Current File : //lib/python3/dist-packages/twisted/conch/test/test_insults.py
# -*- test-case-name: twisted.conch.test.test_insults -*-
# Copyright (c) Twisted Matrix Laboratories.
# See LICENSE for details.
import textwrap
from typing import Optional, Type
from twisted.conch.insults.insults import (
BLINK,
CS_ALTERNATE,
CS_ALTERNATE_SPECIAL,
CS_DRAWING,
CS_UK,
CS_US,
G0,
G1,
UNDERLINE,
ClientProtocol,
ServerProtocol,
modes,
privateModes,
)
from twisted.internet.protocol import Protocol
from twisted.internet.testing import StringTransport
from twisted.python.compat import iterbytes
from twisted.python.constants import ValueConstant, Values
from twisted.trial import unittest
def _getattr(mock, name):
return super(Mock, mock).__getattribute__(name)
def occurrences(mock):
return _getattr(mock, "occurrences")
def methods(mock):
return _getattr(mock, "methods")
def _append(mock, obj):
occurrences(mock).append(obj)
default = object()
def _ecmaCodeTableCoordinate(column, row):
"""
Return the byte in 7- or 8-bit code table identified by C{column}
and C{row}.
"An 8-bit code table consists of 256 positions arranged in 16
columns and 16 rows. The columns and rows are numbered 00 to 15."
"A 7-bit code table consists of 128 positions arranged in 8
columns and 16 rows. The columns are numbered 00 to 07 and the
rows 00 to 15 (see figure 1)."
p.5 of "Standard ECMA-35: Character Code Structure and Extension
Techniques", 6th Edition (December 1994).
"""
# 8 and 15 both happen to take up 4 bits, so the first number
# should be shifted by 4 for both the 7- and 8-bit tables.
return bytes(bytearray([(column << 4) | row]))
def _makeControlFunctionSymbols(name, colOffset, names, doc):
# the value for each name is the concatenation of the bit values
# of its x, y locations, with an offset of 4 added to its x value.
# so CUP is (0 + 4, 8) = (4, 8) = 4||8 = 1001000 = 72 = b"H"
# this is how it's defined in the standard!
attrs = {
name: ValueConstant(_ecmaCodeTableCoordinate(i + colOffset, j))
for j, row in enumerate(names)
for i, name in enumerate(row)
if name
}
attrs["__doc__"] = doc
return type(name, (Values,), attrs)
CSFinalByte = _makeControlFunctionSymbols(
"CSFinalByte",
colOffset=4,
names=[
# 4, 5, 6
["ICH", "DCH", "HPA"],
["CUU", "SSE", "HPR"],
["CUD", "CPR", "REP"],
["CUF", "SU", "DA"],
["CUB", "SD", "VPA"],
["CNL", "NP", "VPR"],
["CPL", "PP", "HVP"],
["CHA", "CTC", "TBC"],
["CUP", "ECH", "SM"],
["CHT", "CVT", "MC"],
["ED", "CBT", "HPB"],
["EL", "SRS", "VPB"],
["IL", "PTX", "RM"],
["DL", "SDS", "SGR"],
["EF", "SIMD", "DSR"],
["EA", None, "DAQ"],
],
doc=textwrap.dedent(
"""
Symbolic constants for all control sequence final bytes
that do not imply intermediate bytes. This happens to cover
movement control sequences.
See page 11 of "Standard ECMA 48: Control Functions for Coded
Character Sets", 5th Edition (June 1991).
Each L{ValueConstant} maps a control sequence name to L{bytes}
"""
),
)
C1SevenBit = _makeControlFunctionSymbols(
"C1SevenBit",
colOffset=4,
names=[
[None, "DCS"],
[None, "PU1"],
["BPH", "PU2"],
["NBH", "STS"],
[None, "CCH"],
["NEL", "MW"],
["SSA", "SPA"],
["ESA", "EPA"],
["HTS", "SOS"],
["HTJ", None],
["VTS", "SCI"],
["PLD", "CSI"],
["PLU", "ST"],
["RI", "OSC"],
["SS2", "PM"],
["SS3", "APC"],
],
doc=textwrap.dedent(
"""
Symbolic constants for all 7 bit versions of the C1 control functions
See page 9 "Standard ECMA 48: Control Functions for Coded
Character Sets", 5th Edition (June 1991).
Each L{ValueConstant} maps a control sequence name to L{bytes}
"""
),
)
class Mock:
callReturnValue = default
def __init__(self, methods=None, callReturnValue=default):
"""
@param methods: Mapping of names to return values
@param callReturnValue: object __call__ should return
"""
self.occurrences = []
if methods is None:
methods = {}
self.methods = methods
if callReturnValue is not default:
self.callReturnValue = callReturnValue
def __call__(self, *a, **kw):
returnValue = _getattr(self, "callReturnValue")
if returnValue is default:
returnValue = Mock()
# _getattr(self, 'occurrences').append(('__call__', returnValue, a, kw))
_append(self, ("__call__", returnValue, a, kw))
return returnValue
def __getattribute__(self, name):
methods = _getattr(self, "methods")
if name in methods:
attrValue = Mock(callReturnValue=methods[name])
else:
attrValue = Mock()
# _getattr(self, 'occurrences').append((name, attrValue))
_append(self, (name, attrValue))
return attrValue
class MockMixin:
def assertCall(
self, occurrence, methodName, expectedPositionalArgs=(), expectedKeywordArgs={}
):
attr, mock = occurrence
self.assertEqual(attr, methodName)
self.assertEqual(len(occurrences(mock)), 1)
[(call, result, args, kw)] = occurrences(mock)
self.assertEqual(call, "__call__")
self.assertEqual(args, expectedPositionalArgs)
self.assertEqual(kw, expectedKeywordArgs)
return result
_byteGroupingTestTemplate = """\
def testByte%(groupName)s(self):
transport = StringTransport()
proto = Mock()
parser = self.protocolFactory(lambda: proto)
parser.factory = self
parser.makeConnection(transport)
bytes = self.TEST_BYTES
while bytes:
chunk = bytes[:%(bytesPer)d]
bytes = bytes[%(bytesPer)d:]
parser.dataReceived(chunk)
self.verifyResults(transport, proto, parser)
"""
class ByteGroupingsMixin(MockMixin):
protocolFactory: Optional[Type[Protocol]] = None
for word, n in [
("Pairs", 2),
("Triples", 3),
("Quads", 4),
("Quints", 5),
("Sexes", 6),
]:
exec(_byteGroupingTestTemplate % {"groupName": word, "bytesPer": n})
del word, n
def verifyResults(self, transport, proto, parser):
result = self.assertCall(occurrences(proto).pop(0), "makeConnection", (parser,))
self.assertEqual(occurrences(result), [])
del _byteGroupingTestTemplate
class ServerArrowKeysTests(ByteGroupingsMixin, unittest.TestCase):
protocolFactory = ServerProtocol
# All the arrow keys once
TEST_BYTES = b"\x1b[A\x1b[B\x1b[C\x1b[D"
def verifyResults(self, transport, proto, parser):
ByteGroupingsMixin.verifyResults(self, transport, proto, parser)
for arrow in (
parser.UP_ARROW,
parser.DOWN_ARROW,
parser.RIGHT_ARROW,
parser.LEFT_ARROW,
):
result = self.assertCall(
occurrences(proto).pop(0), "keystrokeReceived", (arrow, None)
)
self.assertEqual(occurrences(result), [])
self.assertFalse(occurrences(proto))
class PrintableCharactersTests(ByteGroupingsMixin, unittest.TestCase):
protocolFactory = ServerProtocol
# Some letters and digits, first on their own, then capitalized,
# then modified with alt
TEST_BYTES = b"abc123ABC!@#\x1ba\x1bb\x1bc\x1b1\x1b2\x1b3"
def verifyResults(self, transport, proto, parser):
ByteGroupingsMixin.verifyResults(self, transport, proto, parser)
for char in iterbytes(b"abc123ABC!@#"):
result = self.assertCall(
occurrences(proto).pop(0), "keystrokeReceived", (char, None)
)
self.assertEqual(occurrences(result), [])
for char in iterbytes(b"abc123"):
result = self.assertCall(
occurrences(proto).pop(0), "keystrokeReceived", (char, parser.ALT)
)
self.assertEqual(occurrences(result), [])
occs = occurrences(proto)
self.assertFalse(occs, f"{occs!r} should have been []")
class ServerFunctionKeysTests(ByteGroupingsMixin, unittest.TestCase):
"""Test for parsing and dispatching function keys (F1 - F12)"""
protocolFactory = ServerProtocol
byteList = []
for byteCodes in (
b"OP",
b"OQ",
b"OR",
b"OS", # F1 - F4
b"15~",
b"17~",
b"18~",
b"19~", # F5 - F8
b"20~",
b"21~",
b"23~",
b"24~",
): # F9 - F12
byteList.append(b"\x1b[" + byteCodes)
TEST_BYTES = b"".join(byteList)
del byteList, byteCodes
def verifyResults(self, transport, proto, parser):
ByteGroupingsMixin.verifyResults(self, transport, proto, parser)
for funcNum in range(1, 13):
funcArg = getattr(parser, "F%d" % (funcNum,))
result = self.assertCall(
occurrences(proto).pop(0), "keystrokeReceived", (funcArg, None)
)
self.assertEqual(occurrences(result), [])
self.assertFalse(occurrences(proto))
class ClientCursorMovementTests(ByteGroupingsMixin, unittest.TestCase):
protocolFactory = ClientProtocol
d2 = b"\x1b[2B"
r4 = b"\x1b[4C"
u1 = b"\x1b[A"
l2 = b"\x1b[2D"
# Move the cursor down two, right four, up one, left two, up one, left two
TEST_BYTES = d2 + r4 + u1 + l2 + u1 + l2
del d2, r4, u1, l2
def verifyResults(self, transport, proto, parser):
ByteGroupingsMixin.verifyResults(self, transport, proto, parser)
for method, count in [
("Down", 2),
("Forward", 4),
("Up", 1),
("Backward", 2),
("Up", 1),
("Backward", 2),
]:
result = self.assertCall(
occurrences(proto).pop(0), "cursor" + method, (count,)
)
self.assertEqual(occurrences(result), [])
self.assertFalse(occurrences(proto))
class ClientControlSequencesTests(unittest.TestCase, MockMixin):
def setUp(self):
self.transport = StringTransport()
self.proto = Mock()
self.parser = ClientProtocol(lambda: self.proto)
self.parser.factory = self
self.parser.makeConnection(self.transport)
result = self.assertCall(
occurrences(self.proto).pop(0), "makeConnection", (self.parser,)
)
self.assertFalse(occurrences(result))
def testSimpleCardinals(self):
self.parser.dataReceived(
b"".join(
b"\x1b[" + n + ch
for ch in iterbytes(b"BACD")
for n in (b"", b"2", b"20", b"200")
)
)
occs = occurrences(self.proto)
for meth in ("Down", "Up", "Forward", "Backward"):
for count in (1, 2, 20, 200):
result = self.assertCall(occs.pop(0), "cursor" + meth, (count,))
self.assertFalse(occurrences(result))
self.assertFalse(occs)
def testScrollRegion(self):
self.parser.dataReceived(b"\x1b[5;22r\x1b[r")
occs = occurrences(self.proto)
result = self.assertCall(occs.pop(0), "setScrollRegion", (5, 22))
self.assertFalse(occurrences(result))
result = self.assertCall(occs.pop(0), "setScrollRegion", (None, None))
self.assertFalse(occurrences(result))
self.assertFalse(occs)
def testHeightAndWidth(self):
self.parser.dataReceived(b"\x1b#3\x1b#4\x1b#5\x1b#6")
occs = occurrences(self.proto)
result = self.assertCall(occs.pop(0), "doubleHeightLine", (True,))
self.assertFalse(occurrences(result))
result = self.assertCall(occs.pop(0), "doubleHeightLine", (False,))
self.assertFalse(occurrences(result))
result = self.assertCall(occs.pop(0), "singleWidthLine")
self.assertFalse(occurrences(result))
result = self.assertCall(occs.pop(0), "doubleWidthLine")
self.assertFalse(occurrences(result))
self.assertFalse(occs)
def testCharacterSet(self):
self.parser.dataReceived(
b"".join(
[
b"".join([b"\x1b" + g + n for n in iterbytes(b"AB012")])
for g in iterbytes(b"()")
]
)
)
occs = occurrences(self.proto)
for which in (G0, G1):
for charset in (
CS_UK,
CS_US,
CS_DRAWING,
CS_ALTERNATE,
CS_ALTERNATE_SPECIAL,
):
result = self.assertCall(
occs.pop(0), "selectCharacterSet", (charset, which)
)
self.assertFalse(occurrences(result))
self.assertFalse(occs)
def testShifting(self):
self.parser.dataReceived(b"\x15\x14")
occs = occurrences(self.proto)
result = self.assertCall(occs.pop(0), "shiftIn")
self.assertFalse(occurrences(result))
result = self.assertCall(occs.pop(0), "shiftOut")
self.assertFalse(occurrences(result))
self.assertFalse(occs)
def testSingleShifts(self):
self.parser.dataReceived(b"\x1bN\x1bO")
occs = occurrences(self.proto)
result = self.assertCall(occs.pop(0), "singleShift2")
self.assertFalse(occurrences(result))
result = self.assertCall(occs.pop(0), "singleShift3")
self.assertFalse(occurrences(result))
self.assertFalse(occs)
def testKeypadMode(self):
self.parser.dataReceived(b"\x1b=\x1b>")
occs = occurrences(self.proto)
result = self.assertCall(occs.pop(0), "applicationKeypadMode")
self.assertFalse(occurrences(result))
result = self.assertCall(occs.pop(0), "numericKeypadMode")
self.assertFalse(occurrences(result))
self.assertFalse(occs)
def testCursor(self):
self.parser.dataReceived(b"\x1b7\x1b8")
occs = occurrences(self.proto)
result = self.assertCall(occs.pop(0), "saveCursor")
self.assertFalse(occurrences(result))
result = self.assertCall(occs.pop(0), "restoreCursor")
self.assertFalse(occurrences(result))
self.assertFalse(occs)
def testReset(self):
self.parser.dataReceived(b"\x1bc")
occs = occurrences(self.proto)
result = self.assertCall(occs.pop(0), "reset")
self.assertFalse(occurrences(result))
self.assertFalse(occs)
def testIndex(self):
self.parser.dataReceived(b"\x1bD\x1bM\x1bE")
occs = occurrences(self.proto)
result = self.assertCall(occs.pop(0), "index")
self.assertFalse(occurrences(result))
result = self.assertCall(occs.pop(0), "reverseIndex")
self.assertFalse(occurrences(result))
result = self.assertCall(occs.pop(0), "nextLine")
self.assertFalse(occurrences(result))
self.assertFalse(occs)
def testModes(self):
self.parser.dataReceived(
b"\x1b["
+ b";".join(b"%d" % (m,) for m in [modes.KAM, modes.IRM, modes.LNM])
+ b"h"
)
self.parser.dataReceived(
b"\x1b["
+ b";".join(b"%d" % (m,) for m in [modes.KAM, modes.IRM, modes.LNM])
+ b"l"
)
occs = occurrences(self.proto)
result = self.assertCall(
occs.pop(0), "setModes", ([modes.KAM, modes.IRM, modes.LNM],)
)
self.assertFalse(occurrences(result))
result = self.assertCall(
occs.pop(0), "resetModes", ([modes.KAM, modes.IRM, modes.LNM],)
)
self.assertFalse(occurrences(result))
self.assertFalse(occs)
def testErasure(self):
self.parser.dataReceived(b"\x1b[K\x1b[1K\x1b[2K\x1b[J\x1b[1J\x1b[2J\x1b[3P")
occs = occurrences(self.proto)
for meth in (
"eraseToLineEnd",
"eraseToLineBeginning",
"eraseLine",
"eraseToDisplayEnd",
"eraseToDisplayBeginning",
"eraseDisplay",
):
result = self.assertCall(occs.pop(0), meth)
self.assertFalse(occurrences(result))
result = self.assertCall(occs.pop(0), "deleteCharacter", (3,))
self.assertFalse(occurrences(result))
self.assertFalse(occs)
def testLineDeletion(self):
self.parser.dataReceived(b"\x1b[M\x1b[3M")
occs = occurrences(self.proto)
for arg in (1, 3):
result = self.assertCall(occs.pop(0), "deleteLine", (arg,))
self.assertFalse(occurrences(result))
self.assertFalse(occs)
def testLineInsertion(self):
self.parser.dataReceived(b"\x1b[L\x1b[3L")
occs = occurrences(self.proto)
for arg in (1, 3):
result = self.assertCall(occs.pop(0), "insertLine", (arg,))
self.assertFalse(occurrences(result))
self.assertFalse(occs)
def testCursorPosition(self):
methods(self.proto)["reportCursorPosition"] = (6, 7)
self.parser.dataReceived(b"\x1b[6n")
self.assertEqual(self.transport.value(), b"\x1b[7;8R")
occs = occurrences(self.proto)
result = self.assertCall(occs.pop(0), "reportCursorPosition")
# This isn't really an interesting assert, since it only tests that
# our mock setup is working right, but I'll include it anyway.
self.assertEqual(result, (6, 7))
def test_applicationDataBytes(self):
"""
Contiguous non-control bytes are passed to a single call to the
C{write} method of the terminal to which the L{ClientProtocol} is
connected.
"""
occs = occurrences(self.proto)
self.parser.dataReceived(b"a")
self.assertCall(occs.pop(0), "write", (b"a",))
self.parser.dataReceived(b"bc")
self.assertCall(occs.pop(0), "write", (b"bc",))
def _applicationDataTest(self, data, calls):
occs = occurrences(self.proto)
self.parser.dataReceived(data)
while calls:
self.assertCall(occs.pop(0), *calls.pop(0))
self.assertFalse(occs, f"No other calls should happen: {occs!r}")
def test_shiftInAfterApplicationData(self):
"""
Application data bytes followed by a shift-in command are passed to a
call to C{write} before the terminal's C{shiftIn} method is called.
"""
self._applicationDataTest(b"ab\x15", [("write", (b"ab",)), ("shiftIn",)])
def test_shiftOutAfterApplicationData(self):
"""
Application data bytes followed by a shift-out command are passed to a
call to C{write} before the terminal's C{shiftOut} method is called.
"""
self._applicationDataTest(b"ab\x14", [("write", (b"ab",)), ("shiftOut",)])
def test_cursorBackwardAfterApplicationData(self):
"""
Application data bytes followed by a cursor-backward command are passed
to a call to C{write} before the terminal's C{cursorBackward} method is
called.
"""
self._applicationDataTest(b"ab\x08", [("write", (b"ab",)), ("cursorBackward",)])
def test_escapeAfterApplicationData(self):
"""
Application data bytes followed by an escape character are passed to a
call to C{write} before the terminal's handler method for the escape is
called.
"""
# Test a short escape
self._applicationDataTest(b"ab\x1bD", [("write", (b"ab",)), ("index",)])
# And a long escape
self._applicationDataTest(
b"ab\x1b[4h", [("write", (b"ab",)), ("setModes", ([4],))]
)
# There's some other cases too, but they're all handled by the same
# codepaths as above.
class ServerProtocolOutputTests(unittest.TestCase):
"""
Tests for the bytes L{ServerProtocol} writes to its transport when its
methods are called.
"""
# From ECMA 48: CSI is represented by bit combinations 01/11
# (representing ESC) and 05/11 in a 7-bit code or by bit
# combination 09/11 in an 8-bit code
ESC = _ecmaCodeTableCoordinate(1, 11)
CSI = ESC + _ecmaCodeTableCoordinate(5, 11)
def setUp(self):
self.protocol = ServerProtocol()
self.transport = StringTransport()
self.protocol.makeConnection(self.transport)
def test_cursorUp(self):
"""
L{ServerProtocol.cursorUp} writes the control sequence
ending with L{CSFinalByte.CUU} to its transport.
"""
self.protocol.cursorUp(1)
self.assertEqual(
self.transport.value(), self.CSI + b"1" + CSFinalByte.CUU.value
)
def test_cursorDown(self):
"""
L{ServerProtocol.cursorDown} writes the control sequence
ending with L{CSFinalByte.CUD} to its transport.
"""
self.protocol.cursorDown(1)
self.assertEqual(
self.transport.value(), self.CSI + b"1" + CSFinalByte.CUD.value
)
def test_cursorForward(self):
"""
L{ServerProtocol.cursorForward} writes the control sequence
ending with L{CSFinalByte.CUF} to its transport.
"""
self.protocol.cursorForward(1)
self.assertEqual(
self.transport.value(), self.CSI + b"1" + CSFinalByte.CUF.value
)
def test_cursorBackward(self):
"""
L{ServerProtocol.cursorBackward} writes the control sequence
ending with L{CSFinalByte.CUB} to its transport.
"""
self.protocol.cursorBackward(1)
self.assertEqual(
self.transport.value(), self.CSI + b"1" + CSFinalByte.CUB.value
)
def test_cursorPosition(self):
"""
L{ServerProtocol.cursorPosition} writes a control sequence
ending with L{CSFinalByte.CUP} and containing the expected
coordinates to its transport.
"""
self.protocol.cursorPosition(0, 0)
self.assertEqual(
self.transport.value(), self.CSI + b"1;1" + CSFinalByte.CUP.value
)
def test_cursorHome(self):
"""
L{ServerProtocol.cursorHome} writes a control sequence ending
with L{CSFinalByte.CUP} and no parameters, so that the client
defaults to (1, 1).
"""
self.protocol.cursorHome()
self.assertEqual(self.transport.value(), self.CSI + CSFinalByte.CUP.value)
def test_index(self):
"""
L{ServerProtocol.index} writes the control sequence ending in
the 8-bit code table coordinates 4, 4.
Note that ECMA48 5th Edition removes C{IND}.
"""
self.protocol.index()
self.assertEqual(
self.transport.value(), self.ESC + _ecmaCodeTableCoordinate(4, 4)
)
def test_reverseIndex(self):
"""
L{ServerProtocol.reverseIndex} writes the control sequence
ending in the L{C1SevenBit.RI}.
"""
self.protocol.reverseIndex()
self.assertEqual(self.transport.value(), self.ESC + C1SevenBit.RI.value)
def test_nextLine(self):
"""
L{ServerProtocol.nextLine} writes C{"\r\n"} to its transport.
"""
# Why doesn't it write ESC E? Because ESC E is poorly supported. For
# example, gnome-terminal (many different versions) fails to scroll if
# it receives ESC E and the cursor is already on the last row.
self.protocol.nextLine()
self.assertEqual(self.transport.value(), b"\r\n")
def test_setModes(self):
"""
L{ServerProtocol.setModes} writes a control sequence
containing the requested modes and ending in the
L{CSFinalByte.SM}.
"""
modesToSet = [modes.KAM, modes.IRM, modes.LNM]
self.protocol.setModes(modesToSet)
self.assertEqual(
self.transport.value(),
self.CSI
+ b";".join(b"%d" % (m,) for m in modesToSet)
+ CSFinalByte.SM.value,
)
def test_setPrivateModes(self):
"""
L{ServerProtocol.setPrivatesModes} writes a control sequence
containing the requested private modes and ending in the
L{CSFinalByte.SM}.
"""
privateModesToSet = [
privateModes.ERROR,
privateModes.COLUMN,
privateModes.ORIGIN,
]
self.protocol.setModes(privateModesToSet)
self.assertEqual(
self.transport.value(),
self.CSI
+ b";".join(b"%d" % (m,) for m in privateModesToSet)
+ CSFinalByte.SM.value,
)
def test_resetModes(self):
"""
L{ServerProtocol.resetModes} writes the control sequence
ending in the L{CSFinalByte.RM}.
"""
modesToSet = [modes.KAM, modes.IRM, modes.LNM]
self.protocol.resetModes(modesToSet)
self.assertEqual(
self.transport.value(),
self.CSI
+ b";".join(b"%d" % (m,) for m in modesToSet)
+ CSFinalByte.RM.value,
)
def test_singleShift2(self):
"""
L{ServerProtocol.singleShift2} writes an escape sequence
followed by L{C1SevenBit.SS2}
"""
self.protocol.singleShift2()
self.assertEqual(self.transport.value(), self.ESC + C1SevenBit.SS2.value)
def test_singleShift3(self):
"""
L{ServerProtocol.singleShift3} writes an escape sequence
followed by L{C1SevenBit.SS3}
"""
self.protocol.singleShift3()
self.assertEqual(self.transport.value(), self.ESC + C1SevenBit.SS3.value)
def test_selectGraphicRendition(self):
"""
L{ServerProtocol.selectGraphicRendition} writes a control
sequence containing the requested attributes and ending with
L{CSFinalByte.SGR}
"""
self.protocol.selectGraphicRendition(str(BLINK), str(UNDERLINE))
self.assertEqual(
self.transport.value(),
self.CSI + b"%d;%d" % (BLINK, UNDERLINE) + CSFinalByte.SGR.value,
)
def test_horizontalTabulationSet(self):
"""
L{ServerProtocol.horizontalTabulationSet} writes the escape
sequence ending in L{C1SevenBit.HTS}
"""
self.protocol.horizontalTabulationSet()
self.assertEqual(self.transport.value(), self.ESC + C1SevenBit.HTS.value)
def test_eraseToLineEnd(self):
"""
L{ServerProtocol.eraseToLineEnd} writes the control sequence
sequence ending in L{CSFinalByte.EL} and no parameters,
forcing the client to default to 0 (from the active present
position's current location to the end of the line.)
"""
self.protocol.eraseToLineEnd()
self.assertEqual(self.transport.value(), self.CSI + CSFinalByte.EL.value)
def test_eraseToLineBeginning(self):
"""
L{ServerProtocol.eraseToLineBeginning} writes the control
sequence sequence ending in L{CSFinalByte.EL} and a parameter
of 1 (from the beginning of the line up to and include the
active present position's current location.)
"""
self.protocol.eraseToLineBeginning()
self.assertEqual(self.transport.value(), self.CSI + b"1" + CSFinalByte.EL.value)
def test_eraseLine(self):
"""
L{ServerProtocol.eraseLine} writes the control
sequence sequence ending in L{CSFinalByte.EL} and a parameter
of 2 (the entire line.)
"""
self.protocol.eraseLine()
self.assertEqual(self.transport.value(), self.CSI + b"2" + CSFinalByte.EL.value)
def test_eraseToDisplayEnd(self):
"""
L{ServerProtocol.eraseToDisplayEnd} writes the control
sequence sequence ending in L{CSFinalByte.ED} and no parameters,
forcing the client to default to 0 (from the active present
position's current location to the end of the page.)
"""
self.protocol.eraseToDisplayEnd()
self.assertEqual(self.transport.value(), self.CSI + CSFinalByte.ED.value)
def test_eraseToDisplayBeginning(self):
"""
L{ServerProtocol.eraseToDisplayBeginning} writes the control
sequence sequence ending in L{CSFinalByte.ED} a parameter of 1
(from the beginning of the page up to and include the active
present position's current location.)
"""
self.protocol.eraseToDisplayBeginning()
self.assertEqual(self.transport.value(), self.CSI + b"1" + CSFinalByte.ED.value)
def test_eraseToDisplay(self):
"""
L{ServerProtocol.eraseDisplay} writes the control sequence
sequence ending in L{CSFinalByte.ED} a parameter of 2 (the
entire page)
"""
self.protocol.eraseDisplay()
self.assertEqual(self.transport.value(), self.CSI + b"2" + CSFinalByte.ED.value)
def test_deleteCharacter(self):
"""
L{ServerProtocol.deleteCharacter} writes the control sequence
containing the number of characters to delete and ending in
L{CSFinalByte.DCH}
"""
self.protocol.deleteCharacter(4)
self.assertEqual(
self.transport.value(), self.CSI + b"4" + CSFinalByte.DCH.value
)
def test_insertLine(self):
"""
L{ServerProtocol.insertLine} writes the control sequence
containing the number of lines to insert and ending in
L{CSFinalByte.IL}
"""
self.protocol.insertLine(5)
self.assertEqual(self.transport.value(), self.CSI + b"5" + CSFinalByte.IL.value)
def test_deleteLine(self):
"""
L{ServerProtocol.deleteLine} writes the control sequence
containing the number of lines to delete and ending in
L{CSFinalByte.DL}
"""
self.protocol.deleteLine(6)
self.assertEqual(self.transport.value(), self.CSI + b"6" + CSFinalByte.DL.value)
def test_setScrollRegionNoArgs(self):
"""
With no arguments, L{ServerProtocol.setScrollRegion} writes a
control sequence with no parameters, but a parameter
separator, and ending in C{b'r'}.
"""
self.protocol.setScrollRegion()
self.assertEqual(self.transport.value(), self.CSI + b";" + b"r")
def test_setScrollRegionJustFirst(self):
"""
With just a value for its C{first} argument,
L{ServerProtocol.setScrollRegion} writes a control sequence with
that parameter, a parameter separator, and finally a C{b'r'}.
"""
self.protocol.setScrollRegion(first=1)
self.assertEqual(self.transport.value(), self.CSI + b"1;" + b"r")
def test_setScrollRegionJustLast(self):
"""
With just a value for its C{last} argument,
L{ServerProtocol.setScrollRegion} writes a control sequence with
a parameter separator, that parameter, and finally a C{b'r'}.
"""
self.protocol.setScrollRegion(last=1)
self.assertEqual(self.transport.value(), self.CSI + b";1" + b"r")
def test_setScrollRegionFirstAndLast(self):
"""
When given both C{first} and C{last}
L{ServerProtocol.setScrollRegion} writes a control sequence with
the first parameter, a parameter separator, the last
parameter, and finally a C{b'r'}.
"""
self.protocol.setScrollRegion(first=1, last=2)
self.assertEqual(self.transport.value(), self.CSI + b"1;2" + b"r")
def test_reportCursorPosition(self):
"""
L{ServerProtocol.reportCursorPosition} writes a control
sequence ending in L{CSFinalByte.DSR} with a parameter of 6
(the Device Status Report returns the current active
position.)
"""
self.protocol.reportCursorPosition()
self.assertEqual(
self.transport.value(), self.CSI + b"6" + CSFinalByte.DSR.value
)
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