Shofel2_T124_python/venv/lib/python3.10/site-packages/asciimatics/widgets/utilities.py

262 lines
12 KiB
Python
Raw Permalink Normal View History

2024-05-25 16:45:07 +00:00
# -*- coding: utf-8 -*-
"""This module defines commonly used pieces for widgets"""
from __future__ import division
from __future__ import absolute_import
from __future__ import print_function
from __future__ import unicode_literals
from logging import getLogger
from math import sqrt
from builtins import str
from collections import defaultdict
from wcwidth import wcswidth, wcwidth
try:
from functools import lru_cache
except ImportError:
from backports.functools_lru_cache import lru_cache
from asciimatics.screen import Screen
# Logging
logger = getLogger(__name__)
#: Standard palettes for use with :py:meth:`~Frame.set_theme`.
#: Each entry in THEMES contains a colour palette for use by the widgets within a Frame.
#: Each colour palette is a dictionary mapping a colour key to a 3-tuple of
#: (foreground colour, attribute, background colour).
#: The "default" theme defines all the required keys for a palette.
THEMES = {
"default": {
"background": (Screen.COLOUR_WHITE, Screen.A_NORMAL, Screen.COLOUR_BLUE),
"shadow": (Screen.COLOUR_BLACK, None, Screen.COLOUR_BLACK),
"disabled": (Screen.COLOUR_BLACK, Screen.A_BOLD, Screen.COLOUR_BLUE),
"invalid": (Screen.COLOUR_YELLOW, Screen.A_BOLD, Screen.COLOUR_RED),
"label": (Screen.COLOUR_GREEN, Screen.A_BOLD, Screen.COLOUR_BLUE),
"borders": (Screen.COLOUR_BLACK, Screen.A_BOLD, Screen.COLOUR_BLUE),
"scroll": (Screen.COLOUR_CYAN, Screen.A_NORMAL, Screen.COLOUR_BLUE),
"title": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_BLUE),
"edit_text": (Screen.COLOUR_WHITE, Screen.A_NORMAL, Screen.COLOUR_BLUE),
"focus_edit_text": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_CYAN),
"readonly": (Screen.COLOUR_BLACK, Screen.A_BOLD, Screen.COLOUR_BLUE),
"focus_readonly": (Screen.COLOUR_BLACK, Screen.A_BOLD, Screen.COLOUR_CYAN),
"button": (Screen.COLOUR_WHITE, Screen.A_NORMAL, Screen.COLOUR_BLUE),
"focus_button": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_CYAN),
"control": (Screen.COLOUR_YELLOW, Screen.A_NORMAL, Screen.COLOUR_BLUE),
"selected_control": (Screen.COLOUR_YELLOW, Screen.A_BOLD, Screen.COLOUR_BLUE),
"focus_control": (Screen.COLOUR_YELLOW, Screen.A_NORMAL, Screen.COLOUR_BLUE),
"selected_focus_control": (Screen.COLOUR_YELLOW, Screen.A_BOLD, Screen.COLOUR_CYAN),
"field": (Screen.COLOUR_WHITE, Screen.A_NORMAL, Screen.COLOUR_BLUE),
"selected_field": (Screen.COLOUR_YELLOW, Screen.A_BOLD, Screen.COLOUR_BLUE),
"focus_field": (Screen.COLOUR_WHITE, Screen.A_NORMAL, Screen.COLOUR_BLUE),
"selected_focus_field": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_CYAN),
},
"monochrome": defaultdict(
lambda: (Screen.COLOUR_WHITE, Screen.A_NORMAL, Screen.COLOUR_BLACK),
{
"invalid": (Screen.COLOUR_BLACK, Screen.A_NORMAL, Screen.COLOUR_RED),
"label": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_BLACK),
"title": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_BLACK),
"selected_focus_field": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_BLACK),
"focus_edit_text": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_BLACK),
"focus_button": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_BLACK),
"selected_focus_control": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_BLACK),
"disabled": (Screen.COLOUR_BLACK, Screen.A_BOLD, Screen.COLOUR_BLACK),
}
),
"green": defaultdict(
lambda: (Screen.COLOUR_GREEN, Screen.A_NORMAL, Screen.COLOUR_BLACK),
{
"invalid": (Screen.COLOUR_BLACK, Screen.A_NORMAL, Screen.COLOUR_RED),
"label": (Screen.COLOUR_GREEN, Screen.A_BOLD, Screen.COLOUR_BLACK),
"title": (Screen.COLOUR_GREEN, Screen.A_BOLD, Screen.COLOUR_BLACK),
"selected_focus_field": (Screen.COLOUR_GREEN, Screen.A_BOLD, Screen.COLOUR_BLACK),
"focus_edit_text": (Screen.COLOUR_GREEN, Screen.A_BOLD, Screen.COLOUR_BLACK),
"focus_button": (Screen.COLOUR_GREEN, Screen.A_BOLD, Screen.COLOUR_BLACK),
"selected_focus_control": (Screen.COLOUR_GREEN, Screen.A_BOLD, Screen.COLOUR_BLACK),
"disabled": (Screen.COLOUR_BLACK, Screen.A_BOLD, Screen.COLOUR_BLACK),
}
),
"bright": defaultdict(
lambda: (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_BLACK),
{
"invalid": (Screen.COLOUR_BLACK, Screen.A_NORMAL, Screen.COLOUR_RED),
"label": (Screen.COLOUR_GREEN, Screen.A_BOLD, Screen.COLOUR_BLACK),
"control": (Screen.COLOUR_YELLOW, Screen.A_BOLD, Screen.COLOUR_BLACK),
"focus_control": (Screen.COLOUR_YELLOW, Screen.A_BOLD, Screen.COLOUR_BLACK),
"selected_focus_control": (Screen.COLOUR_YELLOW, Screen.A_BOLD, Screen.COLOUR_BLACK),
"selected_focus_field": (Screen.COLOUR_YELLOW, Screen.A_BOLD, Screen.COLOUR_BLACK),
"focus_button": (Screen.COLOUR_YELLOW, Screen.A_BOLD, Screen.COLOUR_BLACK),
"focus_edit_text": (Screen.COLOUR_YELLOW, Screen.A_BOLD, Screen.COLOUR_BLACK),
"disabled": (Screen.COLOUR_BLACK, Screen.A_BOLD, Screen.COLOUR_BLACK),
}
),
"tlj256": defaultdict(
lambda: (16, 0, 15),
{
"invalid": (0, 0, 196),
"label": (88, 0, 15),
"title": (88, 0, 15),
"selected_focus_field": (15, 0, 88),
"focus_edit_text": (15, 0, 88),
"focus_button": (15, 0, 88),
"selected_focus_control": (15, 0, 88),
"disabled": (8, 0, 15),
}
),
"warning": defaultdict(
lambda: (Screen.COLOUR_WHITE, Screen.A_NORMAL, Screen.COLOUR_RED),
{
"label": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_RED),
"title": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_RED),
"focus_edit_text": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_RED),
"focus_field": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_RED),
"focus_button": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_YELLOW),
"focus_control": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_RED),
"disabled": (Screen.COLOUR_WHITE, Screen.A_BOLD, Screen.COLOUR_RED),
"shadow": (Screen.COLOUR_BLACK, None, Screen.COLOUR_BLACK),
}
),
}
def _enforce_width(text, width, unicode_aware=True):
"""
Enforce a displayed piece of text to be a certain number of cells wide. This takes into
account double-width characters used in CJK languages.
:param text: The text to be truncated
:param width: The screen cell width to enforce
:return: The resulting truncated text
"""
# Double-width strings cannot be more than twice the string length, so no need to try
# expensive truncation if this upper bound isn't an issue.
if (2 * len(text) < width) or (len(text) < width and not unicode_aware):
return text
# Can still optimize performance if we are not handling unicode characters.
if unicode_aware:
size = 0
for i, char in enumerate(str(text)):
c_width = wcwidth(char) if ord(char) >= 256 else 1
if size + c_width > width:
return text[0:i]
size += c_width
elif len(text) + 1 > width:
return text[0:width]
return text
def _find_min_start(text, max_width, unicode_aware=True, at_end=False):
"""
Find the starting point in the string that will reduce it to be less than or equal to the
specified width when displayed on screen.
:param text: The text to analyze.
:param max_width: The required maximum width
:param at_end: At the end of the editable line, so allow spaced for cursor.
:return: The offset within `text` to start at to reduce it to the required length.
"""
# Is the solution trivial? Worth optimizing for text heavy UIs...
if 2 * len(text) < max_width:
return 0
# OK - do it the hard way...
result = 0
string_len = wcswidth if unicode_aware else len
char_len = wcwidth if unicode_aware else lambda x: 1
display_end = string_len(text)
while display_end > max_width:
result += 1
display_end -= char_len(text[0])
text = text[1:]
if at_end and display_end == max_width:
result += 1
return result
def _get_offset(text, visible_width, unicode_aware=True):
"""
Find the character offset within some text for a given visible offset (taking into account the
fact that some character glyphs are double width).
:param text: The text to analyze
:param visible_width: The required location within that text (as seen on screen).
:return: The offset within text (as a character offset within the string).
"""
result = 0
width = 0
if unicode_aware:
for char in text:
if visible_width - width <= 0:
break
result += 1
width += wcwidth(char)
if visible_width - width < 0:
result -= 1
else:
result = min(len(text), visible_width)
return result
@lru_cache(256)
def _split_text(text, width, height, unicode_aware=True):
"""
Split text to required dimensions.
This will first try to split the text into multiple lines, then put a "..." on the last
3 characters of the last line if this still doesn't fit.
:param text: The text to split.
:param width: The maximum width for any line.
:param height: The maximum height for the resulting text.
:return: A list of strings of the broken up text.
"""
# At a high level, just try to split on whitespace for the best results.
tokens = text.split(" ")
result = []
current_line = ""
string_len = wcswidth if unicode_aware else len
for token in tokens:
for i, line_token in enumerate(token.split("\n")):
if string_len(current_line + line_token) > width or i > 0:
# Don't bother inserting completely blank lines
# which should only happen on the very first
# line (as the rest will inject whitespace/newlines)
if len(current_line) > 0:
result.append(current_line.rstrip())
current_line = line_token + " "
else:
current_line += line_token + " "
# At this point we've either split nicely or have a hugely long unbroken string
# (e.g. because the language doesn't use whitespace.
# Either way, break this last line up as best we can.
current_line = current_line.rstrip()
while string_len(current_line) > 0:
new_line = _enforce_width(current_line, width, unicode_aware)
result.append(new_line)
current_line = current_line[len(new_line):]
# Check for a height overrun and truncate.
if len(result) > height:
result = result[:height]
result[height - 1] = result[height - 1][:width - 3] + "..."
# Very small columns could be shorter than individual words - truncate
# each line if necessary.
for i, line in enumerate(result):
if len(line) > width:
result[i] = line[:width - 3] + "..."
return result
def _euclidian_distance(widget1, widget2):
"""
Find the Euclidian distance between 2 widgets.
:param widget1: first widget
:param widget2: second widget
"""
point1 = widget1.get_location()
point2 = widget2.get_location()
return sqrt((point1[0] - point2[0]) ** 2 + (point1[1] - point2[1]) ** 2)