tmp-checkpoint-750/sparsification_sftt.py

from transformers import TrainerCallback, Trainer
from trl import SFTTrainer, DataCollatorForCompletionOnlyLM
from peft import PeftModel
from datasets import Dataset
from typing import Any, Dict, Union, Optional, Tuple
from torch.nn import MSELoss
import warnings
import torch
import torch.nn as nn
import matplotlib.pyplot as plt
import numpy as np
import time
import os
import copy

# from deepspeed.utils import save_state_dict


from transformers.models.mistral.modeling_mistral import (
    MistralMLP,
    MistralModel,
    MistralDecoderLayer,
    MistralConfig,
    MistralForCausalLM,
)
from experiments.models.sparse_mistral.svd_router import (
    low_rank_approximation,
    SparsePredictor,
)
from utils.utils import (
    print_size_of_model,
    is_running_deepspeed,
    is_mainprocess,
    get_datetime,
    ds_print,
)


class SparseSFTTTrainer(SFTTrainer):
    def __init__(self, *args, **kwargs):
        self.regularization_coefficient = kwargs.pop("regularization_coefficient", 10)
        self.use_sparse_regularization = kwargs.pop("use_sparse_regularization", False)
        self.use_spm_loss = False
        self.freeze_original_weights = False
        self.regularization_type = kwargs.pop("regularization_type", "L1 positive activation")
        assert self.regularization_type in [
            "L2 activation",
            "L1 positive activation",
        ], f"Invalid regularization type: {self.regularization_type}"
        self.sparse_layers = []
        self.sparse_decoder_layers = []
        super(SparseSFTTTrainer, self).__init__(*args, **kwargs)

    def initialize_sparse_silu_layers(self, model):
        self.sparse_layers = [m for m in model.modules() if isinstance(m, MistralSparseSiluMLP)]

    def initialize_sparse_decoder_layers(self, model):
        self.sparse_decoder_layers = [m for m in model.modules() if isinstance(m, SparseMistralDecoderLayer)]

    def training_step(self, model: nn.Module, inputs: Dict[str, Union[torch.Tensor, Any]]) -> torch.Tensor:
        """
        Override the huggingface's training_step function to add a regularization term.
        A regularization term is computed with intermediate values, which are freed after "backward()."
        You need to set `retain_graph=True` inside `backward` function to keep the values.
        """
        model.train()
        inputs = self._prepare_inputs(inputs)

        with self.compute_loss_context_manager():
            loss = self.compute_loss(model, inputs)

        if self.args.n_gpu > 1:
            loss = loss.mean()  # mean() to average on multi-gpu parallel training
        if not self.freeze_original_weights:
            if loss is not None:
                self.accelerator.backward(loss, retain_graph=True)

        if self.use_sparse_regularization:
            regularization_loss = self.compute_regularization(model)
            if self.args.n_gpu > 1:
                regularization_loss = regularization_loss.mean()
            if regularization_loss is not None:
                self.accelerator.backward(regularization_loss, retain_graph=True)
            loss += regularization_loss

            if self.state.global_step % 5 == 0:
                ds_print("Regularization loss: ", regularization_loss.item())

        if self.use_spm_loss:
            spm_loss = self.compute_spm_loss(model)
            if self.args.n_gpu > 1:
                spm_loss = spm_loss.mean()
            if spm_loss is not None:
                self.accelerator.backward(spm_loss, retain_graph=False)
            loss += spm_loss

        return loss.detach() / self.args.gradient_accumulation_steps

    def compute_regularization(self, model):
        """
        Compute a sparse regularization loss for SiLU
        """
        loss = 0
        if len(self.sparse_layers) == 0:
            self.initialize_sparse_silu_layers(model)
        num_layers = len(self.sparse_layers)

        for module in self.sparse_layers:
            if module.activation_norm is not None:
                loss += module.activation_norm

        loss /= num_layers
        loss *= self.regularization_coefficient

        if self.state.global_step % 20 == 0 and loss != 0:
            print("Negative relularizer loss: ", loss.item())
        return loss

    def compute_spm_loss(self, model):
        loss = 0
        if len(self.sparse_decoder_layers) == 0:
            self.initialize_sparse_decoder_layers(model)
        for module in self.sparse_decoder_layers:
            if module.distill_loss != None:
                loss += module.distill_loss
        if self.state.global_step % 20 == 0 and loss != 0:
            print("Sparse Predictor Distillation loss: ", loss.item())
        return loss

    # def compute_loss(self, model, inputs, return_outputs=False):
    #     loss = super().compute_loss(model, inputs, return_outputs)
    #
    #     if is_sagemaker_mp_enabled():
    #         import smdistributed.modelparallel.torch as smp
    #         @smp.step()
    #         def smp_forward_backward(model, inputs, gradient_accumulation_steps=1):
    #             outputs = model(**inputs)
    #             loss = outputs["loss"] if isinstance(outputs, dict) else outputs[0]
    #             loss /= gradient_accumulation_steps
    #             model.backward(loss)
    #             return loss
    #
    #         loss_mb = smp_forward_backward(
    #             model, inputs, self.args.gradient_accumulation_steps
    #         )
    #         if self.use_sparse_regularization:
    #             return loss_mb.reduce_mean().detach().to(
    #                 self.args.device
    #             ) + self.regularization_coefficient * self.compute_regularization(model)
    #         else:
    #             return loss_mb.reduce_mean().detach().to(self)
    #
    #     if return_outputs:
    #         classification_loss, outputs = loss
    #     else:
    #         classification_loss = loss
    #
    #     loss = classification_loss
    #     if self.use_sparse_regularization:
    #         regularization_loss = self.compute_regularization(model)
    #         loss += self.regularization_coefficient * regularization_loss
    #
    #     return (loss, outputs) if return_outputs else loss


class SparseTrainer(Trainer):
    def __init__(self, *args, **kwargs):
        self.regularization_coefficient = kwargs.pop("regularization_coefficient", 10)
        self.use_sparse_regularization = kwargs.pop("use_sparse_regularization", False)
        self.use_spm_loss = False
        self.freeze_original_weights = False
        self.regularization_type = kwargs.pop("regularization_type", "L1 positive activation")
        assert self.regularization_type in [
            "L2 activation",
            "L1 positive activation",
        ], f"Invalid regularization type: {self.regularization_type}"
        self.sparse_layers = []
        self.sparse_decoder_layers = []
        super(SparseTrainer, self).__init__(*args, **kwargs)

    def initialize_sparse_silu_layers(self, model):
        self.sparse_layers = [m for m in model.modules() if isinstance(m, MistralSparseSiluMLP)]

    def initialize_sparse_decoder_layers(self, model):
        self.sparse_decoder_layers = [m for m in model.modules() if isinstance(m, SparseMistralDecoderLayer)]

    def training_step(self, model: nn.Module, inputs: Dict[str, Union[torch.Tensor, Any]]) -> torch.Tensor:
        """
        Override the huggingface's training_step function to add a regularization term.
        A regularization term is computed with intermediate values, which are freed after "backward()."
        You need to set `retain_graph=True` inside `backward` function to keep the values.
        """
        model.train()
        inputs = self._prepare_inputs(inputs)

        with self.compute_loss_context_manager():
            loss = self.compute_loss(model, inputs)

        if self.args.n_gpu > 1:
            loss = loss.mean()  # mean() to average on multi-gpu parallel training
        if not self.freeze_original_weights:
            if loss is not None:
                self.accelerator.backward(loss, retain_graph=True)

        if self.use_sparse_regularization:
            regularization_loss = self.compute_regularization(model)
            if self.args.n_gpu > 1:
                regularization_loss = regularization_loss.mean()
            if regularization_loss is not None:
                self.accelerator.backward(regularization_loss, retain_graph=True)
            loss += regularization_loss

        if self.use_spm_loss:
            spm_loss = self.compute_spm_loss(model)
            if self.args.n_gpu > 1:
                spm_loss = spm_loss.mean()
            if spm_loss is not None:
                self.accelerator.backward(spm_loss, retain_graph=False)
            loss += spm_loss

        return loss.detach() / self.args.gradient_accumulation_steps

    def compute_regularization(self, model):
        """
        Compute a sparse regularization loss for SiLU
        """
        loss = 0
        if len(self.sparse_layers) == 0:
            self.initialize_sparse_silu_layers(model)
        num_layers = len(self.sparse_layers)

        for module in self.sparse_layers:
            if module.activation_norm is not None:
                loss += module.activation_norm

        loss /= num_layers
        loss *= self.regularization_coefficient

        if self.state.global_step % 20 == 0 and loss != 0:
            print("Negative relularizer loss: ", loss.item())
        return loss

    def compute_spm_loss(self, model):
        loss = 0
        if len(self.sparse_decoder_layers) == 0:
            self.initialize_sparse_decoder_layers(model)
        for module in self.sparse_decoder_layers:
            if module.distill_loss != None:
                loss += module.distill_loss
        if self.state.global_step % 20 == 0 and loss != 0:
            print("Sparse Predictor Distillation loss: ", loss.item())
        return loss


class SparseSiLU(nn.SiLU):
    def __init__(self, threshold):
        super(SparseSiLU, self).__init__()
        self.threshold = threshold
        self.m = nn.Threshold(self.threshold, 0)

    def set_new_threshold(self, threshold):
        self.threshold = threshold
        self.m = nn.Threshold(threshold, 0)

    def forward(self, x):
        act = super(SparseSiLU, self).forward(x)
        return self.m(act) - self.m(-act)


class MistralSparseSiluMLP(MistralMLP):
    def __init__(self, config, *args, **kwargs):
        super().__init__(config)
        self.swish_outputs = None
        self.relu = nn.ReLU()

        self.kill_sparse_swish_outputs = False
        self.dead_percentage = 0
        self.is_stats = False
        self.visit_counts = 0

        # Hyperparameters to tune
        self.dead_threshold = kwargs.pop("dead_threshold", 0)
        self.use_sparse_regularization = kwargs.pop("use_sparse_regularization", True)
        self.regularization_type = kwargs.pop("regularization_type", "L1 regularization")
        self.regularization_threshold = kwargs.pop("regularization_threshold", 0.5)
        self.use_relu = kwargs.pop("use_relu", False)
        self.activation_norm = None

        # Activation Histograms
        self.is_collect_histogram = False
        num_bins = 1000
        self.histogram_bins = torch.linspace(-1, 1, num_bins - 2)
        self.histogram_bins = torch.cat([torch.tensor([-torch.inf]), self.histogram_bins, torch.tensor([torch.inf])])
        self.pre_act_hist_counts = torch.zeros(num_bins - 1)
        self.post_act_hist_counts = torch.zeros(num_bins - 1)
        self.t = 0
        self.agg_sparsity = 0

        # Sparse activation function
        self.sparse_act_fn = SparseSiLU(threshold=self.dead_threshold)

    def activate_stats(self, is_collect_histogram: bool = True):
        self.is_stats = True
        self.dead_percentage = 0
        self.visit_counts = 0
        self.is_collect_histogram = is_collect_histogram
        self.histogram_counts = torch.zeros(2000)  # .to(self.down_proj.weight.device)

    def deactivate_stats(self):
        self.is_stats = False

    def collect_stats(self, pre_activation, post_activation):
        start_time = time.time()
        pre_activation = pre_activation.float().cpu().detach()
        post_activation = post_activation.float().cpu().detach()
        # self.histogram_bins=self.histogram_bins.to(pre_activation.device).type(pre_activation.dtype)
        self.pre_act_hist_counts += torch.histogram(pre_activation, bins=self.histogram_bins)[0]
        self.post_act_hist_counts += torch.histogram(torch.abs(post_activation), bins=self.histogram_bins)[0]
        self.t += time.time() - start_time
        if self.visit_counts % 30 == 0:
            print(f"Time taken to collect stats: {self.t}s.")

    def forward(
        self,
        x,
        sp_mask: torch.tensor = None,
    ):
        """
        If kill_sparse_swish_outputs is set to False, this layer functions exactly like a normal MLP layer.
        """
        if sp_mask != None:  # When sparse mask is given
            return self.down_proj(
                self.sparse_act_fn(self.gate_proj(x) * sp_mask) * self.up_proj(x)
            )  # Todo: This doesn't accelerate runtime (instead slowing down)

        elif self.use_relu:
            return self.down_proj(self.relu(self.gate_proj(x)) * self.up_proj(x))

        else:
            pre_act = self.gate_proj(x)
            post_act = self.act_fn(pre_act)
            if self.kill_sparse_swish_outputs:
                dead_neurons = post_act.abs() <= self.dead_threshold

                dead_percentage = dead_neurons.float().mean()
                agg_sparsity = dead_neurons.all(dim=0).float().mean()

                if self.is_stats:
                    self.dead_percentage = (self.dead_percentage * self.visit_counts + dead_percentage) / (self.visit_counts + 1)
                    self.agg_sparsity = (self.agg_sparsity * self.visit_counts + agg_sparsity) / (self.visit_counts + 1)
                    self.visit_counts += 1

                    # print(self.agg_sparsity)

                    # Collect histogram stats
                    if self.is_collect_histogram:
                        self.collect_stats(pre_act, post_act)

                post_act[dead_neurons] = 0

            out = self.down_proj(post_act * self.up_proj(x))
            if self.use_sparse_regularization:
                if self.regularization_type == "L1 regularization":
                    self.activation_norm = torch.abs(post_act)[post_act < self.regularization_threshold].mean()
                elif self.regularization_type == "L2 regularization":
                    self.activation_norm = torch.sqrt(torch.square(post_act)[post_act < self.regularization_threshold]).mean()

            return out


class SparseMistralDecoderLayer(MistralDecoderLayer):
    def __init__(
        self,
        config: MistralConfig,
        layer_idx: int,
        decoder_layer: MistralDecoderLayer,
        init_svd: bool = True,
        *args,
        **kwargs,
    ):
        assert isinstance(decoder_layer.mlp, MistralSparseSiluMLP), f"{type(decoder_layer.mlp)} should MistralSparseSiluMLP."

        super().__init__(config, layer_idx)
        self.hidden_size = config.hidden_size
        self.intermediate_size = config.intermediate_size

        self.init_svd = init_svd
        self.self_attn = decoder_layer.self_attn

        self.mlp = decoder_layer.mlp
        self.input_layernorm = decoder_layer.input_layernorm
        self.post_attention_layernorm = decoder_layer.post_attention_layernorm

        # Sparse predictor for mlp (initialized with SVD decomposed matrix)
        self.low_rank = kwargs.pop("low_rank", 64)
        self.sparse_act_func = decoder_layer.mlp.sparse_act_fn

        print(f"Setting {layer_idx}th mlp layer's sparse predictor... svd init: {init_svd}")
        self.sp_mlp = low_rank_approximation(
            decoder_layer.mlp.gate_proj,
            act_func=self.sparse_act_func,
            init_svd=init_svd,
        )
        self.use_async = kwargs.pop("use_async", False)
        self.use_sparse_predictor = False
        self.distill_loss = None

    def forward(
        self,
        hidden_states: torch.Tensor,
        attention_mask: Optional[torch.Tensor] = None,
        position_ids: Optional[torch.LongTensor] = None,
        past_key_value: Optional[Tuple[torch.Tensor]] = None,
        output_attentions: Optional[bool] = False,
        use_cache: Optional[bool] = False,
        **kwargs,
    ) -> Tuple[torch.FloatTensor, Optional[Tuple[torch.FloatTensor, torch.FloatTensor]]]:
        if "padding_mask" in kwargs:
            warnings.warn(
                "Passing `padding_mask` is deprecated and will be removed in v4.37. Please make sure use `attention_mask` instead.`"
            )

        residual = hidden_states
        sp_mask = None

        if self.use_async:
            sp_mask = self.sp_mlp(hidden_states)

        hidden_states = self.input_layernorm(hidden_states)

        # Self Attention
        hidden_states, self_attn_weights, present_key_value = self.self_attn(
            hidden_states=hidden_states,
            attention_mask=attention_mask,
            position_ids=position_ids,
            past_key_value=past_key_value,
            output_attentions=output_attentions,
            use_cache=use_cache,
        )
        hidden_states = residual + hidden_states

        # Fully Connected
        residual = hidden_states
        hidden_states = self.post_attention_layernorm(hidden_states)

        if not self.use_async:
            sp_mask = self.sp_mlp(hidden_states)

        # Compute distillation loss
        gating_output = self.mlp.sparse_act_fn(self.mlp.gate_proj(hidden_states))
        loss_func = MSELoss()
        self.distill_loss = loss_func(sp_mask, gating_output)

        # Convert sp mask into binary form
        sp_mask = sp_mask > 0

        if self.training:
            sp_mask = None
        # if not self.use_sparse_predictor:
        #     sp_mask = None

        hidden_states = self.mlp(hidden_states, sp_mask)
        hidden_states = residual + hidden_states

        outputs = (hidden_states,)

        if output_attentions:
            outputs += (self_attn_weights,)

        if use_cache:
            outputs += (present_key_value,)

        return outputs


class SparseMistralConfig(MistralConfig):
    model_type = "sparse_mistral"

    def __init__(self, **kwargs):
        super().__init__(**kwargs)


class SparseMistralforCausalLM(MistralForCausalLM):
    config_class = SparseMistralConfig

    def __init__(self, config):
        super().__init__(config)
        self.config = config
        if config.use_sparse_model:
            self.apply_sparse_mlp()
            if config.thresholds is not None:
                for idx, m in enumerate(self.model.layers):
                    if isinstance(m.mlp, MistralSparseSiluMLP):
                        m.mlp.dead_threshold = config.thresholds[idx]
                        m.mlp.sparse_act_fn.set_new_threshold(m.mlp.dead_threshold)
                        m.mlp.kill_sparse_swish_outputs = True
                        print("Setting a threshold")
        if config.use_sparse_predictor:
            self.apply_sparse_predictor(init_svd=config.init_svd)

    def apply_sparse_mlp(self):
        apply_mistral_sparse_silu_mlp(
            self,
            config=self.config,
            use_sparse_regularization=self.config.use_sparse_regularization,
        )

    def apply_sparse_predictor(self, init_svd: bool = True):
        apply_mistral_sparse_decoder_layer(self, config=self.config, init_svd=init_svd)


class GracefulRegularizationScheduler(TrainerCallback):
    def __init__(
        self,
        num_warmup_steps=40,
        is_enabled: bool = False,
        model_name: str = "mistral",
        test_dataset: Dataset = None,
        targeted_sparsity: float = 0.5,
        keep_regularization_with_kill: bool = False,
        start_steps: int = 0,
    ):
        """Scheduler for regularizing the model first before applying the dead threshold.

        :param num_warmup_steps: number of training steps required to reach the dead threshold, defaults to 40
        :param increment_ratio: by how much to increase the dead threshold.
            For example, 0.5 means "increase the threshold by 0.5 * desired threshold
        """
        self.num_warmup_steps = num_warmup_steps
        self.is_enabled = is_enabled
        self.model_name = model_name
        self.test_dataset = test_dataset
        self.targeted_sparsity = targeted_sparsity
        self.keep_regularization_with_kill = keep_regularization_with_kill
        self.act_hist_path = f"/matx/u/lukeai/histograms/graceful_reg_{targeted_sparsity}/act_hist.pt"
        if self.is_enabled:
            print("GracefulRegularizationScheduler is enabled.")
        self.trainer = None
        self.start_steps = start_steps

    def set_trainer(self, trainer):
        self.trainer = trainer

    def on_step_end(self, args, state, control, **kwargs):
        if not self.is_enabled:
            return

        model = kwargs["model"]
        if isinstance(model, PeftModel):
            base_model = model.get_base_model()
        else:
            base_model = model

        if state.global_step == 1:
            ds_print("Setting an initial reg threshold to 0.1")
            set_regularization_threshold(base_model, 0.1)

        # if state.global_step >= self.num_warmup_steps and state.global_step % 50 == 0:
        if state.global_step == self.num_warmup_steps:
            activate_stats(base_model)
            enable_sparse_silu(base_model)
            self.trainer.evaluate()
            save_act_hist(base_model, self.act_hist_path)
            set_sparse_threshold(base_model, self.targeted_sparsity, False)
            deactivate_stats(base_model)
            self.trainer.use_sparse_regularization = self.keep_regularization_with_kill
            # set_layer_specific_regularization(model.get_base_model())
            print_dead_neuron_stats(base_model)

        if state.global_step % 10 == 0:
            if is_mainprocess():
                current_steps = self.start_steps + state.global_step
                ds_print(
                    f"Saving to /scr/lukeai/{self.model_name}_{current_steps}.pt",
                )
                # save_state_dict(model, f"/scr/lukeai/{self.model_name}_{state.global_step}.pt")
                print("Saving a model...")
                torch.save(
                    model.state_dict(),
                    f"/scr/lukeai/{self.model_name}_{current_steps}.pt",
                )


class GradualSparsificationScheduler(TrainerCallback):
    def __init__(
        self,
        num_warmup_steps=40,
        increment_ratio=0.5,
        is_enabled: bool = False,
        model_name: str = "mistral",
    ):
        """Scheduler for gradually increasing a dead threshold until it reaches the desired threshold.

        :param num_warmup_steps: number of training steps required to reach the dead threshold, defaults to 40
        :param increment_ratio: by how much to increase the dead threshold.
            For example, 0.5 means "increase the threshold by 0.5 * desired threshold
        """
        self.num_warmup_steps = num_warmup_steps
        self.increment_ratio = increment_ratio
        self.step_size = int(num_warmup_steps * increment_ratio)
        self.is_enabled = is_enabled
        self.model_name = model_name

    def on_step_end(self, args, state, control, **kwargs):
        model = kwargs["model"]

        if not self.is_enabled:
            if state.global_step <= 10:
                for module in model.modules():
                    if isinstance(module, MistralSparseSiluMLP):
                        module.current_dead_threshold = module.dead_threshold
            return

        current_dead_threshold = 0
        desired_dead_threshold = 0

        if is_mainprocess():
            ds_print(state.global_step)

        if state.global_step % self.step_size == 2:
            for module in model.modules():
                if isinstance(module, MistralSparseSiluMLP):
                    desired_dead_threshold = copy.deepcopy(module.dead_threshold)
                    current_dead_threshold = module.current_dead_threshold
                    current_dead_threshold += self.increment_ratio * desired_dead_threshold
                    module.current_dead_threshold = min(desired_dead_threshold, current_dead_threshold)

            if is_running_deepspeed and is_mainprocess():
                ds_print(
                    state.global_step,
                    current_dead_threshold,
                    desired_dead_threshold,
                )


def get_sparse_mistral_config(
    config: MistralConfig,
    use_sparse_model=False,
    use_sparse_predictor=False,
    use_sparse_regularization=False,
    thresholds=None,
):
    new_config = SparseMistralConfig()
    new_config.__dict__.update(config.__dict__)
    config = new_config
    config.use_sparse_model = use_sparse_model
    config.use_sparse_predictor = use_sparse_predictor
    config.use_sparse_regularization = use_sparse_regularization
    config.thresholds = thresholds

    return config


def apply_mistral_sparse_silu_mlp(
    model,
    config,
    use_sparse_regularization: bool = False,
):
    # counts = 0
    for layer in model.model.layers:
        # counts += 1
        # if counts < 4:
        #     continue
        original_mlp = layer.mlp
        new_mlp = MistralSparseSiluMLP(config, use_sparse_regularization=use_sparse_regularization)
        new_mlp.gate_proj = original_mlp.gate_proj
        new_mlp.up_proj = original_mlp.up_proj
        new_mlp.down_proj = original_mlp.down_proj
        layer.mlp = new_mlp


def apply_mistral_sparse_decoder_layer(
    model,
    config,
    init_svd: bool = True,
):
    assert isinstance(model.model, MistralModel), "model.model must be a MistralModel."
    new_layers = []
    for layer_idx, layer in enumerate(model.model.layers):
        if isinstance(layer.mlp, MistralSparseSiluMLP):
            new_layers.append(
                SparseMistralDecoderLayer(
                    config=config,
                    layer_idx=layer_idx,
                    decoder_layer=layer,
                    init_svd=init_svd,
                )
            )
            print(f"{layer_idx}th mlp layer activation: {layer.mlp.sparse_act_fn}")
        else:
            new_layers.append(layer)
    model.model.layers = nn.ModuleList(new_layers)


def enable_sparse_predictor(
    model,
):
    for layer_idx, layer in enumerate(model.model.layers):
        if isinstance(layer, MistralDecoderLayer):
            layer.use_sparse_predictor = True


def disable_sparse_predictor(
    model,
):
    for layer_idx, layer in enumerate(model.model.layers):
        if isinstance(layer, MistralDecoderLayer):
            layer.use_sparse_predictor = False


def activate_stats(model, is_collect_histogram: bool = True):
    for layer in model.model.layers:
        if isinstance(layer.mlp, MistralSparseSiluMLP):
            layer.mlp.activate_stats(is_collect_histogram=is_collect_histogram)


def deactivate_stats(model):
    for layer in model.model.layers:
        if isinstance(layer.mlp, MistralSparseSiluMLP):
            layer.mlp.deactivate_stats()


def enable_sparse_silu(model):
    print("Enabling SparseSilu")
    for i, layer in enumerate(model.model.layers):
        if isinstance(layer.mlp, MistralSparseSiluMLP):
            layer.mlp.kill_sparse_swish_outputs = True


def print_dead_neuron_stats(model):
    total_sparsity = 0
    counts = 0
    for i, layer in enumerate(model.model.layers):
        if isinstance(layer.mlp, MistralSparseSiluMLP):
            dead_percentage = layer.mlp.dead_percentage * 100
            agg_sparsity = layer.mlp.agg_sparsity * 100
            ds_print(f"layer {i} threshold: {layer.mlp.dead_threshold:.3f}")
            ds_print(f"layer {i} sparsity: {dead_percentage:.3f}%")
            ds_print(f"layer {i} agg sparsity: {agg_sparsity:.3f}%")
            total_sparsity += dead_percentage
            counts += 1

    ds_print(f"Total sparsity: {total_sparsity/counts: .3f}%")
    return total_sparsity / counts


def get_sparse_layers(model: MistralModel):
    sparse_layers = [m.mlp for m in model.layers() if isinstance(m.mlp, MistralSparseSiluMLP)]
    return sparse_layers


def get_threshold(bin_edges: torch.tensor, histogram_counts: torch.tensor, sparsity_level: float):  # Only for L1 Regularization
    assert len(bin_edges.shape) == len(histogram_counts.shape) == 1, "bin_edges and histogram are expected to be 1-dimensional."
    histogram_counts /= histogram_counts.sum()
    threshold_idx = torch.searchsorted(histogram_counts.cumsum(0), sparsity_level, side="right")

    return bin_edges[threshold_idx]


def set_regularization_threshold(model, threshold: float = 0.1):
    for i, layer in enumerate(model.model.layers):
        if (
            isinstance(layer.mlp, MistralSparseSiluMLP) and layer.mlp.is_stats
        ):  # Can set the threshold only the relevant statistics is collected.
            layer.mlp.regularization_threshold = threshold  # TODO: find better param


def set_sparse_threshold(model, sparsity_level: float, use_relu: bool = False):
    for i, layer in enumerate(model.model.layers):
        if (
            isinstance(layer.mlp, MistralSparseSiluMLP) and layer.mlp.is_stats
        ):  # Can set the threshold only the relevant statistics is collected.
            if use_relu:
                layer.mlp.sparse_act_fn = nn.ReLU()
                layer.mlp.use_relu = True
            else:
                layer.mlp.dead_threshold = get_threshold(
                    layer.mlp.histogram_bins,
                    layer.mlp.post_act_hist_counts,
                    sparsity_level,
                )
                layer.mlp.sparse_act_fn.set_new_threshold(layer.mlp.dead_threshold)
                layer.mlp.regularization_threshold = layer.mlp.dead_threshold * 1.2  # TODO: find better param


def plot_histogram(bin_edges, histogram_counts: torch.tensor, title: str = "Activation Distribution"):
    plt.bar(bin_edges[:-1], histogram_counts, width=np.diff(bin_edges), edgecolor="black")
    plt.title(title)
    plt.xlabel("Activation Value")
    plt.ylabel("Frequency")
    os.makedirs("figures", exist_ok=True)
    plt.savefig(f"figures/{title}.png")
    # plt.show()
    plt.clf()


def plot_act(model):
    for i, layer in enumerate(model.model.layers):
        if (
            isinstance(layer.mlp, MistralSparseSiluMLP) and layer.mlp.is_stats
        ):  # Can set the threshold only the relevant statistics is collected.
            plot_title = f"Layer: {i} Pre-Activation Distribution"
            plot_histogram(layer.mlp.histogram_bins, layer.mlp.pre_act_hist_counts, plot_title)

            plot_title = f"Layer: {i} Post-Activation Absolute Distribution"
            plot_histogram(layer.mlp.histogram_bins, layer.mlp.post_act_hist_counts, plot_title)


def save_act_hist(model, filename="/scr/jay/models/mistral/pre_finetune/cola_act_hist.pt"):
    os.makedirs(os.path.dirname(filename), exist_ok=True)
    act_dict = {}
    for i, layer in enumerate(model.model.layers):
        if (
            isinstance(layer.mlp, MistralSparseSiluMLP) and layer.mlp.is_stats
        ):  # Can set the threshold only the relevant statistics is collected.
            act_dict[i] = (
                layer.mlp.histogram_bins,
                layer.mlp.pre_act_hist_counts,
                layer.mlp.post_act_hist_counts,
            )
    print("Saving activation histograms...\n\n\n")
    torch.save(act_dict, filename)


def load_act_hist(model, filename="/scr/jay/models/mistral/pre_finetune/cola_act_hist.pt"):
    assert os.path.exists(filename), f"{filename} does not exist when loading pre/post-activation histogram of SparseMistralSiluMLP."
    print("Loading activation histograms...\n\n\n")

    act_dict = torch.load(filename)
    for i, layer in enumerate(model.model.layers):
        if (
            isinstance(layer.mlp, MistralSparseSiluMLP) and layer.mlp.is_stats
        ):  # Can set the threshold only the relevant statistics is collected.
            (
                layer.mlp.histogram_bins,
                layer.mlp.pre_act_hist_counts,
                layer.mlp.post_act_hist_counts,
            ) = act_dict[i]


def enable_last_k_modules(model, start_module_idx: int):
    assert 32 > start_module_idx >= 0
    new_modules = []
    new_idx = 0
    for idx in range(start_module_idx, len(model.model.original_layers)):
        module = model.model.original_layers[idx]
        module.layer_idx = new_idx
        module.self_attn.layer_idx = new_idx
        new_modules.append(module)
        new_idx += 1
        print(module.layer_idx)

    model.model.layers = nn.ModuleList(new_modules)


def enable_first_k_modules(model, end_module_idx: int):
    assert 32 > end_module_idx >= 0
    new_modules = []
    new_idx = 0
    for idx in range(0, end_module_idx + 1):
        module = model.model.original_layers[idx]
        module.layer_idx = new_idx
        module.self_attn.layer_idx = new_idx
        new_modules.append(module)
        new_idx += 1
        print(module.layer_idx)

    model.model.layers = nn.ModuleList(new_modules)