/* Derived from Inferno's utils/iyacc/yacc.c http://code.google.com/p/inferno-os/source/browse/utils/iyacc/yacc.c This copyright NOTICE applies to all files in this directory and subdirectories, unless another copyright notice appears in a given file or subdirectory. If you take substantial code from this software to use in other programs, you must somehow include with it an appropriate copyright notice that includes the copyright notice and the other notices below. It is fine (and often tidier) to do that in a separate file such as NOTICE, LICENCE or COPYING. Copyright © 1994-1999 Lucent Technologies Inc. All rights reserved. Portions Copyright © 1995-1997 C H Forsyth (forsyth@terzarima.net) Portions Copyright © 1997-1999 Vita Nuova Limited Portions Copyright © 2000-2007 Vita Nuova Holdings Limited (www.vitanuova.com) Portions Copyright © 2004,2006 Bruce Ellis Portions Copyright © 2005-2007 C H Forsyth (forsyth@terzarima.net) Revisions Copyright © 2000-2007 Lucent Technologies Inc. and others Portions Copyright © 2009 The Go Authors. All rights reserved. Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ package main // yacc // major difference is lack of stem ("y" variable) // import ( "bufio" "bytes" "flag" "fmt" "go/format" "io/ioutil" "os" "strconv" "strings" "unicode" ) // the following are adjustable // according to memory size const ( ACTSIZE = 30000 NSTATES = 2000 TEMPSIZE = 2000 SYMINC = 50 // increase for non-term or term RULEINC = 50 // increase for max rule length prodptr[i] PRODINC = 100 // increase for productions prodptr WSETINC = 50 // increase for working sets wsets STATEINC = 200 // increase for states statemem PRIVATE = 0xE000 // unicode private use // relationships which must hold: // TEMPSIZE >= NTERMS + NNONTERM + 1; // TEMPSIZE >= NSTATES; // NTBASE = 010000 ERRCODE = 8190 ACCEPTCODE = 8191 YYLEXUNK = 3 TOKSTART = 4 //index of first defined token ) // no, left, right, binary assoc. const ( NOASC = iota LASC RASC BASC ) // flags for state generation const ( DONE = iota MUSTDO MUSTLOOKAHEAD ) // flags for a rule having an action, and being reduced const ( ACTFLAG = 1 << (iota + 2) REDFLAG ) // output parser flags const yyFlag = -1000 // parse tokens const ( IDENTIFIER = PRIVATE + iota MARK TERM LEFT RIGHT BINARY PREC LCURLY IDENTCOLON NUMBER START TYPEDEF TYPENAME UNION ERROR ) const ENDFILE = 0 const EMPTY = 1 const WHOKNOWS = 0 const OK = 1 const NOMORE = -1000 // macros for getting associativity and precedence levels func ASSOC(i int) int { return i & 3 } func PLEVEL(i int) int { return (i >> 4) & 077 } func TYPE(i int) int { return (i >> 10) & 077 } // macros for setting associativity and precedence levels func SETASC(i, j int) int { return i | j } func SETPLEV(i, j int) int { return i | (j << 4) } func SETTYPE(i, j int) int { return i | (j << 10) } // I/O descriptors var finput *bufio.Reader // input file var stderr *bufio.Writer var ftable *bufio.Writer // y.go file var fcode = &bytes.Buffer{} // saved code var foutput *bufio.Writer // y.output file var fmtImported bool // output file has recorded an import of "fmt" var oflag string // -o [y.go] - y.go file var vflag string // -v [y.output] - y.output file var lflag bool // -l - disable line directives var prefix string // name prefix for identifiers, default yy func init() { flag.StringVar(&oflag, "o", "y.go", "parser output") flag.StringVar(&prefix, "p", "yy", "name prefix to use in generated code") flag.StringVar(&vflag, "v", "y.output", "create parsing tables") flag.BoolVar(&lflag, "l", false, "disable line directives") } var initialstacksize = 16 // communication variables between various I/O routines var infile string // input file name var numbval int // value of an input number var tokname string // input token name, slop for runes and 0 var tokflag = false // structure declarations type Lkset []int type Pitem struct { prod []int off int // offset within the production first int // first term or non-term in item prodno int // production number for sorting } type Item struct { pitem Pitem look Lkset } type Symb struct { name string noconst bool value int } type Wset struct { pitem Pitem flag int ws Lkset } // storage of types var ntypes int // number of types defined var typeset = make(map[int]string) // pointers to type tags // token information var ntokens = 0 // number of tokens var tokset []Symb var toklev []int // vector with the precedence of the terminals // nonterminal information var nnonter = -1 // the number of nonterminals var nontrst []Symb var start int // start symbol // state information var nstate = 0 // number of states var pstate = make([]int, NSTATES+2) // index into statemem to the descriptions of the states var statemem []Item var tystate = make([]int, NSTATES) // contains type information about the states var tstates []int // states generated by terminal gotos var ntstates []int // states generated by nonterminal gotos var mstates = make([]int, NSTATES) // chain of overflows of term/nonterm generation lists var lastred int // number of last reduction of a state var defact = make([]int, NSTATES) // default actions of states // lookahead set information var nolook = 0 // flag to turn off lookahead computations var tbitset = 0 // size of lookahead sets var clset Lkset // temporary storage for lookahead computations // working set information var wsets []Wset var cwp int // storage for action table var amem []int // action table storage var memp int // next free action table position var indgo = make([]int, NSTATES) // index to the stored goto table // temporary vector, indexable by states, terms, or ntokens var temp1 = make([]int, TEMPSIZE) // temporary storage, indexed by terms + ntokens or states var lineno = 1 // current input line number var fatfl = 1 // if on, error is fatal var nerrors = 0 // number of errors // assigned token type values var extval = 0 // grammar rule information var nprod = 1 // number of productions var prdptr [][]int // pointers to descriptions of productions var levprd []int // precedence levels for the productions var rlines []int // line number for this rule // statistics collection variables var zzgoent = 0 var zzgobest = 0 var zzacent = 0 var zzexcp = 0 var zzclose = 0 var zzrrconf = 0 var zzsrconf = 0 var zzstate = 0 // optimizer arrays var yypgo [][]int var optst [][]int var ggreed []int var pgo []int var maxspr int // maximum spread of any entry var maxoff int // maximum offset into a array var maxa int // storage for information about the nonterminals var pres [][][]int // vector of pointers to productions yielding each nonterminal var pfirst []Lkset var pempty []int // vector of nonterminals nontrivially deriving e // random stuff picked out from between functions var indebug = 0 // debugging flag for cpfir var pidebug = 0 // debugging flag for putitem var gsdebug = 0 // debugging flag for stagen var cldebug = 0 // debugging flag for closure var pkdebug = 0 // debugging flag for apack var g2debug = 0 // debugging for go2gen var adb = 0 // debugging for callopt type Resrv struct { name string value int } var resrv = []Resrv{ {"binary", BINARY}, {"left", LEFT}, {"nonassoc", BINARY}, {"prec", PREC}, {"right", RIGHT}, {"start", START}, {"term", TERM}, {"token", TERM}, {"type", TYPEDEF}, {"union", UNION}, {"struct", UNION}, {"error", ERROR}, } type Error struct { lineno int tokens []string msg string } var errors []Error type Row struct { actions []int defaultAction int } var stateTable []Row var zznewstate = 0 const EOF = -1 func main() { setup() // initialize and read productions tbitset = (ntokens + 32) / 32 cpres() // make table of which productions yield a given nonterminal cempty() // make a table of which nonterminals can match the empty string cpfir() // make a table of firsts of nonterminals stagen() // generate the states yypgo = make([][]int, nnonter+1) optst = make([][]int, nstate) output() // write the states and the tables go2out() hideprod() summary() callopt() others() exit(0) } func setup() { var j, ty int stderr = bufio.NewWriter(os.Stderr) foutput = nil flag.Parse() if flag.NArg() != 1 { usage() } if initialstacksize < 1 { // never set so cannot happen fmt.Fprintf(stderr, "yacc: stack size too small\n") usage() } yaccpar = strings.Replace(yaccpartext, "$$", prefix, -1) openup() defin(0, "$end") extval = PRIVATE // tokens start in unicode 'private use' defin(0, "error") defin(1, "$accept") defin(0, "$unk") i := 0 t := gettok() outer: for { switch t { default: errorf("syntax error tok=%v", t-PRIVATE) case MARK, ENDFILE: break outer case ';': case START: t = gettok() if t != IDENTIFIER { errorf("bad %%start construction") } start = chfind(1, tokname) case ERROR: lno := lineno var tokens []string for { t := gettok() if t == ':' { break } if t != IDENTIFIER && t != IDENTCOLON { errorf("bad syntax in %%error") } tokens = append(tokens, tokname) if t == IDENTCOLON { break } } if gettok() != IDENTIFIER { errorf("bad syntax in %%error") } errors = append(errors, Error{lno, tokens, tokname}) case TYPEDEF: t = gettok() if t != TYPENAME { errorf("bad syntax in %%type") } ty = numbval for { t = gettok() switch t { case IDENTIFIER: t = chfind(1, tokname) if t < NTBASE { j = TYPE(toklev[t]) if j != 0 && j != ty { errorf("type redeclaration of token %s", tokset[t].name) } else { toklev[t] = SETTYPE(toklev[t], ty) } } else { j = nontrst[t-NTBASE].value if j != 0 && j != ty { errorf("type redeclaration of nonterminal %v", nontrst[t-NTBASE].name) } else { nontrst[t-NTBASE].value = ty } } continue case ',': continue } break } continue case UNION: cpyunion() case LEFT, BINARY, RIGHT, TERM: // nonzero means new prec. and assoc. lev := t - TERM if lev != 0 { i++ } ty = 0 // get identifiers so defined t = gettok() // there is a type defined if t == TYPENAME { ty = numbval t = gettok() } for { switch t { case ',': t = gettok() continue case ';': break case IDENTIFIER: j = chfind(0, tokname) if j >= NTBASE { errorf("%v defined earlier as nonterminal", tokname) } if lev != 0 { if ASSOC(toklev[j]) != 0 { errorf("redeclaration of precedence of %v", tokname) } toklev[j] = SETASC(toklev[j], lev) toklev[j] = SETPLEV(toklev[j], i) } if ty != 0 { if TYPE(toklev[j]) != 0 { errorf("redeclaration of type of %v", tokname) } toklev[j] = SETTYPE(toklev[j], ty) } t = gettok() if t == NUMBER { tokset[j].value = numbval t = gettok() } continue } break } continue case LCURLY: cpycode() } t = gettok() } if t == ENDFILE { errorf("unexpected EOF before %%") } fmt.Fprintf(fcode, "switch %snt {\n", prefix) moreprod() prdptr[0] = []int{NTBASE, start, 1, 0} nprod = 1 curprod := make([]int, RULEINC) t = gettok() if t != IDENTCOLON { errorf("bad syntax on first rule") } if start == 0 { prdptr[0][1] = chfind(1, tokname) } // read rules // put into prdptr array in the format // target // followed by id's of terminals and non-terminals // followed by -nprod for t != MARK && t != ENDFILE { mem := 0 // process a rule rlines[nprod] = lineno ruleline := lineno if t == '|' { curprod[mem] = prdptr[nprod-1][0] mem++ } else if t == IDENTCOLON { curprod[mem] = chfind(1, tokname) if curprod[mem] < NTBASE { lerrorf(ruleline, "token illegal on LHS of grammar rule") } mem++ } else { lerrorf(ruleline, "illegal rule: missing semicolon or | ?") } // read rule body t = gettok() for { for t == IDENTIFIER { curprod[mem] = chfind(1, tokname) if curprod[mem] < NTBASE { levprd[nprod] = toklev[curprod[mem]] } mem++ if mem >= len(curprod) { ncurprod := make([]int, mem+RULEINC) copy(ncurprod, curprod) curprod = ncurprod } t = gettok() } if t == PREC { if gettok() != IDENTIFIER { lerrorf(ruleline, "illegal %%prec syntax") } j = chfind(2, tokname) if j >= NTBASE { lerrorf(ruleline, "nonterminal "+nontrst[j-NTBASE].name+" illegal after %%prec") } levprd[nprod] = toklev[j] t = gettok() } if t != '=' { break } levprd[nprod] |= ACTFLAG fmt.Fprintf(fcode, "\n\tcase %v:", nprod) fmt.Fprintf(fcode, "\n\t\t%sDollar = %sS[%spt-%v:%spt+1]", prefix, prefix, prefix, mem-1, prefix) cpyact(curprod, mem) // action within rule... t = gettok() if t == IDENTIFIER { // make it a nonterminal j = chfind(1, fmt.Sprintf("$$%v", nprod)) // // the current rule will become rule number nprod+1 // enter null production for action // prdptr[nprod] = make([]int, 2) prdptr[nprod][0] = j prdptr[nprod][1] = -nprod // update the production information nprod++ moreprod() levprd[nprod] = levprd[nprod-1] & ^ACTFLAG levprd[nprod-1] = ACTFLAG rlines[nprod] = lineno // make the action appear in the original rule curprod[mem] = j mem++ if mem >= len(curprod) { ncurprod := make([]int, mem+RULEINC) copy(ncurprod, curprod) curprod = ncurprod } } } for t == ';' { t = gettok() } curprod[mem] = -nprod mem++ // check that default action is reasonable if ntypes != 0 && (levprd[nprod]&ACTFLAG) == 0 && nontrst[curprod[0]-NTBASE].value != 0 { // no explicit action, LHS has value tempty := curprod[1] if tempty < 0 { lerrorf(ruleline, "must return a value, since LHS has a type") } if tempty >= NTBASE { tempty = nontrst[tempty-NTBASE].value } else { tempty = TYPE(toklev[tempty]) } if tempty != nontrst[curprod[0]-NTBASE].value { lerrorf(ruleline, "default action causes potential type clash") } } moreprod() prdptr[nprod] = make([]int, mem) copy(prdptr[nprod], curprod) nprod++ moreprod() levprd[nprod] = 0 } if TEMPSIZE < ntokens+nnonter+1 { errorf("too many tokens (%d) or non-terminals (%d)", ntokens, nnonter) } // // end of all rules // dump out the prefix code // fmt.Fprintf(fcode, "\n\t}") // put out non-literal terminals for i := TOKSTART; i <= ntokens; i++ { // non-literals if !tokset[i].noconst { fmt.Fprintf(ftable, "const %v = %v\n", tokset[i].name, tokset[i].value) } } // put out names of tokens ftable.WriteRune('\n') fmt.Fprintf(ftable, "var %sToknames = [...]string{\n", prefix) for i := 1; i <= ntokens; i++ { fmt.Fprintf(ftable, "\t%q,\n", tokset[i].name) } fmt.Fprintf(ftable, "}\n") // put out names of states. // commented out to avoid a huge table just for debugging. // re-enable to have the names in the binary. fmt.Fprintf(ftable, "var %sStatenames = [...]string{", prefix) // for i:=TOKSTART; i<=ntokens; i++ { // fmt.Fprintf(ftable, "\t%q,\n", tokset[i].name); // } fmt.Fprintf(ftable, "}\n") ftable.WriteRune('\n') fmt.Fprintf(ftable, "const %sEofCode = 1\n", prefix) fmt.Fprintf(ftable, "const %sErrCode = 2\n", prefix) fmt.Fprintf(ftable, "const %sInitialStackSize = %v\n", prefix, initialstacksize) // // copy any postfix code // if t == MARK { if !lflag { fmt.Fprintf(ftable, "\n//line %v:%v\n", infile, lineno) } for { c := getrune(finput) if c == EOF { break } ftable.WriteRune(c) } } } // // allocate enough room to hold another production // func moreprod() { n := len(prdptr) if nprod >= n { nn := n + PRODINC aprod := make([][]int, nn) alevprd := make([]int, nn) arlines := make([]int, nn) copy(aprod, prdptr) copy(alevprd, levprd) copy(arlines, rlines) prdptr = aprod levprd = alevprd rlines = arlines } } // // define s to be a terminal if nt==0 // or a nonterminal if nt==1 // func defin(nt int, s string) int { val := 0 if nt != 0 { nnonter++ if nnonter >= len(nontrst) { anontrst := make([]Symb, nnonter+SYMINC) copy(anontrst, nontrst) nontrst = anontrst } nontrst[nnonter] = Symb{name: s} return NTBASE + nnonter } // must be a token ntokens++ if ntokens >= len(tokset) { nn := ntokens + SYMINC atokset := make([]Symb, nn) atoklev := make([]int, nn) copy(atoklev, toklev) copy(atokset, tokset) tokset = atokset toklev = atoklev } tokset[ntokens].name = s toklev[ntokens] = 0 // establish value for token // single character literal if s[0] == '\'' || s[0] == '"' { q, err := strconv.Unquote(s) if err != nil { errorf("invalid token: %s", err) } rq := []rune(q) if len(rq) != 1 { errorf("character token too long: %s", s) } val = int(rq[0]) if val == 0 { errorf("token value 0 is illegal") } tokset[ntokens].noconst = true } else { val = extval extval++ if s[0] == '$' { tokset[ntokens].noconst = true } } tokset[ntokens].value = val return ntokens } var peekline = 0 func gettok() int { var i int var match, c rune tokname = "" for { lineno += peekline peekline = 0 c = getrune(finput) for c == ' ' || c == '\n' || c == '\t' || c == '\v' || c == '\r' { if c == '\n' { lineno++ } c = getrune(finput) } // skip comment -- fix if c != '/' { break } lineno += skipcom() } switch c { case EOF: if tokflag { fmt.Printf(">>> ENDFILE %v\n", lineno) } return ENDFILE case '{': ungetrune(finput, c) if tokflag { fmt.Printf(">>> ={ %v\n", lineno) } return '=' case '<': // get, and look up, a type name (union member name) c = getrune(finput) for c != '>' && c != EOF && c != '\n' { tokname += string(c) c = getrune(finput) } if c != '>' { errorf("unterminated < ... > clause") } for i = 1; i <= ntypes; i++ { if typeset[i] == tokname { numbval = i if tokflag { fmt.Printf(">>> TYPENAME old <%v> %v\n", tokname, lineno) } return TYPENAME } } ntypes++ numbval = ntypes typeset[numbval] = tokname if tokflag { fmt.Printf(">>> TYPENAME new <%v> %v\n", tokname, lineno) } return TYPENAME case '"', '\'': match = c tokname = string(c) for { c = getrune(finput) if c == '\n' || c == EOF { errorf("illegal or missing ' or \"") } if c == '\\' { tokname += string('\\') c = getrune(finput) } else if c == match { if tokflag { fmt.Printf(">>> IDENTIFIER \"%v\" %v\n", tokname, lineno) } tokname += string(c) return IDENTIFIER } tokname += string(c) } case '%': c = getrune(finput) switch c { case '%': if tokflag { fmt.Printf(">>> MARK %%%% %v\n", lineno) } return MARK case '=': if tokflag { fmt.Printf(">>> PREC %%= %v\n", lineno) } return PREC case '{': if tokflag { fmt.Printf(">>> LCURLY %%{ %v\n", lineno) } return LCURLY } getword(c) // find a reserved word for i := range resrv { if tokname == resrv[i].name { if tokflag { fmt.Printf(">>> %%%v %v %v\n", tokname, resrv[i].value-PRIVATE, lineno) } return resrv[i].value } } errorf("invalid escape, or illegal reserved word: %v", tokname) case '0', '1', '2', '3', '4', '5', '6', '7', '8', '9': numbval = int(c - '0') for { c = getrune(finput) if !isdigit(c) { break } numbval = numbval*10 + int(c-'0') } ungetrune(finput, c) if tokflag { fmt.Printf(">>> NUMBER %v %v\n", numbval, lineno) } return NUMBER default: if isword(c) || c == '.' || c == '$' { getword(c) break } if tokflag { fmt.Printf(">>> OPERATOR %v %v\n", string(c), lineno) } return int(c) } // look ahead to distinguish IDENTIFIER from IDENTCOLON c = getrune(finput) for c == ' ' || c == '\t' || c == '\n' || c == '\v' || c == '\r' || c == '/' { if c == '\n' { peekline++ } // look for comments if c == '/' { peekline += skipcom() } c = getrune(finput) } if c == ':' { if tokflag { fmt.Printf(">>> IDENTCOLON %v: %v\n", tokname, lineno) } return IDENTCOLON } ungetrune(finput, c) if tokflag { fmt.Printf(">>> IDENTIFIER %v %v\n", tokname, lineno) } return IDENTIFIER } func getword(c rune) { tokname = "" for isword(c) || isdigit(c) || c == '.' || c == '$' { tokname += string(c) c = getrune(finput) } ungetrune(finput, c) } // // determine the type of a symbol // func fdtype(t int) int { var v int var s string if t >= NTBASE { v = nontrst[t-NTBASE].value s = nontrst[t-NTBASE].name } else { v = TYPE(toklev[t]) s = tokset[t].name } if v <= 0 { errorf("must specify type for %v", s) } return v } func chfind(t int, s string) int { if s[0] == '"' || s[0] == '\'' { t = 0 } for i := 0; i <= ntokens; i++ { if s == tokset[i].name { return i } } for i := 0; i <= nnonter; i++ { if s == nontrst[i].name { return NTBASE + i } } // cannot find name if t > 1 { errorf("%v should have been defined earlier", s) } return defin(t, s) } // // copy the union declaration to the output, and the define file if present // func cpyunion() { if !lflag { fmt.Fprintf(ftable, "\n//line %v:%v\n", infile, lineno) } fmt.Fprintf(ftable, "type %sSymType struct", prefix) level := 0 out: for { c := getrune(finput) if c == EOF { errorf("EOF encountered while processing %%union") } ftable.WriteRune(c) switch c { case '\n': lineno++ case '{': if level == 0 { fmt.Fprintf(ftable, "\n\tyys int") } level++ case '}': level-- if level == 0 { break out } } } fmt.Fprintf(ftable, "\n\n") } // // saves code between %{ and %} // adds an import for __fmt__ the first time // func cpycode() { lno := lineno c := getrune(finput) if c == '\n' { c = getrune(finput) lineno++ } if !lflag { fmt.Fprintf(ftable, "\n//line %v:%v\n", infile, lineno) } // accumulate until %} code := make([]rune, 0, 1024) for c != EOF { if c == '%' { c = getrune(finput) if c == '}' { emitcode(code, lno+1) return } code = append(code, '%') } code = append(code, c) if c == '\n' { lineno++ } c = getrune(finput) } lineno = lno errorf("eof before %%}") } // // emits code saved up from between %{ and %} // called by cpycode // adds an import for __yyfmt__ after the package clause // func emitcode(code []rune, lineno int) { for i, line := range lines(code) { writecode(line) if !fmtImported && isPackageClause(line) { fmt.Fprintln(ftable, `import __yyfmt__ "fmt"`) if !lflag { fmt.Fprintf(ftable, "//line %v:%v\n\t\t", infile, lineno+i) } fmtImported = true } } } // // does this line look like a package clause? not perfect: might be confused by early comments. // func isPackageClause(line []rune) bool { line = skipspace(line) // must be big enough. if len(line) < len("package X\n") { return false } // must start with "package" for i, r := range []rune("package") { if line[i] != r { return false } } line = skipspace(line[len("package"):]) // must have another identifier. if len(line) == 0 || (!unicode.IsLetter(line[0]) && line[0] != '_') { return false } for len(line) > 0 { if !unicode.IsLetter(line[0]) && !unicode.IsDigit(line[0]) && line[0] != '_' { break } line = line[1:] } line = skipspace(line) // eol, newline, or comment must follow if len(line) == 0 { return true } if line[0] == '\r' || line[0] == '\n' { return true } if len(line) >= 2 { return line[0] == '/' && (line[1] == '/' || line[1] == '*') } return false } // // skip initial spaces // func skipspace(line []rune) []rune { for len(line) > 0 { if line[0] != ' ' && line[0] != '\t' { break } line = line[1:] } return line } // // break code into lines // func lines(code []rune) [][]rune { l := make([][]rune, 0, 100) for len(code) > 0 { // one line per loop var i int for i = range code { if code[i] == '\n' { break } } l = append(l, code[:i+1]) code = code[i+1:] } return l } // // writes code to ftable // func writecode(code []rune) { for _, r := range code { ftable.WriteRune(r) } } // // skip over comments // skipcom is called after reading a '/' // func skipcom() int { var c rune c = getrune(finput) if c == '/' { for c != EOF { if c == '\n' { return 1 } c = getrune(finput) } errorf("EOF inside comment") return 0 } if c != '*' { errorf("illegal comment") } nl := 0 // lines skipped c = getrune(finput) l1: switch c { case '*': c = getrune(finput) if c == '/' { break } goto l1 case '\n': nl++ fallthrough default: c = getrune(finput) goto l1 } return nl } func dumpprod(curprod []int, max int) { fmt.Printf("\n") for i := 0; i < max; i++ { p := curprod[i] if p < 0 { fmt.Printf("[%v] %v\n", i, p) } else { fmt.Printf("[%v] %v\n", i, symnam(p)) } } } // // copy action to the next ; or closing } // func cpyact(curprod []int, max int) { if !lflag { fmt.Fprintf(fcode, "\n\t\t//line %v:%v", infile, lineno) } fmt.Fprint(fcode, "\n\t\t") lno := lineno brac := 0 loop: for { c := getrune(finput) swt: switch c { case ';': if brac == 0 { fcode.WriteRune(c) return } case '{': if brac == 0 { } brac++ case '$': s := 1 tok := -1 c = getrune(finput) // type description if c == '<' { ungetrune(finput, c) if gettok() != TYPENAME { errorf("bad syntax on $ clause") } tok = numbval c = getrune(finput) } if c == '$' { fmt.Fprintf(fcode, "%sVAL", prefix) // put out the proper tag... if ntypes != 0 { if tok < 0 { tok = fdtype(curprod[0]) } fmt.Fprintf(fcode, ".%v", typeset[tok]) } continue loop } if c == '-' { s = -s c = getrune(finput) } j := 0 if isdigit(c) { for isdigit(c) { j = j*10 + int(c-'0') c = getrune(finput) } ungetrune(finput, c) j = j * s if j >= max { errorf("Illegal use of $%v", j) } } else if isword(c) || c == '.' { // look for $name ungetrune(finput, c) if gettok() != IDENTIFIER { errorf("$ must be followed by an identifier") } tokn := chfind(2, tokname) fnd := -1 c = getrune(finput) if c != '@' { ungetrune(finput, c) } else if gettok() != NUMBER { errorf("@ must be followed by number") } else { fnd = numbval } for j = 1; j < max; j++ { if tokn == curprod[j] { fnd-- if fnd <= 0 { break } } } if j >= max { errorf("$name or $name@number not found") } } else { fcode.WriteRune('$') if s < 0 { fcode.WriteRune('-') } ungetrune(finput, c) continue loop } fmt.Fprintf(fcode, "%sDollar[%v]", prefix, j) // put out the proper tag if ntypes != 0 { if j <= 0 && tok < 0 { errorf("must specify type of $%v", j) } if tok < 0 { tok = fdtype(curprod[j]) } fmt.Fprintf(fcode, ".%v", typeset[tok]) } continue loop case '}': brac-- if brac != 0 { break } fcode.WriteRune(c) return case '/': nc := getrune(finput) if nc != '/' && nc != '*' { ungetrune(finput, nc) break } // a comment fcode.WriteRune(c) fcode.WriteRune(nc) c = getrune(finput) for c != EOF { switch { case c == '\n': lineno++ if nc == '/' { // end of // comment break swt } case c == '*' && nc == '*': // end of /* comment? nnc := getrune(finput) if nnc == '/' { fcode.WriteRune('*') fcode.WriteRune('/') c = getrune(finput) break swt } ungetrune(finput, nnc) } fcode.WriteRune(c) c = getrune(finput) } errorf("EOF inside comment") case '\'', '"': // character string or constant match := c fcode.WriteRune(c) c = getrune(finput) for c != EOF { if c == '\\' { fcode.WriteRune(c) c = getrune(finput) if c == '\n' { lineno++ } } else if c == match { break swt } if c == '\n' { errorf("newline in string or char const") } fcode.WriteRune(c) c = getrune(finput) } errorf("EOF in string or character constant") case EOF: lineno = lno errorf("action does not terminate") case '\n': fmt.Fprint(fcode, "\n\t") lineno++ continue loop } fcode.WriteRune(c) } } func openup() { infile = flag.Arg(0) finput = open(infile) if finput == nil { errorf("cannot open %v", infile) } foutput = nil if vflag != "" { foutput = create(vflag) if foutput == nil { errorf("can't create file %v", vflag) } } ftable = nil if oflag == "" { oflag = "y.go" } ftable = create(oflag) if ftable == nil { errorf("can't create file %v", oflag) } } // // return a pointer to the name of symbol i // func symnam(i int) string { var s string if i >= NTBASE { s = nontrst[i-NTBASE].name } else { s = tokset[i].name } return s } // // set elements 0 through n-1 to c // func aryfil(v []int, n, c int) { for i := 0; i < n; i++ { v[i] = c } } // // compute an array with the beginnings of productions yielding given nonterminals // The array pres points to these lists // the array pyield has the lists: the total size is only NPROD+1 // func cpres() { pres = make([][][]int, nnonter+1) curres := make([][]int, nprod) if false { for j := 0; j <= nnonter; j++ { fmt.Printf("nnonter[%v] = %v\n", j, nontrst[j].name) } for j := 0; j < nprod; j++ { fmt.Printf("prdptr[%v][0] = %v+NTBASE\n", j, prdptr[j][0]-NTBASE) } } fatfl = 0 // make undefined symbols nonfatal for i := 0; i <= nnonter; i++ { n := 0 c := i + NTBASE for j := 0; j < nprod; j++ { if prdptr[j][0] == c { curres[n] = prdptr[j][1:] n++ } } if n == 0 { errorf("nonterminal %v not defined", nontrst[i].name) continue } pres[i] = make([][]int, n) copy(pres[i], curres) } fatfl = 1 if nerrors != 0 { summary() exit(1) } } func dumppres() { for i := 0; i <= nnonter; i++ { fmt.Printf("nonterm %d\n", i) curres := pres[i] for j := 0; j < len(curres); j++ { fmt.Printf("\tproduction %d:", j) prd := curres[j] for k := 0; k < len(prd); k++ { fmt.Printf(" %d", prd[k]) } fmt.Print("\n") } } } // // mark nonterminals which derive the empty string // also, look for nonterminals which don't derive any token strings // func cempty() { var i, p, np int var prd []int pempty = make([]int, nnonter+1) // first, use the array pempty to detect productions that can never be reduced // set pempty to WHONOWS aryfil(pempty, nnonter+1, WHOKNOWS) // now, look at productions, marking nonterminals which derive something more: for { for i = 0; i < nprod; i++ { prd = prdptr[i] if pempty[prd[0]-NTBASE] != 0 { continue } np = len(prd) - 1 for p = 1; p < np; p++ { if prd[p] >= NTBASE && pempty[prd[p]-NTBASE] == WHOKNOWS { break } } // production can be derived if p == np { pempty[prd[0]-NTBASE] = OK continue more } } break } // now, look at the nonterminals, to see if they are all OK for i = 0; i <= nnonter; i++ { // the added production rises or falls as the start symbol ... if i == 0 { continue } if pempty[i] != OK { fatfl = 0 errorf("nonterminal " + nontrst[i].name + " never derives any token string") } } if nerrors != 0 { summary() exit(1) } // now, compute the pempty array, to see which nonterminals derive the empty string // set pempty to WHOKNOWS aryfil(pempty, nnonter+1, WHOKNOWS) // loop as long as we keep finding empty nonterminals again: for { next: for i = 1; i < nprod; i++ { // not known to be empty prd = prdptr[i] if pempty[prd[0]-NTBASE] != WHOKNOWS { continue } np = len(prd) - 1 for p = 1; p < np; p++ { if prd[p] < NTBASE || pempty[prd[p]-NTBASE] != EMPTY { continue next } } // we have a nontrivially empty nonterminal pempty[prd[0]-NTBASE] = EMPTY // got one ... try for another continue again } return } } func dumpempty() { for i := 0; i <= nnonter; i++ { if pempty[i] == EMPTY { fmt.Printf("non-term %d %s matches empty\n", i, symnam(i+NTBASE)) } } } // // compute an array with the first of nonterminals // func cpfir() { var s, n, p, np, ch, i int var curres [][]int var prd []int wsets = make([]Wset, nnonter+WSETINC) pfirst = make([]Lkset, nnonter+1) for i = 0; i <= nnonter; i++ { wsets[i].ws = mkset() pfirst[i] = mkset() curres = pres[i] n = len(curres) // initially fill the sets for s = 0; s < n; s++ { prd = curres[s] np = len(prd) - 1 for p = 0; p < np; p++ { ch = prd[p] if ch < NTBASE { setbit(pfirst[i], ch) break } if pempty[ch-NTBASE] == 0 { break } } } } // now, reflect transitivity changes := 1 for changes != 0 { changes = 0 for i = 0; i <= nnonter; i++ { curres = pres[i] n = len(curres) for s = 0; s < n; s++ { prd = curres[s] np = len(prd) - 1 for p = 0; p < np; p++ { ch = prd[p] - NTBASE if ch < 0 { break } changes |= setunion(pfirst[i], pfirst[ch]) if pempty[ch] == 0 { break } } } } } if indebug == 0 { return } if foutput != nil { for i = 0; i <= nnonter; i++ { fmt.Fprintf(foutput, "\n%v: %v %v\n", nontrst[i].name, pfirst[i], pempty[i]) } } } // // generate the states // func stagen() { // initialize nstate = 0 tstates = make([]int, ntokens+1) // states generated by terminal gotos ntstates = make([]int, nnonter+1) // states generated by nonterminal gotos amem = make([]int, ACTSIZE) memp = 0 clset = mkset() pstate[0] = 0 pstate[1] = 0 aryfil(clset, tbitset, 0) putitem(Pitem{prdptr[0], 0, 0, 0}, clset) tystate[0] = MUSTDO nstate = 1 pstate[2] = pstate[1] // // now, the main state generation loop // first pass generates all of the states // later passes fix up lookahead // could be sped up a lot by remembering // results of the first pass rather than recomputing // first := 1 for more := 1; more != 0; first = 0 { more = 0 for i := 0; i < nstate; i++ { if tystate[i] != MUSTDO { continue } tystate[i] = DONE aryfil(temp1, nnonter+1, 0) // take state i, close it, and do gotos closure(i) // generate goto's for p := 0; p < cwp; p++ { pi := wsets[p] if pi.flag != 0 { continue } wsets[p].flag = 1 c := pi.pitem.first if c <= 1 { if pstate[i+1]-pstate[i] <= p { tystate[i] = MUSTLOOKAHEAD } continue } // do a goto on c putitem(wsets[p].pitem, wsets[p].ws) for q := p + 1; q < cwp; q++ { // this item contributes to the goto if c == wsets[q].pitem.first { putitem(wsets[q].pitem, wsets[q].ws) wsets[q].flag = 1 } } if c < NTBASE { state(c) // register new state } else { temp1[c-NTBASE] = state(c) } } if gsdebug != 0 && foutput != nil { fmt.Fprintf(foutput, "%v: ", i) for j := 0; j <= nnonter; j++ { if temp1[j] != 0 { fmt.Fprintf(foutput, "%v %v,", nontrst[j].name, temp1[j]) } } fmt.Fprintf(foutput, "\n") } if first != 0 { indgo[i] = apack(temp1[1:], nnonter-1) - 1 } more++ } } } // // generate the closure of state i // func closure(i int) { zzclose++ // first, copy kernel of state i to wsets cwp = 0 q := pstate[i+1] for p := pstate[i]; p < q; p++ { wsets[cwp].pitem = statemem[p].pitem wsets[cwp].flag = 1 // this item must get closed copy(wsets[cwp].ws, statemem[p].look) cwp++ } // now, go through the loop, closing each item work := 1 for work != 0 { work = 0 for u := 0; u < cwp; u++ { if wsets[u].flag == 0 { continue } // dot is before c c := wsets[u].pitem.first if c < NTBASE { wsets[u].flag = 0 // only interesting case is where . is before nonterminal continue } // compute the lookahead aryfil(clset, tbitset, 0) // find items involving c for v := u; v < cwp; v++ { if wsets[v].flag != 1 || wsets[v].pitem.first != c { continue } pi := wsets[v].pitem.prod ipi := wsets[v].pitem.off + 1 wsets[v].flag = 0 if nolook != 0 { continue } ch := pi[ipi] ipi++ for ch > 0 { // terminal symbol if ch < NTBASE { setbit(clset, ch) break } // nonterminal symbol setunion(clset, pfirst[ch-NTBASE]) if pempty[ch-NTBASE] == 0 { break } ch = pi[ipi] ipi++ } if ch <= 0 { setunion(clset, wsets[v].ws) } } // // now loop over productions derived from c // curres := pres[c-NTBASE] n := len(curres) nexts: // initially fill the sets for s := 0; s < n; s++ { prd := curres[s] // // put these items into the closure // is the item there // for v := 0; v < cwp; v++ { // yes, it is there if wsets[v].pitem.off == 0 && aryeq(wsets[v].pitem.prod, prd) != 0 { if nolook == 0 && setunion(wsets[v].ws, clset) != 0 { wsets[v].flag = 1 work = 1 } continue nexts } } // not there; make a new entry if cwp >= len(wsets) { awsets := make([]Wset, cwp+WSETINC) copy(awsets, wsets) wsets = awsets } wsets[cwp].pitem = Pitem{prd, 0, prd[0], -prd[len(prd)-1]} wsets[cwp].flag = 1 wsets[cwp].ws = mkset() if nolook == 0 { work = 1 copy(wsets[cwp].ws, clset) } cwp++ } } } // have computed closure; flags are reset; return if cldebug != 0 && foutput != nil { fmt.Fprintf(foutput, "\nState %v, nolook = %v\n", i, nolook) for u := 0; u < cwp; u++ { if wsets[u].flag != 0 { fmt.Fprintf(foutput, "flag set\n") } wsets[u].flag = 0 fmt.Fprintf(foutput, "\t%v", writem(wsets[u].pitem)) prlook(wsets[u].ws) fmt.Fprintf(foutput, "\n") } } } // // sorts last state,and sees if it equals earlier ones. returns state number // func state(c int) int { zzstate++ p1 := pstate[nstate] p2 := pstate[nstate+1] if p1 == p2 { return 0 // null state } // sort the items var k, l int for k = p1 + 1; k < p2; k++ { // make k the biggest for l = k; l > p1; l-- { if statemem[l].pitem.prodno < statemem[l-1].pitem.prodno || statemem[l].pitem.prodno == statemem[l-1].pitem.prodno && statemem[l].pitem.off < statemem[l-1].pitem.off { s := statemem[l] statemem[l] = statemem[l-1] statemem[l-1] = s } else { break } } } size1 := p2 - p1 // size of state var i int if c >= NTBASE { i = ntstates[c-NTBASE] } else { i = tstates[c] } look: for ; i != 0; i = mstates[i] { // get ith state q1 := pstate[i] q2 := pstate[i+1] size2 := q2 - q1 if size1 != size2 { continue } k = p1 for l = q1; l < q2; l++ { if aryeq(statemem[l].pitem.prod, statemem[k].pitem.prod) == 0 || statemem[l].pitem.off != statemem[k].pitem.off { continue look } k++ } // found it pstate[nstate+1] = pstate[nstate] // delete last state // fix up lookaheads if nolook != 0 { return i } k = p1 for l = q1; l < q2; l++ { if setunion(statemem[l].look, statemem[k].look) != 0 { tystate[i] = MUSTDO } k++ } return i } // state is new zznewstate++ if nolook != 0 { errorf("yacc state/nolook error") } pstate[nstate+2] = p2 if nstate+1 >= NSTATES { errorf("too many states") } if c >= NTBASE { mstates[nstate] = ntstates[c-NTBASE] ntstates[c-NTBASE] = nstate } else { mstates[nstate] = tstates[c] tstates[c] = nstate } tystate[nstate] = MUSTDO nstate++ return nstate - 1 } func putitem(p Pitem, set Lkset) { p.off++ p.first = p.prod[p.off] if pidebug != 0 && foutput != nil { fmt.Fprintf(foutput, "putitem(%v), state %v\n", writem(p), nstate) } j := pstate[nstate+1] if j >= len(statemem) { asm := make([]Item, j+STATEINC) copy(asm, statemem) statemem = asm } statemem[j].pitem = p if nolook == 0 { s := mkset() copy(s, set) statemem[j].look = s } j++ pstate[nstate+1] = j } // // creates output string for item pointed to by pp // func writem(pp Pitem) string { var i int p := pp.prod q := chcopy(nontrst[prdptr[pp.prodno][0]-NTBASE].name) + ": " npi := pp.off pi := aryeq(p, prdptr[pp.prodno]) for { c := ' ' if pi == npi { c = '.' } q += string(c) i = p[pi] pi++ if i <= 0 { break } q += chcopy(symnam(i)) } // an item calling for a reduction i = p[npi] if i < 0 { q += fmt.Sprintf(" (%v)", -i) } return q } // // pack state i from temp1 into amem // func apack(p []int, n int) int { // // we don't need to worry about checking because // we will only look at entries known to be there... // eliminate leading and trailing 0's // off := 0 pp := 0 for ; pp <= n && p[pp] == 0; pp++ { off-- } // no actions if pp > n { return 0 } for ; n > pp && p[n] == 0; n-- { } p = p[pp : n+1] // now, find a place for the elements from p to q, inclusive r := len(amem) - len(p) nextk: for rr := 0; rr <= r; rr++ { qq := rr for pp = 0; pp < len(p); pp++ { if p[pp] != 0 { if p[pp] != amem[qq] && amem[qq] != 0 { continue nextk } } qq++ } // we have found an acceptable k if pkdebug != 0 && foutput != nil { fmt.Fprintf(foutput, "off = %v, k = %v\n", off+rr, rr) } qq = rr for pp = 0; pp < len(p); pp++ { if p[pp] != 0 { if qq > memp { memp = qq } amem[qq] = p[pp] } qq++ } if pkdebug != 0 && foutput != nil { for pp = 0; pp <= memp; pp += 10 { fmt.Fprintf(foutput, "\n") for qq = pp; qq <= pp+9; qq++ { fmt.Fprintf(foutput, "%v ", amem[qq]) } fmt.Fprintf(foutput, "\n") } } return off + rr } errorf("no space in action table") return 0 } // // print the output for the states // func output() { var c, u, v int if !lflag { fmt.Fprintf(ftable, "\n//line yacctab:1") } fmt.Fprintf(ftable, "\nvar %sExca = [...]int{\n", prefix) if len(errors) > 0 { stateTable = make([]Row, nstate) } noset := mkset() // output the stuff for state i for i := 0; i < nstate; i++ { nolook = 0 if tystate[i] != MUSTLOOKAHEAD { nolook = 1 } closure(i) // output actions nolook = 1 aryfil(temp1, ntokens+nnonter+1, 0) for u = 0; u < cwp; u++ { c = wsets[u].pitem.first if c > 1 && c < NTBASE && temp1[c] == 0 { for v = u; v < cwp; v++ { if c == wsets[v].pitem.first { putitem(wsets[v].pitem, noset) } } temp1[c] = state(c) } else if c > NTBASE { c -= NTBASE if temp1[c+ntokens] == 0 { temp1[c+ntokens] = amem[indgo[i]+c] } } } if i == 1 { temp1[1] = ACCEPTCODE } // now, we have the shifts; look at the reductions lastred = 0 for u = 0; u < cwp; u++ { c = wsets[u].pitem.first // reduction if c > 0 { continue } lastred = -c us := wsets[u].ws for k := 0; k <= ntokens; k++ { if bitset(us, k) == 0 { continue } if temp1[k] == 0 { temp1[k] = c } else if temp1[k] < 0 { // reduce/reduce conflict if foutput != nil { fmt.Fprintf(foutput, "\n %v: reduce/reduce conflict (red'ns "+ "%v and %v) on %v", i, -temp1[k], lastred, symnam(k)) } if -temp1[k] > lastred { temp1[k] = -lastred } zzrrconf++ } else { // potential shift/reduce conflict precftn(lastred, k, i) } } } wract(i) } fmt.Fprintf(ftable, "}\n") ftable.WriteRune('\n') fmt.Fprintf(ftable, "const %sNprod = %v\n", prefix, nprod) fmt.Fprintf(ftable, "const %sPrivate = %v\n", prefix, PRIVATE) ftable.WriteRune('\n') fmt.Fprintf(ftable, "var %sTokenNames []string\n", prefix) fmt.Fprintf(ftable, "var %sStates []string\n", prefix) } // // decide a shift/reduce conflict by precedence. // r is a rule number, t a token number // the conflict is in state s // temp1[t] is changed to reflect the action // func precftn(r, t, s int) { var action int lp := levprd[r] lt := toklev[t] if PLEVEL(lt) == 0 || PLEVEL(lp) == 0 { // conflict if foutput != nil { fmt.Fprintf(foutput, "\n%v: shift/reduce conflict (shift %v(%v), red'n %v(%v)) on %v", s, temp1[t], PLEVEL(lt), r, PLEVEL(lp), symnam(t)) } zzsrconf++ return } if PLEVEL(lt) == PLEVEL(lp) { action = ASSOC(lt) } else if PLEVEL(lt) > PLEVEL(lp) { action = RASC // shift } else { action = LASC } // reduce switch action { case BASC: // error action temp1[t] = ERRCODE case LASC: // reduce temp1[t] = -r } } // // output state i // temp1 has the actions, lastred the default // func wract(i int) { var p, p1 int // find the best choice for lastred lastred = 0 ntimes := 0 for j := 0; j <= ntokens; j++ { if temp1[j] >= 0 { continue } if temp1[j]+lastred == 0 { continue } // count the number of appearances of temp1[j] count := 0 tred := -temp1[j] levprd[tred] |= REDFLAG for p = 0; p <= ntokens; p++ { if temp1[p]+tred == 0 { count++ } } if count > ntimes { lastred = tred ntimes = count } } // // for error recovery, arrange that, if there is a shift on the // error recovery token, `error', that the default be the error action // if temp1[2] > 0 { lastred = 0 } // clear out entries in temp1 which equal lastred // count entries in optst table n := 0 for p = 0; p <= ntokens; p++ { p1 = temp1[p] if p1+lastred == 0 { temp1[p] = 0 p1 = 0 } if p1 > 0 && p1 != ACCEPTCODE && p1 != ERRCODE { n++ } } wrstate(i) defact[i] = lastred flag := 0 os := make([]int, n*2) n = 0 for p = 0; p <= ntokens; p++ { p1 = temp1[p] if p1 != 0 { if p1 < 0 { p1 = -p1 } else if p1 == ACCEPTCODE { p1 = -1 } else if p1 == ERRCODE { p1 = 0 } else { os[n] = p n++ os[n] = p1 n++ zzacent++ continue } if flag == 0 { fmt.Fprintf(ftable, "\t-1, %v,\n", i) } flag++ fmt.Fprintf(ftable, "\t%v, %v,\n", p, p1) zzexcp++ } } if flag != 0 { defact[i] = -2 fmt.Fprintf(ftable, "\t-2, %v,\n", lastred) } optst[i] = os } // // writes state i // func wrstate(i int) { var j0, j1, u int var pp, qq int if len(errors) > 0 { actions := append([]int(nil), temp1...) defaultAction := ERRCODE if lastred != 0 { defaultAction = -lastred } stateTable[i] = Row{actions, defaultAction} } if foutput == nil { return } fmt.Fprintf(foutput, "\nstate %v\n", i) qq = pstate[i+1] for pp = pstate[i]; pp < qq; pp++ { fmt.Fprintf(foutput, "\t%v\n", writem(statemem[pp].pitem)) } if tystate[i] == MUSTLOOKAHEAD { // print out empty productions in closure for u = pstate[i+1] - pstate[i]; u < cwp; u++ { if wsets[u].pitem.first < 0 { fmt.Fprintf(foutput, "\t%v\n", writem(wsets[u].pitem)) } } } // check for state equal to another for j0 = 0; j0 <= ntokens; j0++ { j1 = temp1[j0] if j1 != 0 { fmt.Fprintf(foutput, "\n\t%v ", symnam(j0)) // shift, error, or accept if j1 > 0 { if j1 == ACCEPTCODE { fmt.Fprintf(foutput, "accept") } else if j1 == ERRCODE { fmt.Fprintf(foutput, "error") } else { fmt.Fprintf(foutput, "shift %v", j1) } } else { fmt.Fprintf(foutput, "reduce %v (src line %v)", -j1, rlines[-j1]) } } } // output the final production if lastred != 0 { fmt.Fprintf(foutput, "\n\t. reduce %v (src line %v)\n\n", lastred, rlines[lastred]) } else { fmt.Fprintf(foutput, "\n\t. error\n\n") } // now, output nonterminal actions j1 = ntokens for j0 = 1; j0 <= nnonter; j0++ { j1++ if temp1[j1] != 0 { fmt.Fprintf(foutput, "\t%v goto %v\n", symnam(j0+NTBASE), temp1[j1]) } } } // // output the gotos for the nontermninals // func go2out() { for i := 1; i <= nnonter; i++ { go2gen(i) // find the best one to make default best := -1 times := 0 // is j the most frequent for j := 0; j < nstate; j++ { if tystate[j] == 0 { continue } if tystate[j] == best { continue } // is tystate[j] the most frequent count := 0 cbest := tystate[j] for k := j; k < nstate; k++ { if tystate[k] == cbest { count++ } } if count > times { best = cbest times = count } } // best is now the default entry zzgobest += times - 1 n := 0 for j := 0; j < nstate; j++ { if tystate[j] != 0 && tystate[j] != best { n++ } } goent := make([]int, 2*n+1) n = 0 for j := 0; j < nstate; j++ { if tystate[j] != 0 && tystate[j] != best { goent[n] = j n++ goent[n] = tystate[j] n++ zzgoent++ } } // now, the default if best == -1 { best = 0 } zzgoent++ goent[n] = best yypgo[i] = goent } } // // output the gotos for nonterminal c // func go2gen(c int) { var i, cc, p, q int // first, find nonterminals with gotos on c aryfil(temp1, nnonter+1, 0) temp1[c] = 1 work := 1 for work != 0 { work = 0 for i = 0; i < nprod; i++ { // cc is a nonterminal with a goto on c cc = prdptr[i][1] - NTBASE if cc >= 0 && temp1[cc] != 0 { // thus, the left side of production i does too cc = prdptr[i][0] - NTBASE if temp1[cc] == 0 { work = 1 temp1[cc] = 1 } } } } // now, we have temp1[c] = 1 if a goto on c in closure of cc if g2debug != 0 && foutput != nil { fmt.Fprintf(foutput, "%v: gotos on ", nontrst[c].name) for i = 0; i <= nnonter; i++ { if temp1[i] != 0 { fmt.Fprintf(foutput, "%v ", nontrst[i].name) } } fmt.Fprintf(foutput, "\n") } // now, go through and put gotos into tystate aryfil(tystate, nstate, 0) for i = 0; i < nstate; i++ { q = pstate[i+1] for p = pstate[i]; p < q; p++ { cc = statemem[p].pitem.first if cc >= NTBASE { // goto on c is possible if temp1[cc-NTBASE] != 0 { tystate[i] = amem[indgo[i]+c] break } } } } } // // in order to free up the mem and amem arrays for the optimizer, // and still be able to output yyr1, etc., after the sizes of // the action array is known, we hide the nonterminals // derived by productions in levprd. // func hideprod() { nred := 0 levprd[0] = 0 for i := 1; i < nprod; i++ { if (levprd[i] & REDFLAG) == 0 { if foutput != nil { fmt.Fprintf(foutput, "Rule not reduced: %v\n", writem(Pitem{prdptr[i], 0, 0, i})) } fmt.Printf("rule %v never reduced\n", writem(Pitem{prdptr[i], 0, 0, i})) nred++ } levprd[i] = prdptr[i][0] - NTBASE } if nred != 0 { fmt.Printf("%v rules never reduced\n", nred) } } func callopt() { var j, k, p, q, i int var v []int pgo = make([]int, nnonter+1) pgo[0] = 0 maxoff = 0 maxspr = 0 for i = 0; i < nstate; i++ { k = 32000 j = 0 v = optst[i] q = len(v) for p = 0; p < q; p += 2 { if v[p] > j { j = v[p] } if v[p] < k { k = v[p] } } // nontrivial situation if k <= j { // j is now the range // j -= k; // call scj if k > maxoff { maxoff = k } } tystate[i] = q + 2*j if j > maxspr { maxspr = j } } // initialize ggreed table ggreed = make([]int, nnonter+1) for i = 1; i <= nnonter; i++ { ggreed[i] = 1 j = 0 // minimum entry index is always 0 v = yypgo[i] q = len(v) - 1 for p = 0; p < q; p += 2 { ggreed[i] += 2 if v[p] > j { j = v[p] } } ggreed[i] = ggreed[i] + 2*j if j > maxoff { maxoff = j } } // now, prepare to put the shift actions into the amem array for i = 0; i < ACTSIZE; i++ { amem[i] = 0 } maxa = 0 for i = 0; i < nstate; i++ { if tystate[i] == 0 && adb > 1 { fmt.Fprintf(ftable, "State %v: null\n", i) } indgo[i] = yyFlag } i = nxti() for i != NOMORE { if i >= 0 { stin(i) } else { gin(-i) } i = nxti() } // print amem array if adb > 2 { for p = 0; p <= maxa; p += 10 { fmt.Fprintf(ftable, "%v ", p) for i = 0; i < 10; i++ { fmt.Fprintf(ftable, "%v ", amem[p+i]) } ftable.WriteRune('\n') } } aoutput() osummary() } // // finds the next i // func nxti() int { max := 0 maxi := 0 for i := 1; i <= nnonter; i++ { if ggreed[i] >= max { max = ggreed[i] maxi = -i } } for i := 0; i < nstate; i++ { if tystate[i] >= max { max = tystate[i] maxi = i } } if max == 0 { return NOMORE } return maxi } func gin(i int) { var s int // enter gotos on nonterminal i into array amem ggreed[i] = 0 q := yypgo[i] nq := len(q) - 1 // now, find amem place for it nextgp: for p := 0; p < ACTSIZE; p++ { if amem[p] != 0 { continue } for r := 0; r < nq; r += 2 { s = p + q[r] + 1 if s > maxa { maxa = s if maxa >= ACTSIZE { errorf("a array overflow") } } if amem[s] != 0 { continue nextgp } } // we have found amem spot amem[p] = q[nq] if p > maxa { maxa = p } for r := 0; r < nq; r += 2 { s = p + q[r] + 1 amem[s] = q[r+1] } pgo[i] = p if adb > 1 { fmt.Fprintf(ftable, "Nonterminal %v, entry at %v\n", i, pgo[i]) } return } errorf("cannot place goto %v\n", i) } func stin(i int) { var s int tystate[i] = 0 // enter state i into the amem array q := optst[i] nq := len(q) nextn: // find an acceptable place for n := -maxoff; n < ACTSIZE; n++ { flag := 0 for r := 0; r < nq; r += 2 { s = q[r] + n if s < 0 || s > ACTSIZE { continue nextn } if amem[s] == 0 { flag++ } else if amem[s] != q[r+1] { continue nextn } } // check the position equals another only if the states are identical for j := 0; j < nstate; j++ { if indgo[j] == n { // we have some disagreement if flag != 0 { continue nextn } if nq == len(optst[j]) { // states are equal indgo[i] = n if adb > 1 { fmt.Fprintf(ftable, "State %v: entry at"+ "%v equals state %v\n", i, n, j) } return } // we have some disagreement continue nextn } } for r := 0; r < nq; r += 2 { s = q[r] + n if s > maxa { maxa = s } if amem[s] != 0 && amem[s] != q[r+1] { errorf("clobber of a array, pos'n %v, by %v", s, q[r+1]) } amem[s] = q[r+1] } indgo[i] = n if adb > 1 { fmt.Fprintf(ftable, "State %v: entry at %v\n", i, indgo[i]) } return } errorf("Error; failure to place state %v", i) } // // this version is for limbo // write out the optimized parser // func aoutput() { ftable.WriteRune('\n') fmt.Fprintf(ftable, "const %sLast = %v\n\n", prefix, maxa+1) arout("Act", amem, maxa+1) arout("Pact", indgo, nstate) arout("Pgo", pgo, nnonter+1) } // // put out other arrays, copy the parsers // func others() { var i, j int arout("R1", levprd, nprod) aryfil(temp1, nprod, 0) // //yyr2 is the number of rules for each production // for i = 1; i < nprod; i++ { temp1[i] = len(prdptr[i]) - 2 } arout("R2", temp1, nprod) aryfil(temp1, nstate, -1000) for i = 0; i <= ntokens; i++ { for j := tstates[i]; j != 0; j = mstates[j] { temp1[j] = i } } for i = 0; i <= nnonter; i++ { for j = ntstates[i]; j != 0; j = mstates[j] { temp1[j] = -i } } arout("Chk", temp1, nstate) arout("Def", defact, nstate) // put out token translation tables // table 1 has 0-256 aryfil(temp1, 256, 0) c := 0 for i = 1; i <= ntokens; i++ { j = tokset[i].value if j >= 0 && j < 256 { if temp1[j] != 0 { fmt.Print("yacc bug -- cannot have 2 different Ts with same value\n") fmt.Printf(" %s and %s\n", tokset[i].name, tokset[temp1[j]].name) nerrors++ } temp1[j] = i if j > c { c = j } } } for i = 0; i <= c; i++ { if temp1[i] == 0 { temp1[i] = YYLEXUNK } } arout("Tok1", temp1, c+1) // table 2 has PRIVATE-PRIVATE+256 aryfil(temp1, 256, 0) c = 0 for i = 1; i <= ntokens; i++ { j = tokset[i].value - PRIVATE if j >= 0 && j < 256 { if temp1[j] != 0 { fmt.Print("yacc bug -- cannot have 2 different Ts with same value\n") fmt.Printf(" %s and %s\n", tokset[i].name, tokset[temp1[j]].name) nerrors++ } temp1[j] = i if j > c { c = j } } } arout("Tok2", temp1, c+1) // table 3 has everything else fmt.Fprintf(ftable, "var %sTok3 = [...]int{\n\t", prefix) c = 0 for i = 1; i <= ntokens; i++ { j = tokset[i].value if j >= 0 && j < 256 { continue } if j >= PRIVATE && j < 256+PRIVATE { continue } if c%5 != 0 { ftable.WriteRune(' ') } fmt.Fprintf(ftable, "%d, %d,", j, i) c++ if c%5 == 0 { fmt.Fprint(ftable, "\n\t") } } if c%5 != 0 { ftable.WriteRune(' ') } fmt.Fprintf(ftable, "%d,\n}\n", 0) // Custom error messages. fmt.Fprintf(ftable, "\n") fmt.Fprintf(ftable, "var %sErrorMessages = [...]struct {\n", prefix) fmt.Fprintf(ftable, "\tstate int\n") fmt.Fprintf(ftable, "\ttoken int\n") fmt.Fprintf(ftable, "\tmsg string\n") fmt.Fprintf(ftable, "}{\n") for _, error := range errors { lineno = error.lineno state, token := runMachine(error.tokens) fmt.Fprintf(ftable, "\t{%v, %v, %s},\n", state, token, error.msg) } fmt.Fprintf(ftable, "}\n") // copy parser text ch := getrune(finput) for ch != EOF { ftable.WriteRune(ch) ch = getrune(finput) } // copy yaccpar if !lflag { fmt.Fprintf(ftable, "\n//line yaccpar:1\n") } parts := strings.SplitN(yaccpar, prefix+"run()", 2) fmt.Fprintf(ftable, "%v", parts[0]) ftable.Write(fcode.Bytes()) fmt.Fprintf(ftable, "%v", parts[1]) } func runMachine(tokens []string) (state, token int) { var stack []int i := 0 token = -1 Loop: if token < 0 { token = chfind(2, tokens[i]) i++ } row := stateTable[state] c := token if token >= NTBASE { c = token - NTBASE + ntokens } action := row.actions[c] if action == 0 { action = row.defaultAction } switch { case action == ACCEPTCODE: errorf("tokens are accepted") return case action == ERRCODE: if token >= NTBASE { errorf("error at non-terminal token %s", symnam(token)) } return case action > 0: // Shift to state action. stack = append(stack, state) state = action token = -1 goto Loop default: // Reduce by production -action. prod := prdptr[-action] if rhsLen := len(prod) - 2; rhsLen > 0 { n := len(stack) - rhsLen state = stack[n] stack = stack[:n] } if token >= 0 { i-- } token = prod[0] goto Loop } } func arout(s string, v []int, n int) { s = prefix + s fmt.Fprintf(ftable, "var %v = [...]int{\n", s) for i := 0; i < n; i++ { if i%10 == 0 { fmt.Fprintf(ftable, "\n\t") } else { ftable.WriteRune(' ') } fmt.Fprintf(ftable, "%d,", v[i]) } fmt.Fprintf(ftable, "\n}\n") } // // output the summary on y.output // func summary() { if foutput != nil { fmt.Fprintf(foutput, "\n%v terminals, %v nonterminals\n", ntokens, nnonter+1) fmt.Fprintf(foutput, "%v grammar rules, %v/%v states\n", nprod, nstate, NSTATES) fmt.Fprintf(foutput, "%v shift/reduce, %v reduce/reduce conflicts reported\n", zzsrconf, zzrrconf) fmt.Fprintf(foutput, "%v working sets used\n", len(wsets)) fmt.Fprintf(foutput, "memory: parser %v/%v\n", memp, ACTSIZE) fmt.Fprintf(foutput, "%v extra closures\n", zzclose-2*nstate) fmt.Fprintf(foutput, "%v shift entries, %v exceptions\n", zzacent, zzexcp) fmt.Fprintf(foutput, "%v goto entries\n", zzgoent) fmt.Fprintf(foutput, "%v entries saved by goto default\n", zzgobest) } if zzsrconf != 0 || zzrrconf != 0 { fmt.Printf("\nconflicts: ") if zzsrconf != 0 { fmt.Printf("%v shift/reduce", zzsrconf) } if zzsrconf != 0 && zzrrconf != 0 { fmt.Printf(", ") } if zzrrconf != 0 { fmt.Printf("%v reduce/reduce", zzrrconf) } fmt.Printf("\n") } } // // write optimizer summary // func osummary() { if foutput == nil { return } i := 0 for p := maxa; p >= 0; p-- { if amem[p] == 0 { i++ } } fmt.Fprintf(foutput, "Optimizer space used: output %v/%v\n", maxa+1, ACTSIZE) fmt.Fprintf(foutput, "%v table entries, %v zero\n", maxa+1, i) fmt.Fprintf(foutput, "maximum spread: %v, maximum offset: %v\n", maxspr, maxoff) } // // copies and protects "'s in q // func chcopy(q string) string { s := "" i := 0 j := 0 for i = 0; i < len(q); i++ { if q[i] == '"' { s += q[j:i] + "\\" j = i } } return s + q[j:i] } func usage() { fmt.Fprintf(stderr, "usage: yacc [-o output] [-v parsetable] input\n") exit(1) } func bitset(set Lkset, bit int) int { return set[bit>>5] & (1 << uint(bit&31)) } func setbit(set Lkset, bit int) { set[bit>>5] |= (1 << uint(bit&31)) } func mkset() Lkset { return make([]int, tbitset) } // // set a to the union of a and b // return 1 if b is not a subset of a, 0 otherwise // func setunion(a, b []int) int { sub := 0 for i := 0; i < tbitset; i++ { x := a[i] y := x | b[i] a[i] = y if y != x { sub = 1 } } return sub } func prlook(p Lkset) { if p == nil { fmt.Fprintf(foutput, "\tNULL") return } fmt.Fprintf(foutput, " { ") for j := 0; j <= ntokens; j++ { if bitset(p, j) != 0 { fmt.Fprintf(foutput, "%v ", symnam(j)) } } fmt.Fprintf(foutput, "}") } // // utility routines // var peekrune rune func isdigit(c rune) bool { return c >= '0' && c <= '9' } func isword(c rune) bool { return c >= 0xa0 || c == '_' || (c >= 'a' && c <= 'z') || (c >= 'A' && c <= 'Z') } // // return 1 if 2 arrays are equal // return 0 if not equal // func aryeq(a []int, b []int) int { n := len(a) if len(b) != n { return 0 } for ll := 0; ll < n; ll++ { if a[ll] != b[ll] { return 0 } } return 1 } func getrune(f *bufio.Reader) rune { var r rune if peekrune != 0 { if peekrune == EOF { return EOF } r = peekrune peekrune = 0 return r } c, n, err := f.ReadRune() if n == 0 { return EOF } if err != nil { errorf("read error: %v", err) } //fmt.Printf("rune = %v n=%v\n", string(c), n); return c } func ungetrune(f *bufio.Reader, c rune) { if f != finput { panic("ungetc - not finput") } if peekrune != 0 { panic("ungetc - 2nd unget") } peekrune = c } func write(f *bufio.Writer, b []byte, n int) int { panic("write") } func open(s string) *bufio.Reader { fi, err := os.Open(s) if err != nil { errorf("error opening %v: %v", s, err) } //fmt.Printf("open %v\n", s); return bufio.NewReader(fi) } func create(s string) *bufio.Writer { fo, err := os.Create(s) if err != nil { errorf("error creating %v: %v", s, err) } //fmt.Printf("create %v mode %v\n", s); return bufio.NewWriter(fo) } // // write out error comment // func lerrorf(lineno int, s string, v ...interface{}) { nerrors++ fmt.Fprintf(stderr, s, v...) fmt.Fprintf(stderr, ": %v:%v\n", infile, lineno) if fatfl != 0 { summary() exit(1) } } func errorf(s string, v ...interface{}) { lerrorf(lineno, s, v...) } func exit(status int) { if ftable != nil { ftable.Flush() ftable = nil gofmt() } if foutput != nil { foutput.Flush() foutput = nil } if stderr != nil { stderr.Flush() stderr = nil } os.Exit(status) } func gofmt() { src, err := ioutil.ReadFile(oflag) if err != nil { return } src, err = format.Source(src) if err != nil { return } ioutil.WriteFile(oflag, src, 0666) } var yaccpar string // will be processed version of yaccpartext: s/$$/prefix/g var yaccpartext = ` /* parser for yacc output */ var ( $$Debug = 0 $$ErrorVerbose = false ) type $$Lexer interface { Lex(lval *$$SymType) int Error(s string) } type $$Parser interface { Parse($$Lexer) int Lookahead() int } type $$ParserImpl struct { lval $$SymType stack [$$InitialStackSize]$$SymType char int } func (p *$$ParserImpl) Lookahead() int { return p.char } func $$NewParser() $$Parser { return &$$ParserImpl{} } const $$Flag = -1000 func $$Tokname(c int) string { if c >= 1 && c-1 < len($$Toknames) { if $$Toknames[c-1] != "" { return $$Toknames[c-1] } } return __yyfmt__.Sprintf("tok-%v", c) } func $$Statname(s int) string { if s >= 0 && s < len($$Statenames) { if $$Statenames[s] != "" { return $$Statenames[s] } } return __yyfmt__.Sprintf("state-%v", s) } func $$ErrorMessage(state, lookAhead int) string { const TOKSTART = 4 if !$$ErrorVerbose { return "syntax error" } for _, e := range $$ErrorMessages { if e.state == state && e.token == lookAhead { return "syntax error: " + e.msg } } res := "syntax error: unexpected " + $$Tokname(lookAhead) // To match Bison, suggest at most four expected tokens. expected := make([]int, 0, 4) // Look for shiftable tokens. base := $$Pact[state] for tok := TOKSTART; tok-1 < len($$Toknames); tok++ { if n := base + tok; n >= 0 && n < $$Last && $$Chk[$$Act[n]] == tok { if len(expected) == cap(expected) { return res } expected = append(expected, tok) } } if $$Def[state] == -2 { i := 0 for $$Exca[i] != -1 || $$Exca[i+1] != state { i += 2 } // Look for tokens that we accept or reduce. for i += 2; $$Exca[i] >= 0; i += 2 { tok := $$Exca[i] if tok < TOKSTART || $$Exca[i+1] == 0 { continue } if len(expected) == cap(expected) { return res } expected = append(expected, tok) } // If the default action is to accept or reduce, give up. if $$Exca[i+1] != 0 { return res } } for i, tok := range expected { if i == 0 { res += ", expecting " } else { res += " or " } res += $$Tokname(tok) } return res } func $$lex1(lex $$Lexer, lval *$$SymType) (char, token int) { token = 0 char = lex.Lex(lval) if char <= 0 { token = $$Tok1[0] goto out } if char < len($$Tok1) { token = $$Tok1[char] goto out } if char >= $$Private { if char < $$Private+len($$Tok2) { token = $$Tok2[char-$$Private] goto out } } for i := 0; i < len($$Tok3); i += 2 { token = $$Tok3[i+0] if token == char { token = $$Tok3[i+1] goto out } } out: if token == 0 { token = $$Tok2[1] /* unknown char */ } if $$Debug >= 3 { __yyfmt__.Printf("lex %s(%d)\n", $$Tokname(token), uint(char)) } return char, token } func $$Parse($$lex $$Lexer) int { return $$NewParser().Parse($$lex) } func ($$rcvr *$$ParserImpl) Parse($$lex $$Lexer) int { var $$n int var $$VAL $$SymType var $$Dollar []$$SymType _ = $$Dollar // silence set and not used $$S := $$rcvr.stack[:] Nerrs := 0 /* number of errors */ Errflag := 0 /* error recovery flag */ $$state := 0 $$rcvr.char = -1 $$token := -1 // $$rcvr.char translated into internal numbering defer func() { // Make sure we report no lookahead when not parsing. $$state = -1 $$rcvr.char = -1 $$token = -1 }() $$p := -1 goto $$stack ret0: return 0 ret1: return 1 $$stack: /* put a state and value onto the stack */ if $$Debug >= 4 { __yyfmt__.Printf("char %v in %v\n", $$Tokname($$token), $$Statname($$state)) } $$p++ if $$p >= len($$S) { nyys := make([]$$SymType, len($$S)*2) copy(nyys, $$S) $$S = nyys } $$S[$$p] = $$VAL $$S[$$p].yys = $$state $$newstate: $$n = $$Pact[$$state] if $$n <= $$Flag { goto $$default /* simple state */ } if $$rcvr.char < 0 { $$rcvr.char, $$token = $$lex1($$lex, &$$rcvr.lval) } $$n += $$token if $$n < 0 || $$n >= $$Last { goto $$default } $$n = $$Act[$$n] if $$Chk[$$n] == $$token { /* valid shift */ $$rcvr.char = -1 $$token = -1 $$VAL = $$rcvr.lval $$state = $$n if Errflag > 0 { Errflag-- } goto $$stack } $$default: /* default state action */ $$n = $$Def[$$state] if $$n == -2 { if $$rcvr.char < 0 { $$rcvr.char, $$token = $$lex1($$lex, &$$rcvr.lval) } /* look through exception table */ xi := 0 for { if $$Exca[xi+0] == -1 && $$Exca[xi+1] == $$state { break } xi += 2 } for xi += 2; ; xi += 2 { $$n = $$Exca[xi+0] if $$n < 0 || $$n == $$token { break } } $$n = $$Exca[xi+1] if $$n < 0 { goto ret0 } } if $$n == 0 { /* error ... attempt to resume parsing */ switch Errflag { case 0: /* brand new error */ $$lex.Error($$ErrorMessage($$state, $$token)) Nerrs++ if $$Debug >= 1 { __yyfmt__.Printf("%s", $$Statname($$state)) __yyfmt__.Printf(" saw %s\n", $$Tokname($$token)) } fallthrough case 1, 2: /* incompletely recovered error ... try again */ Errflag = 3 /* find a state where "error" is a legal shift action */ for $$p >= 0 { $$n = $$Pact[$$S[$$p].yys] + $$ErrCode if $$n >= 0 && $$n < $$Last { $$state = $$Act[$$n] /* simulate a shift of "error" */ if $$Chk[$$state] == $$ErrCode { goto $$stack } } /* the current p has no shift on "error", pop stack */ if $$Debug >= 2 { __yyfmt__.Printf("error recovery pops state %d\n", $$S[$$p].yys) } $$p-- } /* there is no state on the stack with an error shift ... abort */ goto ret1 case 3: /* no shift yet; clobber input char */ if $$Debug >= 2 { __yyfmt__.Printf("error recovery discards %s\n", $$Tokname($$token)) } if $$token == $$EofCode { goto ret1 } $$rcvr.char = -1 $$token = -1 goto $$newstate /* try again in the same state */ } } /* reduction by production $$n */ if $$Debug >= 2 { __yyfmt__.Printf("reduce %v in:\n\t%v\n", $$n, $$Statname($$state)) } $$nt := $$n $$pt := $$p _ = $$pt // guard against "declared and not used" $$p -= $$R2[$$n] // $$p is now the index of $0. Perform the default action. Iff the // reduced production is ε, $1 is possibly out of range. if $$p+1 >= len($$S) { nyys := make([]$$SymType, len($$S)*2) copy(nyys, $$S) $$S = nyys } $$VAL = $$S[$$p+1] /* consult goto table to find next state */ $$n = $$R1[$$n] $$g := $$Pgo[$$n] $$j := $$g + $$S[$$p].yys + 1 if $$j >= $$Last { $$state = $$Act[$$g] } else { $$state = $$Act[$$j] if $$Chk[$$state] != -$$n { $$state = $$Act[$$g] } } // dummy call; replaced with literal code $$run() goto $$stack /* stack new state and value */ } `