gzdoom/tools/re2c/code.cc

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/* $Id: code.cc,v 1.74 2006/05/14 13:38:26 helly Exp $ */
#include <stdlib.h>
#include <string.h>
#include <ctype.h>
#include <iomanip>
#include <iostream>
#include "substr.h"
#include "globals.h"
#include "dfa.h"
#include "parser.h"
#include "code.h"
namespace re2c
{
// there must be at least one span in list; all spans must cover
// same range
std::string indent(uint ind)
{
std::string str;
while (ind-- > 0)
{
str += indString;
}
return str;
}
static std::string space(uint this_label)
{
int nl = next_label > 9999 ? 4 : next_label > 999 ? 3 : next_label > 99 ? 2 : next_label > 9 ? 1 : 0;
int tl = this_label > 9999 ? 4 : this_label > 999 ? 3 : this_label > 99 ? 2 : this_label > 9 ? 1 : 0;
return std::string(std::max(1, nl - tl + 1), ' ');
}
void Go::compact()
{
// arrange so that adjacent spans have different targets
uint i = 0;
for (uint j = 1; j < nSpans; ++j)
{
if (span[j].to != span[i].to)
{
++i;
span[i].to = span[j].to;
}
span[i].ub = span[j].ub;
}
nSpans = i + 1;
}
void Go::unmap(Go *base, const State *x)
{
Span *s = span, *b = base->span, *e = &b[base->nSpans];
uint lb = 0;
s->ub = 0;
s->to = NULL;
for (; b != e; ++b)
{
if (b->to == x)
{
if ((s->ub - lb) > 1)
{
s->ub = b->ub;
}
}
else
{
if (b->to != s->to)
{
if (s->ub)
{
lb = s->ub;
++s;
}
s->to = b->to;
}
s->ub = b->ub;
}
}
s->ub = e[ -1].ub;
++s;
nSpans = s - span;
}
void doGen(const Go *g, const State *s, uint *bm, uint f, uint m)
{
Span *b = g->span, *e = &b[g->nSpans];
uint lb = 0;
for (; b < e; ++b)
{
if (b->to == s)
{
for (; lb < b->ub && lb < 256; ++lb)
{
bm[lb-f] |= m;
}
}
lb = b->ub;
}
}
void prt(std::ostream& o, const Go *g, const State *s)
{
Span *b = g->span, *e = &b[g->nSpans];
uint lb = 0;
for (; b < e; ++b)
{
if (b->to == s)
{
printSpan(o, lb, b->ub);
}
lb = b->ub;
}
}
bool matches(const Go *g1, const State *s1, const Go *g2, const State *s2)
{
Span *b1 = g1->span, *e1 = &b1[g1->nSpans];
uint lb1 = 0;
Span *b2 = g2->span, *e2 = &b2[g2->nSpans];
uint lb2 = 0;
for (;;)
{
for (; b1 < e1 && b1->to != s1; ++b1)
{
lb1 = b1->ub;
}
for (; b2 < e2 && b2->to != s2; ++b2)
{
lb2 = b2->ub;
}
if (b1 == e1)
{
return b2 == e2;
}
if (b2 == e2)
{
return false;
}
if (lb1 != lb2 || b1->ub != b2->ub)
{
return false;
}
++b1;
++b2;
}
}
BitMap *BitMap::first = NULL;
BitMap::BitMap(const Go *g, const State *x)
: go(g)
, on(x)
, next(first)
, i(0)
, m(0)
{
first = this;
}
BitMap::~BitMap()
{
if (next)
{
delete next;
}
}
const BitMap *BitMap::find(const Go *g, const State *x)
{
for (const BitMap *b = first; b; b = b->next)
{
if (matches(b->go, b->on, g, x))
{
return b;
}
}
return new BitMap(g, x);
}
const BitMap *BitMap::find(const State *x)
{
for (const BitMap *b = first; b; b = b->next)
{
if (b->on == x)
{
return b;
}
}
return NULL;
}
void BitMap::gen(std::ostream &o, uint ind, uint lb, uint ub)
{
BitMap *b = first;
if (b && bLastPass)
{
o << indent(ind) << "static unsigned char yybm[] = {";
uint c = 1, n = ub - lb;
while((b = const_cast<BitMap*>(b->next)) != NULL) {
++c;
}
b = first;
uint *bm = new uint[n];
for (uint i = 0, t = 1; b; i += n, t += 8)
{
memset(bm, 0, n * sizeof(uint));
for (uint m = 0x80; b && m; m >>= 1)
{
b->i = i;
b->m = m;
doGen(b->go, b->on, bm, lb, m);
b = const_cast<BitMap*>(b->next);
}
if (c > 8)
{
o << "\n" << indent(ind+1) << "/* table " << t << " .. " << std::min(c, t+7) << ": " << i << " */";
}
for (uint j = 0; j < n; ++j)
{
if (j % 8 == 0)
{
o << "\n" << indent(ind+1);
}
if (yybmHexTable)
{
prtHex(o, bm[j], false);
}
else
{
o << std::setw(3) << (uint)bm[j];
}
o << ", ";
}
}
o << "\n" << indent(ind) << "};\n";
/* stats(); */
delete[] bm;
}
}
void BitMap::stats()
{
uint n = 0;
for (const BitMap *b = first; b; b = b->next)
{
prt(std::cerr, b->go, b->on);
std::cerr << std::endl;
++n;
}
std::cerr << n << " bitmaps\n";
first = NULL;
}
void genGoTo(std::ostream &o, uint ind, const State *from, const State *to, bool & readCh)
{
if (readCh && from->label + 1 != to->label)
{
o << indent(ind) << "yych = *YYCURSOR;\n";
readCh = false;
}
o << indent(ind) << "goto yy" << to->label << ";\n";
vUsedLabels.insert(to->label);
}
void genIf(std::ostream &o, uint ind, const char *cmp, uint v, bool &readCh)
{
if (readCh)
{
o << indent(ind) << "if((yych = *YYCURSOR) ";
readCh = false;
}
else
{
o << indent(ind) << "if(yych ";
}
o << cmp << " ";
prtChOrHex(o, v);
o << ") ";
}
static void need(std::ostream &o, uint ind, uint n, bool & readCh, bool bSetMarker)
{
uint fillIndex = next_fill_index;
if (fFlag)
{
next_fill_index++;
o << indent(ind) << "YYSETSTATE(" << fillIndex << ");\n";
}
if (bUseYYFill)
{
if (n == 1)
{
o << indent(ind) << "if(YYLIMIT == YYCURSOR) YYFILL(1);\n";
}
else
{
o << indent(ind) << "if((YYLIMIT - YYCURSOR) < " << n << ") YYFILL(" << n << ");\n";
}
}
if (fFlag)
{
o << "yyFillLabel" << fillIndex << ":\n";
}
if (bSetMarker)
{
o << indent(ind) << "yych = *(YYMARKER = YYCURSOR);\n";
}
else
{
o << indent(ind) << "yych = *YYCURSOR;\n";
}
readCh = false;
}
void Match::emit(std::ostream &o, uint ind, bool &readCh) const
{
if (state->link)
{
o << indent(ind) << "++YYCURSOR;\n";
}
else if (!readAhead())
{
/* do not read next char if match */
o << indent(ind) << "++YYCURSOR;\n";
readCh = true;
}
else
{
o << indent(ind) << "yych = *++YYCURSOR;\n";
readCh = false;
}
if (state->link)
{
need(o, ind, state->depth, readCh, false);
}
}
void Enter::emit(std::ostream &o, uint ind, bool &readCh) const
{
if (state->link)
{
o << indent(ind) << "++YYCURSOR;\n";
if (vUsedLabels.count(label))
{
o << "yy" << label << ":\n";
}
need(o, ind, state->depth, readCh, false);
}
else
{
/* we shouldn't need 'rule-following' protection here */
o << indent(ind) << "yych = *++YYCURSOR;\n";
if (vUsedLabels.count(label))
{
o << "yy" << label << ":\n";
}
readCh = false;
}
}
void Initial::emit(std::ostream &o, uint ind, bool &readCh) const
{
if (!startLabelName.empty())
{
o << startLabelName << ":\n";
}
if (vUsedLabels.count(1))
{
if (state->link)
{
o << indent(ind) << "++YYCURSOR;\n";
}
else
{
o << indent(ind) << "yych = *++YYCURSOR;\n";
}
}
if (vUsedLabels.count(label))
{
o << "yy" << label << ":\n";
}
else if (!label)
{
o << "\n";
}
if (dFlag)
{
o << indent(ind) << "YYDEBUG(" << label << ", *YYCURSOR);\n";
}
if (state->link)
{
need(o, ind, state->depth, readCh, setMarker && bUsedYYMarker);
}
else
{
if (setMarker && bUsedYYMarker)
{
o << indent(ind) << "YYMARKER = YYCURSOR;\n";
}
readCh = false;
}
}
void Save::emit(std::ostream &o, uint ind, bool &readCh) const
{
if (bUsedYYAccept)
{
o << indent(ind) << "yyaccept = " << selector << ";\n";
}
if (state->link)
{
if (bUsedYYMarker)
{
o << indent(ind) << "YYMARKER = ++YYCURSOR;\n";
}
need(o, ind, state->depth, readCh, false);
}
else
{
if (bUsedYYMarker)
{
o << indent(ind) << "yych = *(YYMARKER = ++YYCURSOR);\n";
}
else
{
o << indent(ind) << "yych = *++YYCURSOR;\n";
}
readCh = false;
}
}
Move::Move(State *s) : Action(s)
{
;
}
void Move::emit(std::ostream &, uint, bool &) const
{
;
}
Accept::Accept(State *x, uint n, uint *s, State **r)
: Action(x), nRules(n), saves(s), rules(r)
{
;
}
void Accept::genRuleMap()
{
for (uint i = 0; i < nRules; ++i)
{
if (saves[i] != ~0u)
{
mapRules[saves[i]] = rules[i];
}
}
}
void Accept::emitBinary(std::ostream &o, uint ind, uint l, uint r, bool &readCh) const
{
if (l < r)
{
uint m = (l + r) >> 1;
o << indent(ind) << "if(yyaccept <= " << m << ") {\n";
emitBinary(o, ++ind, l, m, readCh);
o << indent(--ind) << "} else {\n";
emitBinary(o, ++ind, m + 1, r, readCh);
o << indent(--ind) << "}\n";
}
else
{
genGoTo(o, ind, state, mapRules.find(l)->second, readCh);
}
}
void Accept::emit(std::ostream &o, uint ind, bool &readCh) const
{
if (mapRules.size() > 0)
{
bUsedYYMarker = true;
o << indent(ind) << "YYCURSOR = YYMARKER;\n";
if (readCh) // shouldn't be necessary, but might become at some point
{
o << indent(ind) << "yych = *YYCURSOR;\n";
readCh = false;
}
if (mapRules.size() > 1)
{
bUsedYYAccept = true;
if (gFlag && mapRules.size() >= cGotoThreshold)
{
o << indent(ind++) << "{\n";
o << indent(ind++) << "static void *yytarget[" << mapRules.size() << "] = {\n";
for (RuleMap::const_iterator it = mapRules.begin(); it != mapRules.end(); ++it)
{
o << indent(ind) << "&&yy" << it->second->label << ",\n";
vUsedLabels.insert(it->second->label);
}
o << indent(--ind) << "};\n";
o << indent(ind) << "goto *yytarget[yyaccept];\n";
o << indent(--ind) << "}\n";
}
else if (sFlag)
{
emitBinary(o, ind, 0, mapRules.size() - 1, readCh);
}
else
{
o << indent(ind) << "switch(yyaccept) {\n";
for (RuleMap::const_iterator it = mapRules.begin(); it != mapRules.end(); ++it)
{
o << indent(ind) << "case " << it->first << ": \t";
genGoTo(o, 0, state, it->second, readCh);
}
o << indent(ind) << "}\n";
}
}
else
{
// no need to write if statement here since there is only case 0.
genGoTo(o, ind, state, mapRules.find(0)->second, readCh);
}
}
}
Rule::Rule(State *s, RuleOp *r) : Action(s), rule(r)
{
;
}
void Rule::emit(std::ostream &o, uint ind, bool &) const
{
uint back = rule->ctx->fixedLength();
if (back != 0u)
{
o << indent(ind) << "YYCURSOR = YYCTXMARKER;\n";
}
RuleLine rl(*rule);
o << file_info(sourceFileInfo, &rl);
o << indent(ind);
o << rule->code->text;
o << "\n";
o << outputFileInfo;
}
void doLinear(std::ostream &o, uint ind, Span *s, uint n, const State *from, const State *next, bool &readCh, uint mask)
{
for (;;)
{
State *bg = s[0].to;
while (n >= 3 && s[2].to == bg && (s[1].ub - s[0].ub) == 1)
{
if (s[1].to == next && n == 3)
{
if (!mask || (s[0].ub > 0x00FF))
{
genIf(o, ind, "!=", s[0].ub, readCh);
genGoTo(o, 0, from, bg, readCh);
}
if (next->label != from->label + 1)
{
genGoTo(o, ind, from, next, readCh);
}
return ;
}
else
{
if (!mask || (s[0].ub > 0x00FF))
{
genIf(o, ind, "==", s[0].ub, readCh);
genGoTo(o, 0, from, s[1].to, readCh);
}
}
n -= 2;
s += 2;
}
if (n == 1)
{
// if(bg != next){
if (s[0].to->label != from->label + 1)
{
genGoTo(o, ind, from, s[0].to, readCh);
}
// }
return ;
}
else if (n == 2 && bg == next)
{
if (!mask || (s[0].ub > 0x00FF))
{
genIf(o, ind, ">=", s[0].ub, readCh);
genGoTo(o, 0, from, s[1].to, readCh);
}
if (next->label != from->label + 1)
{
genGoTo(o, ind, from, next, readCh);
}
return ;
}
else
{
if (!mask || ((s[0].ub - 1) > 0x00FF))
{
genIf(o, ind, "<=", s[0].ub - 1, readCh);
genGoTo(o, 0, from, bg, readCh);
}
n -= 1;
s += 1;
}
}
if (next->label != from->label + 1)
{
genGoTo(o, ind, from, next, readCh);
}
}
void Go::genLinear(std::ostream &o, uint ind, const State *from, const State *next, bool &readCh, uint mask) const
{
doLinear(o, ind, span, nSpans, from, next, readCh, mask);
}
bool genCases(std::ostream &o, uint ind, uint lb, Span *s, bool &newLine, uint mask)
{
bool used = false;
if (!newLine)
{
o << "\n";
}
newLine = true;
if (lb < s->ub)
{
for (;;)
{
if (!mask || lb > 0x00FF)
{
o << indent(ind) << "case ";
prtChOrHex(o, lb);
o << ":";
newLine = false;
used = true;
}
if (++lb == s->ub)
{
break;
}
o << "\n";
newLine = true;
}
}
return used;
}
void Go::genSwitch(std::ostream &o, uint ind, const State *from, const State *next, bool &readCh, uint mask) const
{
bool newLine = true;
if ((mask ? wSpans : nSpans) <= 2)
{
genLinear(o, ind, from, next, readCh, mask);
}
else
{
State *def = span[nSpans - 1].to;
Span **sP = new Span * [nSpans - 1], **r, **s, **t;
t = &sP[0];
for (uint i = 0; i < nSpans; ++i)
{
if (span[i].to != def)
{
*(t++) = &span[i];
}
}
if (dFlag)
{
o << indent(ind) << "YYDEBUG(-1, yych);\n";
}
if (readCh)
{
o << indent(ind) << "switch((yych = *YYCURSOR)) {\n";
readCh = false;
}
else
{
o << indent(ind) << "switch(yych){\n";
}
while (t != &sP[0])
{
bool used = false;
r = s = &sP[0];
if (*s == &span[0])
{
used |= genCases(o, ind, 0, *s, newLine, mask);
}
else
{
used |= genCases(o, ind, (*s)[ -1].ub, *s, newLine, mask);
}
State *to = (*s)->to;
while (++s < t)
{
if ((*s)->to == to)
{
used |= genCases(o, ind, (*s)[ -1].ub, *s, newLine, mask);
}
else
{
*(r++) = *s;
}
}
if (used)
{
genGoTo(o, newLine ? ind+1 : 1, from, to, readCh);
newLine = true;
}
t = r;
}
o << indent(ind) << "default:";
genGoTo(o, 1, from, def, readCh);
o << indent(ind) << "}\n";
delete [] sP;
}
}
void doBinary(std::ostream &o, uint ind, Span *s, uint n, const State *from, const State *next, bool &readCh, uint mask)
{
if (n <= 4)
{
doLinear(o, ind, s, n, from, next, readCh, mask);
}
else
{
uint h = n / 2;
genIf(o, ind, "<=", s[h - 1].ub - 1, readCh);
o << "{\n";
doBinary(o, ind+1, &s[0], h, from, next, readCh, mask);
o << indent(ind) << "} else {\n";
doBinary(o, ind+1, &s[h], n - h, from, next, readCh, mask);
o << indent(ind) << "}\n";
}
}
void Go::genBinary(std::ostream &o, uint ind, const State *from, const State *next, bool &readCh, uint mask) const
{
if (mask)
{
Span * sc = new Span[wSpans];
for (uint i = 0, j = 0; i < nSpans; i++)
{
if (span[i].ub > 0xFF)
{
sc[j++] = span[i];
}
}
doBinary(o, ind, sc, wSpans, from, next, readCh, mask);
delete[] sc;
}
else
{
doBinary(o, ind, span, nSpans, from, next, readCh, mask);
}
}
void Go::genBase(std::ostream &o, uint ind, const State *from, const State *next, bool &readCh, uint mask) const
{
if ((mask ? wSpans : nSpans) == 0)
{
return ;
}
if (!sFlag)
{
genSwitch(o, ind, from, next, readCh, mask);
return ;
}
if ((mask ? wSpans : nSpans) > 8)
{
Span *bot = &span[0], *top = &span[nSpans - 1];
uint util;
if (bot[0].to == top[0].to)
{
util = (top[ -1].ub - bot[0].ub) / (nSpans - 2);
}
else
{
if (bot[0].ub > (top[0].ub - top[ -1].ub))
{
util = (top[0].ub - bot[0].ub) / (nSpans - 1);
}
else
{
util = top[ -1].ub / (nSpans - 1);
}
}
if (util <= 2)
{
genSwitch(o, ind, from, next, readCh, mask);
return ;
}
}
if ((mask ? wSpans : nSpans) > 5)
{
genBinary(o, ind, from, next, readCh, mask);
}
else
{
genLinear(o, ind, from, next, readCh, mask);
}
}
void Go::genCpGoto(std::ostream &o, uint ind, const State *from, const State *next, bool &readCh) const
{
const char * sYych = readCh ? "(yych = *YYCURSOR)" : "yych";
readCh = false;
if (wFlag)
{
o << indent(ind) << "if(" << sYych <<" & 0xFF00) {\n";
genBase(o, ind+1, from, next, readCh, 1);
o << indent(ind++) << "} else {\n";
sYych = "yych";
}
else
{
o << indent(ind++) << "{\n";
}
o << indent(ind++) << "static void *yytarget[256] = {\n";
o << indent(ind);
uint ch = 0;
for (uint i = 0; i < lSpans; ++i)
{
vUsedLabels.insert(span[i].to->label);
for(; ch < span[i].ub; ++ch)
{
o << "&&yy" << span[i].to->label;
if (ch == 255)
{
o << "\n";
i = lSpans;
break;
}
else if (ch % 8 == 7)
{
o << ",\n" << indent(ind);
}
else
{
o << "," << space(span[i].to->label);
}
}
}
o << indent(--ind) << "};\n";
o << indent(ind) << "goto *yytarget[" << sYych << "];\n";
o << indent(--ind) << "}\n";
}
void Go::genGoto(std::ostream &o, uint ind, const State *from, const State *next, bool &readCh)
{
if ((gFlag || wFlag) && wSpans == ~0u)
{
uint nBitmaps = 0;
std::set<uint> vTargets;
wSpans = 0;
lSpans = 1;
dSpans = 0;
for (uint i = 0; i < nSpans; ++i)
{
if (span[i].ub > 0xFF)
{
wSpans++;
}
if (span[i].ub < 0x100 || !wFlag)
{
lSpans++;
State *to = span[i].to;
if (to && to->isBase)
{
const BitMap *b = BitMap::find(to);
const char * sYych;
if (b && matches(b->go, b->on, this, to))
{
nBitmaps++;
}
else
{
dSpans++;
vTargets.insert(to->label);
}
}
else
{
dSpans++;
vTargets.insert(to->label);
}
}
}
lTargets = vTargets.size() >> nBitmaps;
}
if (gFlag && (lTargets >= cGotoThreshold || dSpans >= cGotoThreshold))
{
genCpGoto(o, ind, from, next, readCh);
return;
}
else if (bFlag)
{
for (uint i = 0; i < nSpans; ++i)
{
State *to = span[i].to;
if (to && to->isBase)
{
const BitMap *b = BitMap::find(to);
const char * sYych;
if (b && matches(b->go, b->on, this, to))
{
Go go;
go.span = new Span[nSpans];
go.unmap(this, to);
sYych = readCh ? "(yych = *YYCURSOR)" : "yych";
readCh = false;
if (wFlag)
{
o << indent(ind) << "if(" << sYych << " & 0xFF00) {\n";
sYych = "yych";
genBase(o, ind+1, from, next, readCh, 1);
o << indent(ind) << "} else ";
}
else
{
o << indent(ind);
}
o << "if(yybm[" << b->i << "+" << sYych << "] & ";
if (yybmHexTable)
{
prtHex(o, b->m, false);
}
else
{
o << (uint) b->m;
}
o << ") {\n";
genGoTo(o, ind+1, from, to, readCh);
o << indent(ind) << "}\n";
go.genBase(o, ind, from, next, readCh, 0);
delete [] go.span;
return ;
}
}
}
}
genBase(o, ind, from, next, readCh, 0);
}
void State::emit(std::ostream &o, uint ind, bool &readCh) const
{
if (vUsedLabels.count(label))
{
o << "yy" << label << ":\n";
}
if (dFlag && !action->isInitial())
{
o << indent(ind) << "YYDEBUG(" << label << ", *YYCURSOR);\n";
}
if (isPreCtxt)
{
o << indent(ind) << "YYCTXMARKER = YYCURSOR + 1;\n";
}
action->emit(o, ind, readCh);
}
uint merge(Span *x0, State *fg, State *bg)
{
Span *x = x0, *f = fg->go.span, *b = bg->go.span;
uint nf = fg->go.nSpans, nb = bg->go.nSpans;
State *prev = NULL, *to;
// NB: we assume both spans are for same range
for (;;)
{
if (f->ub == b->ub)
{
to = f->to == b->to ? bg : f->to;
if (to == prev)
{
--x;
}
else
{
x->to = prev = to;
}
x->ub = f->ub;
++x;
++f;
--nf;
++b;
--nb;
if (nf == 0 && nb == 0)
{
return x - x0;
}
}
while (f->ub < b->ub)
{
to = f->to == b->to ? bg : f->to;
if (to == prev)
{
--x;
}
else
{
x->to = prev = to;
}
x->ub = f->ub;
++x;
++f;
--nf;
}
while (b->ub < f->ub)
{
to = b->to == f->to ? bg : f->to;
if (to == prev)
{
--x;
}
else
{
x->to = prev = to;
}
x->ub = b->ub;
++x;
++b;
--nb;
}
}
}
const uint cInfinity = ~0;
class SCC
{
public:
State **top, **stk;
public:
SCC(uint);
~SCC();
void traverse(State*);
#ifdef PEDANTIC
private:
SCC(const SCC& oth)
: top(oth.top)
, stk(oth.stk)
{
}
SCC& operator = (const SCC& oth)
{
new(this) SCC(oth);
return *this;
}
#endif
};
SCC::SCC(uint size)
: top(new State * [size])
, stk(top)
{
}
SCC::~SCC()
{
delete [] stk;
}
void SCC::traverse(State *x)
{
*top = x;
uint k = ++top - stk;
x->depth = k;
for (uint i = 0; i < x->go.nSpans; ++i)
{
State *y = x->go.span[i].to;
if (y)
{
if (y->depth == 0)
{
traverse(y);
}
if (y->depth < x->depth)
{
x->depth = y->depth;
}
}
}
if (x->depth == k)
{
do
{
(*--top)->depth = cInfinity;
(*top)->link = x;
}
while (*top != x);
}
}
static bool state_is_in_non_trivial_SCC(const State* s)
{
// does not link to self
if (s->link != s)
{
return true;
}
// or exists i: (s->go.spans[i].to->link == s)
//
// Note: (s->go.spans[i].to == s) is allowed, corresponds to s
// looping back to itself.
//
for (uint i = 0; i < s->go.nSpans; ++i)
{
const State* t = s->go.span[i].to;
if (t && t->link == s)
{
return true;
}
}
// otherwise no
return false;
}
uint maxDist(State *s)
{
if (s->depth != cInfinity)
{
// Already calculated, just return result.
return s->depth;
}
uint mm = 0;
for (uint i = 0; i < s->go.nSpans; ++i)
{
State *t = s->go.span[i].to;
if (t)
{
uint m = 1;
if (!t->link) // marked as non-key state
{
if (t->depth == cInfinity)
{
t->depth = maxDist(t);
}
m += t->depth;
}
if (m > mm)
{
mm = m;
}
}
}
s->depth = mm;
return mm;
}
void calcDepth(State *head)
{
State* s;
// mark non-key states by s->link = NULL ;
for (s = head; s; s = s->next)
{
if (s != head && !state_is_in_non_trivial_SCC(s))
{
s->link = NULL;
}
//else: key state, leave alone
}
for (s = head; s; s = s->next)
{
s->depth = cInfinity;
}
// calculate max number of transitions before guarantied to reach
// a key state.
for (s = head; s; s = s->next)
{
maxDist(s);
}
}
void DFA::findSCCs()
{
SCC scc(nStates);
State *s;
for (s = head; s; s = s->next)
{
s->depth = 0;
s->link = NULL;
}
for (s = head; s; s = s->next)
{
if (!s->depth)
{
scc.traverse(s);
}
}
calcDepth(head);
}
void DFA::split(State *s)
{
State *move = new State;
(void) new Move(move);
addState(&s->next, move);
move->link = s->link;
move->rule = s->rule;
move->go = s->go;
s->rule = NULL;
s->go.nSpans = 1;
s->go.span = new Span[1];
s->go.span[0].ub = ubChar;
s->go.span[0].to = move;
}
void DFA::findBaseState()
{
Span *span = new Span[ubChar - lbChar];
for (State *s = head; s; s = s->next)
{
if (!s->link)
{
for (uint i = 0; i < s->go.nSpans; ++i)
{
State *to = s->go.span[i].to;
if (to && to->isBase)
{
to = to->go.span[0].to;
uint nSpans = merge(span, s, to);
if (nSpans < s->go.nSpans)
{
delete [] s->go.span;
s->go.nSpans = nSpans;
s->go.span = new Span[nSpans];
memcpy(s->go.span, span, nSpans*sizeof(Span));
}
break;
}
}
}
}
delete [] span;
}
void DFA::emit(std::ostream &o, uint ind)
{
State *s;
uint i, bitmap_brace = 0;
findSCCs();
head->link = head;
uint nRules = 0;
for (s = head; s; s = s->next)
{
s->depth = maxDist(s);
if (maxFill < s->depth)
{
maxFill = s->depth;
}
if (s->rule && s->rule->accept >= nRules)
{
nRules = s->rule->accept + 1;
}
}
uint nSaves = 0;
uint *saves = new uint[nRules];
memset(saves, ~0, (nRules)*sizeof(*saves));
// mark backtracking points
bool bSaveOnHead = false;
for (s = head; s; s = s->next)
{
if (s->rule)
{
for (i = 0; i < s->go.nSpans; ++i)
{
if (s->go.span[i].to && !s->go.span[i].to->rule)
{
delete s->action;
if (saves[s->rule->accept] == ~0u)
{
saves[s->rule->accept] = nSaves++;
}
bSaveOnHead |= s == head;
(void) new Save(s, saves[s->rule->accept]); // sets s->action
}
}
}
}
// insert actions
State **rules = new State * [nRules];
memset(rules, 0, (nRules)*sizeof(*rules));
State *accept = NULL;
Accept *accfixup = NULL;
for (s = head; s; s = s->next)
{
State * ow;
if (!s->rule)
{
ow = accept;
}
else
{
if (!rules[s->rule->accept])
{
State *n = new State;
(void) new Rule(n, s->rule);
rules[s->rule->accept] = n;
addState(&s->next, n);
}
ow = rules[s->rule->accept];
}
for (i = 0; i < s->go.nSpans; ++i)
{
if (!s->go.span[i].to)
{
if (!ow)
{
ow = accept = new State;
accfixup = new Accept(accept, nRules, saves, rules);
addState(&s->next, accept);
}
s->go.span[i].to = ow;
}
}
}
if (accfixup)
{
accfixup->genRuleMap();
}
// split ``base'' states into two parts
for (s = head; s; s = s->next)
{
s->isBase = false;
if (s->link)
{
for (i = 0; i < s->go.nSpans; ++i)
{
if (s->go.span[i].to == s)
{
s->isBase = true;
split(s);
if (bFlag)
{
BitMap::find(&s->next->go, s);
}
s = s->next;
break;
}
}
}
}
// find ``base'' state, if possible
findBaseState();
delete head->action;
if (bFlag)
{
o << indent(ind++) << "{\n";
bitmap_brace = 1;
BitMap::gen(o, ind, lbChar, ubChar <= 256 ? ubChar : 256);
}
bUsedYYAccept = false;
uint start_label = next_label;
(void) new Initial(head, next_label++, bSaveOnHead);
if (bUseStartLabel)
{
if (startLabelName.empty())
{
vUsedLabels.insert(start_label);
}
}
for (s = head; s; s = s->next)
{
s->label = next_label++;
}
// Save 'next_fill_index' and compute information about code generation
// while writing to null device.
uint save_fill_index = next_fill_index;
null_stream null_dev;
for (s = head; s; s = s->next)
{
bool readCh = false;
s->emit(null_dev, ind, readCh);
s->go.genGoto(null_dev, ind, s, s->next, readCh);
}
if (last_fill_index < next_fill_index)
{
last_fill_index = next_fill_index;
}
next_fill_index = save_fill_index;
// Generate prolog
o << "\n" << outputFileInfo;
o << indent(ind++) << "{\n";
if (!fFlag)
{
o << indent(ind) << "YYCTYPE yych;\n";
if (bUsedYYAccept)
{
o << indent(ind) << "unsigned int yyaccept = 0;\n";
}
}
else
{
o << "\n";
}
genGetState(o, ind, start_label);
if (vUsedLabels.count(1))
{
vUsedLabels.insert(0);
o << indent(ind) << "goto yy0;\n";
}
// Generate code
for (s = head; s; s = s->next)
{
bool readCh = false;
s->emit(o, ind, readCh);
s->go.genGoto(o, ind, s, s->next, readCh);
}
// Generate epilog
o << indent(--ind) << "}\n";
if (bitmap_brace)
{
o << indent(--ind) << "}\n";
}
// Cleanup
if (BitMap::first)
{
delete BitMap::first;
BitMap::first = NULL;
}
delete [] saves;
delete [] rules;
bUseStartLabel = false;
}
void genGetState(std::ostream &o, uint& ind, uint start_label)
{
if (fFlag && !bWroteGetState)
{
vUsedLabels.insert(start_label);
o << indent(ind) << "switch(YYGETSTATE())\n";
o << indent(ind) << "{\n";
if (bUseStateAbort)
{
o << indent(ind) << "default: abort();\n";
o << indent(ind) << "case -1: goto yy" << start_label << ";\n";
}
else
{
o << indent(ind) << "default: goto yy" << start_label << ";\n";
}
for (size_t i=0; i<last_fill_index; ++i)
{
o << indent(ind) << "case " << i << ": goto yyFillLabel" << i << ";\n";
}
o << indent(ind) << "}\n";
if (bUseStateNext)
{
o << "yyNext:\n";
}
bWroteGetState = true;
}
}
std::ostream& operator << (std::ostream& o, const file_info& li)
{
if (li.ln && !iFlag)
{
o << "#line " << li.ln->get_line() << " \"" << li.fname << "\"\n";
}
return o;
}
uint Scanner::get_line() const
{
return cline;
}
void Scanner::config(const Str& cfg, int num)
{
if (cfg.to_string() == "indent:top")
{
if (num < 0)
{
fatal("configuration 'indent:top' must be a positive integer");
}
topIndent = num;
}
else if (cfg.to_string() == "yybm:hex")
{
yybmHexTable = num != 0;
}
else if (cfg.to_string() == "startlabel")
{
bUseStartLabel = num != 0;
startLabelName = "";
}
else if (cfg.to_string() == "state:abort")
{
bUseStateAbort = num != 0;
}
else if (cfg.to_string() == "state:nextlabel")
{
bUseStateNext = num != 0;
}
else if (cfg.to_string() == "yyfill:enable")
{
bUseYYFill = num != 0;
}
else if (cfg.to_string() == "cgoto:threshold")
{
cGotoThreshold = num;
}
else
{
fatal("unrecognized configuration name or illegal integer value");
}
}
void Scanner::config(const Str& cfg, const Str& val)
{
if (cfg.to_string() == "indent:string")
{
if (val.len >= 2 && val.str[0] == val.str[val.len-1]
&& (val.str[0] == '"' || val.str[0] == '\''))
{
SubStr tmp(val.str + 1, val.len - 2);
unescape(tmp, indString);
}
else
{
indString = val.to_string();
}
return;
}
else if (cfg.to_string() == "startlabel")
{
if (val.len >= 2 && val.str[0] == val.str[val.len-1]
&& (val.str[0] == '"' || val.str[0] == '\''))
{
SubStr tmp(val.str + 1, val.len - 2);
unescape(tmp, startLabelName);
}
else
{
startLabelName = val.to_string();
}
bUseStartLabel = !startLabelName.empty();
}
else
{
fatal("unrecognized configuration name or illegal string value");
}
}
} // end namespace re2c