# Copyright 2017-2025 John Snow Labs
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"""Contains classes for the AutoGGUFVisionModel."""
from sparknlp.common import *
[docs]class AutoGGUFVisionModel(AnnotatorModel, HasBatchedAnnotate, HasLlamaCppProperties):
"""Multimodal annotator that uses the llama.cpp library to generate text completions with large
language models. It supports ingesting images for captioning.
At the moment only CLIP based models are supported.
For settable parameters, and their explanations, see HasLlamaCppInferenceProperties,
HasLlamaCppModelProperties and refer to the llama.cpp documentation of
`server.cpp <https://github.com/ggerganov/llama.cpp/tree/7d5e8777ae1d21af99d4f95be10db4870720da91/examples/server>`__
for more information.
If the parameters are not set, the annotator will default to use the parameters provided by
the model.
This annotator expects a column of annotator type AnnotationImage for the image and
Annotation for the caption. Note that the image bytes in the image annotation need to be
raw image bytes without preprocessing. We provide the helper function
ImageAssembler.loadImagesAsBytes to load the image bytes from a directory.
Pretrained models can be loaded with ``pretrained`` of the companion object:
.. code-block:: python
autoGGUFVisionModel = AutoGGUFVisionModel.pretrained() \\
.setInputCols(["image", "document"]) \\
.setOutputCol("completions")
The default model is ``"llava_v1.5_7b_Q4_0_gguf"``, if no name is provided.
For available pretrained models please see the `Models Hub <https://sparknlp.org/models>`__.
For extended examples of usage, see the
`AutoGGUFVisionModelTest <https://github.com/JohnSnowLabs/spark-nlp/tree/master/src/test/scala/com/johnsnowlabs/nlp/annotators/seq2seq/AutoGGUFVisionModelTest.scala>`__
and the
`example notebook <https://github.com/JohnSnowLabs/spark-nlp/tree/master/examples/python/llama.cpp/llama.cpp_in_Spark_NLP_AutoGGUFVisionModel.ipynb>`__.
====================== ======================
Input Annotation types Output Annotation type
====================== ======================
``IMAGE, DOCUMENT`` ``DOCUMENT``
====================== ======================
Parameters
----------
nThreads
Set the number of threads to use during generation
nThreadsDraft
Set the number of threads to use during draft generation
nThreadsBatch
Set the number of threads to use during batch and prompt processing
nThreadsBatchDraft
Set the number of threads to use during batch and prompt processing
nCtx
Set the size of the prompt context
nBatch
Set the logical batch size for prompt processing (must be >=32 to use BLAS)
nUbatch
Set the physical batch size for prompt processing (must be >=32 to use BLAS)
nDraft
Set the number of tokens to draft for speculative decoding
nChunks
Set the maximal number of chunks to process
nSequences
Set the number of sequences to decode
pSplit
Set the speculative decoding split probability
nGpuLayers
Set the number of layers to store in VRAM (-1 - use default)
nGpuLayersDraft
Set the number of layers to store in VRAM for the draft model (-1 - use default)
gpuSplitMode
Set how to split the model across GPUs
mainGpu
Set the main GPU that is used for scratch and small tensors.
tensorSplit
Set how split tensors should be distributed across GPUs
grpAttnN
Set the group-attention factor
grpAttnW
Set the group-attention width
ropeFreqBase
Set the RoPE base frequency, used by NTK-aware scaling
ropeFreqScale
Set the RoPE frequency scaling factor, expands context by a factor of 1/N
yarnExtFactor
Set the YaRN extrapolation mix factor
yarnAttnFactor
Set the YaRN scale sqrt(t) or attention magnitude
yarnBetaFast
Set the YaRN low correction dim or beta
yarnBetaSlow
Set the YaRN high correction dim or alpha
yarnOrigCtx
Set the YaRN original context size of model
defragmentationThreshold
Set the KV cache defragmentation threshold
numaStrategy
Set optimization strategies that help on some NUMA systems (if available)
ropeScalingType
Set the RoPE frequency scaling method, defaults to linear unless specified by the model
poolingType
Set the pooling type for embeddings, use model default if unspecified
modelDraft
Set the draft model for speculative decoding
modelAlias
Set a model alias
lookupCacheStaticFilePath
Set path to static lookup cache to use for lookup decoding (not updated by generation)
lookupCacheDynamicFilePath
Set path to dynamic lookup cache to use for lookup decoding (updated by generation)
embedding
Whether to load model with embedding support
flashAttention
Whether to enable Flash Attention
inputPrefixBos
Whether to add prefix BOS to user inputs, preceding the `--in-prefix` string
useMmap
Whether to use memory-map model (faster load but may increase pageouts if not using mlock)
useMlock
Whether to force the system to keep model in RAM rather than swapping or compressing
noKvOffload
Whether to disable KV offload
systemPrompt
Set a system prompt to use
chatTemplate
The chat template to use
inputPrefix
Set the prompt to start generation with
inputSuffix
Set a suffix for infilling
cachePrompt
Whether to remember the prompt to avoid reprocessing it
nPredict
Set the number of tokens to predict
topK
Set top-k sampling
topP
Set top-p sampling
minP
Set min-p sampling
tfsZ
Set tail free sampling, parameter z
typicalP
Set locally typical sampling, parameter p
temperature
Set the temperature
dynatempRange
Set the dynamic temperature range
dynatempExponent
Set the dynamic temperature exponent
repeatLastN
Set the last n tokens to consider for penalties
repeatPenalty
Set the penalty of repeated sequences of tokens
frequencyPenalty
Set the repetition alpha frequency penalty
presencePenalty
Set the repetition alpha presence penalty
miroStat
Set MiroStat sampling strategies.
mirostatTau
Set the MiroStat target entropy, parameter tau
mirostatEta
Set the MiroStat learning rate, parameter eta
penalizeNl
Whether to penalize newline tokens
nKeep
Set the number of tokens to keep from the initial prompt
seed
Set the RNG seed
nProbs
Set the amount top tokens probabilities to output if greater than 0.
minKeep
Set the amount of tokens the samplers should return at least (0 = disabled)
grammar
Set BNF-like grammar to constrain generations
penaltyPrompt
Override which part of the prompt is penalized for repetition.
ignoreEos
Set whether to ignore end of stream token and continue generating (implies --logit-bias 2-inf)
disableTokenIds
Set the token ids to disable in the completion
stopStrings
Set strings upon seeing which token generation is stopped
samplers
Set which samplers to use for token generation in the given order
useChatTemplate
Set whether or not generate should apply a chat template
Notes
-----
To use GPU inference with this annotator, make sure to use the Spark NLP GPU package and set
the number of GPU layers with the `setNGpuLayers` method.
When using larger models, we recommend adjusting GPU usage with `setNCtx` and `setNGpuLayers`
according to your hardware to avoid out-of-memory errors.
Examples
>>> import sparknlp
>>> from sparknlp.base import *
>>> from sparknlp.annotator import *
>>> from pyspark.ml import Pipeline
>>> from pyspark.sql.functions import lit
>>> documentAssembler = DocumentAssembler() \\
... .setInputCol("caption") \\
... .setOutputCol("caption_document")
>>> imageAssembler = ImageAssembler() \\
... .setInputCol("image") \\
... .setOutputCol("image_assembler")
>>> imagesPath = "src/test/resources/image/"
>>> data = ImageAssembler \\
... .loadImagesAsBytes(spark, imagesPath) \\
... .withColumn("caption", lit("Caption this image.")) # Add a caption to each image.
>>> nPredict = 40
>>> model = AutoGGUFVisionModel.pretrained() \\
... .setInputCols(["caption_document", "image_assembler"]) \\
... .setOutputCol("completions") \\
... .setBatchSize(4) \\
... .setNGpuLayers(99) \\
... .setNCtx(4096) \\
... .setMinKeep(0) \\
... .setMinP(0.05) \\
... .setNPredict(nPredict) \\
... .setNProbs(0) \\
... .setPenalizeNl(False) \\
... .setRepeatLastN(256) \\
... .setRepeatPenalty(1.18) \\
... .setStopStrings(["</s>", "Llama:", "User:"]) \\
... .setTemperature(0.05) \\
... .setTfsZ(1) \\
... .setTypicalP(1) \\
... .setTopK(40) \\
... .setTopP(0.95)
>>> pipeline = Pipeline().setStages([documentAssembler, imageAssembler, model])
>>> pipeline.fit(data).transform(data) \\
... .selectExpr("reverse(split(image.origin, '/'))[0] as image_name", "completions.result") \\
... .show(truncate = False)
+-----------------+----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------+
|image_name |result |
+-----------------+----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------+
|palace.JPEG |[ The image depicts a large, ornate room with high ceilings and beautifully decorated walls. There are several chairs placed throughout the space, some of which have cushions] |
|egyptian_cat.jpeg|[ The image features two cats lying on a pink surface, possibly a bed or sofa. One cat is positioned towards the left side of the scene and appears to be sleeping while holding] |
|hippopotamus.JPEG|[ A large brown hippo is swimming in a body of water, possibly an aquarium. The hippo appears to be enjoying its time in the water and seems relaxed as it floats] |
|hen.JPEG |[ The image features a large chicken standing next to several baby chickens. In total, there are five birds in the scene: one adult and four young ones. They appear to be gathered together] |
|ostrich.JPEG |[ The image features a large, long-necked bird standing in the grass. It appears to be an ostrich or similar species with its head held high and looking around. In addition to] |
|junco.JPEG |[ A small bird with a black head and white chest is standing on the snow. It appears to be looking at something, possibly food or another animal in its vicinity. The scene takes place out] |
|bluetick.jpg |[ A dog with a red collar is sitting on the floor, looking at something. The dog appears to be staring into the distance or focusing its attention on an object in front of it.] |
|chihuahua.jpg |[ A small brown dog wearing a sweater is sitting on the floor. The dog appears to be looking at something, possibly its owner or another animal in the room. It seems comfortable and relaxed]|
|tractor.JPEG |[ A man is sitting in the driver's seat of a green tractor, which has yellow wheels and tires. The tractor appears to be parked on top of an empty field with] |
|ox.JPEG |[ A large bull with horns is standing in a grassy field.] |
+-----------------+----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------+-------
"""
name = "AutoGGUFVisionModel"
inputAnnotatorTypes = [AnnotatorType.IMAGE, AnnotatorType.DOCUMENT]
outputAnnotatorType = AnnotatorType.DOCUMENT
@keyword_only
def __init__(self, classname="com.johnsnowlabs.nlp.annotators.seq2seq.AutoGGUFVisionModel", java_model=None):
super(AutoGGUFVisionModel, self).__init__(
classname=classname,
java_model=java_model
)
self._setDefault(
useChatTemplate=True,
nCtx=4096,
nBatch=512,
embedding=False,
nPredict=100
)
[docs] @staticmethod
def loadSavedModel(modelPath, mmprojPath, spark_session):
"""Loads a locally saved modelPath.
Parameters
----------
modelPath : str
Path to the modelPath file
mmprojPath : str
Path to the mmprojPath file
spark_session : pyspark.sql.SparkSession
The current SparkSession
Returns
-------
AutoGGUFVisionModel
The restored modelPath
"""
from sparknlp.internal import _AutoGGUFVisionLoader
jModel = _AutoGGUFVisionLoader(modelPath, mmprojPath, spark_session._jsparkSession)._java_obj
return AutoGGUFVisionModel(java_model=jModel)
[docs] @staticmethod
def pretrained(name="llava_v1.5_7b_Q4_0_gguf", lang="en", remote_loc=None):
"""Downloads and loads a pretrained model.
Parameters
----------
name : str, optional
Name of the pretrained model, by default "llava_v1.5_7b_Q4_0_gguf"
lang : str, optional
Language of the pretrained model, by default "en"
remote_loc : str, optional
Optional remote address of the resource, by default None. Will use
Spark NLPs repositories otherwise.
Returns
-------
AutoGGUFVisionModel
The restored model
"""
from sparknlp.pretrained import ResourceDownloader
return ResourceDownloader.downloadModel(AutoGGUFVisionModel, name, lang, remote_loc)