/** * Initialize the ModelBuilder, validating all arguments and preparing the training frame. This * call is expected to be overridden in the subclasses and each subclass will start with * "super.init();". This call is made by the front-end whenever the GUI is clicked, and needs to * be fast; heavy-weight prep needs to wait for the trainModel() call. * * <p>Validate the requested ntrees; precompute actual ntrees. Validate the number of classes to * predict on; validate a checkpoint. */ @Override public void init(boolean expensive) { super.init(expensive); if (H2O.ARGS.client && _parms._build_tree_one_node) error("_build_tree_one_node", "Cannot run on a single node in client mode"); if (_vresponse != null) _vresponse_key = _vresponse._key; if (_response != null) _response_key = _response._key; if (_nclass > SharedTreeModel.SharedTreeParameters.MAX_SUPPORTED_LEVELS) error("_nclass", "Too many levels in response column!"); if (_parms._min_rows < 0) error("_min_rows", "Requested min_rows must be greater than 0"); if (_parms._ntrees < 0 || _parms._ntrees > 100000) error("_ntrees", "Requested ntrees must be between 1 and 100000"); _ntrees = _parms._ntrees; // Total trees in final model if (_parms._checkpoint) { // Asking to continue from checkpoint? Value cv = DKV.get(_parms._model_id); if (cv != null) { // Look for prior model M checkpointModel = cv.get(); if (_parms._ntrees < checkpointModel._output._ntrees + 1) error( "_ntrees", "Requested ntrees must be between " + checkpointModel._output._ntrees + 1 + " and 100000"); _ntrees = _parms._ntrees - checkpointModel._output._ntrees; // Needed trees } } if (_parms._nbins <= 1) error("_nbins", "_nbins must be > 1."); if (_parms._nbins >= 1 << 16) error("_nbins", "_nbins must be < " + (1 << 16)); if (_parms._nbins_cats <= 1) error("_nbins_cats", "_nbins_cats must be > 1."); if (_parms._nbins_cats >= 1 << 16) error("_nbins_cats", "_nbins_cats must be < " + (1 << 16)); if (_parms._max_depth <= 0) error("_max_depth", "_max_depth must be > 0."); if (_parms._min_rows <= 0) error("_min_rows", "_min_rows must be > 0."); if (_parms._distribution == Distributions.Family.tweedie) { _parms._distribution.tweedie.p = _parms._tweedie_power; } if (_train != null) { double sumWeights = _train.numRows() * (hasWeightCol() ? _train.vec(_parms._weights_column).mean() : 1); if (sumWeights < 2 * _parms._min_rows) // Need at least 2*min_rows weighted rows to split even once error( "_min_rows", "The dataset size is too small to split for min_rows=" + _parms._min_rows + ": must have at least " + 2 * _parms._min_rows + " (weighted) rows, but have only " + sumWeights + "."); } if (_train != null) _ncols = _train.numCols() - 1 - numSpecialCols(); }
/** * Initialize the ModelBuilder, validating all arguments and preparing the training frame. This * call is expected to be overridden in the subclasses and each subclass will start with * "super.init();". This call is made by the front-end whenever the GUI is clicked, and needs to * be fast; heavy-weight prep needs to wait for the trainModel() call. * * <p>Validate the requested ntrees; precompute actual ntrees. Validate the number of classes to * predict on; validate a checkpoint. */ @Override public void init(boolean expensive) { super.init(expensive); if (H2O.ARGS.client && _parms._build_tree_one_node) error("_build_tree_one_node", "Cannot run on a single node in client mode"); if (_vresponse != null) _vresponse_key = _vresponse._key; if (_response != null) _response_key = _response._key; if (_parms._min_rows < 0) error("_min_rows", "Requested min_rows must be greater than 0"); if (_parms._ntrees < 0 || _parms._ntrees > MAX_NTREES) error("_ntrees", "Requested ntrees must be between 1 and " + MAX_NTREES); _ntrees = _parms._ntrees; // Total trees in final model if (_parms.hasCheckpoint()) { // Asking to continue from checkpoint? Value cv = DKV.get(_parms._checkpoint); if (cv != null) { // Look for prior model M checkpointModel = cv.get(); try { _parms.validateWithCheckpoint(checkpointModel._parms); } catch (H2OIllegalArgumentException e) { error(e.values.get("argument").toString(), e.values.get("value").toString()); } if (_parms._ntrees < checkpointModel._output._ntrees + 1) error( "_ntrees", "If checkpoint is specified then requested ntrees must be higher than " + (checkpointModel._output._ntrees + 1)); // Compute number of trees to build for this checkpoint _ntrees = _parms._ntrees - checkpointModel._output._ntrees; // Needed trees } } if (_parms._nbins <= 1) error("_nbins", "_nbins must be > 1."); if (_parms._nbins >= 1 << 16) error("_nbins", "_nbins must be < " + (1 << 16)); if (_parms._nbins_cats <= 1) error("_nbins_cats", "_nbins_cats must be > 1."); if (_parms._nbins_cats >= 1 << 16) error("_nbins_cats", "_nbins_cats must be < " + (1 << 16)); if (_parms._max_depth <= 0) error("_max_depth", "_max_depth must be > 0."); if (_parms._min_rows <= 0) error("_min_rows", "_min_rows must be > 0."); if (_train != null) { double sumWeights = _train.numRows() * (hasWeightCol() ? _train.vec(_parms._weights_column).mean() : 1); if (sumWeights < 2 * _parms._min_rows) // Need at least 2*min_rows weighted rows to split even once error( "_min_rows", "The dataset size is too small to split for min_rows=" + _parms._min_rows + ": must have at least " + 2 * _parms._min_rows + " (weighted) rows, but have only " + sumWeights + "."); } if (_train != null) _ncols = _train.numCols() - 1 - numSpecialCols(); }