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InvenTree/InvenTree/build/models.py
Matthias Mair cce3d3a35d make imports on function level
2022-05-16 18:01:16 +02:00

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"""
Build database model definitions
"""
import decimal
import os
from datetime import datetime
from django.contrib.auth.models import User
from django.core.exceptions import ValidationError
from django.core.validators import MinValueValidator
from django.db import models, transaction
from django.db.models import Sum, Q
from django.db.models.functions import Coalesce
from django.db.models.signals import post_save
from django.dispatch.dispatcher import receiver
from django.urls import reverse
from django.utils.translation import gettext_lazy as _
from markdownx.models import MarkdownxField
from mptt.models import MPTTModel, TreeForeignKey
from mptt.exceptions import InvalidMove
from rest_framework import serializers
from InvenTree.status_codes import BuildStatus, StockStatus, StockHistoryCode
from InvenTree.helpers import increment, getSetting, normalize, MakeBarcode
from InvenTree.models import InvenTreeAttachment, ReferenceIndexingMixin
from InvenTree.validators import validate_build_order_reference
import InvenTree.fields
import InvenTree.helpers
import InvenTree.tasks
from plugin.events import trigger_event
from part import models as PartModels
from stock import models as StockModels
from users import models as UserModels
def get_next_build_number():
"""
Returns the next available BuildOrder reference number
"""
if Build.objects.count() == 0:
return '0001'
build = Build.objects.exclude(reference=None).last()
attempts = {build.reference}
reference = build.reference
while 1:
reference = increment(reference)
if reference in attempts:
# Escape infinite recursion
return reference
if Build.objects.filter(reference=reference).exists():
attempts.add(reference)
else:
break
return reference
class Build(MPTTModel, ReferenceIndexingMixin):
""" A Build object organises the creation of new StockItem objects from other existing StockItem objects.
Attributes:
part: The part to be built (from component BOM items)
reference: Build order reference (required, must be unique)
title: Brief title describing the build (required)
quantity: Number of units to be built
parent: Reference to a Build object for which this Build is required
sales_order: References to a SalesOrder object for which this Build is required (e.g. the output of this build will be used to fulfil a sales order)
take_from: Location to take stock from to make this build (if blank, can take from anywhere)
status: Build status code
batch: Batch code transferred to build parts (optional)
creation_date: Date the build was created (auto)
target_date: Date the build will be overdue
completion_date: Date the build was completed (or, if incomplete, the expected date of completion)
link: External URL for extra information
notes: Text notes
completed_by: User that completed the build
issued_by: User that issued the build
responsible: User (or group) responsible for completing the build
"""
OVERDUE_FILTER = Q(status__in=BuildStatus.ACTIVE_CODES) & ~Q(target_date=None) & Q(target_date__lte=datetime.now().date())
@staticmethod
def get_api_url():
return reverse('api-build-list')
def api_instance_filters(self):
return {
'parent': {
'exclude_tree': self.pk,
}
}
@classmethod
def api_defaults(cls, request):
"""
Return default values for this model when issuing an API OPTIONS request
"""
defaults = {
'reference': get_next_build_number(),
}
if request and request.user:
defaults['issued_by'] = request.user.pk
return defaults
def save(self, *args, **kwargs):
self.rebuild_reference_field()
try:
super().save(*args, **kwargs)
except InvalidMove:
raise ValidationError({
'parent': _('Invalid choice for parent build'),
})
class Meta:
verbose_name = _("Build Order")
verbose_name_plural = _("Build Orders")
def format_barcode(self, **kwargs):
"""
Return a JSON string to represent this build as a barcode
"""
return MakeBarcode(
"buildorder",
self.pk,
{
"reference": self.title,
"url": self.get_absolute_url(),
}
)
@staticmethod
def filterByDate(queryset, min_date, max_date):
"""
Filter by 'minimum and maximum date range'
- Specified as min_date, max_date
- Both must be specified for filter to be applied
"""
date_fmt = '%Y-%m-%d' # ISO format date string
# Ensure that both dates are valid
try:
min_date = datetime.strptime(str(min_date), date_fmt).date()
max_date = datetime.strptime(str(max_date), date_fmt).date()
except (ValueError, TypeError):
# Date processing error, return queryset unchanged
return queryset
# Order was completed within the specified range
completed = Q(status=BuildStatus.COMPLETE) & Q(completion_date__gte=min_date) & Q(completion_date__lte=max_date)
# Order target date falls witin specified range
pending = Q(status__in=BuildStatus.ACTIVE_CODES) & ~Q(target_date=None) & Q(target_date__gte=min_date) & Q(target_date__lte=max_date)
# TODO - Construct a queryset for "overdue" orders
queryset = queryset.filter(completed | pending)
return queryset
def __str__(self):
prefix = getSetting("BUILDORDER_REFERENCE_PREFIX")
return f"{prefix}{self.reference}"
def get_absolute_url(self):
return reverse('build-detail', kwargs={'pk': self.id})
reference = models.CharField(
unique=True,
max_length=64,
blank=False,
help_text=_('Build Order Reference'),
verbose_name=_('Reference'),
default=get_next_build_number,
validators=[
validate_build_order_reference
]
)
title = models.CharField(
verbose_name=_('Description'),
blank=False,
max_length=100,
help_text=_('Brief description of the build')
)
# TODO - Perhaps delete the build "tree"
parent = TreeForeignKey(
'self',
on_delete=models.SET_NULL,
blank=True, null=True,
related_name='children',
verbose_name=_('Parent Build'),
help_text=_('BuildOrder to which this build is allocated'),
)
part = models.ForeignKey(
'part.Part',
verbose_name=_('Part'),
on_delete=models.CASCADE,
related_name='builds',
limit_choices_to={
'assembly': True,
'active': True,
'virtual': False,
},
help_text=_('Select part to build'),
)
sales_order = models.ForeignKey(
'order.SalesOrder',
verbose_name=_('Sales Order Reference'),
on_delete=models.SET_NULL,
related_name='builds',
null=True, blank=True,
help_text=_('SalesOrder to which this build is allocated')
)
take_from = models.ForeignKey(
'stock.StockLocation',
verbose_name=_('Source Location'),
on_delete=models.SET_NULL,
related_name='sourcing_builds',
null=True, blank=True,
help_text=_('Select location to take stock from for this build (leave blank to take from any stock location)')
)
destination = models.ForeignKey(
'stock.StockLocation',
verbose_name=_('Destination Location'),
on_delete=models.SET_NULL,
related_name='incoming_builds',
null=True, blank=True,
help_text=_('Select location where the completed items will be stored'),
)
quantity = models.PositiveIntegerField(
verbose_name=_('Build Quantity'),
default=1,
validators=[MinValueValidator(1)],
help_text=_('Number of stock items to build')
)
completed = models.PositiveIntegerField(
verbose_name=_('Completed items'),
default=0,
help_text=_('Number of stock items which have been completed')
)
status = models.PositiveIntegerField(
verbose_name=_('Build Status'),
default=BuildStatus.PENDING,
choices=BuildStatus.items(),
validators=[MinValueValidator(0)],
help_text=_('Build status code')
)
batch = models.CharField(
verbose_name=_('Batch Code'),
max_length=100,
blank=True,
null=True,
help_text=_('Batch code for this build output')
)
creation_date = models.DateField(auto_now_add=True, editable=False, verbose_name=_('Creation Date'))
target_date = models.DateField(
null=True, blank=True,
verbose_name=_('Target completion date'),
help_text=_('Target date for build completion. Build will be overdue after this date.')
)
completion_date = models.DateField(null=True, blank=True, verbose_name=_('Completion Date'))
completed_by = models.ForeignKey(
User,
on_delete=models.SET_NULL,
blank=True, null=True,
verbose_name=_('completed by'),
related_name='builds_completed'
)
issued_by = models.ForeignKey(
User,
on_delete=models.SET_NULL,
blank=True, null=True,
verbose_name=_('Issued by'),
help_text=_('User who issued this build order'),
related_name='builds_issued',
)
responsible = models.ForeignKey(
UserModels.Owner,
on_delete=models.SET_NULL,
blank=True, null=True,
verbose_name=_('Responsible'),
help_text=_('User responsible for this build order'),
related_name='builds_responsible',
)
link = InvenTree.fields.InvenTreeURLField(
verbose_name=_('External Link'),
blank=True, help_text=_('Link to external URL')
)
notes = MarkdownxField(
verbose_name=_('Notes'),
blank=True, help_text=_('Extra build notes')
)
def sub_builds(self, cascade=True):
"""
Return all Build Order objects under this one.
"""
if cascade:
return Build.objects.filter(parent=self.pk)
else:
descendants = self.get_descendants(include_self=True)
Build.objects.filter(parent__pk__in=[d.pk for d in descendants])
def sub_build_count(self, cascade=True):
"""
Return the number of sub builds under this one.
Args:
cascade: If True (defualt), include cascading builds under sub builds
"""
return self.sub_builds(cascade=cascade).count()
@property
def is_overdue(self):
"""
Returns true if this build is "overdue":
Makes use of the OVERDUE_FILTER to avoid code duplication
"""
query = Build.objects.filter(pk=self.pk)
query = query.filter(Build.OVERDUE_FILTER)
return query.exists()
@property
def active(self):
"""
Return True if this build is active
"""
return self.status in BuildStatus.ACTIVE_CODES
@property
def bom_items(self):
"""
Returns the BOM items for the part referenced by this BuildOrder
"""
return self.part.get_bom_items()
@property
def tracked_bom_items(self):
"""
Returns the "trackable" BOM items for this BuildOrder
"""
items = self.bom_items
items = items.filter(sub_part__trackable=True)
return items
def has_tracked_bom_items(self):
"""
Returns True if this BuildOrder has trackable BomItems
"""
return self.tracked_bom_items.count() > 0
@property
def untracked_bom_items(self):
"""
Returns the "non trackable" BOM items for this BuildOrder
"""
items = self.bom_items
items = items.filter(sub_part__trackable=False)
return items
def has_untracked_bom_items(self):
"""
Returns True if this BuildOrder has non trackable BomItems
"""
return self.untracked_bom_items.count() > 0
@property
def remaining(self):
"""
Return the number of outputs remaining to be completed.
"""
return max(0, self.quantity - self.completed)
@property
def output_count(self):
return self.build_outputs.count()
def has_build_outputs(self):
return self.output_count > 0
def get_build_outputs(self, **kwargs):
"""
Return a list of build outputs.
kwargs:
complete = (True / False) - If supplied, filter by completed status
in_stock = (True / False) - If supplied, filter by 'in-stock' status
"""
outputs = self.build_outputs.all()
# Filter by 'in stock' status
in_stock = kwargs.get('in_stock', None)
if in_stock is not None:
if in_stock:
outputs = outputs.filter(StockModels.StockItem.IN_STOCK_FILTER)
else:
outputs = outputs.exclude(StockModels.StockItem.IN_STOCK_FILTER)
# Filter by 'complete' status
complete = kwargs.get('complete', None)
if complete is not None:
if complete:
outputs = outputs.filter(is_building=False)
else:
outputs = outputs.filter(is_building=True)
return outputs
@property
def complete_outputs(self):
"""
Return all the "completed" build outputs
"""
outputs = self.get_build_outputs(complete=True)
return outputs
@property
def complete_count(self):
quantity = 0
for output in self.complete_outputs:
quantity += output.quantity
return quantity
@property
def incomplete_outputs(self):
"""
Return all the "incomplete" build outputs
"""
outputs = self.get_build_outputs(complete=False)
return outputs
@property
def incomplete_count(self):
"""
Return the total number of "incomplete" outputs
"""
quantity = 0
for output in self.incomplete_outputs:
quantity += output.quantity
return quantity
@classmethod
def getNextBuildNumber(cls):
"""
Try to predict the next Build Order reference:
"""
if cls.objects.count() == 0:
return None
# Extract the "most recent" build order reference
builds = cls.objects.exclude(reference=None)
if not builds.exists():
return None
build = builds.last()
ref = build.reference
if not ref:
return None
tries = set(ref)
new_ref = ref
while 1:
new_ref = increment(new_ref)
if new_ref in tries:
# We are potentially stuck in a loop - simply return the original reference
return ref
# Check if the existing build reference exists
if cls.objects.filter(reference=new_ref).exists():
tries.add(new_ref)
else:
break
return new_ref
@property
def can_complete(self):
"""
Returns True if this build can be "completed"
- Must not have any outstanding build outputs
- 'completed' value must meet (or exceed) the 'quantity' value
"""
if self.incomplete_count > 0:
return False
if self.remaining > 0:
return False
if not self.are_untracked_parts_allocated():
return False
# No issues!
return True
@transaction.atomic
def complete_build(self, user):
"""
Mark this build as complete
"""
if self.incomplete_count > 0:
return
self.completion_date = datetime.now().date()
self.completed_by = user
self.status = BuildStatus.COMPLETE
self.save()
# Remove untracked allocated stock
self.subtract_allocated_stock(user)
# Ensure that there are no longer any BuildItem objects
# which point to thisFcan Build Order
self.allocated_stock.all().delete()
# Register an event
trigger_event('build.completed', id=self.pk)
@transaction.atomic
def cancel_build(self, user, **kwargs):
""" Mark the Build as CANCELLED
- Delete any pending BuildItem objects (but do not remove items from stock)
- Set build status to CANCELLED
- Save the Build object
"""
remove_allocated_stock = kwargs.get('remove_allocated_stock', False)
remove_incomplete_outputs = kwargs.get('remove_incomplete_outputs', False)
# Handle stock allocations
for build_item in self.allocated_stock.all():
if remove_allocated_stock:
build_item.complete_allocation(user)
build_item.delete()
# Remove incomplete outputs (if required)
if remove_incomplete_outputs:
outputs = self.build_outputs.filter(is_building=True)
for output in outputs:
output.delete()
# Date of 'completion' is the date the build was cancelled
self.completion_date = datetime.now().date()
self.completed_by = user
self.status = BuildStatus.CANCELLED
self.save()
trigger_event('build.cancelled', id=self.pk)
@transaction.atomic
def unallocateStock(self, bom_item=None, output=None):
"""
Unallocate stock from this Build
arguments:
- bom_item: Specify a particular BomItem to unallocate stock against
- output: Specify a particular StockItem (output) to unallocate stock against
"""
allocations = BuildItem.objects.filter(
build=self,
install_into=output
)
if bom_item:
allocations = allocations.filter(bom_item=bom_item)
allocations.delete()
@transaction.atomic
def create_build_output(self, quantity, **kwargs):
"""
Create a new build output against this BuildOrder.
args:
quantity: The quantity of the item to produce
kwargs:
batch: Override batch code
serials: Serial numbers
location: Override location
auto_allocate: Automatically allocate stock with matching serial numbers
"""
batch = kwargs.get('batch', self.batch)
location = kwargs.get('location', self.destination)
serials = kwargs.get('serials', None)
auto_allocate = kwargs.get('auto_allocate', False)
"""
Determine if we can create a single output (with quantity > 0),
or multiple outputs (with quantity = 1)
"""
multiple = False
# Serial numbers are provided? We need to split!
if serials:
multiple = True
# BOM has trackable parts, so we must split!
if self.part.has_trackable_parts:
multiple = True
if multiple:
"""
Create multiple build outputs with a single quantity of 1
"""
# Quantity *must* be an integer at this point!
quantity = int(quantity)
for ii in range(quantity):
if serials:
serial = serials[ii]
else:
serial = None
output = StockModels.StockItem.objects.create(
quantity=1,
location=location,
part=self.part,
build=self,
batch=batch,
serial=serial,
is_building=True,
)
if auto_allocate and serial is not None:
# Get a list of BomItem objects which point to "trackable" parts
for bom_item in self.part.get_trackable_parts():
parts = bom_item.get_valid_parts_for_allocation()
for part in parts:
items = StockModels.StockItem.objects.filter(
part=part,
serial=str(serial),
quantity=1,
).filter(StockModels.StockItem.IN_STOCK_FILTER)
"""
Test if there is a matching serial number!
"""
if items.exists() and items.count() == 1:
stock_item = items[0]
# Allocate the stock item
BuildItem.objects.create(
build=self,
bom_item=bom_item,
stock_item=stock_item,
quantity=1,
install_into=output,
)
else:
"""
Create a single build output of the given quantity
"""
StockModels.StockItem.objects.create(
quantity=quantity,
location=location,
part=self.part,
build=self,
batch=batch,
is_building=True
)
if self.status == BuildStatus.PENDING:
self.status = BuildStatus.PRODUCTION
self.save()
@transaction.atomic
def delete_output(self, output):
"""
Remove a build output from the database:
- Unallocate any build items against the output
- Delete the output StockItem
"""
if not output:
raise ValidationError(_("No build output specified"))
if not output.is_building:
raise ValidationError(_("Build output is already completed"))
if output.build != self:
raise ValidationError(_("Build output does not match Build Order"))
# Unallocate all build items against the output
self.unallocateStock(output=output)
# Remove the build output from the database
output.delete()
@transaction.atomic
def subtract_allocated_stock(self, user):
"""
Called when the Build is marked as "complete",
this function removes the allocated untracked items from stock.
"""
items = self.allocated_stock.filter(
stock_item__part__trackable=False
)
# Remove stock
for item in items:
item.complete_allocation(user)
# Delete allocation
items.all().delete()
@transaction.atomic
def complete_build_output(self, output, user, **kwargs):
"""
Complete a particular build output
- Remove allocated StockItems
- Mark the output as complete
"""
# Select the location for the build output
location = kwargs.get('location', self.destination)
status = kwargs.get('status', StockStatus.OK)
notes = kwargs.get('notes', '')
# List the allocated BuildItem objects for the given output
allocated_items = output.items_to_install.all()
for build_item in allocated_items:
# Complete the allocation of stock for that item
build_item.complete_allocation(user)
# Delete the BuildItem objects from the database
allocated_items.all().delete()
# Ensure that the output is updated correctly
output.build = self
output.is_building = False
output.location = location
output.status = status
output.save()
output.add_tracking_entry(
StockHistoryCode.BUILD_OUTPUT_COMPLETED,
user,
notes=notes,
deltas={
'status': status,
}
)
# Increase the completed quantity for this build
self.completed += output.quantity
self.save()
@transaction.atomic
def auto_allocate_stock(self, **kwargs):
"""
Automatically allocate stock items against this build order,
following a number of 'guidelines':
- Only "untracked" BOM items are considered (tracked BOM items must be manually allocated)
- If a particular BOM item is already fully allocated, it is skipped
- Extract all available stock items for the BOM part
- If variant stock is allowed, extract stock for those too
- If substitute parts are available, extract stock for those also
- If a single stock item is found, we can allocate that and move on!
- If multiple stock items are found, we *may* be able to allocate:
- If the calling function has specified that items are interchangeable
"""
location = kwargs.get('location', None)
exclude_location = kwargs.get('exclude_location', None)
interchangeable = kwargs.get('interchangeable', False)
substitutes = kwargs.get('substitutes', True)
# Get a list of all 'untracked' BOM items
for bom_item in self.untracked_bom_items:
variant_parts = bom_item.sub_part.get_descendants(include_self=False)
unallocated_quantity = self.unallocated_quantity(bom_item)
if unallocated_quantity <= 0:
# This BomItem is fully allocated, we can continue
continue
# Check which parts we can "use" (may include variants and substitutes)
available_parts = bom_item.get_valid_parts_for_allocation(
allow_variants=True,
allow_substitutes=substitutes,
)
# Look for available stock items
available_stock = StockModels.StockItem.objects.filter(StockModels.StockItem.IN_STOCK_FILTER)
# Filter by list of available parts
available_stock = available_stock.filter(
part__in=[p for p in available_parts],
)
# Filter out "serialized" stock items, these cannot be auto-allocated
available_stock = available_stock.filter(Q(serial=None) | Q(serial=''))
if location:
# Filter only stock items located "below" the specified location
sublocations = location.get_descendants(include_self=True)
available_stock = available_stock.filter(location__in=[loc for loc in sublocations])
if exclude_location:
# Exclude any stock items from the provided location
sublocations = exclude_location.get_descendants(include_self=True)
available_stock = available_stock.exclude(location__in=[loc for loc in sublocations])
"""
Next, we sort the available stock items with the following priority:
1. Direct part matches (+1)
2. Variant part matches (+2)
3. Substitute part matches (+3)
This ensures that allocation priority is first given to "direct" parts
"""
def stock_sort(item):
if item.part == bom_item.sub_part:
return 1
elif item.part in variant_parts:
return 2
else:
return 3
available_stock = sorted(available_stock, key=stock_sort)
if len(available_stock) == 0:
# No stock items are available
continue
elif len(available_stock) == 1 or interchangeable:
# Either there is only a single stock item available,
# or all items are "interchangeable" and we don't care where we take stock from
for stock_item in available_stock:
# How much of the stock item is "available" for allocation?
quantity = min(unallocated_quantity, stock_item.unallocated_quantity())
if quantity > 0:
try:
BuildItem.objects.create(
build=self,
bom_item=bom_item,
stock_item=stock_item,
quantity=quantity,
)
# Subtract the required quantity
unallocated_quantity -= quantity
except (ValidationError, serializers.ValidationError) as exc:
# Catch model errors and re-throw as DRF errors
raise ValidationError(detail=serializers.as_serializer_error(exc))
if unallocated_quantity <= 0:
# We have now fully-allocated this BomItem - no need to continue!
break
def required_quantity(self, bom_item, output=None):
"""
Get the quantity of a part required to complete the particular build output.
Args:
part: The Part object
output - The particular build output (StockItem)
"""
quantity = bom_item.quantity
if output:
quantity *= output.quantity
else:
quantity *= self.quantity
return quantity
def allocated_bom_items(self, bom_item, output=None):
"""
Return all BuildItem objects which allocate stock of <bom_item> to <output>
Note that the bom_item may allow variants, or direct substitutes,
making things difficult.
Args:
bom_item - The BomItem object
output - Build output (StockItem).
"""
allocations = BuildItem.objects.filter(
build=self,
bom_item=bom_item,
install_into=output,
)
return allocations
def allocated_quantity(self, bom_item, output=None):
"""
Return the total quantity of given part allocated to a given build output.
"""
allocations = self.allocated_bom_items(bom_item, output)
allocated = allocations.aggregate(
q=Coalesce(
Sum('quantity'),
0,
output_field=models.DecimalField(),
)
)
return allocated['q']
def unallocated_quantity(self, bom_item, output=None):
"""
Return the total unallocated (remaining) quantity of a part against a particular output.
"""
required = self.required_quantity(bom_item, output)
allocated = self.allocated_quantity(bom_item, output)
return max(required - allocated, 0)
def is_bom_item_allocated(self, bom_item, output=None):
"""
Test if the supplied BomItem has been fully allocated!
"""
return self.unallocated_quantity(bom_item, output) == 0
def is_fully_allocated(self, output):
"""
Returns True if the particular build output is fully allocated.
"""
# If output is not specified, we are talking about "untracked" items
if output is None:
bom_items = self.untracked_bom_items
else:
bom_items = self.tracked_bom_items
for bom_item in bom_items:
if not self.is_bom_item_allocated(bom_item, output):
return False
# All parts must be fully allocated!
return True
def is_partially_allocated(self, output):
"""
Returns True if the particular build output is (at least) partially allocated
"""
# If output is not specified, we are talking about "untracked" items
if output is None:
bom_items = self.untracked_bom_items
else:
bom_items = self.tracked_bom_items
for bom_item in bom_items:
if self.allocated_quantity(bom_item, output) > 0:
return True
return False
def are_untracked_parts_allocated(self):
"""
Returns True if the un-tracked parts are fully allocated for this BuildOrder
"""
return self.is_fully_allocated(None)
def unallocated_bom_items(self, output):
"""
Return a list of bom items which have *not* been fully allocated against a particular output
"""
unallocated = []
# If output is not specified, we are talking about "untracked" items
if output is None:
bom_items = self.untracked_bom_items
else:
bom_items = self.tracked_bom_items
for bom_item in bom_items:
if not self.is_bom_item_allocated(bom_item, output):
unallocated.append(bom_item)
return unallocated
@property
def required_parts(self):
""" Returns a list of parts required to build this part (BOM) """
parts = []
for item in self.bom_items:
parts.append(item.sub_part)
return parts
@property
def required_parts_to_complete_build(self):
""" Returns a list of parts required to complete the full build """
parts = []
for bom_item in self.bom_items:
# Get remaining quantity needed
required_quantity_to_complete_build = self.remaining * bom_item.quantity
# Compare to net stock
if bom_item.sub_part.net_stock < required_quantity_to_complete_build:
parts.append(bom_item.sub_part)
return parts
@property
def is_active(self):
""" Is this build active? An active build is either:
- PENDING
- HOLDING
"""
return self.status in BuildStatus.ACTIVE_CODES
@property
def is_complete(self):
""" Returns True if the build status is COMPLETE """
return self.status == BuildStatus.COMPLETE
@receiver(post_save, sender=Build, dispatch_uid='build_post_save_log')
def after_save_build(sender, instance: Build, created: bool, **kwargs):
"""
Callback function to be executed after a Build instance is saved
"""
from . import tasks as build_tasks
if created:
# A new Build has just been created
# Run checks on required parts
InvenTree.tasks.offload_task(build_tasks.check_build_stock, instance)
class BuildOrderAttachment(InvenTreeAttachment):
"""
Model for storing file attachments against a BuildOrder object
"""
def getSubdir(self):
return os.path.join('bo_files', str(self.build.id))
build = models.ForeignKey(Build, on_delete=models.CASCADE, related_name='attachments')
class BuildItem(models.Model):
""" A BuildItem links multiple StockItem objects to a Build.
These are used to allocate part stock to a build.
Once the Build is completed, the parts are removed from stock and the
BuildItemAllocation objects are removed.
Attributes:
build: Link to a Build object
bom_item: Link to a BomItem object (may or may not point to the same part as the build)
stock_item: Link to a StockItem object
quantity: Number of units allocated
install_into: Destination stock item (or None)
"""
@staticmethod
def get_api_url():
return reverse('api-build-item-list')
def get_absolute_url(self):
# TODO - Fix!
return '/build/item/{pk}/'.format(pk=self.id)
# return reverse('build-detail', kwargs={'pk': self.id})
class Meta:
unique_together = [
('build', 'stock_item', 'install_into'),
]
def save(self, *args, **kwargs):
self.clean()
super().save()
def clean(self):
"""
Check validity of this BuildItem instance.
The following checks are performed:
- StockItem.part must be in the BOM of the Part object referenced by Build
- Allocation quantity cannot exceed available quantity
"""
self.validate_unique()
super().clean()
try:
# If the 'part' is trackable, then the 'install_into' field must be set!
if self.stock_item.part and self.stock_item.part.trackable and not self.install_into:
raise ValidationError(_('Build item must specify a build output, as master part is marked as trackable'))
# Allocated quantity cannot exceed available stock quantity
if self.quantity > self.stock_item.quantity:
q = normalize(self.quantity)
a = normalize(self.stock_item.quantity)
raise ValidationError({
'quantity': _(f'Allocated quantity ({q}) must not exceed available stock quantity ({a})')
})
# Allocated quantity cannot cause the stock item to be over-allocated
available = decimal.Decimal(self.stock_item.quantity)
allocated = decimal.Decimal(self.stock_item.allocation_count())
quantity = decimal.Decimal(self.quantity)
if available - allocated + quantity < quantity:
raise ValidationError({
'quantity': _('Stock item is over-allocated')
})
# Allocated quantity must be positive
if self.quantity <= 0:
raise ValidationError({
'quantity': _('Allocation quantity must be greater than zero'),
})
# Quantity must be 1 for serialized stock
if self.stock_item.serialized and self.quantity != 1:
raise ValidationError({
'quantity': _('Quantity must be 1 for serialized stock')
})
except (StockModels.StockItem.DoesNotExist, PartModels.Part.DoesNotExist):
pass
"""
Attempt to find the "BomItem" which links this BuildItem to the build.
- If a BomItem is already set, and it is valid, then we are ok!
"""
bom_item_valid = False
if self.bom_item and self.build:
"""
A BomItem object has already been assigned. This is valid if:
a) It points to the same "part" as the referenced build
b) Either:
i) The sub_part points to the same part as the referenced StockItem
ii) The BomItem allows variants and the part referenced by the StockItem
is a variant of the sub_part referenced by the BomItem
iii) The Part referenced by the StockItem is a valid substitute for the BomItem
"""
if self.build.part == self.bom_item.part:
bom_item_valid = self.bom_item.is_stock_item_valid(self.stock_item)
elif self.bom_item.inherited:
if self.build.part in self.bom_item.part.get_descendants(include_self=False):
bom_item_valid = self.bom_item.is_stock_item_valid(self.stock_item)
# If the existing BomItem is *not* valid, try to find a match
if not bom_item_valid:
if self.build and self.stock_item:
ancestors = self.stock_item.part.get_ancestors(include_self=True, ascending=True)
for idx, ancestor in enumerate(ancestors):
try:
bom_item = PartModels.BomItem.objects.get(part=self.build.part, sub_part=ancestor)
except PartModels.BomItem.DoesNotExist:
continue
# A matching BOM item has been found!
if idx == 0 or bom_item.allow_variants:
bom_item_valid = True
self.bom_item = bom_item
break
# BomItem did not exist or could not be validated.
# Search for a new one
if not bom_item_valid:
raise ValidationError({
'stock_item': _("Selected stock item not found in BOM")
})
@transaction.atomic
def complete_allocation(self, user, notes=''):
"""
Complete the allocation of this BuildItem into the output stock item.
- If the referenced part is trackable, the stock item will be *installed* into the build output
- If the referenced part is *not* trackable, the stock item will be removed from stock
"""
item = self.stock_item
# For a trackable part, special consideration needed!
if item.part.trackable:
# Split the allocated stock if there are more available than allocated
if item.quantity > self.quantity:
item = item.splitStock(
self.quantity,
None,
user,
code=StockHistoryCode.BUILD_CONSUMED,
)
# Make sure we are pointing to the new item
self.stock_item = item
self.save()
# Install the stock item into the output
self.install_into.installStockItem(
item,
self.quantity,
user,
notes
)
else:
# Simply remove the items from stock
item.take_stock(
self.quantity,
user,
code=StockHistoryCode.BUILD_CONSUMED
)
def getStockItemThumbnail(self):
"""
Return qualified URL for part thumbnail image
"""
thumb_url = None
if self.stock_item and self.stock_item.part:
try:
# Try to extract the thumbnail
thumb_url = self.stock_item.part.image.thumbnail.url
except:
pass
if thumb_url is None and self.bom_item and self.bom_item.sub_part:
try:
thumb_url = self.bom_item.sub_part.image.thumbnail.url
except:
pass
if thumb_url is not None:
return InvenTree.helpers.getMediaUrl(thumb_url)
else:
return InvenTree.helpers.getBlankThumbnail()
build = models.ForeignKey(
Build,
on_delete=models.CASCADE,
related_name='allocated_stock',
verbose_name=_('Build'),
help_text=_('Build to allocate parts')
)
# Internal model which links part <-> sub_part
# We need to track this separately, to allow for "variant' stock
bom_item = models.ForeignKey(
PartModels.BomItem,
on_delete=models.CASCADE,
related_name='allocate_build_items',
blank=True, null=True,
)
stock_item = models.ForeignKey(
'stock.StockItem',
on_delete=models.CASCADE,
related_name='allocations',
verbose_name=_('Stock Item'),
help_text=_('Source stock item'),
limit_choices_to={
'sales_order': None,
'belongs_to': None,
}
)
quantity = models.DecimalField(
decimal_places=5,
max_digits=15,
default=1,
validators=[MinValueValidator(0)],
verbose_name=_('Quantity'),
help_text=_('Stock quantity to allocate to build')
)
install_into = models.ForeignKey(
'stock.StockItem',
on_delete=models.SET_NULL,
blank=True, null=True,
related_name='items_to_install',
verbose_name=_('Install into'),
help_text=_('Destination stock item'),
limit_choices_to={
'is_building': True,
}
)
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