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LLaMA

This document shows how to build and run a LLaMA model in TensorRT-LLM on both single GPU, single node multi-GPU and multi-node multi-GPU.

Overview

The TensorRT-LLM LLaMA implementation can be found in tensorrt_llm/models/llama/model.py. The TensorRT-LLM LLaMA example code is located in examples/llama. There is one main file:

In addition, there are two shared files in the parent folder examples for inference and evaluation:

Support Matrix

  • FP16
  • FP8
  • INT8 & INT4 Weight-Only
  • SmoothQuant
  • Groupwise quantization (AWQ/GPTQ)
  • FP8 KV CACHE
  • INT8 KV CACHE (+ AWQ/per-channel weight-only)
  • Tensor Parallel
  • STRONGLY TYPED

Usage

The TensorRT-LLM LLaMA example code locates at examples/llama. It takes HF weights as input, and builds the corresponding TensorRT engines. The number of TensorRT engines depends on the number of GPUs used to run inference.

Build TensorRT engine(s)

Need to prepare the HF LLaMA checkpoint first by following the guides here https://huggingface.co/docs/transformers/main/en/model_doc/llama.

TensorRT-LLM LLaMA builds TensorRT engine(s) from HF checkpoint. If no checkpoint directory is specified, TensorRT-LLM will build engine(s) with dummy weights.

Normally trtllm-build only requires single GPU, but if you've already got all the GPUs needed while inferencing, you could enable parallelly building to make the engine building process faster by adding --workers argument. Please note that currently workers feature only supports single node.

--use_fused_mlp enables GEMM horizontal fusion in gated MLP layer, which reduces input traffic and potentially improves performance. For FP8 PTQ, the downside is slight reduction of accuracy because one of the quantization scaling factors are discarded (accuracy 0.45734 vs 0.45755 for LLaMA-v2 7B using ammo/examples/hf/instruct_eval/mmlu.py).

Here're some examples:

# Build a single-GPU float16 engine from HF weights.
# Try use_gemm_plugin to prevent accuracy issue.

# Build the LLaMA 7B model using a single GPU and FP16.
python convert_checkpoint.py --model_dir ./tmp/llama/7B/ \
                              --output_dir ./tllm_checkpoint_1gpu_fp16 \
                              --dtype float16

trtllm-build --checkpoint_dir ./tllm_checkpoint_1gpu_fp16 \
            --output_dir ./tmp/llama/7B/trt_engines/fp16/1-gpu \
            --gemm_plugin float16

# Build the LLaMA 7B model using a single GPU and BF16.
python convert_checkpoint.py --model_dir ./tmp/llama/7B/ \
                              --output_dir ./tllm_checkpoint_1gpu_bf16 \
                              --dtype bfloat16

trtllm-build --checkpoint_dir ./tllm_checkpoint_1gpu_bf16 \
            --output_dir ./tmp/llama/7B/trt_engines/bf16/1-gpu \
            --gpt_attention_plugin bfloat16 \
            --gemm_plugin bfloat16

# Build the LLaMA 7B model using a single GPU and apply INT8 weight-only quantization.
python convert_checkpoint.py --model_dir ./tmp/llama/7B/ \
                              --output_dir ./tllm_checkpoint_1gpu_fp16_wq \
                              --dtype float16 \
                              --use_weight_only \
                              --weight_only_precision int8

trtllm-build --checkpoint_dir ./tllm_checkpoint_1gpu_fp16_wq \
            --output_dir ./tmp/llama/7B/trt_engines/weight_only/1-gpu/ \
            --gemm_plugin float16

# Build LLaMA 7B using 2-way tensor parallelism.
python convert_checkpoint.py --model_dir ./tmp/llama/7B/ \
                            --output_dir ./tllm_checkpoint_2gpu_tp2 \
                            --dtype float16 \
                            --tp_size 2

trtllm-build --checkpoint_dir ./tllm_checkpoint_2gpu_tp2 \
            --output_dir ./tmp/llama/7B/trt_engines/fp16/2-gpu/ \
            --gemm_plugin float16

# Build LLaMA 7B using 2-way tensor parallelism and 2-way pipeline parallelism.
python convert_checkpoint.py --model_dir ./tmp/llama/7B/ \
                            --output_dir ./tllm_checkpoint_4gpu_tp2_pp2 \
                            --dtype float16 \
                            --tp_size 2 \
                            --pp_size 2
trtllm-build --checkpoint_dir ./tllm_checkpoint_4gpu_tp2_pp2 \
            --output_dir ./tmp/llama/7B/trt_engines/fp16/4-gpu/ \
            --gemm_plugin float16

# Build LLaMA 30B using 2-way tensor parallelism.
python convert_checkpoint.py --model_dir ./tmp/llama/30B/hf/ \
                            --output_dir ./tllm_checkpoint_2gpu_tp2 \
                            --dtype float16 \
                            --tp_size 2

trtllm-build --checkpoint_dir ./tllm_checkpoint_2gpu_tp2 \
            --output_dir ./tmp/llama/30B/trt_engines/fp16/2-gpu/ \
            --gemm_plugin float16 \

LLaMA v2 Updates

The LLaMA v2 models with 7B and 13B are compatible with the LLaMA v1 implementation. The above commands still work.

For LLaMA v2 70B, there is a restriction on tensor parallelism that the number of KV heads must be divisible by the number of GPUs. For example, since the 70B model has 8 KV heads, you can run it with 2, 4 or 8 GPUs (1 GPU as well for FP8).

# Build LLaMA 70B using 8-way tensor parallelism.
python convert_checkpoint.py --model_dir ./tmp/llama/70B/hf/ \
                            --output_dir ./tllm_checkpoint_8gpu_tp8 \
                            --dtype float16 \
                            --tp_size 8

trtllm-build --checkpoint_dir ./tllm_checkpoint_8gpu_tp8 \
            --output_dir ./tmp/llama/70B/trt_engines/fp16/8-gpu/ \
            --gemm_plugin float16

# Build LLaMA 70B using 4-way tensor parallelism and 2-way pipeline parallelism.
python convert_checkpoint.py --model_dir ./tmp/llama/70B/hf/ \
                            --output_dir ./tllm_checkpoint_8gpu_tp4_pp2 \
                            --dtype float16 \
                            --tp_size 4 \
                            --pp_size 2

trtllm-build --checkpoint_dir ./tllm_checkpoint_8gpu_tp4_pp2 \
            --output_dir ./tmp/llama/70B/trt_engines/fp16/8-gpu/ \
            --gemm_plugin float16

# Build LLaMA 70B TP=8 using Meta checkpoints directly.
python convert_checkpoint.py --meta_ckpt_dir ./tmp/llama/70B/ \
                            --output_dir ./tllm_checkpoint_8gpu_tp8 \
                            --dtype float16 \
                            --tp_size 8

trtllm-build --checkpoint_dir ./tllm_checkpoint_8gpu_tp8 \
            --output_dir ./tmp/llama/70B/trt_engines/fp16/8-gpu/ \
            --gemm_plugin float16 \

Same instructions can be applied to fine-tuned versions of the LLaMA v2 models (e.g. 7Bf or llama-2-7b-chat).

Using RoPE Scaling

RoPE scaling is supported through GPT Attention Plugin. You can add --rotary_scaling <type> <factor> during the build command to enable it.

  • The value of type can be either linear and dynamic.
  • The value of factor can be any value larger than 1.0.

The implementation is identical to Huggingface's. Please refer to https://huggingface.co/docs/transformers/model_doc/llama2#transformers.LlamaConfig.rope_scaling for more details.

Long context length

To use the model with Long context lengths, it is necessary to add --multi_block_mode in the build command to enable faster decoding in multihead attention.

A few LLaMA models are fine-tuned for long context length that TRT-LLM can support today. For example https://huggingface.co/Yukang/LongAlpaca-70B employs rotary scaling plus fine-tuning to support up to 32K context length. The following show the steps for running LongAlpaca-70B in TRT-LLM:

# Build 8-GPU engine with long context LLaMA model
python convert_checkpoint.py --meta_ckpt_dir ./tmp/LongAlpaca-70B/ \
                            --output_dir ./tllm_checkpoint_8gpu_tp8 \
                            --dtype float16 \
                            --tp_size 8 \
                            --vocab_size=32001 \
                            --rotary_scaling linear 8.0

trtllm-build --checkpoint_dir ./tllm_checkpoint_8gpu_tp8 \
            --output_dir ./tmp/llama/70B/trt_engines/fp16/8-gpu/ \
            --gemm_plugin float16 \
            --multi_block_mode

# Get the long text data from Gutenberg Project
wget https://www.gutenberg.org/cache/epub/64317/pg64317.txt

# Run with 8 GPUs
# Notice, `--max_input_length <n>` is a convenience option to limit the input length for the data.
# It should be set to the maximum context length the model supports. Here the limit is set to 32K.
mpirun -n 8 --allow-run-as-root \
    python ../run.py \
    --max_output_len 128 \
    --max_input_length 32768 \
    --input_file pg64317.txt \
    --engine_dir ./tmp/llama/70B/trt_engines/fp16/8-gpu/ \
    --tokenizer_dir ./tmp/LongAlpaca-70B/

Note that if engine is built with contiguous KV cache (i.e., without the flag --paged_kv_cache), you may need to reduce the max batch size (--max_batch_size) to fit the whole model and the KV cache in the GPU memory. The ballpark estimate for runtime memory consumption is given by

Total memory = (Model size + KV cache size + Activation memory) / Parallelism

where

  • The model size is the number of parameters * the size of data type.
  • The KV cache size is the total number of tokens * the size of KV cache data type * the number of layers * the KV hidden dimension
  • The activation memory is determined by TRT engine, which can be a few GBs regardless of the degree of parallelism used

For LLaMA v2 70B FP16 weights + FP8 KV cache, the model size is 70B parameters * 2 bytes = 140GB. The KV cache size is 32K tokens * 1 bytes * 80 layers * 2048 KV hidden dimension = 5GB per 32K tokens. We have 145GB spread across 8 GPUs. The end result is ~18GB per GPU plus some GBs of flat scratch/activation memory allocated by TRT engine and the TRT-LLM runtime.

Note that the KV hidden dimension is derived by the number of KV heads times hidden dimension of each head. LLaMA v2 70B has hidden dimension of 8192, and uses grouped-query attention where 8 key heads and 8 value heads are associated with 64 query heads. Each head has hidden dimension of 8192/64 = 128. So the hidden dimension for KV in total is 128 * 8 * 2 = 2048.

The total number of tokens is determined by beam width, batch size, and maximum sequence length.

INT8 KV cache

INT8 KV cache could be enabled to reduce memory footprint. It will bring more performance gains when batch size gets larger.

For INT8 KV cache, convert_checkpoint.py features a --int8_kv_cache option. Setting --int8_kv_cache will calibrate the model, and then export the scaling factors needed for INT8 KV cache inference.

Example:

python convert_checkpoint.py --model_dir ./llama-models/llama-7b-hf   \
                             --output_dir ./llama-models/llama-7b-hf/int8_kv_cache/ \
                             --dtype float16  \
                             --int8_kv_cache

convert_checkpoint.py add new options for the support of INT8 KV cache.

INT8 KV cache + per-channel weight-only quantization

INT8 KV cache could be combined with per-channel weight-only quantization, as follows:

Examples of INT8 weight-only quantization + INT8 KV cache

# Build model with both INT8 weight-only and INT8 KV cache enabled
python convert_checkpoint.py --model_dir ./llama-models/llama-7b-hf   \
                             --output_dir ./tllm_checkpoint_1gpu_int8_kv_wq \
                             --dtype float16  \
                             --int8_kv_cache \
                             --use_weight_only \
                             --weight_only_precision int8

trtllm-build --checkpoint_dir ./tllm_checkpoint_1gpu_int8_kv_wq \
            --output_dir ./tmp/llama/7B/trt_engines/int8_kv_cache_weight_only/1-gpu \
            --gemm_plugin float16 \
            --multi_block_mode

Test with ../summarize.py:

python ../summarize.py --test_trt_llm \
                       --hf_model_dir ./llama-models/llama-7b-hf \
                       --data_type fp16 \
                       --engine_dir ./tmp/llama/7B/trt_engines/int8_kv_cache_weight_only/1-gpu \
                       --test_hf

INT8 KV cache + AWQ

In addition, you can enable INT8 KV cache together with AWQ (per-group INT4 weight-only quantization)like the following command.

python ../quantization/quantize.py --model_dir /tmp/llama-7b-hf \
                                   --output_dir ./tllm_checkpoint_1gpu_awq_int8_kv_cache \
                                   --dtype float16 \
                                   --qformat int4_awq \
                                   --awq_block_size 128 \
                                   --kv_cache_dtype int8 \
                                   --calib_size 32

trtllm-build --checkpoint_dir ./tllm_checkpoint_1gpu_awq_int8_kv_cache \
            --output_dir ./tmp/llama/7B/trt_engines/int8_kv_cache_int4_AWQ/1-gpu/ \
            --gemm_plugin float16 \

Test with ../summarize.py:

python ../summarize.py --test_trt_llm \
                       --hf_model_dir /tmp/llama-7b-hf \
                       --data_type fp16 \
                       --engine_dir ./tmp/llama/7B/trt_engines/int8_kv_cache_int4_AWQ/1-gpu \
                       --test_hf

SmoothQuant

The smoothquant supports both LLaMA v1 and LLaMA v2. Unlike the FP16 build where the HF weights are processed and loaded into the TensorRT-LLM directly, the SmoothQuant needs to load INT8 weights which should be pre-processed before building an engine.

Example:

python3 convert_checkpoint.py --model_dir /llama-models/llama-7b-hf  --output_dir /tmp/tllm_checkpoint_1gpu_sq --dtype float16 --smoothquant 0.5
trtllm-build --checkpoint_dir /tmp/tllm_checkpoint_1gpu_sq \
             --output_dir ./engine_outputs \
             --gemm_plugin float16

convert_checkpoint.py add new options for the support of INT8 inference of SmoothQuant models.

--smoothquant is the starting point of INT8 inference. By default, it will run the model in the per-tensor mode.

Then, you can add any combination of --per-token and --per-channel to get the corresponding behaviors.

Examples of build invocations:

# Build model for SmoothQuant in the _per_token_ + _per_channel_ mode
python3 convert_checkpoint.py --model_dir /llama-models/llama-7b-hf \
                            --output_dir /tmp/tllm_checkpoint_1gpu_sq \
                            --dtype float16 \
                            --smoothquant 0.5 \
                            --per_token \
                            --per_channel

trtllm-build --checkpoint_dir /tmp/tllm_checkpoint_1gpu_sq \
             --output_dir ./engine_outputs \
             --gemm_plugin float16

FP8 Post-Training Quantization

The examples below uses the NVIDIA AMMO (AlgorithMic Model Optimization) toolkit for the model quantization process.

First make sure AMMO toolkit is installed (see examples/quantization/README.md)

# Quantize HF LLaMA 70B into FP8 and export trtllm checkpoint
python ../quantization/quantize.py --model_dir ./tmp/llama/70B \
                                   --dtype float16 \
                                   --qformat fp8 \
                                   --kv_cache_dtype fp8 \
                                   --output_dir ./tllm_checkpoint_2gpu_fp8 \
                                   --calib_size 512 \
                                   --tp_size 2

# Build trtllm engines from the trtllm checkpoint
trtllm-build --checkpoint_dir ./tllm_checkpoint_2gpu_fp8 \
             --output_dir ./engine_outputs \
             --gemm_plugin float16 \
             --strongly_typed \
             --workers 2

Groupwise quantization (AWQ/GPTQ)

One can enable AWQ/GPTQ INT4 weight only quantization with these options when building engine with trtllm-build:

  • --use_weight_only enables weight only GEMMs in the network.
  • --per_group enable groupwise weight only quantization, for GPT-J example, we support AWQ with the group size default as 128.
  • --weight_only_precision should specify the weight only quantization format. Supported formats are int4_awq or int4_gptq.
  • --ammo_quant_ckpt_path passes the quantized checkpoint to build the engine.

AWQ/GPTQ examples below involves 2 steps:

  1. Weight quantization
  2. Build TRT-LLM engine
AWQ
  1. Weight quantization:

    NVIDIA AMMO toolkit is used for AWQ weight quantization. Please see examples/quantization/README.md for AMMO installation instructions.

    # Quantize HF LLaMA 7B checkpoint into INT4 AWQ format
    python ../quantization/quantize.py --model_dir ./tmp/llama-7b-hf \
                                       --dtype float16 \
                                       --qformat int4_awq \
                                       --awq_block_size 128 \
                                       --output_dir ./quantized_int4-awq \
                                       --calib_size 32
  2. Build TRT-LLM engine:

    trtllm-build --checkpoint_dir ./quantized_int4-awq \
                 --output_dir ./tmp/llama/7B/trt_engines/int4_AWQ/1-gpu/ \
                 --gemm_plugin float16
GPTQ

To run the GPTQ LLaMa example, the following steps are required:

  1. Weight quantization:

    Quantized weights for GPTQ are generated using GPTQ-for-LLaMa as follow:

    git clone https://github.com/qwopqwop200/GPTQ-for-LLaMa.git
    cd GPTQ-for-LLaMa
    pip install -r requirements.txt
    
    # Quantize weights into INT4 and save as safetensors
    # Quantized weight with parameter "--act-order" is not supported in TRT-LLM
    python llama.py ./tmp/llama/7B/ c4 --wbits 4 --true-sequential --groupsize 128 --save_safetensors ./llama-7b-4bit-gs128.safetensors

    Let us build the TRT-LLM engine with the saved ./llama-7b-4bit-gs128.safetensors.

  2. Build TRT-LLM engine:

    # Build the LLaMA 7B model using 2-way tensor parallelism and apply INT4 GPTQ quantization.
    # Compressed checkpoint safetensors are generated separately from GPTQ.
    python convert_checkpoint.py --model_dir /tmp/llama-7b-hf \
                                 --output_dir ./tllm_checkpoint_2gpu_gptq \
                                 --dtype float16 \
                                 --ammo_quant_ckpt_path ./llama-7b-4bit-gs128.safetensors  \
                                 --use_weight_only \
                                 --weight_only_precision int4_gptq \
                                 --per_group \
                                 --tp_size 2
    
    trtllm-build --checkpoint_dir ./tllm_checkpoint_2gpu_gptq \
                --output_dir ./tmp/llama/7B/trt_engines/int4_GPTQ/2-gpu/ \
                --gemm_plugin float16

Run

To run a TensorRT-LLM LLaMA model using the engines generated by trtllm-build

# With fp16 inference
python3 ../run.py --max_output_len=50 \
                  --tokenizer_dir ./tmp/llama/7B/ \
                  --engine_dir=./tmp/llama/7B/trt_engines/fp16/1-gpu/

# With bf16 inference
python3 ../run.py --max_output_len=50 \
                  --tokenizer_dir ./tmp/llama/7B/ \
                  --engine_dir=./tmp/llama/7B/trt_engines/bf16/1-gpu/

Summarization using the LLaMA model

# Run summarization using the LLaMA 7B model in FP16.
python ../summarize.py --test_trt_llm \
                       --hf_model_dir ./tmp/llama/7B/ \
                       --data_type fp16 \
                       --engine_dir ./tmp/llama/7B/trt_engines/fp16/1-gpu/

# Run summarization using the LLaMA 7B model quantized to INT8.
python ../summarize.py --test_trt_llm \
                       --hf_model_dir ./tmp/llama/7B/ \
                       --data_type fp16 \
                       --engine_dir ./tmp/llama/7B/trt_engines/weight_only/1-gpu/

# Run summarization using the LLaMA 7B model in FP16 using two GPUs.
mpirun -n 2 --allow-run-as-root \
    python ../summarize.py --test_trt_llm \
                           --hf_model_dir ./tmp/llama/7B/ \
                           --data_type fp16 \
                           --engine_dir ./tmp/llama/7B/trt_engines/fp16/2-gpu/

# Run summarization using the LLaMA 30B model in FP16 using two GPUs.
mpirun -n 2 --allow-run-as-root \
    python ../summarize.py --test_trt_llm \
                           --hf_model_dir ./tmp/llama/30B/ \
                           --data_type fp16 \
                           --engine_dir ./tmp/llama/30B/trt_engines/fp16/2-gpu/

Mistral v0.1

Mistral v0.1 is compatible with LLaMA interface and can be built and run using the same instructions. Setting --max_input_len, corresponding to the max_position_embeddings in the original Mistral config explicitly regulates context size. The --max_attention_window_size parameter is set to the sliding_window value in the config and regulates both sliding window attention in the context phase and rolling buffer cache in the generation phase.

# Build Mistral 7B with max input length 32256
python convert_checkpoint.py --model_dir ./mistral-7b-v0.1 \
                             --output_dir ./tllm_checkpoint_1gpu_mistral \
                             --dtype float16
trtllm-build --checkpoint_dir ./tllm_checkpoint_2gpu_gptq \
            --output_dir ./tmp/mistral/7B/trt_engines/fp16/1-gpu/ \
            --gemm_plugin float16 \
            --max_input_len 32256

# Run Mistral 7B fp16 inference with sliding window/cache size 4096
python3 run.py --max_output_len=50 \
               --tokenizer_dir ./tmp/llama/7B/ \
               --engine_dir=./tmp/llama/7B/trt_engines/fp16/1-gpu/ \
               --max_attention_window_size=4096

Note that if you are comparing TRT-LLM with Huggingface, you should install transformers with version >= 4.34.1 in order to have Mistral model supported. And upgrade flash-attn package by pip install --upgrade flash-attn or you may see wrong results generated by the huggingface implementation.

Running CodeLlama

Those examples can be used to build and run the CodeLlama models. All 7b, 13b, and 34b sizes and variants are supported.

There are a couple of differences in CodeLlama in comparison to LLaMA v1/v2 models: rotary_base (theta=1000000.0f) and vocabulary size (32016 (1)).

(1): Only applicable to 7b and 13b model sizes. 34b model variants use 32000.

Build

Use the following command to build CodeLlama-7b-Instruct:

python convert_checkpoint.py --model_dir /tmp/CodeLlama-7b-Instruct-hf  \
                             --output_dir ./tllm_checkpoint_1gpu_codellama \
                             --dtype float16 \
                             --rotary_base 1000000 \
                             --vocab_size 32016

trtllm-build --checkpoint_dir ./tllm_checkpoint_1gpu_codellama \
            --output_dir ./tmp/codellama/trt_engines/fp16/1-gpu/ \
            --gemm_plugin float16 \

Use the following command to build CodeLlama-34b-Instruct for 4 GPUs (TP=4):

python convert_checkpoint.py --model_dir /tmp/CodeLlama-34b-Instruct-hf  \
                             --output_dir ./tllm_checkpoint_4gpu_codellama \
                             --dtype float16 \
                             --rotary_base 1000000 \
                             --vocab_size 32000 \
                             --tp_size 4

trtllm-build --checkpoint_dir ./tllm_checkpoint_4gpu_codellama \
            --output_dir ./tmp/codellama/trt_engines/fp16/4-gpu/ \
            --gemm_plugin float16 \

NOTE: CodeLlama uses the max_position_embeddings of 16K. To build the engine for running similarly long input/output, you need to specify that during build.

Use --max_input_len and --max_output_len (which defaults to 2048 and 512, respectively) according to your use case, e.g.:

python convert_checkpoint.py --model_dir /tmp/CodeLlama-34b-Instruct-hf  \
                             --output_dir ./tllm_checkpoint_4gpu_codellama \
                             --dtype float16 \
                             --rotary_base 1000000 \
                             --vocab_size 32000 \
                             --tp_size 8 \
                             --use_parallel_embedding

trtllm-build --checkpoint_dir ./tllm_checkpoint_4gpu_codellama \
            --output_dir ./tmp/codellama/trt_engines/fp16/4-gpu/ \
            --gemm_plugin float16 \
            --max_input_len 15360 \
            --max_output_len 1024 \
            --max_batch_size 4

Run

Use the following command to run the 7b engine from above:

python ../run.py --max_output_len=40 --tokenizer_dir . --engine_dir codellama_7b --input_text "In Bash, how do I list all text files?"

Use the following command to run the 34b engine with long input/output from above:

mpirun -n 8 --allow-run-as-root \
    python ../run.py --max_output_len=160 --tokenizer_dir ./CodeLlama-34b-Instruct \
    --engine_dir codellama_34b --input_text "In python, write a function for binary searching an element in an integer array."

Run LLaMa with LoRA

  • download the base model and lora model from HF
git-lfs clone https://huggingface.co/meta-llama/Llama-2-13b-hf
git-lfs clone https://huggingface.co/hfl/chinese-llama-2-lora-13b
  • Build engine, setting --use_lora_plugin and --hf_lora_dir. If lora has separate lm_head and embedding, they will replace lm_head and embedding of base model.
python convert_checkpoint.py --model_dir /tmp/llama-v2-13b-hf \
                         --output_dir ./tllm_checkpoint_2gpu_lora \
                         --dtype float16 \
                         --tp_size 2 \
                         --hf_lora_dir /tmp/chinese-llama-2-lora-13b \
                         --use_fused_mlp

trtllm-build --checkpoint_dir ./tllm_checkpoint_2gpu_lora \
            --output_dir /tmp/new_lora_13b/trt_engines/fp16/2-gpu/ \
            --gemm_plugin float16 \
            --lora_plugin float16 \
            --max_batch_size 1 \
            --max_input_len 512 \
            --max_output_len 50
  • Run inference. Need to setup the lora_dir. Remember to use lora tokenizer because lora model has larger vocab size.
mpirun -n 2 python ../run.py --engine_dir "/tmp/new_lora_13b/trt_engines/fp16/2-gpu/" \
              --max_output_len 50 \
              --tokenizer_dir "chinese-llama-2-lora-13b/" \
              --input_text "今天天气很好,我到公园的时后," \
              --lora_dir "chinese-llama-2-lora-13b/" \
              --lora_task_uids 0 \
              --no_add_special_tokens \
              --use_py_session

 Input: "今天天气很好,我到公园的时后,"
Output: "发现公园里人很多,有的在打羽毛球,有的在打乒乓球,有的在跳绳,还有的在跑步。我和妈妈来到一个空地上,我和妈妈一起跳绳,我跳了1"

Users who want to skip LoRA module may pass uid -1 with --lora_task_uids -1. In that case, the model will not run the LoRA module and the results will be different.

mpirun -n 2 python ../run.py --engine_dir "/tmp/new_lora_13b/trt_engines/fp16/2-gpu/" \
              --max_output_len 50 \
              --tokenizer_dir "chinese-llama-2-lora-13b/" \
              --input_text "今天天气很好,我到公园的时后," \
              --lora_dir "chinese-llama-2-lora-13b/" \
              --lora_task_uids -1 \
              --no_add_special_tokens \
              --use_py_session

 Input: "今天天气很好,我到公园的时后,"
Output: "我看见一个人坐在那边边看书书,我看起来还挺像你,可是我走过过去问了一下他说你是你吗,他说没有,然后我就说你看我看看你像你,他说说你看我像你,我说你是你,他说你是你,"

Run LLaMa with several lora checkpoints

In this section, we show how to run a model with multiple LoRA modules at the same time. Note that if one of the LoRA module has a fine-tuned embedding table or logit GEMM, users should guarantee that all the instances of the model can use the same finetuned embedding table or logit GEMM. Here, we use two LoRA checkpoints as examples. These two LoRA checkponits add LoRA modules to q_proj and v_proj. Because we only support adding lora modules on q, k and v at the same time, we need to add --lora_target_modules "attn_q" "attn_k" "attn_v". In this case, we assign null pointers for the k LoRA module in TensorRT-LLM and skip the computation at runtime.

As the rank of the LoRA modules of both checkpoints is 8, we can set --max_lora_rank 8 to reduce the memory requirement for the LoRA plugin.

In this example, we use a LoRA checkpoint finetuned on the Chinese dataset luotuo-lora-7b-0.1 and a LoRA checkpoint finetuned on the Japanese dataset Japanese-Alpaca-LoRA-7b-v0. For the lora_manager to load several checkpoints, we pass several directories of LoRA checkpoints at the same time: --lora_dir "luotuo-lora-7b-0.1/" "Japanese-Alpaca-LoRA-7b-v0/". Then, lora_manager will assign lora_task_uids to these checkpoints. lora_task_uids -1 is a predefined value, which corresponds to the base model. If we pass lora_task_uids 0 1, this means we want to use the first LoRA checkpoint on first sentence and use the second LoRA checkpoint on the second sentence.

To verify the correctness, we pass the same Chinese input 美国的首都在哪里? \n答案: three times as well as the same Japanese input アメリカ合衆国の首都はどこですか? \n答え: three times (both inputs mean Where is the capital of America? \nAnswer). We run on base model, luotuo-lora-7b-0.1 and Japanese-Alpaca-LoRA-7b-v0/.

git-lfs clone https://huggingface.co/qychen/luotuo-lora-7b-0.1
git-lfs clone https://huggingface.co/kunishou/Japanese-Alpaca-LoRA-7b-v0
BASE_LLAMA_MODEL=llama-7b-hf/

python convert_checkpoint.py --model_dir ${BASE_LLAMA_MODEL} \
                            --output_dir ./tllm_checkpoint_1gpu_lora_rank \
                            --dtype float16 \
                            --hf_lora_dir /tmp/Japanese-Alpaca-LoRA-7b-v0 \
                            --max_lora_rank 8 \
                            --lora_target_modules "attn_q" "attn_k" "attn_v"
trtllm-build --checkpoint_dir ./tllm_checkpoint_1gpu_lora_rank \
            --output_dir /tmp/llama_7b_with_lora_qkv/trt_engines/fp16/1-gpu/ \
            --gemm_plugin float16 \
            --lora_plugin float16 \
            --max_batch_size 1 \
            --max_input_len 512 \
            --max_output_len 50

python ../run.py --engine_dir "/tmp/llama_7b_with_lora_qkv/trt_engines/fp16/1-gpu/" \
              --max_output_len 10 \
              --tokenizer_dir ${BASE_LLAMA_MODEL} \
              --input_text "美国的首都在哪里? \n答案:" "美国的首都在哪里? \n答案:" "美国的首都在哪里? \n答案:" "アメリカ合衆国の首都はどこですか? \n答え:" "アメリカ合衆国の首都はどこですか? \n答え:" "アメリカ合衆国の首都はどこですか? \n答え:" \
              --lora_dir  "luotuo-lora-7b-0.1/" "Japanese-Alpaca-LoRA-7b-v0/" \
              --lora_task_uids -1 0 1 -1 0 1 \
              --use_py_session --top_p 0.5 --top_k 0

The results would be like

Input [Text 0]: "<s> 美国的首都在哪里? \n答案:"
Output [Text 0 Beam 0]: "Washington, D.C.
What is the"

Input [Text 1]: "<s> 美国的首都在哪里? \n答案:"
Output [Text 1 Beam 0]: "华盛顿。
"

Input [Text 2]: "<s> 美国的首都在哪里? \n答案:"
Output [Text 2 Beam 0]: "Washington D.C.�����"

Input [Text 3]: "<s> アメリカ合衆国の首都はどこですか? \n答え:"
Output [Text 3 Beam 0]: "Washington, D.C.
Which of"

Input [Text 4]: "<s> アメリカ合衆国の首都はどこですか? \n答え:"
Output [Text 4 Beam 0]: "华盛顿。
"

Input [Text 5]: "<s> アメリカ合衆国の首都はどこですか? \n答え:"
Output [Text 5 Beam 0]: "ワシントン D.C."

We can observe that luotuo-lora-7b-0.1 produces correct answers on the first sentence and the fifth sentence (in Chinese), Japanese-Alpaca-LoRA-7b-v0 produces correct answers on the sixth sentence (in Japanese).

Run LLaMa with StreamingLLM

  • Build engine. Set --enable_pos_shift to use positions in KV cache for RoPE, and set --dense_context_fmha to use dense context fmha in context phase.
# Build the LLaMA 7B model with StreamingLLM feature using a single GPU and FP16.
python convert_checkpoint.py --model_dir ./tmp/llama/7B/ \
                         --output_dir ./tllm_checkpoint_1gpu_streamlingllm \
                         --dtype float16 \
                         --dense_context_fmha \
                         --enable_pos_shift

trtllm-build --checkpoint_dir ./tllm_checkpoint_1gpu_streamlingllm \
            --output_dir ./tmp/llama/7B/trt_engines/fp16_StreamingLLM/1-gpu/ \
            --gemm_plugin float16
  • Run inference. Use --sink_token_length to set the number of sink tokens, and use --max_attention_window_size to set the sliding_window value.
# Run LLaMA 7B fp16 inference with sliding window/cache size 2048 and sink token length 4.
python3 ../run.py --max_output_len=50 \
                  --tokenizer_dir ./tmp/llama/7B/ \
                  --engine_dir=./tmp/llama/7B/trt_engines/fp16_StreamingLLM/1-gpu/ \
                  --max_attention_window_size=2048 \
                  --sink_token_length=4

Note that the sink tokens is included in the sliding attention tokens, and there are at most max_attention_window_size tokens are stored in the KV cache.