Lib.xlwt.Bitmap.py Maven / Gradle / Ivy
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... for visual testing and automation
# -*- coding: windows-1251 -*-
# Portions are Copyright (C) 2005 Roman V. Kiseliov
# Portions are Copyright (c) 2004 Evgeny Filatov
# Portions are Copyright (c) 2002-2004 John McNamara (Perl Spreadsheet::WriteExcel)
from BIFFRecords import BiffRecord
from struct import pack, unpack
def _size_col(sheet, col):
return sheet.col_width(col)
def _size_row(sheet, row):
return sheet.row_height(row)
def _position_image(sheet, row_start, col_start, x1, y1, width, height):
"""Calculate the vertices that define the position of the image as required by
the OBJ record.
+------------+------------+
| A | B |
+-----+------------+------------+
| |(x1,y1) | |
| 1 |(A1)._______|______ |
| | | | |
| | | | |
+-----+----| BITMAP |-----+
| | | | |
| 2 | |______________. |
| | | (B2)|
| | | (x2,y2)|
+---- +------------+------------+
Example of a bitmap that covers some of the area from cell A1 to cell B2.
Based on the width and height of the bitmap we need to calculate 8 vars:
col_start, row_start, col_end, row_end, x1, y1, x2, y2.
The width and height of the cells are also variable and have to be taken into
account.
The values of col_start and row_start are passed in from the calling
function. The values of col_end and row_end are calculated by subtracting
the width and height of the bitmap from the width and height of the
underlying cells.
The vertices are expressed as a percentage of the underlying cell width as
follows (rhs values are in pixels):
x1 = X / W *1024
y1 = Y / H *256
x2 = (X-1) / W *1024
y2 = (Y-1) / H *256
Where: X is distance from the left side of the underlying cell
Y is distance from the top of the underlying cell
W is the width of the cell
H is the height of the cell
Note: the SDK incorrectly states that the height should be expressed as a
percentage of 1024.
col_start - Col containing upper left corner of object
row_start - Row containing top left corner of object
x1 - Distance to left side of object
y1 - Distance to top of object
width - Width of image frame
height - Height of image frame
"""
# Adjust start column for offsets that are greater than the col width
while x1 >= _size_col(sheet, col_start):
x1 -= _size_col(sheet, col_start)
col_start += 1
# Adjust start row for offsets that are greater than the row height
while y1 >= _size_row(sheet, row_start):
y1 -= _size_row(sheet, row_start)
row_start += 1
# Initialise end cell to the same as the start cell
row_end = row_start # Row containing bottom right corner of object
col_end = col_start # Col containing lower right corner of object
width = width + x1 - 1
height = height + y1 - 1
# Subtract the underlying cell widths to find the end cell of the image
while (width >= _size_col(sheet, col_end)):
width -= _size_col(sheet, col_end)
col_end += 1
# Subtract the underlying cell heights to find the end cell of the image
while (height >= _size_row(sheet, row_end)):
height -= _size_row(sheet, row_end)
row_end += 1
# Bitmap isn't allowed to start or finish in a hidden cell, i.e. a cell
# with zero height or width.
if ((_size_col(sheet, col_start) == 0) or (_size_col(sheet, col_end) == 0)
or (_size_row(sheet, row_start) == 0) or (_size_row(sheet, row_end) == 0)):
return
# Convert the pixel values to the percentage value expected by Excel
x1 = int(float(x1) / _size_col(sheet, col_start) * 1024)
y1 = int(float(y1) / _size_row(sheet, row_start) * 256)
# Distance to right side of object
x2 = int(float(width) / _size_col(sheet, col_end) * 1024)
# Distance to bottom of object
y2 = int(float(height) / _size_row(sheet, row_end) * 256)
return (col_start, x1, row_start, y1, col_end, x2, row_end, y2)
class ObjBmpRecord(BiffRecord):
_REC_ID = 0x005D # Record identifier
def __init__(self, row, col, sheet, im_data_bmp, x, y, scale_x, scale_y):
# Scale the frame of the image.
width = im_data_bmp.width * scale_x
height = im_data_bmp.height * scale_y
# Calculate the vertices of the image and write the OBJ record
coordinates = _position_image(sheet, row, col, x, y, width, height)
# print coordinates
col_start, x1, row_start, y1, col_end, x2, row_end, y2 = coordinates
"""Store the OBJ record that precedes an IMDATA record. This could be generalise
to support other Excel objects.
"""
cObj = 0x0001 # Count of objects in file (set to 1)
OT = 0x0008 # Object type. 8 = Picture
id = 0x0001 # Object ID
grbit = 0x0614 # Option flags
colL = col_start # Col containing upper left corner of object
dxL = x1 # Distance from left side of cell
rwT = row_start # Row containing top left corner of object
dyT = y1 # Distance from top of cell
colR = col_end # Col containing lower right corner of object
dxR = x2 # Distance from right of cell
rwB = row_end # Row containing bottom right corner of object
dyB = y2 # Distance from bottom of cell
cbMacro = 0x0000 # Length of FMLA structure
Reserved1 = 0x0000 # Reserved
Reserved2 = 0x0000 # Reserved
icvBack = 0x09 # Background colour
icvFore = 0x09 # Foreground colour
fls = 0x00 # Fill pattern
fAuto = 0x00 # Automatic fill
icv = 0x08 # Line colour
lns = 0xff # Line style
lnw = 0x01 # Line weight
fAutoB = 0x00 # Automatic border
frs = 0x0000 # Frame style
cf = 0x0009 # Image format, 9 = bitmap
Reserved3 = 0x0000 # Reserved
cbPictFmla = 0x0000 # Length of FMLA structure
Reserved4 = 0x0000 # Reserved
grbit2 = 0x0001 # Option flags
Reserved5 = 0x0000 # Reserved
data = pack(" 0xFFFF):
raise Exception("bitmap: largest image width supported is 65k.")
if (height > 0xFFFF):
raise Exception("bitmap: largest image height supported is 65k.")
# Read and remove the bitmap planes and bpp data. Verify them.
planes, bitcount = unpack("