from functools import reduce
import re
strings = []
number_of_strings = -1
def top_level_split(s):
balance = 0
parts = []
part = ""
for i in range(len(s)):
c = s[i]
part += c
if c == '(':
balance += 1
elif c == ')':
balance -= 1
elif c == ',' and balance == 0 and not s[i+1] == ',':
part = part[:-1].strip()
parts.append(part)
part = ""
if len(part):
parts.append(part.strip())
return parts
def new_chord(on_pseudolayer, keycodes_hash, has_counter, value1, value2, function, output_buffer, index):
counter_link = "NULL"
output_buffer += "uint8_t state_" + str(index) + " = IDLE;\n"
if has_counter:
output_buffer += "uint8_t counter_" + str(index) + " = 0;\n"
counter_link = "&counter_" + str(index)
output_buffer += "const struct Chord chord_" + str(index) + " PROGMEM = {" + keycodes_hash + ", " + on_pseudolayer + ", &state_" + str(index) + ", " + counter_link + ", " + str(value1) + ", " + str(value2) + ", " + function + "};\n"
index += 1
return [output_buffer, index]
def KC(on_pseudolayer, keycodes_hash, keycode, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, keycode, 0, "single_dance", output_buffer, index)
def AS(on_pseudolayer, keycodes_hash, keycode, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, True, keycode, 0, "autoshift_dance", output_buffer, index)
def AT(on_pseudolayer, keycodes_hash, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, 0, 0, "autoshift_toggle", output_buffer, index)
def KL(on_pseudolayer, keycodes_hash, keycode, to_pseudolayer, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, True, keycode, to_pseudolayer, "key_layer_dance", output_buffer, index)
def KK(on_pseudolayer, keycodes_hash, keycode1, keycode2, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, True, keycode1, keycode2, "key_key_dance", output_buffer, index)
def KM(on_pseudolayer, keycodes_hash, keycode, to_pseudolayer, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, keycode, to_pseudolayer, "key_mod_dance", output_buffer, index)
def MO(on_pseudolayer, keycodes_hash, to_pseudolayer, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, to_pseudolayer, 0, "temp_pseudolayer", output_buffer, index)
def MO_alt(on_pseudolayer, keycodes_hash, from_pseudolayer, to_pseudolayer, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, to_pseudolayer, from_pseudolayer, "temp_pseudolayer_alt", output_buffer, index)
def LOCK(on_pseudolayer, keycodes_hash, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, 0, 0, "lock", output_buffer, index)
def DF(on_pseudolayer, keycodes_hash, to_pseudolayer, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, to_pseudolayer, 0, "perm_pseudolayer", output_buffer, index)
def TO(on_pseudolayer, keycodes_hash, to_pseudolayer, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, to_pseudolayer, 0, "switch_layer", output_buffer, index)
def OSK(on_pseudolayer, keycodes_hash, keycode, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, keycode, 0, "one_shot_key", output_buffer, index)
def OSL(on_pseudolayer, keycodes_hash, to_pseudolayer, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, to_pseudolayer, 0, "one_shot_layer", output_buffer, index)
def CMD(on_pseudolayer, keycodes_hash, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, 0, 0, "command", output_buffer, index)
def DM_RECORD(on_pseudolayer, keycodes_hash, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, 0, 0, "dynamic_macro_record", output_buffer, index)
def DM_NEXT(on_pseudolayer, keycodes_hash, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, 0, 0, "dynamic_macro_next", output_buffer, index)
def DM_END(on_pseudolayer, keycodes_hash, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, 0, 0, "dynamic_macro_end", output_buffer, index)
def DM_PLAY(on_pseudolayer, keycodes_hash, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, 0, 0, "dynamic_macro_play", output_buffer, index)
def LEAD(on_pseudolayer, keycodes_hash, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, 0, 0, "leader", output_buffer, index)
def CLEAR(on_pseudolayer, keycodes_hash, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, 0, 0, "clear", output_buffer, index)
def RESET(on_pseudolayer, keycodes_hash, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, False, 0, 0, "reset", output_buffer, index)
def STR(on_pseudolayer, keycodes_hash, string_input, output_buffer, index, number_of_strings, strings):
[a, b] = new_chord(on_pseudolayer, keycodes_hash, False, number_of_strings, 0, "string_in", output_buffer, index)
return [a, b, number_of_strings + 1, strings + [string_input]]
def M(on_pseudolayer, keycodes_hash, value1, value2, fnc, output_buffer, index):
return new_chord(on_pseudolayer, keycodes_hash, True, value1, value2, fnc, output_buffer, index)
def expand_keycode_fnc(DEFINITION):
if DEFINITION == "`":
DEFINITION = "GRAVE"
elif DEFINITION == "-":
DEFINITION = "MINUS"
elif DEFINITION == "=":
DEFINITION = "EQUAL"
elif DEFINITION == "[":
DEFINITION = "LBRACKET"
elif DEFINITION == "]":
DEFINITION = "RBRACKET"
elif DEFINITION == "\\":
DEFINITION = "BSLASH"
elif DEFINITION == ";":
DEFINITION = "SCOLON"
elif DEFINITION == "'":
DEFINITION = "QUOTE"
elif DEFINITION == ",":
DEFINITION = "COMMA"
elif DEFINITION == ".":
DEFINITION = "DOT"
elif DEFINITION == "/":
DEFINITION = "SLASH"
elif DEFINITION == "~":
DEFINITION = "TILDE"
elif DEFINITION == "*":
DEFINITION = "ASTERISK"
elif DEFINITION == "+":
DEFINITION = "PLUS"
elif DEFINITION == "(":
DEFINITION = "LEFT_PAREN"
elif DEFINITION == ")":
DEFINITION = "RIGHT_PAREN"
elif DEFINITION == "<":
DEFINITION = "LEFT_ANGLE_BRACKET"
elif DEFINITION == ">":
DEFINITION = "RIGHT_ANGLE_BRACKET"
elif DEFINITION == "{":
DEFINITION = "LEFT_CURLY_BRACE"
elif DEFINITION == "}":
DEFINITION = "RIGHT_CURLY_BRACE"
elif DEFINITION == "?":
DEFINITION = "QUESTION"
elif DEFINITION == "~":
DEFINITION = "TILDE"
elif DEFINITION == ":":
DEFINITION = "COLON"
elif DEFINITION == "_":
DEFINITION = "UNDERSCORE"
elif DEFINITION == '"':
DEFINITION = "DOUBLE_QUOTE"
elif DEFINITION == "@":
DEFINITION = "AT"
elif DEFINITION == "#":
DEFINITION = "HASH"
elif DEFINITION == "$":
DEFINITION = "DOLLAR"
elif DEFINITION == "!":
DEFINITION = "EXCLAIM"
elif DEFINITION == "%":
DEFINITION = "PERCENT"
elif DEFINITION == "^":
DEFINITION = "CIRCUMFLEX"
elif DEFINITION == "&":
DEFINITION = "AMPERSAND"
elif DEFINITION == "|":
DEFINITION = "PIPE"
if DEFINITION in [
"A", "a", "B", "b", "C", "c", "D", "d", "E", "e",
"F", "f", "G", "g", "H", "h", "I", "i", "J", "j",
"K", "k", "L", "l", "M", "m", "N", "n", "O", "o",
"P", "p", "Q", "q", "R", "r", "S", "s", "T", "t",
"U", "u", "V", "v", "W", "w", "X", "x", "Y", "y",
"Z", "z", "1", "2", "3", "4", "5", "6", "7", "8",
"9", "0", "F1", "F2", "F3", "F4", "F5", "F6", "F7",
"F8", "F9", "F10", "F11", "F12", "F13", "F14", "F15",
"F16", "F17", "F18", "F19", "F20", "F21", "F22",
"F23", "F24", "ENTER", "ENT", "ESCAPE", "ESC",
"BSPACE", "BSPC", "TAB", "SPACE", "SPC", "NONUS_HASH",
"NUHS", "NONUS_BSLASH", "NUBS", "COMMA", "COMM",
"DOT", "SLASH", "SLSH", "TILDE", "TILD", "EXCLAIM",
"EXLM", "AT", "HASH", "DOLLAR", "DLR", "PERCENT",
"PERC", "CIRCUMFLEX", "CIRC", "AMPERSAND", "AMPR",
"ASTERISK", "ASTR", "LEFT_PAREN", "LPRN", "RIGHT_PAREN",
"RPRN", "UNDERSCORE", "UNDS", "PLUS", "LEFT_CURLY_BRACE",
"LCBR", "RIGHT_CURLY_BRACE", "RCBR", "PIPE", "COLON",
"COLN", "DOUBLE_QUOTE", "DQUO", "DQT",
"LEFT_ANGLE_BRACKET", "LABK", "LT", "RIGHT_ANGLE_BRACKET",
"RABK", "GT", "QUESTION", "QUES", "SCOLON", "SCLN",
"QUOTE", "QUOT", "LBRACKET", "LBRC", "RBRACKET", "RBRC",
"BSLASH", "BSLS", "MINUS", "MINS", "EQUAL", "EQL",
"GRAVE", "GRV", "ZKHK", "CAPSLOCK", "CLCK", "CAPS",
"SCROLLOCK", "SLCK", "BRMD", "NUMLOCK", "NLCK",
"LOCKING_CAPS", "LCAP", "LOCKING_NUM", "LNUM",
"LOCKING_SCROLL", "LSCR", "LCTRL", "LCTL", "LSHIFT",
"LSFT", "LALT", "LGUI", "LCMD", "LWIN", "RCTRL",
"RCTL", "RSHIFT", "RSFT", "RALT", "RGUI", "RCMD",
"RWIN", "INT1", "RO", "INT2", "KANA", "INT3", "JYEN",
"INT4", "HENK", "INT5", "MHEN", "INT6", "INT7",
"INT8", "INT9", "LANG1", "HAEN", "LANG2", "HANJ",
"LANG3", "LANG4", "LANG5", "LANG6", "LANG7", "LANG8",
"LANG9", "PSCREEN", "PSCR", "PAUSE", "PAUS", "BRK",
"BRMU", "INSERT", "INS", "HOME", "PGUP", "DELETE",
"DEL", "END", "PGDOWN", "PGDN", "RIGHT", "RGHT",
"LEFT", "DOWN", "UP", "APPLICATION", "APP", "POWER",
"EXECUTE", "EXEC", "HELP", "MENU", "SELECT", "SLCT",
"STOP", "AGAIN", "AGIN", "UNDO", "CUT", "COPY",
"PASTE", "PSTE", "FIND", "MUTE", "VOLUP", "VOLDOWN",
"ALT_ERASE", "ERAS", "SYSREQ", "CANCEL", "CLEAR",
"CLR", "PRIOR", "RETURN", "SEPARATOR", "OUT", "OPER",
"CLEAR_AGAIN", "CRSEL", "EXSEL", "SYSTEM_POWER",
"PWR", "SYSTEM_SLEEP", "SLEP", "SYSTEM_WAKE", "WAKE",
"AUDIO_MUTE", "MUTE", "AUDIO_VOL_UP", "VOLU",
"AUDIO_VOL_DOWN", "VOLD", "MEDIA_NEXT_TRACK", "MNXT",
"MEDIA_PREV_TRACK", "MPRV", "CPRV", "MEDIA_STOP", "MSTP",
"MEDIA_PLAY_PAUSE", "MPLY", "MEDIA_SELECT", "MSEL",
"MEDIA_EJECT", "EJCT", "MAIL", "CALCULATOR", "CALC",
"MY_COMPUTER", "MYCM", "WWW_SEARCH", "WSCH", "WWW_HOME",
"WHOM", "WWW_BACK", "WBAK", "WWW_FORWARD", "WFWD",
"WWW_STOP", "WSTP", "WWW_REFRESH", "WREF",
"WWW_FAVORITES", "WFAV", "MEDIA_FAST_FORWARD", "MFFD",
"MEDIA_REWIND", "MRWD", "BRIGHTNESS_UP", "BRIU",
"BRIGHTNESS_DOWN", "BRID", "KP_SLASH", "PSLS",
"KP_ASTERISK", "PAST", "KP_MINUS", "PMNS", "KP_PLUS",
"PPLS", "KP_ENTER", "PENT", "KP_1", "P1", "KP_2", "P2",
"KP_3", "P3", "KP_4", "P4", "KP_5", "P5", "KP_6", "P6",
"KP_7", "P7", "KP_8", "P8", "KP_9", "P9", "KP_0", "P0",
"KP_DOT", "PDOT", "KP_EQUAL", "PEQL", "KP_COMMA", "PCMM",
"MS_BTN1", "BTN1", "MS_BTN2", "BTN2", "MS_BTN3", "BTN3",
"MS_BTN4", "BTN4", "MS_BTN5", "BTN5", "MS_BTN6", "BTN6",
"MS_LEFT", "MS_L", "MS_DOWN", "MS_D", "MS_UP", "MS_U",
"MS_RIGHT", "MS_R", "MS_WH_UP", "WH_U", "MS_WH_DOWN",
"WH_D", "MS_WH_LEFT", "MS_WH_L", "MS_WH_RIGHT", "MS_WH_R",
"KC_MS_ACCEL0", "ACL0", "KC_MS_ACCEL1", "ACL1",
"KC_MS_ACCEL2", "ACL2"
]:
return "KC_" + DEFINITION
else:
return DEFINITION
def MK(on_pseudolayer, keycodes_hash, definition, output_buffer, index):
l = len(definition.split(', '))
output_buffer += "void function_" + str(index) + "(const struct Chord* self) {\n"
output_buffer += " switch (*self->state) {\n"
output_buffer += " case ACTIVATED:\n"
for i in range(0, l):
val = definition.split(',')[i].strip()
code = expand_keycode_fnc(val)
output_buffer += " key_in(" + code + ");\n"
output_buffer += " break;\n"
output_buffer += " case DEACTIVATED:\n"
for i in range(0, l):
val = definition.split(',')[i].strip()
code = expand_keycode_fnc(val)
output_buffer += " key_out(" + code + ");\n"
output_buffer += " *self->state = IDLE;\n"
output_buffer += " break;\n"
output_buffer += " case RESTART:\n"
for i in range(0, l):
val = definition.split(',')[i].strip()
code = expand_keycode_fnc(val)
output_buffer += " key_out(" + code + ");\n"
output_buffer += " break;\n"
output_buffer += " default:\n"
output_buffer += " break;\n"
output_buffer += " };\n"
output_buffer += "}\n"
return new_chord(on_pseudolayer, keycodes_hash, True, 0, 0, "function_" + str(index), output_buffer, index)
def D(on_pseudolayer, keycodes_hash, DEFINITION, output_buffer, index):
l = len(DEFINITION.split(','))
output_buffer += "void function_" + str(index) + "(const struct Chord* self) {\n"
output_buffer += " switch (*self->state) {\n"
output_buffer += " case ACTIVATED:\n"
output_buffer += " *self->counter = *self->counter + 1;\n"
output_buffer += " break;\n"
output_buffer += " case PRESS_FROM_ACTIVE:\n"
output_buffer += " switch (*self->counter) {\n"
for i in range(0, l):
val = DEFINITION.split(',')[i].strip()
code = expand_keycode_fnc(val)
output_buffer += " case " + str(i + 1) + ":\n"
output_buffer += " key_in( " + code + ");\n"
output_buffer += " break;\n"
output_buffer += " default:\n"
output_buffer += " break;\n"
output_buffer += " }\n"
output_buffer += " *self->state = FINISHED_FROM_ACTIVE;\n"
output_buffer += " break;\n"
output_buffer += " case FINISHED:\n"
output_buffer += " switch (*self->counter) {\n"
for i in range(0, l):
val = DEFINITION.split(',')[i].strip()
code = expand_keycode_fnc(val)
output_buffer += " case " + str(i + 1) + ":\n"
output_buffer += " tap_key( " + code + ");\n"
output_buffer += " break;\n"
output_buffer += " default:\n"
output_buffer += " break;\n"
output_buffer += " }\n"
output_buffer += " *self->counter = 0;\n"
output_buffer += " *self->state = IDLE;\n"
output_buffer += " break;\n"
output_buffer += " case RESTART:\n"
output_buffer += " switch (*self->counter) {\n"
for i in range(0, l):
val = DEFINITION.split(',')[i].strip()
code = expand_keycode_fnc(val)
output_buffer += " case " + str(i + 1) + ":\n"
output_buffer += " key_out( " + code + ");\n"
output_buffer += " break;\n"
output_buffer += " default:\n"
output_buffer += " break;\n"
output_buffer += " }\n"
output_buffer += " *self->counter = 0;\n"
output_buffer += " break;\n"
output_buffer += " default:\n"
output_buffer += " break;\n"
output_buffer += " }\n"
output_buffer += "}\n"
return new_chord(on_pseudolayer, keycodes_hash, True, 0, 0, "function_" + str(index), output_buffer, index)
def O(on_pseudolayer, keycodes_hash, DEFINITION, output_buffer, index):
if DEFINITION[0:3] == "KC_":
return OSK(on_pseudolayer, keycodes_hash, DEFINITION, output_buffer, index)
else:
return OSL(on_pseudolayer, keycodes_hash, DEFINITION, output_buffer, index)
def add_key(PSEUDOLAYER, KEYCODES_HASH, DEFINITION, output_buffer, index, number_of_strings, strings):
if DEFINITION == "":
return [output_buffer, index, number_of_strings, strings]
else:
split = DEFINITION.split("(")
type = split[0].strip()
if len(split) == 1:
if type == "LOCK":
[output_buffer, index] = LOCK(PSEUDOLAYER, KEYCODES_HASH, output_buffer, index)
elif type == "AT":
[output_buffer, index] = AT(PSEUDOLAYER, KEYCODES_HASH, output_buffer, index)
elif type == "CMD":
[output_buffer, index] = CMD(PSEUDOLAYER, KEYCODES_HASH, output_buffer, index)
elif type == "LEAD":
[output_buffer, index] = LEAD(PSEUDOLAYER, KEYCODES_HASH, output_buffer, index)
elif type == "DM_RECORD":
[output_buffer, index] = DM_RECORD(PSEUDOLAYER, KEYCODES_HASH, output_buffer, index)
elif type == "DM_NEXT":
[output_buffer, index] = DM_NEXT(PSEUDOLAYER, KEYCODES_HASH, output_buffer, index)
elif type == "DM_END":
[output_buffer, index] = DM_END(PSEUDOLAYER, KEYCODES_HASH, output_buffer, index)
elif type == "DM_PLAY":
[output_buffer, index] = DM_PLAY(PSEUDOLAYER, KEYCODES_HASH, output_buffer, index)
elif type == "CLEAR_KB":
[output_buffer, index] = CLEAR(PSEUDOLAYER, KEYCODES_HASH, output_buffer, index)
elif type == "RESET":
[output_buffer, index] = RESET(PSEUDOLAYER, KEYCODES_HASH, output_buffer, index)
else:
code = expand_keycode_fnc(type)
[output_buffer, index] = KC(PSEUDOLAYER, KEYCODES_HASH, code, output_buffer, index)
else:
val = split[1][:-1].strip()
if type == "O":
code = expand_keycode_fnc(val)
[output_buffer, index] = O(PSEUDOLAYER, KEYCODES_HASH, code, output_buffer, index)
elif type == "D":
[output_buffer, index] = D(PSEUDOLAYER, KEYCODES_HASH, val, output_buffer, index)
elif type == "MK":
[output_buffer, index] = MK(PSEUDOLAYER, KEYCODES_HASH, val, output_buffer, index)
elif type == "M":
fnc = val.split(',')[0].strip()
val1 = val.split(',')[1].strip()
val2 = val.split(',')[2].strip()
[output_buffer, index] = M(PSEUDOLAYER, KEYCODES_HASH, val1, val2, fnc, output_buffer, index)
elif type == "KK":
val1 = val.split(',')[0].strip()
code1 = expand_keycode_fnc(val1)
val2 = val.split(',')[1].strip()
code2 = expand_keycode_fnc(val2)
[output_buffer, index] = KK(PSEUDOLAYER, KEYCODES_HASH, code1, code2, output_buffer, index)
elif type == "KL":
val1 = val.split(',')[0].strip()
code1 = expand_keycode_fnc(val1)
val2 = val.split(',')[1].strip()
[output_buffer, index] = KL(PSEUDOLAYER, KEYCODES_HASH, code1, val2, output_buffer, index)
elif type == "KM":
val1 = val.split(',')[0].strip()
code1 = expand_keycode_fnc(val1)
val2 = val.split(',')[1].strip()
code2 = expand_keycode_fnc(val2)
[output_buffer, index] = KM(PSEUDOLAYER, KEYCODES_HASH, code1, code2, output_buffer, index)
elif type == "AS":
code = expand_keycode_fnc(val)
[output_buffer, index] = AS(PSEUDOLAYER, KEYCODES_HASH, code, output_buffer, index)
elif type == "MO":
if not ',' in val:
[output_buffer, index] = MO(PSEUDOLAYER, KEYCODES_HASH, val, output_buffer, index)
else:
val1 = val.split(',')[0].strip()
val2 = val.split(',')[1].strip()
[output_buffer, index] = MO_alt(PSEUDOLAYER, KEYCODES_HASH, val1, val2, output_buffer, index)
elif type == "DF":
[output_buffer, index] = DF(PSEUDOLAYER, KEYCODES_HASH, val, output_buffer, index)
elif type == "TO":
[output_buffer, index] = TO(PSEUDOLAYER, KEYCODES_HASH, val, output_buffer, index)
elif type == "STR":
[output_buffer, index, number_of_strings, strings] = STR(PSEUDOLAYER, KEYCODES_HASH, val, output_buffer, index, number_of_strings, strings)
return [output_buffer, index, number_of_strings, strings]
def add_leader_combo(DEFINITION, FUNCTION):
return list_of_leader_combos.append([DEFINITION, FUNCTION])
def add_chord_set(PSEUDOLAYER, INPUT_STRING, TYPE, data, output_buffer, index, number_of_strings, strings):
chord_set = {}
for set in data["chord_sets"]:
if set["name"] == TYPE:
chord_set = set["chords"]
break
separated_string = top_level_split(INPUT_STRING)
for word, chord in zip(separated_string, chord_set):
chord_hash = reduce((lambda x, y: str(x) + " + " + str(y)), ["H_" + key for key in chord])
[output_buffer, index, number_of_strings, strings] = add_key(PSEUDOLAYER, chord_hash, word, output_buffer, index, number_of_strings, strings)
return [output_buffer, index, number_of_strings, strings]
def add_dictionary(PSEUDOLAYER, keycodes, array, output_buffer, index, number_of_strings, strings):
for chord in array:
hash = ""
for word, key in zip(chord[:-1], keycodes):
if word == "X":
hash = hash + " + H_" + key
hash = hash[3:]
if hash != "":
[output_buffer, index, number_of_strings, strings] = add_key(PSEUDOLAYER, hash, chord[-1], output_buffer, index, number_of_strings, strings)
return [output_buffer, index, number_of_strings, strings]
def secret_chord(PSEUDOLAYER, ACTION, INPUT_STRING, data, output_buffer, index, number_of_strings, strings):
separated_string = top_level_split(INPUT_STRING)
hash = ""
for word, key in zip(separated_string, data["keys"]):
if word == "X":
hash = hash + " + H_" + key
hash = hash[3:]
if hash != "":
return add_key(PSEUDOLAYER, hash, ACTION, output_buffer, index, number_of_strings, strings)