""" This training script can be run both on a single gpu in debug mode, and also in a larger training run with distributed data parallel (ddp). To run on a single GPU, example: $ python train_maze.py --batch_size=32 --compile=False To run with DDP on 4 gpus on 1 node, example: $ torchrun --standalone --nproc_per_node=4 train_maze.py To run with DDP on 4 gpus across 2 nodes, example: - Run on the first (master) node with example IP 123.456.123.456: $ torchrun --nproc_per_node=8 --nnodes=2 --node_rank=0 --master_addr=123.456.123.456 --master_port=1234 train_maze.py - Run on the worker node: $ torchrun --nproc_per_node=8 --nnodes=2 --node_rank=1 --master_addr=123.456.123.456 --master_port=1234 train_maze.py (If your cluster does not have Infiniband interconnect prepend NCCL_IB_DISABLE=1) """ import os import time import math import pickle from contextlib import nullcontext import argparse import numpy as np import torch import torch.nn.functional as F from torch.nn.parallel import DistributedDataParallel as DDP from torch.distributed import init_process_group, destroy_process_group import networkx as nx import re from model.transformer import GPTConfig, GPT from model.transformer_rope import GPTRoPEConfig, GPTRoPE from model.transformer_nextlat import TransformerNextLatConfig, TransformerNextLat from model.mamba import MambaConfig, Mamba from model.mamba2 import Mamba2Config, Mamba2 from model.gated_deltanet import GatedDeltaNetConfig, GatedDeltaNet from model.gru import GRUConfig, GRU from logger import get_logger import logging from cli_utils import parse_count, format_count # Suppress verbose PyTorch Dynamo debug messages logging.getLogger("torch._dynamo").setLevel(logging.WARNING) # torch.backends.cuda.enable_flash_sdp(False) # torch.backends.cuda.enable_mem_efficient_sdp(False) # ----------------------------------------------------------------------------- # the input parameters parser = argparse.ArgumentParser(description='Training of the NanoGPT for maze data.') parser.add_argument('--dataset', type=str, default='maze', help='Name of the dataset to use') parser.add_argument('--model', type=str, default='transformer-nextlat', choices=['transformer', 'transformer-rope', 'transformer-nextlat', 'mamba', 'mamba2', 'gated-deltanet', 'gru'], help='Model architecture to train. Outputs go to out//... (default: transformer)') parser.add_argument('--n_layer', type=int, default=6, help='Number of layers (default: 1)') parser.add_argument('--n_head', type=int, default=6, help='Number of attention heads (default: 1)') parser.add_argument('--n_embd', type=int, default=384, help='Size of the embeddings (default: 120)') parser.add_argument('--max_iters', type=int, default=10000, help='Number of Iterations (default: 10000)') parser.add_argument('--num_nodes', type=int, default=100, help='Number of Nodes (default: 100)') parser.add_argument('--num_of_paths', type=int, default=20, help='Number of Paths (default: 20)') parser.add_argument('--multitasks', action=argparse.BooleanOptionalAction, default=True, help='Use multitask data (default: True)') parser.add_argument('--num_train_dataset', type=parse_count, default='500K', help='Number of multitask training entries (supports K/M/B, default: 50000)') parser.add_argument('--num_test_dataset', type=parse_count, default=10000, help='Number of multitask test entries (supports K/M/B, default: 10000)') parser.add_argument('--tasks', type=str, default='A1', help='Task specification (e.g., A1, A1B1, A3B2, A1D1F1). Default: A1') parser.add_argument('--init_ckpt', type=int, default=0, help='Initial checkpoint iteration to resume from (default: 0 means train from scratch)') parser.add_argument('--validation', action=argparse.BooleanOptionalAction, default=False, help='Enable periodic validation and checkpointing (default: False)') parser.add_argument('--ckpt_interval', type=int, default=None, help='Override checkpoint save interval (default: max_iters // 2)') parser.add_argument('--CL', action=argparse.BooleanOptionalAction, default=False, help='Enable Task C label mode (append node labels after L/R turns) and add _CL_ in filenames') parser.add_argument('--local', action='store_true', default=False, help='Disable flash attention for local GPU compatibility (default: False)') parser.add_argument('--path_type', type=str, default='RWs', choices=['RWc', 'RWa', 'RWs'], help='Path generation type: RWc (random walk with cycles), RWa (random walk acyclic, default), RWs (single source random walk).') parser.add_argument('--compile', action=argparse.BooleanOptionalAction, default=True, help='Use PyTorch 2.0 to compile the model (default: True). Disable with --no-compile if you encounter Triton/CUDA errors.') parser.add_argument('--batch_size', type=int, default=128, help='Training batch size (default: 1024). Reduce if you encounter OOM errors.') parser.add_argument('--grad_accum', type=int, default=8, help='Gradient accumulation steps (default: 1). Use a small --batch_size with larger --grad_accum to keep tokens/iter constant under memory limits (e.g. pure-PyTorch Mamba).') parser.add_argument('--mamba_cuda', action='store_true', default=True, help='For --model mamba: use the official mamba_ssm CUDA selective-scan kernel (much faster) instead of the pure-PyTorch parallel scan. Requires mamba-ssm + causal-conv1d to be installed.') # New argument to handle data without task tags parser.add_argument('--no_task_tag', action='store_true', default=False, help='Data files do not contain task identifiers (A, B, C, etc.). When enabled, data decoding will handle the no-task-tag format. This should match the setting used during data generation.') parser.add_argument('--num_labels', type=int, default=10, help='Number of distinct node labels (default: 10). Must match data generation.') # NextLat (Next-Latent Prediction) arguments (used with --model transformer-nextlat) parser.add_argument('--nextlat_horizon', type=int, default=8, help='NextLat latent dynamics rollout horizon d (default: 1)') parser.add_argument('--lambda_h', type=float, default=1.0, help='NextLat weight for next-hidden-state regression loss (default: 1.0)') parser.add_argument('--lambda_kl', type=float, default=0.1, help='NextLat weight for KL divergence loss (default: 1.0)') parser.add_argument('--mlp_hidden_dim', type=int, default=None, help='NextLat MLP hidden dimension (default: 2*n_embd)') # PostGRU: Post-Transformer GRU refinement layer parser.add_argument('--PostGRU', action='store_true', default=False, help='Enable Post-Transformer GRU refinement layer (adds _PGR suffix to filenames)') # NLS: Per-block Non-Linear prefix Scan sublayer parser.add_argument('--NLS', action='store_true', default=False, help='Enable per-block Non-Linear prefix Scan sublayer (adds _NLS suffix to filenames)') # DyadicAttn: baseline transformer whose attention is hard-coded to the # same fixed 0.5/0.5 dyadic-doubling pattern as the NLS scan. Mutually # exclusive with --NLS / --PostGRU. For fair comparison set # n_layer = ceil(log2(block_size)). parser.add_argument('--DyadicAttn', action='store_true', default=False, help='Enable DyadicTransformer baseline: replace self-attention with fixed 0.5/0.5 dyadic-pattern attention (adds _DA suffix to filenames)') parser.add_argument('--DyadicHybrid', action='store_true', default=False, help='Enable DyadicHybrid ablation: each --n_layer normal Transformer block is followed by ceil(log2(block_size)) DyadicAttn blocks (adds _DH suffix to filenames). Total physical blocks = n_layer * (1 + ceil(log2(block_size))).') parser.add_argument('--auto_n_layer', action='store_true', default=False, help='For DyadicAttn: automatically set n_layer = ceil(log2(block_size)) so the per-layer dyadic strides cover the full sequence length recorded in meta.') # Auxiliary state-supervision: force one layer's OUTPUT hidden state to linearly # decode the walker's (current_node, facing). Supported on transformer+Task C # and gru+Task H. parser.add_argument('--aux_layer', type=int, default=None, help='1-based index of the block/layer whose OUTPUT hidden state is ' 'supervised toward (node, facing). None disables the auxiliary loss ' '(default: None). E.g. --aux_layer 3 = the 3rd layer. Supported on ' 'transformer (Task C) and gru (Task H). Enabling it adds an _SA suffix ' 'to checkpoint filenames.') parser.add_argument('--aux_lambda', type=float, default=1.0, help='Weight of the auxiliary (node, facing) cross-entropy loss.') args = parser.parse_args() dataset = args.dataset model_type = args.model n_layer = args.n_layer n_head = args.n_head n_embd = args.n_embd max_iters = args.max_iters num_nodes = args.num_nodes num_of_paths = args.num_of_paths multitasks = args.multitasks num_train_dataset = args.num_train_dataset num_test_dataset = args.num_test_dataset train_label = format_count(num_train_dataset) test_label = format_count(num_test_dataset) tasks_str = args.tasks tasks_tag = f"{tasks_str}_CL" if args.CL else tasks_str # Parse path_type for filenames (RWc = cyclic, RWa = acyclic, RWs = single source) allow_cycles = (args.path_type == 'RWc') path_type_tag = args.path_type tasks_tag = f"{tasks_tag}_{path_type_tag}" # Include num_labels in tags when non-default if args.num_labels != 10: tasks_tag = f"{tasks_tag}_L{args.num_labels}" # Add _NT_ tag to tasks_tag when no_task_tag is enabled if args.no_task_tag: tasks_tag = f"{tasks_tag}_NT" # NextLat mode: enabled by selecting --model transformer-nextlat. The latent # dynamics model is encapsulated in the module, so a single optimizer + single # checkpoint covers everything. use_nextlat = (args.model == 'transformer-nextlat') nextlat_horizon = args.nextlat_horizon lambda_h = args.lambda_h lambda_kl = args.lambda_kl # data_tasks_tag: used for finding data/meta files (no _NL suffix) data_tasks_tag = tasks_tag # Add _NL tag to tasks_tag when NextLat is enabled (affects checkpoint naming only) if use_nextlat: tasks_tag = f"{tasks_tag}_NL" # PostGRU mode use_post_gru = args.PostGRU # Add _PGR tag to tasks_tag when PostGRU is enabled (affects checkpoint naming only) if use_post_gru: tasks_tag = f"{tasks_tag}_PGR" # NLS mode use_nls = args.NLS # DyadicAttn mode (mutually exclusive with NLS / PostGRU / transformer-nextlat) use_dyadic_attn = args.DyadicAttn use_dyadic_hybrid = args.DyadicHybrid if use_dyadic_hybrid and use_dyadic_attn: # Hybrid takes precedence; DyadicAttn default may be True from CLI. print('[Info] --DyadicHybrid given; auto-disabling DyadicAttn for this run.') use_dyadic_attn = False if (use_dyadic_attn or use_dyadic_hybrid) and (use_post_gru or use_nextlat): raise ValueError('--DyadicAttn / --DyadicHybrid is mutually exclusive with --PostGRU / --model transformer-nextlat') if (use_dyadic_attn or use_dyadic_hybrid) and use_nls: print(f"[Info] --{'DyadicAttn' if use_dyadic_attn else 'DyadicHybrid'} given; auto-disabling NLS for this run.") use_nls = False # Add _NLS tag to tasks_tag when NLS is enabled (affects checkpoint naming only) if use_nls: tasks_tag = f"{tasks_tag}_NLS" if use_dyadic_attn: tasks_tag = f"{tasks_tag}_DA" if use_dyadic_hybrid: tasks_tag = f"{tasks_tag}_DH" # Auxiliary state-supervision (Task C, transformer). Enabled when --aux_layer is # given. Adds a separate linear head that decodes (current_node, facing) from a # chosen block's output; its loss is added to the LM loss. Checkpoints get an # _SA suffix so they never overwrite the baseline (load via test_maze.py # --ckpt_suffix SA). use_aux = args.aux_layer is not None # --aux_layer is 1-based on the CLI; convert to a 0-based block/layer index internally. aux_layer = (args.aux_layer - 1) if use_aux else None aux_lambda = args.aux_lambda aux_task = None # 'C' (transformer) or 'H' (gru) when use_aux if use_aux: aux_task = args.tasks[0].upper() if model_type == 'transformer': if aux_task != 'C': raise ValueError('--aux_layer with --model transformer is defined for Task C only') elif model_type == 'gru': if aux_task != 'H': raise ValueError('--aux_layer with --model gru is defined for Task H only') else: raise ValueError('--aux_layer state-supervision is only implemented for ' '--model transformer (Task C) or --model gru (Task H)') if use_nextlat or use_post_gru or use_nls or use_dyadic_attn or use_dyadic_hybrid: raise ValueError('--aux_layer is mutually exclusive with NextLat / PostGRU / NLS / DyadicAttn / DyadicHybrid') tasks_tag = f"{tasks_tag}_SA" # Mamba does not support the transformer-only training variants. if model_type in ('mamba', 'mamba2', 'gated-deltanet', 'gru') and (use_nextlat or use_post_gru or use_nls or use_dyadic_attn or use_dyadic_hybrid): raise ValueError(f'--model {model_type} is incompatible with ' 'transformer-nextlat / --PostGRU / --NLS / --DyadicAttn / --DyadicHybrid') # Graph tag without path type (same graph structure) graph_tag = f"{tasks_str}_CL" if args.CL else tasks_str # Add _NT_ tag to graph_tag when no_task_tag is enabled if args.no_task_tag: graph_tag = f"{graph_tag}_NT" init_ckpt = args.init_ckpt validation = args.validation local_mode = args.local no_task_tag = args.no_task_tag # Get the no_task_tag flag data_dir = os.path.join('data', f'{dataset}/{num_nodes}') def pick_first_existing(candidates): for path in candidates: if os.path.exists(path): return path return candidates[0] meta_path = pick_first_existing([ os.path.join(data_dir, f'meta_{data_tasks_tag}.pkl'), os.path.join(data_dir, f'meta_{tasks_str}.pkl'), os.path.join(data_dir, 'meta.pkl'), ]) print(f"Loading meta from {meta_path}...") with open(meta_path, 'rb') as f: meta = pickle.load(f) stoi, itos = meta['stoi'], meta['itos'] block_size = meta['block_size'] # Auto-derive n_layer for DyadicAttn so the dyadic strides reach the full # sequence length (max stride = 2^(n_layer-1) >= block_size). if use_dyadic_attn and args.auto_n_layer: auto_n = max(1, math.ceil(math.log2(block_size))) if block_size > 1 else 1 if n_layer != auto_n: print(f"[auto_n_layer] DyadicAttn: overriding n_layer {n_layer} -> {auto_n}" f" (block_size={block_size}, ceil(log2)={auto_n})") n_layer = auto_n args.n_layer = auto_n # Check if metadata contains no_task_tag flag meta_no_task_tag = meta.get('no_task_tag', False) print(f"Metadata no_task_tag flag: {meta_no_task_tag}") print(f"Command line no_task_tag flag: {no_task_tag}") # Use metadata flag if provided, otherwise use command line flag # This ensures consistency with the data generation if 'no_task_tag' in meta: no_task_tag = meta['no_task_tag'] print(f"Using no_task_tag flag from metadata: {no_task_tag}") nt_suffix = '_NT' if args.no_task_tag else '' model_dir = model_type.replace('-', '_') # filesystem-friendly (transformer-nextlat -> transformer_nextlat) # Recurrent / SSM models have no attention heads, so omit n_head from the dir name. if model_type in ('mamba', 'mamba2', 'gated-deltanet', 'gru'): arch_tag = f'{n_layer}_{n_embd}' else: arch_tag = f'{n_layer}_{n_head}_{n_embd}' out_dir = f'out/{model_dir}/{dataset}_{arch_tag}_{num_nodes}{nt_suffix}/' # ----------------------------------------------------------------------------- # default config values designed to train a gpt2 (124M) on OpenWebText # I/O eval_interval = max_iters // 10 if validation else None checkpoint_interval = args.ckpt_interval if args.ckpt_interval is not None else max_iters // 2 # checkpoint cadence (independent of validation) log_interval = max_iters // 100 eval_iters = max_iters // 10 if validation else 1 eval_only = False # if True, script exits right after the first eval always_save_checkpoint = True # if True, always save a checkpoint after each eval init_from = 'resume' if init_ckpt > 0 else 'scratch' # determined by --init_ckpt argument # wandb logging wandb_log = False # disabled by default wandb_project = 'owt' wandb_run_name = 'gpt2' # 'run' + str(time.time()) # data #dataset = 'reasoning' gradient_accumulation_steps = args.grad_accum # used to simulate larger batch sizes train_batch_size = args.batch_size # if gradient_accumulation_steps > 1, this is the micro-batch size val_batch_size = 64 batch_size = train_batch_size #block_size = 64 # model #n_layer = 1 #12 #n_head = 1 #12 #n_embd = 384 #768 dropout = 0.0 # for pretraining 0 is good, for finetuning try 0.1+ bias = False # do we use bias inside LayerNorm and Linear layers? # adamw optimizer learning_rate = 5e-4 # max learning rate #max_iters = 50000 # total number of training iterations weight_decay = 1e-1 beta1 = 0.9 beta2 = 0.95 grad_clip = 1.0 # clip gradients at this value, or disable if == 0.0 # learning rate decay settings decay_lr = True # whether to decay the learning rate warmup_iters = max_iters//20 # how many steps to warm up for lr_decay_iters = max_iters # should be ~= max_iters per Chinchilla min_lr = learning_rate/10 # minimum learning rate, should be ~= learning_rate/10 per Chinchilla # DDP settings backend = 'nccl' # 'nccl', 'gloo', etc. # system device = 'cuda' # examples: 'cpu', 'cuda', 'cuda:0', 'cuda:1' etc., or try 'mps' on macbooks dtype = 'bfloat16' # 'float32', 'bfloat16', or 'float16', the latter will auto implement a GradScaler compile = args.compile # use PyTorch 2.0 to compile the model to be faster '''check_type = 'shortest' max_path_len = 10 max_new_tokens = 200 flag = 0 test_interval = 100''' # ----------------------------------------------------------------------------- config_keys = [k for k,v in globals().items() if not k.startswith('_') and isinstance(v, (int, float, bool, str))] #exec(open('configurator.py').read()) # overrides from command line or config file config = {k: globals()[k] for k in config_keys} # will be useful for logging # ----------------------------------------------------------------------------- # various inits, derived attributes, I/O setup ddp = int(os.environ.get('RANK', -1)) != -1 # is this a ddp run? if ddp: init_process_group(backend=backend) ddp_rank = int(os.environ['RANK']) ddp_local_rank = int(os.environ['LOCAL_RANK']) ddp_world_size = int(os.environ['WORLD_SIZE']) device = f'cuda:{ddp_local_rank}' torch.cuda.set_device(device) master_process = ddp_rank == 0 # this process will do logging, checkpointing etc. seed_offset = ddp_rank # each process gets a different seed assert gradient_accumulation_steps % torch.cuda.device_count() == 0 gradient_accumulation_steps //= torch.cuda.device_count() else: # if not ddp, we are running on a single gpu, and one process master_process = True seed_offset = 0 ddp_world_size = 1 tokens_per_iter = gradient_accumulation_steps * ddp_world_size * batch_size * block_size print(f"tokens per iteration will be: {tokens_per_iter:,}") if master_process: os.makedirs(out_dir, exist_ok=True) torch.manual_seed(1337 + seed_offset) torch.backends.cuda.matmul.allow_tf32 = True # allow tf32 on matmul torch.backends.cudnn.allow_tf32 = True # allow tf32 on cudnn device_type = 'cuda' if 'cuda' in device else 'cpu' # for later use in torch.autocast # note: float16 data type will automatically use a GradScaler ptdtype = {'float32': torch.float32, 'bfloat16': torch.bfloat16, 'float16': torch.float16}[dtype] ctx = nullcontext() if device_type == 'cpu' else torch.amp.autocast(device_type=device_type, dtype=ptdtype) def pick_first_existing(candidates): for path in candidates: if os.path.exists(path): return path return candidates[0] # poor man's data loader if multitasks: train_file = pick_first_existing([ os.path.join(data_dir, f'train_{data_tasks_tag}_{train_label}.bin'), os.path.join(data_dir, f'train_{data_tasks_tag}_{num_train_dataset}.bin'), os.path.join(data_dir, f'train_{tasks_str}_{train_label}.bin'), os.path.join(data_dir, f'train_{tasks_str}_{num_train_dataset}.bin'), ]) val_file = pick_first_existing([ os.path.join(data_dir, f'val_{data_tasks_tag}_{test_label}.bin'), os.path.join(data_dir, f'val_{data_tasks_tag}_{num_test_dataset}.bin'), os.path.join(data_dir, f'val_{tasks_str}_{test_label}.bin'), os.path.join(data_dir, f'val_{tasks_str}_{num_test_dataset}.bin'), ]) train_data = np.memmap(train_file, dtype=np.uint16, mode='r') val_data = np.memmap(val_file, dtype=np.uint16, mode='r') else: if(num_of_paths == 0): train_file = os.path.join(data_dir, 'train.bin') val_file = os.path.join(data_dir, 'val.bin') else: train_file = os.path.join(data_dir, f'train_{num_of_paths}.bin') val_file = os.path.join(data_dir, 'val.bin') train_data = np.memmap(train_file, dtype=np.uint16, mode='r') val_data = np.memmap(val_file, dtype=np.uint16, mode='r') if master_process: print(f"Training data file: {train_file}") print(f"No task tag mode: {'Enabled' if no_task_tag else 'Disabled'}") # ----------------------------------------------------------------------------- # Auxiliary state-supervision. Per-position (current_node, facing) labels are # recomputed on the fly by replaying each row against the maze. Two label # schemes: # * Task C (transformer): replay relative turns L/R/F/T starting facing East. # * Task H (gru): replay clockwise feasible-direction indices starting facing # East -- identical logic to train.py / create_multitask_maze.py::taskH. if use_aux: aux_n_grid = int(round(num_nodes ** 0.5)) AUX_DELTA = {'N': -aux_n_grid, 'S': aux_n_grid, 'E': 1, 'W': -1} AUX_FACE = {'N': 0, 'E': 1, 'S': 2, 'W': 3} AUX_NUM_STATES = num_nodes * 4 AUX_IGNORE = -1 AUX_PAD_ID, AUX_NL_ID = 0, 1 AUX_COLON_ID = stoi[':'] assert 0 <= aux_layer < n_layer, f"--aux_layer must be in [1, {n_layer}] (1-based)" if aux_task == 'C': AUX_LEFT = {'N': 'W', 'W': 'S', 'S': 'E', 'E': 'N'} AUX_RIGHT = {v: k for k, v in AUX_LEFT.items()} AUX_OPP = {'N': 'S', 'S': 'N', 'E': 'W', 'W': 'E'} AUX_C_ID = stoi['C'] AUX_L_ID, AUX_R_ID = stoi['L'], stoi['R'] AUX_F_ID, AUX_T_ID = stoi['F'], stoi['T'] else: # Task H AUX_CLOCKWISE_SCAN = { 'N': ['N', 'E', 'S', 'W'], 'E': ['E', 'S', 'W', 'N'], 'S': ['S', 'W', 'N', 'E'], 'W': ['W', 'N', 'E', 'S'], } AUX_H_ID = stoi['H'] aux_graph_path = os.path.join(data_dir, f'maze_graph_{tasks_str}_{path_type_tag}.graphml') print(f"[aux] Loading maze graph from {aux_graph_path}...") _aux_G = nx.read_graphml(aux_graph_path) AUX_NODE_DIRS = {} for _nd in range(num_nodes): _dirs = set() for _d in ('N', 'E', 'S', 'W'): _nb = _nd + AUX_DELTA[_d] if 0 <= _nb < num_nodes and _aux_G.has_edge(str(_nd), str(_nb)): _dirs.add(_d) AUX_NODE_DIRS[_nd] = _dirs def row_state_labels_taskC(row): """Given a (block_size+1)-id Task C row, return a length-block_size int array S aligned to y (= row[1:]) where S[t] is the PRE-move state (node*4 + facing) the walker stands in just before emitting the turn token at row position t+1, and AUX_IGNORE elsewhere. Node token id n encodes node (n-2).""" S = np.full(block_size, AUX_IGNORE, dtype=np.int64) if len(row) < 5 or int(row[0]) != AUX_C_ID or int(row[3]) != AUX_COLON_ID: return S source = int(row[1]) - 2 # node token id n -> node (n-2) if not (0 <= source < num_nodes): return S current = source facing = 'E' p = 4 # row position of the first turn token while p < len(row): tok = int(row[p]) if tok == AUX_NL_ID or tok == AUX_PAD_ID: break t = p - 1 # hidden at row pos p-1 predicts token at pos p if 0 <= t < block_size: S[t] = current * 4 + AUX_FACE[facing] if tok == AUX_F_ID: new_facing = facing elif tok == AUX_L_ID: new_facing = AUX_LEFT[facing] elif tok == AUX_R_ID: new_facing = AUX_RIGHT[facing] elif tok == AUX_T_ID: new_facing = AUX_OPP[facing] else: break current = current + AUX_DELTA[new_facing] if not (0 <= current < num_nodes): break facing = new_facing p += 1 return S def row_state_labels_taskH(row): """Given a (block_size+1)-id Task H row, return a length-block_size int array S aligned to y (= row[1:]) where S[t] is the PRE-move state (node*4 + facing) the walker stands in just before emitting the index token at row position t+1, and AUX_IGNORE elsewhere. Replays clockwise feasible-direction indices starting facing East. Node token id n encodes node (n-2).""" S = np.full(block_size, AUX_IGNORE, dtype=np.int64) if len(row) < 5 or int(row[0]) != AUX_H_ID or int(row[3]) != AUX_COLON_ID: return S source = int(row[1]) - 2 # node token id n -> node (n-2) if not (0 <= source < num_nodes): return S current = source facing = 'E' p = 4 # row position of the first index token while p < len(row): tok = int(row[p]) if tok == AUX_NL_ID or tok == AUX_PAD_ID: break idx = tok - 2 # index '1'..'4' encoded as node tokens 1..4 -> ids 3..6 t = p - 1 # hidden at row pos p-1 predicts token at pos p if 0 <= t < block_size: S[t] = current * 4 + AUX_FACE[facing] scan_order = AUX_CLOCKWISE_SCAN[facing] feasible = [d for d in scan_order if d in AUX_NODE_DIRS[current]] if idx < 1 or idx > len(feasible): break direction = feasible[idx - 1] current = current + AUX_DELTA[direction] if not (0 <= current < num_nodes): break facing = direction p += 1 return S if use_aux: row_state_labels = row_state_labels_taskC if aux_task == 'C' else row_state_labels_taskH def get_batch(split): data = train_data if split == 'train' else val_data batch_size = train_batch_size if split == 'train' else val_batch_size data_size = block_size + 1 data = train_data if split == 'train' else val_data ix = torch.randint( (len(data) - data_size)//data_size , (batch_size,)) * data_size x = torch.stack([torch.from_numpy((data[i:i+block_size]).astype(np.int64)) for i in ix]) y = torch.stack([torch.from_numpy((data[i+1:i+1+block_size]).astype(np.int64)) for i in ix]) if use_aux: rows = [np.asarray(data[i:i + data_size]).astype(np.int64) for i in ix.tolist()] s = torch.stack([torch.from_numpy(row_state_labels(r)) for r in rows]) else: s = None if device_type == 'cuda': # pin arrays x,y, which allows us to move them to GPU asynchronously (non_blocking=True) x, y = x.pin_memory().to(device, non_blocking=True), y.pin_memory().to(device, non_blocking=True) if s is not None: s = s.pin_memory().to(device, non_blocking=True) else: x, y = x.to(device), y.to(device) if s is not None: s = s.to(device) return x, y, s # init these up here, can override if init_from='resume' (i.e. from a checkpoint) iter_num = 0 best_val_loss = 1e9 # logger if(num_of_paths == 0): logger = get_logger(os.path.join(out_dir, "no_output_train_maze.log")) log_file_name = os.path.join(out_dir, "train_maze.log") #logger.setLevel(logging.DEBUG) else: logger = get_logger(os.path.join(out_dir, f'no_output_train_maze_{num_of_paths}.log')) log_file_name = os.path.join(out_dir, f"train_maze_{num_of_paths}.log") #logger.setLevel(logging.DEBUG) # attempt to derive vocab_size from the dataset # Use the task-specific meta file (already loaded earlier) instead of hardcoded meta.pkl meta_vocab_size = None if meta is not None and 'vocab_size' in meta: meta_vocab_size = meta['vocab_size'] print(f"found vocab_size = {meta_vocab_size} (inside {meta_path})") def get_shortest(p_graph): shortest_paths = {} for i in p_graph.nodes: for j in p_graph.nodes: try: shortest_paths[(i,j)] = list(nx.all_shortest_paths(p_graph, i, j)) except: shortest_paths[(i,j)] = [] return shortest_paths if dataset == 'reasoning': p_graph_path = os.path.join(data_dir, 'fixed_model.graphml') p_graph = nx.read_graphml(p_graph_path) shortest_paths = get_shortest(p_graph) stoi, itos = meta['stoi'], meta['itos'] # Modified decode function to handle no_task_tag format def decode_token_list(l): """Decode a list of token IDs to string.""" if no_task_tag: # In no_task_tag mode, just join all tokens with spaces return ' '.join([itos[i] for i in l if i in itos]) else: # Original decode behavior return ''.join([itos[i] for i in l if i in itos]) decode = decode_token_list # Assign the function to decode variable # model init if model_type in ('transformer', 'transformer-rope'): model_args = dict(n_layer=n_layer, n_head=n_head, n_embd=n_embd, block_size=block_size, bias=bias, vocab_size=None, dropout=dropout, use_flash=not local_mode, post_gru=use_post_gru, per_block_nls=use_nls, dyadic_attn=use_dyadic_attn, dyadic_hybrid=use_dyadic_hybrid) # start with model_args from command line elif model_type == 'transformer-nextlat': # GPT backbone + encapsulated NextLat latent dynamics model. The latent model # is part of the module, so a single optimizer / checkpoint covers everything. model_args = dict(model_type='transformer-nextlat', n_layer=n_layer, n_head=n_head, n_embd=n_embd, block_size=block_size, bias=bias, vocab_size=None, dropout=dropout, use_flash=not local_mode, mlp_hidden_dim=args.mlp_hidden_dim, nextlat_horizon=nextlat_horizon, lambda_h=lambda_h, lambda_kl=lambda_kl) elif model_type == 'gru': # Stacked residual GRU baseline (no attention). pad_id=0 mirrors the # transformer's ignore_index=0 for the padding token. model_args = dict(model_type='gru', n_layer=n_layer, n_embd=n_embd, vocab_size=None, dropout=dropout, bias=bias, pad_id=0) elif model_type == 'gated-deltanet': # Gated DeltaNet (linear-attention / delta-rule). No positional encoding; # token order is carried by the recurrence. pad_id=0 mirrors the # transformer's ignore_index=0 for the padding token. model_args = dict(model_type='gated-deltanet', n_layer=n_layer, n_embd=n_embd, vocab_size=None, pad_id=0) else: # mamba # By default use the pure-PyTorch parallel scan so it runs without the # mamba_ssm package. With --mamba_cuda, use the official fused CUDA # selective-scan kernel (much faster) when mamba-ssm is installed. # pad_id=0 mirrors the transformer's ignore_index=0 for the padding token. if model_type == 'mamba2': # Semi-official Mamba-2: official fused Triton kernel when mamba_ssm>=2.2 # is installed (--mamba_cuda, default), else pure-PyTorch chunked SSD. model_args = dict(model_type='mamba2', n_layer=n_layer, n_embd=n_embd, vocab_size=None, pscan=True, use_cuda=args.mamba_cuda, pad_id=0) else: model_args = dict(model_type='mamba', n_layer=n_layer, n_embd=n_embd, vocab_size=None, pscan=True, use_cuda=args.mamba_cuda, pad_id=0) def build_model(margs): """Instantiate the architecture selected by --model from a model_args dict.""" if model_type == 'mamba': return Mamba(MambaConfig(**margs)) if model_type == 'mamba2': return Mamba2(Mamba2Config(**margs)) if model_type == 'gated-deltanet': return GatedDeltaNet(GatedDeltaNetConfig(**margs)) if model_type == 'transformer-nextlat': return TransformerNextLat(TransformerNextLatConfig(**margs)) if model_type == 'transformer-rope': return GPTRoPE(GPTRoPEConfig(**margs)) if model_type == 'gru': return GRU(GRUConfig(**margs)) return GPT(GPTConfig(**margs)) if init_from == 'scratch': print("Initializing a new model from scratch") if meta_vocab_size is None: print("defaulting to vocab_size of GPT-2 to 50304 (50257 rounded up for efficiency)") model_args['vocab_size'] = meta_vocab_size if meta_vocab_size is not None else 50304 model = build_model(model_args) elif init_from == 'resume': # Determine the checkpoint file path based on init_ckpt and multitask setting if multitasks: candidate_ckpts = [ os.path.join(out_dir, f'{init_ckpt}_ckpt_maze_{tasks_tag}_{train_label}.pt'), os.path.join(out_dir, f'{init_ckpt}_ckpt_maze_{tasks_tag}_{num_train_dataset}.pt'), os.path.join(out_dir, f'{init_ckpt}_ckpt_maze_{tasks_str}_{train_label}.pt'), os.path.join(out_dir, f'{init_ckpt}_ckpt_maze_{num_of_paths}.pt'), os.path.join(out_dir, f'{init_ckpt}_ckpt_maze.pt'), ] ckpt_path = None for path in candidate_ckpts: if os.path.exists(path): ckpt_path = path break if ckpt_path is None: ckpt_path = candidate_ckpts[0] else: if num_of_paths == 0: ckpt_path = os.path.join(out_dir, f'{init_ckpt}_ckpt_maze.pt') else: ckpt_path = os.path.join(out_dir, f'{init_ckpt}_ckpt_maze_{num_of_paths}.pt') print(f"Resuming training from {ckpt_path}") # resume training from a checkpoint. checkpoint = torch.load(ckpt_path, map_location=device) checkpoint_model_args = checkpoint['model_args'] # force these config attributes to be equal otherwise we can't even resume training # the rest of the attributes (e.g. dropout) can stay as desired from command line if model_type in ('transformer', 'transformer-rope'): for k in ['n_layer', 'n_head', 'n_embd', 'block_size', 'bias', 'vocab_size']: model_args[k] = checkpoint_model_args[k] # Restore optional transformer-variant flags from checkpoint if present for k in ['post_gru', 'per_block_nls', 'dyadic_attn', 'dyadic_hybrid']: if k in checkpoint_model_args: model_args[k] = checkpoint_model_args[k] elif model_type == 'transformer-nextlat': for k in ['model_type', 'n_layer', 'n_head', 'n_embd', 'block_size', 'bias', 'vocab_size', 'use_flash', 'dropout', 'mlp_hidden_dim', 'nextlat_horizon', 'lambda_h', 'lambda_kl']: if k in checkpoint_model_args: model_args[k] = checkpoint_model_args[k] elif model_type == 'gru': for k in ['model_type', 'n_layer', 'n_embd', 'vocab_size', 'dropout', 'bias', 'pad_id']: if k in checkpoint_model_args: model_args[k] = checkpoint_model_args[k] elif model_type == 'gated-deltanet': for k in ['model_type', 'n_layer', 'n_embd', 'vocab_size', 'pad_id', 'head_dim', 'expand_v', 'conv_size']: if k in checkpoint_model_args: model_args[k] = checkpoint_model_args[k] else: # mamba / mamba2 for k in ['model_type', 'n_layer', 'n_embd', 'vocab_size', 'pscan', 'use_cuda', 'pad_id', 'd_state', 'expand_factor', 'd_conv', 'dt_rank', 'headdim', 'ngroups']: if k in checkpoint_model_args: model_args[k] = checkpoint_model_args[k] # create the model model = build_model(model_args) state_dict = checkpoint['model'] # fix the keys of the state dictionary :( # honestly no idea how checkpoints sometimes get this prefix, have to debug more unwanted_prefix = '_orig_mod.' for k,v in list(state_dict.items()): if k.startswith(unwanted_prefix): state_dict[k[len(unwanted_prefix):]] = state_dict.pop(k) model.load_state_dict(state_dict) iter_num = checkpoint['iter_num'] best_val_loss = checkpoint['best_val_loss'] elif init_from.startswith('gpt2'): print(f"Initializing from OpenAI GPT-2 weights: {init_from}") override_args = dict(dropout=dropout) model = GPT.from_pretrained(init_from, override_args) for k in ['n_layer', 'n_head', 'n_embd', 'block_size', 'bias', 'vocab_size']: model_args[k] = getattr(model.config, k) if model_type in ('transformer', 'transformer-rope', 'transformer-nextlat') and block_size < model.config.block_size: model.crop_block_size(block_size) model_args['block_size'] = block_size # so that the checkpoint will have the right value model.to(device) # NextLat: the latent dynamics model is encapsulated inside the # transformer-nextlat module (model.latent_model), covered by the single # optimizer / checkpoint below. if use_nextlat: print(f"NextLat (encapsulated) enabled: horizon={nextlat_horizon}, lambda_h={lambda_h}, lambda_kl={lambda_kl}, mlp_hidden_dim={args.mlp_hidden_dim if args.mlp_hidden_dim is not None else 2 * n_embd}") if use_post_gru: gru_params = sum( p.numel() for block in model.transformer.h if block.per_block_gru is not None for p in block.per_block_gru.parameters() ) print(f"PostGRU enabled (per-block): total GRU parameters: {gru_params / 1e6:.4f}M") if use_nls: nls_params = sum( p.numel() for block in model.transformer.h if block.per_block_nls is not None for p in block.per_block_nls.parameters() ) # Number of dyadic-doubling levels actually traversed for this block_size: # stride starts at 1 and doubles until stride >= L, so levels = ceil(log2(L)). nls_levels = max(1, math.ceil(math.log2(block_size))) if block_size > 1 else 0 nls_blocks = sum(1 for block in model.transformer.h if block.per_block_nls is not None) nls_share = all( block.per_block_nls.share for block in model.transformer.h if block.per_block_nls is not None ) print( f"NLS enabled (per-block): {nls_blocks} blocks, " f"{nls_levels} scan levels per block (block_size={block_size}, share={nls_share}), " f"total NLS parameters: {nls_params / 1e6:.4f}M" ) # Auxiliary (node, facing) linear head reading the chosen block's output. aux_head = None if use_aux: import torch.nn as nn aux_head = nn.Linear(n_embd, AUX_NUM_STATES, bias=True).to(device) _aux_unit = 'block' if model_type == 'transformer' else 'layer' print(f"Auxiliary supervision (Task {aux_task}): {_aux_unit} {aux_layer + 1} (1-based) output -> (node, facing) " f"{AUX_NUM_STATES}-way, lambda={aux_lambda}") # optimizer optimizer = model.configure_optimizers(weight_decay, learning_rate, (beta1, beta2), device_type) if use_aux: optimizer.add_param_group({'params': [aux_head.weight], 'weight_decay': weight_decay}) optimizer.add_param_group({'params': [aux_head.bias], 'weight_decay': 0.0}) if init_from == 'resume': optimizer.load_state_dict(checkpoint['optimizer']) if use_aux and 'aux_head' in checkpoint: aux_head.load_state_dict(checkpoint['aux_head']) # initialize a GradScaler. If enabled=False scaler is a no-op scaler = torch.cuda.amp.GradScaler(enabled=(dtype == 'float16')) if init_from == 'resume' and 'scaler' in checkpoint: scaler.load_state_dict(checkpoint['scaler']) # restore random states for reproducibility if init_from == 'resume': if 'torch_rng_state' in checkpoint: # RNG state must be a ByteTensor on CPU torch.set_rng_state(checkpoint['torch_rng_state'].cpu()) if 'cuda_rng_state' in checkpoint and checkpoint['cuda_rng_state'] is not None and torch.cuda.is_available(): # CUDA RNG state must also be a ByteTensor on CPU before setting torch.cuda.set_rng_state(checkpoint['cuda_rng_state'].cpu()) if 'numpy_rng_state' in checkpoint: np.random.set_state(checkpoint['numpy_rng_state']) checkpoint = None # free up memory # compile the model if compile and model_type in ('mamba', 'mamba2', 'gated-deltanet'): print(f"[Info] --model {model_type} uses a custom parallel-scan autograd Function; " "disabling torch.compile for stability.") compile = False if compile and use_aux: print("[Info] --aux_layer hooks into the model's internal blocks; disabling torch.compile.") compile = False if use_aux and ddp: raise ValueError('--aux_layer state-supervision does not support DDP; run on a single GPU.') if compile: print("compiling the model... (takes a ~minute)") unoptimized_model = model model = torch.compile(model) # requires PyTorch 2.0 # wrap model into DDP container if ddp: model = DDP(model, device_ids=[ddp_local_rank]) # helps estimate an arbitrarily accurate loss over either split using many batches @torch.no_grad() def estimate_loss(): out = {} model.eval() for split in ['train', 'val']: losses = torch.zeros(eval_iters) for k in range(eval_iters): X, Y, _ = get_batch(split) with ctx: _, loss = model(X, Y) losses[k] = loss.item() out[split] = losses.mean() model.train() return out # learning rate decay scheduler (cosine with warmup) def get_lr(it): # 1) linear warmup for warmup_iters steps if it < warmup_iters: return learning_rate * it / warmup_iters # 2) if it > lr_decay_iters, return min learning rate if it > lr_decay_iters: return min_lr # 3) in between, use cosine decay down to min learning rate decay_ratio = (it - warmup_iters) / (lr_decay_iters - warmup_iters) assert 0 <= decay_ratio <= 1 coeff = 0.5 * (1.0 + math.cos(math.pi * decay_ratio)) # coeff ranges 0..1 return min_lr + coeff * (learning_rate - min_lr) def open_and_append(filename, text): with open(filename, 'a') as file: file.write(text + '\n') # logging if wandb_log and master_process: import wandb wandb.init(project=wandb_project, name=wandb_run_name, config=config) # Helper function to format seconds into HH:MM:SS def format_time(seconds): hours = int(seconds // 3600) minutes = int((seconds % 3600) // 60) secs = int(seconds % 60) return f"{hours:02d}:{minutes:02d}:{secs:02d}" # training loop X, Y, S = get_batch('train') # fetch the very first batch t0 = time.time() start_time = time.time() # record overall training start time local_iter_num = 0 # number of iterations in the lifetime of this process raw_model = model.module if ddp else model # unwrap DDP container if needed running_mfu = -1.0 accuracy = [] corrects = [] totals = [] def forward_with_aux(idx, targets, state_targets): """Forward that also returns the auxiliary (node, facing) loss computed from the chosen block/layer's output. Branches on model_type: transformer mirrors GPT.forward, gru mirrors GRU.forward for the LM path.""" if model_type == 'gru': h = raw_model.drop(raw_model.embedding(idx)) h_aux = None for i, layer in enumerate(raw_model.layers): h = layer(h) if i == aux_layer: h_aux = h h = raw_model.out_norm(h) logits = raw_model.lm_head(h) else: b, t = idx.size() pos = torch.arange(0, t, dtype=torch.long, device=idx.device).unsqueeze(0) h = raw_model.transformer.drop(raw_model.transformer.wte(idx) + raw_model.transformer.wpe(pos)) h_aux = None for i, block in enumerate(raw_model.transformer.h): h = block(h) if i == aux_layer: h_aux = h h = raw_model.transformer.ln_f(h) logits = raw_model.lm_head(h) lm_loss = F.cross_entropy(logits.view(-1, logits.size(-1)), targets.view(-1), ignore_index=AUX_PAD_ID) aux_logits = aux_head(h_aux) aux_loss = F.cross_entropy(aux_logits.view(-1, AUX_NUM_STATES), state_targets.view(-1), ignore_index=AUX_IGNORE) with torch.no_grad(): mask = state_targets.view(-1) != AUX_IGNORE if mask.any(): pred = aux_logits.view(-1, AUX_NUM_STATES).argmax(-1) aux_acc = (pred[mask] == state_targets.view(-1)[mask]).float().mean() else: aux_acc = torch.zeros((), device=idx.device) return logits, lm_loss, aux_loss, aux_acc # Consolidated training-config summary if master_process: variant_flags = [] if use_nextlat: variant_flags.append('NextLat') if use_post_gru: variant_flags.append('PostGRU') if use_nls: variant_flags.append('NLS') if use_dyadic_attn: variant_flags.append('DyadicAttn') if use_dyadic_hybrid: variant_flags.append('DyadicHybrid') if use_aux: variant_flags.append(f'AuxState{aux_task}(L{aux_layer + 1},λ{aux_lambda})') variant_str = '+'.join(variant_flags) if variant_flags else 'baseline' total_params = sum(p.numel() for p in raw_model.parameters()) print("=" * 70) print("TRAINING CONFIGURATION") print("=" * 70) print(f" Variant : {variant_str}") print(f" Dataset : {dataset} | tasks={tasks_str} | path_type={args.path_type}" f" | num_nodes={num_nodes} | no_task_tag={no_task_tag}") print(f" Model : n_layer={n_layer}, n_head={n_head}, n_embd={n_embd}," f" block_size={block_size}, vocab_size={meta['vocab_size']}, bias={bias}, dropout={dropout}") print(f" Total params : {total_params / 1e6:.2f}M") print(f" Optim : AdamW lr={learning_rate} (min={min_lr}), wd={weight_decay}," f" betas=({beta1},{beta2}), grad_clip={grad_clip}") print(f" Schedule : max_iters={max_iters}, warmup={warmup_iters}," f" decay_iters={lr_decay_iters}, decay_lr={decay_lr}") print(f" Batch / dtype : batch_size={batch_size}, grad_accum={gradient_accumulation_steps}," f" tokens/iter={tokens_per_iter:,}, dtype={dtype}, compile={compile}, ddp={ddp} (world={ddp_world_size})") print(f" Init from : {init_from}" + (f" (iter {init_ckpt})" if init_from == 'resume' else "")) if use_nextlat: print(f" NextLat : horizon={nextlat_horizon}, lambda_h={lambda_h}," f" lambda_kl={lambda_kl}, mlp_hidden_dim={args.mlp_hidden_dim or 2 * n_embd}") if use_post_gru: print(f" PostGRU : per-block GRU enabled") if use_nls: print(f" NLS : per-block Non-Linear prefix Scan enabled") if use_dyadic_attn: recommended_layers = max(1, math.ceil(math.log2(block_size))) if block_size > 1 else 1 warn = '' if n_layer == recommended_layers else f' [WARNING: for fair comparison set n_layer={recommended_layers} (= ceil(log2({block_size})))]' strides = [1 << i for i in range(n_layer)] print(f" DyadicAttn : fixed 0.5/0.5 attention; per-layer strides={strides}{warn}") if use_dyadic_hybrid: L_levels = max(1, math.ceil(math.log2(block_size))) if block_size > 1 else 1 total_blocks = n_layer * (1 + L_levels) unit_strides = [1 << k for k in range(L_levels)] print(f" DyadicHybrid : {n_layer} units of (1 normal + {L_levels} DyadicAttn) = {total_blocks} physical blocks; per-unit dyadic strides={unit_strides}") print(f" Output dir : {out_dir}") print("=" * 70) logger.info(f"TRAINING CONFIG: variant={variant_str}, n_layer={n_layer}, n_head={n_head}," f" n_embd={n_embd}, block_size={block_size}, batch_size={batch_size}," f" max_iters={max_iters}, lr={learning_rate}, params={total_params/1e6:.2f}M") open_and_append(log_file_name, f"TRAINING CONFIG: variant={variant_str}, n_layer={n_layer}, n_head={n_head}," f" n_embd={n_embd}, block_size={block_size}, batch_size={batch_size}," f" max_iters={max_iters}, lr={learning_rate}, params={total_params/1e6:.2f}M") while True: # determine and set the learning rate for this iteration lr = get_lr(iter_num) if decay_lr else learning_rate for param_group in optimizer.param_groups: param_group['lr'] = lr # evaluate the loss on train/val sets and write checkpoints if iter_num % checkpoint_interval == 0 and master_process: losses = None if validation and eval_interval is not None: losses = estimate_loss() print(f"step {iter_num}: train loss {losses['train']:.4f}, val loss {losses['val']:.4f}") logger.info(f"step {iter_num}: train loss {losses['train']:.4f}, val loss {losses['val']:.4f}") open_and_append(log_file_name, f"step {iter_num}: train loss {losses['train']:.4f}, val loss {losses['val']:.4f}") if wandb_log: wandb.log({ "iter": iter_num, "train/loss": losses['train'], "val/loss": losses['val'], "lr": lr, "mfu": running_mfu*100, # convert to percentage }) # Decide whether to save checkpoint save_due_to_val = validation and losses is not None and losses['val'] < best_val_loss save_due_to_policy = always_save_checkpoint if (save_due_to_val or save_due_to_policy) and iter_num > 0: if validation and losses is not None: best_val_loss = min(best_val_loss, losses['val']) checkpoint = { 'model': raw_model.state_dict(), 'optimizer': optimizer.state_dict(), 'model_args': model_args, 'model_type': model_type, 'iter_num': iter_num, 'best_val_loss': best_val_loss, 'config': config, 'scaler': scaler.state_dict(), 'torch_rng_state': torch.get_rng_state(), 'cuda_rng_state': torch.cuda.get_rng_state() if torch.cuda.is_available() else None, 'numpy_rng_state': np.random.get_state(), } if use_aux: checkpoint['aux_head'] = aux_head.state_dict() checkpoint['aux_layer'] = aux_layer checkpoint['aux_lambda'] = aux_lambda print(f"saving checkpoint to {out_dir} (validation={'on' if validation else 'off'})") logger.info(f"saving checkpoint to {out_dir}") open_and_append(log_file_name, f"saving checkpoint to {out_dir}") if multitasks: torch.save(checkpoint, os.path.join(out_dir, f'{iter_num}_ckpt_maze_{tasks_tag}_{train_label}.pt')) elif num_of_paths == 0: torch.save(checkpoint, os.path.join(out_dir, f'{iter_num}_ckpt_maze.pt')) else: torch.save(checkpoint, os.path.join(out_dir, f'{iter_num}_ckpt_maze_{num_of_paths}.pt')) # if iter_num % test_interval == 0 and master_process: # correct, tot = test_model() # corrects.append(correct) # totals.append(tot) if iter_num == 0 and eval_only: break # forward backward update, with optional gradient accumulation to simulate larger batch size # and using the GradScaler if data type is float16 for micro_step in range(gradient_accumulation_steps): if ddp: model.require_backward_grad_sync = (micro_step == gradient_accumulation_steps - 1) with ctx: if use_aux: logits, lm_loss, aux_loss, aux_acc = forward_with_aux(X, Y, S) loss = (lm_loss + aux_lambda * aux_loss) / gradient_accumulation_steps elif use_nextlat: total_loss, loss_nt, loss_nh, loss_kl = raw_model.forward_nextlat( X, Y, horizon=nextlat_horizon, lambda_h=lambda_h, lambda_kl=lambda_kl) loss = total_loss / gradient_accumulation_steps else: logits, loss = model(X, Y) loss = loss / gradient_accumulation_steps # scale the loss to account for gradient accumulation X, Y, S = get_batch('train') # backward pass, with gradient scaling if training in fp16 scaler.scale(loss).backward() # clip the gradient if grad_clip != 0.0: scaler.unscale_(optimizer) clip_params = list(model.parameters()) + (list(aux_head.parameters()) if use_aux else []) torch.nn.utils.clip_grad_norm_(clip_params, grad_clip) scaler.step(optimizer) scaler.update() optimizer.zero_grad(set_to_none=True) # timing and logging t1 = time.time() dt = t1 - t0 t0 = t1 if iter_num % log_interval == 0 and master_process: lossf = loss.item() * gradient_accumulation_steps if local_iter_num >= 5: # let the training loop settle a bit mfu = raw_model.estimate_mfu(batch_size * gradient_accumulation_steps, dt) running_mfu = mfu if running_mfu == -1.0 else 0.9*running_mfu + 0.1*mfu # Compute elapsed and estimated remaining time elapsed = time.time() - start_time if iter_num > 0: eta = (elapsed / iter_num) * (max_iters - iter_num) elapsed_str = format_time(elapsed) eta_str = format_time(eta) time_info = f"elapsed {elapsed_str}, eta {eta_str}" else: time_info = "elapsed 00:00:00, eta --:--:--" if use_nextlat: print(f"iter {iter_num}: loss {lossf:.4f} (nt={loss_nt.item():.4f}, nh={loss_nh.item():.4f}, kl={loss_kl.item():.4f}), time {dt*1000:.2f}ms, mfu {running_mfu*100:.2f}%, {time_info}") elif use_aux: print(f"iter {iter_num}: loss {lossf:.4f} (lm={lm_loss.item():.4f}, aux={aux_loss.item():.4f}, aux_acc={aux_acc.item()*100:.1f}%), time {dt*1000:.2f}ms, mfu {running_mfu*100:.2f}%, {time_info}") else: print(f"iter {iter_num}: loss {lossf:.4f}, time {dt*1000:.2f}ms, mfu {running_mfu*100:.2f}%, {time_info}") logger.info(f"iter {iter_num}: loss {lossf:.4f}") open_and_append(log_file_name, f"iter {iter_num}: loss {lossf:.4f}") iter_num += 1 local_iter_num += 1 if iter_num > max_iters: break torch.save(torch.tensor(corrects).cpu(), os.path.join(out_dir, f'corrects_maze.pt')) torch.save(torch.tensor(totals).cpu(), os.path.join(out_dir, f'totals_maze.pt')) # Final total training time summary if master_process: total_elapsed = time.time() - start_time total_str = format_time(total_elapsed) avg_iter_ms = (total_elapsed / max(1, iter_num)) * 1000 summary = (f"Total training time: {total_str} ({total_elapsed:.1f}s) " f"over {iter_num} iters, avg {avg_iter_ms:.2f} ms/iter") print(summary) logger.info(summary) open_and_append(log_file_name, summary) if ddp: destroy_process_group()