"""
Grammalecte: compile rules
Create a Direct Acyclic Rule Graphs (DARGs)
"""
import re
import darg
import compile_rules_js_convert as jsconv
dACTIONS = {}
dFUNCTIONS = {}
dFUNCNAME = {}
dDECLENSIONS = {}
def createFunction (sType, sCode, bStartWithEqual=False):
"create a function (stored in <dFUNCTIONS>) and return function name"
sCode = prepareFunction(sCode)
if sType not in dFUNCNAME:
dFUNCNAME[sType] = {}
if sCode not in dFUNCNAME[sType]:
dFUNCNAME[sType][sCode] = len(dFUNCNAME[sType])+1
sFuncName = "_g_" + sType + "_" + str(dFUNCNAME[sType][sCode])
dFUNCTIONS[sFuncName] = sCode
return sFuncName if not bStartWithEqual else "="+sFuncName
def storeAction (sActionId, aAction):
"store <aAction> in <dACTIONS> avoiding duplicates"
nVar = 0
while True:
sActionName = sActionId + "_" + str(nVar)
if sActionName not in dACTIONS:
dACTIONS[sActionName] = aAction
return sActionName
if aAction == dACTIONS[sActionName]:
return sActionName
nVar += 1
def prepareFunction (sCode):
"convert simple rule syntax to a string of Python code"
if sCode[0:1] == "=":
sCode = sCode[1:]
sCode = sCode.replace("__also__", "bCondMemo")
sCode = sCode.replace("__else__", "not bCondMemo")
sCode = sCode.replace("sContext", "_sAppContext")
sCode = re.sub(r"(morph|morphVC|analyse|value|tag|displayInfo)[(]\\(\d+)", 'g_\\1(lToken[nTokenOffset+\\2]', sCode)
sCode = re.sub(r"(morph|morphVC|analyse|value|tag|displayInfo)[(]\\-(\d+)", 'g_\\1(lToken[nLastToken-\\2+1]', sCode)
sCode = re.sub(r"(select|exclude|define|define_from)[(][\\](\d+)", 'g_\\1(lToken[nTokenOffset+\\2]', sCode)
sCode = re.sub(r"(select|exclude|define|define_from)[(][\\]-(\d+)", 'g_\\1(lToken[nLastToken-\\2+1]', sCode)
sCode = re.sub(r"(tag_before|tag_after)[(][\\](\d+)", 'g_\\1(lToken[nTokenOffset+\\2], dTags', sCode)
sCode = re.sub(r"(tag_before|tag_after)[(][\\]-(\d+)", 'g_\\1(lToken[nLastToken-\\2+1], dTags', sCode)
sCode = re.sub(r"space_after[(][\\](\d+)", 'g_space_between_tokens(lToken[nTokenOffset+\\1], lToken[nTokenOffset+\\1+1]', sCode)
sCode = re.sub(r"space_after[(][\\]-(\d+)", 'g_space_between_tokens(lToken[nLastToken-\\1+1], lToken[nLastToken-\\1+2]', sCode)
sCode = re.sub(r"analyse_with_next[(][\\](\d+)", 'g_merged_analyse(lToken[nTokenOffset+\\1], lToken[nTokenOffset+\\1+1]', sCode)
sCode = re.sub(r"analyse_with_next[(][\\]-(\d+)", 'g_merged_analyse(lToken[nLastToken-\\1+1], lToken[nLastToken-\\1+2]', sCode)
sCode = re.sub(r"(morph|analyse|tag|value)\(>1", 'g_\\1(lToken[nLastToken+1]', sCode) # next token
sCode = re.sub(r"(morph|analyse|tag|value)\(<1", 'g_\\1(lToken[nTokenOffset]', sCode) # previous token
sCode = re.sub(r"(morph|analyse|tag|value)\(>(\d+)", 'g_\\1(g_token(lToken, nLastToken+\\2)', sCode) # next token
sCode = re.sub(r"(morph|analyse|tag|value)\(<(\d+)", 'g_\\1(g_token(lToken, nTokenOffset+1-\\2)', sCode) # previous token
sCode = re.sub(r"\bspell *[(]", '_oSpellChecker.isValid(', sCode)
sCode = re.sub(r"\bbefore\(\s*", 'look(sSentence[:lToken[1+nTokenOffset]["nStart"]], ', sCode) # before(sCode)
sCode = re.sub(r"\bafter\(\s*", 'look(sSentence[lToken[nLastToken]["nEnd"]:], ', sCode) # after(sCode)
sCode = re.sub(r"\bbefore0\(\s*", 'look(sSentence0[:lToken[1+nTokenOffset]["nStart"]], ', sCode) # before0(sCode)
sCode = re.sub(r"\bafter0\(\s*", 'look(sSentence[lToken[nLastToken]["nEnd"]:], ', sCode) # after0(sCode)
sCode = re.sub(r"analyseWord[(]", 'analyse(', sCode)
sCode = re.sub(r"[\\](\d+)", 'lToken[nTokenOffset+\\1]["sValue"]', sCode)
sCode = re.sub(r"[\\]-(\d+)", 'lToken[nLastToken-\\1+1]["sValue"]', sCode)
sCode = re.sub(r">1", 'lToken[nLastToken+1]["sValue"]', sCode)
sCode = re.sub(r"<1", 'lToken[nTokenOffset]["sValue"]', sCode)
return sCode
def genTokenLines (sTokenLine, dDef, dDecl):
"tokenize a string and return a list of lines of tokens"
lTokenLines = []
for sTokBlock in sTokenLine.split():
# replace merger characters by spaces
if "␣" in sTokBlock:
sTokBlock = sTokBlock.replace("␣", " ")
# optional token?
bNullPossible = sTokBlock.startswith("?") and sTokBlock.endswith("¿")
if bNullPossible:
sTokBlock = sTokBlock[1:-1]
# token with definition?
if sTokBlock.startswith("({") and sTokBlock.endswith("})") and sTokBlock[1:-1] in dDef:
sTokBlock = "(" + dDef[sTokBlock[1:-1]] + ")"
elif sTokBlock.startswith("{") and sTokBlock.endswith("}") and sTokBlock in dDef:
sTokBlock = dDef[sTokBlock]
if ( (sTokBlock.startswith("[") and sTokBlock.endswith("]")) or (sTokBlock.startswith("([") and sTokBlock.endswith("])")) ):
# multiple token
bSelectedGroup = sTokBlock.startswith("(") and sTokBlock.endswith(")")
if bSelectedGroup:
sTokBlock = sTokBlock[1:-1]
lToken = createTokenList(sTokBlock, dDecl)
if not lTokenLines:
lTokenLines = [ ["("+s+")"] for s in lToken ] if bSelectedGroup else [ [s] for s in lToken ]
if bNullPossible:
lTokenLines.extend([ [] for i in range(len(lToken)+1) ])
else:
lNewTemp = []
if bNullPossible:
for aRule in lTokenLines:
for sElem in lToken:
aNewRule = list(aRule)
aNewRule.append(sElem)
lNewTemp.append(aNewRule)
else:
sElem1 = lToken.pop(0)
for aRule in lTokenLines:
for sElem in lToken:
aNewRule = list(aRule)
aNewRule.append("(" + sElem + ")" if bSelectedGroup else sElem)
lNewTemp.append(aNewRule)
aRule.append("(" + sElem1 + ")" if bSelectedGroup else sElem1)
lTokenLines.extend(lNewTemp)
else:
# simple token
if not lTokenLines:
lTokenLines = [[sTokBlock], []] if bNullPossible else [[sTokBlock]]
else:
if bNullPossible:
lNewTemp = []
for aRule in lTokenLines:
lNew = list(aRule)
lNew.append(sTokBlock)
lNewTemp.append(lNew)
lTokenLines.extend(lNewTemp)
else:
for aRule in lTokenLines:
aRule.append(sTokBlock)
for aRule in lTokenLines:
yield aRule
def createTokenList (sTokBlock, dDeclensions):
"return a list of tokens from a block of tokens"
lToken = []
for sToken in sTokBlock[1:-1].split("|"):
if "+" in sToken and not sToken.startswith("+"):
for sCode in dDeclensions:
if sToken.endswith(sCode):
sToken = sToken[:-len(sCode)]
lToken.append(sToken)
for sSuffix in dDeclensions[sCode]:
lToken.append(sToken+sSuffix)
break
else:
lToken.append(sToken)
return lToken
def createRule (iLine, sRuleName, sTokenLine, iActionBlock, sActions, nPriority, dOptPriority, dDef, dDecl):
"generator: create rule as list"
# print(iLine, "//", sRuleName, "//", sTokenLine, "//", sActions, "//", nPriority)
for lToken in genTokenLines(sTokenLine, dDef, dDecl):
# Calculate positions
dPos = {} # key: iGroup, value: iToken
iGroup = 0
#if iLine == 15818: # debug
# print(" ".join(lToken))
for i, sToken in enumerate(lToken):
if sToken.startswith("(") and sToken.endswith(")"):
lToken[i] = sToken[1:-1]
iGroup += 1
dPos[iGroup] = i + 1 # we add 1, for we count tokens from 1 to n (not from 0)
# Parse actions
for iAction, sAction in enumerate(sActions.split(" <<- ")):
sAction = sAction.strip()
if sAction:
sActionId = sRuleName + "__b" + str(iActionBlock) + "_a" + str(iAction)
aAction = createAction(sActionId, sAction, nPriority, dOptPriority, len(lToken), dPos)
if aAction:
sActionName = storeAction(sActionId, aAction)
lResult = list(lToken)
lResult.extend(["##"+str(iLine), sActionName])
#if iLine == 13341:
# print(" ".join(lToken))
# print(sActionId, aAction)
yield lResult
else:
print(" # Error on action at line:", iLine)
print(sTokenLine, "\n", sActions)
def changeReferenceToken (sText, dPos):
"change group reference in <sText> with values in <dPos>"
if "\\" not in sText:
return sText
for i in range(len(dPos), 0, -1):
sText = re.sub("\\\\"+str(i)+"(?![0-9])", "\\\\"+str(dPos[i]), sText)
return sText
def checkTokenNumbers (sText, sActionId, nToken):
"check if token references in <sText> greater than <nToken> (debugging)"
for x in re.finditer(r"\\(\d+)", sText):
if int(x.group(1)) > nToken:
print("# Error in token index at line " + sActionId + " ("+str(nToken)+" tokens only)")
print(sText)
def checkIfThereIsCode (sText, sActionId):
"check if there is code in <sText> (debugging)"
if re.search(r"[.]\w+[(]|sugg\w+[(]|\(\\[0-9]|\[[0-9]", sText):
print("# Warning at line " + sActionId + ": This message looks like code. Line should probably begin with =")
print(sText)
def createAction (sActionId, sAction, nPriority, dOptPriority, nToken, dPos):
"create action rule as a list"
# Option
sOption = False
m = re.match("/(\\w+)/", sAction)
if m:
sOption = m.group(1)
sAction = sAction[m.end():].strip()
if nPriority == -1:
nPriority = dOptPriority.get(sOption, 4)
# valid action?
m = re.search(r"(?P<action>[-=~/!>])(?P<start>-?\d+\.?|)(?P<end>:\.?-?\d+|)(?P<casing>:|)>>", sAction)
if not m:
print(" # Error. No action found at: ", sActionId)
return None
# Condition
sCondition = sAction[:m.start()].strip()
if sCondition:
sCondition = changeReferenceToken(sCondition, dPos)
sCondition = createFunction("cond", sCondition)
else:
sCondition = ""
# Case sensitivity
bCaseSensitivity = not bool(m.group("casing"))
# Action
cAction = m.group("action")
sAction = sAction[m.end():].strip()
sAction = changeReferenceToken(sAction, dPos)
# target
cStartLimit = "<"
cEndLimit = ">"
if not m.group("start"):
iStartAction = 1
iEndAction = 0
else:
if cAction != "-" and (m.group("start").endswith(".") or m.group("end").startswith(":.")):
print(" # Error. Wrong selection on tokens.", sActionId)
return None
if m.group("start").endswith("."):
cStartLimit = ">"
iStartAction = int(m.group("start").rstrip("."))
if not m.group("end"):
iEndAction = iStartAction
else:
if m.group("end").startswith(":."):
cEndLimit = "<"
iEndAction = int(m.group("end").lstrip(":."))
if dPos and m.group("start"):
iStartAction = dPos.get(iStartAction, iStartAction)
if iEndAction:
iEndAction = dPos.get(iEndAction, iEndAction)
if iStartAction < 0:
iStartAction += 1
if iEndAction < 0:
iEndAction += 1
if cAction == "-":
## error
iMsg = sAction.find(" # ")
if iMsg == -1:
sMsg = "# Error. Error message not found."
sURL = ""
print(sMsg + " Action id: " + sActionId)
else:
sMsg = sAction[iMsg+3:].strip()
sAction = sAction[:iMsg].strip()
sURL = ""
mURL = re.search("[|] *(https?://.*)", sMsg)
if mURL:
sURL = mURL.group(1).strip()
sMsg = sMsg[:mURL.start(0)].strip()
checkTokenNumbers(sMsg, sActionId, nToken)
if sMsg[0:1] == "=":
sMsg = createFunction("msg", sMsg, True)
else:
checkIfThereIsCode(sMsg, sActionId)
# checking consistancy
checkTokenNumbers(sAction, sActionId, nToken)
if cAction == ">":
## no action, break loop if condition is False
return [sOption, sCondition, cAction, ""]
if not sAction and cAction != "!":
print("# Error in action at line " + sActionId + ": This action is empty.")
if sAction[0:1] != "=" and cAction != "=":
checkIfThereIsCode(sAction, sActionId)
if cAction == "-":
## error detected --> suggestion
if sAction[0:1] == "=":
sAction = createFunction("sugg", sAction, True)
elif sAction.startswith('"') and sAction.endswith('"'):
sAction = sAction[1:-1]
if not sMsg:
print("# Error in action at line " + sActionId + ": The message is empty.")
return [sOption, sCondition, cAction, sAction, iStartAction, iEndAction, cStartLimit, cEndLimit, bCaseSensitivity, nPriority, sMsg, sURL]
if cAction == "~":
## text processor
if sAction[0:1] == "=":
sAction = createFunction("tp", sAction, True)
elif sAction.startswith('"') and sAction.endswith('"'):
sAction = sAction[1:-1]
return [sOption, sCondition, cAction, sAction, iStartAction, iEndAction, bCaseSensitivity]
if cAction in "!/":
## tags
return [sOption, sCondition, cAction, sAction, iStartAction, iEndAction]
if cAction == "=":
## disambiguator
if "define(" in sAction and not re.search(r"define\(\\-?\d+ *, *\[.*\] *\)", sAction):
print("# Error in action at line " + sActionId + ": second argument for <define> must be a list of strings")
sAction = createFunction("da", sAction)
return [sOption, sCondition, cAction, sAction]
print(" # Unknown action.", sActionId)
return None
def make (lRule, sLang, dDef, dDecl, dOptPriority):
"compile rules, returns a dictionary of values"
# for clarity purpose, don’t create any file here
# removing comments, zeroing empty lines, creating definitions, storing tests, merging rule lines
print(" parsing rules...")
lTokenLine = []
sActions = ""
nPriority = -1
dAllGraph = {}
sGraphName = ""
iActionBlock = 0
aRuleName = set()
for i, sLine in lRule:
sLine = sLine.rstrip()
if "\t" in sLine:
# tabulation not allowed
print("Error. Tabulation at line: ", i)
exit()
elif sLine.startswith("@@@@GRAPH: "):
# rules graph call
m = re.match(r"@@@@GRAPH: *(\w+)", sLine.strip())
if m:
sGraphName = m.group(1)
if sGraphName in dAllGraph:
print("Error at line " + i + ". Graph name <" + sGraphName + "> already exists.")
exit()
dAllGraph[sGraphName] = []
else:
print("Error. Graph name not found at line", i)
exit()
elif sLine.startswith("__") and sLine.endswith("__"):
# new rule group
m = re.match("__(\\w+)(!\\d|)__", sLine)
if m:
sRuleName = m.group(1)
if sRuleName in aRuleName:
print("Error at line " + i + ". Rule name <" + sRuleName + "> already exists.")
exit()
iActionBlock = 1
nPriority = int(m.group(2)[1:]) if m.group(2) else -1
else:
print("Syntax error in rule group: ", sLine, " -- line:", i)
exit()
elif re.search("^ +<<- ", sLine) or (sLine.startswith(" ") and not sLine.startswith(" ||")) \
or re.search("^ +#", sLine) or re.search(r"[-=~/!>](?:-?\d\.?(?::\.?-?\d+|)|)>> ", sLine) :
# actions
sActions += " " + sLine.strip()
elif re.match("[ ]*$", sLine):
# empty line to end merging
if not lTokenLine:
continue
if not sActions:
print("Error. No action found at line:", i)
exit()
if not sGraphName:
print("Error. All rules must belong to a named graph. Line: ", i)
exit()
for j, sTokenLine in lTokenLine:
dAllGraph[sGraphName].append((j, sRuleName, sTokenLine, iActionBlock, sActions, nPriority))
lTokenLine.clear()
sActions = ""
iActionBlock += 1
elif sLine.startswith(" "):
# tokens
sLine = sLine.strip()
if sLine.startswith("||"):
iPrevLine, sPrevLine = lTokenLine[-1]
lTokenLine[-1] = [iPrevLine, sPrevLine + " " + sLine[2:]]
else:
lTokenLine.append([i, sLine])
else:
print("Unknown line:")
print(sLine)
# processing rules
print(" preparing rules...")
for sGraphName, lRuleLine in dAllGraph.items():
print("{:>8,} rules in {:<24} ".format(len(lRuleLine), "<"+sGraphName+">"), end="")
lPreparedRule = []
for i, sRuleGroup, sTokenLine, iActionBlock, sActions, nPriority in lRuleLine:
for aRule in createRule(i, sRuleGroup, sTokenLine, iActionBlock, sActions, nPriority, dOptPriority, dDef, dDecl):
lPreparedRule.append(aRule)
# Graph creation
oDARG = darg.DARG(lPreparedRule, sLang)
dAllGraph[sGraphName] = oDARG.createGraph()
# Debugging
if False:
print("\nRULES:")
for e in lPreparedRule:
if e[-2] == "##2211":
print(e)
if False:
print("\nGRAPH:", sGraphName)
for k, v in dAllGraph[sGraphName].items():
print(k, "\t", v)
# creating file with all functions callable by rules
print(" creating callables for graph rules...")
sPyCallables = ""
sJSCallables = ""
for sFuncName, sReturn in dFUNCTIONS.items():
if sFuncName.startswith("_g_cond_"): # condition
sParams = "lToken, nTokenOffset, nLastToken, sCountry, bCondMemo, dTags, sSentence, sSentence0"
elif sFuncName.startswith("g_msg_"): # message
sParams = "lToken, nTokenOffset, nLastToken"
elif sFuncName.startswith("_g_sugg_"): # suggestion
sParams = "lToken, nTokenOffset, nLastToken"
elif sFuncName.startswith("_g_tp_"): # text preprocessor
sParams = "lToken, nTokenOffset, nLastToken"
elif sFuncName.startswith("_g_da_"): # disambiguator
sParams = "lToken, nTokenOffset, nLastToken"
else:
print("# Unknown function type in [" + sFuncName + "]")
continue
# Python
sPyCallables += "def {} ({}):\n".format(sFuncName, sParams)
sPyCallables += " return " + sReturn + "\n"
# JavaScript
sJSCallables += " {}: function ({})".format(sFuncName, sParams) + " {\n"
sJSCallables += " return " + jsconv.py2js(sReturn) + ";\n"
sJSCallables += " },\n"
# Debugging
if False:
print("\nActions:")
for sActionName, aAction in dACTIONS.items():
print(sActionName, aAction)
print("\nFunctions:")
print(sPyCallables)
# Result
return {
"graph_callables": sPyCallables,
"graph_callablesJS": sJSCallables,
"rules_graphs": str(dAllGraph),
"rules_graphsJS": str(dAllGraph),
"rules_actions": str(dACTIONS),
"rules_actionsJS": jsconv.pyActionsToString(dACTIONS)
}