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InvokeAI/docs/contributing/MODEL_MANAGER.md

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# Introduction to the Model Manager V2
The Model Manager is responsible for organizing the various machine
learning models used by InvokeAI. It consists of a series of
interdependent services that together handle the full lifecycle of a
model. These are the:
* _ModelRecordServiceBase_ Responsible for managing model metadata and
configuration information. Among other things, the record service
tracks the type of the model, its provenance, and where it can be
found on disk.
* _ModelInstallServiceBase_ A service for installing models to
disk. It uses `DownloadQueueServiceBase` to download models and
their metadata, and `ModelRecordServiceBase` to store that
information. It is also responsible for managing the InvokeAI
`models` directory and its contents.
* _DownloadQueueServiceBase_ (**CURRENTLY UNDER DEVELOPMENT - NOT IMPLEMENTED**)
A multithreaded downloader responsible
for downloading models from a remote source to disk. The download
queue has special methods for downloading repo_id folders from
Hugging Face, as well as discriminating among model versions in
Civitai, but can be used for arbitrary content.
* _ModelLoadServiceBase_ (**CURRENTLY UNDER DEVELOPMENT - NOT IMPLEMENTED**)
Responsible for loading a model from disk
into RAM and VRAM and getting it ready for inference.
## Location of the Code
All four of these services can be found in
`invokeai/app/services` in the following directories:
* `invokeai/app/services/model_records/`
* `invokeai/app/services/model_install/`
* `invokeai/app/services/model_loader/` (**under development**)
* `invokeai/app/services/downloads/`(**under development**)
Code related to the FastAPI web API can be found in
`invokeai/app/api/routers/model_records.py`.
***
## What's in a Model? The ModelRecordService
The `ModelRecordService` manages the model's metadata. It supports a
hierarchy of pydantic metadata "config" objects, which become
increasingly specialized to support particular model types.
### ModelConfigBase
All model metadata classes inherit from this pydantic class. it
provides the following fields:
| **Field Name** | **Type** | **Description** |
|----------------|-----------------|------------------|
| `key` | str | Unique identifier for the model |
| `name` | str | Name of the model (not unique) |
| `model_type` | ModelType | The type of the model |
| `model_format` | ModelFormat | The format of the model (e.g. "diffusers"); also used as a Union discriminator |
| `base_model` | BaseModelType | The base model that the model is compatible with |
| `path` | str | Location of model on disk |
| `original_hash` | str | Hash of the model when it was first installed |
| `current_hash` | str | Most recent hash of the model's contents |
| `description` | str | Human-readable description of the model (optional) |
| `source` | str | Model's source URL or repo id (optional) |
The `key` is a unique 32-character random ID which was generated at
install time. The `original_hash` field stores a hash of the model's
contents at install time obtained by sampling several parts of the
model's files using the `imohash` library. Over the course of the
model's lifetime it may be transformed in various ways, such as
changing its precision or converting it from a .safetensors to a
diffusers model. When this happens, `original_hash` is unchanged, but
`current_hash` is updated to indicate the current contents.
`ModelType`, `ModelFormat` and `BaseModelType` are string enums that
are defined in `invokeai.backend.model_manager.config`. They are also
imported by, and can be reexported from,
`invokeai.app.services.model_record_service`:
```
from invokeai.app.services.model_record_service import ModelType, ModelFormat, BaseModelType
```
The `path` field can be absolute or relative. If relative, it is taken
to be relative to the `models_dir` setting in the user's
`invokeai.yaml` file.
### CheckpointConfig
This adds support for checkpoint configurations, and adds the
following field:
| **Field Name** | **Type** | **Description** |
|----------------|-----------------|------------------|
| `config` | str | Path to the checkpoint's config file |
`config` is the path to the checkpoint's config file. If relative, it
is taken to be relative to the InvokeAI root directory
(e.g. `configs/stable-diffusion/v1-inference.yaml`)
### MainConfig
This adds support for "main" Stable Diffusion models, and adds these
fields:
| **Field Name** | **Type** | **Description** |
|----------------|-----------------|------------------|
| `vae` | str | Path to a VAE to use instead of the burnt-in one |
| `variant` | ModelVariantType| Model variant type, such as "inpainting" |
`vae` can be an absolute or relative path. If relative, its base is
taken to be the `models_dir` directory.
`variant` is an enumerated string class with values `normal`,
`inpaint` and `depth`. If needed, it can be imported if needed from
either `invokeai.app.services.model_record_service` or
`invokeai.backend.model_manager.config`.
### ONNXSD2Config
| **Field Name** | **Type** | **Description** |
|----------------|-----------------|------------------|
| `prediction_type` | SchedulerPredictionType | Scheduler prediction type to use, e.g. "epsilon" |
| `upcast_attention` | bool | Model requires its attention module to be upcast |
The `SchedulerPredictionType` enum can be imported from either
`invokeai.app.services.model_record_service` or
`invokeai.backend.model_manager.config`.
### Other config classes
There are a series of such classes each discriminated by their
`ModelFormat`, including `LoRAConfig`, `IPAdapterConfig`, and so
forth. These are rarely needed outside the model manager's internal
code, but available in `invokeai.backend.model_manager.config` if
needed. There is also a Union of all ModelConfig classes, called
`AnyModelConfig` that can be imported from the same file.
### Limitations of the Data Model
The config hierarchy has a major limitation in its handling of the
base model type. Each model can only be compatible with one base
model, which breaks down in the event of models that are compatible
with two or more base models. For example, SD-1 VAEs also work with
SD-2 models. A partial workaround is to use `BaseModelType.Any`, which
indicates that the model is compatible with any of the base
models. This works OK for some models, such as the IP Adapter image
encoders, but is an all-or-nothing proposition.
Another issue is that the config class hierarchy is paralleled to some
extent by a `ModelBase` class hierarchy defined in
`invokeai.backend.model_manager.models.base` and its subclasses. These
are classes representing the models after they are loaded into RAM and
include runtime information such as load status and bytes used. Some
of the fields, including `name`, `model_type` and `base_model`, are
shared between `ModelConfigBase` and `ModelBase`, and this is a
potential source of confusion.
## Reading and Writing Model Configuration Records
The `ModelRecordService` provides the ability to retrieve model
configuration records from SQL or YAML databases, update them, and
write them back.
A application-wide `ModelRecordService` is created during API
initialization and can be retrieved within an invocation from the
`InvocationContext` object:
```
store = context.services.model_record_store
```
or from elsewhere in the code by accessing
`ApiDependencies.invoker.services.model_record_store`.
### Creating a `ModelRecordService`
To create a new `ModelRecordService` database or open an existing one,
you can directly create either a `ModelRecordServiceSQL` or a
`ModelRecordServiceFile` object:
```
from invokeai.app.services.model_record_service import ModelRecordServiceSQL, ModelRecordServiceFile
store = ModelRecordServiceSQL.from_connection(connection, lock)
store = ModelRecordServiceSQL.from_db_file('/path/to/sqlite_database.db')
store = ModelRecordServiceFile.from_db_file('/path/to/database.yaml')
```
The `from_connection()` form is only available from the
`ModelRecordServiceSQL` class, and is used to manage records in a
previously-opened SQLITE3 database using a `sqlite3.connection` object
and a `threading.lock` object. It is intended for the specific use
case of storing the record information in the main InvokeAI database,
usually `databases/invokeai.db`.
The `from_db_file()` methods can be used to open new connections to
the named database files. If the file doesn't exist, it will be
created and initialized.
As a convenience, `ModelRecordServiceBase` offers two methods,
`from_db_file` and `open`, which will return either a SQL or File
implementation depending on the context. The former looks at the file
extension to determine whether to open the file as a SQL database
(".db") or as a file database (".yaml"). If the file exists, but is
either the wrong type or does not contain the expected schema
metainformation, then an appropriate `AssertionError` will be raised:
```
store = ModelRecordServiceBase.from_db_file('/path/to/a/file.{yaml,db}')
```
The `ModelRecordServiceBase.open()` method is specifically designed
for use in the InvokeAI web server. Its signature is:
```
def open(
cls,
config: InvokeAIAppConfig,
conn: Optional[sqlite3.Connection] = None,
lock: Optional[threading.Lock] = None
) -> Union[ModelRecordServiceSQL, ModelRecordServiceFile]:
```
The way it works is as follows:
1. Retrieve the value of the `model_config_db` option from the user's
`invokeai.yaml` config file.
2. If `model_config_db` is `auto` (the default), then:
- Use the values of `conn` and `lock` to return a `ModelRecordServiceSQL` object
opened on the passed connection and lock.
- Open up a new connection to `databases/invokeai.db` if `conn`
and/or `lock` are missing (see note below).
3. If `model_config_db` is a Path, then use `from_db_file`
to return the appropriate type of ModelRecordService.
4. If `model_config_db` is None, then retrieve the legacy
`conf_path` option from `invokeai.yaml` and use the Path
indicated there. This will default to `configs/models.yaml`.
So a typical startup pattern would be:
```
import sqlite3
from invokeai.app.services.thread import lock
from invokeai.app.services.model_record_service import ModelRecordServiceBase
from invokeai.app.services.config import InvokeAIAppConfig
config = InvokeAIAppConfig.get_config()
db_conn = sqlite3.connect(config.db_path.as_posix(), check_same_thread=False)
store = ModelRecordServiceBase.open(config, db_conn, lock)
```
_A note on simultaneous access to `invokeai.db`_: The current InvokeAI
service architecture for the image and graph databases is careful to
use a shared sqlite3 connection and a thread lock to ensure that two
threads don't attempt to access the database simultaneously. However,
the default `sqlite3` library used by Python reports using
**Serialized** mode, which allows multiple threads to access the
database simultaneously using multiple database connections (see
https://www.sqlite.org/threadsafe.html and
https://ricardoanderegg.com/posts/python-sqlite-thread-safety/). Therefore
it should be safe to allow the record service to open its own SQLite
database connection. Opening a model record service should then be as
simple as `ModelRecordServiceBase.open(config)`.
### Fetching a Model's Configuration from `ModelRecordServiceBase`
Configurations can be retrieved in several ways.
#### get_model(key) -> AnyModelConfig:
The basic functionality is to call the record store object's
`get_model()` method with the desired model's unique key. It returns
the appropriate subclass of ModelConfigBase:
```
model_conf = store.get_model('f13dd932c0c35c22dcb8d6cda4203764')
print(model_conf.path)
>> '/tmp/models/ckpts/v1-5-pruned-emaonly.safetensors'
```
If the key is unrecognized, this call raises an
`UnknownModelException`.
#### exists(key) -> AnyModelConfig:
Returns True if a model with the given key exists in the databsae.
#### search_by_path(path) -> AnyModelConfig:
Returns the configuration of the model whose path is `path`. The path
is matched using a simple string comparison and won't correctly match
models referred to by different paths (e.g. using symbolic links).
#### search_by_name(name, base, type) -> List[AnyModelConfig]:
This method searches for models that match some combination of `name`,
`BaseType` and `ModelType`. Calling without any arguments will return
all the models in the database.
#### all_models() -> List[AnyModelConfig]:
Return all the model configs in the database. Exactly equivalent to
calling `search_by_name()` with no arguments.
#### search_by_tag(tags) -> List[AnyModelConfig]:
`tags` is a list of strings. This method returns a list of model
configs that contain all of the given tags. Examples:
```
# find all models that are marked as both SFW and as generating
# background scenery
configs = store.search_by_tag(['sfw', 'scenery'])
```
Note that only tags are not searchable in this way. Other fields can
be searched using a filter:
```
commercializable_models = [x for x in store.all_models() \
if x.license.contains('allowCommercialUse=Sell')]
```
#### version() -> str:
Returns the version of the database, currently at `3.2`
#### model_info_by_name(name, base_model, model_type) -> ModelConfigBase:
This method exists to ease the transition from the previous version of
the model manager, in which `get_model()` took the three arguments
shown above. This looks for a unique model identified by name, base
model and model type and returns it.
The method will generate a `DuplicateModelException` if there are more
than one models that share the same type, base and name. While
unlikely, it is certainly possible to have a situation in which the
user had added two models with the same name, base and type, one
located at path `/foo/my_model` and the other at `/bar/my_model`. It
is strongly recommended to search for models using `search_by_name()`,
which can return multiple results, and then to select the desired
model and pass its key to `get_model()`.
### Writing model configs to the database
Several methods allow you to create and update stored model config
records.
#### add_model(key, config) -> AnyModelConfig:
Given a key and a configuration, this will add the model's
configuration record to the database. `config` can either be a subclass of
`ModelConfigBase` (i.e. any class listed in `AnyModelConfig`), or a
`dict` of key/value pairs. In the latter case, the correct
configuration class will be picked by Pydantic's discriminated union
mechanism.
If successful, the method will return the appropriate subclass of
`ModelConfigBase`. It will raise a `DuplicateModelException` if a
model with the same key is already in the database, or an
`InvalidModelConfigException` if a dict was passed and Pydantic
experienced a parse or validation error.
### update_model(key, config) -> AnyModelConfig:
Given a key and a configuration, this will update the model
configuration record in the database. `config` can be either a
instance of `ModelConfigBase`, or a sparse `dict` containing the
fields to be updated. This will return an `AnyModelConfig` on success,
or raise `InvalidModelConfigException` or `UnknownModelException`
exceptions on failure.
***
## Model installation
The `ModelInstallService` class implements the
`ModelInstallServiceBase` abstract base class, and provides a one-stop
shop for all your model install needs. It provides the following
functionality:
- Registering a model config record for a model already located on the
local filesystem, without moving it or changing its path.
- Installing a model alreadiy located on the local filesystem, by
moving it into the InvokeAI root directory under the
`models` folder (or wherever config parameter `models_dir`
specifies).
- Probing of models to determine their type, base type and other key
information.
- Interface with the InvokeAI event bus to provide status updates on
the download, installation and registration process.
- Downloading a model from an arbitrary URL and installing it in
`models_dir` (_implementation pending_).
- Special handling for Civitai model URLs which allow the user to
paste in a model page's URL or download link (_implementation pending_).
- Special handling for HuggingFace repo_ids to recursively download
the contents of the repository, paying attention to alternative
variants such as fp16. (_implementation pending_)
### Initializing the installer
A default installer is created at InvokeAI api startup time and stored
in `ApiDependencies.invoker.services.model_install` and can
also be retrieved from an invocation's `context` argument with
`context.services.model_install`.
In the event you wish to create a new installer, you may use the
following initialization pattern:
```
from invokeai.app.services.config import InvokeAIAppConfig
from invokeai.app.services.model_records import ModelRecordServiceSQL
from invokeai.app.services.model_install import ModelInstallService
from invokeai.app.services.shared.sqlite import SqliteDatabase
from invokeai.backend.util.logging import InvokeAILogger
config = InvokeAIAppConfig.get_config()
config.parse_args()
logger = InvokeAILogger.get_logger(config=config)
db = SqliteDatabase(config, logger)
store = ModelRecordServiceSQL(db)
installer = ModelInstallService(config, store)
```
The full form of `ModelInstallService()` takes the following
required parameters:
| **Argument** | **Type** | **Description** |
|------------------|------------------------------|------------------------------|
| `config` | InvokeAIAppConfig | InvokeAI app configuration object |
| `record_store` | ModelRecordServiceBase | Config record storage database |
| `event_bus` | EventServiceBase | Optional event bus to send download/install progress events to |
Once initialized, the installer will provide the following methods:
#### install_job = installer.import_model()
The `import_model()` method is the core of the installer. The
following illustrates basic usage:
```
from invokeai.app.services.model_install import (
LocalModelSource,
HFModelSource,
URLModelSource,
)
source1 = LocalModelSource(path='/opt/models/sushi.safetensors') # a local safetensors file
source2 = LocalModelSource(path='/opt/models/sushi_diffusers') # a local diffusers folder
source3 = HFModelSource(repo_id='runwayml/stable-diffusion-v1-5') # a repo_id
source4 = HFModelSource(repo_id='runwayml/stable-diffusion-v1-5', subfolder='vae') # a subfolder within a repo_id
source5 = HFModelSource(repo_id='runwayml/stable-diffusion-v1-5', variant='fp16') # a named variant of a HF model
source6 = URLModelSource(url='https://civitai.com/api/download/models/63006') # model located at a URL
source7 = URLModelSource(url='https://civitai.com/api/download/models/63006', access_token='letmein') # with an access token
for source in [source1, source2, source3, source4, source5, source6, source7]:
install_job = installer.install_model(source)
source2job = installer.wait_for_installs()
for source in sources:
job = source2job[source]
if job.status == "completed":
model_config = job.config_out
model_key = model_config.key
print(f"{source} installed as {model_key}")
elif job.status == "error":
print(f"{source}: {job.error_type}.\nStack trace:\n{job.error}")
```
As shown here, the `import_model()` method accepts a variety of
sources, including local safetensors files, local diffusers folders,
HuggingFace repo_ids with and without a subfolder designation,
Civitai model URLs and arbitrary URLs that point to checkpoint files
(but not to folders).
Each call to `import_model()` return a `ModelInstallJob` job,
an object which tracks the progress of the install.
If a remote model is requested, the model's files are downloaded in
parallel across a multiple set of threads using the download
queue. During the download process, the `ModelInstallJob` is updated
to provide status and progress information. After the files (if any)
are downloaded, the remainder of the installation runs in a single
serialized background thread. These are the model probing, file
copying, and config record database update steps.
Multiple install jobs can be queued up. You may block until all
install jobs are completed (or errored) by calling the
`wait_for_installs()` method as shown in the code
example. `wait_for_installs()` will return a `dict` that maps the
requested source to its job. This object can be interrogated
to determine its status. If the job errored out, then the error type
and details can be recovered from `job.error_type` and `job.error`.
The full list of arguments to `import_model()` is as follows:
| **Argument** | **Type** | **Default** | **Description** |
|------------------|------------------------------|-------------|-------------------------------------------|
| `source` | Union[str, Path, AnyHttpUrl] | | The source of the model, Path, URL or repo_id |
| `inplace` | bool | True | Leave a local model in its current location |
| `variant` | str | None | Desired variant, such as 'fp16' or 'onnx' (HuggingFace only) |
| `subfolder` | str | None | Repository subfolder (HuggingFace only) |
| `config` | Dict[str, Any] | None | Override all or a portion of model's probed attributes |
| `access_token` | str | None | Provide authorization information needed to download |
The `inplace` field controls how local model Paths are handled. If
True (the default), then the model is simply registered in its current
location by the installer's `ModelConfigRecordService`. Otherwise, a
copy of the model put into the location specified by the `models_dir`
application configuration parameter.
The `variant` field is used for HuggingFace repo_ids only. If
provided, the repo_id download handler will look for and download
tensors files that follow the convention for the selected variant:
- "fp16" will select files named "*model.fp16.{safetensors,bin}"
- "onnx" will select files ending with the suffix ".onnx"
- "openvino" will select files beginning with "openvino_model"
In the special case of the "fp16" variant, the installer will select
the 32-bit version of the files if the 16-bit version is unavailable.
`subfolder` is used for HuggingFace repo_ids only. If provided, the
model will be downloaded from the designated subfolder rather than the
top-level repository folder. If a subfolder is attached to the repo_id
using the format `repo_owner/repo_name:subfolder`, then the subfolder
specified by the repo_id will override the subfolder argument.
`config` can be used to override all or a portion of the configuration
attributes returned by the model prober. See the section below for
details.
`access_token` is passed to the download queue and used to access
repositories that require it.
#### Monitoring the install job process
When you create an install job with `import_model()`, it launches the
download and installation process in the background and returns a
`ModelInstallJob` object for monitoring the process.
The `ModelInstallJob` class has the following structure:
| **Attribute** | **Type** | **Description** |
|----------------|-----------------|------------------|
| `status` | `InstallStatus` | An enum of ["waiting", "running", "completed" and "error" |
| `config_in` | `dict` | Overriding configuration values provided by the caller |
| `config_out` | `AnyModelConfig`| After successful completion, contains the configuration record written to the database |
| `inplace` | `boolean` | True if the caller asked to install the model in place using its local path |
| `source` | `ModelSource` | The local path, remote URL or repo_id of the model to be installed |
| `local_path` | `Path` | If a remote model, holds the path of the model after it is downloaded; if a local model, same as `source` |
| `error_type` | `str` | Name of the exception that led to an error status |
| `error` | `str` | Traceback of the error |
If the `event_bus` argument was provided, events will also be
broadcast to the InvokeAI event bus. The events will appear on the bus
as an event of type `EventServiceBase.model_event`, a timestamp and
the following event names:
- `model_install_started`
The payload will contain the keys `timestamp` and `source`. The latter
indicates the requested model source for installation.
- `model_install_progress`
Emitted at regular intervals when downloading a remote model, the
payload will contain the keys `timestamp`, `source`, `current_bytes`
and `total_bytes`. These events are _not_ emitted when a local model
already on the filesystem is imported.
- `model_install_completed`
Issued once at the end of a successful installation. The payload will
contain the keys `timestamp`, `source` and `key`, where `key` is the
ID under which the model has been registered.
- `model_install_error`
Emitted if the installation process fails for some reason. The payload
will contain the keys `timestamp`, `source`, `error_type` and
`error`. `error_type` is a short message indicating the nature of the
error, and `error` is the long traceback to help debug the problem.
#### Model confguration and probing
The install service uses the `invokeai.backend.model_manager.probe`
module during import to determine the model's type, base type, and
other configuration parameters. Among other things, it assigns a
default name and description for the model based on probed
fields.
When downloading remote models is implemented, additional
configuration information, such as list of trigger terms, will be
retrieved from the HuggingFace and Civitai model repositories.
The probed values can be overriden by providing a dictionary in the
optional `config` argument passed to `import_model()`. You may provide
overriding values for any of the model's configuration
attributes. Here is an example of setting the
`SchedulerPredictionType` and `name` for an sd-2 model:
This is typically used to set
the model's name and description, but can also be used to overcome
cases in which automatic probing is unable to (correctly) determine
the model's attribute. The most common situation is the
`prediction_type` field for sd-2 (and rare sd-1) models. Here is an
example of how it works:
```
install_job = installer.import_model(
source='stabilityai/stable-diffusion-2-1',
variant='fp16',
config=dict(
prediction_type=SchedulerPredictionType('v_prediction')
name='stable diffusion 2 base model',
)
)
```
### Other installer methods
This section describes additional methods provided by the installer class.
#### source2job = installer.wait_for_installs()
Block until all pending installs are completed or errored and return a
dictionary that maps the model `source` to the completed
`ModelInstallJob`.
#### jobs = installer.list_jobs([source])
Return a list of all active and complete `ModelInstallJobs`. An
optional `source` argument allows you to filter the returned list by a
model source string pattern using a partial string match.
#### job = installer.get_job(source)
Return the `ModelInstallJob` corresponding to the indicated model source.
#### installer.prune_jobs
Remove non-pending jobs (completed or errored) from the job list
returned by `list_jobs()` and `get_job()`.
#### installer.app_config, installer.record_store,
installer.event_bus
Properties that provide access to the installer's `InvokeAIAppConfig`,
`ModelRecordServiceBase` and `EventServiceBase` objects.
#### key = installer.register_path(model_path, config), key = installer.install_path(model_path, config)
These methods bypass the download queue and directly register or
install the model at the indicated path, returning the unique ID for
the installed model.
Both methods accept a Path object corresponding to a checkpoint or
diffusers folder, and an optional dict of config attributes to use to
override the values derived from model probing.
The difference between `register_path()` and `install_path()` is that
the former creates a model configuration record without changing the
location of the model in the filesystem. The latter makes a copy of
the model inside the InvokeAI models directory before registering
it.
#### installer.unregister(key)
This will remove the model config record for the model at key, and is
equivalent to `installer.record_store.del_model(key)`
#### installer.delete(key)
This is similar to `unregister()` but has the additional effect of
conditionally deleting the underlying model file(s) if they reside
within the InvokeAI models directory
#### installer.unconditionally_delete(key)
This method is similar to `unregister()`, but also unconditionally
deletes the corresponding model weights file(s), regardless of whether
they are inside or outside the InvokeAI models hierarchy.
#### List[str]=installer.scan_directory(scan_dir: Path, install: bool)
This method will recursively scan the directory indicated in
`scan_dir` for new models and either install them in the models
directory or register them in place, depending on the setting of
`install` (default False).
The return value is the list of keys of the new installed/registered
models.
#### installer.sync_to_config()
This method synchronizes models in the models directory and autoimport
directory to those in the `ModelConfigRecordService` database. New
models are registered and orphan models are unregistered.
#### installer.start(invoker)
The `start` method is called by the API intialization routines when
the API starts up. Its effect is to call `sync_to_config()` to
synchronize the model record store database with what's currently on
disk.
# The remainder of this documentation is provisional, pending implementation of the Download and Load services
## Let's get loaded, the lowdown on ModelLoadService
The `ModelLoadService` is responsible for loading a named model into
memory so that it can be used for inference. Despite the fact that it
does a lot under the covers, it is very straightforward to use.
An application-wide model loader is created at API initialization time
and stored in
`ApiDependencies.invoker.services.model_loader`. However, you can
create alternative instances if you wish.
### Creating a ModelLoadService object
The class is defined in
`invokeai.app.services.model_loader_service`. It is initialized with
an InvokeAIAppConfig object, from which it gets configuration
information such as the user's desired GPU and precision, and with a
previously-created `ModelRecordServiceBase` object, from which it
loads the requested model's configuration information.
Here is a typical initialization pattern:
```
from invokeai.app.services.config import InvokeAIAppConfig
from invokeai.app.services.model_record_service import ModelRecordServiceBase
from invokeai.app.services.model_loader_service import ModelLoadService
config = InvokeAIAppConfig.get_config()
store = ModelRecordServiceBase.open(config)
loader = ModelLoadService(config, store)
```
Note that we are relying on the contents of the application
configuration to choose the implementation of
`ModelRecordServiceBase`.
### get_model(key, [submodel_type], [context]) -> ModelInfo:
*** TO DO: change to get_model(key, context=None, **kwargs)
The `get_model()` method, like its similarly-named cousin in
`ModelRecordService`, receives the unique key that identifies the
model. It loads the model into memory, gets the model ready for use,
and returns a `ModelInfo` object.
The optional second argument, `subtype` is a `SubModelType` string
enum, such as "vae". It is mandatory when used with a main model, and
is used to select which part of the main model to load.
The optional third argument, `context` can be provided by
an invocation to trigger model load event reporting. See below for
details.
The returned `ModelInfo` object shares some fields in common with
`ModelConfigBase`, but is otherwise a completely different beast:
| **Field Name** | **Type** | **Description** |
|----------------|-----------------|------------------|
| `key` | str | The model key derived from the ModelRecordService database |
| `name` | str | Name of this model |
| `base_model` | BaseModelType | Base model for this model |
| `type` | ModelType or SubModelType | Either the model type (non-main) or the submodel type (main models)|
| `location` | Path or str | Location of the model on the filesystem |
| `precision` | torch.dtype | The torch.precision to use for inference |
| `context` | ModelCache.ModelLocker | A context class used to lock the model in VRAM while in use |
The types for `ModelInfo` and `SubModelType` can be imported from
`invokeai.app.services.model_loader_service`.
To use the model, you use the `ModelInfo` as a context manager using
the following pattern:
```
model_info = loader.get_model('f13dd932c0c35c22dcb8d6cda4203764', SubModelType('vae'))
with model_info as vae:
image = vae.decode(latents)[0]
```
The `vae` model will stay locked in the GPU during the period of time
it is in the context manager's scope.
`get_model()` may raise any of the following exceptions:
- `UnknownModelException` -- key not in database
- `ModelNotFoundException` -- key in database but model not found at path
- `InvalidModelException` -- the model is guilty of a variety of sins
** TO DO: ** Resolve discrepancy between ModelInfo.location and
ModelConfig.path.
### Emitting model loading events
When the `context` argument is passed to `get_model()`, it will
retrieve the invocation event bus from the passed `InvocationContext`
object to emit events on the invocation bus. The two events are
"model_load_started" and "model_load_completed". Both carry the
following payload:
```
payload=dict(
queue_id=queue_id,
queue_item_id=queue_item_id,
queue_batch_id=queue_batch_id,
graph_execution_state_id=graph_execution_state_id,
model_key=model_key,
submodel=submodel,
hash=model_info.hash,
location=str(model_info.location),
precision=str(model_info.precision),
)
```
***
## Get on line: The Download Queue
InvokeAI can download arbitrary files using a multithreaded background
download queue. Internally, the download queue is used for installing
models located at remote locations. The queue is implemented by the
`DownloadQueueService` defined in
`invokeai.app.services.download_manager`. However, most of the
implementation is spread out among several files in
`invokeai/backend/model_manager/download/*`
A default download queue is located in
`ApiDependencies.invoker.services.download_queue`. However, you can
create additional instances if you need to isolate your queue from the
main one.
### A job for every task
The queue operates on a series of download job objects. These objects
specify the source and destination of the download, and keep track of
the progress of the download. Jobs come in a variety of shapes and
colors as they are progressively specialized for particular download
task.
The basic job is the `DownloadJobBase`, a pydantic object with the
following fields:
| **Field** | **Type** | **Default** | **Description** |
|----------------|-----------------|---------------|-----------------|
| `id` | int | | Job ID, an integer >= 0 |
| `priority` | int | 10 | Job priority. Lower priorities run before higher priorities |
| `source` | str | | Where to download from (specialized types used in subclasses)|
| `destination` | Path | | Where to download to |
| `status` | DownloadJobStatus| Idle | Job's status (see below) |
| `event_handlers` | List[DownloadEventHandler]| | Event handlers (see below) |
| `job_started` | float | | Timestamp for when the job started running |
| `job_ended` | float | | Timestamp for when the job completed or errored out |
| `job_sequence` | int | | A counter that is incremented each time a model is dequeued |
| `preserve_partial_downloads`| bool | False | Resume partial downloads when relaunched. |
| `error` | Exception | | A copy of the Exception that caused an error during download |
When you create a job, you can assign it a `priority`. If multiple
jobs are queued, the job with the lowest priority runs first. (Don't
blame me! The Unix developers came up with this convention.)
Every job has a `source` and a `destination`. `source` is a string in
the base class, but subclassses redefine it more specifically.
The `destination` must be the Path to a file or directory on the local
filesystem. If the Path points to a new or existing file, then the
source will be stored under that filename. If the Path ponts to an
existing directory, then the downloaded file will be stored inside the
directory, usually using the name assigned to it at the remote site in
the `content-disposition` http field.
When the job is submitted, it is assigned a numeric `id`. The id can
then be used to control the job, such as starting, stopping and
cancelling its download.
The `status` field is updated by the queue to indicate where the job
is in its lifecycle. Values are defined in the string enum
`DownloadJobStatus`, a symbol available from
`invokeai.app.services.download_manager`. Possible values are:
| **Value** | **String Value** | ** Description ** |
|--------------|---------------------|-------------------|
| `IDLE` | idle | Job created, but not submitted to the queue |
| `ENQUEUED` | enqueued | Job is patiently waiting on the queue |
| `RUNNING` | running | Job is running! |
| `PAUSED` | paused | Job was paused and can be restarted |
| `COMPLETED` | completed | Job has finished its work without an error |
| `ERROR` | error | Job encountered an error and will not run again|
| `CANCELLED` | cancelled | Job was cancelled and will not run (again) |
`job_started`, `job_ended` and `job_sequence` indicate when the job
was started (using a python timestamp), when it completed, and the
order in which it was taken off the queue. These are mostly used for
debugging and performance testing.
In case of an error, the Exception that caused the error will be
placed in the `error` field, and the job's status will be set to
`DownloadJobStatus.ERROR`.
After an error occurs, any partially downloaded files will be deleted
from disk, unless `preserve_partial_downloads` was set to True at job
creation time (or set to True any time before the error
occurred). Note that since all InvokeAI model install operations
involve downloading files to a temporary directory that has a limited
lifetime, this flag is not used by the model installer.
There are a series of subclasses of `DownloadJobBase` that provide
support for specific types of downloads. These are:
#### DownloadJobPath
This subclass redefines `source` to be a filesystem Path. It is used
to move a file or directory from the `source` to the `destination`
paths in the background using a uniform event-based infrastructure.
#### DownloadJobRemoteSource
This subclass adds the following fields to the job:
| **Field** | **Type** | **Default** | **Description** |
|----------------|-----------------|---------------|-----------------|
| `bytes` | int | 0 | bytes downloaded so far |
| `total_bytes` | int | 0 | total size to download |
| `access_token` | Any | None | an authorization token to present to the remote source |
The job will start out with 0/0 in its bytes/total_bytes fields. Once
it starts running, `total_bytes` will be populated from information
provided in the HTTP download header (if available), and the number of
bytes downloaded so far will be progressively incremented.
#### DownloadJobURL
This is a subclass of `DownloadJobBase`. It redefines `source` to be a
Pydantic `AnyHttpUrl` object, which enforces URL validation checking
on the field.
Note that the installer service defines an additional subclass of
`DownloadJobRemoteSource` that accepts HuggingFace repo_ids in
addition to URLs. This is discussed later in this document.
### Event handlers
While a job is being downloaded, the queue will emit events at
periodic intervals. A typical series of events during a successful
download session will look like this:
- enqueued
- running
- running
- running
- completed
There will be a single enqueued event, followed by one or more running
events, and finally one `completed`, `error` or `cancelled`
events.
It is possible for a caller to pause download temporarily, in which
case the events may look something like this:
- enqueued
- running
- running
- paused
- running
- completed
The download queue logs when downloads start and end (unless `quiet`
is set to True at initialization time) but doesn't log any progress
events. You will probably want to be alerted to events during the
download job and provide more user feedback. In order to intercept and
respond to events you may install a series of one or more event
handlers in the job. Whenever the job's status changes, the chain of
event handlers is traversed and executed in the same thread that the
download job is running in.
Event handlers have the signature `Callable[["DownloadJobBase"],
None]`, i.e.
```
def handler(job: DownloadJobBase):
pass
```
A typical handler will examine `job.status` and decide if there's
something to be done. This can include cancelling or erroring the job,
but more typically is used to report on the job status to the user
interface or to perform certain actions on successful completion of
the job.
Event handlers can be attached to a job at creation time. In addition,
you can create a series of default handlers that are attached to the
queue object itself. These handlers will be executed for each job
after the job's own handlers (if any) have run.
During a download, running events are issued every time roughly 1% of
the file is transferred. This is to provide just enough granularity to
update a tqdm progress bar smoothly.
Handlers can be added to a job after the fact using the job's
`add_event_handler` method:
```
job.add_event_handler(my_handler)
```
All handlers can be cleared using the job's `clear_event_handlers()`
method. Note that it might be a good idea to pause the job before
altering its handlers.
### Creating a download queue object
The `DownloadQueueService` constructor takes the following arguments:
| **Argument** | **Type** | **Default** | **Description** |
|----------------|-----------------|---------------|-----------------|
| `event_handlers` | List[DownloadEventHandler] | [] | Event handlers |
| `max_parallel_dl` | int | 5 | Maximum number of simultaneous downloads allowed |
| `requests_session` | requests.sessions.Session | None | An alternative requests Session object to use for the download |
| `quiet` | bool | False| Do work quietly without issuing log messages |
A typical initialization sequence will look like:
```
from invokeai.app.services.download_manager import DownloadQueueService
def log_download_event(job: DownloadJobBase):
logger.info(f'job={job.id}: status={job.status}')
queue = DownloadQueueService(
event_handlers=[log_download_event]
)
```
Event handlers can be provided to the queue at initialization time as
shown in the example. These will be automatically appended to the
handler list for any job that is submitted to this queue.
`max_parallel_dl` sets the number of simultaneous active downloads
that are allowed. The default of five has not been benchmarked in any
way, but seems to give acceptable performance.
`requests_session` can be used to provide a `requests` module Session
object that will be used to stream remote URLs to disk. This facility
was added for use in the module's unit tests to simulate a remote web
server, but may be useful in other contexts.
`quiet` will prevent the queue from issuing any log messages at the
INFO or higher levels.
### Submitting a download job
You can submit a download job to the queue either by creating the job
manually and passing it to the queue's `submit_download_job()` method,
or using the `create_download_job()` method, which will do the same
thing on your behalf.
To use the former method, follow this example:
```
job = DownloadJobRemoteSource(
source='http://www.civitai.com/models/13456',
destination='/tmp/models/',
event_handlers=[my_handler1, my_handler2], # if desired
)
queue.submit_download_job(job, start=True)
```
`submit_download_job()` takes just two arguments: the job to submit,
and a flag indicating whether to immediately start the job (defaulting
to True). If you choose not to start the job immediately, you can
start it later by calling the queue's `start_job()` or
`start_all_jobs()` methods, which are described later.
To have the queue create the job for you, follow this example instead:
```
job = queue.create_download_job(
source='http://www.civitai.com/models/13456',
destdir='/tmp/models/',
filename='my_model.safetensors',
event_handlers=[my_handler1, my_handler2], # if desired
start=True,
)
```
The `filename` argument forces the downloader to use the specified
name for the file rather than the name provided by the remote source,
and is equivalent to manually specifying a destination of
`/tmp/models/my_model.safetensors' in the submitted job.
Here is the full list of arguments that can be provided to
`create_download_job()`:
| **Argument** | **Type** | **Default** | **Description** |
|------------------|------------------------------|-------------|-------------------------------------------|
| `source` | Union[str, Path, AnyHttpUrl] | | Download remote or local source |
| `destdir` | Path | | Destination directory for downloaded file |
| `filename` | Path | None | Filename for downloaded file |
| `start` | bool | True | Enqueue the job immediately |
| `priority` | int | 10 | Starting priority for this job |
| `access_token` | str | None | Authorization token for this resource |
| `event_handlers` | List[DownloadEventHandler] | [] | Event handlers for this job |
Internally, `create_download_job()` has a little bit of internal logic
that looks at the type of the source and selects the right subclass of
`DownloadJobBase` to create and enqueue.
**TODO**: move this logic into its own method for overriding in
subclasses.
### Job control
Prior to completion, jobs can be controlled with a series of queue
method calls. Do not attempt to modify jobs by directly writing to
their fields, as this is likely to lead to unexpected results.
Any method that accepts a job argument may raise an
`UnknownJobIDException` if the job has not yet been submitted to the
queue or was not created by this queue.
#### queue.join()
This method will block until all the active jobs in the queue have
reached a terminal state (completed, errored or cancelled).
#### jobs = queue.list_jobs()
This will return a list of all jobs, including ones that have not yet
been enqueued and those that have completed or errored out.
#### job = queue.id_to_job(int)
This method allows you to recover a submitted job using its ID.
#### queue.prune_jobs()
Remove completed and errored jobs from the job list.
#### queue.start_job(job)
If the job was submitted with `start=False`, then it can be started
using this method.
#### queue.pause_job(job)
This will temporarily pause the job, if possible. It can later be
restarted and pick up where it left off using `queue.start_job()`.
#### queue.cancel_job(job)
This will cancel the job if possible and clean up temporary files and
other resources that it might have been using.
#### queue.start_all_jobs(), queue.pause_all_jobs(), queue.cancel_all_jobs()
This will start/pause/cancel all jobs that have been submitted to the
queue and have not yet reached a terminal state.
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