Add sparse transformer v19 with Triton-backed KNN scheduler and various backward modes. Includes utilities for synthetic data generation and model training. Implements chunked sparse updates and integrates with existing sparse linear layers.
bc1b8eb | #!/usr/bin/env python3 | |
| """End-to-end training benchmark: Dense vs PyLoop vs Triton sparse backward.""" | |
| import math, os, time, urllib.request | |
| import torch, torch.nn as nn, torch.nn.functional as F | |
| import tiktoken | |
| # Import our Triton kernels from the module | |
| from triton_sparse import ( | |
| TritonChunkedSparseLinear, PythonLoopSparseLinear, | |
| sparse_bwd_dW, sparse_bwd_dX, sparse_bwd_dbias | |
| ) | |
| device = 'cuda' | |
| BS, BLK = 8, 256 | |
| # Data | |
| if not os.path.exists('input.txt'): | |
| urllib.request.urlretrieve('https://raw.githubusercontent.com/karpathy/char-rnn/master/data/tinyshakespeare/input.txt', 'input.txt') | |
| enc = tiktoken.get_encoding('gpt2') | |
| tokens = torch.tensor(enc.encode(open('input.txt').read()), dtype=torch.long) | |
| train_data = tokens[:int(0.9*len(tokens))] | |
| val_data = tokens[int(0.9*len(tokens)):] | |
| V = enc.n_vocab | |
| def get_batch(data, gen=None): | |
| ix = torch.randint(len(data)-BLK-1, (BS,), generator=gen) | |
| return (torch.stack([data[i:i+BLK] for i in ix]).to(device), | |
| torch.stack([data[i+1:i+BLK+1] for i in ix]).to(device)) | |
| # Model | |
| class SparseFFN(nn.Module): | |
| def __init__(self, d, cs=64): | |
| super().__init__() | |
| self.fc = nn.Linear(d, 4*d) | |
| self.proj = nn.Linear(4*d, d) | |
| self.do = nn.Dropout(0.1) | |
| self.cs = cs | |
| self.mode = 'dense' | |
| self.active_chunks = None | |
| def forward(self, x): | |
| h = F.gelu(self.fc(x)) | |
| if self.mode == 'dense' or self.active_chunks is None: | |
| return self.do(self.proj(h)) | |
| elif self.mode == 'pyloop': | |
| return self.do(PythonLoopSparseLinear.apply( | |
| h, self.proj.weight, self.proj.bias, self.active_chunks, self.cs, False)) | |
| else: # triton | |
| return self.do(TritonChunkedSparseLinear.apply( | |
| h, self.proj.weight, self.proj.bias, self.active_chunks, self.cs, False)) | |
| class Attn(nn.Module): | |
| def __init__(self, d, nh, bs): | |
| super().__init__() | |
| self.nh, self.hd = nh, d//nh | |
| self.qkv = nn.Linear(d, 3*d) | |
| self.proj = nn.Linear(d, d) | |
| self.do = nn.Dropout(0.1) | |
| self.register_buffer('mask', torch.tril(torch.ones(bs,bs)).view(1,1,bs,bs)) | |
| def forward(self, x): | |
| B,T,C = x.shape | |
| q,k,v = self.qkv(x).split(C,2) | |
| q = q.view(B,T,self.nh,self.hd).transpose(1,2) | |
| k = k.view(B,T,self.nh,self.hd).transpose(1,2) | |
| v = v.view(B,T,self.nh,self.hd).transpose(1,2) | |
| att = (q @ k.transpose(-2,-1)) / math.sqrt(self.hd) | |
| att = att.masked_fill(self.mask[:,:,:T,:T]==0, float('-inf')) | |
| att = self.do(F.softmax(att, dim=-1)) | |
| return self.proj((att @ v).transpose(1,2).contiguous().view(B,T,C)) | |
| class Block(nn.Module): | |
| def __init__(self, d, nh, bs): | |
| super().__init__() | |
| self.ln1=nn.LayerNorm(d); self.attn=Attn(d,nh,bs) | |
| self.ln2=nn.LayerNorm(d); self.mlp=SparseFFN(d) | |
| def forward(self, x): | |
| x = x + self.attn(self.ln1(x)) | |
| return x + self.mlp(self.ln2(x)) | |
| class GPT(nn.Module): | |
| def __init__(self, d, nl, nh, bs): | |
| super().__init__() | |
| self.te=nn.Embedding(V,d); self.pe=nn.Embedding(bs,d) | |
| self.blocks=nn.ModuleList([Block(d,nh,bs) for _ in range(nl)]) | |
| self.ln=nn.LayerNorm(d); self.head=nn.Linear(d,V) | |
| def forward(self, idx, tgt=None): | |
| x = self.te(idx)+self.pe(torch.arange(idx.shape[1],device=idx.device))[None] | |
| for b in self.blocks: x = b(x) | |
| lo = self.head(self.ln(x)) | |
| loss = F.cross_entropy(lo.view(-1,lo.size(-1)), tgt.view(-1)) if tgt is not None else None | |
| return lo, loss | |
| def get_ffns(self): | |
| return [b.mlp for b in self.blocks] | |
| # Run | |
| STEPS = 100 | |
| af = 0.10 | |
| cs = 64 | |
| print(f"End-to-end training: {STEPS} steps, B={BS}, T={BLK}, active_frac={af}") | |
| print(f"{'d_model':>7} | {'Mode':>8} | {'ms/step':>10} | {'vs Dense':>10} | {'val_loss':>10}") | |
| print("-"*60) | |
| for d in [512, 1024, 2048]: | |
| nh = 8; nl = 6 | |
| results = {} | |
| for mode in ['dense', 'pyloop', 'triton']: | |
| torch.manual_seed(42) | |
| model = GPT(d, nl, nh, BLK).to(device) | |
| opt = torch.optim.AdamW(model.parameters(), lr=5e-4) | |
| ffns = model.get_ffns() | |
| torch.cuda.synchronize() | |
| t0 = time.perf_counter() | |
| for step in range(STEPS): | |
| if mode != 'dense': | |
| for ffn in ffns: | |
| ffn.mode = mode | |
| # proj: Linear(4d, d) -> weight shape (d, 4d), out_features=d | |
| nc = ffn.proj.out_features // cs | |
| k = max(1, int(af * nc)) | |
| ffn.active_chunks = torch.randperm(nc, device=device)[:k].sort().values | |
| else: | |
| for ffn in ffns: | |
| ffn.mode = 'dense'; ffn.active_chunks = None | |
| x, y = get_batch(train_data, torch.Generator().manual_seed(step)) | |
| opt.zero_grad() | |
| _, loss = model(x, y) | |
| loss.backward() | |
| opt.step() | |
| torch.cuda.synchronize() | |
| ms = 1000 * (time.perf_counter() - t0) / STEPS | |
| # Eval | |
| model.eval() | |
| for ffn in ffns: ffn.mode = 'dense'; ffn.active_chunks = None | |
| with torch.no_grad(): | |
| vl = sum(model(*get_batch(val_data, torch.Generator().manual_seed(9999+i)))[1].item() for i in range(20))/20 | |
| results[mode] = (ms, vl) | |
| del model; torch.cuda.empty_cache() | |
| d_ms = results['dense'][0] | |
| for mode in ['dense', 'pyloop', 'triton']: | |
| ms, vl = results[mode] | |
| sp = d_ms / ms | |
| print(f"{d:>7} | {mode:>8} | {ms:>9.1f}ms | {sp:>9.2f}x | {vl:>9.4f}") | |
| print() | |