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# $Id: tableparser.py 9038 2022-03-05 23:31:46Z milde $
# Author: David Goodger <goodger@python.org>
# Copyright: This module has been placed in the public domain.
"""
This module defines table parser classes,which parse plaintext-graphic tables
and produce a well-formed data structure suitable for building a CALS table.
:Classes:
- `GridTableParser`: Parse fully-formed tables represented with a grid.
- `SimpleTableParser`: Parse simple tables, delimited by top & bottom
borders.
:Exception class: `TableMarkupError`
:Function:
`update_dict_of_lists()`: Merge two dictionaries containing list values.
"""
__docformat__ = 'reStructuredText'
import re
import sys
from docutils import DataError
from docutils.utils import strip_combining_chars
class TableMarkupError(DataError):
"""
Raise if there is any problem with table markup.
The keyword argument `offset` denotes the offset of the problem
from the table's start line.
"""
def __init__(self, *args, **kwargs):
self.offset = kwargs.pop('offset', 0)
DataError.__init__(self, *args)
class TableParser:
"""
Abstract superclass for the common parts of the syntax-specific parsers.
"""
head_body_separator_pat = None
"""Matches the row separator between head rows and body rows."""
double_width_pad_char = '\x00'
"""Padding character for East Asian double-width text."""
def parse(self, block):
"""
Analyze the text `block` and return a table data structure.
Given a plaintext-graphic table in `block` (list of lines of text; no
whitespace padding), parse the table, construct and return the data
necessary to construct a CALS table or equivalent.
Raise `TableMarkupError` if there is any problem with the markup.
"""
self.setup(block)
self.find_head_body_sep()
self.parse_table()
return self.structure_from_cells()
def find_head_body_sep(self):
"""Look for a head/body row separator line; store the line index."""
for i in range(len(self.block)):
line = self.block[i]
if self.head_body_separator_pat.match(line):
if self.head_body_sep:
raise TableMarkupError(
'Multiple head/body row separators '
'(table lines %s and %s); only one allowed.'
% (self.head_body_sep+1, i+1), offset=i)
else:
self.head_body_sep = i
self.block[i] = line.replace('=', '-')
if self.head_body_sep == 0 or self.head_body_sep == (len(self.block)
- 1):
raise TableMarkupError('The head/body row separator may not be '
'the first or last line of the table.',
offset=i)
class GridTableParser(TableParser):
"""
Parse a grid table using `parse()`.
Here's an example of a grid table::
+------------------------+------------+----------+----------+
| Header row, column 1 | Header 2 | Header 3 | Header 4 |
+========================+============+==========+==========+
| body row 1, column 1 | column 2 | column 3 | column 4 |
+------------------------+------------+----------+----------+
| body row 2 | Cells may span columns. |
+------------------------+------------+---------------------+
| body row 3 | Cells may | - Table cells |
+------------------------+ span rows. | - contain |
| body row 4 | | - body elements. |
+------------------------+------------+---------------------+
Intersections use '+', row separators use '-' (except for one optional
head/body row separator, which uses '='), and column separators use '|'.
Passing the above table to the `parse()` method will result in the
following data structure::
([24, 12, 10, 10],
[[(0, 0, 1, ['Header row, column 1']),
(0, 0, 1, ['Header 2']),
(0, 0, 1, ['Header 3']),
(0, 0, 1, ['Header 4'])]],
[[(0, 0, 3, ['body row 1, column 1']),
(0, 0, 3, ['column 2']),
(0, 0, 3, ['column 3']),
(0, 0, 3, ['column 4'])],
[(0, 0, 5, ['body row 2']),
(0, 2, 5, ['Cells may span columns.']),
None,
None],
[(0, 0, 7, ['body row 3']),
(1, 0, 7, ['Cells may', 'span rows.', '']),
(1, 1, 7, ['- Table cells', '- contain', '- body elements.']),
None],
[(0, 0, 9, ['body row 4']), None, None, None]])
The first item is a list containing column widths (colspecs). The second
item is a list of head rows, and the third is a list of body rows. Each
row contains a list of cells. Each cell is either None (for a cell unused
because of another cell's span), or a tuple. A cell tuple contains four
items: the number of extra rows used by the cell in a vertical span
(morerows); the number of extra columns used by the cell in a horizontal
span (morecols); the line offset of the first line of the cell contents;
and the cell contents, a list of lines of text.
"""
head_body_separator_pat = re.compile(r'\+=[=+]+=\+ *$')
def setup(self, block):
self.block = block[:] # make a copy; it may be modified
self.block.disconnect() # don't propagate changes to parent
self.bottom = len(block) - 1
self.right = len(block[0]) - 1
self.head_body_sep = None
self.done = [-1] * len(block[0])
self.cells = []
self.rowseps = {0: [0]}
self.colseps = {0: [0]}
def parse_table(self):
"""
Start with a queue of upper-left corners, containing the upper-left
corner of the table itself. Trace out one rectangular cell, remember
it, and add its upper-right and lower-left corners to the queue of
potential upper-left corners of further cells. Process the queue in
top-to-bottom order, keeping track of how much of each text column has
been seen.
We'll end up knowing all the row and column boundaries, cell positions
and their dimensions.
"""
corners = [(0, 0)]
while corners:
top, left = corners.pop(0)
if (top == self.bottom
or left == self.right
or top <= self.done[left]):
continue
result = self.scan_cell(top, left)
if not result:
continue
bottom, right, rowseps, colseps = result
update_dict_of_lists(self.rowseps, rowseps)
update_dict_of_lists(self.colseps, colseps)
self.mark_done(top, left, bottom, right)
cellblock = self.block.get_2D_block(top + 1, left + 1,
bottom, right)
cellblock.disconnect() # lines in cell can't sync with parent
cellblock.replace(self.double_width_pad_char, '')
self.cells.append((top, left, bottom, right, cellblock))
corners.extend([(top, right), (bottom, left)])
corners.sort()
if not self.check_parse_complete():
raise TableMarkupError('Malformed table; parse incomplete.')
def mark_done(self, top, left, bottom, right):
"""For keeping track of how much of each text column has been seen."""
before = top - 1
after = bottom - 1
for col in range(left, right):
assert self.done[col] == before
self.done[col] = after
def check_parse_complete(self):
"""Each text column should have been completely seen."""
last = self.bottom - 1
for col in range(self.right):
if self.done[col] != last:
return False
return True
def scan_cell(self, top, left):
"""Starting at the top-left corner, start tracing out a cell."""
assert self.block[top][left] == '+'
return self.scan_right(top, left)
def scan_right(self, top, left):
"""
Look for the top-right corner of the cell, and make note of all column
boundaries ('+').
"""
colseps = {}
line = self.block[top]
for i in range(left + 1, self.right + 1):
if line[i] == '+':
colseps[i] = [top]
result = self.scan_down(top, left, i)
if result:
bottom, rowseps, newcolseps = result
update_dict_of_lists(colseps, newcolseps)
return bottom, i, rowseps, colseps
elif line[i] != '-':
return None
return None
def scan_down(self, top, left, right):
"""
Look for the bottom-right corner of the cell, making note of all row
boundaries.
"""
rowseps = {}
for i in range(top + 1, self.bottom + 1):
if self.block[i][right] == '+':
rowseps[i] = [right]
result = self.scan_left(top, left, i, right)
if result:
newrowseps, colseps = result
update_dict_of_lists(rowseps, newrowseps)
return i, rowseps, colseps
elif self.block[i][right] != '|':
return None
return None
def scan_left(self, top, left, bottom, right):
"""
Noting column boundaries, look for the bottom-left corner of the cell.
It must line up with the starting point.
"""
colseps = {}
line = self.block[bottom]
for i in range(right - 1, left, -1):
if line[i] == '+':
colseps[i] = [bottom]
elif line[i] != '-':
return None
if line[left] != '+':
return None
result = self.scan_up(top, left, bottom, right)
if result is not None:
rowseps = result
return rowseps, colseps
return None
def scan_up(self, top, left, bottom, right):
"""
Noting row boundaries, see if we can return to the starting point.
"""
rowseps = {}
for i in range(bottom - 1, top, -1):
if self.block[i][left] == '+':
rowseps[i] = [left]
elif self.block[i][left] != '|':
return None
return rowseps
def structure_from_cells(self):
"""
From the data collected by `scan_cell()`, convert to the final data
structure.
"""
rowseps = sorted(self.rowseps.keys()) # list of row boundaries
rowindex = {}
for i in range(len(rowseps)):
rowindex[rowseps[i]] = i # row boundary -> row number mapping
colseps = sorted(self.colseps.keys()) # list of column boundaries
colindex = {}
for i in range(len(colseps)):
colindex[colseps[i]] = i # column boundary -> col number map
colspecs = [(colseps[i] - colseps[i - 1] - 1)
for i in range(1, len(colseps))] # list of column widths
# prepare an empty table with the correct number of rows & columns
onerow = [None for i in range(len(colseps) - 1)]
rows = [onerow[:] for i in range(len(rowseps) - 1)]
# keep track of # of cells remaining; should reduce to zero
remaining = (len(rowseps) - 1) * (len(colseps) - 1)
for top, left, bottom, right, block in self.cells:
rownum = rowindex[top]
colnum = colindex[left]
assert rows[rownum][colnum] is None, (
'Cell (row %s, column %s) already used.'
% (rownum + 1, colnum + 1))
morerows = rowindex[bottom] - rownum - 1
morecols = colindex[right] - colnum - 1
remaining -= (morerows + 1) * (morecols + 1)
# write the cell into the table
rows[rownum][colnum] = (morerows, morecols, top + 1, block)
assert remaining == 0, 'Unused cells remaining.'
if self.head_body_sep: # separate head rows from body rows
numheadrows = rowindex[self.head_body_sep]
headrows = rows[:numheadrows]
bodyrows = rows[numheadrows:]
else:
headrows = []
bodyrows = rows
return colspecs, headrows, bodyrows
class SimpleTableParser(TableParser):
"""
Parse a simple table using `parse()`.
Here's an example of a simple table::
===== =====
col 1 col 2
===== =====
1 Second column of row 1.
2 Second column of row 2.
Second line of paragraph.
3 - Second column of row 3.
- Second item in bullet
list (row 3, column 2).
4 is a span
------------
5
===== =====
Top and bottom borders use '=', column span underlines use '-', column
separation is indicated with spaces.
Passing the above table to the `parse()` method will result in the
following data structure, whose interpretation is the same as for
`GridTableParser`::
([5, 25],
[[(0, 0, 1, ['col 1']),
(0, 0, 1, ['col 2'])]],
[[(0, 0, 3, ['1']),
(0, 0, 3, ['Second column of row 1.'])],
[(0, 0, 4, ['2']),
(0, 0, 4, ['Second column of row 2.',
'Second line of paragraph.'])],
[(0, 0, 6, ['3']),
(0, 0, 6, ['- Second column of row 3.',
'',
'- Second item in bullet',
' list (row 3, column 2).'])],
[(0, 1, 10, ['4 is a span'])],
[(0, 0, 12, ['5']),
(0, 0, 12, [''])]])
"""
head_body_separator_pat = re.compile('=[ =]*$')
span_pat = re.compile('-[ -]*$')
def setup(self, block):
self.block = block[:] # make a copy; it will be modified
self.block.disconnect() # don't propagate changes to parent
# Convert top & bottom borders to column span underlines:
self.block[0] = self.block[0].replace('=', '-')
self.block[-1] = self.block[-1].replace('=', '-')
self.head_body_sep = None
self.columns = []
self.border_end = None
self.table = []
self.done = [-1] * len(block[0])
self.rowseps = {0: [0]}
self.colseps = {0: [0]}
def parse_table(self):
"""
First determine the column boundaries from the top border, then
process rows. Each row may consist of multiple lines; accumulate
lines until a row is complete. Call `self.parse_row` to finish the
job.
"""
# Top border must fully describe all table columns.
self.columns = self.parse_columns(self.block[0], 0)
self.border_end = self.columns[-1][1]
firststart, firstend = self.columns[0]
offset = 1 # skip top border
start = 1
text_found = None
while offset < len(self.block):
line = self.block[offset]
if self.span_pat.match(line):
# Column span underline or border; row is complete.
self.parse_row(self.block[start:offset], start,
(line.rstrip(), offset))
start = offset + 1
text_found = None
elif line[firststart:firstend].strip():
# First column not blank, therefore it's a new row.
if text_found and offset != start:
self.parse_row(self.block[start:offset], start)
start = offset
text_found = 1
elif not text_found:
start = offset + 1
offset += 1
def parse_columns(self, line, offset):
"""
Given a column span underline, return a list of (begin, end) pairs.
"""
cols = []
end = 0
while True:
begin = line.find('-', end)
end = line.find(' ', begin)
if begin < 0:
break
if end < 0:
end = len(line)
cols.append((begin, end))
if self.columns:
if cols[-1][1] != self.border_end:
raise TableMarkupError('Column span incomplete in table '
'line %s.' % (offset+1),
offset=offset)
# Allow for an unbounded rightmost column:
cols[-1] = (cols[-1][0], self.columns[-1][1])
return cols
def init_row(self, colspec, offset):
i = 0
cells = []
for start, end in colspec:
morecols = 0
try:
assert start == self.columns[i][0]
while end != self.columns[i][1]:
i += 1
morecols += 1
except (AssertionError, IndexError):
raise TableMarkupError('Column span alignment problem '
'in table line %s.' % (offset+2),
offset=offset+1)
cells.append([0, morecols, offset, []])
i += 1
return cells
def parse_row(self, lines, start, spanline=None):
"""
Given the text `lines` of a row, parse it and append to `self.table`.
The row is parsed according to the current column spec (either
`spanline` if provided or `self.columns`). For each column, extract
text from each line, and check for text in column margins. Finally,
adjust for insignificant whitespace.
"""
if not (lines or spanline):
# No new row, just blank lines.
return
if spanline:
columns = self.parse_columns(*spanline)
else:
columns = self.columns[:]
self.check_columns(lines, start, columns)
row = self.init_row(columns, start)
for i in range(len(columns)):
start, end = columns[i]
cellblock = lines.get_2D_block(0, start, len(lines), end)
cellblock.disconnect() # lines in cell can't sync with parent
cellblock.replace(self.double_width_pad_char, '')
row[i][3] = cellblock
self.table.append(row)
def check_columns(self, lines, first_line, columns):
"""
Check for text in column margins and text overflow in the last column.
Raise TableMarkupError if anything but whitespace is in column margins.
Adjust the end value for the last column if there is text overflow.
"""
# "Infinite" value for a dummy last column's beginning, used to
# check for text overflow:
columns.append((sys.maxsize, None))
lastcol = len(columns) - 2
# combining characters do not contribute to the column width
lines = [strip_combining_chars(line) for line in lines]
for i in range(len(columns) - 1):
start, end = columns[i]
nextstart = columns[i+1][0]
offset = 0
for line in lines:
if i == lastcol and line[end:].strip():
text = line[start:].rstrip()
new_end = start + len(text)
main_start, main_end = self.columns[-1]
columns[i] = (start, max(main_end, new_end))
if new_end > main_end:
self.columns[-1] = (main_start, new_end)
elif line[end:nextstart].strip():
raise TableMarkupError('Text in column margin in table '
'line %s.' % (first_line+offset+1),
offset=first_line+offset)
offset += 1
columns.pop()
def structure_from_cells(self):
colspecs = [end - start for start, end in self.columns]
first_body_row = 0
if self.head_body_sep:
for i in range(len(self.table)):
if self.table[i][0][2] > self.head_body_sep:
first_body_row = i
break
return (colspecs, self.table[:first_body_row],
self.table[first_body_row:])
def update_dict_of_lists(master, newdata):
"""
Extend the list values of `master` with those from `newdata`.
Both parameters must be dictionaries containing list values.
"""
for key, values in newdata.items():
master.setdefault(key, []).extend(values)
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