TensorRT-LLM includes a C++ component to execute TensorRT engines built with the Python API as described in the Architecture document. That component is called the C++ runtime.
The API of the C++ runtime is composed of the classes declared in
cpp/include/tensorrt_llm/runtime
and
implemented in
cpp/tensorrt_llm/runtime
. An example of
how to use the C++ runtime for a GPT-like auto-regressive model can be found in
cpp/tests/runtime/gptSessionTest.cpp
.
Even if the different components described in that document mention GPT in their name, they are not restricted to this specific model. Those classes can be used to implement auto-regressive models like BLOOM, GPT-J, GPT-NeoX or LLaMA, for example.
Complete support of encoder-decoder models, like T5, will be added to
TensorRT-LLM in a future release. An experimental version, only in Python for
now, can be found in the examples/enc_dec
folder.
The main component of the C++ runtime is the session. For GPT-like
auto-regressive models, it is the
GptSession
class.
The constructors of that class allow users to specify the model and the
environment to execute it. The model is described by an instance of the
GptModelConfig
class and a pointer to the TensorRT engine that must be
executed to perform the inference. The environment is configured through the
WorldConfig
(that name comes from
MPI and its "famous"
MPI_COMM_WORLD
default communicator). The constructor also accepts an
optional object to log information, warnings and errors:
#include <tensorrt_llm/runtime/gptSession.h>
using namespace tensorrt_llm::runtime;
GptSession session(sessionConfig, // Configuration of the session,
modelConfig, // Description of the model,
worldConfig, // Description of the environment,
engineBuffer, // The compiled TensorRT engine (const void*),
engineSize, // The size in bytes of the TensorRT engine (size_t),
logger); // The optional logger.
The above constructor accepts a const void*
pointer to the engine and the
associated size (in bytes) of that buffer. There exist other overloaded
versions that take std::vector<uint8_t>
or std::string
arguments to
encapsulate the engine.
The session configuration is an instance of the
GptSession::Config
class.
The constructor of this class requires three arguments:
maxBatchSize
, the maximum number of sequences in a batch,maxBeamWidth
, the maximum width of the beams in beam-search,maxSequenceLength
, the length of the longest input sequence,
Additionally, the class encapsulates the following optional parameters (they are declared as public member variables and can be accessed directly):
decoderPerRequest
, whether the session will use a different decoder per request. It must be set totrue
when running in-flight batching,cudaGraphMode
, whether the session will use CUDA graphs for the engine execution in generation phase,kvCacheConfig
encapsulates parameters to configure paged KV cache, when the paged KV cache is enabled in the engine:maxTokens
, the maximum number of tokens that will have to be stored in the paged KV cache,freeGpuMemoryFraction
, the fraction of free GPU memory that will be reserved for paged KV cache,
ctxMicroBatchSize
, the micro batch size to be used in context phase. Batches entered inGptSession::generation
will be split into smaller micro batches of this size,genMicroBatchSize
, the micro batch size to be used in generation phase, Batches entered inGptSession::generation
will be split into smaller micro batches of this size.
The model configuration is an instance of the
GptModelConfig
class.
That class encapsulates the following parameters (they are declared as private
member variables and exposed through getters and setters):
vocabSize
, the size of the vocabulary,numLayers
, the number of layers in the model,numHeads
, the number of heads in the attention block,numKvHeads
, is the number of heads for K and V in the attention component. When the number of K/V heads is the same as the number of (Q) heads, the model uses Multi-head Attention. When the number of K/V heads is 1, it uses Multi-query Attention. Otherwise, it uses Group-query Attention. See GPT Attention,hiddenSize
, the size of the hidden dimension,dataType
, the datatype that was used to build the TensorRT engine and that must be used to run the model during inference,useGptAttentionPlugin
, indicates if the GPT Attention operator was compiled using the GPT Attention plugin,inputPacked
, indicates that the input must be packed (or padded when set tofalse
). For performance reasons, it is recommended to always use packed, even if its default is set tofalse
(will be changed in a future release). See GPT Attention,pagedKvCache
, indicates if the K/V cache uses paging. See GPT Attention,tokensPerBlock
, is the number of tokens in each block of the K/V cache. It's relevant when the paged K/V cache is enabled. By default, the value is 64. See GPT Attention,quantMode
, controls the quantization method. See Numerical Precision.maxBatchSize
, indicates the maximum batch size that the TensorRT engine was built for,maxInputLen
/maxOutputLen
, are the maximum sizes of the input/output sequences.
Familiarity with MPI, is not required to utilize the TensorRT-LMM C++ runtime. There are two main things you need to know: (1) The C++ Runtime in TensorRT-LLM uses processes to execute TensorRT engines on the different GPUs. Those GPUs can be located on a single node as well as on different nodes in a cluster. Each process is called a rank in MPI. (2) The ranks are grouped in communication groups. The TensorRT-LLM C++ Runtime calls that group the world.
The world configuration is an instance of the
WorldConfig
class. In this release, that class encapsulates the following parameters:
tensorParallelism
, is the number of ranks that collaborate together to implement Tensor Parallelism (TP). With TP each GPU performs computations for all the layers of the model. Some of those computations are distributed across the GPU. TP is more balanced than PP (see below), in most cases, but requires higher bandwidth between the GPUs. It is the recommended setting in the presence of NVLINK between GPUs,pipelineParallelism
, is the number of ranks that collaborate together to implement Pipeline Parallelism (PP). With PP, each GPU works on a subset of consecutive layers and communications between the GPUs happen only at the boundaries of the subsets of layers. It is harder to guarantee the full utilization of the GPUs with PP but it requires less memory bandwidth. It is recommended in the absence of NVLINK between GPUs,rank
, is the unique identifier of the rank (see below),gpusPerNode
, indicates the number of GPUs on each node. Having that information allows the C++ runtime to optimize communications between GPUs in a node (like taking advantage of the NVLINK interconnect between GPUs of an A100 DGX node).
For a multi-GPU configuration (single or multi-node), each rank must create its
own instance of GptSession
using its own WorldConfig
. A typical example
is:
#include "tensorrt_llm/common/mpiUtils.h"
// Get the unique identifier for each rank.
auto const rank = COMM_SESSION.getRank();
// Create the TensorRT-LLM Runtime WorldConfig.
tensorrt_llm::runtime::WorldConfig worldConfig(tensorParallelism, pipelineParallelism, rank);
// Create the GPT session (as shown above).
tensorrt_llm::runtime::GptSession session(sessionConfig, modelConfig, worldConfig, ...);
For simplicity, TensorRT-LLM provides users with the following simplified API:
auto worldConfig = tensorrt_llm::runtime::WorldConfig::mpi();
Once compiled, that C++ code must be executed using the mpirun
command
installed on the system (talk to your system administrator if needed):
# Launch the program using two processes (worldSize == 2 and ranks == {0, 1}).
mpirun -n 2 ...
The GptSession::generate
member function performs the generation loop. Given
input tensors to read from, output tensors to populate, that member function
will run the generation loop until it reaches the maximum number of tokens that
can be produced or each sequence has reached completion (due to the production
of "end-of-sequence" or a word in the list of "stop words"). The pseudo-code of
that function looks like (member function names were changed to keep the
presentation simple):
// Have all the sequences in the batch reached completion?
bool allFinished = false;
// Until all sequences are finished or the number of steps reaches the limit...
for (int step = 0; !allFinished && step < maxNewTokens; ++step) {
// Trigger the computation of the logits...
computeLogits(...);
// Run the sampling to produce a token (for each active sequence) from the logits.
allFinished = generateTokensFromLogits(...);
// Callback to stream the output tokens while the generation loop continues.
onTokenGenerated(...);
}
The generate
member function takes an instance of the
GenerationInput
class and
populates an instance of the
GenerationOutput
class.
Mandatory inputs
endId
, is the token ID that marks the end of the input sequence (akaEOS
or end-of-sequence). It's50,256
for the GPT2 model which has a vocabulary of50,257
tokens, for example,padId
, is the token ID that is used for padding (i.e. fills in the slots that are at an index greater-or-equal to the input length for padded sequences). It can be set to the same value asendId
,ids
, is the tensor of input IDs. That tensor must be allocated on the GPU. When the input tensor is padded, the shape ofids
is[batchSize, maxInputLength]
, wherebatchSize
andmaxInputLength
must respect the maximum sizes insessionConfig
passed to theGptSession
constructor. When the input is packed, the shape ofids
is[numTokens]
, wherenumTokens
is the sum of the lengths of the different sequences in the batch,lengths
, is the tensor of input sequence lengths. That tensor must be allocated on the GPU and containbatchSize
values,packed
, indicates if theids
tensor is packed or padded. In this release, that flag must match the value passed to the constructor through the instance of theModelConfig
class. In a future release, the session may be made more flexible and automatically pad or pack the input,
Optional inputs
embeddingBiasOpt
, is a tensor of floating-point values on the GPU that contains the bias to add to the logits during sampling (after the projection from hidden states to logits as the last step of the model). This tensor must havevocabSize
elements (as defined in theModelConfig
argument passed to the constructor),badWordsList
, is a tensor of integers on the GPU that encodes the list of words that have to be banned from generated sequences. Its shape is[2, badWordsLength]
, as explained below, or[batchSize, 2, badWordsLength]
when there is a different list for each sequence in the batch,stopWordsList
, is a tensor of integers on the GPU that encodes the list of words that trigger the end of the generation for a sequence. Its shape is[2, stopWordsLength]
, as explained below, or[batchSize, 2, stopWordsLength]
when there is a different list for each sequence in the batch,maxNewTokens
, is the maximum number of tokens to generate.
The badWordsList
and stopWordsList
tensors have the same shape [2, length]
. Let's consider an example with three words to describe the
representation of those lists. The first word contains tokens [5, 7, 3]
, the
second one contains [9, 2]
and the third one is composed of tokens [6, 2, 4, 1]
. In total, there are 9 tokens. That's the length. The shape of the tensor
is [2, 9]
. The first row of the tensor must contain the 9 token IDs and the
second row must store the
inclusive prefix-sum
of the word lengths as shown on the following diagram:
0 3 5 9
| | | |
V V V V
[ 5, 7, 3, 9, 2, 6, 2, 4, 1]
[ 3, 5, 9, -1, -1, -1, -1, -1, -1]
In case all the words are made of a single token, the inner-most dimension of
the tensor must be increased by 1 (i.e. the length for 4 words, each made of a
single token, must be 5 instead of 4 -- the shape is [2, 5]
).
Mandatory outputs
ids
, is a tensor that contains the output token IDs. Its shape is[batchSize, beamWidth, maxSeqLength]
wheremaxSeqLength
is the sum ofmaxInputLength
andmaxNewTokens
. After generation, it contains, for each sequence, a copy of the input tokens followed by the output tokens. When a sequence is shorter thanmaxSeqLength
, padding tokens are added at the end of the sequence.
Note that the shape of that tensor is different in this version of
TensorRT-LLM from its shape in previous versions where it was [maxSeqLength, batchSize, beamWidth]
.
Optional outputs
logProbs
, is a tensor of floating-point values on the GPU to store the log-prob of the generated tokens. Its shape is[maxNewTokens, batchSize, beamWidth]
. Its shape will likely change in a future release to match the shape of the outputids
tensor.contextLogits
, is a tensor of values on the GPU (same datatype as the computation type) to store the logits for the context. Its shape is[batchSize, maxSequenceLength, vocabSizePadded]
. If useremove_input_padding
, its shape is[packedSize, vocabSizePadded]
. This buffer will only be filled in if the TensorRT engine was built with thegather_context_logits
orgather_all_token_logits
parameter enabled. It is important to point out that enabling that computation may have an impact on performance (the final LM head has to perform a matrix multiplication on all the context tokens instead of a just the last one).generationLogits
, is a tensor of values on the GPU (same datatype as the computation type) to store the logits for the generation. Its shape is[batchSize, beamWidth, maxOutputLen, vocabSizePadded]
. This buffer will only be filled in if the TensorRT engine was built with thegather_generation_logits
orgather_all_token_logits
parameter enabled.onTokenGenerated
, is a callback function invoked in the generation loop to pass newly generated tokens to the caller while the loop continues to execute. An implementation of that callback must accept the outputids
tensor, the generationstep
and a boolean flag that indicates if the generation is complete.
The SamplingConfig
class encapsulates parameters that control the
generation of new tokens.
Except for the beamWidth
parameter, all the fields are optional and the
runtime will use a default value if no values are provided by the user. For
vector fields, the TensorRT-LLM runtime supports one value per sequence (i.e.
the vector contains batchSize
values). If all the sequences use the same
value for a given parameter, the vector can be limited to a single element
(i.e. size() == 1
).
General
temperature
, a vector of floating-point numbers to control the modulation of logits when sampling new tokens. The default value is1.0f
,minLength
, a vector of integers to set a lower-bound on the number of tokens generated. The default value is 0,repetitionPenalty
, a vector of float-point numbers to penalize tokens based on how often they appear in the sequence. The default value is0.f
,presencePenalty
, a vector of float-point numbers to penalize tokens already present in the sequence (irrespective of the number of appearances). The default value is0.f
,frequencyPenalty
, a vector of float-point numbers to penalize tokens already present in the sequence (dependent on the number of appearances). The default value is0.f
,
The parameters repetitionPenalty
, presencePenalty
, and frequencyPenalty
are not mutually
exclusive.
Sampling
randomSeed
, a vector of 64-bit integers to control the random seed used by the random number generator in sampling. Its default value is 0,topK
, a vector of integers to control the number of logits to sample from. Its default value is 0. Note that if different values are provided for the different sequences in the batch, the performance of the implementation will depend on the largest value. For efficiency reasons, we recommend to batch requests with similartopK
values together,topP
, a vector of floating-point values to control the top-P probability to sample from. Its default value is0.f
,topPDecay
,topPMin
andtopPResetIds
, vectors to control the decay in the top-P algorithm. The top-P values are modulated by a decay that exponentially depends on the length of the sequence as explained in Factuality Enhanced Language Models for Open-Ended Text Generation.topPDecay
is the decay,topPMin
is the lower-bound andtopPResetIds
indicates where to reset the decay. Defaults are1.f
,1.0e-6,f
and-1
,
If both topK
and topP
fields are set, the top-K method will be run for
sequences with a topK
value greater than 0.f
. In that case, the topP
value for that sequence also influences the result. If the topK
values for
some sequences are 0.f
, the top-P method will be used for those remaining
sequences. If both topK
and topP
are zero, greedy search is performed.
Beam-search
beamWidth
, is the width used for the beam search sampling algorithm. There is no explicit upper-bound on the beam width but increasing the beam width will likely increase the latency. Use 1 to disable beam-search,beamSearchDiversityRate
, a floating-point value that controls the diversity in beam-search. Its default value is0.f
,lengthPenalty
, a floating-point value that controls how to penalize the longer sequences in beam-search (the log-probability of a sequence will be penalized by a factor that depends on1.f / (length ^ lengthPenalty)
). The default is value0.f
. The parameterlengthPenalty
may be renamed tobeamSearchLengthPenalty
in a future release,
The beamWidth
parameter is a scalar value. It means that in this release of
TensorRT-LLM, it is not possible to specify a different width for each input
sequence. This limitation is likely to be removed in a future release.
The GptSession
class encapsulates two main components. The
TllmRuntime
is in charge of the
execution of the TensorRT engine. The
GptDecoder
does the generation of the tokens from the logits. The TllmRuntime
class is
an internal component and users are not expected to use that class directly.
The GptDecoder
can be used directly to implement very custom generation loop
and for use cases that cannot be satisfied by the implementation in
GptSession
.
In this release, in-flight batching is supported using separate decoders per
request. The biggest difference compared to using a single decoder is in how
the token generation from logits is managed. A batch is split into batchSize
individual requests and kernels are issued using separated CUDA streams.
This behavior may be revisited in a future release to maintain the structure
of the batch and improve efficiency.
- In the current release of TensorRT-LLM, the C++ and Python runtimes are two separate software components and the C++ runtime is being more actively developed (with features like in-flight batching). An objective, for a future release, could be to rebuild the Python runtime on top of the C++ one.