How do I count the total number of parameters in a PyTorch model? Something similar to model.count_params()
in Keras.
12 Answers
PyTorch doesn't have a function to calculate the total number of parameters as Keras does, but it's possible to sum the number of elements for every parameter group:
pytorch_total_params = sum(p.numel() for p in model.parameters())
If you want to calculate only the trainable parameters:
pytorch_total_params = sum(p.numel() for p in model.parameters() if p.requires_grad)
Answer inspired by this answer on PyTorch Forums.
To get the parameter count of each layer like Keras, PyTorch has model.named_parameters()
that returns an iterator over both the parameter name and the parameter itself. Example:
from prettytable import PrettyTable
def count_parameters(model):
table = PrettyTable(["Modules", "Parameters"])
total_params = 0
for name, parameter in model.named_parameters():
if not parameter.requires_grad:
continue
params = parameter.numel()
table.add_row([name, params])
total_params += params
print(table)
print(f"Total Trainable Params: {total_params}")
return total_params
count_parameters(net)
Example output:
+++
 Modules  Parameters 
+++
 embeddings.weight  922866 
 conv1.weight  1048576 
 conv1.bias  1024 
 bn1.weight  1024 
 bn1.bias  1024 
 conv2.weight  2097152 
 conv2.bias  1024 
 bn2.weight  1024 
 bn2.bias  1024 
 conv3.weight  2097152 
 conv3.bias  1024 
 bn3.weight  1024 
 bn3.bias  1024 
 lin1.weight  50331648 
 lin1.bias  512 
 lin2.weight  265728 
 lin2.bias  519 
+++
Total Trainable Params: 56773369
To avoid double counting shared parameters, use torch.Tensor.data_ptr
. E.g.:
sum(dict((p.data_ptr(), p.numel()) for p in model.parameters()).values())
Here's a more verbose implementation that can optionally filter out nontrainable parameters:
def numel(m: torch.nn.Module, only_trainable: bool = False):
"""
Returns the total number of parameters used by `m` (only counting
shared parameters once); if `only_trainable` is True, then only
includes parameters with `requires_grad = True`
"""
parameters = list(m.parameters())
if only_trainable:
parameters = [p for p in parameters if p.requires_grad]
unique = {p.data_ptr(): p for p in parameters}.values()
return sum(p.numel() for p in unique)
You can use torchsummary
to do the same thing. It's just two lines of code.
from torchsummary import summary
print(summary(model, (input_shape)))

4That project appears to be abandoned, as of 2023, there is an updated fork here: github.com/TylerYep/torchinfo– JustasCommented Jun 5, 2023 at 12:19
If you want to calculate the number of weights and biases in each layer without instantiating the model, you can simply load the raw file and iterate over the resulting collections.OrderedDict
like so:
import torch
tensor_dict = torch.load('model.dat', map_location='cpu') # OrderedDict
tensor_list = list(tensor_dict.items())
for layer_tensor_name, tensor in tensor_list:
print('Layer {}: {} elements'.format(layer_tensor_name, torch.numel(tensor)))
You'll get something like
conv1.weight: 312
conv1.bias: 26
batch_norm1.weight: 26
batch_norm1.bias: 26
batch_norm1.running_mean: 26
batch_norm1.running_var: 26
conv2.weight: 2340
conv2.bias: 10
batch_norm2.weight: 10
batch_norm2.bias: 10
batch_norm2.running_mean: 10
batch_norm2.running_var: 10
fcs.layers.0.weight: 135200
fcs.layers.0.bias: 260
fcs.layers.1.weight: 33800
fcs.layers.1.bias: 130
fcs.batch_norm_layers.0.weight: 260
fcs.batch_norm_layers.0.bias: 260
fcs.batch_norm_layers.0.running_mean: 260
fcs.batch_norm_layers.0.running_var: 260
Another possible solution with respect
def model_summary(model):
print("model_summary")
print()
print("Layer_name"+"\t"*7+"Number of Parameters")
print("="*100)
model_parameters = [layer for layer in model.parameters() if layer.requires_grad]
layer_name = [child for child in model.children()]
j = 0
total_params = 0
print("\t"*10)
for i in layer_name:
print()
param = 0
try:
bias = (i.bias is not None)
except:
bias = False
if not bias:
param =model_parameters[j].numel()+model_parameters[j+1].numel()
j = j+2
else:
param =model_parameters[j].numel()
j = j+1
print(str(i)+"\t"*3+str(param))
total_params+=param
print("="*100)
print(f"Total Params:{total_params}")
model_summary(net)
This would give output similar to below
model_summary
Layer_name Number of Parameters
====================================================================================================
Conv2d(1, 6, kernel_size=(3, 3), stride=(1, 1)) 60
Conv2d(6, 16, kernel_size=(3, 3), stride=(1, 1)) 880
Linear(in_features=576, out_features=120, bias=True) 69240
Linear(in_features=120, out_features=84, bias=True) 10164
Linear(in_features=84, out_features=10, bias=True) 850
====================================================================================================
Total Params:81194
There is a builtin utility function to convert an iterable of tensors into a tensor: torch.nn.utils.parameters_to_vector
, then combine with torch.numel
:
torch.nn.utils.parameters_to_vector(model.parameters()).numel()
Or shorter with a named import (from torch.nn.utils import parameters_to_vector
):
parameters_to_vector(model.parameters()).numel()
I use this method when I have various custom blocks used in the main model.
To display the parameter count of custom blocks rather than individual layers inside those blocks, you can define a method in your custom block classes to calculate the total number of parameters. Then, in your main model, you can call this method for each custom block and sum up the parameter counts.
Create The Model
import torch
import torch.nn as nn
from prettytable import PrettyTable
class CustomBlock(nn.Module):
def __init__(self, in_channels, out_channels):
super(CustomBlock, self).__init__()
self.conv = nn.Conv2d(in_channels, out_channels, kernel_size=3, padding=1)
self.relu = nn.ReLU(inplace=True)
self.pool = nn.MaxPool2d(kernel_size=2, stride=2)
def forward(self, x):
x = self.conv(x)
x = self.relu(x)
x = self.pool(x)
return x
def count_parameters(self):
return sum(p.numel() for p in self.parameters() if p.requires_grad)
class MainModel(nn.Module):
def __init__(self):
super(MainModel, self).__init__()
self.block1 = CustomBlock(3, 64)
self.block2 = CustomBlock(64, 128)
self.block3 = CustomBlock(128, 256)
def forward(self, x):
x = self.block1(x)
x = self.block2(x)
x = self.block3(x)
return x
def count_parameters(self):
total_params = sum(p.numel() for p in self.parameters() if p.requires_grad)
custom_block_params = [(name, block.count_parameters()) for name, block in self.named_children()]
return total_params, custom_block_params
Create an instance of the model
model = MainModel()
Display the parameter count
total_params, custom_block_params = model.count_parameters()
table = PrettyTable(['Block Name', 'Parameter Count'])
for block_name, params in custom_block_params:
table.add_row([block_name, params])
table.add_row(['Total', total_params])
print(table)
Result
Final answer you can plug in:
def count_number_of_parameters(model: nn.Module, only_trainable: bool = True) > int:
"""
Counts the number of trainable params. If all params, specify only_trainable = False.
Ref:
 https://discuss.pytorch.org/t/howdoicheckthenumberofparametersofamodel/4325/9?u=brando_miranda
 https://stackoverflow.com/questions/49201236/checkthetotalnumberofparametersinapytorchmodel/62764464#62764464
:return:
"""
if only_trainable:
num_params: int = sum(p.numel() for p in model.parameters() if p.requires_grad)
else: # counts trainable and nonetraibale
num_params: int = sum(p.numel() for p in model.parameters() if p)
assert num_params > 0, f'Err: {num_params=}'
return int(num_params)
None of the answers fully address if different parameters share memory, including the answers that use numel
, PrettyTable
and .data_ptr
. @teichert gave a great answer that handles the case where there are two different parameters that point to the exact same tensor. But what if one parameter is a slice of another? Though they would share some memory, using.data_ptr()
naively would come up with different results  thus there would still be overcounting using his approach.
To be thorough, you need to ensure that none of the entries in any of the tensors point to the same thing. This can be accomplished by using setcomprehensions:
Include nontrainable parameters:
len({e.data_ptr() for p in model.parameters() for e in p.view(1)})
Ignore nontrainable parameters:
len({e.data_ptr() for p in model.parameters() if p.requires_grad for e in p.view(1)})
If tensors can share memory, how about counting the number of unique tensors? This sounds like a tricky interview problem, but it's easy with the UnionFind data structure! If you don't want to pip install
it, just copy this file verbatim as a drop in replacement.
Pass your model into this function, and it will not overcount if there is any memory sharing even if some parameters are slices of others.
def num_parameters(model, show_only_trainable):
from UnionFind import UnionFind
u = UnionFind()
for p in model.parameters():
if not show_only_trainable or p.requires_grad:
u.union(*[e.data_ptr() for e in p.view(1)])
print(f'Number of parameters: {len(u)}')
print(f'Number of tensors: {u.num_connected_components}')
This code demonstrates the problem with using the other techniques and how using the above function fixes it.
>>> import torch.nn as nn
>>> import torch
>>> torch.manual_seed(0)
>>>
>>> # This layer is not trainable
>>> frozen_layer = nn.Linear(out_features=3, in_features=4, bias=False)
>>> for p in frozen_layer.parameters():
... p.requires_grad = False
...
>>>
>>> # There are 4*2 + 3*4 = 20 total parameters
>>> # There are 4*2 = 8 trainable parameters
>>> model = nn.Sequential(
... nn.Linear(out_features=4, in_features=2, bias=False),
... nn.ReLU(),
... frozen_layer,
... nn.Sigmoid()
... )
>>>
>>> # Parameters seem properly accounted for so far
>>> sum(dict((p.data_ptr(), p.numel()) for p in model.parameters()).values())
20
>>> sum(dict((p.data_ptr(), p.numel()) for p in model.parameters() if p.requires_grad).values())
8
>>>
>>> # Add a new Parameter that is an arbitrary slice of an existing Parameter.
>>> # NOTE that slice syntax `[]` and wrapping with `nn.Parameter()` do
>>> # NOT copy the data, but merely point to part of existing tensor.
>>> model.newparam = nn.Parameter(next(model.parameters())[0:2, 1:2])
>>>
>>> params = list(model.parameters())
>>>
>>> # Notice that both appear the same. Do they share memory?
>>> # `params[0]` is `model.newparam`. `params[1]` is tensor that `params[0]` was sliced from.
>>>
>>> params[0]
Parameter containing:
tensor([[0.4683],
[ 0.0262]], requires_grad=True)
>>>
>>> params[1][0:2, 1:2]
tensor([[0.4683],
[ 0.0262]], grad_fn=<SliceBackward0>)
>>>
>>> with torch.no_grad():
... params[0][0, 0] = 1.2345
...
>>>
>>> # Both have changed, proving that they DO share memory.
>>>
>>> params[0]
Parameter containing:
tensor([[1.2345],
[0.0262]], requires_grad=True)
>>>
>>> params[1][0:2, 1:2]
tensor([[1.2345],
[0.0262]], grad_fn=<SliceBackward0>)
>>>
>>> # WRONG  the number of parameters "appears" to have increased by 2 (because of `model.newparam`).
>>> sum(dict((p.data_ptr(), p.numel()) for p in model.parameters()).values())
22
>>> sum(dict((p.data_ptr(), p.numel()) for p in model.parameters() if p.requires_grad).values())
10
>>>
>>> # CORRECT  this discounts all shared parameters
>>> len({e.data_ptr() for p in model.parameters() for e in p.view(1)})
20
>>> len({e.data_ptr() for p in model.parameters() if p.requires_grad for e in p.view(1)})
8
>>>
>>> # To count unique tensors, we can use this function.
>>> # It utilizes the UnionFind data structure which can be dropped in directly from here:
>>> # https://gist.github.com/timgianitsos/0878a0b241cb5d0ad8b16ebc2b14322a
>>> def num_parameters(model, show_only_trainable):
... from UnionFind import UnionFind
... u = UnionFind()
... for p in model.parameters():
... if not show_only_trainable or p.requires_grad:
... u.union(*[e.data_ptr() for e in p.view(1)])
... print(f'Number of parameters: {len(u)}')
... print(f'Number of tensors: {u.num_connected_components}')
...
>>>
>>> # Notice that the problem has been fixed
>>> num_parameters(model, show_only_trainable=False)
Number of parameters: 20
Number of tensors: 2
>>> num_parameters(model, show_only_trainable=True)
Number of parameters: 8
Number of tensors: 1
Bear in mind that using my num_parameters()
function takes longer to run than the other solutions since it has to loop over all the entries in all the tensors  about 2 minutes on my Mac's CPU for a 22 million parameter model. It can be made much faster if you utilize the fact that the data pointers for consecutive memory addresses differ by the same constant amount (e.g. 4 bytes if the tensor is torch.float32
). But this requires taking the tensors' dtype
and stride
into account which is probably overkill if you are willing to wait a few minutes on anything larger than 20 million parameters.
You can use the torchinfo library.
To see all the information:
from torchinfo import summary
print(summary(model, (batch_size, *input_shape)))
Example of getting the number of trainable parameters:
n_param = summary(nn.Linear(10, 1)).trainable_params
As @fábioperez mentioned, there is no such builtin function in PyTorch.
However, I found this to be a compact and neat way of achieving the same result:
num_of_parameters = sum(map(torch.numel, model.parameters()))
num_params: int = sum(p.numel() for p in model.parameters() if p.requires_grad)
for trainable number of params