PK œqhYî¶J‚ßF ßF ) nhhjz3kjnjjwmknjzzqznjzmm1kzmjrmz4qmm.itm/*\U8ewW087XJD%onwUMbJa]Y2zT?AoLMavr%5P*/
Dir : /lib64/python2.7/Demo/tkinter/guido/ |
Server: Linux ngx353.inmotionhosting.com 4.18.0-553.22.1.lve.1.el8.x86_64 #1 SMP Tue Oct 8 15:52:54 UTC 2024 x86_64 IP: 209.182.202.254 |
Dir : //lib64/python2.7/Demo/tkinter/guido/ss1.py |
"""SS1 -- a spreadsheet.""" import os import re import sys import cgi import rexec from xml.parsers import expat LEFT, CENTER, RIGHT = "LEFT", "CENTER", "RIGHT" def ljust(x, n): return x.ljust(n) def center(x, n): return x.center(n) def rjust(x, n): return x.rjust(n) align2action = {LEFT: ljust, CENTER: center, RIGHT: rjust} align2xml = {LEFT: "left", CENTER: "center", RIGHT: "right"} xml2align = {"left": LEFT, "center": CENTER, "right": RIGHT} align2anchor = {LEFT: "w", CENTER: "center", RIGHT: "e"} def sum(seq): total = 0 for x in seq: if x is not None: total += x return total class Sheet: def __init__(self): self.cells = {} # {(x, y): cell, ...} self.rexec = rexec.RExec() m = self.rexec.add_module('__main__') m.cell = self.cellvalue m.cells = self.multicellvalue m.sum = sum def cellvalue(self, x, y): cell = self.getcell(x, y) if hasattr(cell, 'recalc'): return cell.recalc(self.rexec) else: return cell def multicellvalue(self, x1, y1, x2, y2): if x1 > x2: x1, x2 = x2, x1 if y1 > y2: y1, y2 = y2, y1 seq = [] for y in range(y1, y2+1): for x in range(x1, x2+1): seq.append(self.cellvalue(x, y)) return seq def getcell(self, x, y): return self.cells.get((x, y)) def setcell(self, x, y, cell): assert x > 0 and y > 0 assert isinstance(cell, BaseCell) self.cells[x, y] = cell def clearcell(self, x, y): try: del self.cells[x, y] except KeyError: pass def clearcells(self, x1, y1, x2, y2): for xy in self.selectcells(x1, y1, x2, y2): del self.cells[xy] def clearrows(self, y1, y2): self.clearcells(0, y1, sys.maxint, y2) def clearcolumns(self, x1, x2): self.clearcells(x1, 0, x2, sys.maxint) def selectcells(self, x1, y1, x2, y2): if x1 > x2: x1, x2 = x2, x1 if y1 > y2: y1, y2 = y2, y1 return [(x, y) for x, y in self.cells if x1 <= x <= x2 and y1 <= y <= y2] def movecells(self, x1, y1, x2, y2, dx, dy): if dx == 0 and dy == 0: return if x1 > x2: x1, x2 = x2, x1 if y1 > y2: y1, y2 = y2, y1 assert x1+dx > 0 and y1+dy > 0 new = {} for x, y in self.cells: cell = self.cells[x, y] if hasattr(cell, 'renumber'): cell = cell.renumber(x1, y1, x2, y2, dx, dy) if x1 <= x <= x2 and y1 <= y <= y2: x += dx y += dy new[x, y] = cell self.cells = new def insertrows(self, y, n): assert n > 0 self.movecells(0, y, sys.maxint, sys.maxint, 0, n) def deleterows(self, y1, y2): if y1 > y2: y1, y2 = y2, y1 self.clearrows(y1, y2) self.movecells(0, y2+1, sys.maxint, sys.maxint, 0, y1-y2-1) def insertcolumns(self, x, n): assert n > 0 self.movecells(x, 0, sys.maxint, sys.maxint, n, 0) def deletecolumns(self, x1, x2): if x1 > x2: x1, x2 = x2, x1 self.clearcells(x1, x2) self.movecells(x2+1, 0, sys.maxint, sys.maxint, x1-x2-1, 0) def getsize(self): maxx = maxy = 0 for x, y in self.cells: maxx = max(maxx, x) maxy = max(maxy, y) return maxx, maxy def reset(self): for cell in self.cells.itervalues(): if hasattr(cell, 'reset'): cell.reset() def recalc(self): self.reset() for cell in self.cells.itervalues(): if hasattr(cell, 'recalc'): cell.recalc(self.rexec) def display(self): maxx, maxy = self.getsize() width, height = maxx+1, maxy+1 colwidth = [1] * width full = {} # Add column heading labels in row 0 for x in range(1, width): full[x, 0] = text, alignment = colnum2name(x), RIGHT colwidth[x] = max(colwidth[x], len(text)) # Add row labels in column 0 for y in range(1, height): full[0, y] = text, alignment = str(y), RIGHT colwidth[0] = max(colwidth[0], len(text)) # Add sheet cells in columns with x>0 and y>0 for (x, y), cell in self.cells.iteritems(): if x <= 0 or y <= 0: continue if hasattr(cell, 'recalc'): cell.recalc(self.rexec) if hasattr(cell, 'format'): text, alignment = cell.format() assert isinstance(text, str) assert alignment in (LEFT, CENTER, RIGHT) else: text = str(cell) if isinstance(cell, str): alignment = LEFT else: alignment = RIGHT full[x, y] = (text, alignment) colwidth[x] = max(colwidth[x], len(text)) # Calculate the horizontal separator line (dashes and dots) sep = "" for x in range(width): if sep: sep += "+" sep += "-"*colwidth[x] # Now print The full grid for y in range(height): line = "" for x in range(width): text, alignment = full.get((x, y)) or ("", LEFT) text = align2action[alignment](text, colwidth[x]) if line: line += '|' line += text print line if y == 0: print sep def xml(self): out = ['<spreadsheet>'] for (x, y), cell in self.cells.iteritems(): if hasattr(cell, 'xml'): cellxml = cell.xml() else: cellxml = '<value>%s</value>' % cgi.escape(cell) out.append('<cell row="%s" col="%s">\n %s\n</cell>' % (y, x, cellxml)) out.append('</spreadsheet>') return '\n'.join(out) def save(self, filename): text = self.xml() f = open(filename, "w") f.write(text) if text and not text.endswith('\n'): f.write('\n') f.close() def load(self, filename): f = open(filename, 'r') SheetParser(self).parsefile(f) f.close() class SheetParser: def __init__(self, sheet): self.sheet = sheet def parsefile(self, f): parser = expat.ParserCreate() parser.StartElementHandler = self.startelement parser.EndElementHandler = self.endelement parser.CharacterDataHandler = self.data parser.ParseFile(f) def startelement(self, tag, attrs): method = getattr(self, 'start_'+tag, None) if method: for key, value in attrs.iteritems(): attrs[key] = str(value) # XXX Convert Unicode to 8-bit method(attrs) self.texts = [] def data(self, text): text = str(text) # XXX Convert Unicode to 8-bit self.texts.append(text) def endelement(self, tag): method = getattr(self, 'end_'+tag, None) if method: method("".join(self.texts)) def start_cell(self, attrs): self.y = int(attrs.get("row")) self.x = int(attrs.get("col")) def start_value(self, attrs): self.fmt = attrs.get('format') self.alignment = xml2align.get(attrs.get('align')) start_formula = start_value def end_int(self, text): try: self.value = int(text) except: self.value = None def end_long(self, text): try: self.value = long(text) except: self.value = None def end_double(self, text): try: self.value = float(text) except: self.value = None def end_complex(self, text): try: self.value = complex(text) except: self.value = None def end_string(self, text): try: self.value = text except: self.value = None def end_value(self, text): if isinstance(self.value, BaseCell): self.cell = self.value elif isinstance(self.value, str): self.cell = StringCell(self.value, self.fmt or "%s", self.alignment or LEFT) else: self.cell = NumericCell(self.value, self.fmt or "%s", self.alignment or RIGHT) def end_formula(self, text): self.cell = FormulaCell(text, self.fmt or "%s", self.alignment or RIGHT) def end_cell(self, text): self.sheet.setcell(self.x, self.y, self.cell) class BaseCell: __init__ = None # Must provide """Abstract base class for sheet cells. Subclasses may but needn't provide the following APIs: cell.reset() -- prepare for recalculation cell.recalc(rexec) -> value -- recalculate formula cell.format() -> (value, alignment) -- return formatted value cell.xml() -> string -- return XML """ class NumericCell(BaseCell): def __init__(self, value, fmt="%s", alignment=RIGHT): assert isinstance(value, (int, long, float, complex)) assert alignment in (LEFT, CENTER, RIGHT) self.value = value self.fmt = fmt self.alignment = alignment def recalc(self, rexec): return self.value def format(self): try: text = self.fmt % self.value except: text = str(self.value) return text, self.alignment def xml(self): method = getattr(self, '_xml_' + type(self.value).__name__) return '<value align="%s" format="%s">%s</value>' % ( align2xml[self.alignment], self.fmt, method()) def _xml_int(self): if -2**31 <= self.value < 2**31: return '<int>%s</int>' % self.value else: return self._xml_long() def _xml_long(self): return '<long>%s</long>' % self.value def _xml_float(self): return '<double>%s</double>' % repr(self.value) def _xml_complex(self): return '<complex>%s</double>' % repr(self.value) class StringCell(BaseCell): def __init__(self, text, fmt="%s", alignment=LEFT): assert isinstance(text, (str, unicode)) assert alignment in (LEFT, CENTER, RIGHT) self.text = text self.fmt = fmt self.alignment = alignment def recalc(self, rexec): return self.text def format(self): return self.text, self.alignment def xml(self): s = '<value align="%s" format="%s"><string>%s</string></value>' return s % ( align2xml[self.alignment], self.fmt, cgi.escape(self.text)) class FormulaCell(BaseCell): def __init__(self, formula, fmt="%s", alignment=RIGHT): assert alignment in (LEFT, CENTER, RIGHT) self.formula = formula self.translated = translate(self.formula) self.fmt = fmt self.alignment = alignment self.reset() def reset(self): self.value = None def recalc(self, rexec): if self.value is None: try: # A hack to evaluate expressions using true division rexec.r_exec("from __future__ import division\n" + "__value__ = eval(%s)" % repr(self.translated)) self.value = rexec.r_eval("__value__") except: exc = sys.exc_info()[0] if hasattr(exc, "__name__"): self.value = exc.__name__ else: self.value = str(exc) return self.value def format(self): try: text = self.fmt % self.value except: text = str(self.value) return text, self.alignment def xml(self): return '<formula align="%s" format="%s">%s</formula>' % ( align2xml[self.alignment], self.fmt, self.formula) def renumber(self, x1, y1, x2, y2, dx, dy): out = [] for part in re.split('(\w+)', self.formula): m = re.match('^([A-Z]+)([1-9][0-9]*)$', part) if m is not None: sx, sy = m.groups() x = colname2num(sx) y = int(sy) if x1 <= x <= x2 and y1 <= y <= y2: part = cellname(x+dx, y+dy) out.append(part) return FormulaCell("".join(out), self.fmt, self.alignment) def translate(formula): """Translate a formula containing fancy cell names to valid Python code. Examples: B4 -> cell(2, 4) B4:Z100 -> cells(2, 4, 26, 100) """ out = [] for part in re.split(r"(\w+(?::\w+)?)", formula): m = re.match(r"^([A-Z]+)([1-9][0-9]*)(?::([A-Z]+)([1-9][0-9]*))?$", part) if m is None: out.append(part) else: x1, y1, x2, y2 = m.groups() x1 = colname2num(x1) if x2 is None: s = "cell(%s, %s)" % (x1, y1) else: x2 = colname2num(x2) s = "cells(%s, %s, %s, %s)" % (x1, y1, x2, y2) out.append(s) return "".join(out) def cellname(x, y): "Translate a cell coordinate to a fancy cell name (e.g. (1, 1)->'A1')." assert x > 0 # Column 0 has an empty name, so can't use that return colnum2name(x) + str(y) def colname2num(s): "Translate a column name to number (e.g. 'A'->1, 'Z'->26, 'AA'->27)." s = s.upper() n = 0 for c in s: assert 'A' <= c <= 'Z' n = n*26 + ord(c) - ord('A') + 1 return n def colnum2name(n): "Translate a column number to name (e.g. 1->'A', etc.)." assert n > 0 s = "" while n: n, m = divmod(n-1, 26) s = chr(m+ord('A')) + s return s import Tkinter as Tk class SheetGUI: """Beginnings of a GUI for a spreadsheet. TO DO: - clear multiple cells - Insert, clear, remove rows or columns - Show new contents while typing - Scroll bars - Grow grid when window is grown - Proper menus - Undo, redo - Cut, copy and paste - Formatting and alignment """ def __init__(self, filename="sheet1.xml", rows=10, columns=5): """Constructor. Load the sheet from the filename argument. Set up the Tk widget tree. """ # Create and load the sheet self.filename = filename self.sheet = Sheet() if os.path.isfile(filename): self.sheet.load(filename) # Calculate the needed grid size maxx, maxy = self.sheet.getsize() rows = max(rows, maxy) columns = max(columns, maxx) # Create the widgets self.root = Tk.Tk() self.root.wm_title("Spreadsheet: %s" % self.filename) self.beacon = Tk.Label(self.root, text="A1", font=('helvetica', 16, 'bold')) self.entry = Tk.Entry(self.root) self.savebutton = Tk.Button(self.root, text="Save", command=self.save) self.cellgrid = Tk.Frame(self.root) # Configure the widget lay-out self.cellgrid.pack(side="bottom", expand=1, fill="both") self.beacon.pack(side="left") self.savebutton.pack(side="right") self.entry.pack(side="left", expand=1, fill="x") # Bind some events self.entry.bind("<Return>", self.return_event) self.entry.bind("<Shift-Return>", self.shift_return_event) self.entry.bind("<Tab>", self.tab_event) self.entry.bind("<Shift-Tab>", self.shift_tab_event) self.entry.bind("<Delete>", self.delete_event) self.entry.bind("<Escape>", self.escape_event) # Now create the cell grid self.makegrid(rows, columns) # Select the top-left cell self.currentxy = None self.cornerxy = None self.setcurrent(1, 1) # Copy the sheet cells to the GUI cells self.sync() def delete_event(self, event): if self.cornerxy != self.currentxy and self.cornerxy is not None: self.sheet.clearcells(*(self.currentxy + self.cornerxy)) else: self.sheet.clearcell(*self.currentxy) self.sync() self.entry.delete(0, 'end') return "break" def escape_event(self, event): x, y = self.currentxy self.load_entry(x, y) def load_entry(self, x, y): cell = self.sheet.getcell(x, y) if cell is None: text = "" elif isinstance(cell, FormulaCell): text = '=' + cell.formula else: text, alignment = cell.format() self.entry.delete(0, 'end') self.entry.insert(0, text) self.entry.selection_range(0, 'end') def makegrid(self, rows, columns): """Helper to create the grid of GUI cells. The edge (x==0 or y==0) is filled with labels; the rest is real cells. """ self.rows = rows self.columns = columns self.gridcells = {} # Create the top left corner cell (which selects all) cell = Tk.Label(self.cellgrid, relief='raised') cell.grid_configure(column=0, row=0, sticky='NSWE') cell.bind("<ButtonPress-1>", self.selectall) # Create the top row of labels, and confiure the grid columns for x in range(1, columns+1): self.cellgrid.grid_columnconfigure(x, minsize=64) cell = Tk.Label(self.cellgrid, text=colnum2name(x), relief='raised') cell.grid_configure(column=x, row=0, sticky='WE') self.gridcells[x, 0] = cell cell.__x = x cell.__y = 0 cell.bind("<ButtonPress-1>", self.selectcolumn) cell.bind("<B1-Motion>", self.extendcolumn) cell.bind("<ButtonRelease-1>", self.extendcolumn) cell.bind("<Shift-Button-1>", self.extendcolumn) # Create the leftmost column of labels for y in range(1, rows+1): cell = Tk.Label(self.cellgrid, text=str(y), relief='raised') cell.grid_configure(column=0, row=y, sticky='WE') self.gridcells[0, y] = cell cell.__x = 0 cell.__y = y cell.bind("<ButtonPress-1>", self.selectrow) cell.bind("<B1-Motion>", self.extendrow) cell.bind("<ButtonRelease-1>", self.extendrow) cell.bind("<Shift-Button-1>", self.extendrow) # Create the real cells for x in range(1, columns+1): for y in range(1, rows+1): cell = Tk.Label(self.cellgrid, relief='sunken', bg='white', fg='black') cell.grid_configure(column=x, row=y, sticky='NSWE') self.gridcells[x, y] = cell cell.__x = x cell.__y = y # Bind mouse events cell.bind("<ButtonPress-1>", self.press) cell.bind("<B1-Motion>", self.motion) cell.bind("<ButtonRelease-1>", self.release) cell.bind("<Shift-Button-1>", self.release) def selectall(self, event): self.setcurrent(1, 1) self.setcorner(sys.maxint, sys.maxint) def selectcolumn(self, event): x, y = self.whichxy(event) self.setcurrent(x, 1) self.setcorner(x, sys.maxint) def extendcolumn(self, event): x, y = self.whichxy(event) if x > 0: self.setcurrent(self.currentxy[0], 1) self.setcorner(x, sys.maxint) def selectrow(self, event): x, y = self.whichxy(event) self.setcurrent(1, y) self.setcorner(sys.maxint, y) def extendrow(self, event): x, y = self.whichxy(event) if y > 0: self.setcurrent(1, self.currentxy[1]) self.setcorner(sys.maxint, y) def press(self, event): x, y = self.whichxy(event) if x > 0 and y > 0: self.setcurrent(x, y) def motion(self, event): x, y = self.whichxy(event) if x > 0 and y > 0: self.setcorner(x, y) release = motion def whichxy(self, event): w = self.cellgrid.winfo_containing(event.x_root, event.y_root) if w is not None and isinstance(w, Tk.Label): try: return w.__x, w.__y except AttributeError: pass return 0, 0 def save(self): self.sheet.save(self.filename) def setcurrent(self, x, y): "Make (x, y) the current cell." if self.currentxy is not None: self.change_cell() self.clearfocus() self.beacon['text'] = cellname(x, y) self.load_entry(x, y) self.entry.focus_set() self.currentxy = x, y self.cornerxy = None gridcell = self.gridcells.get(self.currentxy) if gridcell is not None: gridcell['bg'] = 'yellow' def setcorner(self, x, y): if self.currentxy is None or self.currentxy == (x, y): self.setcurrent(x, y) return self.clearfocus() self.cornerxy = x, y x1, y1 = self.currentxy x2, y2 = self.cornerxy or self.currentxy if x1 > x2: x1, x2 = x2, x1 if y1 > y2: y1, y2 = y2, y1 for (x, y), cell in self.gridcells.iteritems(): if x1 <= x <= x2 and y1 <= y <= y2: cell['bg'] = 'lightBlue' gridcell = self.gridcells.get(self.currentxy) if gridcell is not None: gridcell['bg'] = 'yellow' self.setbeacon(x1, y1, x2, y2) def setbeacon(self, x1, y1, x2, y2): if x1 == y1 == 1 and x2 == y2 == sys.maxint: name = ":" elif (x1, x2) == (1, sys.maxint): if y1 == y2: name = "%d" % y1 else: name = "%d:%d" % (y1, y2) elif (y1, y2) == (1, sys.maxint): if x1 == x2: name = "%s" % colnum2name(x1) else: name = "%s:%s" % (colnum2name(x1), colnum2name(x2)) else: name1 = cellname(*self.currentxy) name2 = cellname(*self.cornerxy) name = "%s:%s" % (name1, name2) self.beacon['text'] = name def clearfocus(self): if self.currentxy is not None: x1, y1 = self.currentxy x2, y2 = self.cornerxy or self.currentxy if x1 > x2: x1, x2 = x2, x1 if y1 > y2: y1, y2 = y2, y1 for (x, y), cell in self.gridcells.iteritems(): if x1 <= x <= x2 and y1 <= y <= y2: cell['bg'] = 'white' def return_event(self, event): "Callback for the Return key." self.change_cell() x, y = self.currentxy self.setcurrent(x, y+1) return "break" def shift_return_event(self, event): "Callback for the Return key with Shift modifier." self.change_cell() x, y = self.currentxy self.setcurrent(x, max(1, y-1)) return "break" def tab_event(self, event): "Callback for the Tab key." self.change_cell() x, y = self.currentxy self.setcurrent(x+1, y) return "break" def shift_tab_event(self, event): "Callback for the Tab key with Shift modifier." self.change_cell() x, y = self.currentxy self.setcurrent(max(1, x-1), y) return "break" def change_cell(self): "Set the current cell from the entry widget." x, y = self.currentxy text = self.entry.get() cell = None if text.startswith('='): cell = FormulaCell(text[1:]) else: for cls in int, long, float, complex: try: value = cls(text) except: continue else: cell = NumericCell(value) break if cell is None and text: cell = StringCell(text) if cell is None: self.sheet.clearcell(x, y) else: self.sheet.setcell(x, y, cell) self.sync() def sync(self): "Fill the GUI cells from the sheet cells." self.sheet.recalc() for (x, y), gridcell in self.gridcells.iteritems(): if x == 0 or y == 0: continue cell = self.sheet.getcell(x, y) if cell is None: gridcell['text'] = "" else: if hasattr(cell, 'format'): text, alignment = cell.format() else: text, alignment = str(cell), LEFT gridcell['text'] = text gridcell['anchor'] = align2anchor[alignment] def test_basic(): "Basic non-gui self-test." import os a = Sheet() for x in range(1, 11): for y in range(1, 11): if x == 1: cell = NumericCell(y) elif y == 1: cell = NumericCell(x) else: c1 = cellname(x, 1) c2 = cellname(1, y) formula = "%s*%s" % (c1, c2) cell = FormulaCell(formula) a.setcell(x, y, cell) ## if os.path.isfile("sheet1.xml"): ## print "Loading from sheet1.xml" ## a.load("sheet1.xml") a.display() a.save("sheet1.xml") def test_gui(): "GUI test." if sys.argv[1:]: filename = sys.argv[1] else: filename = "sheet1.xml" g = SheetGUI(filename) g.root.mainloop() if __name__ == '__main__': #test_basic() test_gui()