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import torch
import torch.nn.functional as F
from torch.utils.data import DataLoader, TensorDataset
import numpy as np
import logging
import hashlib

from math_verifier import MathReward

logger = logging.getLogger(__name__)

class DCPOTrainer:
    def __init__(
        self,
        actor_model,
        ref_model,
        tokenizer,
        learning_rate: float = 1e-6,
        group_size: int = 4,
        eps_low: float = 0.16,  
        eps_high: float = 0.2,
        r_max: float = 10.0,
        grpo_epochs: int = 1,
        max_grad_norm: float = 1.0,
        use_amp: bool = True,
        gradient_accumulation_steps: int = 1,
        inner_batch_size: int = 4,
        use_reference_comparison: bool = True,  
        use_progressive_reward: bool = False,   
        phase1_steps: int = 2000,              
        phase2_steps: int = 4000               
    ):
        self.actor = actor_model
        self.ref_model = ref_model
        self.tokenizer = tokenizer
        
        self.use_progressive_reward = use_progressive_reward
        
        if use_progressive_reward:
            from progressive_reward import ProgressiveMathReward
            self.math_verifier = ProgressiveMathReward(
                use_reference_comparison=use_reference_comparison,
                phase1_steps=phase1_steps,
                phase2_steps=phase2_steps,
                verbose=True
            )
        else:
            self.math_verifier = MathReward(
                use_reference_comparison=use_reference_comparison
            )
        
        self.group_size = group_size
        self.eps_low = eps_low
        self.eps_high = eps_high
        self.r_max = r_max
        self.grpo_epochs = grpo_epochs
        self.use_amp = use_amp
        self.max_grad_norm = max_grad_norm
        
        self.gradient_accumulation_steps = gradient_accumulation_steps
        self.inner_batch_size = inner_batch_size
        self.experience_buffer = [] 
        self.current_step = 0

        if hasattr(actor_model, 'module'):
            self.device = next(actor_model.module.parameters()).device
        else:
            self.device = next(actor_model.parameters()).device

        self.optimizer = torch.optim.AdamW(
            self.actor.parameters(), 
            lr=learning_rate,
            weight_decay=0.01
        )

        self.scaler = torch.amp.GradScaler('cuda', enabled=use_amp)

        if self.ref_model:
            self.ref_model.eval()
            self.ref_model.requires_grad_(False)

        self.sas_stats = {}

    def _get_stable_hash(self, text):
        return hashlib.md5(text.encode('utf-8')).hexdigest()

    def state_dict(self):
        return {
            'optimizer_state_dict': self.optimizer.state_dict(),
            'sas_stats': self.sas_stats,
            'scaler_state_dict': self.scaler.state_dict() if self.scaler is not None else None,
            'current_step': self.current_step  
        }

    def load_state_dict(self, state_dict):
        if 'optimizer_state_dict' in state_dict:
            self.optimizer.load_state_dict(state_dict['optimizer_state_dict'])
            for state in self.optimizer.state.values():
                for k, v in state.items():
                    if isinstance(v, torch.Tensor):
                        state[k] = v.to(self.device)
                        
        if 'sas_stats' in state_dict:
            self.sas_stats = state_dict['sas_stats']

            
        if 'scaler_state_dict' in state_dict and state_dict['scaler_state_dict'] is not None:
            self.scaler.load_state_dict(state_dict['scaler_state_dict'])
        
        if 'current_step' in state_dict:
            self.current_step = state_dict['current_step']

    def update_step(self, step):
        self.current_step = step
        if self.use_progressive_reward:
            self.math_verifier.update_step(step)

    def _get_unwrapped_model(self, model):
        if hasattr(model, 'module'): 
            return model.module
        return model

    @torch.no_grad()
    def generate_and_prepare(self, prompt_batch, max_gen_len=512, temperature=1.0):
        self.actor.eval()
        prompts_text = prompt_batch['prompt']
        ground_truths = prompt_batch['ground_truth']
        
        inputs = self.tokenizer(
            prompts_text, 
            return_tensors="pt", 
            padding=True, 
            padding_side="left"
        ).to(self.device)
        
        prompts_ids = inputs['input_ids']
        attention_mask = inputs['attention_mask']
        prompt_len = int(prompts_ids.shape[1])
        
        prompts_ids_repeated = prompts_ids.repeat_interleave(self.group_size, dim=0)
        attention_mask_repeated = attention_mask.repeat_interleave(self.group_size, dim=0)
        
        input_data = {
            'segments': [{'type': 'text', 'data': prompts_ids_repeated, 'modality_id': 0}],
            'attention_mask': attention_mask_repeated
        }
        
        # 推理时使用 unwrapped model
        unwrapped_actor = self._get_unwrapped_model(self.actor)
        with torch.amp.autocast('cuda', enabled=self.use_amp):
            generated_ids = unwrapped_actor.generate(
                input_data,
                max_new_tokens=max_gen_len,
                do_sample=True,
                temperature=temperature,
                top_p=0.95,
                pad_token_id=self.tokenizer.pad_token_id
            )
            
        sequences = torch.cat([prompts_ids_repeated, generated_ids], dim=1)
        decoded_responses = self.tokenizer.batch_decode(generated_ids, skip_special_tokens=True)
        
        # 处理 Think 标签
        full_responses_for_reward = []
        for r in decoded_responses:
            if not r.strip().startswith("<think>"):
                full_responses_for_reward.append("<think>\n" + r.strip())
            else:
                full_responses_for_reward.append(r)
                
        expanded_gts = []
        for gt in ground_truths:
            expanded_gts.extend([gt] * self.group_size)

        raw_rewards = self.math_verifier.compute_rewards(full_responses_for_reward, expanded_gts)
        rewards_tensor = torch.tensor(raw_rewards, device=self.device, dtype=torch.float32)
        
        gen_mask = (generated_ids != self.tokenizer.pad_token_id).long()
        full_attention_mask = torch.cat([attention_mask_repeated, gen_mask], dim=1)
        
        batch_size = sequences.size(0)
        seq_len = sequences.size(1)
        position_ids = torch.zeros((batch_size, seq_len), dtype=torch.long, device=self.device)
        
        for i in range(batch_size):
            # 找到第一个非 padding token 的位置
            non_pad_positions = (full_attention_mask[i] == 1).nonzero(as_tuple=True)[0]
            if len(non_pad_positions) > 0:
                start_pos = non_pad_positions[0].item()
                valid_len = len(non_pad_positions)
                # 从 0 开始编号有效 token 的位置
                position_ids[i, start_pos:start_pos + valid_len] = torch.arange(valid_len, device=self.device)
        
        full_input_data = {'segments': [{'type': 'text', 'data': sequences, 'modality_id': 0}]}
        
        with torch.amp.autocast('cuda', enabled=self.use_amp):
            actor_out = self.actor(
                full_input_data, 
                attention_mask=full_attention_mask,
                position_ids=position_ids  
            )
        
        logits = actor_out['logits'][:, :-1, :]
        targets = sequences[:, 1:]
        log_probs = F.log_softmax(logits, dim=-1)
        per_token_log_probs = torch.gather(log_probs, -1, targets.unsqueeze(-1)).squeeze(-1)
        
        return {
            'prompts_text': prompts_text,
            'sequences': sequences.detach().cpu(),  
            'old_log_probs': per_token_log_probs.detach().cpu(), 
            'rewards': rewards_tensor.cpu(), 
            'attention_mask': full_attention_mask.cpu(),  
            'position_ids': position_ids.cpu(),  
            'prompt_length': prompt_len
        }

    def _update_sas_stats(self, prompt_text, new_rewards):
        """更新 SAS 均值和方差统计"""
        prompt_hash = self._get_stable_hash(prompt_text)
        
        mu_new = new_rewards.mean().item()
        var_new = new_rewards.var(unbiased=False).item() if len(new_rewards) > 1 else 0.0
        
        if prompt_hash not in self.sas_stats:
            self.sas_stats[prompt_hash] = {
                'i': 1,
                'mu_total': mu_new,
                'var_total': var_new
            }
            return mu_new, np.sqrt(var_new + 1e-8), mu_new, np.sqrt(var_new + 1e-8)
        
        stats = self.sas_stats[prompt_hash]
        i = stats['i'] + 1
        mu_old = stats['mu_total']
        var_old = stats['var_total']
        
        mu_total = (mu_new + (i - 1) * mu_old) / i
        term3 = ((i - 1) / i) * (mu_old - mu_new)**2
        var_total = (var_new + (i - 1) * var_old + term3) / i
        
        stats['i'] = i
        stats['mu_total'] = mu_total
        stats['var_total'] = var_total
        
        return mu_new, np.sqrt(var_new + 1e-8), mu_total, np.sqrt(var_total + 1e-8)

    def _compute_sas_advantages(self, experience_batch):
        prompts = experience_batch['prompts_text']
        rewards = experience_batch['rewards'].view(-1, self.group_size)
        
        final_advantages = []
        
        for idx, prompt in enumerate(prompts):
            group_rewards = rewards[idx]
            mu_new, std_new, mu_total, std_total = self._update_sas_stats(prompt, group_rewards)
            
            A_new = (group_rewards - mu_new) / (std_new + 1e-8)
            A_total = (group_rewards - mu_total) / (std_total + 1e-8)
            
            i = self.sas_stats[self._get_stable_hash(prompt)]['i']
            
            SA_new = ((i - 1) / i) * A_new + (1 / i) * A_total
            SA_total = (1 / i) * A_new + ((i - 1) / i) * A_total
            
            mask = (torch.abs(SA_new) < torch.abs(SA_total)).float()
            A_final = mask * SA_new + (1 - mask) * SA_total
            final_advantages.append(A_final)
            
        return torch.cat(final_advantages)

    def train_step(self, experience):
        self.experience_buffer.append(experience)
        if len(self.experience_buffer) < self.gradient_accumulation_steps:
            return None

        all_advantages = []
        for exp in self.experience_buffer:
            adv = self._compute_sas_advantages(exp)
            exp['advantages'] = adv.detach()  
            all_advantages.append(exp['advantages'])
        
        self.actor.train()
        
        max_seq_len = max([e['sequences'].size(1) for e in self.experience_buffer])
        max_lp_len = max([e['old_log_probs'].size(1) for e in self.experience_buffer])
        
        def pad_tensor(t, target_len, val):
            return F.pad(t, (0, target_len - t.size(1)), value=val)

        padded_seqs = []
        padded_old_lp = []
        padded_attn_masks = []  
        padded_pos_ids = []  
        prompt_lens_list = []
        
        for e in self.experience_buffer:
            padded_seqs.append(pad_tensor(e['sequences'], max_seq_len, self.tokenizer.pad_token_id))

            padded_old_lp.append(pad_tensor(e['old_log_probs'], max_lp_len, 0.0))
            
            padded_attn_masks.append(pad_tensor(e['attention_mask'], max_seq_len, 0))
            padded_pos_ids.append(pad_tensor(e['position_ids'], max_seq_len, 0))
            
            prompt_lens_list.extend([e['prompt_length']] * (len(e['sequences'])))

        # 显存优化:Dataset 保持在 CPU
        cat_sequences = torch.cat(padded_seqs, dim=0)
        cat_old_log_probs = torch.cat(padded_old_lp, dim=0)
        cat_advantages = torch.cat(all_advantages, dim=0)
        cat_prompt_lens = torch.tensor(prompt_lens_list)
        cat_attention_masks = torch.cat(padded_attn_masks, dim=0)  
        cat_position_ids = torch.cat(padded_pos_ids, dim=0)  
        
        self.experience_buffer = []
        
        dataset = TensorDataset(
            cat_sequences, 
            cat_old_log_probs, 
            cat_advantages, 
            cat_prompt_lens,
            cat_attention_masks,  
            cat_position_ids  
        )
        dataloader = DataLoader(dataset, batch_size=self.inner_batch_size, shuffle=True)
        
        total_loss = 0
        update_steps = 0
        
        for _ in range(self.grpo_epochs):
            for batch in dataloader:
                seqs, old_lp, advs, p_lens, attn_masks, pos_ids = [b.to(self.device) for b in batch]
                
                input_data = {'segments': [{'type': 'text', 'data': seqs, 'modality_id': 0}]}
                
                with torch.amp.autocast('cuda', enabled=self.use_amp):
                    outputs = self.actor(
                        input_data, 
                        attention_mask=attn_masks,
                        position_ids=pos_ids
                    )
                    logits = outputs['logits'][:, :-1, :]
                    targets = seqs[:, 1:]
                    
                    new_log_probs = F.log_softmax(logits, dim=-1)
                    new_token_log_probs = torch.gather(new_log_probs, -1, targets.unsqueeze(-1)).squeeze(-1)

                    mask = torch.zeros_like(new_token_log_probs)
                    for i, pl in enumerate(p_lens):
                        pl_val = int(pl.item())
                        start_idx = max(0, pl_val - 1)
                        if start_idx < mask.size(1):
                            mask[i, start_idx:] = 1.0

                    is_padding = (targets == self.tokenizer.pad_token_id)
                    is_valid_old_lp = (old_lp != 0.0)  
                    mask = mask * (~is_padding).float() * is_valid_old_lp.float()
                    
                    q_probs = torch.exp(old_lp).clamp(min=1e-10, max=1.0)  
                    term_low = 1.0 - (4.0 * self.eps_low) / q_probs
                    lower_clip = 0.5 + 0.5 * torch.sqrt(torch.clamp(term_low, min=0.0))
                    term_high = 1.0 + (4.0 * self.eps_high) / q_probs
                    upper_clip = 0.5 + 0.5 * torch.sqrt(torch.clamp(term_high, min=0.0))
                    
                    ratio = torch.exp(new_token_log_probs - old_lp)
                    ratio = torch.clamp(ratio, 0, self.r_max)
                    
                    advs_expanded = advs.unsqueeze(1).expand_as(ratio)
                    surr1 = ratio * advs_expanded
                    clipped_ratio = torch.min(torch.max(ratio, lower_clip), upper_clip)
                    surr2 = clipped_ratio * advs_expanded
                    
                    element_wise_loss = torch.min(surr1, surr2)
                    masked_loss = element_wise_loss * mask
                    response_lens = torch.clamp(mask.sum(dim=1), min=1.0)
                    per_response_loss = masked_loss.sum(dim=1) / response_lens
                    loss = -per_response_loss.mean()
                
                self.optimizer.zero_grad()
                self.scaler.scale(loss).backward()
                self.scaler.unscale_(self.optimizer)
                torch.nn.utils.clip_grad_norm_(self.actor.parameters(), self.max_grad_norm)
                self.scaler.step(self.optimizer)
                self.scaler.update()
                
                total_loss += loss.item()
                update_steps += 1
                
        return total_loss / max(update_steps, 1)