macrostat.core.Behavior#
- class macrostat.core.Behavior(parameters: Parameters, scenarios: Scenarios, variables: Variables, scenario: int = 0, differentiable: bool = False, debug: bool = False)[source]#
Bases:
ModuleBase class for the behavior of the MacroStat model.
- __init__(parameters: Parameters, scenarios: Scenarios, variables: Variables, scenario: int = 0, differentiable: bool = False, debug: bool = False)[source]#
Initialize the behavior of the MacroStat model.
- Parameters:
parameters (macrostat.core.parameters.Parameters) – The parameters of the model.
scenarios (macrostat.core.scenarios.Scenarios) – The scenarios of the model.
variables (macrostat.core.variables.Variables) – The variables of the model.
scenario (int) – The scenario to use for the model run.
debug (bool) – Whether to print debug information.
Methods
__init__(parameters, scenarios, variables[, ...])Initialize the behavior of the MacroStat model.
add_module(name, module)Add a child module to the current module.
apply(fn)Apply
fnrecursively to every submodule (as returned by.children()) as well as self.apply_parameter_shocks(t, scenario)Apply parameter shocks to the model.
bfloat16()Casts all floating point parameters and buffers to
bfloat16datatype.buffers([recurse])Return an iterator over module buffers.
children()Return an iterator over immediate children modules.
compile(*args, **kwargs)Compile this Module's forward using
torch.compile().compute_theoretical_steady_state(**kwargs)Compute the theoretical steady state of the model.
Compute the theoretical steady state of the model per step.
cpu()Move all model parameters and buffers to the CPU.
cuda([device])Move all model parameters and buffers to the GPU.
diffmax(x1, x2)Smooth approximation to the minimum B: https://mathoverflow.net/questions/35191/a-differentiable-approximation-to-the-minimum-function
diffmax_v(x)Smooth approximation to the maximum for a tensor.
diffmin(x1, x2)Smooth approximation to the minimum B: https://mathoverflow.net/questions/35191/a-differentiable-approximation-to-the-minimum-function
diffmin_v(x)Smooth approximation to the minimum.
diffwhere(condition, x1, x2)Where condition that is differentiable with respect to the condition.
double()Casts all floating point parameters and buffers to
doubledatatype.eval()Set the module in evaluation mode.
extra_repr()Return the extra representation of the module.
float()Casts all floating point parameters and buffers to
floatdatatype.forward()Forward pass of the behavior.
get_buffer(target)Return the buffer given by
targetif it exists, otherwise throw an error.get_extra_state()Return any extra state to include in the module's state_dict.
get_parameter(target)Return the parameter given by
targetif it exists, otherwise throw an error.get_submodule(target)Return the submodule given by
targetif it exists, otherwise throw an error.half()Casts all floating point parameters and buffers to
halfdatatype.Initialize the behavior.
ipu([device])Move all model parameters and buffers to the IPU.
load_state_dict(state_dict[, strict, assign])Copy parameters and buffers from
state_dictinto this module and its descendants.modules()Return an iterator over all modules in the network.
mtia([device])Move all model parameters and buffers to the MTIA.
named_buffers([prefix, recurse, ...])Return an iterator over module buffers, yielding both the name of the buffer as well as the buffer itself.
named_children()Return an iterator over immediate children modules, yielding both the name of the module as well as the module itself.
named_modules([memo, prefix, remove_duplicate])Return an iterator over all modules in the network, yielding both the name of the module as well as the module itself.
named_parameters([prefix, recurse, ...])Return an iterator over module parameters, yielding both the name of the parameter as well as the parameter itself.
parameters([recurse])Return an iterator over module parameters.
register_backward_hook(hook)Register a backward hook on the module.
register_buffer(name, tensor[, persistent])Add a buffer to the module.
register_forward_hook(hook, *[, prepend, ...])Register a forward hook on the module.
register_forward_pre_hook(hook, *[, ...])Register a forward pre-hook on the module.
register_full_backward_hook(hook[, prepend])Register a backward hook on the module.
register_full_backward_pre_hook(hook[, prepend])Register a backward pre-hook on the module.
register_load_state_dict_post_hook(hook)Register a post-hook to be run after module's
load_state_dict()is called.register_load_state_dict_pre_hook(hook)Register a pre-hook to be run before module's
load_state_dict()is called.register_module(name, module)Alias for
add_module().register_parameter(name, param)Add a parameter to the module.
register_state_dict_post_hook(hook)Register a post-hook for the
state_dict()method.register_state_dict_pre_hook(hook)Register a pre-hook for the
state_dict()method.requires_grad_([requires_grad])Change if autograd should record operations on parameters in this module.
set_extra_state(state)Set extra state contained in the loaded state_dict.
set_submodule(target, module[, strict])Set the submodule given by
targetif it exists, otherwise throw an error.share_memory()See
torch.Tensor.share_memory_().state_dict(*args[, destination, prefix, ...])Return a dictionary containing references to the whole state of the module.
step(t, scenario[, params])Step function of the behavior.
tanhmask(x)Convert a variable into 0 (x<0) and 1 (x>0)
to(*args, **kwargs)Move and/or cast the parameters and buffers.
to_empty(*, device[, recurse])Move the parameters and buffers to the specified device without copying storage.
train([mode])Set the module in training mode.
type(dst_type)Casts all parameters and buffers to
dst_type.xpu([device])Move all model parameters and buffers to the XPU.
zero_grad([set_to_none])Reset gradients of all model parameters.
Attributes
T_destinationcall_super_initdump_patches- apply_parameter_shocks(t: int, scenario: dict)[source]#
Apply parameter shocks to the model.
Any parameter in the model can be shocked/changed during the simulation using the scenario information. Specifically, for a parameter alpha, the user can pass two types of potential shocks: 1. An multiplicative shock, generically named alpha_multiply 2. An additive shock, generically named alpha_add
This function will apply the shocks to the parameters, and return a dictionary with the updated parameters. The application of the shocks is independent, that is, the multiplicative shock does not affect the additive shock and vice versa. This is done by first applying the multiplicative shock, and then the additive shock.
- compute_theoretical_steady_state(**kwargs)[source]#
Compute the theoretical steady state of the model.
This process generally follows the structure of the forward() function, but instead of simulating the model, the steady state is computed at each timestep. Therefore, (1) the model is initialized, and (2) for each timestep the parameter and scenario information is passed to the compute_theoretical_steady_state_per_step() function that computes the steady state at that timestep.
- Parameters:
**kwargs (dict) – Additional keyword arguments.
- compute_theoretical_steady_state_per_step(**kwargs)[source]#
Compute the theoretical steady state of the model per step.
- diffmax(x1, x2)[source]#
Smooth approximation to the minimum B: https://mathoverflow.net/questions/35191/a-differentiable-approximation-to-the-minimum-function
- Requires:
self.hyper[‘max_constant’] as a large number
- Parameters:
x1 (torch.Tensor) – The first variable to be compared.
x2 (torch.Tensor) – The second variable to be compared.
- diffmax_v(x)[source]#
Smooth approximation to the maximum for a tensor. See diffmax
- Requires:
self.hyper[‘max_constant’] as a large number
- Parameters:
x (torch.Tensor) – The variable to be converted.
- diffmin(x1, x2)[source]#
Smooth approximation to the minimum B: https://mathoverflow.net/questions/35191/a-differentiable-approximation-to-the-minimum-function
- Requires:
self.hyper[‘min_constant’] as a large number
- Parameters:
x1 (torch.Tensor) – The first variable to be compared.
x2 (torch.Tensor) – The second variable to be compared.
- diffmin_v(x)[source]#
Smooth approximation to the minimum. See diffmin
- Parameters:
x (torch.Tensor) – The variable to be converted.
Requires – self.hyper[‘min_constant’] as a large number
- diffwhere(condition, x1, x2)[source]#
Where condition that is differentiable with respect to the condition.
- Requires:
self.hyper[‘diffwhere’] = True self.hyper[‘sigmoid_constant’] as a large number
Note: For non-NaN/inf, where(x > eps, z, y) is (x - eps > 0) * (z - y) + y, so we can use the sigmoid function to approximate the where function.
- Parameters:
condition (torch.Tensor) – Condition to be evaluated expressed as x - eps
x1 (torch.Tensor) – Value to be returned if condition is True
x2 (torch.Tensor) – Value to be returned if condition is False
- forward()[source]#
Forward pass of the behavior.
This should include the model’s main loop, and is implemented as a placeholder. The idea is for users to implement an initialize() and step() function, which will be called by the forward() function.
If there are additional steps necessary, users may wish to overwrite this function.
- initialize()[source]#
Initialize the behavior.
This should include the model’s initialization steps, and set all of the necessary state variables. They only need to be set for one period, and will then be copied to the history and prior to be used in the step function.