llama.py

import time

import torch
import torch.nn as nn

from gptq import *
from modelutils import *
from quant import *


def get_llama(model):
    import torch
    def skip(*args, **kwargs):
        pass
    torch.nn.init.kaiming_uniform_ = skip
    torch.nn.init.uniform_ = skip
    torch.nn.init.normal_ = skip
    from transformers import LLaMAForCausalLM
    model = LLaMAForCausalLM.from_pretrained(model, torch_dtype='auto')
    model.seqlen = 2048
    return model

@torch.no_grad()
def llama_sequential(model, dataloader, dev):
    print('Starting ...')

    use_cache = model.config.use_cache
    model.config.use_cache = False
    layers = model.model.layers

    model.model.embed_tokens = model.model.embed_tokens.to(dev)
    model.model.norm = model.model.norm.to(dev)
    layers[0] = layers[0].to(dev)

    dtype = next(iter(model.parameters())).dtype
    inps = torch.zeros(
        (args.nsamples, model.seqlen, model.config.hidden_size), dtype=dtype, device=dev
    )
    cache = {'i': 0, 'attention_mask': None}

    class Catcher(nn.Module):
        def __init__(self, module):
            super().__init__()
            self.module = module
        def forward(self, inp, **kwargs):
            inps[cache['i']] = inp
            cache['i'] += 1
            cache['attention_mask'] = kwargs['attention_mask']
            raise ValueError
    layers[0] = Catcher(layers[0])
    for batch in dataloader:
        try:
            model(batch[0].to(dev))
        except ValueError:
            pass
    layers[0] = layers[0].module

    layers[0] = layers[0].cpu()
    model.model.embed_tokens = model.model.embed_tokens.cpu()
    model.model.norm = model.model.norm.cpu()
    torch.cuda.empty_cache()

    outs = torch.zeros_like(inps)
    attention_mask = cache['attention_mask']

    print('Ready.')

    quantizers = {}
    for i in range(len(layers)):
        layer = layers[i].to(dev)
        subset = find_layers(layer)
        gptq = {}
        for name in subset:
            gptq[name] = GPTQ(subset[name])
            gptq[name].quantizer = Quantizer()
            gptq[name].quantizer.configure(
                args.wbits, perchannel=True, sym=False, mse=False
            )

        def add_batch(name):
            def tmp(_, inp, out):
                gptq[name].add_batch(inp[0].data, out.data)
            return tmp
        handles = []
        for name in subset:
            handles.append(subset[name].register_forward_hook(add_batch(name)))
        for j in range(args.nsamples):
            outs[j] = layer(inps[j].unsqueeze(0), attention_mask=attention_mask)[0]
        for h in handles:
            h.remove()

        for name in subset:
            print(i, name)
            print('Quantizing ...')
            gptq[name].fasterquant(percdamp=args.percdamp, groupsize=args.groupsize)
            quantizers['model.layers.%d.%s' % (i, name)] = gptq[name].quantizer
            gptq[name].free()
        for j in range(args.nsamples):
            outs[j] = layer(inps[j].unsqueeze(0), attention_mask=attention_mask)[0]

        layers[i] = layer.cpu()
        del layer
        del gptq 
        torch.cuda.empty_cache()

        inps, outs = outs, inps

    model.config.use_cache = use_cache
    
    return quantizers

@torch.no_grad()
def llama_eval(model, testenc, dev):
    print('Evaluating ...')

    testenc = testenc.input_ids
    nsamples = testenc.numel() // model.seqlen

    use_cache = model.config.use_cache
    model.config.use_cache = False
    layers = model.model.layers

    model.model.embed_tokens = model.model.embed_tokens.to(dev)
    layers[0] = layers[0].to(dev)

    dtype = next(iter(model.parameters())).dtype
    inps = torch.zeros(
        (nsamples, model.seqlen, model.config.hidden_size), dtype=dtype, device=dev
    )
    cache = {'i': 0, 'attention_mask': None}

    class Catcher(nn.Module):
        def __init__(self, module):
            super().__init__()
            self.module = module
        def forward(self, inp, **kwargs):
            inps[cache['i']] = inp
            cache['i'] += 1
            cache['attention_mask'] = kwargs['attention_mask']
            raise ValueError
    layers[0] = Catcher(layers[0])
    for i in range(nsamples):
        batch = testenc[:, (i * model.seqlen):((i + 1) * model.seqlen)].to(dev)
        try:
            model(batch)
        except ValueError:
            pass
    layers[0] = layers[0].module

    layers[0] = layers[0].cpu()
    model.model.embed_tokens = model.model.embed_tokens.cpu()
    torch.cuda.empty_cache()

    outs = torch.zeros_like(inps)
    attention_mask = cache['attention_mask']

    for i in range(len(layers)):
        print(i)
        layer = layers[i].to(dev)
        
        if args.nearest:
            subset = find_layers(layer)
            for name in subset:
                quantizer = Quantizer()
                quantizer.configure(
                    args.wbits, perchannel=True, sym=False, mse=False
                )
                W = subset[name].weight.data
                quantizer.find_params(W, weight=True)
                subset[name].weight.data = quantize(
                    W, quantizer.scale, quantizer.zero, quantizer.maxq
                ).to(next(iter(layer.parameters())).dtype)

        for j in range(nsamples):
            outs[j] = layer(inps[j].unsqueeze(0), attention_mask=attention_mask)[0]
        layers[i] = layer.cpu()
        del layer
        torch.cuda.empty_cache()
        inps, outs = outs, inps

    if model.model.norm is not None:
        model.model.norm = model.model.norm.to(dev)
    model.lm_head = model.lm_head.to(dev)

    testenc = testenc.to(dev)
    nlls = []
    for i in range(nsamples):
        hidden_states = inps[i].unsqueeze(0)
        if model.model.norm is not None:
            hidden_states = model.model.norm(hidden_states)
        lm_logits = model.lm_head(hidden_states)
        shift_logits = lm_logits[:, :-1, :].contiguous()
        shift_labels = testenc[
            :, (i * model.seqlen):((i + 1) * model.seqlen)
        ][:, 1:]
        loss_fct = nn.CrossEntropyLoss()
        loss = loss_fct(shift_logits.view(-1, shift_logits.size(-1)), shift_labels.view(-1))
        neg_log_likelihood = loss.float() * model.seqlen
        nlls.append(neg_log_likelihood)
    ppl = torch.exp(torch.stack(nlls).sum() / (nsamples * model.seqlen))
    print(ppl.item())

    model.config.use_cache = use_cache

# TODO: perform packing on GPU
def llama_pack(model, quantizers, wbits):
    layers = find_layers(model)
    layers = {n: layers[n] for n in quantizers}
    make_quant(model, quantizers, wbits)
    qlayers = find_layers(model, [QuantLinear])
    print('Packing ...')
    for name in qlayers:
        print(name)
        quantizers[name] = quantizers[name].cpu()
        qlayers[name].pack(layers[name], quantizers[name].scale, quantizers[name].zero)
    print('Done.')
    return model

def load_quant(model, checkpoint, wbits):
    from transformers import LLaMAConfig, LLaMAForCausalLM 
    config = LLaMAConfig.from_pretrained(model)
    def noop(*args, **kwargs):
        pass
    torch.nn.init.kaiming_uniform_ = noop 
    torch.nn.init.uniform_ = noop 
    torch.nn.init.normal_ = noop 

    torch.set_default_dtype(torch.half)
    transformers.modeling_utils._init_weights = False
    torch.set_default_dtype(torch.half)
    model = LLaMAForCausalLM(config)
    torch.set_default_dtype(torch.float)
    model = model.eval()
    layers = find_layers(model)
    for name in ['lm_head']:
        if name in layers:
            del layers[name]
    make_quant(model, layers, wbits)

    print('Loading model ...')
    if checkpoint.endswith('.safetensors'):
        from safetensors.torch import load_file as safe_load
        model.load_state_dict(safe_load(checkpoint))
    else:
        model.load_state_dict(torch.load(checkpoint))
    model.seqlen = 2048
    print('Done.')

    return model

def llama_multigpu(model, gpus):
    model.model.embed_tokens = model.model.embed_tokens.to(gpus[0])
    if hasattr(model.model, 'norm') and model.model.norm:
        model.model.norm = model.model.norm.to(gpus[-1])
    import copy
    model.lm_head = copy.deepcopy(model.lm_head).to(gpus[-1])

    cache = {'mask': None}

    class MoveModule(nn.Module):
        def __init__(self, module):
            super().__init__()
            self.module = module
            self.dev = next(iter(self.module.parameters())).device
        def forward(self, *inp, **kwargs):
            inp = list(inp)
            if inp[0].device != self.dev:
                inp[0] = inp[0].to(self.dev)
            if cache['mask'] is None or cache['mask'].device != self.dev:
                cache['mask'] = kwargs['attention_mask'].to(self.dev)
            kwargs['attention_mask'] = cache['mask']
            tmp = self.module(*inp, **kwargs)
            return tmp

    layers = model.model.layers
    pergpu = math.ceil(len(layers) / len(gpus))
    for i in range(len(layers)):
        layers[i] = MoveModule(layers[i].to(gpus[i // pergpu]))

    model.gpus = gpus

def benchmark(model, input_ids, check=False):
    input_ids = input_ids.to(model.gpus[0] if hasattr(model, 'gpus') else DEV)
    torch.cuda.synchronize()

    cache = {'past': None}
    def clear_past(i):
        def tmp(layer, inp, out):
            if cache['past']:
                cache['past'][i] = None
        return tmp
    for i, layer in enumerate(model.model.layers):
        layer.register_forward_hook(clear_past(i))

    print('Benchmarking ...')

    if check:
        loss = nn.CrossEntropyLoss()
        tot = 0.

    def sync():
        if hasattr(model, 'gpus'):
            for gpu in model.gpus:
                torch.cuda.synchronize(gpu)
        else:
            torch.cuda.synchronize()
    max_memory = 0
    with torch.no_grad():
        attention_mask = torch.ones((1, input_ids.numel()), device=DEV)
        times = []
        for i in range(input_ids.numel()):
            tick = time.time()
            out = model(
                input_ids[:, i].reshape(-1),
                past_key_values=cache['past'],
                attention_mask=attention_mask[:, :(i + 1)].reshape((1, -1))
            )
            sync()
            times.append(time.time() - tick)
            print(i, times[-1])
            max_memory = max(max_memory,torch.cuda.memory_allocated() / 1024 /1024)
            if check and i != input_ids.numel() - 1:
                tot += loss(out.logits[0].to(DEV), input_ids[:, (i + 1)].to(DEV)).float()
            cache['past'] = list(out.past_key_values)
            del out
        sync()
        import numpy as np
        print('Median:', np.median(times))
        if check:
            print('PPL:', torch.exp(tot / (input_ids.numel() - 1)).item())
            print('max memory(MiB):',max_memory)


if __name__ == '__main__':
    import argparse
    from datautils import *

    parser = argparse.ArgumentParser()

    parser.add_argument(
        'model', type=str,
        help='llama model to load'
    )
    parser.add_argument(
        'dataset', type=str, choices=['wikitext2', 'ptb', 'c4'],
        help='Where to extract calibration data from.'
    )
    parser.add_argument(
        '--seed',
        type=int, default=0, help='Seed for sampling the calibration data.'
    )
    parser.add_argument(
        '--nsamples', type=int, default=128,
        help='Number of calibration data samples.'
    )
    parser.add_argument(
        '--percdamp', type=float, default=.01,
        help='Percent of the average Hessian diagonal to use for dampening.'
    )
    parser.add_argument(
        '--nearest', action='store_true',
        help='Whether to run the RTN baseline.'
    ) 
    parser.add_argument(
        '--wbits', type=int, default=16, choices=[2, 3, 4, 8, 16],
        help='#bits to use for quantization; use 16 for evaluating base model.'
    )
    parser.add_argument(
        '--groupsize', type=int, default=-1,
        help='Groupsize to use for quantization; default uses full row.'
    )
    parser.add_argument(
        '--save', type=str, default='',
        help='Save quantized checkpoint under this name.'
    )
    parser.add_argument(
        '--save_safetensors', type=str, default='',
        help='Save quantized `.safetensors` checkpoint under this name.'
    )
    parser.add_argument(
        '--load', type=str, default='',
        help='Load quantized model.'
    )
    parser.add_argument(
        '--benchmark', type=int, default=0,
        help='Number of tokens to use for benchmarking.'
    )
    parser.add_argument(
        '--check', action='store_true',
        help='Whether to compute perplexity during benchmarking for verification.'
    )

    args = parser.parse_args()

    if type(args.load) is not str:
        args.load = args.load.as_posix()
    
    if args.load:
        model = load_quant(args.model, args.load, args.wbits)
    else:
        model = get_llama(args.model)
        model.eval()

    dataloader, testloader = get_loaders(
        args.dataset, nsamples=args.nsamples, seed=args.seed, model=args.model, seqlen=model.seqlen
    )

    if not args.load and args.wbits < 16 and not args.nearest:
        tick = time.time()
        quantizers = llama_sequential(model, dataloader, DEV)
        print(time.time() - tick)

    if args.benchmark:
        gpus = [torch.device('cuda:%d' % i) for i in range(torch.cuda.device_count())]
        if len(gpus) > 1:
            llama_multigpu(model, gpus)
        else:
            model = model.to(DEV)
        if args.benchmark:
            input_ids = next(iter(dataloader))[0][:, :args.benchmark]
            benchmark(model, input_ids, check=args.check)
    if args.load:
        exit()

    for dataset in ['wikitext2', 'ptb', 'c4']:
        dataloader, testloader = get_loaders(
            dataset, seed=args.seed, model=args.model, seqlen=model.seqlen
        )
        print(dataset)
        llama_eval(model, testloader, DEV)

    if args.save:
        llama_pack(model, quantizers, args.wbits)
        torch.save(model.state_dict(), args.save) 

    if args.save_safetensors:
        llama_pack(model, quantizers, args.wbits)
        from safetensors.torch import save_file as safe_save
        safe_save(model.state_dict(), args.save_safetensors)