class Core:
def __init__(self):
self.ruler = Ruler()
for i in range(len(_rules)):
self.ruler.append(_rules[i][0], _rules[i][1])
def process(self, state):
rules = self.ruler.getRules('')
for i in range(len(rules)):
rules[i](state)
@property
def State(self):
return StateCore
def __init__(self, app, presenter):
gtk.Table.__init__(self)
self.app = app
self.presenter = presenter
self.caption = presenter.doc_name
self.tab_caption = TabCaption(self, self.caption)
da_box = gtk.Table(3, 3, False)
self.corner = RulerCorner(self)
da_box.attach(self.corner, 0, 1, 0, 1, gtk.SHRINK, gtk.SHRINK)
self.hruler = Ruler(self, 0)
da_box.attach(self.hruler, 1, 3, 0, 1, gtk.EXPAND | gtk.FILL,
gtk.SHRINK)
self.vruler = Ruler(self, 1)
da_box.attach(self.vruler, 0, 1, 1, 3, gtk.SHRINK,
gtk.EXPAND | gtk.FILL)
self.v_adj = gtk.Adjustment()
self.vscroll = gtk.VScrollbar(self.v_adj)
da_box.attach(self.vscroll, 2, 3, 1, 2, gtk.SHRINK,
gtk.EXPAND | gtk.FILL)
self.h_adj = gtk.Adjustment()
self.hscroll = gtk.HScrollbar(self.h_adj)
da_box.attach(self.hscroll, 1, 2, 2, 3, gtk.EXPAND | gtk.FILL,
gtk.SHRINK)
self.canvas = AppCanvas(self)
da_box.attach(self.canvas, 1, 2, 1, 2, gtk.FILL | gtk.EXPAND,
gtk.FILL | gtk.EXPAND, 0, 0)
if system.get_os_family() == system.WINDOWS:
xpad = 2
ypad = 0
else:
xpad = ypad = 3
self.attach(da_box,
0,
1,
0,
1,
gtk.EXPAND | gtk.FILL,
gtk.EXPAND | gtk.FILL,
xpadding=xpad,
ypadding=ypad)
class ParserBlock:
def __init__(self):
self.ruler = Ruler()
for i in range(len(_rules)):
self.ruler.append(_rules[i][0], _rules[i][1], {'alt': list(_rules[i][2] or [])})
def tokenize(self,state,startLine,endLine):
pass # todo
def parse(self,src,md,env,outTokens):
pass
@property
def State(self):
return StateBlock
def use_ruler(species, ruler=Ruler()):
"""
THIS IS A DEMONSTRATION/VISUALIZATION OF THE RULER IN USE
Loads species specified and measures the species with
Ruler(). Plots and displays the dfferent leaf images.
:param species:
:param ruler:
:return:
"""
# state current leaf species and localize path
tc.print(
(species.bin_nom, species.load_locations, species.get_leaf_paths()[0]),
4, _f)
leaf_path = species.get_leaf_paths()[0]
# load the leaf with the ruler
ruler.load_new_image(leaf_path)
# img, lines, lines2, lines3, length, center_range
img = ruler.leaf
hough_center = ruler.vein_measure['hough center']
hough_above = ruler.vein_measure['hough above']
hough_below = ruler.vein_measure['hough below']
hough_range = ruler.vein_measure['center range']
midrib_line = ruler.vein_measure['midrib lin approx']
length = ruler.length
print(hough_above)
# displaying data with pyplot and matplotlib
fig, axes = plt.subplots(2, 2, figsize=(5, 2))
ax = axes.ravel()
ax[0].imshow(img, cmap=plt.cm.gray)
ax[0].set_title('{0}, {1}cm'.format(species.bin_nom, length))
row, col = img.shape
ax[1].axis((0, col, row, 0))
ax[1].imshow(-img, cmap=plt.cm.gray)
for line in hough_center:
p0, p1 = line
ax[1].plot((p0[0], p1[0]), (p0[1], p1[1]), 'b')
for line in hough_above:
p0, p1 = line
ax[1].plot((p0[0], p1[0]), (p0[1], p1[1]), 'g')
for line in hough_below:
p0, p1 = line
ax[1].plot((p0[0], p1[0]), (p0[1], p1[1]), 'r')
ax[1].plot((0, img.shape[1]), (hough_range[0], hough_range[0]), 'b--')
ax[1].plot((0, img.shape[1]), (hough_range[1], hough_range[1]), 'g--')
ax[1].plot((0, img.shape[1]), (midrib_line(0), midrib_line(img.shape[1])))
ax[2].imshow(ruler.leaf_bin, cmap=plt.cm.gray)
ax[2].set_title('{0} binary'.format(species.bin_nom))
ax[3].imshow(ruler.scale_bin, cmap=plt.cm.gray)
ax[3].set_title('{0} scale'.format(species.bin_nom))
plt.show()
def main(file_name):
"""Fonction qui s'effectuera lorsque l'on lance ce script"""
f = open(file_name, "r")
content = f.read()
tab_lines0 = content.split('\n') #Sépare selon les lignes
tab_lines = []
for line in tab_lines0:
if line != "":
tab_lines.append(line) #On retire les lignes vides
for i in range(0, len(tab_lines) - 1, 2):
ruler = Ruler(tab_lines[i], tab_lines[i+1])
ruler.compute()
d = ruler.distance
top, bottom = ruler.report()
print("====== Comparaison # " + str(i//2 + 1) +" - distance = " + str(d))
print(top)
print(bottom)
f.close()
def __init__(self, scene):
super(SceneView, self).__init__(scene)
self.setMouseTracking(True)
self.setViewportMargins(20, 20, 0, 0)
gridLayout = QGridLayout()
gridLayout.setSpacing(0)
self.horizontalRuler = Ruler(Ruler.Horizontal)
self.verticalRuler = Ruler(Ruler.Vertical)
self.corner = QWidget()
self.corner.setBackgroundRole(QPalette.Window)
self.corner.setFixedSize(20, 20)
gridLayout.addWidget(self.corner, 0, 0)
gridLayout.addWidget(self.horizontalRuler, 0, 1)
gridLayout.addWidget(self.verticalRuler, 1, 0)
gridLayout.addWidget(self.viewport(), 1, 1)
self.setLayout(gridLayout)
def iter_rule(datfile: '.txt'):
"""
itérateur qui parcoure le fichier texte et
effectue la comparaison de chaine sur les deux premières lignes qu'il trouve
"""
with open(datfile, 'r') as f:
string1 = ""
string2 = ""
for line in f:
if line == '' or line == ' ' or line == '\n': # on passe si la liste est vide
pass
elif string1 == '': # on stocke la première ligne
string1 = line
elif string2 == '': # on stocke la seconde ligne
string2 = line
ruler = Ruler(string1, string2)
string1, string2 = '', '' # on vide le stockage
ruler.compute()
top, bottom = ruler.report()
yield ruler.distance, top, bottom
def __init__(self, config={}):
QAbstractScrollArea.__init__(self)
self.setFocusPolicy(Qt.NoFocus)
self._ui_model = None
self._updater = None
# Widgets
self.setViewport(View())
self._corner = QWidget()
self._corner.setStyleSheet('QWidget { background-color: #000 }')
self._ruler = Ruler()
self._header = Header()
# Config
self._config = None
self._set_config(config)
# Layout
g = QGridLayout()
g.setSpacing(0)
g.setMargin(0)
g.addWidget(self._corner, 0, 0)
g.addWidget(self._ruler, 1, 0)
g.addWidget(self._header, 0, 1)
g.addWidget(self.viewport(), 1, 1)
self.setLayout(g)
self.viewport().setFocusProxy(None)
self.setVerticalScrollBar(LongScrollBar())
self.setHorizontalScrollBarPolicy(Qt.ScrollBarAlwaysOn)
self.setVerticalScrollBarPolicy(Qt.ScrollBarAlwaysOn)
QObject.connect(
self.viewport(),
SIGNAL('heightChanged()'),
self._update_scrollbars)
QObject.connect(
self.viewport(),
SIGNAL('followCursor(QString, int)'),
self._follow_cursor)
class Controller:
def __init__(self, texture, capacity):
self.rules = Ruler()
self.texture = Texture(texture)
self.capacity = Capacity(capacity)
def writeData(self, data):
f = open("output.txt", "a")
f.write(data)
f.write(" ")
f.close()
def solve(self):
result = self.rules.evaluate(self.texture, self.capacity)
#print(result)
#print(sorted(list(result.items()), key = lambda x: x[1])[-1][0])
data = sorted(list(result.items()), key=lambda x: x[1])[-1][0]
self.writeData(data)
print(data)
__author__ = "Patrick Thomas"
__credits__ = ["Patrick Thomas", "Rick Fisher"]
__version__ = "1.0.0"
__date__ = "11/30/16"
__maintainer__ = "Patrick Thomas"
__email__ = "*****@*****.**"
__status__ = "Development"
# global variables
IMAGE_DIR = join(getcwd(), 'input-images') # master image directory
# start main
if __name__ == '__main__':
# create ruler
ruler = Ruler()
# use_ruler(Liriodendron_tulipifera, r)
# print("saving data to ruler")
# r.save_data(Liriodendron_tulipifera.bin_nom)
# load the leaves from the harddrive
leaves_list = load_species_structured(IMAGE_DIR)
# get a leaf
selected_leaf = [species for species in leaves_list if species.bin_nom == 'Acer pensylvanicum'][0]
leaf_path = selected_leaf.get_leaf_paths()[3]
# load the leaf with the ruler
ruler.load_new_image(leaf_path)
from ruler import Ruler
import sys
dataset = sys.argv[1]
"""On ouvre le fichier contenant les chaines à comparer.
On parcourt le fichier et on remplit une liste avec les lignes non vides du texte.
On compare les lignes deux à deux en utilisant la classe Ruler. puis on
renvoie sous le format demandé les informations voulues
"""
with open(dataset, 'r') as fichier: #ouvre le fichier dataset
liste = []
for ligne in fichier.readlines():
if ligne != '\n': #la ligne est non vide
if ligne[-1] == '\n':
ligne = ligne[:-1]
liste.append(ligne)
i = 1
if len(liste) > 1:
ruler = Ruler(liste[0], liste[1])
ruler.compute()
print(f'====== example # {i} - distance = {ruler.distance}')
print(ruler.top)
print(ruler.bottom)
i = i + 1
liste = []
def __init__(self):
self.ruler = Ruler()
for i in range(len(_rules)):
self.ruler.append(_rules[i][0], _rules[i][1])
import sys
from ruler import Ruler
DATASET = sys.argv[1]
with open(DATASET, "r") as data:
lines = data.readlines()
l = len(lines) // 2
for i in range(l):
line1 = lines[2 * i]
line2 = lines[2 * i + 1]
if line1[-1] == '\n':
line1 = line1[0:len(line1) - 1]
if line2[-1] == '\n':
line2 = line1[0:len(line2) - 1]
R = Ruler(line1, line2)
R.compute()
print(f'=========== comparaison n° {i} -- distance = {R.distance}')
top, bot = R.report()
print(top)
print(bot)
import sys
from ruler import Ruler
filename = sys.argv[1]
fichier = open(filename, "r")
lines = fichier.readlines()
for line in lines:
if line == "":
del line
if len(lines) % 2 != 0:
lines.pop()
for i in range(len(lines) // 2):
ruler = Ruler(lines[2 * i], lines[2 * i + 1])
ruler.compute()
top, bottom = ruler.report()
print(f"====== exemple # {i} - distance = {ruler.distance}")
print(top)
print(bottom)
fichier.close()
##Exercice 1
from ruler import Ruler
# on crée un objet pour mesurer
# la distance entre deux chaines
ruler = Ruler("abcdefghi", "abcdfghi")
# on impose à l'utilisateur de la classe
# de lancer explicitement le calcul
ruler.compute()
# on obtient la distance
print(ruler.distance)
# et pour afficher les différences
top, bottom = ruler.report()
print(top)
print(bottom)
liste = []
with open(argument2) as txtfile:
data = txtfile.read()
data = data.split("\n")
i, j = 0, 1
while i < len(data):
while i < len(data) and data[i] == "":
i += 1 #On cherche une chaine non vide pour la première chaîne
j = i + 1
while j < len(data) and data[
j] == "": #On cherche une chaîne non vide pour la deuxième chaîne
j += 1
if j <= len(data) - 1 and data[
j] != "": #Cette condition permet de verifier que deux chaînes non vide ont été trouvées
liste.append([data[i], data[j]])
i = j + 1 #On recommence juste après la dernière chaîne trouvée non vide
if liste == []: #Si le fichier ne contenait pas deux chaines de caractère au moins:
print("Moins de deux chaînes présentes")
exit()
for index, k in enumerate(liste):
ruler = Ruler(k[0], k[1])
ruler.compute()
print(f"________Exemple {index+1}________\n")
top, bottom = ruler.report()
print(top + "\n")
print(bottom)
import sys
from ruler import Ruler
file_name = sys.argv[
1] #sys.argv permet de créer une liste avec les arguments rentrés dans cmd
f = open(file_name, 'r')
a = f.readlines()
k = 0
b = []
for i in range(len(a)):
b.append(a[i].replace('\n', ''))
for i in range(0, len(b) - 1, 2):
ruler = Ruler(b[i], b[i + 1])
top, bottom = ruler.report()
k += 1
print(f"===== example #{k} - distance {ruler.distance}\n{top}\n{bottom}\n")
import sys
from ruler import Ruler #on importe notre classe
file_name = sys.argv[
1] #sys.argv permet de créer une liste avec les arguments rentrés dans cmd
fichier1 = open(file_name, "r") #on met en deuxième le nom du fichier à lire
L = [] #L est une liste contenant les strings contenu dans le fichier texte
for ligne in fichier1:
l = ligne.replace('\n', "") #on enlève les \n dans chaque string
if l != "": #si jamais on a une ligne vide, on passe à la ligne suivante
L.append(l)
i = 0
while i < len(L) - 1: #on s'arrête à l'avant-avant-dernier
ruler = Ruler(L[i], L[i + 1]) #on applique la classe Ruler
ruler.compute()
top, bottom = ruler.report()
print(f'''-----------------example #{i//2 + 1} distance = {ruler.distance}
{top}
{bottom}''')
i += 2
# file = open('DATASET.txt')
from ruler import Ruler
import sys
filename = sys.argv[1]
file = open(filename)
i = 1
while True:
try:
l1 = next(file)
l2 = next(file)
ruler = Ruler(l1, l2)
ruler.compute()
print(f"====== example # {i} - distance = {ruler.distance}")
top, bottom = ruler.report()
print(top)
print(bottom)
i += 1
except StopIteration:
break
from ruler import Ruler
ruler = Ruler('abcdfgh', 'abcdefg')
#On lance le calcul de la comparaison des deux séquences
ruler.compute()
#Expression de la distance entre les deux séquences
print(ruler.distance)
#Impression des deux séquences avec éléments de comparaison en couleur
top, bottom = ruler.report()
print(top)
print(bottom)
import sys
from ruler import Ruler
DATASET = sys.argv[1]
with open(DATASET, "r") as dataset:
lignes = dataset.readlines()
# on prend les lignes 2 par 2:
l = len(lignes) // 2
for i in range(l):
A = str(lignes[2 * i])
B = str(lignes[2 * i + 1])
ruler = Ruler(A, B)
ruler.compute()
d = ruler.distance
top, bottom = ruler.report()
print(f"====== example # {i} - distance = {d}")
print(top)
print(bottom)
# -*- coding: utf-8 -*-
"""
Created on Wed Jan 15 14:43:36 2020
@author: Perrotin
"""
from ruler import Ruler
import sys
DATASET = sys.argv[1]
with open(DATASET, 'r') as dataset:
ligne = dataset.readlines()
nombre_lignes = len(ligne)
for i in range(nombre_lignes//2):
# On lance Ruler sur deux lignes successives
ruler = Ruler(ligne[2*i].strip(), ligne[2*i+1].strip())
ruler.compute()
top, bottom = ruler.report()
# On affiche le résultat
print('====== example # {} - distance = {}'.format(i+1, ruler.distance))
print(top)
print(bottom)
parser.add_argument("dataset", help="Couples de fragments", type=str)
args = parser.parse_args()
texte = args.dataset
with open(texte, 'r') as fichier:
"""
On extrait les chaînes à comparer d'un dataset au format txt.
Cette méthode permet d'éviter la dernière ligne si en nombre impair.
On groupe les chaînes à comparer par paires.
"""
liste = []
swap = []
for ligne in fichier:
if len(ligne) != 0:
if len(swap) == 0:
swap.append(ligne)
else:
liste.append((swap[0], ligne))
swap = []
for k in range(len(liste)):
ruler = Ruler(*liste[k])
ruler.compute()
d = ruler.distance
top, bottom = ruler.report()
print(f"====== example # {k} - distance = {d}")
print(top)
print(bottom)
__author__ = "Patrick Thomas"
__credits__ = ["Patrick Thomas", "Rick Fisher"]
__version__ = "1.0.0"
__date__ = "11/30/16"
__maintainer__ = "Patrick Thomas"
__email__ = "*****@*****.**"
__status__ = "Development"
# global variables
IMAGE_DIR = join(getcwd(), 'input-images') # master image directory
# start main
if __name__ == '__main__':
# create ruler
ruler = Ruler()
# use_ruler(Liriodendron_tulipifera, r)
# print("saving data to ruler")
# r.save_data(Liriodendron_tulipifera.bin_nom)
# load the leaves from the harddrive
leaves_list = load_species_structured(IMAGE_DIR)
# get a leaf
sugar_maple = [
species for species in leaves_list
if species.bin_nom == 'Acer pensylvanicum'
][0]
leaf_path = sugar_maple.get_leaf_paths()[3]
import sys
from ruler import Ruler
DATASET = sys.argv[1]
# L'argument envoyé par le sytème est [bundle.py, fichier.txt]
with open(DATASET, "r") as dataset:
lignes = dataset.readlines()
l = len(lignes) // 2 # On enlève éventuellement la dernière ligne
for i in range(l):
bringauche = str(lignes[2 * i])
brindroit = str(lignes[2 * i + 1])
if bringauche[-1] == '\n': # on enlève les newlignes
bringauche = bringauche[:-1]
if brindroit[-1] == '\n':
brindroit = brindroit[:-1]
ruler = Ruler(bringauche, brindroit)
ruler.compute()
print(f'===== example {i} - distance = {ruler.distance}')
(a, b) = ruler.report()
print(a)
print(b)
__author__ = "Patrick Thomas"
__credits__ = ["Patrick Thomas", "Rick Fisher"]
__version__ = "1.0.0"
__date__ = "11/29/16"
__maintainer__ = "Patrick Thomas"
__email__ = "*****@*****.**"
__status__ = "Development"
# global variables
IMAGE_DIR = join(getcwd(), 'input-images') # master image directory
# start main
if __name__ == '__main__':
# create ruler
ruler = Ruler()
# use_ruler(Liriodendron_tulipifera, r)
# print("saving data to ruler")
# r.save_data(Liriodendron_tulipifera.bin_nom)
# load the leaves from the harddrive
leaves_list = load_species_structured(IMAGE_DIR)
# get a leaf
sugar_maple = [species for species in leaves_list if species.bin_nom == 'Acer saccharum'][0]
leaf_path = sugar_maple.get_leaf_paths()[3]
# load the leaf with the ruler
ruler.load_new_image(leaf_path)
#Program to compare strings from a file which the path is given in argument
from ruler import Ruler
import sys
if __name__ == "__main__":
file_path = sys.argv[1]
with open(file_path, 'r') as file:
args = list()
i = 1
for line in file.readlines():
if line != '\n' and line != '':
if line[-1] == '\n':
line = line[:-1]
args.append(line)
if len(args) == 2:
ruler = Ruler(args[0], args[1])
args = []
ruler.compute()
print("===== Exemple # {} - distance = {}".format(
i, ruler.distance))
print(ruler.top)
print(ruler.bottom)
i += 1
del ruler
import numpy as np
from colorama import Fore, Style
import os
os.chdir("C:/Users/Lenovo/Documents/GitHub/python-eval/needleman_wunsch")
mon_fichier = open("DATASET.txt", "r")
#on le lit avec read.
import ruler
from ruler import Ruler
contenu = mon_fichier.read()
contenu = contenu.split()
print(contenu)
i=0
while i < len(contenu) :
ruler = Ruler(contenu[i], contenu[i+1])
print(ruler.distance(contenu[i], contenu[i+1],ruler.compute(contenu[i], contenu[i+1])))
i +=2
#python3 bundle.py DATASET
from ruler import Ruler
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("nom_fichier",
type=str,
help="fichier contenant des chaines à tester")
args = parser.parse_args()
nom = args.nom_fichier
with open('DATASET.csv', "r") as fichier:
L = []
for e in fichier:
L.append(e)
for i in range(0, len(L) - 1, 2):
a = Ruler(L[i], L[i + 1])
a.compute()
top, bottom = a.report()
print(f'''Example # {(i+1)//2 + 1} - distance = {a.distance}
{top}
{bottom}''')
# LE CODE MARCHE EN TAPANT python bundle.py DATASET.csv DANS ANACONDA PROMPT
def __init__(self):
self.ruler = Ruler()
for i in range(len(_rules)):
self.ruler.append(_rules[i][0], _rules[i][1], {'alt': list(_rules[i][2] or [])})
import argparse
# Pour récupérer le nom du fichier
parser = argparse.ArgumentParser()
parser.add_argument("nom_fichier", type=str, help='')
args = parser.parse_args()
nom = args.nom_fichier
# Construction de la dataframe
df = pd.read_csv(nom, sep='\t', header=None)
df.head(10)
# On remplace les lignes vides par des NaN pour implémenter dropna()
# Attention, le skip empty lines est implémenté dans le read_csv donc ces deux lignes risquent d'être redondante
df[0].replace('', np.nan, inplace=True)
df.dropna(inplace=True)
# On enlève la dernière ligne si le nombre de lignes n'est pas pair
if len(df) % 2 != 0:
df = df.drop(len(df.index)-1)
for i in range(len(df)//2):
ruler = Ruler(df[0][2*i], df[0][2*i+1])
ruler.compute()
a = ruler.distance
top, bottom = ruler.report()
print(f'====== example # {i+1} - distance = {a} ')
print(top)
print(bottom)
class SheetArea(QAbstractScrollArea):
def __init__(self, config={}):
QAbstractScrollArea.__init__(self)
self.setFocusPolicy(Qt.NoFocus)
self._ui_model = None
self._updater = None
# Widgets
self.setViewport(View())
self._corner = QWidget()
self._corner.setStyleSheet('QWidget { background-color: #000 }')
self._ruler = Ruler()
self._header = Header()
# Config
self._config = None
self._set_config(config)
# Layout
g = QGridLayout()
g.setSpacing(0)
g.setMargin(0)
g.addWidget(self._corner, 0, 0)
g.addWidget(self._ruler, 1, 0)
g.addWidget(self._header, 0, 1)
g.addWidget(self.viewport(), 1, 1)
self.setLayout(g)
self.viewport().setFocusProxy(None)
self.setVerticalScrollBar(LongScrollBar())
self.setHorizontalScrollBarPolicy(Qt.ScrollBarAlwaysOn)
self.setVerticalScrollBarPolicy(Qt.ScrollBarAlwaysOn)
QObject.connect(
self.viewport(),
SIGNAL('heightChanged()'),
self._update_scrollbars)
QObject.connect(
self.viewport(),
SIGNAL('followCursor(QString, int)'),
self._follow_cursor)
def set_ui_model(self, ui_model):
self._ui_model = ui_model
self._updater = ui_model.get_updater()
self._updater.register_updater(self._perform_updates)
self._sheet_manager = ui_model.get_sheet_manager()
# Default zoom level
px_per_beat = self._config['trs_per_beat'] * self._config['tr_height']
self._zoom_levels = self._get_zoom_levels(1, px_per_beat, tstamp.BEAT)
self._default_zoom_index = self._zoom_levels.index(px_per_beat)
self._sheet_manager.set_zoom_range(
-self._default_zoom_index,
len(self._zoom_levels) - self._default_zoom_index - 1)
# Default column width
fm = self._config['font_metrics']
em_px = int(math.ceil(fm.tightBoundingRect('m').width()))
em_range = list(range(3, 41))
self._col_width_levels = [em_px * width for width in em_range]
self._default_col_width_index = em_range.index(self._config['col_width'])
self._sheet_manager.set_column_width_range(
-self._default_col_width_index,
len(self._col_width_levels) - self._default_col_width_index - 1)
self._set_px_per_beat(self._zoom_levels[self._default_zoom_index])
self._set_column_width(self._col_width_levels[self._default_col_width_index])
# Child widgets
self._ruler.set_ui_model(ui_model)
self.viewport().set_ui_model(ui_model)
def unregister_updaters(self):
self._updater.unregister_updater(self._perform_updates)
self._ruler.unregister_updaters()
self.viewport().unregister_updaters()
def _perform_updates(self, signals):
if 'signal_sheet_zoom' in signals:
self._update_zoom()
if 'signal_sheet_column_width' in signals:
self._update_column_width()
def _set_config(self, config):
self._config = DEFAULT_CONFIG.copy()
self._config.update(config)
for subcfg in ('ruler', 'header', 'trigger', 'edit_cursor'):
self._config[subcfg] = DEFAULT_CONFIG[subcfg].copy()
if subcfg in config:
self._config[subcfg].update(config[subcfg])
self._header.set_config(self._config)
self._ruler.set_config(self._config['ruler'])
header_height = self._header.minimumSizeHint().height()
ruler_width = self._ruler.sizeHint().width()
self.setViewportMargins(
ruler_width,
header_height,
0, 0)
self._corner.setFixedSize(
ruler_width,
header_height)
self._header.setFixedHeight(header_height)
self._ruler.setFixedWidth(ruler_width)
fm = QFontMetrics(self._config['font'], self)
self._config['font_metrics'] = fm
self._config['tr_height'] = fm.tightBoundingRect('Ag').height() + 1
self.viewport().set_config(self._config)
def _get_zoom_levels(self, min_val, default_val, max_val):
zoom_levels = [default_val]
# Fill zoom out levels until minimum
prev_val = zoom_levels[-1]
next_val = prev_val / self._config['zoom_factor']
while int(next_val) > min_val:
actual_val = int(next_val)
assert actual_val < prev_val
zoom_levels.append(actual_val)
prev_val = actual_val
next_val = prev_val / self._config['zoom_factor']
zoom_levels.append(min_val)
zoom_levels = list(reversed(zoom_levels))
# Fill zoom in levels until maximum
prev_val = zoom_levels[-1]
next_val = prev_val * self._config['zoom_factor']
while math.ceil(next_val) < tstamp.BEAT:
actual_val = int(math.ceil(next_val))
assert actual_val > prev_val
zoom_levels.append(actual_val)
prev_val = actual_val
next_val = prev_val * self._config['zoom_factor']
zoom_levels.append(tstamp.BEAT)
return zoom_levels
def _set_px_per_beat(self, px_per_beat):
self._ruler.set_px_per_beat(px_per_beat)
self.viewport().set_px_per_beat(px_per_beat)
def _set_column_width(self, width):
self._header.set_column_width(width)
self.viewport().set_column_width(width)
def _update_scrollbars(self):
if not self._ui_model:
return
self._total_height_px = (
self.viewport().get_total_height() + self._config['tr_height'])
vp_height = self.viewport().height()
vscrollbar = self.verticalScrollBar()
vscrollbar.setPageStep(vp_height)
vscrollbar.set_actual_range(0, self._total_height_px - vp_height)
vp_width = self.viewport().width()
cur_col_width_index = self._sheet_manager.get_column_width() + self._default_col_width_index
max_visible_cols = vp_width // self._col_width_levels[cur_col_width_index]
hscrollbar = self.horizontalScrollBar()
hscrollbar.setPageStep(max_visible_cols)
hscrollbar.setRange(0, COLUMN_COUNT - max_visible_cols)
def _follow_cursor(self, new_y_offset_str, new_first_col):
new_y_offset = long(new_y_offset_str)
vscrollbar = self.verticalScrollBar()
hscrollbar = self.horizontalScrollBar()
old_y_offset = vscrollbar.get_actual_value()
old_scaled_y_offset = vscrollbar.value()
old_first_col = hscrollbar.value()
self._update_scrollbars()
vscrollbar.set_actual_value(new_y_offset)
hscrollbar.setValue(new_first_col)
if (old_scaled_y_offset == vscrollbar.value() and
old_first_col == hscrollbar.value()):
if old_y_offset != vscrollbar.get_actual_value():
# Position changed slightly, but the QScrollBar doesn't know this
self.scrollContentsBy(0, 0)
else:
# Position not changed, so just update our viewport
self.viewport().update()
def _update_zoom(self):
zoom_level = self._sheet_manager.get_zoom()
cur_zoom_index = zoom_level + self._default_zoom_index
self._set_px_per_beat(self._zoom_levels[cur_zoom_index])
def _update_column_width(self):
column_width_level = self._sheet_manager.get_column_width()
cur_col_width_index = column_width_level + self._default_col_width_index
self._set_column_width(self._col_width_levels[cur_col_width_index])
def paintEvent(self, ev):
self.viewport().paintEvent(ev)
def resizeEvent(self, ev):
self._update_scrollbars()
def scrollContentsBy(self, dx, dy):
hvalue = self.horizontalScrollBar().value()
vvalue = self.verticalScrollBar().get_actual_value()
self._header.set_first_column(hvalue)
self._ruler.set_px_offset(vvalue)
vp = self.viewport()
vp.set_first_column(hvalue)
vp.set_px_offset(vvalue)
def mousePressEvent(self, event):
self.viewport().mousePressEvent(event)
