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kll/common/parse.py

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KLL Compiler Re-Write This was many months of efforts in re-designing how the KLL compiler should work. The major problem with the original compiler was how difficult it was to extend language wise. This lead to many delays in KLL 0.4 and 0.5 being implemented. The new design is a multi-staged compiler, where even tokenization occurs over multiple stages. This allows individual parsing and token regexes to be expressed more simply without affect other expressions. Another area of change is the concept of Contexts. In the original KLL compiler the idea of a cache assigned was "hacked" on when I realized the language was "broken" (after nearly finishing the compiler). Since assignment order is generally considered not to matter for keymappings, I created a "cached" assignment where the whole file is read into a sub-datastructure, then apply to the master datastructure. Unfortunately, this wasn't really all that clear, so it was annoying to work with. To remedy this, I created KLL Contexts, which contain information about a group of expressions. Not only can these groups can be merged with other Contexts, they have historical data about how they were generated allowing for errors very late in processing to be pin-pointed back to the offending kll file. Backends work nearly the same as they did before. However, all call-backs for capability evaluations have been removed. This makes the interface much cleaner as Contexts can only be symbolically merged now. (Previously datastructures did evaluation merges where the ScanCode or Capability was looked up right before passing to the backend, but this required additional information from the backend). Many of the old parsing and tokenization rules have been reused, along with the hid_dict.py code. The new design takes advantage of processor pools to handle multithreading where it makes sense. For example, all specified files are loaded into ram simulatenously rather than sparingly reading from. The reason for this is so that each Context always has all the information it requires at all times. kll - Program entry point (previously kll.py) - Very small now, does some setting up of command-line args - Most command-line args are specified by the corresponding processing stage common/channel.py - Pixel Channel container classes common/context.py - Context container classes - As is usual with other files, blank classes inherit a base class - These blank classes are identified by the class name itself to handle special behaviour - And if/when necessary functions are re-implemented - MergeConext class facilitates merging of contexts while maintaining lineage common/expression.py - Expression container classes * Expression base class * AssignmentExpression * NameAssociationExpression * DataAssociationExpression * MapExpression - These classes are used to store expressions after they have finished parsing and tokenization common/file.py - Container class for files being read by the KLL compiler common/emitter.py - Base class for all KLL emitters - TextEmitter for dealing with text file templates common/hid_dict.py - Slightly modified version of kll_lib/hid_dict.py common/id.py - Identification container classes - Used to indentify different types of elements used within the KLL language common/modifier.py - Container classes for animation and pixel change functions common/organization.py - Data structure merging container classes - Contains all the sub-datastructure classes as well - The Organization class handles the merge orchestration and expression insertion common/parse.py - Parsing rules for funcparserlib - Much of this file was taken from the original kll.py - Many changes to support the multi-stage processing and support KLL 0.5 common/position.py - Container class dealing with physical positions common/schedule.py - Container class dealing with scheduling and timing events common/stage.py - Contains ControlStage and main Stage classes * CompilerConfigurationStage * FileImportStage * PreprocessorStage * OperationClassificationStage * OperationSpecificsStage * OperationOrganizationStage * DataOrganziationStage * DataFinalizationStage * DataAnalysisStage * CodeGenerationStage * ReportGenerationStage - Each of these classes controls the life-cycle of each stage - If multi-threading is desired, it must be handled within the class * The next stage will not start until the current stage is finished - Errors are handled such that as many errors as possible are recorded before forcing an exit * The exit is handled at the end of each stage if necessary - Command-line arguments for each stage can be defined if necessary (they are given their own grouping) - Each stage can pull variables and functions from other stages if necessary using a name lookup * This means you don't have to worry about over-arching datastructures emitters/emitters.py - Container class for KLL emitters - Handles emitter setup and selection emitters/kiibohd/kiibohd.py - kiibohd .h file KLL emitter - Re-uses some backend code from the original KLL compiler funcparserlib/parser.py - Added debug mode control examples/assignment.kll examples/defaultMapExample.kll examples/example.kll examples/hhkbpro2.kll examples/leds.kll examples/mapping.kll examples/simple1.kll examples/simple2.kll examples/simpleExample.kll examples/state_scheduling.kll - Updating/Adding rules for new compiler and KLL 0.4 + KLL 0.5 support
2016-09-02 06:48:13 +00:00
#!/usr/bin/env python3
'''
KLL Parsing Expressions
This file contains various parsing rules and processors used by funcparserlib for KLL
REMEMBER: When editing parser BNF-like expressions, order matters. Specifically lexer tokens and parser |
'''
# Parser doesn't play nice with linters, disable some checks
# pylint: disable=no-self-argument, too-many-public-methods, no-self-use, bad-builtin
# Copyright (C) 2016 by Jacob Alexander
#
# This file is free software: you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# This file is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this file. If not, see <http://www.gnu.org/licenses/>.
### Imports ###
from common.hid_dict import kll_hid_lookup_dictionary
from common.id import (
AnimationId, AnimationFrameId,
CapArgId, CapId,
HIDId,
NoneId,
PixelId, PixelLayerId,
ScanCodeId
)
from common.modifier import AnimationModifierList
from common.schedule import AnalogScheduleParam, ScheduleParam, Time
from funcparserlib.lexer import Token
from funcparserlib.parser import (some, a, many, oneplus, skip, maybe)
### Decorators ###
## Print Decorator Variables
ERROR = '\033[5;1;31mERROR\033[0m:'
WARNING = '\033[5;1;33mWARNING\033[0m:'
### Classes ###
## Parsing Functions
class Make:
'''
Collection of parse string interpreters
'''
def scanCode( token ):
'''
Converts a raw scan code string into an ScanCodeId /w integer
S0x10 -> 16
'''
if isinstance( token, int ):
return ScanCodeId( token )
else:
return ScanCodeId( int( token[1:], 0 ) )
def hidCode( type, token ):
'''
Convert a given raw hid token string to an integer /w a type
U"Enter" -> USB, Enter(0x28)
'''
# If already converted to a HIDId, just return
if isinstance( token, HIDId ):
return token
# If first character is a U or I, strip
if token[0] == "U" or token[0] == "I":
token = token[1:]
# CONS specifier
elif 'CONS' in token:
token = token[4:]
# SYS specifier
elif 'SYS' in token:
token = token[3:]
# If using string representation of USB Code, do lookup, case-insensitive
if '"' in token:
try:
hidCode = kll_hid_lookup_dictionary[ type ][ token[1:-1].upper() ][1]
except LookupError as err:
print ( "{0} {1} is an invalid USB HID Code Lookup...".format( ERROR, err ) )
raise
else:
# Already tokenized
if (
type == 'USBCode' and token[0] == 'USB'
or
type == 'SysCode' and token[0] == 'SYS'
or
type == 'ConsCode' and token[0] == 'CONS'
or
type == 'IndCode' and token[0] == 'IND'
):
hidCode = token[1]
# Convert
else:
hidCode = int( token, 0 )
return HIDId( type, hidCode )
def usbCode( token ):
'''
Convert a given raw USB Keyboard hid token string to an integer /w a type
U"Enter" -> USB, Enter(0x28)
'''
return Make.hidCode( 'USBCode', token )
def consCode( token ):
'''
Convert a given raw Consumer Control hid token string to an integer /w a type
'''
return Make.hidCode( 'ConsCode', token )
def sysCode( token ):
'''
Convert a given raw System Control hid token string to an integer /w a type
'''
return Make.hidCode( 'SysCode', token )
def indCode( token ):
'''
Convert a given raw Indicator hid token string to an integer /w a type
'''
return Make.hidCode( 'IndCode', token )
def animation( name ):
'''
Converts a raw animation value into an AnimationId /w name
A"myname" -> myname
'''
if name[0] == "A":
return AnimationId( name[2:-1] )
else:
return AnimationId( name )
def animationTrigger( animation, frame_indices ):
'''
Generate either an AnimationId or an AnimationFrameId
frame_indices indicate that this is an AnimationFrameId
'''
trigger_list = []
# AnimationFrameId
if len( frame_indices ) > 0:
for index in frame_indices:
trigger_list.append( [ [ AnimationFrameId( animation, index ) ] ] )
# AnimationId
else:
trigger_list.append( [ [ AnimationId( animation ) ] ] )
return trigger_list
def animationCapability( animation, modifiers ):
'''
Apply modifiers to AnimationId
'''
if modifiers is not None:
animation.setModifiers( modifiers )
return [ animation ]
def animationModlist( modifiers ):
'''
Build an AnimationModifierList
Only used for animation data association
'''
modlist = AnimationModifierList()
modlist.setModifiers( modifiers )
return modlist
def pixelCapability( pixels, modifiers ):
'''
Apply modifiers to list of pixels/pixellists
Results in a combination of pixel capabilities
'''
pixelcap_list = []
for pixel in pixels:
pixel.setModifiers( modifiers )
pixelcap_list.append( pixel )
return pixelcap_list
def pixel( token ):
'''
Converts a raw pixel value into a PixelId /w integer
P0x3 -> 3
'''
if isinstance( token, int ):
return PixelId( token )
else:
return PixelId( int( token[1:], 0 ) )
def pixel_list( pixel_list ):
'''
Converts a list a numbers into a list of PixelIds
'''
pixels = []
for pixel in pixel_list:
pixels.append( PixelId( pixel ) )
return pixels
def pixelLayer( token ):
'''
Converts a raw pixel layer value into a PixelLayerId /w integer
PL0x3 -> 3
'''
if isinstance( token, int ):
return PixelLayerId( token )
else:
return PixelLayerId( int( token[2:], 0 ) )
def pixelLayer_list( layer_list ):
'''
Converts a list a numbers into a list of PixelLayerIds
'''
layers = []
for layer in layer_list:
layers.append( PixelLayerId( layer ) )
return layers
def pixelchan( pixel_list, chans ):
'''
Apply channels to PixelId
Only one pixel at a time can be mapped, hence pixel_list[0]
'''
pixel = pixel_list[0]
pixel.setChannels( chans )
return pixel
def pixelmod( pixels, modifiers ):
'''
Apply modifiers to list of pixels/pixellists
Results in a combination of pixel capabilities
'''
pixelcap_list = []
for pixel in pixels:
pixel.setModifiers( modifiers )
pixelcap_list.append( pixel )
return pixelcap_list
def position( token ):
'''
Physical position split
x:20 -> (x, 20)
'''
return token.split(':')
def usbCode_number( token ):
'''
USB Keyboard HID Code lookup
'''
return HIDId( 'USBCode', token )
def consCode_number( token ):
'''
Consumer Control HID Code lookup
'''
return HIDId( 'ConsCode', token )
def sysCode_number( token ):
'''
System Control HID Code lookup
'''
return HIDId( 'SysCode', token )
def indCode_number( token ):
'''
Indicator HID Code lookup
'''
return HIDId( 'IndCode', token )
def none( token ):
'''
Replace key-word with NoneId specifier (which indicates a noneOut capability)
'''
return [[[NoneId()]]]
def seqString( token ):
'''
Converts sequence string to a sequence of combinations
'Ab' -> U"Shift" + U"A", U"B"
'''
# TODO - Add locale support
# Shifted Characters, and amount to move by to get non-shifted version
# US ANSI
shiftCharacters = (
( "ABCDEFGHIJKLMNOPQRSTUVWXYZ", 0x20 ),
( "+", 0x12 ),
( "&(", 0x11 ),
( "!#$%", 0x10 ),
( "*", 0x0E ),
( ")", 0x07 ),
( '"', 0x05 ),
( ":", 0x01 ),
( "@", -0x0E ),
( "<>?", -0x10 ),
( "~", -0x1E ),
( "{}|", -0x20 ),
( "^", -0x28 ),
( "_", -0x32 ),
)
listOfLists = []
shiftKey = kll_hid_lookup_dictionary['USBCode']["SHIFT"]
# Creates a list of USB codes from the string: sequence (list) of combos (lists)
for char in token[1:-1]:
processedChar = char
# Whether or not to create a combo for this sequence with a shift
shiftCombo = False
# Depending on the ASCII character, convert to single character or Shift + character
for pair in shiftCharacters:
if char in pair[0]:
shiftCombo = True
processedChar = chr( ord( char ) + pair[1] )
break
# Do KLL HID Lookup on non-shifted character
# NOTE: Case-insensitive, which is why the shift must be pre-computed
usb_code = kll_hid_lookup_dictionary['USBCode'][ processedChar.upper() ]
# Create Combo for this character, add shift key if shifted
charCombo = []
if shiftCombo:
charCombo = [ [ HIDId( 'USBCode', shiftKey[1] ) ] ]
charCombo.append( [ HIDId( 'USBCode', usb_code[1] ) ] )
# Add to list of lists
listOfLists.append( charCombo )
return listOfLists
def string( token ):
'''
Converts a raw string to a Python string
"this string" -> this string
'''
return token[1:-1]
def unseqString( token ):
'''
Converts a raw sequence string to a Python string
'this string' -> this string
'''
return token[1:-1]
def number( token ):
'''
Convert string number to Python integer
'''
return int( token, 0 )
def timing( token ):
'''
Convert raw timing parameter to integer time and determine units
1ms -> 1, ms
'''
# Find ms, us, or s
if 'ms' in token:
unit = 'ms'
num = token.split('m')[0]
elif 'us' in token:
unit = 'us'
num = token.split('u')[0]
elif 'ns' in token:
unit = 'ns'
num = token.split('n')[0]
elif 's' in token:
unit = 's'
num = token.split('s')[0]
else:
print ( "{0} cannot find timing unit in token '{1}'".format( ERROR, token ) )
return Time( float( num ), unit )
def specifierTiming( timing ):
'''
When only timing is given, infer state at a later stage from the context of the mapping
'''
return ScheduleParam( None, timing )
def specifierState( state, timing=None ):
'''
Generate a Schedule Parameter
Automatically mutates itself into the correct object type
'''
return ScheduleParam( state, timing )
def specifierAnalog( value ):
'''
Generate an Analog Schedule Parameter
'''
return AnalogScheduleParam( value )
def specifierUnroll( identifier, schedule_params ):
'''
Unroll specifiers into the trigger/result identifier
First, combine all Schedule Parameters into a Schedul
Then attach Schedule to the identifier
If the identifier is a list, then iterate through them
and apply the schedule to each
'''
# Check if this is a list of identifiers
if isinstance( identifier, list ):
for ident in identifier:
ident.setSchedule( schedule_params )
return identifier
else:
identifier.setSchedule( schedule_params )
return [ identifier ]
# Range can go from high to low or low to high
def scanCode_range( rangeVals ):
'''
Scan Code range expansion
S[0x10-0x12] -> S0x10, S0x11, S0x12
'''
start = rangeVals[0]
end = rangeVals[1]
# Swap start, end if start is greater than end
if start > end:
start, end = end, start
# Iterate from start to end, and generate the range
values = list( range( start, end + 1 ) )
# Generate ScanCodeIds
return [ ScanCodeId( v ) for v in values ]
# Range can go from high to low or low to high
# Warn on 0-9 for USBCodes (as this does not do what one would expect) TODO
# Lookup USB HID tags and convert to a number
def hidCode_range( type, rangeVals ):
'''
HID Code range expansion
U["A"-"C"] -> U"A", U"B", U"C"
'''
# Check if already integers
if isinstance( rangeVals[0], int ):
start = rangeVals[0]
else:
start = Make.hidCode( type, rangeVals[0] ).uid
if isinstance( rangeVals[1], int ):
end = rangeVals[1]
else:
end = Make.hidCode( type, rangeVals[1] ).uid
# Swap start, end if start is greater than end
if start > end:
start, end = end, start
# Iterate from start to end, and generate the range
listRange = list( range( start, end + 1 ) )
# Convert each item in the list to a tuple
for item in range( len( listRange ) ):
listRange[ item ] = HIDId( type, listRange[ item ] )
return listRange
def usbCode_range( rangeVals ):
'''
USB Keyboard HID Code range expansion
'''
return Make.hidCode_range( 'USBCode', rangeVals )
def sysCode_range( rangeVals ):
'''
System Control HID Code range expansion
'''
return Make.hidCode_range( 'SysCode', rangeVals )
def consCode_range( rangeVals ):
'''
Consumer Control HID Code range expansion
'''
return Make.hidCode_range( 'ConsCode', rangeVals )
def indCode_range( rangeVals ):
'''
Indicator HID Code range expansion
'''
return Make.hidCode_range( 'IndCode', rangeVals )
def range( start, end ):
'''
Converts a start and end points of a range to a list of numbers
Can go low to high or high to low
'''
# High to low
if end < start:
return list( range( end, start + 1 ) )
# Low to high
return list( range( start, end + 1 ) )
def capArg( argument, width=None ):
'''
Converts a capability argument:width to a CapArgId
If no width is specified, it is ignored
'''
return CapArgId( argument, width )
def capUsage( name, arguments ):
'''
Converts a capability tuple, argument list to a CapId Usage
'''
return CapId( name, 'Usage', arguments )
### Rules ###
## Base Rules
const = lambda x: lambda _: x
unarg = lambda f: lambda x: f(*x)
flatten = lambda list: sum( list, [] )
tokenValue = lambda x: x.value
tokenType = lambda t: some( lambda x: x.type == t ) >> tokenValue
operator = lambda s: a( Token( 'Operator', s ) ) >> tokenValue
parenthesis = lambda s: a( Token( 'Parenthesis', s ) ) >> tokenValue
bracket = lambda s: a( Token( 'Bracket', s ) ) >> tokenValue
eol = a( Token( 'EndOfLine', ';' ) )
def maybeFlatten( items ):
'''
Iterate through top-level lists
Flatten, only if the element is also a list
[[1,2],3,[[4,5]]] -> [1,2,3,[4,5]]
'''
new_list = []
for elem in items:
# Flatten only if a list
if isinstance( elem, list ):
new_list.extend( elem )
else:
new_list.append( elem )
return new_list
def listElem( item ):
'''
Convert to a list element
'''
return [ item ]
def listToTuple( items ):
'''
Convert list to a tuple
'''
return tuple( items )
def oneLayerFlatten( items ):
'''
Flatten only the top layer (list of lists of ...)
'''
mainList = []
for sublist in items:
for item in sublist:
mainList.append( item )
return mainList
def optionExpansion( sequences ):
'''
Expand ranges of values in the 3rd dimension of the list, to a list of 2nd lists
i.e. [ sequence, [ combo, [ range ] ] ] --> [ [ sequence, [ combo ] ], <option 2>, <option 3> ]
'''
expandedSequences = []
# Total number of combinations of the sequence of combos that needs to be generated
totalCombinations = 1
# List of leaf lists, with number of leaves
maxLeafList = []
# Traverse to the leaf nodes, and count the items in each leaf list
for sequence in sequences:
for combo in sequence:
rangeLen = len( combo )
totalCombinations *= rangeLen
maxLeafList.append( rangeLen )
# Counter list to keep track of which combination is being generated
curLeafList = [0] * len( maxLeafList )
# Generate a list of permuations of the sequence of combos
for count in range( 0, totalCombinations ):
expandedSequences.append( [] ) # Prepare list for adding the new combination
pos = 0
# Traverse sequence of combos to generate permuation
for sequence in sequences:
expandedSequences[ -1 ].append( [] )
for combo in sequence:
expandedSequences[ -1 ][ -1 ].append( combo[ curLeafList[ pos ] ] )
pos += 1
# Increment combination tracker
for leaf in range( 0, len( curLeafList ) ):
curLeafList[ leaf ] += 1
# Reset this position, increment next position (if it exists), then stop
if curLeafList[ leaf ] >= maxLeafList[ leaf ]:
curLeafList[ leaf ] = 0
if leaf + 1 < len( curLeafList ):
curLeafList[ leaf + 1 ] += 1
return expandedSequences
def listit( t ):
'''
Convert tuple of tuples to list of lists
'''
return list( map( listit, t ) ) if isinstance( t, ( list, tuple ) ) else t
def tupleit( t ):
'''
Convert list of lists to tuple of tuples
'''
return tuple( map( tupleit, t ) ) if isinstance( t, ( tuple, list ) ) else t
## Sub Rules
usbCode = tokenType('USBCode') >> Make.usbCode
scanCode = tokenType('ScanCode') >> Make.scanCode
consCode = tokenType('ConsCode') >> Make.consCode
sysCode = tokenType('SysCode') >> Make.sysCode
indCode = tokenType('IndCode') >> Make.indCode
animation = tokenType('Animation') >> Make.animation
pixel = tokenType('Pixel') >> Make.pixel
pixelLayer = tokenType('PixelLayer') >> Make.pixelLayer
none = tokenType('None') >> Make.none
position = tokenType('Position') >> Make.position
name = tokenType('Name')
number = tokenType('Number') >> Make.number
timing = tokenType('Timing') >> Make.timing
comma = tokenType('Comma')
dash = tokenType('Dash')
plus = tokenType('Plus')
content = tokenType('VariableContents')
string = tokenType('String') >> Make.string
unString = tokenType('String') # When the double quotes are still needed for internal processing
seqString = tokenType('SequenceString') >> Make.seqString
unseqString = tokenType('SequenceString') >> Make.unseqString # For use with variables
pixelOperator = tokenType('PixelOperator')
# Code variants
code_begin = tokenType('CodeBegin')
code_end = tokenType('CodeEnd')
# Specifier
specifier_basic = ( timing >> Make.specifierTiming ) | ( name >> Make.specifierState )
specifier_complex = ( name + skip( operator(':') ) + timing ) >> unarg( Make.specifierState )
specifier_state = specifier_complex | specifier_basic
specifier_analog = number >> Make.specifierAnalog
specifier_list = skip( parenthesis('(') ) + many( ( specifier_state | specifier_analog ) + skip( maybe( comma ) ) ) + skip( parenthesis(')') )
# Scan Codes
scanCode_start = tokenType('ScanCodeStart')
scanCode_range = number + skip( dash ) + number >> Make.scanCode_range
scanCode_listElem = number >> Make.scanCode
scanCode_specifier = ( scanCode_range | scanCode_listElem ) + maybe( specifier_list ) >> unarg( Make.specifierUnroll )
scanCode_innerList = many( scanCode_specifier + skip( maybe( comma ) ) ) >> flatten
scanCode_expanded = skip( scanCode_start ) + scanCode_innerList + skip( code_end ) + maybe( specifier_list ) >> unarg( Make.specifierUnroll )
scanCode_elem = scanCode + maybe( specifier_list ) >> unarg( Make.specifierUnroll )
scanCode_combo = oneplus( ( scanCode_expanded | scanCode_elem ) + skip( maybe( plus ) ) )
scanCode_sequence = oneplus( scanCode_combo + skip( maybe( comma ) ) )
scanCode_single = ( skip( scanCode_start ) + scanCode_listElem + skip( code_end ) ) | scanCode
# Cons Codes
consCode_start = tokenType('ConsCodeStart')
consCode_number = number >> Make.consCode_number
consCode_range = ( consCode_number | unString ) + skip( dash ) + ( number | unString ) >> Make.consCode_range
consCode_listElemTag = unString >> Make.consCode
consCode_listElem = ( consCode_number | consCode_listElemTag )
consCode_specifier = ( consCode_range | consCode_listElem ) + maybe( specifier_list ) >> unarg( Make.specifierUnroll )
consCode_innerList = oneplus( consCode_specifier + skip( maybe( comma ) ) ) >> flatten
consCode_expanded = skip( consCode_start ) + consCode_innerList + skip( code_end ) + maybe( specifier_list ) >> unarg( Make.specifierUnroll )
consCode_elem = consCode + maybe( specifier_list ) >> unarg( Make.specifierUnroll )
# Sys Codes
sysCode_start = tokenType('SysCodeStart')
sysCode_number = number >> Make.sysCode_number
sysCode_range = ( sysCode_number | unString ) + skip( dash ) + ( number | unString ) >> Make.sysCode_range
sysCode_listElemTag = unString >> Make.sysCode
sysCode_listElem = ( sysCode_number | sysCode_listElemTag )
sysCode_specifier = ( sysCode_range | sysCode_listElem ) + maybe( specifier_list ) >> unarg( Make.specifierUnroll )
sysCode_innerList = oneplus( sysCode_specifier + skip( maybe( comma ) ) ) >> flatten
sysCode_expanded = skip( sysCode_start ) + sysCode_innerList + skip( code_end ) + maybe( specifier_list ) >> unarg( Make.specifierUnroll )
sysCode_elem = sysCode + maybe( specifier_list ) >> unarg( Make.specifierUnroll )
# Indicator Codes
indCode_start = tokenType('IndicatorStart')
indCode_number = number >> Make.indCode_number
indCode_range = ( indCode_number | unString ) + skip( dash ) + ( number | unString ) >> Make.indCode_range
indCode_listElemTag = unString >> Make.indCode
indCode_listElem = ( indCode_number | indCode_listElemTag )
indCode_specifier = ( indCode_range | indCode_listElem ) + maybe( specifier_list ) >> unarg( Make.specifierUnroll )
indCode_innerList = oneplus( indCode_specifier + skip( maybe( comma ) ) ) >> flatten
indCode_expanded = skip( indCode_start ) + indCode_innerList + skip( code_end ) + maybe( specifier_list ) >> unarg( Make.specifierUnroll )
indCode_elem = indCode + maybe( specifier_list ) >> unarg( Make.specifierUnroll )
# USB Codes
usbCode_start = tokenType('USBCodeStart')
usbCode_number = number >> Make.usbCode_number
usbCode_range = ( usbCode_number | unString ) + skip( dash ) + ( number | unString ) >> Make.usbCode_range
usbCode_listElemTag = unString >> Make.usbCode
usbCode_listElem = ( usbCode_number | usbCode_listElemTag )
usbCode_specifier = ( usbCode_range | usbCode_listElem ) + maybe( specifier_list ) >> unarg( Make.specifierUnroll )
usbCode_innerList = oneplus( usbCode_specifier + skip( maybe( comma ) ) ) >> flatten
usbCode_expanded = skip( usbCode_start ) + usbCode_innerList + skip( code_end ) + maybe( specifier_list ) >> unarg( Make.specifierUnroll )
usbCode_elem = usbCode + maybe( specifier_list ) >> unarg( Make.specifierUnroll )
# HID Codes
hidCode_elem = usbCode_expanded | usbCode_elem | sysCode_expanded | sysCode_elem | consCode_expanded | consCode_elem | indCode_expanded | indCode_elem
usbCode_combo = oneplus( hidCode_elem + skip( maybe( plus ) ) ) >> listElem
usbCode_sequence = oneplus( ( usbCode_combo | seqString ) + skip( maybe( comma ) ) ) >> oneLayerFlatten
# Pixels
pixel_start = tokenType('PixelStart')
pixel_range = ( number ) + skip( dash ) + ( number ) >> unarg( Make.range )
pixel_listElem = number >> listElem
pixel_innerList = many( ( pixel_range | pixel_listElem ) + skip( maybe( comma ) ) ) >> flatten >> Make.pixel_list
pixel_expanded = skip( pixel_start ) + pixel_innerList + skip( code_end )
pixel_elem = pixel >> listElem
# Pixel Layer
pixellayer_start = tokenType('PixelLayerStart')
pixellayer_range = ( number ) + skip( dash ) + ( number ) >> unarg( Make.range )
pixellayer_listElem = number >> listElem
pixellayer_innerList = many( ( pixellayer_range | pixellayer_listElem ) + skip( maybe( comma ) ) ) >> flatten >> Make.pixelLayer_list
pixellayer_expanded = skip( pixellayer_start ) + pixellayer_innerList + skip( code_end )
pixellayer_elem = pixelLayer >> listElem
# Pixel Channels
pixelchan_chans = many( number + skip( operator(':') ) + number + skip( maybe( comma ) ) )
pixelchan_elem = ( pixel_expanded | pixel_elem ) + skip( parenthesis('(') ) + pixelchan_chans + skip( parenthesis(')') ) >> unarg( Make.pixelchan )
# Pixel Mods
pixelmod_mods = many( maybe( pixelOperator | plus | dash ) + number + skip( maybe( comma ) ) )
pixelmod_layer = ( pixellayer_expanded | pixellayer_elem )
pixelmod_elem = ( pixel_expanded | pixel_elem | pixelmod_layer ) + skip( parenthesis('(') ) + pixelmod_mods + skip( parenthesis(')') ) >> unarg( Make.pixelmod )
# Pixel Capability
pixel_capability = pixelmod_elem
# Animations
animation_start = tokenType('AnimationStart')
animation_name = name
animation_frame_range = ( number ) + skip( dash ) + ( number ) >> unarg( Make.range )
animation_name_frame = many( ( animation_frame_range | number ) + skip( maybe( comma ) ) ) >> maybeFlatten
animation_def = skip( animation_start ) + animation_name + skip( code_end ) >> Make.animation
animation_expanded = skip( animation_start ) + animation_name + skip( maybe( comma ) ) + animation_name_frame + skip( code_end ) >> unarg( Make.animationTrigger )
animation_flattened = animation_expanded >> flatten >> flatten
animation_elem = animation
# Animation Modifier
animation_modifier = many( ( name | number ) + maybe( skip( operator(':') ) + number ) + skip( maybe( comma ) ) )
animation_modlist = animation_modifier >> Make.animationModlist
# Animation Capability
animation_capability = ( ( animation_def | animation_elem ) + maybe( skip( parenthesis('(') ) + animation_modifier + skip( parenthesis(')') ) ) ) >> unarg( Make.animationCapability )
# Capabilities
capFunc_argument = number >> Make.capArg # TODO Allow for symbolic arguments, i.e. arrays and variables
capFunc_arguments = many( capFunc_argument + skip( maybe( comma ) ) )
capFunc_elem = name + skip( parenthesis('(') ) + capFunc_arguments + skip( parenthesis(')') ) >> unarg( Make.capUsage ) >> listElem
capFunc_combo = oneplus( ( hidCode_elem | capFunc_elem | animation_capability | pixel_capability ) + skip( maybe( plus ) ) ) >> listElem
capFunc_sequence = oneplus( ( capFunc_combo | seqString ) + skip( maybe( comma ) ) ) >> oneLayerFlatten
# Trigger / Result Codes
triggerCode_outerList = scanCode_sequence >> optionExpansion
triggerUSBCode_outerList = usbCode_sequence >> optionExpansion
resultCode_outerList = ( ( capFunc_sequence >> optionExpansion ) | none )
# Positions
position_list = oneplus( position + skip( maybe( comma ) ) )