f0064c07ab
* Refactor configuration [Part II].
* General changes:
** Remove `Init` methods to avoid ambiguity.
** Remove `Configure(std::map<>)` to avoid redundant copying and prepare for
parameter validation. (`std::vector` is returned from `InitAllowUnknown`).
** Add name to tree updaters for easier debugging.
* Learner changes:
** Make `LearnerImpl` the only source of configuration.
All configurations are stored and carried out by `LearnerImpl::Configure()`.
** Remove booster in C API.
Originally kept for "compatibility reason", but did not state why. So here
we just remove it.
** Add a `metric_names_` field in `LearnerImpl`.
** Remove `LazyInit`. Configuration will always be lazy.
** Run `Configure` before every iteration.
* Predictor changes:
** Allocate both cpu and gpu predictor.
** Remove cpu_predictor from gpu_predictor.
`GBTree` is now used to dispatch the predictor.
** Remove some GPU Predictor tests.
* IO
No IO changes. The binary model format stability is tested by comparing
hashing value of save models between two commits
203 lines
6.6 KiB
C++
203 lines
6.6 KiB
C++
/*!
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* Copyright 2016-2019 XGBoost contributors
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*/
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#ifndef XGBOOST_TESTS_CPP_HELPERS_H_
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#define XGBOOST_TESTS_CPP_HELPERS_H_
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#include <iostream>
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#include <fstream>
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#include <cstdio>
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#include <string>
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#include <vector>
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#include <sys/stat.h>
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#include <sys/types.h>
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#include <gtest/gtest.h>
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#include <xgboost/base.h>
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#include <xgboost/objective.h>
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#include <xgboost/metric.h>
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#include <xgboost/predictor.h>
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#include <xgboost/generic_parameters.h>
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#include "../../src/common/common.h"
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#if defined(__CUDACC__)
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#define DeclareUnifiedTest(name) GPU ## name
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#else
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#define DeclareUnifiedTest(name) name
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#endif
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#if defined(__CUDACC__)
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#define NGPUS 1
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#else
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#define NGPUS 0
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#endif
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bool FileExists(const std::string& filename);
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int64_t GetFileSize(const std::string& filename);
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void CreateSimpleTestData(const std::string& filename);
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void CreateBigTestData(const std::string& filename, size_t n_entries);
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void CheckObjFunction(xgboost::ObjFunction * obj,
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std::vector<xgboost::bst_float> preds,
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std::vector<xgboost::bst_float> labels,
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std::vector<xgboost::bst_float> weights,
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std::vector<xgboost::bst_float> out_grad,
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std::vector<xgboost::bst_float> out_hess);
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void CheckRankingObjFunction(xgboost::ObjFunction * obj,
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std::vector<xgboost::bst_float> preds,
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std::vector<xgboost::bst_float> labels,
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std::vector<xgboost::bst_float> weights,
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std::vector<xgboost::bst_uint> groups,
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std::vector<xgboost::bst_float> out_grad,
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std::vector<xgboost::bst_float> out_hess);
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xgboost::bst_float GetMetricEval(
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xgboost::Metric * metric,
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xgboost::HostDeviceVector<xgboost::bst_float> preds,
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std::vector<xgboost::bst_float> labels,
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std::vector<xgboost::bst_float> weights = std::vector<xgboost::bst_float> ());
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namespace xgboost {
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bool IsNear(std::vector<xgboost::bst_float>::const_iterator _beg1,
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std::vector<xgboost::bst_float>::const_iterator _end1,
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std::vector<xgboost::bst_float>::const_iterator _beg2);
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/*!
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* \brief Linear congruential generator.
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*
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* The distribution defined in std is not portable. Given the same seed, it
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* migth produce different outputs on different platforms or with different
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* compilers. The SimpleLCG implemented here is to make sure all tests are
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* reproducible.
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*/
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class SimpleLCG {
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private:
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using StateType = int64_t;
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static StateType constexpr default_init_ = 3;
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static StateType constexpr default_alpha_ = 61;
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static StateType constexpr max_value_ = ((StateType)1 << 32) - 1;
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StateType state_;
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StateType const alpha_;
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StateType const mod_;
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StateType const seed_;
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public:
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SimpleLCG() : state_{default_init_},
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alpha_{default_alpha_}, mod_{max_value_}, seed_{state_}{}
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/*!
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* \brief Initialize SimpleLCG.
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*
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* \param state Initial state, can also be considered as seed. If set to
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* zero, SimpleLCG will use internal default value.
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* \param alpha multiplier
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* \param mod modulo
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*/
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SimpleLCG(StateType state,
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StateType alpha=default_alpha_, StateType mod=max_value_)
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: state_{state == 0 ? default_init_ : state},
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alpha_{alpha}, mod_{mod} , seed_{state} {}
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StateType operator()();
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StateType Min() const;
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StateType Max() const;
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};
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template <typename ResultT>
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class SimpleRealUniformDistribution {
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private:
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ResultT const lower;
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ResultT const upper;
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/*! \brief Over-simplified version of std::generate_canonical. */
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template <size_t Bits, typename GeneratorT>
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ResultT GenerateCanonical(GeneratorT* rng) const {
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static_assert(std::is_floating_point<ResultT>::value,
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"Result type must be floating point.");
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long double const r = (static_cast<long double>(rng->Max())
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- static_cast<long double>(rng->Min())) + 1.0L;
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size_t const log2r = std::log(r) / std::log(2.0L);
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size_t m = std::max<size_t>(1UL, (Bits + log2r - 1UL) / log2r);
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ResultT sum_value = 0, r_k = 1;
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for (size_t k = m; k != 0; --k) {
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sum_value += ResultT((*rng)() - rng->Min()) * r_k;
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r_k *= r;
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}
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ResultT res = sum_value / r_k;
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return res;
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}
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public:
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SimpleRealUniformDistribution(ResultT l, ResultT u) :
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lower{l}, upper{u} {}
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template <typename GeneratorT>
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ResultT operator()(GeneratorT* rng) const {
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ResultT tmp = GenerateCanonical<std::numeric_limits<ResultT>::digits,
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GeneratorT>(rng);
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return (tmp * (upper - lower)) + lower;
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}
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};
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/**
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* \fn std::shared_ptr<xgboost::DMatrix> CreateDMatrix(int rows, int columns, float sparsity, int seed);
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*
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* \brief Creates dmatrix with uniform random data between 0-1.
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*
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* \param rows The rows.
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* \param columns The columns.
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* \param sparsity The sparsity.
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* \param seed The seed.
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*
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* \return The new d matrix.
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*/
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std::shared_ptr<xgboost::DMatrix> *CreateDMatrix(int rows, int columns,
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float sparsity, int seed = 0);
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std::unique_ptr<DMatrix> CreateSparsePageDMatrix(
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size_t n_entries, size_t page_size, std::string tmp_file);
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/**
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* \fn std::unique_ptr<DMatrix> CreateSparsePageDMatrixWithRC(size_t n_rows, size_t n_cols,
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* size_t page_size);
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*
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* \brief Creates dmatrix with some records, each record containing random number of
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* features in [1, n_cols]
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*
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* \param n_rows Number of records to create.
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* \param n_cols Max number of features within that record.
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* \param page_size Sparse page size for the pages within the dmatrix. If page size is 0
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* then the entire dmatrix is resident in memory; else, multiple sparse pages
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* of page size are created and backed to disk, which would have to be
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* streamed in at point of use.
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* \param deterministic The content inside the dmatrix is constant for this configuration, if true;
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* else, the content changes every time this method is invoked
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*
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* \return The new dmatrix.
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*/
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std::unique_ptr<DMatrix> CreateSparsePageDMatrixWithRC(size_t n_rows, size_t n_cols,
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size_t page_size, bool deterministic);
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gbm::GBTreeModel CreateTestModel();
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inline GenericParameter CreateEmptyGenericParam(int gpu_id, int n_gpus) {
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xgboost::GenericParameter tparam;
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std::vector<std::pair<std::string, std::string>> args {
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{"gpu_id", std::to_string(gpu_id)},
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{"n_gpus", std::to_string(n_gpus)}};
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tparam.Init(args);
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return tparam;
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}
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} // namespace xgboost
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#endif
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