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sharded_optimization_utils.cc
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sharded_optimization_utils.cc
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// Copyright 2010-2024 Google LLC
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "ortools/pdlp/sharded_optimization_utils.h"
#include <algorithm>
#include <cmath>
#include <cstdint>
#include <limits>
#include <optional>
#include <random>
#include <utility>
#include <vector>
#include "Eigen/Core"
#include "Eigen/SparseCore"
#include "absl/log/check.h"
#include "absl/random/distributions.h"
#include "ortools/base/logging.h"
#include "ortools/base/mathutil.h"
#include "ortools/pdlp/quadratic_program.h"
#include "ortools/pdlp/sharded_quadratic_program.h"
#include "ortools/pdlp/sharder.h"
namespace operations_research::pdlp {
constexpr double kInfinity = std::numeric_limits<double>::infinity();
using ::Eigen::ColMajor;
using ::Eigen::SparseMatrix;
using ::Eigen::VectorXd;
using ::Eigen::VectorXi;
ShardedWeightedAverage::ShardedWeightedAverage(const Sharder* sharder)
: sharder_(sharder) {
average_ = ZeroVector(*sharder_);
}
// We considered the five averaging algorithms M_* listed on the first page of
// https://www.jstor.org/stable/2286154 and the Kahan summation algorithm
// (https://en.wikipedia.org/wiki/Kahan_summation_algorithm). Of these only M_14
// satisfies our desired property that a constant sequence is averaged without
// roundoff while requiring only a single vector be stored. We therefore use
// M_14 (actually a natural weighted generalization, see below).
void ShardedWeightedAverage::Add(const VectorXd& datapoint, double weight) {
CHECK_GE(weight, 0.0);
CHECK_EQ(datapoint.size(), average_.size());
// This `if` protects against NaN if `sum_weights_` also == 0.0.
if (weight > 0.0) {
const double weight_ratio = weight / (sum_weights_ + weight);
sharder_->ParallelForEachShard([&](const Sharder::Shard& shard) {
shard(average_) += weight_ratio * (shard(datapoint) - shard(average_));
});
sum_weights_ += weight;
}
++num_terms_;
}
void ShardedWeightedAverage::Clear() {
SetZero(*sharder_, average_);
sum_weights_ = 0.0;
num_terms_ = 0;
}
VectorXd ShardedWeightedAverage::ComputeAverage() const {
VectorXd result;
// TODO(user): consider returning a reference to avoid this copy.
AssignVector(average_, *sharder_, result);
return result;
}
namespace {
double CombineBounds(const double v1, const double v2) {
double max = 0.0;
if (std::abs(v1) < kInfinity) {
max = std::abs(v1);
}
if (std::abs(v2) < kInfinity) {
max = std::max(max, std::abs(v2));
}
return max;
}
struct VectorInfo {
int64_t num_finite_nonzero = 0;
int64_t num_infinite = 0;
int64_t num_zero = 0;
// The largest absolute value of the finite non-zero values.
double largest = 0.0;
// The smallest absolute value of the finite non-zero values.
double smallest = 0.0;
// The average absolute value of the finite values.
double average = 0.0;
// The L2 norm of the finite values.
double l2_norm = 0.0;
};
struct InfNormInfo {
VectorInfo row_norms;
VectorInfo col_norms;
};
// `VectorInfoAccumulator` accumulates values for a `VectorInfo`.
// NOTE: In `VectorInfo`, the max and min of an empty set is 0.0 by convention.
// In `VectorInfoAccumulator`, it is -`kInfinity` and `kInfinity` to simplify
// adding additional values.
class VectorInfoAccumulator {
public:
VectorInfoAccumulator() {}
// Move-only even though move and copy are the same cost, to help catch
// unintentional moves/copies (which are probably performance bugs).
VectorInfoAccumulator(const VectorInfoAccumulator&) = delete;
VectorInfoAccumulator& operator=(const VectorInfoAccumulator&) = delete;
VectorInfoAccumulator(VectorInfoAccumulator&&) = default;
VectorInfoAccumulator& operator=(VectorInfoAccumulator&&) = default;
void Add(double value);
void Add(const VectorInfoAccumulator& other);
explicit operator VectorInfo() const;
private:
int64_t num_infinite_ = 0;
int64_t num_zero_ = 0;
int64_t num_finite_nonzero_ = 0;
double max_ = -kInfinity;
double min_ = kInfinity;
double sum_ = 0.0;
double sum_squared_ = 0.0;
};
void VectorInfoAccumulator::Add(const double value) {
if (std::isinf(value)) {
++num_infinite_;
} else if (value == 0) {
++num_zero_;
} else {
++num_finite_nonzero_;
const double abs_value = std::abs(value);
max_ = std::max(max_, abs_value);
min_ = std::min(min_, abs_value);
sum_ += abs_value;
sum_squared_ += abs_value * abs_value;
}
}
void VectorInfoAccumulator::Add(const VectorInfoAccumulator& other) {
num_infinite_ += other.num_infinite_;
num_zero_ += other.num_zero_;
num_finite_nonzero_ += other.num_finite_nonzero_;
max_ = std::max(max_, other.max_);
min_ = std::min(min_, other.min_);
sum_ += other.sum_;
sum_squared_ += other.sum_squared_;
}
VectorInfoAccumulator::operator VectorInfo() const {
return VectorInfo{
.num_finite_nonzero = num_finite_nonzero_,
.num_infinite = num_infinite_,
.num_zero = num_zero_,
.largest = num_finite_nonzero_ > 0 ? max_ : 0.0,
.smallest = num_finite_nonzero_ > 0 ? min_ : 0.0,
.average = num_finite_nonzero_ + num_zero_ > 0
? sum_ / (num_finite_nonzero_ + num_zero_)
: std::numeric_limits<double>::quiet_NaN(),
.l2_norm = std::sqrt(sum_squared_),
};
}
VectorInfo CombineAccumulators(
const std::vector<VectorInfoAccumulator>& accumulators) {
VectorInfoAccumulator result;
for (const VectorInfoAccumulator& accumulator : accumulators) {
result.Add(accumulator);
}
return VectorInfo(result);
}
// TODO(b/223148482): Switch `vec` to `const Eigen::Ref<const VectorXd>` if/when
// `Sharder` supports `Eigen::Ref`, to avoid a copy when called on
// `qp.Qp().objective_matrix->diagonal()`.
VectorInfo ComputeVectorInfo(const VectorXd& vec, const Sharder& sharder) {
std::vector<VectorInfoAccumulator> local_accumulator(sharder.NumShards());
sharder.ParallelForEachShard([&](const Sharder::Shard& shard) {
VectorInfoAccumulator shard_accumulator;
for (double element : shard(vec)) {
shard_accumulator.Add(element);
}
local_accumulator[shard.Index()] = std::move(shard_accumulator);
});
return CombineAccumulators(local_accumulator);
}
VectorInfo VariableBoundGapInfo(const VectorXd& lower_bounds,
const VectorXd& upper_bounds,
const Sharder& sharder) {
std::vector<VectorInfoAccumulator> local_accumulator(sharder.NumShards());
sharder.ParallelForEachShard([&](const Sharder::Shard& shard) {
VectorInfoAccumulator shard_accumulator;
for (double element : shard(upper_bounds) - shard(lower_bounds)) {
shard_accumulator.Add(element);
}
local_accumulator[shard.Index()] = std::move(shard_accumulator);
});
return CombineAccumulators(local_accumulator);
}
VectorInfo MatrixAbsElementInfo(
const SparseMatrix<double, ColMajor, int64_t>& matrix,
const Sharder& sharder) {
std::vector<VectorInfoAccumulator> local_accumulator(sharder.NumShards());
sharder.ParallelForEachShard([&](const Sharder::Shard& shard) {
VectorInfoAccumulator shard_accumulator;
const auto matrix_shard = shard(matrix);
for (int64_t col_idx = 0; col_idx < matrix_shard.outerSize(); ++col_idx) {
for (decltype(matrix_shard)::InnerIterator it(matrix_shard, col_idx); it;
++it) {
shard_accumulator.Add(it.value());
}
}
local_accumulator[shard.Index()] = std::move(shard_accumulator);
});
return CombineAccumulators(local_accumulator);
}
VectorInfo CombinedBoundsInfo(const VectorXd& rhs_upper_bounds,
const VectorXd& rhs_lower_bounds,
const Sharder& sharder) {
std::vector<VectorInfoAccumulator> local_accumulator(sharder.NumShards());
sharder.ParallelForEachShard([&](const Sharder::Shard& shard) {
VectorInfoAccumulator shard_accumulator;
const auto lb_shard = shard(rhs_lower_bounds);
const auto ub_shard = shard(rhs_upper_bounds);
for (int64_t i = 0; i < lb_shard.size(); ++i) {
shard_accumulator.Add(CombineBounds(ub_shard[i], lb_shard[i]));
}
local_accumulator[shard.Index()] = std::move(shard_accumulator);
});
return CombineAccumulators(local_accumulator);
}
InfNormInfo ConstraintMatrixRowColInfo(
const SparseMatrix<double, ColMajor, int64_t>& constraint_matrix,
const SparseMatrix<double, ColMajor, int64_t>& constraint_matrix_transpose,
const Sharder& matrix_sharder, const Sharder& matrix_transpose_sharder,
const Sharder& primal_sharder, const Sharder& dual_sharder) {
VectorXd row_norms = ScaledColLInfNorm(
constraint_matrix_transpose,
/*col_scaling_vec=*/OnesVector(primal_sharder),
/*row_scaling_vec=*/OnesVector(dual_sharder), matrix_transpose_sharder);
VectorXd col_norms = ScaledColLInfNorm(
constraint_matrix,
/*row_scaling_vec=*/OnesVector(dual_sharder),
/*col_scaling_vec=*/OnesVector(primal_sharder), matrix_sharder);
return InfNormInfo{.row_norms = ComputeVectorInfo(row_norms, dual_sharder),
.col_norms = ComputeVectorInfo(col_norms, primal_sharder)};
}
} // namespace
QuadraticProgramStats ComputeStats(const ShardedQuadraticProgram& qp) {
// Caution: if the constraint matrix is empty, elementwise operations
// (like `.coeffs().maxCoeff()` or `.minCoeff()`) will fail.
InfNormInfo cons_matrix_norm_info = ConstraintMatrixRowColInfo(
qp.Qp().constraint_matrix, qp.TransposedConstraintMatrix(),
qp.ConstraintMatrixSharder(), qp.TransposedConstraintMatrixSharder(),
qp.PrimalSharder(), qp.DualSharder());
VectorInfo cons_matrix_info = MatrixAbsElementInfo(
qp.Qp().constraint_matrix, qp.ConstraintMatrixSharder());
VectorInfo combined_bounds_info =
CombinedBoundsInfo(qp.Qp().constraint_lower_bounds,
qp.Qp().constraint_upper_bounds, qp.DualSharder());
VectorInfo combined_variable_bounds_info =
CombinedBoundsInfo(qp.Qp().variable_lower_bounds,
qp.Qp().variable_upper_bounds, qp.PrimalSharder());
VectorInfo obj_vec_info =
ComputeVectorInfo(qp.Qp().objective_vector, qp.PrimalSharder());
VectorInfo gaps_info =
VariableBoundGapInfo(qp.Qp().variable_lower_bounds,
qp.Qp().variable_upper_bounds, qp.PrimalSharder());
QuadraticProgramStats program_stats;
program_stats.set_num_variables(qp.PrimalSize());
program_stats.set_num_constraints(qp.DualSize());
program_stats.set_constraint_matrix_col_min_l_inf_norm(
cons_matrix_norm_info.col_norms.smallest);
program_stats.set_constraint_matrix_row_min_l_inf_norm(
cons_matrix_norm_info.row_norms.smallest);
program_stats.set_constraint_matrix_num_nonzeros(
cons_matrix_info.num_finite_nonzero);
program_stats.set_constraint_matrix_abs_max(cons_matrix_info.largest);
program_stats.set_constraint_matrix_abs_min(cons_matrix_info.smallest);
program_stats.set_constraint_matrix_abs_avg(cons_matrix_info.average);
program_stats.set_constraint_matrix_l2_norm(cons_matrix_info.l2_norm);
program_stats.set_combined_bounds_max(combined_bounds_info.largest);
program_stats.set_combined_bounds_min(combined_bounds_info.smallest);
program_stats.set_combined_bounds_avg(combined_bounds_info.average);
program_stats.set_combined_bounds_l2_norm(combined_bounds_info.l2_norm);
program_stats.set_combined_variable_bounds_max(
combined_variable_bounds_info.largest);
program_stats.set_combined_variable_bounds_min(
combined_variable_bounds_info.smallest);
program_stats.set_combined_variable_bounds_avg(
combined_variable_bounds_info.average);
program_stats.set_combined_variable_bounds_l2_norm(
combined_variable_bounds_info.l2_norm);
program_stats.set_variable_bound_gaps_num_finite(
gaps_info.num_finite_nonzero + gaps_info.num_zero);
program_stats.set_variable_bound_gaps_max(gaps_info.largest);
program_stats.set_variable_bound_gaps_min(gaps_info.smallest);
program_stats.set_variable_bound_gaps_avg(gaps_info.average);
program_stats.set_variable_bound_gaps_l2_norm(gaps_info.l2_norm);
program_stats.set_objective_vector_abs_max(obj_vec_info.largest);
program_stats.set_objective_vector_abs_min(obj_vec_info.smallest);
program_stats.set_objective_vector_abs_avg(obj_vec_info.average);
program_stats.set_objective_vector_l2_norm(obj_vec_info.l2_norm);
if (IsLinearProgram(qp.Qp())) {
program_stats.set_objective_matrix_num_nonzeros(0);
program_stats.set_objective_matrix_abs_max(0);
program_stats.set_objective_matrix_abs_min(0);
program_stats.set_objective_matrix_abs_avg(
std::numeric_limits<double>::quiet_NaN());
program_stats.set_objective_matrix_l2_norm(0);
} else {
VectorInfo obj_matrix_info = ComputeVectorInfo(
qp.Qp().objective_matrix->diagonal(), qp.PrimalSharder());
program_stats.set_objective_matrix_num_nonzeros(
obj_matrix_info.num_finite_nonzero);
program_stats.set_objective_matrix_abs_max(obj_matrix_info.largest);
program_stats.set_objective_matrix_abs_min(obj_matrix_info.smallest);
program_stats.set_objective_matrix_abs_avg(obj_matrix_info.average);
program_stats.set_objective_matrix_l2_norm(obj_matrix_info.l2_norm);
}
return program_stats;
}
namespace {
enum class ScalingNorm { kL2, kLInf };
// Divides `vector` (componentwise) by the square root of `divisor`, updating
// `vector` in-place. If a component of `divisor` is equal to zero, leaves the
// component of `vector` unchanged. `sharder` should have the same size as
// `vector`. For best performance `sharder` should have been created with the
// `Sharder(int64_t, int, ThreadPool*)` constructor.
void DivideBySquareRootOfDivisor(const VectorXd& divisor,
const Sharder& sharder, VectorXd& vector) {
sharder.ParallelForEachShard([&](const Sharder::Shard& shard) {
auto vec_shard = shard(vector);
const auto divisor_shard = shard(divisor);
for (int64_t index = 0; index < vec_shard.size(); ++index) {
if (divisor_shard[index] != 0) {
vec_shard[index] /= std::sqrt(divisor_shard[index]);
}
}
});
}
void ApplyScalingIterationsForNorm(const ShardedQuadraticProgram& sharded_qp,
const int num_iterations,
const ScalingNorm norm,
VectorXd& row_scaling_vec,
VectorXd& col_scaling_vec) {
const QuadraticProgram& qp = sharded_qp.Qp();
const int64_t num_col = qp.constraint_matrix.cols();
const int64_t num_row = qp.constraint_matrix.rows();
CHECK_EQ(num_col, col_scaling_vec.size());
CHECK_EQ(num_row, row_scaling_vec.size());
for (int i = 0; i < num_iterations; ++i) {
VectorXd col_norm;
VectorXd row_norm;
switch (norm) {
case ScalingNorm::kL2: {
col_norm = ScaledColL2Norm(qp.constraint_matrix, row_scaling_vec,
col_scaling_vec,
sharded_qp.ConstraintMatrixSharder());
row_norm = ScaledColL2Norm(
sharded_qp.TransposedConstraintMatrix(), col_scaling_vec,
row_scaling_vec, sharded_qp.TransposedConstraintMatrixSharder());
break;
}
case ScalingNorm::kLInf: {
col_norm = ScaledColLInfNorm(qp.constraint_matrix, row_scaling_vec,
col_scaling_vec,
sharded_qp.ConstraintMatrixSharder());
row_norm = ScaledColLInfNorm(
sharded_qp.TransposedConstraintMatrix(), col_scaling_vec,
row_scaling_vec, sharded_qp.TransposedConstraintMatrixSharder());
break;
}
}
DivideBySquareRootOfDivisor(col_norm, sharded_qp.PrimalSharder(),
col_scaling_vec);
DivideBySquareRootOfDivisor(row_norm, sharded_qp.DualSharder(),
row_scaling_vec);
}
}
} // namespace
void LInfRuizRescaling(const ShardedQuadraticProgram& sharded_qp,
const int num_iterations, VectorXd& row_scaling_vec,
VectorXd& col_scaling_vec) {
ApplyScalingIterationsForNorm(sharded_qp, num_iterations, ScalingNorm::kLInf,
row_scaling_vec, col_scaling_vec);
}
void L2NormRescaling(const ShardedQuadraticProgram& sharded_qp,
VectorXd& row_scaling_vec, VectorXd& col_scaling_vec) {
ApplyScalingIterationsForNorm(sharded_qp, /*num_iterations=*/1,
ScalingNorm::kL2, row_scaling_vec,
col_scaling_vec);
}
ScalingVectors ApplyRescaling(const RescalingOptions& rescaling_options,
ShardedQuadraticProgram& sharded_qp) {
ScalingVectors scaling{
.row_scaling_vec = OnesVector(sharded_qp.DualSharder()),
.col_scaling_vec = OnesVector(sharded_qp.PrimalSharder())};
bool do_rescale = false;
if (rescaling_options.l_inf_ruiz_iterations > 0) {
do_rescale = true;
LInfRuizRescaling(sharded_qp, rescaling_options.l_inf_ruiz_iterations,
scaling.row_scaling_vec, scaling.col_scaling_vec);
}
if (rescaling_options.l2_norm_rescaling) {
do_rescale = true;
L2NormRescaling(sharded_qp, scaling.row_scaling_vec,
scaling.col_scaling_vec);
}
if (do_rescale) {
sharded_qp.RescaleQuadraticProgram(scaling.col_scaling_vec,
scaling.row_scaling_vec);
}
return scaling;
}
LagrangianPart ComputePrimalGradient(const ShardedQuadraticProgram& sharded_qp,
const VectorXd& primal_solution,
const VectorXd& dual_product) {
LagrangianPart result{.gradient = VectorXd(sharded_qp.PrimalSize())};
const QuadraticProgram& qp = sharded_qp.Qp();
VectorXd value_parts(sharded_qp.PrimalSharder().NumShards());
sharded_qp.PrimalSharder().ParallelForEachShard(
[&](const Sharder::Shard& shard) {
if (IsLinearProgram(qp)) {
shard(result.gradient) =
shard(qp.objective_vector) - shard(dual_product);
value_parts[shard.Index()] =
shard(primal_solution).dot(shard(result.gradient));
} else {
// Note: using `auto` instead of `VectorXd` for the type of
// `objective_product` causes eigen to defer the matrix product until
// it is used (twice).
const VectorXd objective_product =
shard(*qp.objective_matrix) * shard(primal_solution);
shard(result.gradient) = shard(qp.objective_vector) +
objective_product - shard(dual_product);
value_parts[shard.Index()] =
shard(primal_solution)
.dot(shard(result.gradient) - 0.5 * objective_product);
}
});
result.value = value_parts.sum();
return result;
}
double DualSubgradientCoefficient(const double constraint_lower_bound,
const double constraint_upper_bound,
const double dual,
const double primal_product) {
if (dual < 0.0) {
return constraint_upper_bound;
} else if (dual > 0.0) {
return constraint_lower_bound;
} else if (std::isfinite(constraint_lower_bound) &&
std::isfinite(constraint_upper_bound)) {
if (primal_product < constraint_lower_bound) {
return constraint_lower_bound;
} else if (primal_product > constraint_upper_bound) {
return constraint_upper_bound;
} else {
return primal_product;
}
} else if (std::isfinite(constraint_lower_bound)) {
return constraint_lower_bound;
} else if (std::isfinite(constraint_upper_bound)) {
return constraint_upper_bound;
} else {
return 0.0;
}
}
LagrangianPart ComputeDualGradient(const ShardedQuadraticProgram& sharded_qp,
const VectorXd& dual_solution,
const VectorXd& primal_product) {
LagrangianPart result{.gradient = VectorXd(sharded_qp.DualSize())};
const QuadraticProgram& qp = sharded_qp.Qp();
VectorXd value_parts(sharded_qp.DualSharder().NumShards());
sharded_qp.DualSharder().ParallelForEachShard(
[&](const Sharder::Shard& shard) {
const auto constraint_lower_bounds = shard(qp.constraint_lower_bounds);
const auto constraint_upper_bounds = shard(qp.constraint_upper_bounds);
const auto dual_solution_shard = shard(dual_solution);
auto dual_gradient_shard = shard(result.gradient);
const auto primal_product_shard = shard(primal_product);
double value_sum = 0.0;
for (int64_t i = 0; i < dual_gradient_shard.size(); ++i) {
dual_gradient_shard[i] = DualSubgradientCoefficient(
constraint_lower_bounds[i], constraint_upper_bounds[i],
dual_solution_shard[i], primal_product_shard[i]);
value_sum += dual_gradient_shard[i] * dual_solution_shard[i];
}
value_parts[shard.Index()] = value_sum;
dual_gradient_shard -= primal_product_shard;
});
result.value = value_parts.sum();
return result;
}
namespace {
using ::Eigen::ColMajor;
using ::Eigen::SparseMatrix;
// Scales `vector` (in-place) to have norm 1, unless it has norm 0 (in which
// case it is left unscaled). Returns the original norm of `vector`.
double NormalizeVector(const Sharder& sharder, VectorXd& vector) {
const double norm = Norm(vector, sharder);
if (norm != 0.0) {
sharder.ParallelForEachShard(
[&](const Sharder::Shard& shard) { shard(vector) /= norm; });
}
return norm;
}
// Estimates the probability that the power method, after k iterations, has
// relative error > `epsilon`. This is based on Theorem 4.1(a) (on page 13) from
// "Estimating the Largest Eigenvalue by the Power and Lanczos Algorithms with a
// Random Start"
// https://pdfs.semanticscholar.org/2b2e/a941e55e5fa2ee9d8f4ff393c14482051143.pdf
double PowerMethodFailureProbability(int64_t dimension, double epsilon, int k) {
if (k < 2 || epsilon <= 0.0) {
// The theorem requires `epsilon > 0` and `k >= 2`.
return 1.0;
}
return std::min(0.824, 0.354 / std::sqrt(epsilon * (k - 1))) *
std::sqrt(dimension) * std::pow(1.0 - epsilon, k - 0.5);
}
SingularValueAndIterations EstimateMaximumSingularValue(
const SparseMatrix<double, ColMajor, int64_t>& matrix,
const SparseMatrix<double, ColMajor, int64_t>& matrix_transpose,
const std::optional<VectorXd>& active_set_indicator,
const std::optional<VectorXd>& transpose_active_set_indicator,
const Sharder& matrix_sharder, const Sharder& matrix_transpose_sharder,
const Sharder& primal_vector_sharder, const Sharder& dual_vector_sharder,
const double desired_relative_error, const double failure_probability,
std::mt19937& mt_generator) {
const int64_t dimension = matrix.cols();
VectorXd eigenvector(dimension);
// Even though it will be slower, we initialize `eigenvector` sequentially so
// that the result doesn't depend on the number of threads.
for (double& entry : eigenvector) {
entry = absl::Gaussian<double>(mt_generator);
}
if (active_set_indicator.has_value()) {
CoefficientWiseProductInPlace(*active_set_indicator, primal_vector_sharder,
eigenvector);
}
NormalizeVector(primal_vector_sharder, eigenvector);
double eigenvalue_estimate = 0.0;
int num_iterations = 0;
// The maximum singular value of A is the square root of the maximum
// eigenvalue of A^T A. `epsilon` is the relative error needed for the maximum
// eigenvalue of A^T A that gives `desired_relative_error` for the maximum
// singular value of A.
const double epsilon = 1.0 - MathUtil::Square(1.0 - desired_relative_error);
while (PowerMethodFailureProbability(dimension, epsilon, num_iterations) >
failure_probability) {
VectorXd dual_eigenvector = TransposedMatrixVectorProduct(
matrix_transpose, eigenvector, matrix_transpose_sharder);
if (transpose_active_set_indicator.has_value()) {
CoefficientWiseProductInPlace(*transpose_active_set_indicator,
dual_vector_sharder, dual_eigenvector);
}
VectorXd next_eigenvector =
TransposedMatrixVectorProduct(matrix, dual_eigenvector, matrix_sharder);
if (active_set_indicator.has_value()) {
CoefficientWiseProductInPlace(*active_set_indicator,
primal_vector_sharder, next_eigenvector);
}
eigenvalue_estimate =
Dot(eigenvector, next_eigenvector, primal_vector_sharder);
eigenvector = std::move(next_eigenvector);
++num_iterations;
const double primal_norm =
NormalizeVector(primal_vector_sharder, eigenvector);
VLOG(1) << "Iteration " << num_iterations << " singular value estimate "
<< std::sqrt(eigenvalue_estimate) << " primal norm " << primal_norm;
}
return SingularValueAndIterations{
.singular_value = std::sqrt(eigenvalue_estimate),
.num_iterations = num_iterations,
.estimated_relative_error = desired_relative_error};
}
// Given `primal_solution`, compute a {0, 1}-valued vector that is nonzero in
// all the coordinates that are not saturating the primal variable bounds.
VectorXd ComputePrimalActiveSetIndicator(
const ShardedQuadraticProgram& sharded_qp,
const VectorXd& primal_solution) {
VectorXd indicator(sharded_qp.PrimalSize());
sharded_qp.PrimalSharder().ParallelForEachShard(
[&](const Sharder::Shard& shard) {
const auto lower_bound_shard =
shard(sharded_qp.Qp().variable_lower_bounds);
const auto upper_bound_shard =
shard(sharded_qp.Qp().variable_upper_bounds);
const auto primal_solution_shard = shard(primal_solution);
auto indicator_shard = shard(indicator);
const int64_t shard_size =
sharded_qp.PrimalSharder().ShardSize(shard.Index());
for (int64_t i = 0; i < shard_size; ++i) {
if ((primal_solution_shard[i] == lower_bound_shard[i]) ||
(primal_solution_shard[i] == upper_bound_shard[i])) {
indicator_shard[i] = 0.0;
} else {
indicator_shard[i] = 1.0;
}
}
});
return indicator;
}
// Like `ComputePrimalActiveSetIndicator(sharded_qp, primal_solution)`, but this
// time using the implicit bounds on the dual variables.
VectorXd ComputeDualActiveSetIndicator(
const ShardedQuadraticProgram& sharded_qp, const VectorXd& dual_solution) {
VectorXd indicator(sharded_qp.DualSize());
sharded_qp.DualSharder().ParallelForEachShard(
[&](const Sharder::Shard& shard) {
const auto lower_bound_shard =
shard(sharded_qp.Qp().constraint_lower_bounds);
const auto upper_bound_shard =
shard(sharded_qp.Qp().constraint_upper_bounds);
const auto dual_solution_shard = shard(dual_solution);
auto indicator_shard = shard(indicator);
const int64_t shard_size =
sharded_qp.DualSharder().ShardSize(shard.Index());
for (int64_t i = 0; i < shard_size; ++i) {
if (dual_solution_shard[i] == 0.0 &&
(std::isinf(lower_bound_shard[i]) ||
std::isinf(upper_bound_shard[i]))) {
indicator_shard[i] = 0.0;
} else {
indicator_shard[i] = 1.0;
}
}
});
return indicator;
}
} // namespace
SingularValueAndIterations EstimateMaximumSingularValueOfConstraintMatrix(
const ShardedQuadraticProgram& sharded_qp,
const std::optional<VectorXd>& primal_solution,
const std::optional<VectorXd>& dual_solution,
const double desired_relative_error, const double failure_probability,
std::mt19937& mt_generator) {
std::optional<VectorXd> primal_active_set_indicator;
std::optional<VectorXd> dual_active_set_indicator;
if (primal_solution.has_value()) {
primal_active_set_indicator =
ComputePrimalActiveSetIndicator(sharded_qp, *primal_solution);
}
if (dual_solution.has_value()) {
dual_active_set_indicator =
ComputeDualActiveSetIndicator(sharded_qp, *dual_solution);
}
return EstimateMaximumSingularValue(
sharded_qp.Qp().constraint_matrix,
sharded_qp.TransposedConstraintMatrix(), primal_active_set_indicator,
dual_active_set_indicator, sharded_qp.ConstraintMatrixSharder(),
sharded_qp.TransposedConstraintMatrixSharder(),
sharded_qp.PrimalSharder(), sharded_qp.DualSharder(),
desired_relative_error, failure_probability, mt_generator);
}
bool HasValidBounds(const ShardedQuadraticProgram& sharded_qp) {
const QuadraticProgram& qp = sharded_qp.Qp();
const bool constraint_bounds_valid =
sharded_qp.DualSharder().ParallelTrueForAllShards(
[&](const Sharder::Shard& shard) {
return (shard(qp.constraint_lower_bounds).array() <=
shard(qp.constraint_upper_bounds).array() &&
shard(qp.constraint_lower_bounds).array() < kInfinity &&
shard(qp.constraint_upper_bounds).array() > -kInfinity)
.all();
});
const bool variable_bounds_valid =
sharded_qp.PrimalSharder().ParallelTrueForAllShards(
[&](const Sharder::Shard& shard) {
return (shard(qp.variable_lower_bounds).array() <=
shard(qp.variable_upper_bounds).array() &&
shard(qp.variable_lower_bounds).array() < kInfinity &&
shard(qp.variable_upper_bounds).array() > -kInfinity)
.all();
});
return constraint_bounds_valid && variable_bounds_valid;
}
void ProjectToPrimalVariableBounds(const ShardedQuadraticProgram& sharded_qp,
VectorXd& primal,
const bool use_feasibility_bounds) {
const auto make_finite_values_zero = [](const double x) {
return std::isfinite(x) ? 0.0 : x;
};
sharded_qp.PrimalSharder().ParallelForEachShard(
[&](const Sharder::Shard& shard) {
const QuadraticProgram& qp = sharded_qp.Qp();
if (use_feasibility_bounds) {
shard(primal) =
shard(primal)
.cwiseMin(shard(qp.variable_upper_bounds)
.unaryExpr(make_finite_values_zero))
.cwiseMax(shard(qp.variable_lower_bounds)
.unaryExpr(make_finite_values_zero));
} else {
shard(primal) = shard(primal)
.cwiseMin(shard(qp.variable_upper_bounds))
.cwiseMax(shard(qp.variable_lower_bounds));
}
});
}
void ProjectToDualVariableBounds(const ShardedQuadraticProgram& sharded_qp,
VectorXd& dual) {
const QuadraticProgram& qp = sharded_qp.Qp();
sharded_qp.DualSharder().ParallelForEachShard(
[&](const Sharder::Shard& shard) {
const auto lower_bound_shard = shard(qp.constraint_lower_bounds);
const auto upper_bound_shard = shard(qp.constraint_upper_bounds);
auto dual_shard = shard(dual);
// TODO(user): Investigate whether it is more efficient to
// use .cwiseMax() + .cwiseMin() with unaryExpr(s) that map
// upper_bound_shard and lower_bound_shard to appropriate values.
for (int64_t i = 0; i < dual_shard.size(); ++i) {
if (!std::isfinite(upper_bound_shard[i])) {
dual_shard[i] = std::max(dual_shard[i], 0.0);
}
if (!std::isfinite(lower_bound_shard[i])) {
dual_shard[i] = std::min(dual_shard[i], 0.0);
}
}
});
}
} // namespace operations_research::pdlp