| from __future__ import annotations |
|
|
| import hashlib |
| import os |
| from collections import OrderedDict |
| from pathlib import Path |
| from typing import Any, Sequence |
|
|
| import numpy as np |
| import pandas as pd |
| import rasterio |
| from rasterio.windows import Window |
| import torch |
| from torch.utils.data import Dataset |
| from tqdm import tqdm |
| import xarray as xr |
| import yaml |
| import zarr |
|
|
| from .grid_utils import ( |
| MISSING_TEXT_VALUES, |
| _GridParams, |
| _build_land_mask_patch_table, |
| _center_lon_deg, |
| _deep_update_config, |
| _force_include_cache_hash, |
| _normalize_lon, |
| _parse_date_int, |
| _parse_force_include_regions, |
| _path_cache_hash, |
| _sanitize_cache_text, |
| _validate_grid_params, |
| ) |
| from .normalizations import ( |
| CELSIUS_TO_KELVIN_OFFSET, |
| salinity_normalize, |
| temperature_normalize, |
| ) |
|
|
| VALID_CODE_MAX = 254.0 |
| NODATA_CODE = 255 |
| DEFAULT_ACCEPTED_ARGO_QC_FLAGS = (1, 2) |
| ARGO_LEVEL_QC_VARS = { |
| "depth": "argo_depth_qc_on_glorys_depth", |
| "temp": "argo_temp_qc_on_glorys_depth", |
| "psal": "argo_psal_qc_on_glorys_depth", |
| } |
| ARGO_PROFILE_QC_VARS = { |
| "juld": "argo_juld_qc", |
| "position": "argo_position_qc", |
| "profile_depth": "argo_profile_depth_qc", |
| "profile_potm": "argo_profile_potm_qc", |
| "profile_psal": "argo_profile_psal_qc", |
| } |
| COMPACT_PROFILE_QC_VARS = { |
| "temp": "argo_temp_profile_qc", |
| "psal": "argo_psal_profile_qc", |
| } |
|
|
|
|
| def _decode_stretched_uint8(values: np.ndarray, stretch: dict[str, Any]) -> np.ndarray: |
| """Decode uint8 GeoTIFF values into physical units from manifest metadata.""" |
| arr = np.asarray(values, dtype=np.uint8) |
| nodata = int(stretch.get("nodata", NODATA_CODE)) |
| valid_code_max = float(stretch.get("valid_code_max", VALID_CODE_MAX)) |
| minimum = np.float32(stretch["minimum"]) |
| maximum = np.float32(stretch["maximum"]) |
| out = np.full(arr.shape, np.nan, dtype=np.float32) |
| valid = arr != nodata |
| out[valid] = minimum + ( |
| arr[valid].astype(np.float32) |
| / np.float32(valid_code_max) |
| * np.float32(maximum - minimum) |
| ) |
| return out |
|
|
|
|
| def _kelvin_to_celsius(values: np.ndarray) -> np.ndarray: |
| """Convert decoded Kelvin temperature values to Celsius for model normalization.""" |
| return np.asarray(values, dtype=np.float32) - np.float32(CELSIUS_TO_KELVIN_OFFSET) |
|
|
|
|
| def _resolve_manifest_path(root_dir: Path, raw_path: str | Path) -> Path: |
| """Resolve a manifest path that may be absolute or export-root relative.""" |
| path = Path(raw_path) |
| if path.is_absolute(): |
| return path |
| return root_dir / path |
|
|
|
|
| def _resolve_land_mask_path(root_dir: Path, raw_path: str | Path) -> Path: |
| """Resolve a land-mask path inside the packaged GeoTIFF dataset root.""" |
| export_path = _resolve_manifest_path(root_dir, raw_path) |
| if not export_path.exists(): |
| raise FileNotFoundError( |
| "Land-mask GeoTIFF must be present in the packaged dataset layout: " |
| f"{export_path}" |
| ) |
| return export_path |
|
|
|
|
| def _records_by_date( |
| entries: Sequence[dict[str, Any]], root_dir: Path |
| ) -> dict[int, Path]: |
| """Map manifest raster entries by date.""" |
| records: dict[int, Path] = {} |
| for entry in entries: |
| records[int(entry["date"])] = _resolve_manifest_path(root_dir, entry["path"]) |
| return records |
|
|
|
|
| def _date_signature(dates: Sequence[int]) -> str: |
| """Return a compact hashable date coverage signature.""" |
| if not dates: |
| return "empty" |
| raw = (int(min(dates)), int(max(dates)), int(len(dates))) |
| return "-".join(str(value) for value in raw) |
|
|
|
|
| class RasterDatasetCache: |
| """Small LRU cache for rasterio datasets opened by one worker process.""" |
|
|
| def __init__(self, max_open: int = 8) -> None: |
| """Initialize a bounded raster path cache.""" |
| self.max_open = int(max_open) |
| self._pid = os.getpid() |
| self._items: OrderedDict[Path, rasterio.io.DatasetReader] = OrderedDict() |
|
|
| def _ensure_current_process(self) -> None: |
| """Drop inherited file handles after DataLoader worker forks.""" |
| pid = os.getpid() |
| if pid == self._pid: |
| return |
| self.close() |
| self._pid = pid |
|
|
| def get(self, path: Path) -> rasterio.io.DatasetReader: |
| """Return an opened raster dataset for ``path``.""" |
| self._ensure_current_process() |
| path = Path(path) |
| if path in self._items: |
| src = self._items.pop(path) |
| self._items[path] = src |
| return src |
| src = rasterio.open(path) |
| self._items[path] = src |
| while len(self._items) > self.max_open: |
| _, old = self._items.popitem(last=False) |
| old.close() |
| return src |
|
|
| def close(self) -> None: |
| """Close all cached raster datasets.""" |
| for src in self._items.values(): |
| src.close() |
| self._items.clear() |
|
|
|
|
| class GeoTIFFRasterStore: |
| """Date-indexed GeoTIFF raster source for one exported variable.""" |
|
|
| def __init__( |
| self, |
| *, |
| paths_by_date: dict[int, Path], |
| stretch: dict[str, Any], |
| cache: RasterDatasetCache, |
| kelvin_temperature: bool, |
| ) -> None: |
| """Initialize a date-to-raster lookup.""" |
| self.paths_by_date = dict(paths_by_date) |
| self.stretch = dict(stretch) |
| self.cache = cache |
| self.kelvin_temperature = bool(kelvin_temperature) |
|
|
| @property |
| def dates(self) -> set[int]: |
| """Return available YYYYMMDD dates.""" |
| return set(int(value) for value in self.paths_by_date) |
|
|
| def read_patch( |
| self, |
| *, |
| target_date: int, |
| grid_y0: int, |
| grid_x0: int, |
| tile_size: int, |
| ) -> np.ndarray: |
| """Read and decode one patch for ``target_date``.""" |
| path = self.paths_by_date[int(target_date)] |
| src = self.cache.get(path) |
| window = Window( |
| col_off=int(grid_x0), |
| row_off=int(grid_y0), |
| width=int(tile_size), |
| height=int(tile_size), |
| ) |
| encoded = src.read(window=window) |
| decoded = _decode_stretched_uint8(encoded, self.stretch) |
| if self.kelvin_temperature: |
| decoded = _kelvin_to_celsius(decoded) |
| return decoded.astype(np.float32, copy=False) |
|
|
|
|
| def _normalize_accepted_qc_flags(values: Sequence[int] | None) -> tuple[int, ...]: |
| """Return accepted ARGO QC flags as small integer codes.""" |
| if values is None: |
| return DEFAULT_ACCEPTED_ARGO_QC_FLAGS |
| flags = tuple(sorted({int(value) for value in values})) |
| if not flags: |
| raise ValueError("accepted_argo_qc_flags must contain at least one code.") |
| return flags |
|
|
|
|
| class ArgoGeoTIFFProfileStore: |
| """Profile-indexed ARGO zarr source exported with the GeoTIFF dataset.""" |
|
|
| def __init__( |
| self, |
| path: str | Path, |
| *, |
| include_salinity: bool = False, |
| filter_bad_quality: bool = True, |
| accepted_qc_flags: Sequence[int] | None = None, |
| ) -> None: |
| """Open a compact ARGO profile zarr store.""" |
| self.path = Path(path) |
| if not self.path.exists(): |
| raise FileNotFoundError(f"ARGO profile zarr does not exist: {self.path}") |
| self.include_salinity = bool(include_salinity) |
| self.filter_bad_quality = bool(filter_bad_quality) |
| self.accepted_qc_flags = _normalize_accepted_qc_flags(accepted_qc_flags) |
| self._pid = os.getpid() |
| self.ds = self._open_dataset() |
| self._zarr_pid = os.getpid() |
| self._zarr_group = self._open_zarr_group() |
| required = { |
| "target_date", |
| "grid_row", |
| "grid_col", |
| "argo_temp_kelvin_uint8", |
| "argo_temp_valid", |
| } |
| if self.include_salinity: |
| required.update({"argo_psal_uint8", "argo_psal_valid"}) |
| missing = sorted(name for name in required if name not in self.ds) |
| if missing: |
| raise RuntimeError( |
| f"ARGO profile zarr is missing required variables {missing}: {self.path}" |
| ) |
| self.target_date = np.asarray(self.ds["target_date"].values, dtype=np.int32) |
| self.grid_row = np.asarray(self.ds["grid_row"].values, dtype=np.int32) |
| self.grid_col = np.asarray(self.ds["grid_col"].values, dtype=np.int32) |
| self.depth_axis_m = np.asarray( |
| self.ds["glorys_depth"].values, dtype=np.float32 |
| ).reshape(-1) |
| temp_valid = np.asarray(self.ds["argo_temp_valid"].values, dtype=bool) |
| if self.filter_bad_quality: |
| temp_valid &= self._quality_mask_for_variable("temp") |
| self._has_valid_temp = temp_valid.any(axis=1) |
| ( |
| self._valid_profile_indices_by_date, |
| self._profile_index_bounds_by_date, |
| ) = self._build_valid_profile_index() |
| self.temperature_stretch = self._temperature_stretch() |
| self.salinity_stretch = ( |
| self._salinity_stretch() if self.include_salinity else None |
| ) |
|
|
| def _open_dataset(self) -> xr.Dataset: |
| """Open the zarr dataset in the current process.""" |
| return xr.open_zarr(self.path, consolidated=None) |
|
|
| def _open_zarr_group(self) -> zarr.Group: |
| """Open the zarr group used for direct array reads.""" |
| return zarr.open_group(self.path, mode="r") |
|
|
| def _ensure_current_process(self) -> xr.Dataset: |
| """Reopen zarr handles after DataLoader worker forks.""" |
| pid = os.getpid() |
| if pid == self._pid: |
| return self.ds |
| |
| |
| self.ds = self._open_dataset() |
| self._pid = pid |
| return self.ds |
|
|
| def _ensure_zarr_group(self) -> zarr.Group: |
| """Return a direct zarr group opened in the current process.""" |
| pid = os.getpid() |
| if pid != self._zarr_pid: |
| self._zarr_group = self._open_zarr_group() |
| self._zarr_pid = pid |
| return self._zarr_group |
|
|
| def _accepted_qc_mask(self, values: np.ndarray) -> np.ndarray: |
| """Return True where QC is missing or one of the accepted flags.""" |
| qc = np.asarray(values, dtype=np.int16) |
| missing = qc < 0 |
| accepted = np.isin(qc, np.asarray(self.accepted_qc_flags, dtype=np.int16)) |
| return missing | accepted |
|
|
| def _profile_qc_names_for_variable(self, variable: str) -> tuple[str, ...]: |
| """Return profile-level QC variables relevant to one ARGO variable.""" |
| names = ["juld", "position", "profile_depth"] |
| if variable == "psal": |
| names.append("profile_psal") |
| return tuple(ARGO_PROFILE_QC_VARS[name] for name in names) |
|
|
| def _level_qc_names_for_variable(self, variable: str) -> tuple[str, ...]: |
| """Return level-level QC variables relevant to one ARGO variable.""" |
| if variable == "psal": |
| return (ARGO_LEVEL_QC_VARS["depth"], ARGO_LEVEL_QC_VARS["psal"]) |
| return (ARGO_LEVEL_QC_VARS["depth"], ARGO_LEVEL_QC_VARS["temp"]) |
|
|
| def _quality_mask_for_variable( |
| self, |
| variable: str, |
| *, |
| indices: np.ndarray | None = None, |
| ) -> np.ndarray: |
| """Return a profile-depth quality mask for one compact ARGO variable.""" |
| if indices is None: |
| profile_count = int(self.target_date.size) |
| mask = np.ones((profile_count, int(self.depth_axis_m.size)), dtype=bool) |
| indexer: Any = slice(None) |
| else: |
| selected = np.asarray(indices, dtype=np.int64).reshape(-1) |
| mask = np.ones( |
| (int(selected.size), int(self.depth_axis_m.size)), dtype=bool |
| ) |
| indexer = selected |
| ds = self._ensure_current_process() |
| compact_name = COMPACT_PROFILE_QC_VARS.get(variable) |
| if compact_name in ds: |
| qc = np.asarray(ds[compact_name].isel(profile=indexer).values).reshape(-1) |
| return mask & self._accepted_qc_mask(qc)[:, None] |
| for name in self._level_qc_names_for_variable(variable): |
| if name not in ds: |
| continue |
| qc = np.asarray(ds[name].isel(profile=indexer).values) |
| mask &= self._accepted_qc_mask(qc) |
| for name in self._profile_qc_names_for_variable(variable): |
| if name not in ds: |
| continue |
| qc = np.asarray(ds[name].isel(profile=indexer).values).reshape(-1) |
| |
| mask &= self._accepted_qc_mask(qc)[:, None] |
| return mask |
|
|
| def _build_valid_profile_index( |
| self, |
| ) -> tuple[np.ndarray, dict[int, tuple[int, int]]]: |
| """Build date slices over valid-temperature profile indices.""" |
| valid_indices = np.flatnonzero(self._has_valid_temp).astype(np.int64) |
| if valid_indices.size == 0: |
| return valid_indices, {} |
|
|
| |
| order = np.argsort(self.target_date[valid_indices], kind="stable") |
| sorted_indices = valid_indices[order] |
| sorted_dates = self.target_date[sorted_indices] |
| unique_dates, starts, counts = np.unique( |
| sorted_dates, return_index=True, return_counts=True |
| ) |
| bounds = { |
| int(date): (int(start), int(start + count)) |
| for date, start, count in zip( |
| unique_dates.tolist(), |
| starts.tolist(), |
| counts.tolist(), |
| strict=False, |
| ) |
| } |
| return sorted_indices, bounds |
|
|
| def _temperature_stretch(self) -> dict[str, Any]: |
| """Read temperature stretch metadata from variable or dataset attributes.""" |
| ds = self._ensure_current_process() |
| attrs = dict(ds["argo_temp_kelvin_uint8"].attrs) |
| if "minimum" in attrs and "maximum" in attrs: |
| return attrs |
| ds_attrs = dict(ds.attrs) |
| stretch = ds_attrs.get("temperature_stretch") |
| if isinstance(stretch, dict): |
| return stretch |
| raise RuntimeError( |
| f"ARGO profile zarr lacks temperature stretch metadata: {self.path}" |
| ) |
|
|
| def _salinity_stretch(self) -> dict[str, Any]: |
| """Read salinity stretch metadata from variable or dataset attributes.""" |
| ds = self._ensure_current_process() |
| attrs = dict(ds["argo_psal_uint8"].attrs) |
| if "minimum" in attrs and "maximum" in attrs: |
| return attrs |
| ds_attrs = dict(ds.attrs) |
| stretch = ds_attrs.get("salinity_stretch") |
| if isinstance(stretch, dict): |
| return stretch |
| raise RuntimeError( |
| f"ARGO profile zarr lacks salinity stretch metadata: {self.path}" |
| ) |
|
|
| def query_indices( |
| self, |
| *, |
| target_date: int, |
| grid_y0: int, |
| grid_x0: int, |
| tile_size: int, |
| ) -> np.ndarray: |
| """Return profile indices assigned to one date and grid patch.""" |
| y0 = int(grid_y0) |
| x0 = int(grid_x0) |
| tile = int(tile_size) |
| bounds = self._profile_index_bounds_by_date.get(int(target_date)) |
| if bounds is None: |
| return np.zeros((0,), dtype=np.int64) |
| start, stop = bounds |
| candidates = self._valid_profile_indices_by_date[start:stop] |
| mask = ( |
| (self.grid_row[candidates] >= y0) |
| & (self.grid_row[candidates] < y0 + tile) |
| & (self.grid_col[candidates] >= x0) |
| & (self.grid_col[candidates] < x0 + tile) |
| ) |
| return candidates[mask].astype(np.int64, copy=False) |
|
|
| def load_temperature_profiles(self, indices: np.ndarray) -> np.ndarray: |
| """Load selected ARGO temperature profiles as Celsius arrays.""" |
| indices = np.asarray(indices, dtype=np.int64).reshape(-1) |
| depth_size = int(self.depth_axis_m.size) |
| if indices.size == 0: |
| return np.zeros((0, depth_size), dtype=np.float32) |
| group = self._ensure_zarr_group() |
| encoded = np.asarray( |
| group["argo_temp_kelvin_uint8"].get_orthogonal_selection( |
| (indices, slice(None)) |
| ), |
| dtype=np.uint8, |
| ) |
| valid = np.asarray( |
| group["argo_temp_valid"].get_orthogonal_selection((indices, slice(None))), |
| dtype=bool, |
| ) |
| if self.filter_bad_quality: |
| valid &= self._quality_mask_for_variable("temp", indices=indices) |
| kelvin = _decode_stretched_uint8(encoded, self.temperature_stretch) |
| kelvin[~valid] = np.nan |
| return _kelvin_to_celsius(kelvin).astype(np.float32, copy=False) |
|
|
| def load_salinity_profiles(self, indices: np.ndarray) -> np.ndarray: |
| """Load selected ARGO salinity profiles as raw PSU arrays.""" |
| if self.salinity_stretch is None: |
| raise RuntimeError( |
| "ARGO salinity profiles were not enabled for this store." |
| ) |
| indices = np.asarray(indices, dtype=np.int64).reshape(-1) |
| depth_size = int(self.depth_axis_m.size) |
| if indices.size == 0: |
| return np.zeros((0, depth_size), dtype=np.float32) |
| group = self._ensure_zarr_group() |
| encoded = np.asarray( |
| group["argo_psal_uint8"].get_orthogonal_selection((indices, slice(None))), |
| dtype=np.uint8, |
| ) |
| valid = np.asarray( |
| group["argo_psal_valid"].get_orthogonal_selection((indices, slice(None))), |
| dtype=bool, |
| ) |
| if self.filter_bad_quality: |
| valid &= self._quality_mask_for_variable("psal", indices=indices) |
| salinity = _decode_stretched_uint8(encoded, self.salinity_stretch) |
| salinity[~valid] = np.nan |
| return salinity.astype(np.float32, copy=False) |
|
|
| def quality_cache_signature(self) -> str: |
| """Return the ARGO quality-filter settings that affect support counts.""" |
| marker_text = "markers-" + "-".join( |
| name for name in COMPACT_PROFILE_QC_VARS.values() if name in self.ds |
| ) |
| flags_text = "-".join(str(value) for value in self.accepted_qc_flags) |
| return _sanitize_cache_text( |
| f"filter{int(self.filter_bad_quality)}_flags{flags_text}_{marker_text}" |
| ) |
|
|
| def close(self) -> None: |
| """Close the opened zarr dataset.""" |
| self.ds.close() |
|
|
|
|
| class GeoTIFFPatchIndex: |
| """Build compact patch/date metadata rows for GeoTIFF training stores.""" |
|
|
| CACHE_VERSION = 3 |
|
|
| def __init__( |
| self, |
| *, |
| root_dir: Path, |
| dates: Sequence[int], |
| argo_store: ArgoGeoTIFFProfileStore | None, |
| cache_dir: str | Path | None, |
| grid_params: _GridParams, |
| ) -> None: |
| """Initialize index inputs.""" |
| self.root_dir = Path(root_dir) |
| self.dates = sorted(int(value) for value in dates) |
| self.argo_store = argo_store |
| self.cache_dir = None if cache_dir is None else Path(cache_dir) |
| self.grid_params = grid_params |
| _validate_grid_params(self.grid_params) |
| if str(self.grid_params.patch_grid_source).strip().lower() != "land_mask": |
| raise ValueError( |
| "GeoTIFF datasets require grid.patch_grid_source='land_mask'." |
| ) |
|
|
| def load_rows(self) -> list[dict[str, Any]]: |
| """Load cached rows or build a fresh patch/date registry.""" |
| cache_path = self._cache_path() |
| if cache_path is not None and cache_path.exists(): |
| return pd.read_csv(cache_path).to_dict(orient="records") |
|
|
| patch_df = _build_land_mask_patch_table(self.grid_params) |
| if self.grid_params.val_year is None: |
| patch_records = patch_df.to_dict(orient="records") |
| phases = self._split_phases(len(patch_records)) |
| for rec, phase in zip(patch_records, phases, strict=False): |
| rec["split"] = phase |
| rec["phase"] = phase |
| patch_df = pd.DataFrame.from_records(patch_records) |
| support_counts = self._build_support_counts(patch_df) |
| rows: list[dict[str, Any]] = [] |
| export_index = 0 |
| for date_value in self.dates: |
| for patch in patch_df.to_dict(orient="records"): |
| patch_id = int(patch["patch_id"]) |
| row = dict(patch) |
| row["date"] = int(date_value) |
| row["export_index"] = int(export_index) |
| if self.grid_params.val_year is not None: |
| phase = self._phase_for_date(int(date_value)) |
| row["split"] = phase |
| row["phase"] = phase |
| else: |
| phase = str(patch.get("split", patch.get("phase", "train"))) |
| row["split"] = phase |
| row["phase"] = phase |
| row["argo_profile_count"] = int( |
| support_counts.get((patch_id, int(date_value)), 0) |
| ) |
| rows.append(row) |
| export_index += 1 |
|
|
| if cache_path is not None: |
| cache_path.parent.mkdir(parents=True, exist_ok=True) |
| pd.DataFrame.from_records(rows).to_csv(cache_path, index=False) |
| return rows |
|
|
| def _cache_path(self) -> Path | None: |
| """Return the metadata cache path for these index settings.""" |
| if self.cache_dir is None: |
| return None |
| res_text = str(float(self.grid_params.resolution_deg)).replace(".", "p") |
| land_text = str(float(self.grid_params.max_land_fraction)).replace(".", "p") |
| grid_source = _sanitize_cache_text(self.grid_params.patch_grid_source) |
| mask_hash = _path_cache_hash(self.grid_params.land_mask_path) |
| force_hash = _force_include_cache_hash(self.grid_params.force_include_regions) |
| root_hash = hashlib.sha1(str(self.root_dir).encode("utf-8")).hexdigest()[:8] |
| split_text = ( |
| f"valyear{int(self.grid_params.val_year)}" |
| if self.grid_params.val_year is not None |
| else "patchsplit" |
| ) |
| argo_quality_text = ( |
| "noargo" |
| if self.argo_store is None |
| else self.argo_store.quality_cache_signature() |
| ) |
| name = ( |
| f"argo_geotiff_gridded_v{self.CACHE_VERSION}_root{root_hash}_" |
| f"dates{_date_signature(self.dates)}_" |
| f"tile{int(self.grid_params.tile_size)}_res{res_text}_" |
| f"stride{int(self.grid_params.effective_patch_stride)}_" |
| f"grid{grid_source}_land{land_text}_mask{mask_hash}_" |
| f"force{force_hash}_{split_text}_argo{argo_quality_text}.csv" |
| ) |
| return self.cache_dir / name |
|
|
| def _phase_for_date(self, date_value: int) -> str: |
| """Return the train/validation phase for one date.""" |
| year = int(date_value) // 10000 |
| return "val" if year == int(self.grid_params.val_year) else "train" |
|
|
| def _split_phases(self, n_patches: int) -> list[str]: |
| """Return deterministic spatial train/validation phases.""" |
| phases = np.full((int(n_patches),), "train", dtype=object) |
| val_len = int(round(int(n_patches) * float(self.grid_params.val_fraction))) |
| if n_patches > 1: |
| val_len = min( |
| max(val_len, 1 if self.grid_params.val_fraction > 0.0 else 0), |
| int(n_patches) - 1, |
| ) |
| else: |
| val_len = 0 |
| if val_len > 0: |
| rng = np.random.default_rng(int(self.grid_params.split_seed)) |
| val_indices = rng.permutation(np.arange(int(n_patches)))[:val_len] |
| phases[val_indices] = "val" |
| return [str(value) for value in phases.tolist()] |
|
|
| def _build_support_counts( |
| self, |
| patch_df: pd.DataFrame, |
| ) -> dict[tuple[int, int], int]: |
| """Count ARGO profiles per overlapping patch/date row.""" |
| support_counts: dict[tuple[int, int], int] = {} |
| if self.argo_store is None or patch_df.empty or not self.dates: |
| return support_counts |
|
|
| date_set = set(int(value) for value in self.dates) |
| tile = int(self.grid_params.tile_size) |
| patch_by_start = { |
| (int(row["grid_y0"]), int(row["grid_x0"])): int(row["patch_id"]) |
| for row in patch_df.to_dict(orient="records") |
| } |
| y_starts = np.asarray( |
| sorted({key[0] for key in patch_by_start}), dtype=np.int64 |
| ) |
| x_starts = np.asarray( |
| sorted({key[1] for key in patch_by_start}), dtype=np.int64 |
| ) |
| selected_profile_indices: list[np.ndarray] = [] |
| for date_value in sorted(date_set): |
| bounds = self.argo_store._profile_index_bounds_by_date.get(int(date_value)) |
| if bounds is None: |
| continue |
| start, stop = bounds |
| selected_profile_indices.append( |
| self.argo_store._valid_profile_indices_by_date[start:stop] |
| ) |
| if not selected_profile_indices: |
| return support_counts |
| profile_indices = np.concatenate(selected_profile_indices).astype( |
| np.int64, |
| copy=False, |
| ) |
|
|
| for profile_idx in tqdm( |
| profile_indices.tolist(), |
| total=int(profile_indices.size), |
| desc="Counting ARGO overlap support", |
| unit="profile", |
| dynamic_ncols=True, |
| ): |
| date_value = int(self.argo_store.target_date[profile_idx]) |
| row_idx = int(self.argo_store.grid_row[profile_idx]) |
| col_idx = int(self.argo_store.grid_col[profile_idx]) |
| y_candidates = y_starts[(y_starts <= row_idx) & (row_idx < y_starts + tile)] |
| x_candidates = x_starts[(x_starts <= col_idx) & (col_idx < x_starts + tile)] |
| for y0 in y_candidates.tolist(): |
| for x0 in x_candidates.tolist(): |
| patch_id = patch_by_start.get((int(y0), int(x0))) |
| if patch_id is None: |
| continue |
| key = (int(patch_id), int(date_value)) |
| support_counts[key] = support_counts.get(key, 0) + 1 |
| return support_counts |
|
|
|
|
| DEFAULT_DATASET_ROOT_DIR = Path(__file__).resolve().parents[1] |
| DEFAULT_GEOTIFF_ROOT_DIR = DEFAULT_DATASET_ROOT_DIR.as_posix() |
| DEFAULT_METADATA_CACHE_DIR = (DEFAULT_DATASET_ROOT_DIR / "depthdif_cache").as_posix() |
| DEFAULT_CONFIG_PATH = ( |
| Path(__file__).resolve().parent / "configs/default_dataset.yaml" |
| ).as_posix() |
| DEFAULT_LAND_MASK_RELATIVE_PATH = "masks/world_land_mask_glorys_0p1.tif" |
| EO_SOURCE_DEFAULTS = {"ostia": "analysed_sst", "sss": "sos"} |
| EO_STRETCH_BY_SOURCE_VAR = { |
| ("ostia", "analysed_sst"): ("temperature_kelvin", "temperature"), |
| ("sss", "sos"): ("salinity", "salinity"), |
| } |
|
|
|
|
| class ArgoGeoTIFFGriddedPatchDataset(Dataset): |
| """Dataset that lazily reads training patches from exported GeoTIFF stores.""" |
|
|
| DEFAULT_CONFIG_PATH = DEFAULT_CONFIG_PATH |
| DEFAULT_GEOTIFF_ROOT_DIR = DEFAULT_DATASET_ROOT_DIR.as_posix() |
| DEFAULT_METADATA_CACHE_DIR = ( |
| DEFAULT_DATASET_ROOT_DIR / "depthdif_cache" |
| ).as_posix() |
|
|
| def __init__( |
| self, |
| *, |
| geotiff_root_dir: str | Path = DEFAULT_GEOTIFF_ROOT_DIR, |
| metadata_cache_dir: str | Path | None = DEFAULT_METADATA_CACHE_DIR, |
| split: str = "all", |
| tile_size: int = 128, |
| resolution_deg: float = 0.1, |
| patch_grid_source: str = "land_mask", |
| land_mask_path: str | Path | None = None, |
| patch_stride: int | None = None, |
| max_land_fraction: float = 0.30, |
| force_include_regions: Sequence[dict[str, Any]] | None = None, |
| finetune_sampling: dict[str, Any] | None = None, |
| temporal_window_days: int = 7, |
| glorys_var_name: str = "thetao", |
| ostia_var_name: str = "analysed_sst", |
| eo_source: str = "ostia", |
| eo_var_name: str | None = None, |
| require_argo_for_train: bool = True, |
| require_argo_for_val: bool = True, |
| require_argo_for_all: bool = False, |
| synthetic_mode: bool = False, |
| synthetic_pixel_count: int = 250, |
| return_info: bool = True, |
| return_coords: bool = True, |
| include_salinity: bool = False, |
| output_fields: Sequence[str] | str | None = None, |
| date_start: int | str | None = None, |
| date_end: int | str | None = None, |
| max_dates: int | None = None, |
| count_argo_support: bool | None = None, |
| random_seed: int = 7, |
| cache_size: int = 8, |
| val_fraction: float = 0.2, |
| val_year: int | None = None, |
| filter_bad_argo_quality: bool = True, |
| accepted_argo_qc_flags: Sequence[int] | None = None, |
| ) -> None: |
| """Initialize the GeoTIFF-backed patch dataset.""" |
| self.split = str(split).strip().lower() |
| if self.split not in {"all", "train", "val"}: |
| raise ValueError("split must be one of: 'all', 'train', 'val'") |
| self.root_dir = Path(geotiff_root_dir) |
| self.manifest_path = self.root_dir / "manifest.yaml" |
| if not self.manifest_path.exists(): |
| raise FileNotFoundError( |
| f"GeoTIFF manifest does not exist: {self.manifest_path}" |
| ) |
| with self.manifest_path.open("r", encoding="utf-8") as f: |
| self.manifest = yaml.safe_load(f) |
|
|
| self.tile_size = int(tile_size) |
| self.resolution_deg = float(resolution_deg) |
| self.patch_grid_source = str(patch_grid_source) |
| manifest_grid = self.manifest.get("grid", {}) |
| configured_land_mask = ( |
| land_mask_path |
| or manifest_grid.get("source") |
| or DEFAULT_LAND_MASK_RELATIVE_PATH |
| ) |
| self.land_mask_path = _resolve_land_mask_path( |
| self.root_dir, |
| configured_land_mask, |
| ) |
| self.patch_stride = None if patch_stride is None else int(patch_stride) |
| self.max_land_fraction = float(max_land_fraction) |
| self.force_include_regions = _parse_force_include_regions(force_include_regions) |
| self.finetune_sampling = self._normalize_finetune_sampling(finetune_sampling) |
| self.finetune_sampling_summary: dict[str, Any] = { |
| "enabled": bool(self.finetune_sampling["enabled"]), |
| "applied": False, |
| "split": self.split, |
| } |
| self.temporal_window_days = int(temporal_window_days) |
| self.glorys_var_name = str(glorys_var_name) |
| self.ostia_var_name = str(ostia_var_name) |
| self.eo_source, self.eo_var_name = self._normalize_eo_selection( |
| eo_source=eo_source, |
| eo_var_name=eo_var_name, |
| ostia_var_name=self.ostia_var_name, |
| ) |
| self.eo_stretch_name, self.eo_normalization = self._resolve_eo_metadata( |
| self.eo_source, self.eo_var_name |
| ) |
| self.return_info = bool(return_info) |
| self.return_coords = bool(return_coords) |
| self.output_fields = self._normalize_output_fields( |
| output_fields, include_salinity=bool(include_salinity) |
| ) |
| self.include_salinity = "salinity" in self.output_fields |
| self._loads_temperature = "temperature" in self.output_fields |
| self.random_seed = int(random_seed) |
| self.require_argo_for_train = bool(require_argo_for_train) |
| self.require_argo_for_val = bool(require_argo_for_val) |
| self.require_argo_for_all = bool(require_argo_for_all) |
| self.synthetic_mode = bool(synthetic_mode) |
| self.synthetic_pixel_count = int(synthetic_pixel_count) |
| self.filter_bad_argo_quality = bool(filter_bad_argo_quality) |
| self.accepted_argo_qc_flags = _normalize_accepted_qc_flags( |
| accepted_argo_qc_flags |
| ) |
| self.date_start = self._optional_int(date_start) |
| self.date_end = self._optional_int(date_end) |
| self.max_dates = None if max_dates is None else int(max_dates) |
| if self.temporal_window_days < 1: |
| raise ValueError("sampling.temporal_window_days must be >= 1.") |
| if self.synthetic_pixel_count < 0: |
| raise ValueError("synthetic.pixel_count must be >= 0.") |
| if self.max_dates is not None and self.max_dates < 1: |
| raise ValueError("max_dates must be >= 1 when provided.") |
| if ( |
| self.date_start is not None |
| and self.date_end is not None |
| and int(self.date_start) > int(self.date_end) |
| ): |
| raise ValueError("date_start must be <= date_end.") |
|
|
| self.raster_cache = RasterDatasetCache(max_open=cache_size) |
| self._depth_axis_m = np.asarray( |
| self.manifest.get("depth_axis_m", ()), dtype=np.float32 |
| ).reshape(-1) |
| if self._depth_axis_m.size == 0: |
| raise RuntimeError("GeoTIFF manifest is missing depth_axis_m.") |
|
|
| self.argo_store = self._open_argo_store() |
| if self.argo_store is not None and int( |
| self.argo_store.depth_axis_m.size |
| ) != int(self._depth_axis_m.size): |
| raise RuntimeError( |
| "ARGO profile zarr depth axis does not match GeoTIFF manifest depth_axis_m." |
| ) |
|
|
| self.glorys_store, self.salinity_store, self.eo_store = ( |
| self._build_raster_stores() |
| ) |
| |
| self.ostia_store = self.eo_store |
| self.available_dates = self._filter_available_dates( |
| sorted(self.glorys_store.dates & self.eo_store.dates) |
| ) |
| if not self.available_dates: |
| raise RuntimeError("No overlapping GeoTIFF raster dates were found.") |
| self.count_argo_support = self._resolve_count_argo_support(count_argo_support) |
| if self._require_argo_for_current_split() and not self.count_argo_support: |
| raise ValueError( |
| "count_argo_support=False is incompatible with requiring ARGO " |
| "profiles for the current split." |
| ) |
| if self.include_salinity: |
| if self.salinity_store is None: |
| raise RuntimeError("GeoTIFF salinity store was not initialized.") |
| missing_salinity_dates = sorted( |
| set(self.available_dates) - self.salinity_store.dates |
| ) |
| if missing_salinity_dates: |
| raise RuntimeError( |
| "GeoTIFF manifest is missing GLORYS salinity 'so' rasters " |
| f"for dates: {missing_salinity_dates[:5]}" |
| ) |
|
|
| grid_params = _GridParams( |
| tile_size=self.tile_size, |
| resolution_deg=self.resolution_deg, |
| invalid_threshold=0.5, |
| invalid_mask_flags=("land",), |
| val_fraction=float(val_fraction), |
| val_year=None if val_year is None else int(val_year), |
| split_seed=self.random_seed, |
| patch_grid_source=self.patch_grid_source, |
| land_mask_path=self.land_mask_path, |
| patch_stride=self.patch_stride, |
| max_land_fraction=self.max_land_fraction, |
| force_include_regions=self._effective_force_include_regions(), |
| ) |
| index = GeoTIFFPatchIndex( |
| root_dir=self.root_dir, |
| dates=self.available_dates, |
| argo_store=self.argo_store if self.count_argo_support else None, |
| cache_dir=metadata_cache_dir, |
| grid_params=grid_params, |
| ) |
| rows = index.load_rows() |
| rows = self._filter_rows(rows) |
| rows = self._apply_finetune_sampling(rows) |
| if not rows: |
| raise RuntimeError("Dataset is empty after split/ARGO filtering.") |
| self._rows = rows |
|
|
| def _filter_available_dates(self, dates: Sequence[int]) -> list[int]: |
| """Apply optional date-window controls before row indexing.""" |
| filtered = [ |
| int(date) |
| for date in dates |
| if (self.date_start is None or int(date) >= int(self.date_start)) |
| and (self.date_end is None or int(date) <= int(self.date_end)) |
| ] |
| if self.max_dates is not None: |
| filtered = filtered[: int(self.max_dates)] |
| return filtered |
|
|
| def _resolve_count_argo_support(self, value: bool | None) -> bool: |
| """Decide whether to compute profile counts during index creation.""" |
| if value is not None: |
| return bool(value) |
| |
| |
| return bool(self._require_argo_for_current_split()) |
|
|
| @staticmethod |
| def _normalize_eo_selection( |
| *, |
| eo_source: str, |
| eo_var_name: str | None, |
| ostia_var_name: str, |
| ) -> tuple[str, str]: |
| """Resolve the dense surface EO raster group and variable.""" |
| source = str(eo_source or "ostia").strip().lower() |
| if not source: |
| source = "ostia" |
| var_name = eo_var_name |
| if var_name is None: |
| var_name = ( |
| ostia_var_name if source == "ostia" else EO_SOURCE_DEFAULTS.get(source) |
| ) |
| if var_name is None or not str(var_name).strip(): |
| raise ValueError(f"No EO variable configured for source {source!r}.") |
| return source, str(var_name).strip() |
|
|
| @staticmethod |
| def _resolve_eo_metadata(eo_source: str, eo_var_name: str) -> tuple[str, str]: |
| """Return manifest stretch and normalization family for one EO raster.""" |
| key = (str(eo_source).strip().lower(), str(eo_var_name).strip()) |
| metadata = EO_STRETCH_BY_SOURCE_VAR.get(key) |
| if metadata is None: |
| supported = ", ".join( |
| f"{source}/{var}" for source, var in sorted(EO_STRETCH_BY_SOURCE_VAR) |
| ) |
| raise ValueError( |
| "Unsupported EO raster selection " |
| f"{key[0]!r}/{key[1]!r}. Supported selections: {supported}." |
| ) |
| return metadata |
|
|
| def _open_argo_store(self) -> ArgoGeoTIFFProfileStore | None: |
| """Open the optional compact ARGO zarr profile store.""" |
| argo_info = self.manifest.get("argo", {}) |
| raw_path = argo_info.get("path") |
| if raw_path is None or str(raw_path).strip().lower() in MISSING_TEXT_VALUES: |
| return None |
| return ArgoGeoTIFFProfileStore( |
| _resolve_manifest_path(self.root_dir, raw_path), |
| include_salinity=self.include_salinity, |
| filter_bad_quality=self.filter_bad_argo_quality, |
| accepted_qc_flags=self.accepted_argo_qc_flags, |
| ) |
|
|
| def _build_raster_stores( |
| self, |
| ) -> tuple[GeoTIFFRasterStore, GeoTIFFRasterStore | None, GeoTIFFRasterStore]: |
| """Build date-indexed dense raster stores from manifest entries.""" |
| rasters = self.manifest.get("rasters", {}) |
| stretch = self.manifest.get("stretch", {}) |
| temp_stretch = stretch.get("temperature_kelvin") |
| if not isinstance(temp_stretch, dict): |
| raise RuntimeError( |
| "GeoTIFF manifest is missing temperature_kelvin stretch." |
| ) |
| eo_stretch = stretch.get(self.eo_stretch_name) |
| if not isinstance(eo_stretch, dict): |
| raise RuntimeError( |
| "GeoTIFF manifest is missing EO stretch " |
| f"{self.eo_stretch_name!r} for {self.eo_source}/{self.eo_var_name}." |
| ) |
| glorys_rasters = rasters.get("glorys", {}) |
| glorys_entries = ( |
| glorys_rasters.get(self.glorys_var_name, []) |
| if isinstance(glorys_rasters, dict) |
| else [] |
| ) |
| eo_rasters = rasters.get(self.eo_source, {}) |
| eo_entries = ( |
| eo_rasters.get(self.eo_var_name, []) if isinstance(eo_rasters, dict) else [] |
| ) |
| if not glorys_entries or not eo_entries: |
| raise RuntimeError( |
| "GeoTIFF manifest is missing GLORYS/EO raster entries for " |
| f"{self.glorys_var_name!r}/{self.eo_source}/{self.eo_var_name}." |
| ) |
| salinity_store = None |
| if self.include_salinity: |
| salinity_stretch = stretch.get("salinity") |
| if not isinstance(salinity_stretch, dict): |
| raise RuntimeError("GeoTIFF manifest is missing salinity stretch.") |
| salinity_entries = ( |
| glorys_rasters.get("so", []) if isinstance(glorys_rasters, dict) else [] |
| ) |
| if not salinity_entries: |
| raise RuntimeError( |
| "GeoTIFF manifest is missing GLORYS salinity 'so' raster entries." |
| ) |
| salinity_store = GeoTIFFRasterStore( |
| paths_by_date=_records_by_date(salinity_entries, self.root_dir), |
| stretch=salinity_stretch, |
| cache=self.raster_cache, |
| kelvin_temperature=False, |
| ) |
| return ( |
| GeoTIFFRasterStore( |
| paths_by_date=_records_by_date(glorys_entries, self.root_dir), |
| stretch=temp_stretch, |
| cache=self.raster_cache, |
| kelvin_temperature=True, |
| ), |
| salinity_store, |
| GeoTIFFRasterStore( |
| paths_by_date=_records_by_date(eo_entries, self.root_dir), |
| stretch=eo_stretch, |
| cache=self.raster_cache, |
| kelvin_temperature=self.eo_normalization == "temperature", |
| ), |
| ) |
|
|
| @property |
| def rows(self) -> list[dict[str, Any]]: |
| """Return patch/date metadata rows.""" |
| return self._rows |
|
|
| @property |
| def depth_axis_m(self) -> np.ndarray: |
| """Return the GLORYS depth axis in meters.""" |
| return self._depth_axis_m.copy() |
|
|
| @classmethod |
| def from_config( |
| cls, |
| config_path: str | Path | None = None, |
| *, |
| split: str = "all", |
| dataset_overrides: dict[str, Any] | None = None, |
| ) -> "ArgoGeoTIFFGriddedPatchDataset": |
| """Build a GeoTIFF dataset from a YAML data config.""" |
| if config_path is None: |
| config_path = cls.DEFAULT_CONFIG_PATH |
| config_path = Path(config_path).expanduser() |
| if not config_path.is_absolute(): |
| config_path = (DEFAULT_DATASET_ROOT_DIR / config_path).resolve() |
| with config_path.open("r", encoding="utf-8") as f: |
| cfg = yaml.safe_load(f) |
|
|
| ds_cfg = cfg.get("data", cfg).get("dataset", {}) |
| if dataset_overrides: |
| ds_cfg = _deep_update_config(ds_cfg, dataset_overrides) |
| return cls( |
| geotiff_root_dir=cls._cfg_get( |
| ds_cfg, |
| "core.geotiff_root_dir", |
| "geotiff_root_dir", |
| default=cls.DEFAULT_GEOTIFF_ROOT_DIR, |
| ), |
| metadata_cache_dir=cls._cfg_get( |
| ds_cfg, |
| "core.metadata_cache_dir", |
| "metadata_cache_dir", |
| default=cls.DEFAULT_METADATA_CACHE_DIR, |
| ), |
| split=split, |
| tile_size=int( |
| cls._cfg_get(ds_cfg, "grid.tile_size", "tile_size", default=128) |
| ), |
| resolution_deg=float( |
| cls._cfg_get( |
| ds_cfg, "grid.resolution_deg", "resolution_deg", default=0.1 |
| ) |
| ), |
| patch_grid_source=str( |
| cls._cfg_get( |
| ds_cfg, |
| "grid.patch_grid_source", |
| "patch_grid_source", |
| default="land_mask", |
| ) |
| ), |
| land_mask_path=cls._cfg_get( |
| ds_cfg, |
| "grid.land_mask_path", |
| "land_mask_path", |
| default=None, |
| ), |
| patch_stride=cls._optional_int( |
| cls._cfg_get( |
| ds_cfg, |
| "grid.patch_stride", |
| "patch_stride", |
| default=None, |
| ) |
| ), |
| max_land_fraction=float( |
| cls._cfg_get( |
| ds_cfg, |
| "grid.max_land_fraction", |
| "max_land_fraction", |
| default=0.30, |
| ) |
| ), |
| force_include_regions=cls._cfg_get( |
| ds_cfg, |
| "grid.force_include_regions", |
| "force_include_regions", |
| default=None, |
| ), |
| finetune_sampling=cls._cfg_get( |
| ds_cfg, |
| "finetune_sampling", |
| "finetune_sampling", |
| default=None, |
| ), |
| temporal_window_days=int( |
| cls._cfg_get( |
| ds_cfg, |
| "sampling.temporal_window_days", |
| "temporal_window_days", |
| default=7, |
| ) |
| ), |
| glorys_var_name=str( |
| cls._cfg_get( |
| ds_cfg, |
| "sampling.glorys_var_name", |
| "glorys_var_name", |
| default="thetao", |
| ) |
| ), |
| ostia_var_name=str( |
| cls._cfg_get( |
| ds_cfg, |
| "sampling.ostia_var_name", |
| "ostia_var_name", |
| default="analysed_sst", |
| ) |
| ), |
| eo_source=str( |
| cls._cfg_get( |
| ds_cfg, |
| "sampling.eo_source", |
| "eo_source", |
| default="ostia", |
| ) |
| ), |
| eo_var_name=cls._cfg_get( |
| ds_cfg, |
| "sampling.eo_var_name", |
| "eo_var_name", |
| default=None, |
| ), |
| val_fraction=float(cfg.get("split", {}).get("val_fraction", 0.2)), |
| val_year=cls._optional_int(cfg.get("split", {}).get("val_year", None)), |
| date_start=cls._cfg_get( |
| ds_cfg, "sampling.date_start", "date_start", default=None |
| ), |
| date_end=cls._cfg_get( |
| ds_cfg, "sampling.date_end", "date_end", default=None |
| ), |
| max_dates=cls._optional_int( |
| cls._cfg_get(ds_cfg, "sampling.max_dates", "max_dates", default=None) |
| ), |
| count_argo_support=cls._optional_bool( |
| cls._cfg_get( |
| ds_cfg, |
| "selection.count_argo_support", |
| "count_argo_support", |
| default=None, |
| ) |
| ), |
| require_argo_for_train=bool( |
| cls._cfg_get( |
| ds_cfg, |
| "selection.require_argo_for_train", |
| "require_argo_for_train", |
| default=True, |
| ) |
| ), |
| require_argo_for_val=bool( |
| cls._cfg_get( |
| ds_cfg, |
| "selection.require_argo_for_val", |
| "require_argo_for_val", |
| default=True, |
| ) |
| ), |
| require_argo_for_all=bool( |
| cls._cfg_get( |
| ds_cfg, |
| "selection.require_argo_for_all", |
| "require_argo_for_all", |
| default=False, |
| ) |
| ), |
| filter_bad_argo_quality=bool( |
| cls._cfg_get( |
| ds_cfg, |
| "selection.filter_bad_argo_quality", |
| "filter_bad_argo_quality", |
| default=True, |
| ) |
| ), |
| accepted_argo_qc_flags=cls._cfg_get( |
| ds_cfg, |
| "selection.accepted_argo_qc_flags", |
| "accepted_argo_qc_flags", |
| default=None, |
| ), |
| synthetic_mode=bool( |
| cls._cfg_get( |
| ds_cfg, "synthetic.enabled", "synthetic_enabled", default=False |
| ) |
| ), |
| synthetic_pixel_count=int( |
| cls._cfg_get( |
| ds_cfg, |
| "synthetic.pixel_count", |
| "synthetic_pixel_count", |
| default=250, |
| ) |
| ), |
| return_info=bool( |
| cls._cfg_get(ds_cfg, "output.return_info", "return_info", default=True) |
| ), |
| return_coords=bool( |
| cls._cfg_get( |
| ds_cfg, "output.return_coords", "return_coords", default=True |
| ) |
| ), |
| include_salinity=bool( |
| cls._cfg_get( |
| ds_cfg, |
| "output.include_salinity", |
| "include_salinity", |
| default=False, |
| ) |
| ), |
| output_fields=cls._cfg_get( |
| ds_cfg, "output.fields", "output_fields", default=None |
| ), |
| random_seed=int( |
| cls._cfg_get(ds_cfg, "runtime.random_seed", "random_seed", default=7) |
| ), |
| cache_size=int( |
| cls._cfg_get(ds_cfg, "runtime.cache_size", "cache_size", default=8) |
| ), |
| ) |
|
|
| @staticmethod |
| def _cfg_get( |
| cfg: dict[str, Any], |
| nested_key: str, |
| flat_key: str, |
| *, |
| default: Any, |
| ) -> Any: |
| """Read nested config values while keeping flat-key compatibility.""" |
| node: Any = cfg |
| for part in nested_key.split("."): |
| if not isinstance(node, dict) or part not in node: |
| node = None |
| break |
| node = node[part] |
| if node is not None: |
| return node |
| _ = flat_key |
| return default |
|
|
| @staticmethod |
| def _normalize_output_fields( |
| output_fields: Sequence[str] | str | None, |
| *, |
| include_salinity: bool, |
| ) -> tuple[str, ...]: |
| """Resolve physical fields loaded for each dataset sample.""" |
| if output_fields is None: |
| return ("temperature", "salinity") if include_salinity else ("temperature",) |
| if isinstance(output_fields, str): |
| fields = (output_fields,) |
| else: |
| fields = tuple(str(field) for field in output_fields) |
| normalized = tuple(field.strip().lower() for field in fields if field.strip()) |
| if not normalized: |
| raise ValueError("dataset.output.fields must contain at least one field.") |
| unsupported = sorted(set(normalized) - {"temperature", "salinity"}) |
| if unsupported: |
| raise ValueError( |
| "dataset.output.fields contains unsupported fields: " |
| f"{unsupported}. Supported fields are: temperature, salinity." |
| ) |
| if len(set(normalized)) != len(normalized): |
| raise ValueError("dataset.output.fields cannot contain duplicates.") |
| return normalized |
|
|
| @staticmethod |
| def _optional_bool(value: Any) -> bool | None: |
| """Parse nullable boolean config values.""" |
| if value is None: |
| return None |
| if isinstance(value, str): |
| normalized = value.strip().lower() |
| if normalized in MISSING_TEXT_VALUES: |
| return None |
| if normalized in {"true", "yes", "on", "1"}: |
| return True |
| if normalized in {"false", "no", "off", "0"}: |
| return False |
| if isinstance(value, bool): |
| return value |
| raise ValueError(f"Expected a nullable boolean value, got {value!r}.") |
|
|
| @staticmethod |
| def _optional_int(value: Any) -> int | None: |
| """Parse nullable integer config values.""" |
| if value is None: |
| return None |
| if isinstance(value, str) and value.strip().lower() in MISSING_TEXT_VALUES: |
| return None |
| return int(value) |
|
|
| @staticmethod |
| def _normalize_finetune_sampling(raw_cfg: dict[str, Any] | None) -> dict[str, Any]: |
| """Normalize optional hard-area finetuning row-sampling settings.""" |
| cfg = dict(raw_cfg or {}) |
| hard_fraction = float(cfg.get("hard_fraction", 0.75)) |
| if not (0.0 < hard_fraction <= 1.0): |
| raise ValueError("finetune_sampling.hard_fraction must be in (0, 1].") |
| default_max_land_fraction = float(cfg.get("default_max_land_fraction", 0.85)) |
| if not (0.0 <= default_max_land_fraction <= 1.0): |
| raise ValueError( |
| "finetune_sampling.default_max_land_fraction must be in [0, 1]." |
| ) |
|
|
| raw_splits = cfg.get("apply_to_splits", ("train",)) |
| if isinstance(raw_splits, str): |
| apply_to_splits = (raw_splits.strip().lower(),) |
| else: |
| apply_to_splits = tuple(str(value).strip().lower() for value in raw_splits) |
| if not apply_to_splits or any( |
| value not in {"all", "train", "val"} for value in apply_to_splits |
| ): |
| raise ValueError( |
| "finetune_sampling.apply_to_splits must contain split names from " |
| "{'all', 'train', 'val'}." |
| ) |
|
|
| hard_regions: list[dict[str, Any]] = [] |
| for idx, raw_region in enumerate(cfg.get("hard_regions", ()) or ()): |
| if not isinstance(raw_region, dict): |
| raise ValueError( |
| "Each finetune_sampling.hard_regions item must be a mapping." |
| ) |
| region = dict(raw_region) |
| region["name"] = str(region.get("name", f"hard_region_{idx}")) |
| region["lon_min"] = float(region["lon_min"]) |
| region["lon_max"] = float(region["lon_max"]) |
| region["lat_min"] = float(region["lat_min"]) |
| region["lat_max"] = float(region["lat_max"]) |
| region["max_land_fraction"] = float( |
| region.get("max_land_fraction", default_max_land_fraction) |
| ) |
| if not (0.0 <= region["max_land_fraction"] <= 1.0): |
| raise ValueError( |
| "finetune_sampling.hard_regions[].max_land_fraction must be " |
| "in [0, 1]." |
| ) |
| hard_regions.append(region) |
|
|
| return { |
| "enabled": bool(cfg.get("enabled", False)), |
| "hard_fraction": hard_fraction, |
| "apply_to_splits": apply_to_splits, |
| "relax_land_filter": bool(cfg.get("relax_land_filter", True)), |
| "default_max_land_fraction": default_max_land_fraction, |
| "hard_regions": tuple(hard_regions), |
| } |
|
|
| def _finetune_applies_to_current_split(self) -> bool: |
| """Return whether hard-area finetuning should filter this split.""" |
| if not bool(self.finetune_sampling["enabled"]): |
| return False |
| apply_to_splits = set(self.finetune_sampling["apply_to_splits"]) |
| return "all" in apply_to_splits or self.split in apply_to_splits |
|
|
| def _effective_force_include_regions(self) -> tuple[Any, ...]: |
| """Return force-include regions, extended by finetune boxes when needed.""" |
| if not ( |
| self._finetune_applies_to_current_split() |
| and bool(self.finetune_sampling["relax_land_filter"]) |
| ): |
| return self.force_include_regions |
|
|
| merged = {region.name: region for region in self.force_include_regions} |
| for raw_region in self.finetune_sampling["hard_regions"]: |
| parsed_region = _parse_force_include_regions([raw_region])[0] |
| existing = merged.get(parsed_region.name) |
| if existing is not None: |
| |
| parsed_region = parsed_region.__class__( |
| name=parsed_region.name, |
| lon_min=parsed_region.lon_min, |
| lon_max=parsed_region.lon_max, |
| lat_min=parsed_region.lat_min, |
| lat_max=parsed_region.lat_max, |
| max_land_fraction=max( |
| float(existing.max_land_fraction), |
| float(parsed_region.max_land_fraction), |
| ), |
| ) |
| merged[parsed_region.name] = parsed_region |
| return tuple(merged.values()) |
|
|
| @staticmethod |
| def _row_in_hard_region( |
| row: dict[str, Any], regions: Sequence[dict[str, Any]] |
| ) -> bool: |
| """Return whether a patch center falls inside any hard finetune box.""" |
| lat_center = float(row.get("lat_center", np.nan)) |
| lon_center = _normalize_lon(float(row.get("lon_center", np.nan))) |
| if not (np.isfinite(lat_center) and np.isfinite(lon_center)): |
| return False |
| for region in regions: |
| lat_min = min(float(region["lat_min"]), float(region["lat_max"])) |
| lat_max = max(float(region["lat_min"]), float(region["lat_max"])) |
| lon_min = min(float(region["lon_min"]), float(region["lon_max"])) |
| lon_max = max(float(region["lon_min"]), float(region["lon_max"])) |
| if lat_min <= lat_center <= lat_max and lon_min <= lon_center <= lon_max: |
| return True |
| return False |
|
|
| def _apply_finetune_sampling( |
| self, rows: list[dict[str, Any]] |
| ) -> list[dict[str, Any]]: |
| """Apply deterministic hard/easy row filtering for finetuning runs.""" |
| if not self._finetune_applies_to_current_split(): |
| self.finetune_sampling_summary = { |
| "enabled": bool(self.finetune_sampling["enabled"]), |
| "applied": False, |
| "split": self.split, |
| "total_rows": len(rows), |
| } |
| return rows |
|
|
| regions = self.finetune_sampling["hard_regions"] |
| hard_indices = [ |
| idx |
| for idx, row in enumerate(rows) |
| if self._row_in_hard_region(row, regions) |
| ] |
| if not hard_indices: |
| raise RuntimeError( |
| "Finetune hard-area sampling matched no rows for split " |
| f"{self.split!r}. Check data.dataset.finetune_sampling.hard_regions." |
| ) |
|
|
| hard_fraction = float(self.finetune_sampling["hard_fraction"]) |
| hard_index_set = set(hard_indices) |
| easy_indices = [idx for idx in range(len(rows)) if idx not in hard_index_set] |
| requested_easy = int( |
| round(len(hard_indices) * (1.0 - hard_fraction) / hard_fraction) |
| ) |
| selected_easy: list[int] = [] |
| if requested_easy > 0 and easy_indices: |
| sample_count = min(int(requested_easy), len(easy_indices)) |
| rng = np.random.default_rng(int(self.random_seed)) |
| selected_easy = sorted( |
| int(value) |
| for value in rng.choice(easy_indices, size=sample_count, replace=False) |
| ) |
|
|
| selected_indices = sorted(hard_indices + selected_easy) |
| filtered_rows = [rows[idx] for idx in selected_indices] |
| actual_hard_fraction = len(hard_indices) / float(len(filtered_rows)) |
| self.finetune_sampling_summary = { |
| "enabled": True, |
| "applied": True, |
| "split": self.split, |
| "target_hard_fraction": hard_fraction, |
| "actual_hard_fraction": actual_hard_fraction, |
| "hard_rows": len(hard_indices), |
| "easy_rows": len(selected_easy), |
| "total_rows": len(filtered_rows), |
| "available_easy_rows": len(easy_indices), |
| "region_names": [str(region["name"]) for region in regions], |
| } |
| return filtered_rows |
|
|
| def _filter_rows(self, rows: list[dict[str, Any]]) -> list[dict[str, Any]]: |
| """Apply split and ARGO-support filters.""" |
| if self.split in {"train", "val"}: |
| rows = [ |
| row |
| for row in rows |
| if str(row.get("split", row.get("phase", ""))).strip().lower() |
| == self.split |
| ] |
| require_argo = self._require_argo_for_current_split() |
| if require_argo: |
| rows = [row for row in rows if int(row.get("argo_profile_count", 0)) > 0] |
| return rows |
|
|
| def _require_argo_for_current_split(self) -> bool: |
| """Return whether the current split requires sparse ARGO support.""" |
| if self.synthetic_mode: |
| return False |
| if self.split == "train": |
| return self.require_argo_for_train |
| if self.split == "val": |
| return self.require_argo_for_val |
| return self.require_argo_for_all |
|
|
| def __len__(self) -> int: |
| """Return dataset row count.""" |
| return len(self._rows) |
|
|
| def _load_y_patch(self, row: dict[str, Any]) -> np.ndarray: |
| """Load the dense GLORYS target patch.""" |
| y_np = self.glorys_store.read_patch( |
| target_date=int(row["date"]), |
| grid_y0=int(row["grid_y0"]), |
| grid_x0=int(row["grid_x0"]), |
| tile_size=self.tile_size, |
| ) |
| if y_np.ndim != 3: |
| raise RuntimeError( |
| f"Expected GLORYS patch shape (D,H,W), got {tuple(y_np.shape)}" |
| ) |
| if int(y_np.shape[0]) != int(self._depth_axis_m.size): |
| raise RuntimeError( |
| "GLORYS raster band count does not match manifest depth_axis_m: " |
| f"{int(y_np.shape[0])} != {int(self._depth_axis_m.size)}" |
| ) |
| return y_np.astype(np.float32, copy=False) |
|
|
| def _load_y_salinity_patch(self, row: dict[str, Any]) -> np.ndarray: |
| """Load the dense GLORYS salinity target patch as raw PSU.""" |
| if self.salinity_store is None: |
| raise RuntimeError("GeoTIFF salinity output is not enabled.") |
| salinity_np = self.salinity_store.read_patch( |
| target_date=int(row["date"]), |
| grid_y0=int(row["grid_y0"]), |
| grid_x0=int(row["grid_x0"]), |
| tile_size=self.tile_size, |
| ) |
| if salinity_np.ndim != 3: |
| raise RuntimeError( |
| "Expected GLORYS salinity patch shape (D,H,W), " |
| f"got {tuple(salinity_np.shape)}" |
| ) |
| if int(salinity_np.shape[0]) != int(self._depth_axis_m.size): |
| raise RuntimeError( |
| "GLORYS salinity raster band count does not match manifest " |
| f"depth_axis_m: {int(salinity_np.shape[0])} != " |
| f"{int(self._depth_axis_m.size)}" |
| ) |
| return salinity_np.astype(np.float32, copy=False) |
|
|
| def _load_land_mask_patch(self, row: dict[str, Any]) -> np.ndarray: |
| """Load the configured on-disk world-mask patch as an ocean mask.""" |
| src = self.raster_cache.get(self.land_mask_path) |
| window = Window( |
| col_off=int(row["grid_x0"]), |
| row_off=int(row["grid_y0"]), |
| width=int(self.tile_size), |
| height=int(self.tile_size), |
| ) |
| land_np = src.read(1, window=window) |
| expected_shape = (int(self.tile_size), int(self.tile_size)) |
| if land_np.shape != expected_shape: |
| raise RuntimeError( |
| "Land-mask patch shape does not match dataset tile_size: " |
| f"{tuple(land_np.shape)} != {expected_shape}" |
| ) |
| |
| return (np.asarray(land_np, dtype=np.float32) <= 0.5).astype( |
| np.float32, |
| copy=False, |
| )[None, ...] |
|
|
| def _load_eo_patch(self, row: dict[str, Any]) -> np.ndarray: |
| """Load the configured dense surface-context patch.""" |
| eo_np = self.eo_store.read_patch( |
| target_date=int(row["date"]), |
| grid_y0=int(row["grid_y0"]), |
| grid_x0=int(row["grid_x0"]), |
| tile_size=self.tile_size, |
| ) |
| if eo_np.ndim == 3 and int(eo_np.shape[0]) == 1: |
| eo_np = eo_np[0] |
| if eo_np.ndim != 2: |
| raise RuntimeError( |
| f"Expected EO patch shape (H,W), got {tuple(eo_np.shape)}" |
| ) |
| return eo_np.astype(np.float32, copy=False)[None, ...] |
|
|
| def _normalize_eo_tensor(self, tensor: torch.Tensor) -> torch.Tensor: |
| """Normalize the EO channel according to its physical variable family.""" |
| if self.eo_normalization == "temperature": |
| return temperature_normalize(mode="norm", tensor=tensor) |
| if self.eo_normalization == "salinity": |
| return salinity_normalize(mode="norm", tensor=tensor) |
| raise RuntimeError(f"Unsupported EO normalization: {self.eo_normalization}") |
|
|
| def _spatial_support_from_valid_mask( |
| self, |
| valid_mask_np: np.ndarray, |
| *, |
| source_name: str, |
| ) -> np.ndarray: |
| """Collapse a per-band validity mask into one spatial ocean-support mask.""" |
| valid_np = np.asarray(valid_mask_np, dtype=bool) |
| if valid_np.ndim == 3: |
| spatial_mask = valid_np.any(axis=0, keepdims=True) |
| elif valid_np.ndim == 2: |
| spatial_mask = valid_np[None, ...] |
| else: |
| raise RuntimeError( |
| f"{source_name} support must be shaped as (C,H,W) or (H,W), " |
| f"got {tuple(valid_np.shape)}." |
| ) |
| expected_shape = (1, int(self.tile_size), int(self.tile_size)) |
| if tuple(spatial_mask.shape) != expected_shape: |
| raise RuntimeError( |
| f"{source_name} support shape does not match dataset tile_size: " |
| f"{tuple(spatial_mask.shape)} != {expected_shape}." |
| ) |
| return spatial_mask.astype(np.float32, copy=False) |
|
|
| def _build_land_mask_patch( |
| self, |
| row: dict[str, Any], |
| *, |
| y_valid_mask_np: np.ndarray | None, |
| eo_np: np.ndarray | None, |
| ) -> np.ndarray: |
| """Build one spatial ocean mask from GLORYS, EO, or the on-disk mask.""" |
| if y_valid_mask_np is not None: |
| return self._spatial_support_from_valid_mask( |
| y_valid_mask_np, |
| source_name="GLORYS target", |
| ) |
| if eo_np is not None: |
| return self._spatial_support_from_valid_mask( |
| np.isfinite(eo_np), |
| source_name="EO surface context", |
| ) |
| if self.land_mask_path.exists(): |
| return self._load_land_mask_patch(row) |
| raise RuntimeError( |
| "Could not build land_mask: GLORYS target support was unavailable, " |
| "EO support was unavailable, and the configured on-disk land mask " |
| f"does not exist: {self.land_mask_path}" |
| ) |
|
|
| def _empty_sparse_patch(self) -> tuple[np.ndarray, np.ndarray]: |
| """Return an empty sparse profile patch and validity mask.""" |
| depth_size = int(self._depth_axis_m.size) |
| shape = (depth_size, self.tile_size, self.tile_size) |
| return np.full(shape, np.nan, dtype=np.float32), np.zeros(shape, dtype=bool) |
|
|
| def _rasterize_profile_values( |
| self, |
| row: dict[str, Any], |
| indices: np.ndarray, |
| values: np.ndarray, |
| ) -> tuple[np.ndarray, np.ndarray]: |
| """Rasterize selected profile values into one sparse patch.""" |
| depth_size = int(self._depth_axis_m.size) |
| if indices.size == 0: |
| return self._empty_sparse_patch() |
| if values.ndim != 2 or int(values.shape[1]) != depth_size: |
| raise RuntimeError( |
| "ARGO profile values do not match manifest depth_axis_m: " |
| f"{tuple(values.shape)}" |
| ) |
|
|
| value_sum = np.zeros( |
| (depth_size, self.tile_size, self.tile_size), dtype=np.float64 |
| ) |
| value_count = np.zeros( |
| (depth_size, self.tile_size, self.tile_size), dtype=np.uint16 |
| ) |
| y0 = int(row["grid_y0"]) |
| x0 = int(row["grid_x0"]) |
| for local_idx, profile_idx in enumerate(indices.tolist()): |
| row_idx = int(self.argo_store.grid_row[int(profile_idx)]) - y0 |
| col_idx = int(self.argo_store.grid_col[int(profile_idx)]) - x0 |
| if ( |
| row_idx < 0 |
| or row_idx >= self.tile_size |
| or col_idx < 0 |
| or col_idx >= self.tile_size |
| ): |
| continue |
| profile = values[int(local_idx)] |
| valid = np.isfinite(profile) |
| if not np.any(valid): |
| continue |
| |
| value_sum[valid, row_idx, col_idx] += profile[valid].astype(np.float64) |
| value_count[valid, row_idx, col_idx] += 1 |
|
|
| value_np = np.full(value_sum.shape, np.nan, dtype=np.float32) |
| value_valid = value_count > 0 |
| value_np[value_valid] = ( |
| value_sum[value_valid] / value_count[value_valid].astype(np.float64) |
| ).astype( |
| np.float32, |
| copy=False, |
| ) |
| return value_np, value_valid |
|
|
| def _query_temperature_valid_argo_indices(self, row: dict[str, Any]) -> np.ndarray: |
| """Return temperature-valid ARGO indices for the current patch.""" |
| if self.argo_store is None: |
| return np.zeros((0,), dtype=np.int64) |
| return self.argo_store.query_indices( |
| target_date=int(row["date"]), |
| grid_y0=int(row["grid_y0"]), |
| grid_x0=int(row["grid_x0"]), |
| tile_size=self.tile_size, |
| ) |
|
|
| def _rasterize_argo_patch( |
| self, row: dict[str, Any] |
| ) -> tuple[np.ndarray, np.ndarray]: |
| """Rasterize compact ARGO temperature observations into one patch.""" |
| indices = self._query_temperature_valid_argo_indices(row) |
| if indices.size == 0 or self.argo_store is None: |
| return self._empty_sparse_patch() |
| values = self.argo_store.load_temperature_profiles(indices) |
| return self._rasterize_profile_values(row, indices, values) |
|
|
| def _rasterize_argo_salinity_patch( |
| self, row: dict[str, Any] |
| ) -> tuple[np.ndarray, np.ndarray]: |
| """Rasterize compact ARGO salinity observations into one patch.""" |
| if not self.include_salinity: |
| raise RuntimeError("ARGO salinity output is not enabled.") |
| indices = self._query_temperature_valid_argo_indices(row) |
| if indices.size == 0 or self.argo_store is None: |
| return self._empty_sparse_patch() |
| |
| values = self.argo_store.load_salinity_profiles(indices) |
| return self._rasterize_profile_values(row, indices, values) |
|
|
| def _synthetic_rng_for_row( |
| self, |
| row: dict[str, Any], |
| *, |
| idx: int, |
| ) -> np.random.Generator: |
| """Build a deterministic synthetic-sampling RNG for one row.""" |
| seed = np.random.SeedSequence( |
| [ |
| int(self.random_seed), |
| int(row.get("patch_id", 0)), |
| int(row.get("date", 0)), |
| int(idx), |
| ] |
| ) |
| return np.random.default_rng(seed) |
|
|
| def _build_synthetic_x_from_glorys( |
| self, |
| y_np: np.ndarray, |
| y_valid_mask_np: np.ndarray, |
| row: dict[str, Any], |
| *, |
| idx: int, |
| ) -> tuple[np.ndarray, np.ndarray]: |
| """Build sparse synthetic observations by sampling the dense target.""" |
| x_np = np.full(y_np.shape, np.nan, dtype=np.float32) |
| x_valid = np.zeros(y_valid_mask_np.shape, dtype=bool) |
| if self.synthetic_pixel_count == 0: |
| return x_np, x_valid |
|
|
| valid_columns = np.asarray(y_valid_mask_np, dtype=bool).any(axis=0) |
| flat_valid_columns = np.flatnonzero(valid_columns.reshape(-1)) |
| if flat_valid_columns.size == 0: |
| return x_np, x_valid |
|
|
| sample_count = min( |
| int(self.synthetic_pixel_count), int(flat_valid_columns.size) |
| ) |
| rng = self._synthetic_rng_for_row(row, idx=idx) |
| selected = rng.choice(flat_valid_columns, size=sample_count, replace=False) |
| row_indices, col_indices = np.unravel_index(selected, valid_columns.shape) |
| for row_idx, col_idx in zip(row_indices.tolist(), col_indices.tolist()): |
| depth_valid = y_valid_mask_np[:, int(row_idx), int(col_idx)] |
| if not np.any(depth_valid): |
| continue |
| |
| x_np[depth_valid, int(row_idx), int(col_idx)] = y_np[ |
| depth_valid, |
| int(row_idx), |
| int(col_idx), |
| ] |
| x_valid[depth_valid, int(row_idx), int(col_idx)] = True |
| return x_np, x_valid |
|
|
| def __getitem__(self, idx: int) -> dict[str, Any]: |
| """Return one model-ready training sample.""" |
| row = self._rows[int(idx)] |
| eo_np = self._load_eo_patch(row) |
| temperature_payload: dict[str, torch.Tensor] | None = None |
| salinity_payload: dict[str, torch.Tensor] | None = None |
| land_support_np: np.ndarray | None = None |
|
|
| if self._loads_temperature: |
| y_np = self._load_y_patch(row) |
| y_valid_mask_np = np.isfinite(y_np) |
| if self.synthetic_mode: |
| x_np, x_valid_mask_np = self._build_synthetic_x_from_glorys( |
| y_np, |
| y_valid_mask_np, |
| row, |
| idx=int(idx), |
| ) |
| else: |
| x_np, x_valid_mask_np = self._rasterize_argo_patch(row) |
|
|
| x = temperature_normalize(mode="norm", tensor=torch.from_numpy(x_np)) |
| y = temperature_normalize(mode="norm", tensor=torch.from_numpy(y_np)) |
| x = torch.nan_to_num(x, nan=0.0, posinf=0.0, neginf=0.0) |
| y = torch.nan_to_num(y, nan=0.0, posinf=0.0, neginf=0.0) |
| x_valid_mask = torch.from_numpy( |
| x_valid_mask_np.astype(np.bool_, copy=False) |
| ) |
| y_valid_mask = torch.from_numpy( |
| y_valid_mask_np.astype(np.bool_, copy=False) |
| ) |
| temperature_payload = { |
| "x": x, |
| "y": y, |
| "x_valid_mask": x_valid_mask, |
| "y_valid_mask": y_valid_mask, |
| "x_valid_mask_1d": x_valid_mask.any(dim=0, keepdim=True), |
| } |
| land_support_np = y_valid_mask_np |
|
|
| if self.include_salinity: |
| y_salinity_np = self._load_y_salinity_patch(row) |
| y_salinity_valid_mask_np = np.isfinite(y_salinity_np) |
| if self.synthetic_mode: |
| x_salinity_np, x_salinity_valid_mask_np = ( |
| self._build_synthetic_x_from_glorys( |
| y_salinity_np, |
| y_salinity_valid_mask_np, |
| row, |
| idx=int(idx), |
| ) |
| ) |
| else: |
| x_salinity_np, x_salinity_valid_mask_np = ( |
| self._rasterize_argo_salinity_patch(row) |
| ) |
| x_salinity = salinity_normalize( |
| mode="norm", tensor=torch.from_numpy(x_salinity_np) |
| ) |
| y_salinity = salinity_normalize( |
| mode="norm", tensor=torch.from_numpy(y_salinity_np) |
| ) |
| x_salinity = torch.nan_to_num(x_salinity, nan=0.0, posinf=0.0, neginf=0.0) |
| y_salinity = torch.nan_to_num(y_salinity, nan=0.0, posinf=0.0, neginf=0.0) |
| x_salinity_valid_mask = torch.from_numpy( |
| x_salinity_valid_mask_np.astype(np.bool_, copy=False) |
| ) |
| y_salinity_valid_mask = torch.from_numpy( |
| y_salinity_valid_mask_np.astype(np.bool_, copy=False) |
| ) |
| salinity_payload = { |
| "x_salinity": x_salinity, |
| "y_salinity": y_salinity, |
| "x_salinity_valid_mask": x_salinity_valid_mask, |
| "y_salinity_valid_mask": y_salinity_valid_mask, |
| "x_salinity_valid_mask_1d": x_salinity_valid_mask.any( |
| dim=0, keepdim=True |
| ), |
| } |
| if land_support_np is None: |
| |
| land_support_np = y_salinity_valid_mask_np |
|
|
| land_mask_np = self._build_land_mask_patch( |
| row, |
| y_valid_mask_np=land_support_np, |
| eo_np=eo_np, |
| ) |
| eo = self._normalize_eo_tensor(torch.from_numpy(eo_np)) |
| eo = torch.nan_to_num(eo, nan=0.0, posinf=0.0, neginf=0.0) |
| sample: dict[str, Any] = { |
| "eo": eo, |
| "land_mask": torch.from_numpy(land_mask_np), |
| "date": _parse_date_int(row.get("date", 19700115)), |
| } |
| if temperature_payload is not None: |
| sample.update(temperature_payload) |
| if salinity_payload is not None: |
| sample.update(salinity_payload) |
| if self.return_coords: |
| sample["coords"] = torch.tensor( |
| [ |
| 0.5 * (float(row["lat0"]) + float(row["lat1"])), |
| _center_lon_deg(float(row["lon0"]), float(row["lon1"])), |
| ], |
| dtype=torch.float32, |
| ) |
| if self.return_info: |
| info = dict(row) |
| info["x_source"] = "glorys_synthetic" if self.synthetic_mode else "argo" |
| info["synthetic_pixel_count"] = ( |
| int(self.synthetic_pixel_count) if self.synthetic_mode else 0 |
| ) |
| sample["info"] = info |
| return sample |
|
|