// 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 import ( "os"; "io"; "array"; "tabwriter"; "flag"; "fmt"; Scanner "scanner"; AST "ast"; ) var ( debug = flag.Bool("debug", false, nil, "print debugging information"); // layout control tabwidth = flag.Int("tabwidth", 8, nil, "tab width"); usetabs = flag.Bool("usetabs", true, nil, "align with tabs instead of blanks"); newlines = flag.Bool("newlines", true, nil, "respect newlines in source"); maxnewlines = flag.Int("maxnewlines", 3, nil, "max. number of consecutive newlines"); // formatting control html = flag.Bool("html", false, nil, "generate html"); comments = flag.Bool("comments", true, nil, "print comments"); optsemicolons = flag.Bool("optsemicolons", false, nil, "print optional semicolons"); ) // ---------------------------------------------------------------------------- // Printer // Separators - printed in a delayed fashion, depending on context. const ( none = iota; blank; tab; comma; semicolon; ) // Semantic states - control formatting. const ( normal = iota; opening_scope; // controls indentation, scope level closing_scope; // controls indentation, scope level inside_list; // controls extra line breaks ) type Printer struct { // output text io.Write; // comments comments *array.Array; // the list of all comments cindex int; // the current comments index cpos int; // the position of the next comment // current state lastpos int; // pos after last string level int; // scope level indentation int; // indentation level (may be different from scope level) // formatting parameters separator int; // pending separator newlines int; // pending newlines // semantic state state int; // current semantic state laststate int; // state for last string } func (P *Printer) HasComment(pos int) bool { return comments.BVal() && P.cpos < pos; } func (P *Printer) NextComment() { P.cindex++; if P.comments != nil && P.cindex < P.comments.Len() { P.cpos = P.comments.At(P.cindex).(*AST.Comment).pos; } else { P.cpos = 1<<30; // infinite } } func (P *Printer) Init(text io.Write, comments *array.Array) { // writers P.text = text; // comments P.comments = comments; P.cindex = -1; P.NextComment(); // formatting parameters & semantic state initialized correctly by default } // ---------------------------------------------------------------------------- // Printing support func HtmlEscape(s string) string { if html.BVal() { var esc string; for i := 0; i < len(s); i++ { switch s[i] { case '<': esc = "<"; case '&': esc = "&"; default: continue; } return s[0 : i] + esc + HtmlEscape(s[i+1 : len(s)]); } } return s; } func (P *Printer) Printf(format string, s ...) { n, err := fmt.fprintf(P.text, format, s); if err != nil { panic("print error - exiting"); } } func (P *Printer) Newline(n int) { if n > 0 { m := int(maxnewlines.IVal()); if n > m { n = m; } for ; n > 0; n-- { P.Printf("\n"); } for i := P.indentation; i > 0; i-- { P.Printf("\t"); } } } func (P *Printer) TaggedString(pos int, tag, s, endtag string) { // use estimate for pos if we don't have one if pos == 0 { pos = P.lastpos; } // -------------------------------- // print pending separator, if any // - keep track of white space printed for better comment formatting // TODO print white space separators after potential comments and newlines // (currently, we may get trailing white space before a newline) trailing_char := 0; switch P.separator { case none: // nothing to do case blank: P.Printf(" "); trailing_char = ' '; case tab: P.Printf("\t"); trailing_char = '\t'; case comma: P.Printf(","); if P.newlines == 0 { P.Printf(" "); trailing_char = ' '; } case semicolon: if P.level > 0 { // no semicolons at level 0 P.Printf(";"); if P.newlines == 0 { P.Printf(" "); trailing_char = ' '; } } default: panic("UNREACHABLE"); } P.separator = none; // -------------------------------- // interleave comments, if any nlcount := 0; for ; P.HasComment(pos); P.NextComment() { // we have a comment/newline that comes before the string comment := P.comments.At(P.cindex).(*AST.Comment); ctext := comment.text; if ctext == "\n" { // found a newline in src - count it nlcount++; } else { // classify comment (len(ctext) >= 2) //-style comment if nlcount > 0 || P.cpos == 0 { // only white space before comment on this line // or file starts with comment // - indent if !newlines.BVal() && P.cpos != 0 { nlcount = 1; } P.Newline(nlcount); nlcount = 0; } else { // black space before comment on this line if ctext[1] == '/' { //-style comment // - put in next cell unless a scope was just opened // in which case we print 2 blanks (otherwise the // entire scope gets indented like the next cell) if P.laststate == opening_scope { switch trailing_char { case ' ': P.Printf(" "); // one space already printed case '\t': // do nothing default: P.Printf(" "); } } else { if trailing_char != '\t' { P.Printf("\t"); } } } else { /*-style comment */ // - print surrounded by blanks if trailing_char == 0 { P.Printf(" "); } ctext += " "; } } // print comment if debug.BVal() { P.Printf("[%d]", P.cpos); } P.Printf("%s", HtmlEscape(ctext)); if ctext[1] == '/' { //-style comments must end in newline if P.newlines == 0 { // don't add newlines if not needed P.newlines = 1; } } } } // At this point we may have nlcount > 0: In this case we found newlines // that were not followed by a comment. They are recognized (or not) when // printing newlines below. // -------------------------------- // interpret state // (any pending separator or comment must be printed in previous state) switch P.state { case normal: case opening_scope: case closing_scope: P.indentation--; case inside_list: default: panic("UNREACHABLE"); } // -------------------------------- // print pending newlines if newlines.BVal() && (P.newlines > 0 || P.state == inside_list) && nlcount > P.newlines { // Respect additional newlines in the source, but only if we // enabled this feature (newlines.BVal()) and we are expecting // newlines (P.newlines > 0 || P.state == inside_list). // Otherwise - because we don't have all token positions - we // get funny formatting. P.newlines = nlcount; } nlcount = 0; P.Newline(P.newlines); P.newlines = 0; // -------------------------------- // print string if debug.BVal() { P.Printf("[%d]", pos); } P.Printf("%s%s%s", tag, HtmlEscape(s), endtag); // -------------------------------- // interpret state switch P.state { case normal: case opening_scope: P.level++; P.indentation++; case closing_scope: P.level--; case inside_list: default: panic("UNREACHABLE"); } P.laststate = P.state; P.state = none; // -------------------------------- // done P.lastpos = pos + len(s); // rough estimate } func (P *Printer) String(pos int, s string) { P.TaggedString(pos, "", s, ""); } func (P *Printer) Token(pos int, tok int) { P.String(pos, Scanner.TokenString(tok)); } func (P *Printer) Error(pos int, tok int, msg string) { P.String(0, "<"); P.Token(pos, tok); P.String(0, " " + msg + ">"); } // ---------------------------------------------------------------------------- // HTML support func (P *Printer) HtmlPrologue(title string) { if html.BVal() { P.TaggedString(0, "\n" "
\n" " \n" "\n", "", "" ) } } func (P *Printer) HtmlEpilogue() { if html.BVal() { P.TaggedString(0, "\n" "\n" "\n", "", "" ) } } func (P *Printer) HtmlIdentifier(pos int, ident string) { if html.BVal() { // no need to HtmlEscape ident P.TaggedString(pos, ``, ident, ``); } else { P.String(pos, ident); } } // ---------------------------------------------------------------------------- // Types func (P *Printer) Type(t *AST.Type) int func (P *Printer) Expr(x *AST.Expr) func (P *Printer) Parameters(pos int, list *array.Array) { P.String(pos, "("); if list != nil { var prev int; for i, n := 0, list.Len(); i < n; i++ { x := list.At(i).(*AST.Expr); if i > 0 { if prev == x.tok || prev == Scanner.TYPE { P.separator = comma; } else { P.separator = blank; } } P.Expr(x); prev = x.tok; } } P.String(0, ")"); } func (P *Printer) Fields(list *array.Array, end int) { P.state = opening_scope; P.String(0, "{"); if list.Len() > 0 { P.newlines = 1; var prev int; for i, n := 0, list.Len(); i < n; i++ { x := list.At(i).(*AST.Expr); if i > 0 { if prev == Scanner.TYPE && x.tok != Scanner.STRING || prev == Scanner.STRING { P.separator = semicolon; P.newlines = 1; } else if prev == x.tok { P.separator = comma; } else { P.separator = tab; } } P.Expr(x); prev = x.tok; } P.newlines = 1; } P.state = closing_scope; P.String(end, "}"); } // Returns the separator (semicolon or none) required if // the type is terminating a declaration or statement. func (P *Printer) Type(t *AST.Type) int { separator := semicolon; switch t.tok { case Scanner.IDENT: P.Expr(t.expr); case Scanner.LBRACK: P.String(t.pos, "["); if t.expr != nil { P.Expr(t.expr); } P.String(0, "]"); separator = P.Type(t.elt); case Scanner.STRUCT, Scanner.INTERFACE: P.Token(t.pos, t.tok); if t.list != nil { P.separator = blank; P.Fields(t.list, t.end); } separator = none; case Scanner.MAP: P.String(t.pos, "map ["); P.Type(t.key); P.String(0, "]"); separator = P.Type(t.elt); case Scanner.CHAN: var m string; switch t.mode { case AST.FULL: m = "chan "; case AST.RECV: m = "<-chan "; case AST.SEND: m = "chan <- "; } P.String(t.pos, m); separator = P.Type(t.elt); case Scanner.MUL: P.String(t.pos, "*"); separator = P.Type(t.elt); case Scanner.LPAREN: P.Parameters(t.pos, t.list); if t.elt != nil { P.separator = blank; list := t.elt.list; if list.Len() > 1 { P.Parameters(0, list); } else { // single, anonymous result type P.Expr(list.At(0).(*AST.Expr)); } } case Scanner.ELLIPSIS: P.String(t.pos, "..."); default: P.Error(t.pos, t.tok, "type"); } return separator; } // ---------------------------------------------------------------------------- // Expressions func (P *Printer) Block(pos int, list *array.Array, end int, indent bool); func (P *Printer) Expr1(x *AST.Expr, prec1 int) { if x == nil { return; // empty expression list } switch x.tok { case Scanner.TYPE: // type expr P.Type(x.t); case Scanner.IDENT: P.HtmlIdentifier(x.pos, x.s); case Scanner.INT, Scanner.STRING, Scanner.FLOAT: // literal P.String(x.pos, x.s); case Scanner.FUNC: // function literal P.String(x.pos, "func"); P.Type(x.t); P.Block(0, x.block, x.end, true); P.newlines = 0; case Scanner.COMMA: // list // (don't use binary expression printing because of different spacing) P.Expr(x.x); P.String(x.pos, ","); P.separator = blank; P.state = inside_list; P.Expr(x.y); case Scanner.PERIOD: // selector or type guard P.Expr1(x.x, Scanner.HighestPrec); P.String(x.pos, "."); if x.y != nil { P.Expr1(x.y, Scanner.HighestPrec); } else { P.String(0, "("); P.Type(x.t); P.String(0, ")"); } case Scanner.LBRACK: // index P.Expr1(x.x, Scanner.HighestPrec); P.String(x.pos, "["); P.Expr1(x.y, 0); P.String(0, "]"); case Scanner.LPAREN: // call P.Expr1(x.x, Scanner.HighestPrec); P.String(x.pos, "("); P.Expr(x.y); P.String(0, ")"); case Scanner.LBRACE: // composite P.Type(x.t); P.String(x.pos, "{"); P.Expr(x.y); P.String(0, "}"); default: // unary and binary expressions including ":" for pairs prec := Scanner.UnaryPrec; if x.x != nil { prec = Scanner.Precedence(x.tok); } if prec < prec1 { P.String(0, "("); } if x.x == nil { // unary expression P.Token(x.pos, x.tok); if x.tok == Scanner.RANGE { P.separator = blank; } } else { // binary expression P.Expr1(x.x, prec); P.separator = blank; P.Token(x.pos, x.tok); P.separator = blank; } P.Expr1(x.y, prec); if prec < prec1 { P.String(0, ")"); } } } func (P *Printer) Expr(x *AST.Expr) { P.Expr1(x, Scanner.LowestPrec); } // ---------------------------------------------------------------------------- // Statements func (P *Printer) Stat(s *AST.Stat) func (P *Printer) StatementList(list *array.Array) { if list != nil { P.newlines = 1; for i, n := 0, list.Len(); i < n; i++ { P.Stat(list.At(i).(*AST.Stat)); P.newlines = 1; P.state = inside_list; } } } func (P *Printer) Block(pos int, list *array.Array, end int, indent bool) { P.state = opening_scope; P.String(pos, "{"); if !indent { P.indentation--; } P.StatementList(list); if !indent { P.indentation++; } if !optsemicolons.BVal() { P.separator = none; } P.state = closing_scope; P.String(end, "}"); } func (P *Printer) ControlClause(s *AST.Stat) { has_post := s.tok == Scanner.FOR && s.post != nil; // post also used by "if" P.separator = blank; if s.init == nil && !has_post { // no semicolons required if s.expr != nil { P.Expr(s.expr); } } else { // all semicolons required // (they are not separators, print them explicitly) if s.init != nil { P.Stat(s.init); P.separator = none; } P.String(0, ";"); P.separator = blank; if s.expr != nil { P.Expr(s.expr); P.separator = none; } if s.tok == Scanner.FOR { P.String(0, ";"); P.separator = blank; if has_post { P.Stat(s.post); } } } P.separator = blank; } func (P *Printer) Declaration(d *AST.Decl, parenthesized bool); func (P *Printer) Stat(s *AST.Stat) { switch s.tok { case Scanner.EXPRSTAT: // expression statement P.Expr(s.expr); P.separator = semicolon; case Scanner.COLON: // label declaration P.indentation--; P.Expr(s.expr); P.Token(s.pos, s.tok); P.indentation++; P.separator = none; case Scanner.CONST, Scanner.TYPE, Scanner.VAR: // declaration P.Declaration(s.decl, false); case Scanner.INC, Scanner.DEC: P.Expr(s.expr); P.Token(s.pos, s.tok); P.separator = semicolon; case Scanner.LBRACE: // block P.Block(s.pos, s.block, s.end, true); case Scanner.IF: P.String(s.pos, "if"); P.ControlClause(s); P.Block(0, s.block, s.end, true); if s.post != nil { P.separator = blank; P.String(0, "else"); P.separator = blank; P.Stat(s.post); } case Scanner.FOR: P.String(s.pos, "for"); P.ControlClause(s); P.Block(0, s.block, s.end, true); case Scanner.SWITCH, Scanner.SELECT: P.Token(s.pos, s.tok); P.ControlClause(s); P.Block(0, s.block, s.end, false); case Scanner.CASE, Scanner.DEFAULT: P.Token(s.pos, s.tok); if s.expr != nil { P.separator = blank; P.Expr(s.expr); } P.String(0, ":"); P.indentation++; P.StatementList(s.block); P.indentation--; P.newlines = 1; case Scanner.GO, Scanner.RETURN, Scanner.FALLTHROUGH, Scanner.BREAK, Scanner.CONTINUE, Scanner.GOTO: P.Token(s.pos, s.tok); if s.expr != nil { P.separator = blank; P.Expr(s.expr); } P.separator = semicolon; default: P.Error(s.pos, s.tok, "stat"); } } // ---------------------------------------------------------------------------- // Declarations func (P *Printer) Declaration(d *AST.Decl, parenthesized bool) { if !parenthesized { if d.exported { P.String(d.pos, "export"); P.separator = blank; } P.Token(d.pos, d.tok); P.separator = blank; } if d.tok != Scanner.FUNC && d.list != nil { // group of parenthesized declarations P.state = opening_scope; P.String(0, "("); if d.list.Len() > 0 { P.newlines = 1; for i := 0; i < d.list.Len(); i++ { P.Declaration(d.list.At(i).(*AST.Decl), true); P.separator = semicolon; P.newlines = 1; } } P.state = closing_scope; P.String(d.end, ")"); } else { // single declaration switch d.tok { case Scanner.IMPORT: if d.ident != nil { P.Expr(d.ident); } else { P.String(d.val.pos, ""); // flush pending ';' separator/newlines } P.separator = tab; P.Expr(d.val); P.separator = semicolon; case Scanner.EXPORT: P.Expr(d.ident); P.separator = semicolon; case Scanner.TYPE: P.Expr(d.ident); P.separator = blank; // TODO switch to tab? (but indentation problem with structs) P.separator = P.Type(d.typ); case Scanner.CONST, Scanner.VAR: P.Expr(d.ident); if d.typ != nil { P.separator = blank; // TODO switch to tab? (indentation problem with structs) P.separator = P.Type(d.typ); } if d.val != nil { P.separator = tab; P.String(0, "="); P.separator = blank; P.Expr(d.val); } P.separator = semicolon; case Scanner.FUNC: if d.typ.key != nil { // method: print receiver P.Parameters(0, d.typ.key.list); P.separator = blank; } P.Expr(d.ident); P.separator = P.Type(d.typ); if d.list != nil { P.separator = blank; P.Block(0, d.list, d.end, true); } default: P.Error(d.pos, d.tok, "decl"); } } P.newlines = 2; } // ---------------------------------------------------------------------------- // Program func (P *Printer) Program(p *AST.Program) { P.String(p.pos, "package"); P.separator = blank; P.Expr(p.ident); P.newlines = 1; for i := 0; i < p.decls.Len(); i++ { P.Declaration(p.decls.At(i), false); } P.newlines = 1; } // ---------------------------------------------------------------------------- // External interface export func Print(prog *AST.Program) { // setup var P Printer; padchar := byte(' '); if usetabs.BVal() { padchar = '\t'; } text := tabwriter.New(os.Stdout, int(tabwidth.IVal()), 1, padchar, true, html.BVal()); P.Init(text, prog.comments); P.HtmlPrologue("