Files
StarPilot/tinygrad_repo/tinygrad/nn/__init__.py
T
firestar5683 d97100bd14 tiny my BUTT
2026-06-23 12:01:44 -05:00

420 lines
18 KiB
Python

from __future__ import annotations
import math, functools
from tinygrad.tensor import Tensor
from tinygrad.dtype import dtypes
from tinygrad.helpers import prod, make_tuple, flatten, USE_ATOMICS
from tinygrad.nn import optim, state, datasets # noqa: F401
class BatchNorm:
"""
Applies Batch Normalization over a 2D or 3D input.
- Paper: https://arxiv.org/abs/1502.03167v3
See: `Tensor.batchnorm`
```python exec="true" session="tensor"
from tinygrad import Tensor, dtypes, nn
import numpy as np
np.set_printoptions(precision=4)
```
```python exec="true" source="above" session="tensor" result="python"
norm = nn.BatchNorm(3)
t = Tensor.rand(2, 3, 4, 4)
print(t.mean().item(), t.std().item())
```
```python exec="true" source="above" session="tensor" result="python"
t = norm(t)
print(t.mean().item(), t.std().item())
```
"""
def __init__(self, sz:int, eps=1e-5, affine=True, track_running_stats=True, momentum=0.1):
self.eps, self.track_running_stats, self.momentum = eps, track_running_stats, momentum
self.weight: Tensor|None = Tensor.ones(sz) if affine else None
self.bias: Tensor|None = Tensor.zeros(sz) if affine else None
self.num_batches_tracked = Tensor.zeros(dtype='long').is_param_(False)
if track_running_stats: self.running_mean, self.running_var = Tensor.zeros(sz).is_param_(False), Tensor.ones(sz).is_param_(False)
def calc_stats(self, x:Tensor) -> tuple[Tensor, Tensor]:
shape_mask: list[int] = [1, -1, *([1]*(x.ndim-2))]
if self.track_running_stats and not Tensor.training: return self.running_mean, self.running_var.reshape(shape=shape_mask).expand(x.shape)
# This requires two full memory accesses to x
# https://github.com/pytorch/pytorch/blob/c618dc13d2aa23625cb0d7ada694137532a4fa33/aten/src/ATen/native/cuda/Normalization.cuh
# There's "online" algorithms that fix this, like https://en.wikipedia.org/wiki/Algorithms_for_calculating_variance#Welford's_Online_algorithm
batch_mean = x.mean(axis=(reduce_axes:=tuple(x for x in range(x.ndim) if x != 1)))
y = (x - batch_mean.detach().reshape(shape=shape_mask)) # d(var)/d(mean) = 0
batch_var = (y*y).mean(axis=reduce_axes)
return batch_mean, batch_var
def __call__(self, x:Tensor) -> Tensor:
batch_mean, batch_var = self.calc_stats(x)
# NOTE: wow, this is done all throughout training in most PyTorch models
if self.track_running_stats and Tensor.training:
self.running_mean.assign((1-self.momentum) * self.running_mean + self.momentum * batch_mean.detach())
self.running_var.assign((1-self.momentum) * self.running_var + self.momentum * x.numel()/(x.numel()-x.shape[1]) * batch_var.detach())
self.num_batches_tracked += 1
return x.batchnorm(self.weight, self.bias, batch_mean, batch_var.add(self.eps).rsqrt())
BatchNorm2d = BatchNorm3d = BatchNorm
def Conv1d(in_channels:int, out_channels:int, kernel_size:int, stride=1, padding:int|str=0, dilation=1, groups=1, bias=True) -> Conv2d:
"""
Applies a 1D convolution over an input signal composed of several input planes.
See: https://pytorch.org/docs/stable/generated/torch.nn.Conv1d
```python exec="true" source="above" session="tensor" result="python"
conv = nn.Conv1d(1, 1, 3)
t = Tensor.rand(1, 1, 4)
print(t.numpy())
```
```python exec="true" source="above" session="tensor" result="python"
t = conv(t)
print(t.numpy())
```
"""
return Conv2d(in_channels, out_channels, (kernel_size,), stride, padding, dilation, groups, bias)
class Conv2d:
"""
Applies a 2D convolution over an input signal composed of several input planes.
See: https://pytorch.org/docs/stable/generated/torch.nn.Conv2d
```python exec="true" source="above" session="tensor" result="python"
conv = nn.Conv2d(1, 1, 3)
t = Tensor.rand(1, 1, 4, 4)
print(t.numpy())
```
```python exec="true" source="above" session="tensor" result="python"
t = conv(t)
print(t.numpy())
```
"""
def __init__(self, in_channels:int, out_channels:int, kernel_size:int|tuple[int, ...], stride=1, padding:int|tuple[int, ...]|str=0,
dilation=1, groups=1, bias=True):
self.kernel_size = make_tuple(kernel_size, 2)
if isinstance(padding, str):
if padding.lower() != 'same': raise ValueError(f"Invalid padding string {padding!r}, only 'same' is supported")
if stride != 1: raise ValueError("padding='same' is not supported for strided convolutions")
pad = [(d*(k-1)//2, d*(k-1) - d*(k-1)//2) for d,k in zip(make_tuple(dilation, len(self.kernel_size)), self.kernel_size[::-1])]
padding = tuple(flatten(pad))
self.stride, self.dilation, self.groups, self.padding = stride, dilation, groups, padding
scale = 1 / math.sqrt(in_channels * prod(self.kernel_size))
self.weight = Tensor.uniform(out_channels, in_channels//groups, *self.kernel_size, low=-scale, high=scale)
self.bias: Tensor|None = Tensor.uniform(out_channels, low=-scale, high=scale) if bias else None
def __call__(self, x:Tensor) -> Tensor: return x.conv2d(self.weight, self.bias, self.groups, self.stride, self.dilation, self.padding)
def ConvTranspose1d(in_channels:int, out_channels:int, kernel_size:int, stride=1, padding=0, output_padding=0, dilation=1,
groups=1, bias=True) -> ConvTranspose2d:
"""
Applies a 1D transposed convolution operator over an input signal composed of several input planes.
See: https://pytorch.org/docs/stable/generated/torch.nn.ConvTranspose1d
```python exec="true" source="above" session="tensor" result="python"
conv = nn.ConvTranspose1d(1, 1, 3)
t = Tensor.rand(1, 1, 4)
print(t.numpy())
```
```python exec="true" source="above" session="tensor" result="python"
t = conv(t)
print(t.numpy())
```
"""
return ConvTranspose2d(in_channels, out_channels, (kernel_size,), stride, padding, output_padding, dilation, groups, bias)
class ConvTranspose2d(Conv2d):
"""
Applies a 2D transposed convolution operator over an input image.
See: https://pytorch.org/docs/stable/generated/torch.nn.ConvTranspose2d
```python exec="true" source="above" session="tensor" result="python"
conv = nn.ConvTranspose2d(1, 1, 3)
t = Tensor.rand(1, 1, 4, 4)
print(t.numpy())
```
```python exec="true" source="above" session="tensor" result="python"
t = conv(t)
print(t.numpy())
```
"""
def __init__(self, in_channels:int, out_channels:int, kernel_size:int|tuple[int, ...], stride=1, padding=0, output_padding=0,
dilation=1, groups=1, bias=True):
super().__init__(in_channels, out_channels, kernel_size, stride, padding, dilation, groups, bias)
scale = 1 / math.sqrt(in_channels * prod(self.kernel_size))
self.weight = Tensor.uniform(in_channels, out_channels//groups, *self.kernel_size, low=-scale, high=scale)
self.output_padding = output_padding
def __call__(self, x:Tensor) -> Tensor:
return x.conv_transpose2d(self.weight, self.bias, self.groups, self.stride, self.dilation, self.padding, self.output_padding)
class Linear:
"""
Applies a linear transformation to the incoming data.
See: https://pytorch.org/docs/stable/generated/torch.nn.Linear
```python exec="true" source="above" session="tensor" result="python"
lin = nn.Linear(3, 4)
t = Tensor.rand(2, 3)
print(t.numpy())
```
```python exec="true" source="above" session="tensor" result="python"
t = lin(t)
print(t.numpy())
```
"""
def __init__(self, in_features:int, out_features:int, bias=True):
bound = 1 / math.sqrt(in_features)
self.weight = Tensor.uniform(out_features, in_features, low=-bound, high=bound)
self.bias = Tensor.uniform(out_features, low=-bound, high=bound) if bias else None
def __call__(self, x:Tensor) -> Tensor: return x.linear(self.weight.transpose(), self.bias)
class GroupNorm:
"""
Applies Group Normalization over a mini-batch of inputs.
- Paper: https://arxiv.org/abs/1803.08494v3
```python exec="true" source="above" session="tensor" result="python"
norm = nn.GroupNorm(2, 12)
t = Tensor.rand(2, 12, 4, 4) * 2 + 1
print(t.mean().item(), t.std().item())
```
```python exec="true" source="above" session="tensor" result="python"
t = norm(t)
print(t.mean().item(), t.std().item())
```
"""
def __init__(self, num_groups:int, num_channels:int, eps=1e-5, affine=True):
self.num_groups, self.num_channels, self.eps = num_groups, num_channels, eps
self.weight: Tensor|None = Tensor.ones(num_channels) if affine else None
self.bias: Tensor|None = Tensor.zeros(num_channels) if affine else None
def __call__(self, x:Tensor) -> Tensor:
# reshape for layernorm to work as group norm
# subtract mean and divide stddev
x = x.reshape(x.shape[0], self.num_groups, -1).layernorm(eps=self.eps).reshape(x.shape)
if self.weight is None or self.bias is None: return x
# elementwise_affine on channels
return x * self.weight.reshape(1, -1, *[1] * (x.ndim-2)) + self.bias.reshape(1, -1, *[1] * (x.ndim-2))
class InstanceNorm:
"""
Applies Instance Normalization over a mini-batch of inputs.
- Paper: https://arxiv.org/abs/1607.08022v3
```python exec="true" source="above" session="tensor" result="python"
norm = nn.InstanceNorm(3)
t = Tensor.rand(2, 3, 4, 4) * 2 + 1
print(t.mean().item(), t.std().item())
```
```python exec="true" source="above" session="tensor" result="python"
t = norm(t)
print(t.mean().item(), t.std().item())
```
"""
def __init__(self, num_features:int, eps:float=1e-5, affine:bool=True):
self.num_features, self.eps = num_features, eps
self.weight: Tensor|None = Tensor.ones(num_features) if affine else None
self.bias: Tensor|None = Tensor.zeros(num_features) if affine else None
def __call__(self, x:Tensor) -> Tensor:
x = x.reshape(x.shape[0], self.num_features, -1).layernorm(eps=self.eps).reshape(x.shape)
if self.weight is None or self.bias is None: return x
return x * self.weight.reshape(1, -1, *[1] * (x.ndim-2)) + self.bias.reshape(1, -1, *[1] * (x.ndim-2))
class LayerNorm:
"""
Applies Layer Normalization over a mini-batch of inputs.
- Paper: https://arxiv.org/abs/1607.06450v1
```python exec="true" source="above" session="tensor" result="python"
norm = nn.LayerNorm(3)
t = Tensor.rand(2, 5, 3) * 2 + 1
print(t.mean().item(), t.std().item())
```
```python exec="true" source="above" session="tensor" result="python"
t = norm(t)
print(t.mean().item(), t.std().item())
```
"""
def __init__(self, normalized_shape:int|tuple[int, ...], eps:float=1e-5, elementwise_affine:bool=True):
self.normalized_shape: tuple[int, ...] = make_tuple(normalized_shape, 1)
self.axis, self.eps = tuple(-1-i for i in range(len(self.normalized_shape))), eps
self.weight: Tensor|None = Tensor.ones(*self.normalized_shape) if elementwise_affine else None
self.bias: Tensor|None = Tensor.zeros(*self.normalized_shape) if elementwise_affine else None
def __call__(self, x:Tensor) -> Tensor:
assert self.normalized_shape == x.shape[-len(self.normalized_shape):], f"last dimensions of {x.shape} must match {self.normalized_shape}"
x = x.layernorm(eps=self.eps, axis=self.axis)
if self.weight is None or self.bias is None: return x
return x * self.weight + self.bias
class LayerNorm2d(LayerNorm):
"""
Applies Layer Normalization over a mini-batch of 2D inputs.
See: `LayerNorm`
```python exec="true" source="above" session="tensor" result="python"
norm = nn.LayerNorm2d(3)
t = Tensor.rand(2, 3, 4, 4) * 2 + 1
print(t.mean().item(), t.std().item())
```
```python exec="true" source="above" session="tensor" result="python"
t = norm(t)
print(t.mean().item(), t.std().item())
```
"""
def __call__(self, x: Tensor) -> Tensor: return super().__call__(x.permute(0, 2, 3, 1)).permute(0, 3, 1, 2)
class RMSNorm:
"""
Applies Root Mean Square Normalization to input.
- Paper: https://arxiv.org/abs/1910.07467
```python exec="true" source="above" session="tensor" result="python"
norm = nn.RMSNorm(4)
t = Tensor.arange(12, dtype=dtypes.float).reshape(3, 4)
print(t.numpy())
```
```python exec="true" source="above" session="tensor" result="python"
print(norm(t).numpy())
```
"""
def __init__(self, dim:int, eps=1e-6, elementwise_affine=True):
self.eps = eps
self.weight = Tensor.ones(dim) if elementwise_affine else None
def _norm(self, x:Tensor) -> Tensor: return x * (x.square().mean(-1, keepdim=True) + self.eps).rsqrt()
def __call__(self, x:Tensor) -> Tensor:
x = self._norm(x.float()).cast(x.dtype)
return x if self.weight is None else x * self.weight
from tinygrad.uop.ops import UOp, KernelInfo, Ops, AxisType
def _embedding_bwd(grad_emb:UOp, call:UOp) -> tuple:
weight, idx = call.src[1:]
is_vocab_sharded = isinstance(weight.device, tuple) and weight.axis == 0
# for multi-device: replicate grad_emb and idx on all devices
if isinstance(weight.device, tuple):
assert weight.axis is None or weight.axis == 0, "only vocab (axis=0) sharding supported on Embedding with USE_ATOMICS"
grad_emb = grad_emb.copy_to_device(weight.device)
idx = idx.copy_to_device(weight.device)
if is_vocab_sharded:
ndev = len(weight.device)
local_vocab_size = weight.shape[0] // ndev
grad_weight_uop = Tensor.empty(local_vocab_size, weight.shape[1], dtype=dtypes.float, device=weight.device).uop.multi(axis=0)
else:
# weight is replicated (or single device), grad_weight should match
grad_weight_uop = Tensor.empty(weight.shape, dtype=dtypes.float, device=weight.device).uop
# TODO: how do we remove this dumb kernel and use Tensor.zeros?
def _zero_kernel(out:UOp) -> UOp:
i = UOp.range(out.numel(), 0)
return out.flatten()[i].store(0).end(i).sink(arg=KernelInfo(name="zero"))
grad_weight_uop = grad_weight_uop.custom_kernel(fxn=_zero_kernel)[0]
# TODO: do we have a universal helper for this?
device = call.device.split(":")[0] if not isinstance(call.device, tuple) else call.device[0].split(":")[0]
# this is the real atomic kernel
def _embedding_bwd_kernel(grad_weight:UOp, grad_emb:UOp, idx:UOp) -> UOp:
idx_flat, grad_emb_flat = idx.flatten(), grad_emb.reshape((idx.numel(), grad_weight.shape[-1]))
embed_size = grad_weight.shape[-1]
BLOCK_J = min(256, embed_size)
assert embed_size % BLOCK_J == 0, f"embed_size {embed_size} must be divisible by {BLOCK_J}"
n_j_blocks = embed_size // BLOCK_J
i = UOp.range(grad_emb_flat.shape[0], 0) # batch_size * sequence_length -> GLOBAL
j_inner = UOp.range(BLOCK_J, 2, AxisType.LOOP if device in ("CPU", "NULL") else AxisType.LOCAL) # BLOCK_J threads per workgroup
j_outer = UOp.range(n_j_blocks, 1)
j = j_outer * BLOCK_J + j_inner
if is_vocab_sharded:
# each device owns [offset, offset+local_vocab_size) of the global vocabulary
dnum = UOp.variable("_device_num", 0, ndev-1)
offset = dnum * local_vocab_size
global_token_id = idx_flat[i].cast(dtypes.weakint)
local_token_id = (global_token_id - offset).clip(0, grad_weight.shape[0]-1)
in_range = (global_token_id >= offset) & (global_token_id < (offset + local_vocab_size))
grad_val = in_range.where(grad_emb_flat[i, j].cast(dtypes.float), 0.0)
else:
local_token_id = idx_flat[i].clip(0, grad_weight.shape[0]-1).cast(dtypes.weakint)
grad_val = grad_emb_flat[i, j].cast(dtypes.float)
# atomic scatter-add: grad_weight[token_id, j] += grad_emb_flat[i, j]
if device in ("CPU", "NULL"): atomic_arg = "__atomic_fetch_add({0}, {1}, __ATOMIC_RELAXED);"
elif device == "AMD": atomic_arg = "__hip_atomic_fetch_add({0}, {1}, __ATOMIC_RELAXED, __HIP_MEMORY_SCOPE_AGENT);"
else: raise NotImplementedError(f"no atomics for device {device}")
atomic = UOp(Ops.CUSTOM, dtypes.void, (grad_weight.index(local_token_id, j, ptr=True), grad_val), arg = atomic_arg)
return atomic.end(i, j_outer, j_inner).sink(arg=KernelInfo(name="embedding_bwd", opts_to_apply=()))
grad_weight_uop = grad_weight_uop.custom_kernel(grad_emb, idx, fxn=_embedding_bwd_kernel)[0]
return (grad_weight_uop.cast(weight.dtype), None)
def _embedding_fwd(weight:Tensor, idx:Tensor) -> Tensor:
arange = Tensor.arange(weight.shape[0])
return (arange == idx.unsqueeze(-1)).unsqueeze(-1).where(weight, 0).sum(-2, dtype=weight.dtype)
@functools.cache
def _embedding_fwd_fxn(wp, ip, device):
return _embedding_fwd(Tensor(wp, device=device), Tensor(ip, device=device))
class Embedding:
"""
A simple lookup table that stores embeddings of a fixed dictionary and size.
See: https://pytorch.org/docs/stable/generated/torch.nn.Embedding
```python exec="true" source="above" session="tensor" result="python"
emb = nn.Embedding(10, 3)
print(emb(Tensor([1, 2, 3, 1])).numpy())
```
"""
def __init__(self, vocab_size:int, embed_size:int):
self.weight = Tensor.glorot_uniform(vocab_size, embed_size)
def __call__(self, idx:Tensor) -> Tensor:
if not dtypes.is_int(idx.dtype): raise TypeError(f"Expected integer dtype for index in embedding, got {idx.dtype}")
if USE_ATOMICS:
fxn = _embedding_fwd_fxn(self.weight.as_param(0).uop, idx.as_param(1).uop, self.weight.device)
return Tensor.call(self.weight, idx, fxn=fxn, grad_fxn=_embedding_bwd)
return _embedding_fwd(self.weight, idx)
class LSTMCell:
"""
A long short-term memory (LSTM) cell.
Args:
input_size: The number of expected features in the input `x`
hidden_size: The number of features in the hidden state `h`
bias: If ``False``, then the layer does not use bias weights `b_ih` and `b_hh`
"""
def __init__(self, input_size:int, hidden_size:int, bias:bool=True):
stdv = 1.0 / math.sqrt(hidden_size)
self.weight_ih = Tensor.uniform(hidden_size*4, input_size, low=-stdv, high=stdv)
self.weight_hh = Tensor.uniform(hidden_size*4, hidden_size, low=-stdv, high=stdv)
self.bias_ih: Tensor|None = Tensor.zeros(hidden_size*4) if bias else None
self.bias_hh: Tensor|None = Tensor.zeros(hidden_size*4) if bias else None
def __call__(self, x:Tensor, hc:tuple[Tensor, Tensor]|None=None) -> tuple[Tensor, Tensor]:
if hc is None: hc = (Tensor.zeros(x.size(0), self.weight_hh.size(1), dtype=x.dtype, buffer=False),)*2
gates = x.linear(self.weight_ih.T, self.bias_ih) + hc[0].linear(self.weight_hh.T, self.bias_hh)
i, f, g, o = gates.chunk(4, dim=1)
i, f, g, o = i.sigmoid(), f.sigmoid(), g.tanh(), o.sigmoid()
new_c = f * hc[1] + i * g
return o * new_c.tanh(), new_c