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MIPLearn.jl
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Make dual GMI cuts stronger

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fs11_01
Alinson S. Xavier 2 months ago
parent d351d84d58
commit 05e7d1619c
3 changed files with 350 additions and 6 deletions
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4
src/Cuts/tableau/gmi.jl
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@ -185,7 +185,7 @@ function collect_gmi(
) )
end end
function select_gmi_rows(data, basis, x; max_rows = 10, atol = 1e-4) function select_gmi_rows(data, basis, x; max_rows = 10, atol = 0.001)
candidate_rows = [ candidate_rows = [
r for r = 1:length(basis.var_basic) if ( r for r = 1:length(basis.var_basic) if (
(data.var_types[basis.var_basic[r]] != 'C') && (data.var_types[basis.var_basic[r]] != 'C') &&
@ -202,7 +202,7 @@ end
function compute_gmi(data::ProblemData, tableau::Tableau)::ConstraintSet function compute_gmi(data::ProblemData, tableau::Tableau)::ConstraintSet
nrows, ncols = size(tableau.lhs) nrows, ncols = size(tableau.lhs)
ub = Float64[Inf for _ = 1:nrows] ub = Float64[Inf for _ = 1:nrows]
lb = Float64[0.9999 for _ = 1:nrows] lb = Float64[0.999 for _ = 1:nrows]
tableau_I, tableau_J, tableau_V = findnz(tableau.lhs) tableau_I, tableau_J, tableau_V = findnz(tableau.lhs)
lhs_I = Int[] lhs_I = Int[]
lhs_J = Int[] lhs_J = Int[]

341
src/Cuts/tableau/gmi_dual.jl
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@ -7,6 +7,7 @@ using JuMP
using HiGHS using HiGHS
using Random using Random
using DataStructures using DataStructures
using Statistics
import ..H5FieldsExtractor import ..H5FieldsExtractor
@ -25,7 +26,7 @@ function collect_gmi_dual(
mps_filename; mps_filename;
optimizer, optimizer,
max_rounds = 10, max_rounds = 10,
max_cuts_per_round = 500, max_cuts_per_round = 1_000_000,
time_limit = 3_600, time_limit = 3_600,
) )
reset_timer!() reset_timer!()
@ -263,6 +264,342 @@ function collect_gmi_dual(
) )
end end
function collect_gmi_FisSal2011(
mps_filename;
optimizer,
max_rounds = 10_000,
max_cuts_per_round = 1_000_000,
time_limit = 30,
interval_print=1,
max_cut_age=10,
)
reset_timer!()
initial_time = time()
@timeit "Read H5" begin
h5_filename = replace(mps_filename, ".mps.gz" => ".h5")
h5 = H5File(h5_filename, "r")
sol_opt_dict = Dict(
zip(
h5.get_array("static_var_names"),
convert(Array{Float64}, h5.get_array("mip_var_values")),
),
)
obj_mip = h5.get_scalar("mip_obj_value")
h5.file.close()
end
@timeit "Initialize" begin
stats_obj = []
stats_gap = []
stats_ncuts = []
pool = nothing
cut_age = nothing
lambda_curr = nothing
lambda_best = nothing
last_print_time = 0
obj_initial = nothing
obj_curr = 0
obj_best = 0
noimprov_count = 0
backtrack_count = 0
gapcl_best = 0
end
gap(v) = 100 * abs(obj_mip - v) / abs(obj_mip)
gapcl(v) = 100 * (v - obj_initial) / (obj_mip - obj_initial)
function perturb(v, ε=0.001)
p = (1 - ε) .+ 2 * ε * rand(length(v))
return v .* p
end
@timeit "Read problem" begin
model = read_from_file(mps_filename)
set_optimizer(model, optimizer)
end
@timeit "Convert model to standard form" begin
# Extract problem data
data = ProblemData(model)
# Construct optimal solution vector (with correct variable sequence)
sol_opt = [sol_opt_dict[n] for n in data.var_names]
# Assert optimal solution is feasible for the original problem
assert_leq(data.constr_lb, data.constr_lhs * sol_opt)
assert_leq(data.constr_lhs * sol_opt, data.constr_ub)
# Convert to standard form
data_s, transforms = convert_to_standard_form(data)
model_s = to_model(data_s)
vars_s = all_variables(model_s)
orig_obj_s = objective_function(model_s)
set_optimizer(model_s, optimizer)
relax_integrality(model_s)
# Convert optimal solution to standard form
sol_opt_s = forward(transforms, sol_opt)
# Assert converted solution is feasible for standard form problem
assert_eq(data_s.constr_lhs * sol_opt_s, data_s.constr_lb)
end
for round = 1:max_rounds
if round > 1
@timeit "Update objective function" begin
# Build Lagrangian term
lambda_perturbed = perturb(lambda_curr)
v = sparse(pool.lhs' * lambda_perturbed)
lagr_term = AffExpr(dot(lambda_perturbed, pool.lb))
for offset in 1:nnz(v)
var_idx = v.nzind[offset]
add_to_expression!(
lagr_term,
vars_s[var_idx],
- v.nzval[offset],
)
end
# Update objective
set_objective_function(
model_s,
orig_obj_s + lagr_term,
)
end
end
@timeit "Optimize LP (lagrangian)" begin
set_silent(model_s)
optimize!(model_s)
sol_frac = get_x(model_s)
obj_curr = objective_value(model_s)
obj_curr <= obj_mip || error("LP value higher than MIP value: $(obj_curr) > $(obj_mip)")
if round == 1
obj_initial = obj_curr
end
if obj_curr >= obj_best
obj_best = obj_curr
gapcl_best = gapcl(obj_best)
lambda_best = lambda_curr
noimprov_count = 0
else
noimprov_count += 1
end
if noimprov_count > 10
lambda_curr = lambda_best
backtrack_count += 1
noimprov_count = 0
continue
end
push!(stats_obj, obj_curr)
push!(stats_gap, gap(obj_curr))
if round == 1
push!(stats_ncuts, 0)
else
push!(stats_ncuts, length(pool.lb))
end
if termination_status(model_s) != MOI.OPTIMAL
error("Non-optimal termination status")
end
end
@timeit "Select tableau rows" begin
basis = get_basis(model_s)
if round == 1
original_basis = basis
end
selected_rows =
select_gmi_rows(data_s, basis, sol_frac, max_rows = max_cuts_per_round)
end
@timeit "Compute tableau rows" begin
tableau = compute_tableau(data_s, basis, x = sol_frac, rows = selected_rows)
# Assert tableau rows have been computed correctly
assert_eq(tableau.lhs * sol_frac, tableau.rhs, atol=1e-3)
assert_eq(tableau.lhs * sol_opt_s, tableau.rhs, atol=1e-3)
end
@timeit "Compute GMI cuts" begin
cuts_s = compute_gmi(data_s, tableau)
assert_cuts_off(cuts_s, sol_frac)
assert_does_not_cut_off(cuts_s, sol_opt_s)
ncuts = length(cuts_s.lb)
end
@timeit "Add new cuts to the pool" begin
if round == 1
pool = cuts_s
lambda_curr = zeros(ncuts)
lambda_best = zeros(ncuts)
cut_age = zeros(ncuts)
else
pool.lhs = [pool.lhs; cuts_s.lhs]
pool.lb = [pool.lb; cuts_s.lb]
pool.ub = [pool.ub; cuts_s.ub]
lambda_curr = [lambda_curr; zeros(ncuts)]
lambda_best = [lambda_best; zeros(ncuts)]
cut_age = [cut_age; zeros(ncuts)]
end
end
# @timeit "Update multipliers (subgradient)" begin
# subgrad = pool.lb .- pool.lhs * sol_frac
# lambda = max.(0, lambda .+ 0.01 * subgrad)
# end
selected_idx = []
selected_contrs = []
@timeit "Update multipliers (large LP)" begin
while true
@timeit "Optimize LP (extended)" begin
set_objective_function(model_s, orig_obj_s)
optimize!(model_s)
sol_frac = get_x(model_s)
end
@timeit "Find most violated cut" begin
violations = pool.lb .- pool.lhs * sol_frac
σ = sortperm(violations, rev=true)
end
# Stop if all cuts are satisfied
if violations[σ[1]] <= 1e-6
break
end
@timeit "Add constraint to the model" begin
push!(selected_idx, σ[1])
cut_lhs = pool.lhs[σ[1], :]
cut_lhs_value = 0.0
cut_lb = pool.lb[σ[1]]
cut_expr = AffExpr()
for offset in 1:nnz(cut_lhs)
var_idx = cut_lhs.nzind[offset]
add_to_expression!(
cut_expr,
vars_s[var_idx],
cut_lhs.nzval[offset],
)
cut_lhs_value += sol_frac[var_idx] * cut_lhs.nzval[offset]
end
cut_constr = @constraint(model_s, cut_expr >= cut_lb)
push!(selected_contrs, cut_constr)
end
end
@timeit "Find dual values for all selected cuts" begin
lambda_curr .= 0
cut_age .+= 1
for (offset, idx) in enumerate(selected_idx)
lambda_curr[idx] = -shadow_price(selected_contrs[offset])
if lambda_curr[idx] > 1e-5
cut_age[idx] = 0
end
end
end
# Filter cut pool
keep = findall(cut_age .< max_cut_age)
pool.lhs = pool.lhs[keep, :]
pool.ub = pool.ub[keep]
pool.lb = pool.lb[keep]
lambda_curr = lambda_curr[keep]
lambda_best = lambda_best[keep]
cut_age = cut_age[keep]
@timeit "Delete all cut constraints" begin
delete.(model_s, selected_contrs)
end
end
push!(stats_ncuts, length(pool.lb))
elapsed_time = time() - initial_time
if elapsed_time > time_limit
@info "Time limit exceeded. Stopping."
break
end
if round == 1
@printf(
"%8s %12s %12s %12s %8s %8s %9s\n",
"round",
"obj",
"gapcl_curr",
"gapcl_best",
"active",
"pool",
"backtrack",
)
end
if time() - last_print_time > interval_print
last_print_time = time()
@printf(
"%8d %12.6e %12.2f %12.2f %8d %8d %9d\n",
round,
obj_curr,
gapcl(obj_curr),
gapcl_best,
length(selected_idx),
length(pool.ub),
backtrack_count,
)
end
end
# @timeit "Store cuts in H5 file" begin
# if all_cuts !== nothing
# ncuts = length(all_cuts_rows)
# total =
# length(original_basis.var_basic) +
# length(original_basis.var_nonbasic) +
# length(original_basis.constr_basic) +
# length(original_basis.constr_nonbasic)
# all_cuts_basis_sizes = Array{Int64,2}(undef, ncuts, 4)
# all_cuts_basis_vars = Array{Int64,2}(undef, ncuts, total)
# for i = 1:ncuts
# vb = all_cuts_bases[i].var_basic
# vn = all_cuts_bases[i].var_nonbasic
# cb = all_cuts_bases[i].constr_basic
# cn = all_cuts_bases[i].constr_nonbasic
# all_cuts_basis_sizes[i, :] = [length(vb) length(vn) length(cb) length(cn)]
# all_cuts_basis_vars[i, :] = [vb' vn' cb' cn']
# end
# @info "Storing $(length(all_cuts.ub)) GMI cuts..."
# h5 = H5File(h5_filename)
# h5.put_sparse("cuts_lhs", all_cuts.lhs)
# h5.put_array("cuts_lb", all_cuts.lb)
# h5.put_array("cuts_ub", all_cuts.ub)
# h5.put_array("cuts_basis_vars", all_cuts_basis_vars)
# h5.put_array("cuts_basis_sizes", all_cuts_basis_sizes)
# h5.put_array("cuts_rows", all_cuts_rows)
# h5.file.close()
# end
# end
to = TimerOutputs.get_defaulttimer()
stats_time = TimerOutputs.tottime(to) / 1e9
print_timer()
return OrderedDict(
"instance" => mps_filename,
"max_rounds" => max_rounds,
"rounds" => length(stats_obj) - 1,
"obj_mip" => obj_mip,
"stats_obj" => stats_obj,
"stats_ncuts" => stats_ncuts,
"stats_time" => stats_time,
)
end
function add_constraint_set_dual_v2(model::JuMP.Model, cs::ConstraintSet) function add_constraint_set_dual_v2(model::JuMP.Model, cs::ConstraintSet)
vars = all_variables(model) vars = all_variables(model)
nrows, ncols = size(cs.lhs) nrows, ncols = size(cs.lhs)
@ -576,5 +913,5 @@ function __init_gmi_dual__()
copy!(ExpertDualGmiComponent, ExpertDualGmiComponentPy) copy!(ExpertDualGmiComponent, ExpertDualGmiComponentPy)
end end
export collect_gmi_dual, expert_gmi_dual, ExpertDualGmiComponent, KnnDualGmiComponent export collect_gmi_dual, expert_gmi_dual, ExpertDualGmiComponent, KnnDualGmiComponent, collect_gmi_FisSal2011

11
src/Cuts/tableau/transform.jl
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@ -102,7 +102,14 @@ function forward!(t::AddSlackVariables, data::ProblemData)
ge = [i for i = 1:nrows if isfinite(data.constr_lb[i]) && !isequality[i]] ge = [i for i = 1:nrows if isfinite(data.constr_lb[i]) && !isequality[i]]
le = [i for i = 1:nrows if isfinite(data.constr_ub[i]) && !isequality[i]] le = [i for i = 1:nrows if isfinite(data.constr_ub[i]) && !isequality[i]]
EQ, GE, LE = length(eq), length(ge), length(le) EQ, GE, LE = length(eq), length(ge), length(le)
is_integral(row_idx, rhs) = (
abs(rhs - round(rhs)) <= 1e-6 &&
all(j -> data.var_types[j] ['I', 'B'], findnz(data.constr_lhs[row_idx, :])[1])
)
slack_types = [
[is_integral(ge[i], data.constr_lb[ge[i]]) ? 'I' : 'C' for i = 1:GE];
[is_integral(le[i], data.constr_ub[le[i]]) ? 'I' : 'C' for i = 1:LE]
]
t.M1 = [ t.M1 = [
I spzeros(ncols, GE + LE) I spzeros(ncols, GE + LE)
data.constr_lhs[ge, :] spzeros(GE, GE + LE) data.constr_lhs[ge, :] spzeros(GE, GE + LE)
@ -129,7 +136,7 @@ function forward!(t::AddSlackVariables, data::ProblemData)
data.var_lb = [data.var_lb; zeros(GE + LE)] data.var_lb = [data.var_lb; zeros(GE + LE)]
data.var_ub = [data.var_ub; [Inf for _ = 1:(GE+LE)]] data.var_ub = [data.var_ub; [Inf for _ = 1:(GE+LE)]]
data.var_names = [data.var_names; ["__s$i" for i = 1:(GE+LE)]] data.var_names = [data.var_names; ["__s$i" for i = 1:(GE+LE)]]
data.var_types = [data.var_types; ['C' for _ = 1:(GE+LE)]] data.var_types = [data.var_types; slack_types]
data.constr_lb = [ data.constr_lb = [
data.constr_lb[eq] data.constr_lb[eq]
data.constr_lb[ge] data.constr_lb[ge]

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