def mod(gfile):
'''For each of the files to process either rotate, move, copy, or
replicate the code. General idea:
read in ascii
Process into a toolpath list.
modify.
Write out toolpath.'''
start = datetime.now()
puts(
colored.blue('Modifying file: %s\n Started: %s' %
(gfile.name, datetime.now())))
# Parse the gcode.
gcode = GCode(gfile)
gcode.parseAll()
# Create a toolpath from the gcode
# add in the index so that we can match it to the gcode
out = []
if args.move:
loc = parse(args.move, getUnits=True) # only one move at a time.
puts(
colored.blue('Moving!\n (0,0) -> (%.3f,%.3f)' %
(loc[0], loc[1])))
tool = Tool()
# is the addIndex atribut even used any longer?
tool.build(gcode, addIndex=True)
tool.move(loc) # ok well this should work
gcode.update(tool)
out.append([loc, gcode])
if args.copy:
locs = parse(args.copy, getUnits=True)
puts(colored.blue('Copying!'))
for loc in locs:
puts(colored.blue(' (0,0) -> (%.3f,%.3f)' % (loc[0], loc[1])))
gc = gcode.copy()
tool = Tool()
# is the addIndex atribut even used any longer?
tool.build(gc, addIndex=True)
tool.move(loc)
gc.update(tool)
out.append([loc, gc])
# if args.replicate:
# nxy = map(int,parse(args.replicate)[0]) # ensure int, and only one
# puts(colored.blue('Replicating!\n nx=%i, ny=%i)'%(nxy[0],nxy[1])))
output = ''.join([o.getGcode(tag=args.name, start=l) for l, o in out])
outfile = FILEENDING.join(os.path.splitext(gfile.name))
puts(colored.green('Writing: %s' % outfile))
with open(outfile, 'w') as f:
f.write(output)
# how long did this take?
puts(colored.green('Time to completion: %s' % (deltaTime(start))))
print
def main(etch_file, args=None):
start = datetime.now()
name = etch_file if isinstance(etch_file, str) else etch_file.name
puts(
colored.blue('Visualizing the file: %s\n Started: %s' %
(name, datetime.now())))
# Read in the gcode
gcode = GCode(etch_file, limit=None)
gcode.parse()
# parse the code into an array of tool moves
tool = Tool(gcode)
box = tool.boundBox()
# proces and save image
outfile = os.path.splitext(etch_file.name)[0] + '.eps'
print box
print box[0:2]
image = Drawing(outfile) #, bbox=box)
image.process(tool)
image.save()
# how long did this take?
puts(colored.green('Time to completion: %s' % (deltaTime(start))))
print
def main(gfile, args=None):
start = datetime.now()
name = gfile if isinstance(gfile, str) else gfile.name
puts(
colored.blue('Visualizing the file: %s\n Started: %s' %
(name, datetime.now())))
# Read in the gcode
gcode = GCode(gfile, limit=None)
gcode.parse()
# parse the code into an array of tool moves
tool = Tool(gcode)
tool.uniq()
box = tool.boundBox()
# proces and save image
ext = args.ext if args is not None else '.pdf'
outfile = os.path.splitext(gfile.name)[0] + FILEENDING + ext
print box
print box[0:2]
image = Image(outfile, gridsize=box[0:2])
image.process(tool)
image.save()
# how long did this take?
puts(colored.green('Time to completion: %s' % (deltaTime(start))))
print
def run(self):
#清理目录下存在的图片
Tool().clear_picture()
#生成测试套件
suit = unittest.TestSuite()
#获取测试用例
cases = unittest.defaultTestLoader.discover(WEBCASE_PATH, '*.py')
#循环添加测试用例至测试套件
for case in cases:
suit.addTest(case)
#测试报告
report_name = os.path.join(REPOR_TPATH, 'UI测试报告.html')
f = open(report_name, 'wb')
#以报告模版运行用例
runner = HTMLTestRunner(f,
verbosity=1,
title='测试报告',
description='用例执行情况:')
res = runner.run(suit)
#将报告文件写入磁盘,并关闭文件
f.flush()
f.close()
success = res.success_count
failure = res.failure_count
#发送报告邮件
title = 'UI测试报告'
msg = '''
大家好:
本次UI测试结果如下:
通过用例:%s条。
失败用例:%s条。
详情信息请看附件【%s】
''' % (success, failure, os.path.basename(report_name))
def __init__(self):
self.tool = Tool()
self.yml = self.tool.app_data
self.devices = self.yml.get('devices')
self.app = self.yml.get('tester')
self.device_type = self.yml.get('device_type')
self.ports = []
def __init__(self):
self.tool = Tool()
# 获取所有配置信息 字典格式
self.yml = self.tool.app_data
self.device_type = self.yml.get('device_type')
self.tester = self.yml.get('tester')
self.devices = self.yml.get('devices')
self.deviceName = self.devices.get(
self.device_type)[0].get('deviceName')
self.ports = []
def __init__(self):
self.tool = Tool()
# 配置信息
self.yml = self.tool.app_data
# 所有手机配置信息
self.devices = self.yml.get('devices')
# 测试app的信息
self.app = self.yml.get('tester')
# Android OR iOS
self.device_type = self.yml.get('device_type')
# 用于校验服务是否成功,存储端口号
self.ports = []
def __init__(self):
self.tool = Tool()
#获取所有配置信息
self.yml = self.tool.app_data
#操作系统
self.device_type = self.yml.get('device_type')
#测试APP信息
self.tester = self.yml.get('tester')
#获取所有手机配置信息
self.devices = self.yml.get('devices')
#设备名称
self.deviceName = self.devices.get(
self.device_type)[0].get('deviceName')
#用于校验服务是否成功,存放端口号
self.ports = []
def run(self):
Tool().clear_picture()
suit = unittest.TestSuite()
cases = unittest.defaultTestLoader.discover(WEBCASEPATH)
for case in cases:
suit.addTest(case)
f = open(REPORTPATH, 'wb')
runner = HTMLTestRunner(f,
verbosity=1,
title='UI测试报告',
description='用例执行情况:')
res = runner.run(suit)
logger.info('共运行%s条,成功%s条,失败%s条' %
(res.all_count, res.success_count, res.failure_count))
f.flush()
f.close()
def _generate_report(self, result):
rows = []
sortedResult = self.sortResult(result.result)
for cid, (cls, cls_results) in enumerate(sortedResult):
# subtotal for a class
np = nf = ne = 0
for n, t, o, e in cls_results:
if n == 0:
np += 1
elif n == 1:
nf += 1
else:
ne += 1
# format class description
if cls.__module__ == "__main__":
name = cls.__name__
else:
name = "%s.%s" % (cls.__module__, cls.__name__)
doc = cls.__doc__ and cls.__doc__.split("\n")[0] or ""
desc = doc and '%s: %s' % (name, doc) or name
row = self.REPORT_CLASS_TMPL % dict(
style=ne > 0 and 'errorClass' or nf > 0 and 'failClass' or 'passClass',
desc=desc,
count=np + nf + ne,
Pass=np,
fail=nf,
error=ne,
cid='c%s' % (cid + 1),
)
rows.append(row)
from lib.tool import Tool
import os
pnglist = Tool().app_error_picture()
logger.debug(pnglist)
if len(pnglist) > 0:
Rewrite_results = []
for cls_p in cls_results:
name = cls_p[1].id().split('.')[-1]
for png in pnglist:
png_name = png[0].split('.')[2]
png_name = png_name.split('/')[-1]
if png_name == name:
tmp = cls_p + png
Rewrite_results.append(tmp)
break
else:
tmp = cls_p + ('',)
Rewrite_results.append(tmp)
for tid, (n, t, o, e, png) in enumerate(Rewrite_results):
self._generate_report_test(rows, cid, tid, n, t, o, e, png)
else:
for tid, (n, t, o, e) in enumerate(cls_results):
self._generate_report_test(rows, cid, tid, n, t, o, e)
report = self.REPORT_TMPL % dict(
test_list=''.join(rows),
count=str(result.success_count + result.failure_count + result.error_count),
Pass=str(result.success_count),
fail=str(result.failure_count),
error=str(result.error_count),
)
return report
def opt(gfile, offset=(0.0,0.0,0.0), rotate=False):
'''Optimization core function:
Reads in gCode ascii file.
Processes gcode into toolpath list
figures out milling.
Reorders milling to get optimal
Writes out to new file.'''
start = datetime.now()
puts(colored.blue('Optimizing file: %s\n Started: %s'%(gfile.name,datetime.now())))
# Parse the gcode from the ascii to a list of command numbers and location
gcode = GCode(gfile)
gcode.parse()
# Take the list and make a toolpath out of it. A toolpath is a list of locations
# where the bit needs to be moved / milled : [ [x,y,z,t], ...]
tool = Tool(gcode)
tool.offset(offset)
tool.rotate(rotate)
tool.groupMills()
puts(colored.blue('Toolpath length: %.2f inches, (mill only: %.2f)'%(tool.length(),tool.millLength())))
if args.setMillHeight:
tool.setMillHeight(Z_MILL,Z_SPOT)
tool.uniqMills()
# This starts the optimization process:
# start at here, and go to the next path which is closest is the overall plan
puts(colored.blue('Starting Optimization:'))
here = [0.0]*3 # start at the origin
newMills = [] # accumulate mills here
k = 0
while len(tool.mills) > 0:
# No Optimization
# mill = tool.mills.pop(0)
# Basic optimization, find the next closest one and use it.
# mill = tool.getNextMill(here)
# Advanced Optimization: Assumes that each mill path closed, so finds
# the mill path which is close to the point and reorders it to be so
mill = tool.getClosestMill(here)
# you were here, now you are there
# move mills and update location
newMills.append(mill)
here = newMills[-1][-1]
k += 1
if (k%10) == 0:
sys.stdout.write('.')
sys.stdout.flush()
tool.mills.extend(newMills)
tool.reTool(Z_MOVE)
tool.uniq()
puts(colored.blue('Toolpath length: %.2f inches, (mill only: %.2f)'%(tool.length(),tool.millLength())))
# Save this with the _opt file ending.
output = tool.buildGcode()
outfile = FILEENDING.join(os.path.splitext(gfile.name))
puts(colored.green('Writing: %s'%outfile))
with open(outfile,'w') as f:
f.write(output)
# how long did this take?
puts(colored.green('Time to completion: %s'%(deltaTime(start))))
print
def zcorrect_file(gfile,surface_file_name = 'probe_test.out'):
# Load the correction surface
correction_surface = CorrectionSurface(surface_file_name)
# keep track of time
start = datetime.now()
name = gfile if isinstance(gfile,str) else gfile.name
puts(colored.blue('Z correcting the file: %s\n Started: %s'%(name,datetime.now())))
# Load the gcode.
gcode = GCode(gfile)
#parse the Gcode
gcode.parseAll()
# start an empty list
#out = []
# need to get rid of use of 'loc'
# loc = parse(args.move, getUnits=True) # only one move at a time.
# puts(colored.blue('Moving!\n (0,0) -> (%.3f,%.3f)'%(loc[0],loc[1])))
# create a tool object (toolpath object)
tool = Tool()
# load the gcode into the tool object
tool.build(gcode)
# adjust the z position at each point by the given amount
tool.zcorrect(correction_surface)
''' the follwing doe not work. is gcode.update(tool) broken?'''
# load the changes back into the gcode object
# append the modified g code to the empty list called out
# out.append([gcode])
# gcode.update(tool)
# out = gcode
# convert gcode to text format
# output = ''.join([o.getGcode(tag=args.name) for o in out])
# output = ''.join([out.getGcode()])
'''instead the following simgle lin suffices'''
'''is any info lost by doing it this way? E F M'''
# generate a gcode file from the tool object
output = tool.buildGcode()
# get an output file name
outfile = FILEENDING.join(os.path.splitext(gfile))
print "outfile is:"
print outfile
# tell the user
puts(colored.green('Writing: %s'%outfile))
# write to file
f = open(outfile,'w')
f.write(output)
'''
with open(outfile,'w') as f:
f.write(output)
'''
# how long did this take?
puts(colored.green('Time to completion: %s'%(deltaTime(start))))
print
from conf.settings import logger from lib.tool import Tool logger.debug(Tool().app_data)
