forked from public/foundryvtt-swade-fr
1057 lines
35 KiB
Lua
1057 lines
35 KiB
Lua
--[[
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LPEGLJ
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lpcode.lua
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Generating code from tree
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Copyright (C) 2014 Rostislav Sacek.
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based on LPeg v1.0 - PEG pattern matching for Lua
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Lua.org & PUC-Rio written by Roberto Ierusalimschy
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http://www.inf.puc-rio.br/~roberto/lpeg/
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** Permission is hereby granted, free of charge, to any person obtaining
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** a copy of this software and associated documentation files (the
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** "Software"), to deal in the Software without restriction, including
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** without limitation the rights to use, copy, modify, merge, publish,
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** distribute, sublicense, and/or sell copies of the Software, and to
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** permit persons to whom the Software is furnished to do so, subject to
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** the following conditions:
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**
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** The above copyright notice and this permission notice shall be
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** included in all copies or substantial portions of the Software.
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**
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** THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
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** EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
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** MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
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** IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
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** CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
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** TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
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** SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
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**
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** [ MIT license: http://www.opensource.org/licenses/mit-license.php ]
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--]]
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local ffi = require "ffi"
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require "lpvm"
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local band, bor, bnot, rshift, lshift = bit.band, bit.bor, bit.bnot, bit.rshift, bit.lshift
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local TChar = 0
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local TSet = 1
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local TAny = 2 -- standard PEG elements
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local TTrue = 3
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local TFalse = 4
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local TRep = 5
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local TSeq = 6
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local TChoice = 7
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local TNot = 8
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local TAnd = 9
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local TCall = 10
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local TOpenCall = 11
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local TRule = 12 -- sib1 is rule's pattern, sib2 is 'next' rule
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local TGrammar = 13 -- sib1 is initial (and first) rule
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local TBehind = 14 -- match behind
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local TCapture = 15 -- regular capture
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local TRunTime = 16 -- run-time capture
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local IAny = 0 -- if no char, fail
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local IChar = 1 -- if char != val, fail
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local ISet = 2 -- if char not in val, fail
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local ITestAny = 3 -- in no char, jump to 'offset'
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local ITestChar = 4 -- if char != val, jump to 'offset'
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local ITestSet = 5 -- if char not in val, jump to 'offset'
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local ISpan = 6 -- read a span of chars in val
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local IBehind = 7 -- walk back 'val' characters (fail if not possible)
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local IRet = 8 -- return from a rule
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local IEnd = 9 -- end of pattern
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local IChoice = 10 -- stack a choice; next fail will jump to 'offset'
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local IJmp = 11 -- jump to 'offset'
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local ICall = 12 -- call rule at 'offset'
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local IOpenCall = 13 -- call rule number 'offset' (must be closed to a ICall)
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local ICommit = 14 -- pop choice and jump to 'offset'
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local IPartialCommit = 15 -- update top choice to current position and jump
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local IBackCommit = 16 -- "fails" but jump to its own 'offset'
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local IFailTwice = 17 -- pop one choice and then fail
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local IFail = 18 -- go back to saved state on choice and jump to saved offset
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local IGiveup = 19 -- internal use
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local IFullCapture = 20 -- complete capture of last 'off' chars
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local IOpenCapture = 21 -- start a capture
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local ICloseCapture = 22
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local ICloseRunTime = 23
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local Cclose = 0
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local Cposition = 1
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local Cconst = 2
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local Cbackref = 3
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local Carg = 4
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local Csimple = 5
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local Ctable = 6
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local Cfunction = 7
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local Cquery = 8
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local Cstring = 9
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local Cnum = 10
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local Csubst = 11
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local Cfold = 12
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local Cruntime = 13
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local Cgroup = 14
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local PEnullable = 0
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local PEnofail = 1
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local RuleLR = 0x10000
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local NOINST = -2
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local MAXBEHINDPREDICATE = 255
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local MAXRULES = 200
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local MAXOFF = 0xF
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-- number of siblings for each tree
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local numsiblings = {
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0, 0, 0, -- char, set, any
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0, 0, -- true, false
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1, -- rep
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2, 2, -- seq, choice
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1, 1, -- not, and
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0, 0, 2, 1, -- call, opencall, rule, grammar
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1, -- behind
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1, 1 -- capture, runtime capture
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}
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local patternelement = ffi.typeof('PATTERN_ELEMENT')
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local pattern = ffi.typeof('PATTERN')
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local settype = ffi.typeof('int32_t[8]')
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local fullset = settype(-1, -1, -1, -1, -1, -1, -1, -1)
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-- {======================================================
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-- Analysis and some optimizations
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-- =======================================================
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local codegen
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-- Check whether a charset is empty (IFail), singleton (IChar),
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-- full (IAny), or none of those (ISet).
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local function charsettype(cs)
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local count = 0;
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local candidate = -1; -- candidate position for a char
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for i = 0, 8 - 1 do
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local b = cs[i];
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if b == 0 then
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if count > 1 then
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return ISet; -- else set is still empty
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end
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elseif b == -1 then
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if count < (i * 32) then
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return ISet;
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else
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count = count + 32; -- set is still full
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end
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-- byte has only one bit?
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elseif band(b, (b - 1)) == 0 then
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if count > 0 then
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return ISet; -- set is neither full nor empty
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-- set has only one char till now; track it
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else
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count = count + 1;
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candidate = i;
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end
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else
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return ISet; -- byte is neither empty, full, nor singleton
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end
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end
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if count == 0 then
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return IFail, 0 -- empty set
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-- singleton; find character bit inside byte
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elseif count == 1 then
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local b = cs[candidate];
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local c = candidate * 32;
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for i = 1, 32 do
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if b == 1 then
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c = c + i - 1
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break
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end
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b = rshift(b, 1)
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end
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return IChar, c
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elseif count == 256 then
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return IAny, 0 -- full set
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else
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assert(false) -- should have returned by now
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end
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end
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-- A few basic operations on Charsets
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local function cs_complement(cs)
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for i = 0, 8 - 1 do
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cs[i] = bnot(cs[i])
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end
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end
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local function cs_equal(cs1, cs2)
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for i = 0, 8 - 1 do
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if cs1[i] ~= cs2[i] then
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return
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end
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end
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return true
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end
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-- computes whether sets st1 and st2 are disjoint
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local function cs_disjoint(st1, st2)
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for i = 0, 8 - 1 do
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if band(st1[i], st2[i]) ~= 0 then
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return
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end
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end
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return true
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end
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-- Convert a 'char' pattern (TSet, TChar, TAny) to a charset
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local function tocharset(tree, index, valuetable)
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local val = settype()
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if tree.p[index].tag == TSet then
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ffi.copy(val, valuetable[tree.p[index].val], ffi.sizeof(val))
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return val
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elseif tree.p[index].tag == TChar then
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local b = tree.p[index].val
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-- only one char
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-- add that one
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val[rshift(b, 5)] = lshift(1, band(b, 31))
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return val
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elseif tree.p[index].tag == TAny then
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ffi.fill(val, ffi.sizeof(val), 0xff)
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return val
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end
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end
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-- checks whether a pattern has captures
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local function hascaptures(tree, index)
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if tree.p[index].tag == TCapture or tree.p[index].tag == TRunTime then
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return true
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elseif tree.p[index].tag == TCall then
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return hascaptures(tree, index + tree.p[index].ps)
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else
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local ns = numsiblings[tree.p[index].tag + 1]
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if ns == 0 then
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return
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elseif ns == 1 then
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return hascaptures(tree, index + 1)
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elseif ns == 2 then
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if hascaptures(tree, index + 1) then
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return true
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else
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return hascaptures(tree, index + tree.p[index].ps)
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end
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else
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assert(false)
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end
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end
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end
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-- Checks how a pattern behaves regarding the empty string,
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-- in one of two different ways:
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-- A pattern is *nullable* if it can match without consuming any character;
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-- A pattern is *nofail* if it never fails for any string
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-- (including the empty string).
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-- The difference is only for predicates; for patterns without
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-- predicates, the two properties are equivalent.
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-- (With predicates, &'a' is nullable but not nofail. Of course,
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-- nofail => nullable.)
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-- These functions are all convervative in the following way:
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-- p is nullable => nullable(p)
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-- nofail(p) => p cannot fail
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-- (The function assumes that TOpenCall and TRunTime are not nullable:
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-- TOpenCall must be checked again when the grammar is fixed;
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-- TRunTime is an arbitrary choice.)
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local function checkaux(tree, pred, index, lrcall)
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lrcall = lrcall or {}
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local tag = tree.p[index].tag
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if tag == TChar or tag == TSet or tag == TAny or
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tag == TFalse or tag == TOpenCall then
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return -- not nullable
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elseif tag == TRep or tag == TTrue then
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return true -- no fail
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elseif tag == TNot or tag == TBehind then
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-- can match empty, but may fail
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if pred == PEnofail then
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return
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else
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return true -- PEnullable
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end
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elseif tag == TAnd then
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-- can match empty; fail iff body does
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if pred == PEnullable then
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return true
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else
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return checkaux(tree, pred, index + 1, lrcall)
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end
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-- can fail; match empty iff body does
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elseif tag == TRunTime then
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if pred == PEnofail then
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return
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else
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return checkaux(tree, pred, index + 1, lrcall)
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end
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elseif tag == TSeq then
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if not checkaux(tree, pred, index + 1, lrcall) then
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return
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else
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return checkaux(tree, pred, index + tree.p[index].ps, lrcall)
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end
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elseif tag == TChoice then
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if checkaux(tree, pred, index + tree.p[index].ps, lrcall) then
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return true
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else
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return checkaux(tree, pred, index + 1, lrcall)
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end
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elseif tag == TCapture or tag == TGrammar or tag == TRule then
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return checkaux(tree, pred, index + 1, lrcall)
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elseif tag == TCall then
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--left recursive rule
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if bit.band(tree.p[index].cap, 0xffff) ~= 0 then
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local lr = index + tree.p[index].ps
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if lrcall[lr] then
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return
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end
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lrcall[lr] = true
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end
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return checkaux(tree, pred, index + tree.p[index].ps, lrcall)
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else
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assert(false)
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end
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end
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-- number of characters to match a pattern (or -1 if variable)
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-- ('count' avoids infinite loops for grammars)
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local function fixedlenx(tree, count, len, index)
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local tag = tree.p[index].tag
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if tag == TChar or tag == TSet or tag == TAny then
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return len + 1;
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elseif tag == TFalse or tag == TTrue or tag == TNot or tag == TAnd or tag == TBehind then
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return len;
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elseif tag == TRep or tag == TRunTime or tag == TOpenCall then
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return -1;
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elseif tag == TCapture or tag == TRule or tag == TGrammar then
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return fixedlenx(tree, count, len, index + 1)
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elseif tag == TCall then
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if count >= MAXRULES then
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return -1; -- may be a loop
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else
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return fixedlenx(tree, count + 1, len, index + tree.p[index].ps)
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end
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elseif tag == TSeq then
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len = fixedlenx(tree, count, len, index + 1)
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if (len < 0) then
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return -1;
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else
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return fixedlenx(tree, count, len, index + tree.p[index].ps)
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end
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elseif tag == TChoice then
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local n1 = fixedlenx(tree, count, len, index + 1)
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if n1 < 0 then return -1 end
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local n2 = fixedlenx(tree, count, len, index + tree.p[index].ps)
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if n1 == n2 then
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return n1
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else
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return -1
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end
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else
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assert(false)
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end
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end
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-- Computes the 'first set' of a pattern.
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-- The result is a conservative aproximation:
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-- match p ax -> x' for some x ==> a in first(p).
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-- match p '' -> '' ==> returns 1.
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-- The set 'follow' is the first set of what follows the
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-- pattern (full set if nothing follows it)
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local function getfirst(tree, follow, index, valuetable, lrcall)
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lrcall = lrcall or {}
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local tag = tree.p[index].tag
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if tag == TChar or tag == TSet or tag == TAny then
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local firstset = tocharset(tree, index, valuetable)
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return 0, firstset
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elseif tag == TTrue then
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local firstset = settype()
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ffi.copy(firstset, follow, ffi.sizeof(firstset))
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return 1, firstset
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elseif tag == TFalse then
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local firstset = settype()
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return 0, firstset
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elseif tag == TChoice then
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local e1, firstset = getfirst(tree, follow, index + 1, valuetable, lrcall)
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local e2, csaux = getfirst(tree, follow, index + tree.p[index].ps, valuetable, lrcall)
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for i = 0, 8 - 1 do
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firstset[i] = bor(firstset[i], csaux[i])
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end
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return bor(e1, e2), firstset
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elseif tag == TSeq then
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if not checkaux(tree, PEnullable, index + 1) then
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return getfirst(tree, fullset, index + 1, valuetable, lrcall)
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-- FIRST(p1 p2, fl) = FIRST(p1, FIRST(p2, fl))
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else
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local e2, csaux = getfirst(tree, follow, index + tree.p[index].ps, valuetable, lrcall)
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local e1, firstset = getfirst(tree, csaux, index + 1, valuetable, lrcall)
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if e1 == 0 then -- 'e1' ensures that first can be used
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return 0, firstset
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-- one of the children has a matchtime?
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elseif band(bor(e1, e2), 2) == 2 then
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return 2, firstset -- pattern has a matchtime capture
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else
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return e2, firstset -- else depends on 'e2'
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end
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end
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elseif tag == TRep then
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local _, firstset = getfirst(tree, follow, index + 1, valuetable, lrcall)
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for i = 0, 8 - 1 do
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firstset[i] = bor(firstset[i], follow[i])
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end
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return 1, firstset -- accept the empty string
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elseif tag == TCapture or tag == TGrammar or tag == TRule then
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return getfirst(tree, follow, index + 1, valuetable, lrcall)
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-- function invalidates any follow info.
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elseif tag == TRunTime then
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local e, firstset = getfirst(tree, fullset, index + 1, valuetable, lrcall)
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if e ~= 0 then
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return 2, firstset -- function is not "protected"?
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else
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return 0, firstset -- pattern inside capture ensures first can be used
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end
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elseif tag == TCall then
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-- left recursive rule
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if bit.band(tree.p[index].cap, 0xffff) ~= 0 then
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local lr = index + tree.p[index].ps
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if lrcall[lr] then
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return 0, settype()
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else
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lrcall[lr] = true
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end
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end
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return getfirst(tree, follow, index + tree.p[index].ps, valuetable, lrcall)
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elseif tag == TAnd then
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local e, firstset = getfirst(tree, follow, index + 1, valuetable, lrcall)
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for i = 0, 8 - 1 do
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firstset[i] = band(firstset[i], follow[i])
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end
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return e, firstset
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elseif tag == TNot then
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local firstset = tocharset(tree, index + 1, valuetable)
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if firstset then
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cs_complement(firstset)
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return 1, firstset
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end
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local e, firstset = getfirst(tree, follow, index + 1, valuetable, lrcall)
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ffi.copy(firstset, follow, ffi.sizeof(firstset))
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return bor(e, 1), firstset -- always can accept the empty string
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-- instruction gives no new information
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elseif tag == TBehind then
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-- call 'getfirst' to check for math-time captures
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local e, firstset = getfirst(tree, follow, index + 1, valuetable, lrcall)
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ffi.copy(firstset, follow, ffi.sizeof(firstset))
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return bor(e, 1), firstset -- always can accept the empty string
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else
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assert(false)
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end
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end
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-- If it returns true, then pattern can fail only depending on the next
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-- character of the subject
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|
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local function headfail(tree, index, lrcall)
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lrcall = lrcall or {}
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local tag = tree.p[index].tag
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if tag == TChar or tag == TSet or tag == TAny or tag == TFalse then
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return true
|
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elseif tag == TTrue or tag == TRep or tag == TRunTime or tag == TNot or tag == TBehind then
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return
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elseif tag == TCapture or tag == TGrammar or tag == TRule or tag == TAnd then
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return headfail(tree, index + 1, lrcall)
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elseif tag == TCall then
|
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-- left recursive rule
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if bit.band(tree.p[index].cap, 0xffff) ~= 0 then
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local lr = index + tree.p[index].ps
|
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if lrcall[lr] then
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return true
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else
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lrcall[lr] = true
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end
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end
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return headfail(tree, index + tree.p[index].ps, lrcall)
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elseif tag == TSeq then
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if not checkaux(tree, PEnofail, index + tree.p[index].ps) then
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return
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else
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return headfail(tree, index + 1, lrcall)
|
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end
|
|
elseif tag == TChoice then
|
|
if not headfail(tree, index + 1, lrcall) then
|
|
return
|
|
else
|
|
return headfail(tree, index + tree.p[index].ps, lrcall)
|
|
end
|
|
else
|
|
assert(false)
|
|
end
|
|
end
|
|
|
|
|
|
-- Check whether the code generation for the given tree can benefit
|
|
-- from a follow set (to avoid computing the follow set when it is
|
|
-- not needed)
|
|
|
|
local function needfollow(tree, index)
|
|
local tag = tree.p[index].tag
|
|
if tag == TChar or tag == TSet or tag == TAny or tag == TFalse or tag == TTrue or tag == TAnd or tag == TNot or
|
|
tag == TRunTime or tag == TGrammar or tag == TCall or tag == TBehind then
|
|
return
|
|
elseif tag == TChoice or tag == TRep then
|
|
return true
|
|
elseif tag == TCapture then
|
|
return needfollow(tree, index + 1)
|
|
elseif tag == TSeq then
|
|
return needfollow(tree, index + tree.p[index].ps)
|
|
else
|
|
assert(false)
|
|
end
|
|
end
|
|
|
|
-- ======================================================
|
|
|
|
|
|
-- {======================================================
|
|
-- Code generation
|
|
-- =======================================================
|
|
|
|
|
|
-- code generation is recursive; 'opt' indicates that the code is
|
|
-- being generated under a 'IChoice' operator jumping to its end.
|
|
-- 'tt' points to a previous test protecting this code. 'fl' is
|
|
-- the follow set of the pattern.
|
|
|
|
|
|
local function addinstruction(code, op, val)
|
|
local size = code.size
|
|
if size >= code.allocsize then
|
|
code:doublesize()
|
|
end
|
|
code.p[size].code = op
|
|
code.p[size].val = val
|
|
code.size = size + 1
|
|
return size
|
|
end
|
|
|
|
|
|
local function setoffset(code, instruction, offset)
|
|
code.p[instruction].offset = offset;
|
|
end
|
|
|
|
|
|
-- Add a capture instruction:
|
|
-- 'op' is the capture instruction; 'cap' the capture kind;
|
|
-- 'key' the key into ktable; 'aux' is optional offset
|
|
|
|
local function addinstcap(code, op, cap, key, aux)
|
|
local i = addinstruction(code, op, bor(cap, lshift(aux, 4)))
|
|
setoffset(code, i, key)
|
|
return i
|
|
end
|
|
|
|
|
|
local function jumptothere(code, instruction, target)
|
|
if instruction >= 0 then
|
|
setoffset(code, instruction, target - instruction)
|
|
end
|
|
end
|
|
|
|
|
|
local function jumptohere(code, instruction)
|
|
jumptothere(code, instruction, code.size)
|
|
end
|
|
|
|
|
|
-- Code an IChar instruction, or IAny if there is an equivalent
|
|
-- test dominating it
|
|
|
|
local function codechar(code, c, tt)
|
|
assert(tt ~= -1)
|
|
if tt >= 0 and code.p[tt].code == ITestChar and
|
|
code.p[tt].val == c then
|
|
addinstruction(code, IAny, 0)
|
|
else
|
|
addinstruction(code, IChar, c)
|
|
end
|
|
end
|
|
|
|
|
|
-- Code an ISet instruction
|
|
|
|
local function coderealcharset(code, cs, valuetable)
|
|
local ind = #valuetable + 1
|
|
valuetable[ind] = cs
|
|
return addinstruction(code, ISet, ind)
|
|
end
|
|
|
|
|
|
-- code a char set, optimizing unit sets for IChar, "complete"
|
|
-- sets for IAny, and empty sets for IFail; also use an IAny
|
|
-- when instruction is dominated by an equivalent test.
|
|
|
|
local function codecharset(code, cs, tt, valuetable)
|
|
local op, c = charsettype(cs)
|
|
if op == IChar then
|
|
codechar(code, c, tt)
|
|
elseif op == ISet then
|
|
assert(tt ~= -1)
|
|
if tt >= 0 and code.p[tt].code == ITestSet and
|
|
cs_equal(cs, valuetable[code.p[tt].val]) then
|
|
addinstruction(code, IAny, 0)
|
|
else
|
|
coderealcharset(code, cs, valuetable)
|
|
end
|
|
else
|
|
addinstruction(code, op, c)
|
|
end
|
|
end
|
|
|
|
|
|
-- code a test set, optimizing unit sets for ITestChar, "complete"
|
|
-- sets for ITestAny, and empty sets for IJmp (always fails).
|
|
-- 'e' is true iff test should accept the empty string. (Test
|
|
-- instructions in the current VM never accept the empty string.)
|
|
|
|
local function codetestset(code, cs, e, valuetable)
|
|
if e ~= 0 then
|
|
return NOINST -- no test
|
|
else
|
|
local pos = code.size
|
|
codecharset(code, cs, NOINST, valuetable)
|
|
local inst = code.p[pos]
|
|
local code = inst.code
|
|
if code == IFail then
|
|
inst.code = IJmp -- always jump
|
|
elseif code == IAny then
|
|
inst.code = ITestAny
|
|
elseif code == IChar then
|
|
inst.code = ITestChar
|
|
elseif code == ISet then
|
|
inst.code = ITestSet
|
|
else
|
|
assert(false)
|
|
end
|
|
return pos
|
|
end
|
|
end
|
|
|
|
|
|
-- Find the final destination of a sequence of jumps
|
|
|
|
local function finaltarget(code, i)
|
|
while code.p[i].code == IJmp do
|
|
i = i + code.p[i].offset
|
|
end
|
|
return i
|
|
end
|
|
|
|
|
|
-- final label (after traversing any jumps)
|
|
|
|
local function finallabel(code, i)
|
|
return finaltarget(code, i + code.p[i].offset)
|
|
end
|
|
|
|
-- <behind(p)> == behind n; <p> (where n = fixedlen(p))
|
|
|
|
local function codebehind(code, tree, index, valuetable)
|
|
if tree.p[index].val > 0 then
|
|
addinstruction(code, IBehind, tree.p[index].val)
|
|
end
|
|
codegen(code, tree, fullset, false, NOINST, index + 1, valuetable) -- NOINST
|
|
end
|
|
|
|
|
|
-- Choice; optimizations:
|
|
-- - when p1 is headfail
|
|
-- - when first(p1) and first(p2) are disjoint; than
|
|
-- a character not in first(p1) cannot go to p1, and a character
|
|
-- in first(p1) cannot go to p2 (at it is not in first(p2)).
|
|
-- (The optimization is not valid if p1 accepts the empty string,
|
|
-- as then there is no character at all...)
|
|
-- - when p2 is empty and opt is true; a IPartialCommit can resuse
|
|
-- the Choice already active in the stack.
|
|
|
|
local function codechoice(code, tree, fl, opt, p1, p2, valuetable)
|
|
local emptyp2 = tree.p[p2].tag == TTrue
|
|
local e1, st1 = getfirst(tree, fullset, p1, valuetable)
|
|
local _, st2 = getfirst(tree, fl, p2, valuetable)
|
|
if headfail(tree, p1) or (e1 == 0 and cs_disjoint(st1, st2)) then
|
|
-- <p1 / p2> == test (fail(p1)) -> L1 ; p1 ; jmp L2; L1: p2; L2:
|
|
local test = codetestset(code, st1, 0, valuetable)
|
|
local jmp = NOINST;
|
|
codegen(code, tree, fl, false, test, p1, valuetable)
|
|
if not emptyp2 then
|
|
jmp = addinstruction(code, IJmp, 0)
|
|
end
|
|
jumptohere(code, test)
|
|
codegen(code, tree, fl, opt, NOINST, p2, valuetable)
|
|
jumptohere(code, jmp)
|
|
elseif opt and emptyp2 then
|
|
-- p1? == IPartialCommit; p1
|
|
jumptohere(code, addinstruction(code, IPartialCommit, 0))
|
|
codegen(code, tree, fullset, true, NOINST, p1, valuetable)
|
|
else
|
|
-- <p1 / p2> ==
|
|
-- test(fail(p1)) -> L1; choice L1; <p1>; commit L2; L1: <p2>; L2:
|
|
local test = codetestset(code, st1, e1, valuetable)
|
|
local pchoice = addinstruction(code, IChoice, 0)
|
|
codegen(code, tree, fullset, emptyp2, test, p1, valuetable)
|
|
local pcommit = addinstruction(code, ICommit, 0)
|
|
jumptohere(code, pchoice)
|
|
jumptohere(code, test)
|
|
codegen(code, tree, fl, opt, NOINST, p2, valuetable)
|
|
jumptohere(code, pcommit)
|
|
end
|
|
end
|
|
|
|
|
|
-- And predicate
|
|
-- optimization: fixedlen(p) = n ==> <&p> == <p>; behind n
|
|
-- (valid only when 'p' has no captures)
|
|
|
|
local function codeand(code, tree, tt, index, valuetable)
|
|
local n = fixedlenx(tree, 0, 0, index)
|
|
if n >= 0 and n <= MAXBEHINDPREDICATE and not hascaptures(tree, index) then
|
|
codegen(code, tree, fullset, false, tt, index, valuetable)
|
|
if n > 0 then
|
|
addinstruction(code, IBehind, n)
|
|
end
|
|
else
|
|
-- default: Choice L1; p1; BackCommit L2; L1: Fail; L2:
|
|
local pchoice = addinstruction(code, IChoice, 0)
|
|
codegen(code, tree, fullset, false, tt, index, valuetable)
|
|
local pcommit = addinstruction(code, IBackCommit, 0)
|
|
jumptohere(code, pchoice)
|
|
addinstruction(code, IFail, 0)
|
|
jumptohere(code, pcommit)
|
|
end
|
|
end
|
|
|
|
|
|
-- Captures: if pattern has fixed (and not too big) length, use
|
|
-- a single IFullCapture instruction after the match; otherwise,
|
|
-- enclose the pattern with OpenCapture - CloseCapture.
|
|
|
|
local function codecapture(code, tree, fl, tt, index, valuetable)
|
|
local len = fixedlenx(tree, 0, 0, index + 1)
|
|
if len >= 0 and len <= MAXOFF and not hascaptures(tree, index + 1) then
|
|
codegen(code, tree, fl, false, tt, index + 1, valuetable)
|
|
addinstcap(code, IFullCapture, tree.p[index].cap, tree.p[index].val, len)
|
|
else
|
|
addinstcap(code, IOpenCapture, tree.p[index].cap, tree.p[index].val, 0)
|
|
codegen(code, tree, fl, false, tt, index + 1, valuetable)
|
|
addinstcap(code, ICloseCapture, Cclose, 0, 0)
|
|
end
|
|
end
|
|
|
|
|
|
local function coderuntime(code, tree, tt, index, valuetable)
|
|
addinstcap(code, IOpenCapture, Cgroup, tree.p[index].val, 0)
|
|
codegen(code, tree, fullset, false, tt, index + 1, valuetable)
|
|
addinstcap(code, ICloseRunTime, Cclose, 0, 0)
|
|
end
|
|
|
|
|
|
-- Repetion; optimizations:
|
|
-- When pattern is a charset, can use special instruction ISpan.
|
|
-- When pattern is head fail, or if it starts with characters that
|
|
-- are disjoint from what follows the repetions, a simple test
|
|
-- is enough (a fail inside the repetition would backtrack to fail
|
|
-- again in the following pattern, so there is no need for a choice).
|
|
-- When 'opt' is true, the repetion can reuse the Choice already
|
|
-- active in the stack.
|
|
|
|
local function coderep(code, tree, opt, fl, index, valuetable)
|
|
local st = tocharset(tree, index, valuetable)
|
|
if st then
|
|
local op = coderealcharset(code, st, valuetable)
|
|
code.p[op].code = ISpan;
|
|
else
|
|
local e1, st = getfirst(tree, fullset, index, valuetable)
|
|
if headfail(tree, index) or (e1 == 0 and cs_disjoint(st, fl)) then
|
|
-- L1: test (fail(p1)) -> L2; <p>; jmp L1; L2:
|
|
local test = codetestset(code, st, 0, valuetable)
|
|
codegen(code, tree, fullset, false, test, index, valuetable)
|
|
local jmp = addinstruction(code, IJmp, 0)
|
|
jumptohere(code, test)
|
|
jumptothere(code, jmp, test)
|
|
else
|
|
-- test(fail(p1)) -> L2; choice L2; L1: <p>; partialcommit L1; L2:
|
|
-- or (if 'opt'): partialcommit L1; L1: <p>; partialcommit L1;
|
|
local test = codetestset(code, st, e1, valuetable)
|
|
local pchoice = NOINST;
|
|
if opt then
|
|
jumptohere(code, addinstruction(code, IPartialCommit, 0))
|
|
else
|
|
pchoice = addinstruction(code, IChoice, 0)
|
|
end
|
|
local l2 = code.size
|
|
codegen(code, tree, fullset, false, NOINST, index, valuetable)
|
|
local commit = addinstruction(code, IPartialCommit, 0)
|
|
jumptothere(code, commit, l2)
|
|
jumptohere(code, pchoice)
|
|
jumptohere(code, test)
|
|
end
|
|
end
|
|
end
|
|
|
|
|
|
-- Not predicate; optimizations:
|
|
-- In any case, if first test fails, 'not' succeeds, so it can jump to
|
|
-- the end. If pattern is headfail, that is all (it cannot fail
|
|
-- in other parts); this case includes 'not' of simple sets. Otherwise,
|
|
-- use the default code (a choice plus a failtwice).
|
|
|
|
local function codenot(code, tree, index, valuetable)
|
|
local e, st = getfirst(tree, fullset, index, valuetable)
|
|
local test = codetestset(code, st, e, valuetable)
|
|
-- test (fail(p1)) -> L1; fail; L1:
|
|
if headfail(tree, index) then
|
|
addinstruction(code, IFail, 0)
|
|
else
|
|
-- test(fail(p))-> L1; choice L1; <p>; failtwice; L1:
|
|
local pchoice = addinstruction(code, IChoice, 0)
|
|
codegen(code, tree, fullset, false, NOINST, index, valuetable)
|
|
addinstruction(code, IFailTwice, 0)
|
|
jumptohere(code, pchoice)
|
|
end
|
|
jumptohere(code, test)
|
|
end
|
|
|
|
|
|
-- change open calls to calls, using list 'positions' to find
|
|
-- correct offsets; also optimize tail calls
|
|
|
|
local function correctcalls(code, positions, from, to)
|
|
for i = from, to - 1 do
|
|
if code.p[i].code == IOpenCall then
|
|
local n = code.p[i].offset; -- rule number
|
|
local rule = positions[n]; -- rule position
|
|
assert(rule == from or code.p[rule - 1].code == IRet)
|
|
-- call; ret ?
|
|
if bit.band(code.p[i].val, 0xffff) == 0 and code.p[finaltarget(code, i + 1)].code == IRet then
|
|
code.p[i].code = IJmp; -- tail call
|
|
else
|
|
code.p[i].code = ICall;
|
|
end
|
|
jumptothere(code, i, rule) -- call jumps to respective rule
|
|
end
|
|
end
|
|
end
|
|
|
|
|
|
-- Code for a grammar:
|
|
-- call L1; jmp L2; L1: rule 1; ret; rule 2; ret; ...; L2:
|
|
|
|
local function codegrammar(code, tree, index, valuetable)
|
|
local positions = {}
|
|
local rulenumber = 1;
|
|
-- tree.p[rule].tag
|
|
local rule = index + 1
|
|
assert(tree.p[rule].tag == TRule)
|
|
local LR = 0
|
|
if band(RuleLR, tree.p[rule].cap) ~= 0 then LR = 1 end
|
|
local firstcall = addinstruction(code, ICall, LR) -- call initial rule
|
|
code.p[firstcall].aux = tree.p[rule].val
|
|
local jumptoend = addinstruction(code, IJmp, 0) -- jump to the end
|
|
jumptohere(code, firstcall) -- here starts the initial rule
|
|
while tree.p[rule].tag == TRule do
|
|
positions[rulenumber] = code.size -- save rule position
|
|
rulenumber = rulenumber + 1
|
|
codegen(code, tree, fullset, false, NOINST, rule + 1, valuetable) -- code rule
|
|
addinstruction(code, IRet, 0)
|
|
rule = rule + tree.p[rule].ps
|
|
end
|
|
assert(tree.p[rule].tag == TTrue)
|
|
jumptohere(code, jumptoend)
|
|
correctcalls(code, positions, firstcall + 2, code.size)
|
|
end
|
|
|
|
|
|
local function codecall(code, tree, index, val)
|
|
local c = addinstruction(code, IOpenCall, tree.p[index].cap) -- to be corrected later
|
|
code.p[c].aux = val
|
|
assert(tree.p[index + tree.p[index].ps].tag == TRule)
|
|
setoffset(code, c, band(tree.p[index + tree.p[index].ps].cap, 0x7fff)) -- offset = rule number
|
|
end
|
|
|
|
|
|
local function codeseq(code, tree, fl, opt, tt, p1, p2, valuetable)
|
|
if needfollow(tree, p1) then
|
|
local _, fll = getfirst(tree, fl, p2, valuetable) -- p1 follow is p2 first
|
|
codegen(code, tree, fll, false, tt, p1, valuetable)
|
|
else
|
|
-- use 'fullset' as follow
|
|
codegen(code, tree, fullset, false, tt, p1, valuetable)
|
|
end
|
|
-- can p1 consume anything?
|
|
if (fixedlenx(tree, 0, 0, p1) ~= 0) then
|
|
tt = NOINST; -- invalidate test
|
|
end
|
|
return codegen(code, tree, fl, opt, tt, p2, valuetable)
|
|
end
|
|
|
|
|
|
-- Main code-generation function: dispatch to auxiliar functions
|
|
-- according to kind of tree
|
|
|
|
-- code generation is recursive; 'opt' indicates that the code is being
|
|
-- generated as the last thing inside an optional pattern (so, if that
|
|
-- code is optional too, it can reuse the 'IChoice' already in place for
|
|
-- the outer pattern). 'tt' points to a previous test protecting this
|
|
-- code (or NOINST). 'fl' is the follow set of the pattern.
|
|
|
|
function codegen(code, tree, fl, opt, tt, index, valuetable)
|
|
local tag = tree.p[index].tag
|
|
if tag == TChar then
|
|
return codechar(code, tree.p[index].val, tt)
|
|
elseif tag == TAny then
|
|
return addinstruction(code, IAny, 0)
|
|
elseif tag == TSet then
|
|
return codecharset(code, valuetable[tree.p[index].val], tt, valuetable)
|
|
elseif tag == TTrue then
|
|
elseif tag == TFalse then
|
|
return addinstruction(code, IFail, 0)
|
|
elseif tag == TSeq then
|
|
return codeseq(code, tree, fl, opt, tt, index + 1, index + tree.p[index].ps, valuetable)
|
|
elseif tag == TChoice then
|
|
return codechoice(code, tree, fl, opt, index + 1, index + tree.p[index].ps, valuetable)
|
|
elseif tag == TRep then
|
|
return coderep(code, tree, opt, fl, index + 1, valuetable)
|
|
elseif tag == TBehind then
|
|
return codebehind(code, tree, index, valuetable)
|
|
elseif tag == TNot then
|
|
return codenot(code, tree, index + 1, valuetable)
|
|
elseif tag == TAnd then
|
|
return codeand(code, tree, tt, index + 1, valuetable)
|
|
elseif tag == TCapture then
|
|
return codecapture(code, tree, fl, tt, index, valuetable)
|
|
elseif tag == TRunTime then
|
|
return coderuntime(code, tree, tt, index, valuetable)
|
|
elseif tag == TGrammar then
|
|
return codegrammar(code, tree, index, valuetable)
|
|
elseif tag == TCall then
|
|
return codecall(code, tree, index, tree.p[index].val)
|
|
else
|
|
assert(false)
|
|
end
|
|
end
|
|
|
|
|
|
-- Optimize jumps and other jump-like instructions.
|
|
-- * Update labels of instructions with labels to their final
|
|
-- destinations (e.g., choice L1; ... L1: jmp L2: becomes
|
|
-- choice L2)
|
|
-- * Jumps to other instructions that do jumps become those
|
|
-- instructions (e.g., jump to return becomes a return; jump
|
|
-- to commit becomes a commit)
|
|
|
|
local function peephole(code)
|
|
local i = 0
|
|
while i < code.size do
|
|
local tag = code.p[i].code
|
|
if tag == IChoice or tag == ICall or tag == ICommit or tag == IPartialCommit or
|
|
tag == IBackCommit or tag == ITestChar or tag == ITestSet or tag == ITestAny then
|
|
-- instructions with labels
|
|
jumptothere(code, i, finallabel(code, i)) -- optimize label
|
|
|
|
elseif tag == IJmp then
|
|
local ft = finaltarget(code, i)
|
|
local tag = code.p[ft].code -- jumping to what?
|
|
-- instructions with unconditional implicit jumps
|
|
if tag == IRet or tag == IFail or tag == IFailTwice or tag == IEnd then
|
|
ffi.copy(code.p + i, code.p + ft, ffi.sizeof(patternelement)) -- jump becomes that instruction
|
|
elseif tag == ICommit or tag == IPartialCommit or tag == IBackCommit then
|
|
-- inst. with unconditional explicit jumps
|
|
local fft = finallabel(code, ft)
|
|
ffi.copy(code.p + i, code.p + ft, ffi.sizeof(patternelement)) -- jump becomes that instruction...
|
|
jumptothere(code, i, fft) -- but must correct its offset
|
|
i = i - 1 -- reoptimize its label
|
|
else
|
|
jumptothere(code, i, ft) -- optimize label
|
|
end
|
|
end
|
|
i = i + 1
|
|
end
|
|
end
|
|
|
|
|
|
-- Compile a pattern
|
|
|
|
local function compile(tree, index, valuetable)
|
|
local code = pattern()
|
|
codegen(code, tree, fullset, false, NOINST, index, valuetable)
|
|
addinstruction(code, IEnd, 0)
|
|
peephole(code)
|
|
ffi.C.free(tree.code)
|
|
tree.code = code
|
|
end
|
|
|
|
local function pat_new(ct, size)
|
|
size = size or 0
|
|
local allocsize = size
|
|
if allocsize < 10 then
|
|
allocsize = 10
|
|
end
|
|
local pat = ffi.cast('PATTERN*', ffi.C.malloc(ffi.sizeof(pattern)))
|
|
assert(pat ~= nil)
|
|
pat.allocsize = allocsize
|
|
pat.size = size
|
|
pat.p = ffi.C.malloc(ffi.sizeof(patternelement) * allocsize)
|
|
assert(pat.p ~= nil)
|
|
ffi.fill(pat.p, ffi.sizeof(patternelement) * allocsize)
|
|
return pat
|
|
end
|
|
|
|
local function doublesize(ct)
|
|
ct.p = ffi.C.realloc(ct.p, ffi.sizeof(patternelement) * ct.allocsize * 2)
|
|
assert(ct.p ~= nil)
|
|
ffi.fill(ct.p + ct.allocsize, ffi.sizeof(patternelement) * ct.allocsize)
|
|
ct.allocsize = ct.allocsize * 2
|
|
end
|
|
|
|
local pattreg = {
|
|
doublesize = doublesize,
|
|
}
|
|
|
|
local metareg = {
|
|
["__new"] = pat_new,
|
|
["__index"] = pattreg
|
|
}
|
|
|
|
ffi.metatype(pattern, metareg)
|
|
|
|
return {
|
|
checkaux = checkaux,
|
|
tocharset = tocharset,
|
|
fixedlenx = fixedlenx,
|
|
hascaptures = hascaptures,
|
|
compile = compile,
|
|
} |