/* Kickstart is a coarse-grained "filter" engine that finds likely matches to be verified by full-blown matcher. */ module std.regex.internal.shiftor; package(std.regex): import std.regex.internal.ir; import std.range.primitives, std.utf; //utility for shiftOr, returns a minimum number of bytes to test in a Char uint effectiveSize(Char)() { static if (is(Char == char)) return 1; else static if (is(Char == wchar)) return 2; else static if (is(Char == dchar)) return 3; else static assert(0); } /* Kickstart engine using ShiftOr algorithm, a bit parallel technique for inexact string searching. */ class ShiftOr(Char) : Kickstart!Char { private: uint[] table; uint fChar; uint n_length; enum charSize = effectiveSize!Char(); //maximum number of chars in CodepointSet to process enum uint charsetThreshold = 32_000; static struct ShiftThread { uint[] tab; uint mask; uint idx; uint pc, counter, hops; this(uint newPc, uint newCounter, uint[] table) { pc = newPc; counter = newCounter; mask = 1; idx = 0; hops = 0; tab = table; } void setMask(uint idx, uint mask) { tab[idx] |= mask; } void setInvMask(uint idx, uint mask) { tab[idx] &= ~mask; } void set(alias setBits = setInvMask)(dchar ch) { static if (charSize == 3) { uint val = ch, tmask = mask; setBits(val&0xFF, tmask); tmask <<= 1; val >>= 8; setBits(val&0xFF, tmask); tmask <<= 1; val >>= 8; assert(val <= 0x10); setBits(val, tmask); tmask <<= 1; } else { Char[dchar.sizeof/Char.sizeof] buf; uint tmask = mask; size_t total = encode(buf, ch); for (size_t i = 0; i < total; i++, tmask<<=1) { static if (charSize == 1) setBits(buf[i], tmask); else static if (charSize == 2) { setBits(buf[i]&0xFF, tmask); tmask <<= 1; setBits(buf[i]>>8, tmask); } } } } void add(dchar ch){ return set!setInvMask(ch); } void advance(uint s) { mask <<= s; idx += s; } @property bool full(){ return !mask; } } static ShiftThread fork(ShiftThread t, uint newPc, uint newCounter) { ShiftThread nt = t; nt.pc = newPc; nt.counter = newCounter; return nt; } @trusted static ShiftThread fetch(ref ShiftThread[] worklist) { auto t = worklist[$-1]; worklist.length -= 1; if (!__ctfe) cast(void)worklist.assumeSafeAppend(); return t; } static uint charLen(uint ch) { assert(ch <= 0x10FFFF); return codeLength!Char(cast(dchar)ch)*charSize; } public: @trusted this(ref Regex!Char re) { static import std.algorithm.comparison; import std.algorithm.searching : countUntil; import std.conv : text; import std.range : assumeSorted; uint[] memory = new uint[256]; fChar = uint.max; // FNV-1a flavored hash (uses 32bits at a time) ulong hash(uint[] tab) { ulong h = 0xcbf29ce484222325; foreach (v; tab) { h ^= v; h *= 0x100000001b3; } return h; } L_FindChar: for (size_t i = 0;;) { switch (re.ir[i].code) { case IR.Char: fChar = re.ir[i].data; static if (charSize != 3) { Char[dchar.sizeof/Char.sizeof] buf; encode(buf, fChar); fChar = buf[0]; } fChar = fChar & 0xFF; break L_FindChar; case IR.GroupStart, IR.GroupEnd: i += IRL!(IR.GroupStart); break; case IR.Bof, IR.Bol, IR.Wordboundary, IR.Notwordboundary: i += IRL!(IR.Bol); break; default: break L_FindChar; } } table = memory; table[] = uint.max; alias MergeTab = bool[ulong]; // use reasonably complex hash to identify equivalent tables auto merge = new MergeTab[re.hotspotTableSize]; ShiftThread[] trs; ShiftThread t = ShiftThread(0, 0, table); //locate first fixed char if any n_length = 32; for (;;) { L_Eval_Thread: for (;;) { switch (re.ir[t.pc].code) { case IR.Char: uint s = charLen(re.ir[t.pc].data); if (t.idx+s > n_length) goto L_StopThread; t.add(re.ir[t.pc].data); t.advance(s); t.pc += IRL!(IR.Char); break; case IR.OrChar://assumes IRL!(OrChar) == 1 uint len = re.ir[t.pc].sequence; uint end = t.pc + len; uint[Bytecode.maxSequence] s; uint numS; for (uint i = 0; i < len; i++) { auto x = charLen(re.ir[t.pc+i].data); if (countUntil(s[0..numS], x) < 0) s[numS++] = x; } for (uint i = t.pc; i < end; i++) { t.add(re.ir[i].data); } for (uint i = 0; i < numS; i++) { auto tx = fork(t, t.pc + len, t.counter); if (tx.idx + s[i] <= n_length) { tx.advance(s[i]); trs ~= tx; } } if (!trs.empty) t = fetch(trs); else goto L_StopThread; break; case IR.CodepointSet: case IR.Trie: auto set = re.charsets[re.ir[t.pc].data]; uint[4] s; uint numS; static if (charSize == 3) { s[0] = charSize; numS = 1; } else { static if (charSize == 1) static immutable codeBounds = [0x0, 0x7F, 0x80, 0x7FF, 0x800, 0xFFFF, 0x10000, 0x10FFFF]; else //== 2 static immutable codeBounds = [0x0, 0xFFFF, 0x10000, 0x10FFFF]; uint[] arr = new uint[set.byInterval.length * 2]; size_t ofs = 0; foreach (ival; set.byInterval) { arr[ofs++] = ival.a; arr[ofs++] = ival.b; } auto srange = assumeSorted!"a <= b"(arr); for (uint i = 0; i < codeBounds.length/2; i++) { auto start = srange.lowerBound(codeBounds[2*i]).length; auto end = srange.lowerBound(codeBounds[2*i+1]).length; if (end > start || (end == start && (end & 1))) s[numS++] = (i+1)*charSize; } } if (numS == 0 || t.idx + s[numS-1] > n_length) goto L_StopThread; auto chars = set.length; if (chars > charsetThreshold) goto L_StopThread; foreach (ch; set.byCodepoint) { //avoid surrogate pairs if (0xD800 <= ch && ch <= 0xDFFF) continue; t.add(ch); } for (uint i = 0; i < numS; i++) { auto tx = fork(t, t.pc + IRL!(IR.CodepointSet), t.counter); tx.advance(s[i]); trs ~= tx; } if (!trs.empty) t = fetch(trs); else goto L_StopThread; break; case IR.Any: goto L_StopThread; case IR.GotoEndOr: t.pc += IRL!(IR.GotoEndOr)+re.ir[t.pc].data; assert(re.ir[t.pc].code == IR.OrEnd); goto case; case IR.OrEnd: auto slot = re.ir[t.pc+1].raw+t.counter; auto val = hash(t.tab); if (val in merge[slot]) goto L_StopThread; // merge equivalent merge[slot][val] = true; t.pc += IRL!(IR.OrEnd); break; case IR.OrStart: t.pc += IRL!(IR.OrStart); goto case; case IR.Option: uint next = t.pc + re.ir[t.pc].data + IRL!(IR.Option); //queue next Option if (re.ir[next].code == IR.Option) { trs ~= fork(t, next, t.counter); } t.pc += IRL!(IR.Option); break; case IR.RepeatStart:case IR.RepeatQStart: t.pc += IRL!(IR.RepeatStart)+re.ir[t.pc].data; goto case IR.RepeatEnd; case IR.RepeatEnd: case IR.RepeatQEnd: auto slot = re.ir[t.pc+1].raw+t.counter; auto val = hash(t.tab); if (val in merge[slot]) goto L_StopThread; // merge equivalent merge[slot][val] = true; uint len = re.ir[t.pc].data; uint step = re.ir[t.pc+2].raw; uint min = re.ir[t.pc+3].raw; if (t.counter < min) { t.counter += step; t.pc -= len; break; } uint max = re.ir[t.pc+4].raw; if (t.counter < max) { trs ~= fork(t, t.pc - len, t.counter + step); t.counter = t.counter%step; t.pc += IRL!(IR.RepeatEnd); } else { t.counter = t.counter%step; t.pc += IRL!(IR.RepeatEnd); } break; case IR.GroupStart, IR.GroupEnd: t.pc += IRL!(IR.GroupStart); break; case IR.Bof, IR.Bol, IR.Wordboundary, IR.Notwordboundary: t.pc += IRL!(IR.Bol); break; case IR.LookaheadStart, IR.NeglookaheadStart, IR.LookbehindStart, IR.NeglookbehindStart: t.pc += IRL!(IR.LookaheadStart) + IRL!(IR.LookaheadEnd) + re.ir[t.pc].data; break; default: L_StopThread: assert(re.ir[t.pc].code >= 0x80, text(re.ir[t.pc].code)); debug (fred_search) writeln("ShiftOr stumbled on ",re.ir[t.pc].mnemonic); n_length = std.algorithm.comparison.min(t.idx, n_length); break L_Eval_Thread; } } if (trs.empty) break; t = fetch(trs); } debug(std_regex_search) { writeln("Min length: ", n_length); } } final @property bool empty() const { return n_length < 3 && fChar == uint.max; } final @property uint length() const{ return n_length/charSize; } // lookup compatible bit pattern in haystack, return starting index // has a useful trait: if supplied with valid UTF indexes, // returns only valid UTF indexes // (that given the haystack in question is valid UTF string) final @trusted bool search(ref Input!Char s) {//@BUG: apparently assumes little endian machines import std.conv : text; import core.stdc.string : memchr; assert(!empty); auto haystack = s._origin; uint state = uint.max; uint limit = 1u<<(n_length - 1u); auto p = cast(const(ubyte)*)(haystack.ptr+s._index); debug(std_regex_search) writefln("Limit: %32b",limit); if (fChar != uint.max) { const(ubyte)* end = cast(ubyte*)(haystack.ptr + haystack.length); const orginalAlign = cast(size_t)p & (Char.sizeof-1); while (p != end) { if (!~state) {//speed up seeking first matching place for (;;) { assert(p <= end, text(p," vs ", end)); p = cast(ubyte*)memchr(p, fChar, end - p); if (!p) { s._index = haystack.length; return false; } if ((cast(size_t)p & (Char.sizeof-1)) == orginalAlign) break; if (++p == end) { s._index = haystack.length; return false; } } state = ~1u; assert((cast(size_t)p & (Char.sizeof-1)) == orginalAlign); static if (charSize == 3) { state = (state<<1) | table[p[1]]; state = (state<<1) | table[p[2]]; p += 4; } else p++; //first char is tested, see if that's all if (!(state & limit)) { s._index = (p-cast(ubyte*)haystack.ptr)/Char.sizeof-length; return true; } } else {//have some bits/states for possible matches, //use the usual shift-or cycle static if (charSize == 3) { state = (state<<1) | table[p[0]]; state = (state<<1) | table[p[1]]; state = (state<<1) | table[p[2]]; p += 4; } else { state = (state<<1) | table[p[0]]; p++; } if (!(state & limit)) { s._index = (p-cast(ubyte*)haystack.ptr)/Char.sizeof-length; return true; } } debug(std_regex_search) writefln("State: %32b", state); } } else { //normal path, partially unrolled for char/wchar static if (charSize == 3) { const(ubyte)* end = cast(ubyte*)(haystack.ptr + haystack.length); while (p != end) { state = (state<<1) | table[p[0]]; state = (state<<1) | table[p[1]]; state = (state<<1) | table[p[2]]; p += 4; if (!(state & limit))//division rounds down for dchar { s._index = (p-cast(ubyte*)haystack.ptr)/Char.sizeof-length; return true; } } } else { auto len = cast(ubyte*)(haystack.ptr + haystack.length) - p; size_t i = 0; if (len & 1) { state = (state<<1) | table[p[i++]]; if (!(state & limit)) { s._index += i/Char.sizeof-length; return true; } } while (i < len) { state = (state<<1) | table[p[i++]]; if (!(state & limit)) { s._index += i/Char.sizeof-length; return true; } state = (state<<1) | table[p[i++]]; if (!(state & limit)) { s._index += i/Char.sizeof-length; return true; } debug(std_regex_search) writefln("State: %32b", state); } } } s._index = haystack.length; return false; } final @trusted bool match(ref Input!Char s) { //TODO: stub return false; } @system debug static void dump(uint[] table) {//@@@BUG@@@ writef(ln) is @system import std.stdio : writefln; for (size_t i = 0; i < table.length; i += 4) { writefln("%32b %32b %32b %32b",table[i], table[i+1], table[i+2], table[i+3]); } } } unittest { import std.conv, std.regex; auto shiftOrLength(C)(const(C)[] pat, uint length) { auto r = regex(pat); auto kick = new ShiftOr!C(r); assert(kick.length == length, text(C.stringof, " == ", kick.length)); return kick; } auto searches(C)(const (C)[] source, ShiftOr!C kick, uint[] results...) { auto inp = Input!C(source); foreach(r; results) { kick.search(inp); dchar ch; size_t idx; assert(inp._index == r, text(inp._index, " vs ", r)); inp.nextChar(ch, idx); } } foreach(i, Char; AliasSeq!(char, wchar, dchar)) { alias String = immutable(Char)[]; shiftOrLength(`abc`.to!String, 3); shiftOrLength(`abc$`.to!String, 3); shiftOrLength(`(abc){2}a+`.to!String, 7); shiftOrLength(`\b(a{2}b{3}){2,4}`.to!String, 10); shiftOrLength(`\ba{2}c\bxyz`.to!String, 6); auto kick = shiftOrLength(`\ba{2}c\b`.to!String, 3); auto inp = Input!Char("aabaacaa"); assert(kick.search(inp)); assert(inp._index == 3, text(Char.stringof," == ", kick.length)); dchar ch; size_t idx; inp.nextChar(ch, idx); assert(!kick.search(inp)); assert(inp._index == 8, text(Char.stringof," == ", kick.length)); } foreach(i, Char; AliasSeq!(char, wchar, dchar)) { alias String = immutable(Char)[]; auto kick = shiftOrLength(`abc[a-z]`.to!String, 4); searches("abbabca".to!String, kick, 3); kick = shiftOrLength(`(ax|bd|cdy)`.to!String, 2); searches("abdcdyabax".to!String, kick, 1, 3, 8); shiftOrLength(`...`.to!String, 0); kick = shiftOrLength(`a(b{1,2}|c{1,2})x`.to!String, 3); searches("ababx".to!String, kick, 2); searches("abaacba".to!String, kick, 3); //expected inexact } }