit bool) { if p.out.Column == 1 { if p.Config.Mode&SourcePos != 0 { p.writeLineDirective(pos) } p.writeIndent() } if pos.IsValid() { // update p.pos (if pos is invalid, continue with existing p.pos) // Note: Must do this after handling line beginnings because // writeIndent updates p.pos if there's indentation, but p.pos // is the position of s. p.pos = pos } if isLit { // Protect s such that is passes through the tabwriter // unchanged. Note that valid Go programs cannot contain // tabwriter.Escape bytes since they do not appear in legal // UTF-8 sequences. p.output = append(p.output, tabwriter.Escape) } if debug { p.output = append(p.output, fmt.Sprintf("/*%s*/", pos)...) // do not update p.pos! } p.output = append(p.output, s...) // update positions nlines := 0 var li int // index of last newline; valid if nlines > 0 for i := 0; i < len(s); i++ { // Raw string literals may contain any character except back quote (`). if ch := s[i]; ch == '\n' || ch == '\f' { // account for line break nlines++ li = i // A line break inside a literal will break whatever column // formatting is in place; ignore any further alignment through // the end of the line. p.endAlignment = true } } p.pos.Offset += len(s) if nlines > 0 { p.pos.Line += nlines p.out.Line += nlines c := len(s) - li p.pos.Column = c p.out.Column = c } else { p.pos.Column += len(s) p.out.Column += len(s) } if isLit { p.output = append(p.output, tabwriter.Escape) } p.last = p.pos } // writeCommentPrefix writes the whitespace before a comment. // If there is any pending whitespace, it consumes as much of // it as is likely to help position the comment nicely. // pos is the comment position, next the position of the item // after all pending comments, prev is the previous comment in // a group of comments (or nil), and tok is the next token. // func (p *printer) writeCommentPrefix(pos, next token.Position, prev *ast.Comment, tok token.Token) { if len(p.output) == 0 { // the comment is the first item to be printed - don't write any whitespace return } if pos.IsValid() && pos.Filename != p.last.Filename { // comment in a different file - separate with newlines p.writeByte('\f', maxNewlines) return } if pos.Line == p.last.Line && (prev == nil || prev.Text[1] != '/') { // comment on the same line as last item: // separate with at least one separator hasSep := false if prev == nil { // first comment of a comment group j := 0 for i, ch := range p.wsbuf { switch ch { case blank: // ignore any blanks before a comment p.wsbuf[i] = ignore continue case vtab: // respect existing tabs - important // for proper formatting of commented structs hasSep = true continue case indent: // apply pending indentation continue } j = i break } p.writeWhitespace(j) } // make sure there is at least one separator if !hasSep { sep := byte('\t') if pos.Line == next.Line { // next item is on the same line as the comment // (which must be a /*-style comment): separate // with a blank instead of a tab sep = ' ' } p.writeByte(sep, 1) } } else { // comment on a different line: // separate with at least one line break droppedLinebreak := false j := 0 for i, ch := range p.wsbuf { switch ch { case blank, vtab: // ignore any horizontal whitespace before line breaks p.wsbuf[i] = ignore continue case indent: // apply pending indentation continue case unindent: // if this is not the last unindent, apply it // as it is (likely) belonging to the last // construct (e.g., a multi-line expression list) // and is not part of closing a block if i+1 < len(p.wsbuf) && p.wsbuf[i+1] == unindent { continue } // if the next token is not a closing }, apply the unindent // if it appears that the comment is aligned with the // token; otherwise assume the unindent is part of a // closing block and stop (this scenario appears with // comments before a case label where the comments // apply to the next case instead of the current one) if tok != token.RBRACE && pos.Column == next.Column { continue } case newline, formfeed: p.wsbuf[i] = ignore droppedLinebreak = prev == nil // record only if first comment of a group } j = i break } p.writeWhitespace(j) // determine number of linebreaks before the comment n := 0 if pos.IsValid() && p.last.IsValid() { n = pos.Line - p.last.Line if n < 0 { // should never happen n = 0 } } // at the package scope level only (p.indent == 0), // add an extra newline if we dropped one before: // this preserves a blank line before documentation // comments at the package scope level (issue 2570) if p.indent == 0 && droppedLinebreak { n++ } // make sure there is at least one line break // if the previous comment was a line comment if n == 0 && prev != nil && prev.Text[1] == '/' { n = 1 } if n > 0 { // use formfeeds to break columns before a comment; // this is analogous to using formfeeds to separate // individual lines of /*-style comments p.writeByte('\f', nlimit(n)) } } } // Returns true if s contains only white space // (only tabs and blanks can appear in the printer's context). // func isBlank(s string) bool { for i := 0; i < len(s); i++ { if s[i] > ' ' { return false } } return true } // commonPrefix returns the common prefix of a and b. func commonPrefix(a, b string) string { i := 0 for i < len(a) && i < len(b) && a[i] == b[i] && (a[i] <= ' ' || a[i] == '*') { i++ } return a[0:i] } // trimRight returns s with trailing whitespace removed. func trimRight(s string) string { return strings.TrimRightFunc(s, unicode.IsSpace) } // stripCommonPrefix removes a common prefix from /*-style comment lines (unless no // comment line is indented, all but the first line have some form of space prefix). // The prefix is computed using heuristics such that is likely that the comment // contents are nicely laid out after re-printing each line using the printer's // current indentation. // func stripCommonPrefix(lines []string) { if len(lines) <= 1 { return // at most one line - nothing to do } // len(lines) > 1 // The heuristic in this function tries to handle a few // common patterns of /*-style comments: Comments where // the opening /* and closing */ are aligned and the // rest of the comment text is aligned and indented with // blanks or tabs, cases with a vertical "line of stars" // on the left, and cases where the closing */ is on the // same line as the last comment text. // Compute maximum common white prefix of all but the first, // last, and blank lines, and replace blank lines with empty // lines (the first line starts with /* and has no prefix). // In cases where only the first and last lines are not blank, // such as two-line comments, or comments where all inner lines // are blank, consider the last line for the prefix computation // since otherwise the prefix would be empty. // // Note that the first and last line are never empty (they // contain the opening /* and closing */ respectively) and // thus they can be ignored by the blank line check. prefix := "" prefixSet := false if len(lines) > 2 { for i, line := range lines[1 : len(lines)-1] { if isBlank(line) { lines[1+i] = "" // range starts with lines[1] } else { if !prefixSet { prefix = line prefixSet = true } prefix = commonPrefix(prefix, line) } } } // If we don't have a prefix yet, consider the last line. if !prefixSet { line := lines[len(lines)-1] prefix = commonPrefix(line, line) } /* * Check for vertical "line of stars" and correct prefix accordingly. */ lineOfStars := false if p, _, ok := strings.Cut(prefix, "*"); ok { // remove trailing blank from prefix so stars remain aligned prefix = strings.TrimSuffix(p, " ") lineOfStars = true } else { // No line of stars present. // Determine the white space on the first line after the /* // and before the beginning of the comment text, assume two // blanks instead of the /* unless the first character after // the /* is a tab. If the first comment line is empty but // for the opening /*, assume up to 3 blanks or a tab. This // whitespace may be found as suffix in the common prefix. first := lines[0] if isBlank(first[2:]) { // no comment text on the first line: // reduce prefix by up to 3 blanks or a tab // if present - this keeps comment text indented // relative to the /* and */'s if it was indented // in the first place i := len(prefix) for n := 0; n < 3 && i > 0 && prefix[i-1] == ' '; n++ { i-- } if i == len(prefix) && i > 0 && prefix[i-1] == '\t' { i-- } prefix = prefix[0:i] } else { // comment text on the first line suffix := make([]byte, len(first)) n := 2 // start after opening /* for n < len(first) && first[n] <= ' ' { suffix[n] = first[n] n++ } if n > 2 && suffix[2] == '\t' { // assume the '\t' compensates for the /* suffix = suffix[2:n] } else { // otherwise assume two blanks suffix[0], suffix[1] = ' ', ' ' suffix = suffix[0:n] } // Shorten the computed common prefix by the length of // suffix, if it is found as suffix of the prefix. prefix = strings.TrimSuffix(prefix, string(suffix)) } } // Handle last line: If it only contains a closing */, align it // with the opening /*, otherwise align the text with the other // lines. last := lines[len(lines)-1] closing := "*/" before, _, _ := strings.Cut(last, closing) // closing always present if isBlank(before) { // last line only contains closing */ if lineOfStars { closing = " */" // add blank to align final star } lines[len(lines)-1] = prefix + closing } else { // last line contains more comment text - assume // it is aligned like the other lines and include // in prefix computation prefix = commonPrefix(prefix, last) } // Remove the common prefix from all but the first and empty lines. for i, line := range lines { if i > 0 && line != "" { lines[i] = line[len(prefix):] } } } func (p *printer) writeComment(comment *ast.Comment) { text := comment.Text pos := p.posFor(comment.Pos()) const linePrefix = "//line " if strings.HasPrefix(text, linePrefix) && (!pos.IsValid() || pos.Column == 1) { // Possibly a //-style line directive. // Suspend indentation temporarily to keep line directive valid. defer func(indent int) { p.indent = indent }(p.indent) p.indent = 0 } // shortcut common case of //-style comments if text[1] == '/' { if constraint.IsGoBuild(text) { p.goBuild = append(p.goBuild, len(p.output)) } else if constraint.IsPlusBuild(text) { p.plusBuild = append(p.plusBuild, len(p.output)) } p.writeString(pos, trimRight(text), true) return } // for /*-style comments, print line by line and let the // write function take care of the proper indentation lines := strings.Split(text, "\n") // The comment started in the first column but is going // to be indented. For an idempotent result, add indentation // to all lines such that they look like they were indented // before - this will make sure the common prefix computation // is the same independent of how many times formatting is // applied (was issue 1835). if pos.IsValid() && pos.Column == 1 && p.indent > 0 { for i, line := range lines[1:] { lines[1+i] = " " + line } } stripCommonPrefix(lines) // write comment lines, separated by formfeed, // without a line break after the last line for i, line := range lines { if i > 0 { p.writeByte('\f', 1) pos = p.pos } if len(line) > 0 { p.writeString(pos, trimRight(line), true) } } } // writeCommentSuffix writes a line break after a comment if indicated // and processes any leftover indentation information. If a line break // is needed, the kind of break (newline vs formfeed) depends on the // pending whitespace. The writeCommentSuffix result indicates if a // newline was written or if a formfeed was dropped from the whitespace // buffer. // func (p *printer) writeCommentSuffix(needsLinebreak bool) (wroteNewline, droppedFF bool) { for i, ch := range p.wsbuf { switch ch { case blank, vtab: // ignore trailing whitespace p.wsbuf[i] = ignore case indent, unindent: // don't lose indentation information case newline, formfeed: // if we need a line break, keep exactly one // but remember if we dropped any formfeeds if needsLinebreak { needsLinebreak = false wroteNewline = true } else { if ch == formfeed { droppedFF = true } p.wsbuf[i] = ignore } } } p.writeWhitespace(len(p.wsbuf)) // make sure we have a line break if needsLinebreak { p.writeByte('\n', 1) wroteNewline = true } return } // containsLinebreak reports whether the whitespace buffer contains any line breaks. func (p *printer) containsLinebreak() bool { for _, ch := range p.wsbuf { if ch == newline || ch == formfeed { return true } } return false } // intersperseComments consumes all comments that appear before the next token // tok and prints it together with the buffered whitespace (i.e., the whitespace // that needs to be written before the next token). A heuristic is used to mix // the comments and whitespace. The intersperseComments result indicates if a // newline was written or if a formfeed was dropped from the whitespace buffer. // func (p *printer) intersperseComments(next token.Position, tok token.Token) (wroteNewline, droppedFF bool) { var last *ast.Comment for p.commentBefore(next) { for _, c := range p.comment.List { p.writeCommentPrefix(p.posFor(c.Pos()), next, last, tok) p.writeComment(c) last = c } p.nextComment() } if last != nil { // If the last comment is a /*-style comment and the next item // follows on the same line but is not a comma, and not a "closing" // token immediately following its corresponding "opening" token, // add an extra separator unless explicitly disabled. Use a blank // as separator unless we have pending linebreaks, they are not // disabled, and we are outside a composite literal, in which case // we want a linebreak (issue 15137). // TODO(gri) This has become overly complicated. We should be able // to track whether we're inside an expression or statement and // use that information to decide more directly. needsLinebreak := false if p.mode&noExtraBlank == 0 && last.Text[1] == '*' && p.lineFor(last.Pos()) == next.Line && tok != token.COMMA && (tok != token.RPAREN || p.prevOpen == token.LPAREN) && (tok != token.RBRACK || p.prevOpen == token.LBRACK) { if p.containsLinebreak() && p.mode&noExtraLinebreak == 0 && p.level == 0 { needsLinebreak = true } else { p.writeByte(' ', 1) } } // Ensure that there is a line break after a //-style comment, // before EOF, and before a closing '}' unless explicitly disabled. if last.Text[1] == '/' || tok == token.EOF || tok == token.RBRACE && p.mode&noExtraLinebreak == 0 { needsLinebreak = true } return p.writeCommentSuffix(needsLinebreak) } // no comment was written - we should never reach here since // intersperseComments should not be called in that case p.internalError("intersperseComments called without pending comments") return } // whiteWhitespace writes the first n whitespace entries. func (p *printer) writeWhitespace(n int) { // write entries for i := 0; i < n; i++ { switch ch := p.wsbuf[i]; ch { case ignore: // ignore! case indent: p.indent++ case unindent: p.indent-- if p.indent < 0 { p.internalError("negative indentation:", p.indent) p.indent = 0 } case newline, formfeed: // A line break immediately followed by a "correcting" // unindent is swapped with the unindent - this permits // proper label positioning. If a comment is between // the line break and the label, the unindent is not // part of the comment whitespace prefix and the comment // will be positioned correctly indented. if i+1 < n && p.wsbuf[i+1] == unindent { // Use a formfeed to terminate the current section. // Otherwise, a long label name on the next line leading // to a wide column may increase the indentation column // of lines before the label; effectively leading to wrong // indentation. p.wsbuf[i], p.wsbuf[i+1] = unindent, formfeed i-- // do it again continue } fallthrough default: p.writeByte(byte(ch), 1) } } // shift remaining entries down l := copy(p.wsbuf, p.wsbuf[n:]) p.wsbuf = p.wsbuf[:l] } // ---------------------------------------------------------------------------- // Printing interface // nlimit limits n to maxNewlines. func nlimit(n int) int { if n > maxNewlines { n = maxNewlines } return n } func mayCombine(prev token.Token, next byte) (b bool) { switch prev { case token.INT: b = next == '.' // 1. case token.ADD: b = next == '+' // ++ case token.SUB: b = next == '-' // -- case token.QUO: b = next == '*' // /* case token.LSS: b = next == '-' || next == '<' // <- or << case token.AND: b = next == '&' || next == '^' // && or &^ } return } // print prints a list of "items" (roughly corresponding to syntactic // tokens, but also including whitespace and formatting information). // It is the only print function that should be called directly from // any of the AST printing functions in nodes.go. // // Whitespace is accumulated until a non-whitespace token appears. Any // comments that need to appear before that token are printed first, // taking into account the amount and structure of any pending white- // space for best comment placement. Then, any leftover whitespace is // printed, followed by the actual token. // func (p *printer) print(args ...any) { for _, arg := range args { // information about the current arg var data string var isLit bool var impliedSemi bool // value for p.impliedSemi after this arg // record previous opening token, if any switch p.lastTok { case token.ILLEGAL: // ignore (white space) case token.LPAREN, token.LBRACK: p.prevOpen = p.lastTok default: // other tokens followed any opening token p.prevOpen = token.ILLEGAL } switch x := arg.(type) { case pmode: // toggle printer mode p.mode ^= x continue case whiteSpace: if x == ignore { // don't add ignore's to the buffer; they // may screw up "correcting" unindents (see // LabeledStmt) continue } i := len(p.wsbuf) if i == cap(p.wsbuf) { // Whitespace sequences are very short so this should // never happen. Handle gracefully (but possibly with // bad comment placement) if it does happen. p.writeWhitespace(i) i = 0 } p.wsbuf = p.wsbuf[0 : i+1] p.wsbuf[i] = x if x == newline || x == formfeed { // newlines affect the current state (p.impliedSemi) // and not the state after printing arg (impliedSemi) // because comments can be interspersed before the arg // in this case p.impliedSemi = false } p.lastTok = token.ILLEGAL continue case *ast.Ident: data = x.Name impliedSemi = true p.lastTok = token.IDENT case *ast.BasicLit: data = x.Value isLit = true impliedSemi = true p.lastTok = x.Kind case token.Token: s := x.String() if mayCombine(p.lastTok, s[0]) { // the previous and the current token must be // separated by a blank otherwise they combine // into a different incorrect token sequence // (except for token.INT followed by a '.' this // should never happen because it is taken care // of via binary expression formatting) if len(p.wsbuf) != 0 { p.internalError("whitespace buffer not empty") } p.wsbuf = p.wsbuf[0:1] p.wsbuf[0] = ' ' } data = s // some keywords followed by a newline imply a semicolon switch x { case token.BREAK, token.CONTINUE, token.FALLTHROUGH, token.RETURN, token.INC, token.DEC, token.RPAREN, token.RBRACK, token.RBRACE: impliedSemi = true } p.lastTok = x case token.Pos: if x.IsValid() { p.pos = p.posFor(x) // accurate position of next item } continue case string: // incorrect AST - print error message data = x isLit = true impliedSemi = true p.lastTok = token.STRING default: fmt.Fprintf(os.Stderr, "print: unsupported argument %v (%T)\n", arg, arg) panic("go/printer type") } // data != "" next := p.pos // estimated/accurate position of next item wroteNewline, droppedFF := p.flush(next, p.lastTok) // intersperse extra newlines if present in the source and // if they don't cause extra semicolons (don't do this in // flush as it will cause extra newlines at the end of a file) if !p.impliedSemi { n := nlimit(next.Line - p.pos.Line) // don't exceed maxNewlines if we already wrote one if wroteNewline && n == maxNewlines { n = maxNewlines - 1 } if n > 0 { ch := byte('\n') if droppedFF { ch = '\f' // use formfeed since we dropped one before } p.writeByte(ch, n) impliedSemi = false } } // the next token starts now - record its line number if requested if p.linePtr != nil { *p.linePtr = p.out.Line p.linePtr = nil } p.writeString(next, data, isLit) p.impliedSemi = impliedSemi } } // flush prints any pending comments and whitespace occurring textually // before the position of the next token tok. The flush result indicates // if a newline was written or if a formfeed was dropped from the whitespace // buffer. // func (p *printer) flush(next token.Position, tok token.Token) (wroteNewline, droppedFF bool) { if p.commentBefore(next) { // if there are comments before the next item, intersperse them wroteNewline, droppedFF = p.intersperseComments(next, tok) } else { // otherwise, write any leftover whitespace p.writeWhitespace(len(p.wsbuf)) } return } // getNode returns the ast.CommentGroup associated with n, if any. func getDoc(n ast.Node) *ast.CommentGroup { switch n := n.(type) { case *ast.Field: return n.Doc case *ast.ImportSpec: return n.Doc case *ast.ValueSpec: return n.Doc case *ast.TypeSpec: return n.Doc case *ast.GenDecl: return n.Doc case *ast.FuncDecl: return n.Doc case *ast.File: return n.Doc } return nil } func getLastComment(n ast.Node) *ast.CommentGroup { switch n := n.(type) { case *ast.Field: return n.Comment case *ast.ImportSpec: return n.Comment case *ast.ValueSpec: return n.Comment case *ast.TypeSpec: return n.Comment case *ast.GenDecl: if len(n.Specs) > 0 { return getLastComment(n.Specs[len(n.Specs)-1]) } case *ast.File: if len(n.Comments) > 0 { return n.Comments[len(n.Comments)-1] } } return nil } func (p *printer) printNode(node any) error { // unpack *CommentedNode, if any var comments []*ast.CommentGroup if cnode, ok := node.(*CommentedNode); ok { node = cnode.Node comments = cnode.Comments } if comments != nil { // commented node - restrict comment list to relevant range n, ok := node.(ast.Node) if !ok { goto unsupported } beg := n.Pos() end := n.End() // if the node has associated documentation, // include that commentgroup in the range // (the comment list is sorted in the order // of the comment appearance in the source code) if doc := getDoc(n); doc != nil { beg = doc.Pos() } if com := getLastComment(n); com != nil { if e := com.End(); e > end { end = e } } // token.Pos values are global offsets, we can // compare them directly i := 0 for i < len(comments) && comments[i].End() < beg { i++ } j := i for j < len(comments) && comments[j].Pos() < end { j++ } if i < j { p.comments = comments[i:j] } } else if n, ok := node.(*ast.File); ok { // use ast.File comments, if any p.comments = n.Comments } // if there are no comments, use node comments p.useNodeComments = p.comments == nil // get comments ready for use p.nextComment() p.print(pmode(0)) // format node switch n := node.(type) { case ast.Expr: p.expr(n) case ast.Stmt: // A labeled statement will un-indent to position the label. // Set p.indent to 1 so we don't get indent "underflow". if _, ok := n.(*ast.LabeledStmt); ok { p.indent = 1 } p.stmt(n, false) case ast.Decl: p.decl(n) case ast.Spec: p.spec(n, 1, false) case []ast.Stmt: // A labeled statement will un-indent to position the label. // Set p.indent to 1 so we don't get indent "underflow". for _, s := range n { if _, ok := s.(*ast.LabeledStmt); ok { p.indent = 1 } } p.stmtList(n, 0, false) case []ast.Decl: p.declList(n) case *ast.File: p.file(n) default: goto unsupported } return nil unsupported: return fmt.Errorf("go/printer: unsupported node type %T", node) } // ---------------------------------------------------------------------------- // Trimmer // A trimmer is an io.Writer filter for stripping tabwriter.Escape // characters, trailing blanks and tabs, and for converting formfeed // and vtab characters into newlines and htabs (in case no tabwriter // is used). Text bracketed by tabwriter.Escape characters is passed // through unchanged. // type trimmer struct { output io.Writer state int space []byte } // trimmer is implemented as a state machine. // It can be in one of the following states: const ( inSpace = iota // inside space inEscape // inside text bracketed by tabwriter.Escapes inText // inside text ) func (p *trimmer) resetSpace() { p.state = inSpace p.space = p.space[0:0] } // Design note: It is tempting to eliminate extra blanks occurring in // whitespace in this function as it could simplify some // of the blanks logic in the node printing functions. // However, this would mess up any formatting done by // the tabwriter. var aNewline = []byte("\n") func (p *trimmer) Write(data []byte) (n int, err error) { // invariants: // p.state == inSpace: // p.space is unwritten // p.state == inEscape, inText: // data[m:n] is unwritten m := 0 var b byte for n, b = range data { if b == '\v' { b = '\t' // convert to htab } switch p.state { case inSpace: switch b { case '\t', ' ': p.space = append(p.space, b) case '\n', '\f': p.resetSpace() // discard trailing space _, err = p.output.Write(aNewline) case tabwriter.Escape: _, err = p.output.Write(p.space) p.state = inEscape m = n + 1 // +1: skip tabwriter.Escape default: _, err = p.output.Write(p.space) p.state = inText m = n } case inEscape: if b == tabwriter.Escape { _, err = p.output.Write(data[m:n]) p.resetSpace() } case inText: switch b { case '\t', ' ': _, err = p.output.Write(data[m:n]) p.resetSpace() p.space = append(p.space, b) case '\n', '\f': _, err = p.output.Write(data[m:n]) p.resetSpace() if err == nil { _, err = p.output.Write(aNewline) } case tabwriter.Escape: _, err = p.output.Write(data[m:n]) p.state = inEscape m = n + 1 // +1: skip tabwriter.Escape } default: panic("unreachable") } if err != nil { return } } n = len(data) switch p.state { case inEscape, inText: _, err = p.output.Write(data[m:n]) p.resetSpace() } return } // ---------------------------------------------------------------------------- // Public interface // A Mode value is a set of flags (or 0). They control printing. type Mode uint const ( RawFormat Mode = 1 << iota // do not use a tabwriter; if set, UseSpaces is ignored TabIndent // use tabs for indentation independent of UseSpaces UseSpaces // use spaces instead of tabs for alignment SourcePos // emit //line directives to preserve original source positions ) // The mode below is not included in printer's public API because // editing code text is deemed out of scope. Because this mode is // unexported, it's also possible to modify or remove it based on // the evolving needs of go/format and cmd/gofmt without breaking // users. See discussion in CL 240683. const ( // normalizeNumbers means to canonicalize number // literal prefixes and exponents while printing. // // This value is known in and used by go/format and cmd/gofmt. // It is currently more convenient and performant for those // packages to apply number normalization during printing, // rather than by modifying the AST in advance. normalizeNumbers Mode = 1 << 30 ) // A Config node controls the output of Fprint. type Config struct { Mode Mode // default: 0 Tabwidth int // default: 8 Indent int // default: 0 (all code is indented at least by this much) } // fprint implements Fprint and takes a nodesSizes map for setting up the printer state. func (cfg *Config) fprint(output io.Writer, fset *token.FileSet, node any, nodeSizes map[ast.Node]int) (err error) { // print node var p printer p.init(cfg, fset, nodeSizes) if err = p.printNode(node); err != nil { return } // print outstanding comments p.impliedSemi = false // EOF acts like a newline p.flush(token.Position{Offset: infinity, Line: infinity}, token.EOF) // output is buffered in p.output now. // fix //go:build and // +build comments if needed. p.fixGoBuildLines() // redirect output through a trimmer to eliminate trailing whitespace // (Input to a tabwriter must be untrimmed since trailing tabs provide // formatting information. The tabwriter could provide trimming // functionality but no tabwriter is used when RawFormat is set.) output = &trimmer{output: output} // redirect output through a tabwriter if necessary if cfg.Mode&RawFormat == 0 { minwidth := cfg.Tabwidth padchar := byte('\t') if cfg.Mode&UseSpaces != 0 { padchar = ' ' } twmode := tabwriter.DiscardEmptyColumns if cfg.Mode&TabIndent != 0 { minwidth = 0 twmode |= tabwriter.TabIndent } output = tabwriter.NewWriter(output, minwidth, cfg.Tabwidth, 1, padchar, twmode) } // write printer result via tabwriter/trimmer to output if _, err = output.Write(p.output); err != nil { return } // flush tabwriter, if any if tw, _ := output.(*tabwriter.Writer); tw != nil { err = tw.Flush() } return } // A CommentedNode bundles an AST node and corresponding comments. // It may be provided as argument to any of the Fprint functions. // type CommentedNode struct { Node any // *ast.File, or ast.Expr, ast.Decl, ast.Spec, or ast.Stmt Comments []*ast.CommentGroup } // Fprint "pretty-prints" an AST node to output for a given configuration cfg. // Position information is interpreted relative to the file set fset. // The node type must be *ast.File, *CommentedNode, []ast.Decl, []ast.Stmt, // or assignment-compatible to ast.Expr, ast.Decl, ast.Spec, or ast.Stmt. // func (cfg *Config) Fprint(output io.Writer, fset *token.FileSet, node any) error { return cfg.fprint(output, fset, node, make(map[ast.Node]int)) } // Fprint "pretty-prints" an AST node to output. // It calls Config.Fprint with default settings. // Note that gofmt uses tabs for indentation but spaces for alignment; // use format.Node (package go/format) for output that matches gofmt. // func Fprint(output io.Writer, fset *token.FileSet, node any) error { return (&Config{Tabwidth: 8}).Fprint(output, fset, node) }