ref: 0f956d6bb55e0455326f4627024c1fa8c8adbff8
dir: /lib/regex/interp.myr/
use std use "types" pkg regex = /* regex execution */ const exec : (re : regex#, str : byte[:] -> std.option(byte[:][:])) const search : (re : regex#, str : byte[:] -> std.option(byte[:][:])) /* regex execution returning indexes */ const iexec : (re : regex#, str : byte[:] -> std.option((std.size, std.size)[:])) const isearch : (re : regex#, str : byte[:] -> std.option((std.size, std.size)[:])) /* substitution */ const sub : (re : regex#, str : byte[:], subst : byte[:][:] -> std.option(byte[:])) const sbsub : (sb : std.strbuf#, re : regex#, str : byte[:], subst : byte[:][:] -> bool) const suball : (re : regex#, str : byte[:], subst : byte[:][:] -> byte[:]) const sbsuball : (sb : std.strbuf#, re : regex#, str : byte[:], subst : byte[:][:] -> void) const matchfree : (pat : byte[:][:] -> void) ;; /* Ugly: for performance. std.option() should be used instead when unions get faster. */ const Zthr = (0 : rethread#) const Maxfree = 128 const matchfree = {m std.slfree(m) } const exec = {re, str -> getmatches(re, run(re, str, 0, true)) } const iexec = {re, str -> getidxmatches(re, run(re, str, 0, true)) } const search = {re, str var thr = Zthr for var i = 0; i < str.len; i++ thr = run(re, str[i:], 0, false) if thr != Zthr break ;; ;; -> getmatches(re, thr) } const isearch = {re, str var thr = Zthr for var i = 0; i < str.len; i++ thr = run(re, str[i:], 0, false) if thr != Zthr break ;; ;; -> getidxmatches(re, thr) } const sub = {re, str, subst var sb sb = std.mksb() if sbsub(sb, re, str, subst) -> `std.Some std.sbfin(sb) ;; -> `std.None } const sbsub = {sb, re, str, subst std.assert(re.nmatch == subst.len + 1, "substitution length does not match capture count") -> dosubst(sb, re, run(re, str, 0, true), str, subst) } const suball = {re, str, subst var sb sb = std.mksb() sbsuball(sb, re, str, subst) -> std.sbfin(sb) } const sbsuball = {sb, re, str, subst var thr, len, i std.assert(re.nmatch == subst.len + 1, "substitution length does not match capture count") i = 0 while i < str.len thr = run(re, str[i:], 0, false) if thr == Zthr std.sbputb(sb, str[i]) i++ else len = thr.mgroup[0][1] dosubst(sb, re, thr, str[i:len + i], subst) i += len ;; cleanup(re, thr) ;; } const dosubst = {sb, re, thr, str, subst var off if thr == Zthr -> false ;; off = 0 for var i = 1; i < re.nmatch; i++ if thr.mgroup[i][0] != -1 && thr.mgroup[i][1] != -1 std.sbputs(sb, str[off:thr.mgroup[i][0]]) std.sbputs(sb, subst[i - 1]) off = thr.mgroup[i][1] ;; ;; std.sbputs(sb, str[off:]) -> true } const cleanup = {re, result lfree(re.runq) lfree(re.expired) lfree(re.free) std.free(result) re.runq = Zthr re.expired = Zthr re.free = Zthr re.nfree = 0 re.nthr = 0 } const lfree = {thr for var next = thr; thr != Zthr; thr = next next = thr.next std.free(thr) ;; } const getmatches = {re, thr var ret, i if thr == Zthr -> `std.None ;; i = 0 ret = std.slalloc(re.nmatch) for [lo, hi] : thr.mgroup[:re.nmatch] if lo != -1 && hi != -1 ret[i] = re.str[lo : hi] ;; i++ ;; cleanup(re, thr) -> `std.Some ret } const getidxmatches = {re, thr var ret if thr == Zthr -> `std.None ;; ret = std.slalloc(re.nmatch) for var i = 0; i < re.nmatch; i++ ret[i] = (thr.mgroup[i][0], thr.mgroup[i][1]) ;; cleanup(re, thr) -> `std.Some ret } /* * Run manages the virtual machine state, and schedules the * regex threads. Each linear match runs in its own thread. * When a new thread is created, it is carefully scheduled * after the current thread, to ensure that match order is * preserved. */ const run = {re, str, idx, wholestr var bestmatch var consumed var states var thr var ip re.str = str re.strp = 0 re.nexttid = 0 bestmatch = Zthr states = std.mkbs() re.runq = mkthread(re, 0) if re.debug /* If we're in debug mode, then we keep the traces around, so we can show them to the user. To avoid leaking, we need to free the traces from the last run when we start a new one. */ for bs : re.traces std.bsfree(bs) ;; std.slfree(re.traces) re.traces = [][:] std.slpush(&re.traces, std.mkbs()) ;; for var i = 0; i < re.nmatch; i++ re.runq.mgroup[i][0] = -1 re.runq.mgroup[i][1] = -1 ;; while re.nthr > 0 while re.runq != Zthr if re.trace std.put("switch\n") ;; thr = re.runq re.runq = thr.next ip = thr.ip /* Stepping continues until the first non-consuming operator is seen. This keeps all the threads in lockstep, which means that when a match is encountered, we know all the other threads have seen what they need to, and we can terminate them. */ consumed = step(re, thr, -1) while !consumed consumed = step(re, thr, ip) ;; /* * Because threads have no memory, * their ip (and current input * character, which is the same * thanks to the above mentioned * lockstep) uniquely identify them. * As a result, if we have two * threads with the same ip, one of * them can be culled. */ if std.bshas(states, thr.ip) die(re, thr) ;; if thr.dead thrfree(re, thr) elif thr.matched if bestmatch != Zthr thrfree(re, bestmatch) ;; if re.strp == re.str.len bestmatch = thr goto done elif !wholestr bestmatch = thr else thrfree(re, thr) ;; elif !thr.matched std.bsput(states, thr.ip) if re.expired == Zthr re.expired = thr ;; if re.expiredtail != Zthr re.expiredtail.next = thr ;; re.expiredtail = thr thr.next = Zthr ;; ;; std.bsclear(states) re.runq = re.expired re.expired = Zthr re.expiredtail = Zthr re.strp++ ;; :done std.bsfree(states) -> bestmatch } /* * Step executes a single step of the compiled regex. * * Operations fall into two overall categories. Consuming * operators advance the match, and nonconsuming operators * change the state of the regex virtual machine. * * Consuming operators are simple: They check if the current * character matches a criteria, and then advance the regex. * * Nonconsuming operators can do one of several things. They * can fork the vm, record a successful match, or mark a * thread as a failure. * * A thread continues to run forward until a consuming * opcode is encountered, after which it must switch. * This is in order to keep all threads in lockstep * operating over the same characters, and finishing * at the same time. */ const step = {re, thr, curip var str, nthr, inst str = re.str inst = re.code[thr.ip] if re.trace itrace(re, thr, re.prog[thr.ip]) ;; if re.debug std.bsput(re.traces[thr.tid], thr.ip) ;; match inst & 0xf /* Consuming opcodes */ | OpRange: var lo = (inst >> 4 : byte) var hi = (inst >> 16 : byte) if !within(re, str) || lo > str[re.strp] || hi < str[re.strp] die(re, thr) else thr.ip++ ;; | OpByte: var b = (inst >> 4 : byte) if !within(re, str) die(re, thr) elif b != str[re.strp] die(re, thr) else thr.ip++ ;; | OpFork: var lip = ((inst >> 4) & 0x3fffffff : std.size) var rip = ((inst >> 34) & 0x3fffffff : std.size) if rip != curip nthr = mkthread(re, rip) nthr.next = re.runq nthr.mgroup = thr.mgroup re.runq = nthr ;; if re.debug std.slpush(&re.traces, std.bsdup(re.traces[thr.tid])) ;; thr.ip = lip -> false /* Non-consuming opcodes. */ | OpJmp: var ip = (inst >> 4 : std.size) thr.ip = ip -> false | OpMatch: var id = (inst >> 4 : std.size) re.lastthr = thr.tid finish(re, thr) -> true | OpLbra: var m = (inst >> 4 : std.size) thr.mgroup[m][0] = re.strp thr.ip++ -> false | OpRbra: var m = (inst >> 4 : std.size) thr.mgroup[m][1] = re.strp thr.ip++ -> false | OpBol: if re.strp == 0 || str[re.strp - 1] == ('\n' : byte) thr.ip++ -> false else die(re, thr) ;; | OpEol: if re.strp == str.len || str[re.strp] == ('\n' : byte) thr.ip++ -> false else die(re, thr) ;; | OpBow: if iswordchar(str[re.strp:]) && (re.strp == 0 || !iswordchar(prevchar(str, re.strp))) thr.ip++ -> false else die(re, thr) ;; | OpEow: if re.strp == str.len && iswordchar(prevchar(str, re.strp)) thr.ip++ -> false elif re.strp > 0 && !iswordchar(str[re.strp:]) && iswordchar(prevchar(str, re.strp)) thr.ip++ -> false else die(re, thr) ;; | _: std.die("corrupt regex bytecode") ;; -> true } const die = {re, thr /* we can have die called on a thread multiple times, eg, if it has a bad range *and* end in a state that another thread is in. We should only decrement the number of threads for that once. */ if !thr.dead re.nthr-- ;; re.lastip = thr.ip re.lastthr = thr.tid thr.dead = true } const finish = {re, thr thr.matched = true re.nthr-- } const mkthread = {re, ip var thr : rethread# if re.free != Zthr thr = re.free re.free = thr.next re.nfree-- else thr = std.alloc() ;; thr.next = Zthr thr.ip = ip thr.tid = re.nexttid++ thr.dead = false thr.matched = false re.nthr++ -> thr } const thrfree = {re, thr if re.nfree >= Maxfree std.free(thr) else thr.next = re.free re.free = thr re.nfree++ ;; } const within = {re, str -> re.strp < str.len } const itrace = {re, thr, inst match inst | `Ibyte b: std.put("\t{}.{}:\tByte ({})\n", thr.tid, thr.ip, thr.tid, thr.ip, b) | `Irange (lo, hi): std.put("\t{}.{}:\tRange {}, {}\n", thr.tid, thr.ip, lo, hi) | `Ilbra m: std.put("\t{}.{}:\tLbra {}\n", thr.tid, thr.ip, m) | `Irbra m: std.put("\t{}.{}:\tRbra {}\n", thr.tid, thr.ip, m) /* anchors */ | `Ibol: std.put("\t{}.{}:\tBol\n", thr.tid, thr.ip) | `Ieol: std.put("\t{}.{}:\tEol\n", thr.tid, thr.ip) | `Ibow: std.put("\t{}.{}:\tBow\n", thr.tid, thr.ip) | `Ieow: std.put("\t{}.{}:\tEow\n", thr.tid, thr.ip) /* control flow */ | `Ifork (l, r): std.put("\t{}.{}:\tFork {}, {}\n", thr.tid, thr.ip, l, r) | `Ijmp ip: std.put("\t{}.{}:\tJmp {}\n", thr.tid, thr.ip, ip) | `Imatch m: std.put("\t{}.{}:\tMatch {}\n", thr.tid, thr.ip, m) ;; } const prevchar = {s, i std.assert(i != 0, "prevchar must be called with i >= 1\n") i-- while i != 0 && s[i] >= 0x80 i-- ;; -> s[i:] } const iswordchar = {s var c c = std.decode(s) -> std.isalpha(c) || std.isdigit(c) || c == '_' }