The `Release Build` workflow still targeted macOS 13.0 for the x64/arm64
packaging jobs, while the codebase now relies on libc++ functionality
that is only available with a 13.3 deployment target. This updates the
release workflow to use the same macOS target configuration already
applied in `nightly.yml`.
- **Release workflow**
- Raise `MACOSX_DEPLOYMENT_TARGET` from `13.0` to `13.3` for both
`mac-build-x64` and `mac-build-arm64`
- Update the packaging target passed to `mk_unix_dist.py` from
`--os=osx-13.0` to `--os=osx-13.3`
- **Config alignment**
- Bring `release.yml` in sync with the existing nightly macOS fix so
both workflows build against the same minimum macOS version
```yaml
env:
MACOSX_DEPLOYMENT_TARGET: "13.3"
run: python scripts/mk_unix_dist.py --arch=x64 --os=osx-13.3
```
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
`seq.foldl` could produce a concrete sequence model while related
`seq.nth` constraints were still validated against stale or
underconstrained length information, leading to invalid models. In the
reported case, `all` was modeled as `(seq.++ (seq.unit 7) (seq.unit 0))`
while `final = (seq.nth all 0)` remained inconsistent with `final = 6`.
- **Root cause**
- Sequence solutions were propagated as equalities, but parent `seq.len`
terms were not updated when a sequence term was solved.
- As a result, `seq.nth` guard reasoning could miss that a solved
sequence had known in-bounds length.
- **Solver change**
- Extend `theory_seq::add_solution` to collect parent `seq.len`
expressions of a solved term when the solved result is sequence-typed.
- After propagating the solved sequence equality, also propagate the
rewritten length equality for those parent length terms.
- Keep this propagation guarded to sequence results so scalar
`seq.foldl`/`seq.foldli` solutions do not regress from `sat` to
`unknown` under model validation.
- **Regression coverage**
- Add a focused test for the reported SMT-LIB pattern:
- `all = seq.foldl(...)`
- `final = seq.nth all 0`
- `initial = 0`
- `final = 6`
- Add focused scalar `seq.foldl`/`seq.foldli` model-validation coverage
for the existing benchmark shapes that must continue returning `sat`.
- The regressions check both that model validation no longer reports an
invalid model for the `seq.nth` case and that scalar fold/foldi cases do
not regress to `unknown`.
- **Effect**
- Solved sequence terms now push enough derived length information for
dependent `seq.nth` constraints to validate against the actual modeled
sequence.
- Existing scalar fold/foldi solving behavior is preserved.
```smt2
(define-fun all_sums ((prev_sums (Seq Int)) (elem Int)) (Seq Int)
(seq.++ (seq.unit (+ (seq.nth prev_sums 0) elem)) prev_sums)
)
(assert (= all (seq.foldl all_sums (seq.unit initial) elements)))
(assert (= final (seq.nth all 0)))
(assert (= initial 0))
(assert (= final 6))
```
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
The `release-notes-updater` agent job was failing with HTTP 401 on every
Copilot API inference request because the GitHub Actions token lacked
`copilot-requests: write`.
## Changes
- **`release-notes-updater.md`**: Replace `permissions: read-all`
shorthand with an explicit permissions object that includes
`copilot-requests: write`
- **`release-notes-updater.lock.yml`**: Recompiled via `gh aw compile`
```yaml
# Before
permissions: read-all
# After
permissions:
contents: read
issues: read
pull-requests: read
discussions: read
copilot-requests: write
```
`read-all` expands all scopes to read but does not grant
`copilot-requests: write`, which is the permission required for the
GitHub Actions token to authenticate with the Copilot API proxy.
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
The reported case showed expensive reasoning for lexicographic string
comparisons under the default sequence solver, and incorrect handling
expectations with `z3str3` (which does not interpret these comparisons).
This change targets the default solver path by short-circuiting
contradictory constant-bound `<` constraints earlier.
- **Theory shortcut for constant lexical bounds**
- In `theory_seq::assign_eh`, detect asserted `str.<` constraints of the
form `c < x` or `x < c` where `c` is a string constant.
- When a complementary bound on the same equivalence class is already
true, check bound consistency immediately.
- If bounds are contradictory (`!(lower < upper)`), emit a direct theory
conflict from the two active literals instead of waiting for deeper
axiom propagation.
- **Preserve existing comparison reasoning**
- Existing `check_lts` transitivity/axiom flow is retained.
- The new logic is a narrow fast path for contradictory constant bounds
and does not alter general string-order semantics.
- **Regression coverage**
- Added a solver-level regression in `src/test/seq_rewriter.cpp` for
contradictory date-like lexical bounds to ensure this class of
constraints is rejected as `unsat`.
```cpp
ctx.assert_expr(su.str.mk_lex_lt(su.str.mk_string("2024-01-01"), x));
ctx.assert_expr(su.str.mk_lex_lt(x, su.str.mk_string("2024-12-31")));
ctx.assert_expr(su.str.mk_lex_lt(x, su.str.mk_string("2023-01-01")));
ENSURE(ctx.check() == l_false);
```
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
Combining `mod0`/`div0` quantifier axioms with a mod-idempotency
quantifier caused Z3 to loop forever. The core issue was that
`mk_mod_core` in `arith_rewriter.cpp` only handled rewrite rules for
*numeral* moduli, leaving two gaps for symbolic `y`:
1. `mod(a + k*y, y)` was not reduced to `mod(a, y)`, so `(not (= (mod (+
a b) b) (mod a b)))` stayed unreduced and caused the nlsat solver to
spin.
2. The E-matching pattern `(mod (mod x y) y)` fired on every new term it
produced, creating an unbounded chain of nested `mod` expressions.
```lisp
; Previously non-terminating, now returns unsat immediately
(assert (forall ((x Int)) (! (= (mod0 x 0) 0) :pattern ((mod0 x 0)))))
(assert (forall ((x Int)) (! (= (div0 x 0) 0) :pattern ((div0 x 0)))))
(assert (forall ((x Int) (y Int))
(! (= (mod (mod x y) y) (mod x y)) :pattern ((mod (mod x y) y)))))
(assert (not (= (mod (+ a b) b) (mod a b))))
(check-sat)
```
## Changes
- **`src/ast/rewriter/arith_rewriter.cpp` — symbolic summand
elimination**: In `mk_mod_core`, when the modulus is a non-numeral
integer and the dividend is an `add`, strip any summand equal to the
modulus or an integer multiple of it. Soundness: `k*0 = 0` for all `k`,
so the rule holds even at `y = 0`. This immediately collapses the
reported formula to `false`.
- **`src/ast/rewriter/arith_rewriter.cpp` — symbolic idempotency via
ite**: Extend the existing `mod(mod(x,y), y) → mod(x,y)` rule
(previously numeral-only) to symbolic `y` by rewriting to `ite(y=0,
mod(mod(x,0),0), mod(x,y))`. The `y=0` branch uses a numeral divisor,
which is excluded by the `!v2.is_zero()` guard, halting the E-matching
chain.
- **`src/test/arith_rewriter.cpp`**: Regression tests for `mod(a+y, y) =
mod(a,y)`, `mod(a+2y, y) = mod(a,y)`, and `mod(mod(a,3),3) = mod(a,3)`.
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
`ASSERTION VIOLATION` at `bv2int_translator.h:72` when using
`smt.bv.solver=2` with formulas containing `abs` (or other arith
expressions that rewrite to ITE with arith predicates).
**Root cause**
`ensure_translated` skips adding sub-expressions of boolean non-BV nodes
to the `todo` list — correct, since the base theory owns them in plugin
mode. However, `translate_expr`'s early-return only covered
`basic_family_id` booleans, not non-basic ones (e.g.,
`arith_family_id`).
When `(abs f)` is rewritten by the arith rewriter to `(ite (>= f 0) f (-
f))`, the predicate `(>= f 0)` ends up in `todo` (as a child of the
ITE), but its own children (e.g., the integer literal `0`) are not
added. `translate_expr` then calls `translated(0)` on an unmapped
expression, firing `SASSERT(r)`.
Reproducer:
```smt2
(declare-const f Int)
(assert (= 0 (mod 0 (bv2nat ((_ int_to_bv 1) (abs f))))))
(check-sat)
; z3 test.smt2 smt.bv.solver=2 → ASSERTION VIOLATION (before fix)
```
**Fix**
Extend the early-return in `translate_expr` to match
`ensure_translated`'s skip condition — all boolean non-BV expressions in
plugin mode map to themselves:
```cpp
// before
if (m_is_plugin && ap->get_family_id() == basic_family_id && m.is_bool(ap)) {
// after
if (m_is_plugin && m.is_bool(ap) && ap->get_family_id() != bv.get_family_id()) {
```
BV boolean predicates (`bvule`, etc.) are unaffected — they still route
through `translate_bv`.
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
`Expr.getSort()` on a constant with an `EnumSort` sort returns a
`DatatypeSort`, causing `ClassCastException` when enum-specific methods
are called.
```java
Context ctx = new Context();
EnumSort<Foo> enumSort = ctx.mkEnumSort("my-enum", "e1", "e2");
Expr<EnumSort<Foo>> c = ctx.mkConst("my-const", enumSort);
c.getSort().getName(); // ClassCastException — getSort() returns DatatypeSort, not EnumSort
```
### Changes
- **`Sort.java`**: In `Sort.create()`, detect enum sorts at the
`Z3_DATATYPE_SORT` case by checking whether all constructors have arity
0 — matching Z3's own `util::is_enum_sort` logic in
`datatype_decl_plugin.cpp`. Return `EnumSort<>` when true,
`DatatypeSort<>` otherwise.
- **`EnumSort.java`**: Add package-private `EnumSort(Context ctx, long
obj)` constructor so an `EnumSort` can be instantiated from an existing
native sort handle (analogous to `DatatypeSort(Context ctx, long obj)`).
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
## Summary
Fixes the divergence in issue #7464: formulas involving `mod`/`div` by a
**variable** divisor could send `smt.arith.solver=6` into a
non-terminating nonlinear search.
Minimal reproducer (UNSAT, previously timed out; now solved in <0.5s):
```smt2
(declare-fun V () Int)
(declare-fun n () Int)
(declare-fun l () Int)
(assert (and (> V 0) (= 0 (mod n 2)) (= (div n 2) (div n l)) (= 0 (mod (div n l) V))))
(assert (distinct 0 (mod n V)))
(check-sat)
```
## Root cause
A variable-divisor `mod n V` is axiomatized by the Euclidean identity
`n = V*(n div V) + (n mod V)`. The `V*(n div V)` term is nonlinear, so
arith.solver=6
hands the problem to the nlsat/Gröbner branch, which branches on values
of `V` with no
termination bound and diverges.
## Fix
Add a **linear divisibility closure** lemma in `nla_divisions`:
> `mod(a, y) = 0 & x = c*a` (c an integer constant) ⟹ `mod(x, y) = 0`.
The emitted clause
```
(x - c*a != 0) \/ (mod(a, y) != 0) \/ (mod(x, y) = 0)
```
is a **tautology for every integer `c`**, so mining a candidate `c =
val(x)/val(a)` from
the current model can never be unsound. It is only emitted when all
three literals are
false in the current model, so the clause is a genuine
conflict/propagation and always
makes progress. This lets the theory refute the instance directly
instead of entering the
divergent nonlinear branch.
Variable-divisor `mod` terms were previously **not registered** in nla
at all; they are now
registered into a new `m_divisibility` list in `theory_lra`, so the
reasoner can pair a
violated `mod(x, y)` with a satisfied `mod(a, y)` of the same divisor.
## Changes
- `src/math/lp/nla_divisions.{h,cpp}` — new `m_divisibility` list
`{r=mod, x=dividend, y=divisor}`, `add_divisibility(...)`, and
`check_linear_divisibility()`; invoked from `divisions::check()`.
- `src/math/lp/nla_core.h`, `src/math/lp/nla_solver.{h,cpp}` —
forwarding of `add_divisibility`.
- `src/smt/theory_lra.cpp` — register variable-divisor `mod` into the
divisibility list.
## Validation
- `min.smt2` → `unsat` in 0.46s, minimized core → 0.15s (were timeouts).
- Soundness: 350 differential fuzz formulas (arith.solver=6 vs
arith.solver=2), **0 mismatches**.
- Spot checks correct (divisor-3 variant → unsat; non-divisible variants
→ sat).
Co-authored-by: Copilot <223556219+Copilot@users.noreply.github.com>
`decl_collector::visit_sort` did not collect sorts with `poly_family_id`
(type variables created via `mk_type_var` / `declare-type-var`), so
`solver::display` and `ast_pp_util::display_decls` never emitted type
variable declarations before referencing them — producing invalid
SMT-LIB2 output.
## Changes
- **`src/ast/decl_collector.h`**: added a dedicated `lim_svector<sort*>
m_type_vars` field (separate from `m_sorts`) with a `get_type_vars()`
getter; `reset()` clears it; `push()`/`pop()` maintain its scope.
- **`src/ast/decl_collector.cpp` — `visit_sort`**: sorts with
`poly_family_id` are now pushed to `m_type_vars` instead of `m_sorts`,
keeping type variables distinct from uninterpreted sorts:
```cpp
if (m.is_uninterp(n))
m_sorts.push_back(n);
else if (fid == poly_family_id)
m_type_vars.push_back(n);
```
- **`src/ast/ast_pp_util.h`**: added a `stacked_value<unsigned>
m_type_vars` cursor to track which type variables have already been
printed.
- **`src/ast/ast_pp_util.cpp` — `display_decls`**: emits
`(declare-type-var <name>)` for each collected type variable before
other sort declarations; `reset()`/`push()`/`pop()` maintain the new
cursor.
**Example** — given `(declare-type-var A)(declare-fun f (A) A)`, the
dump now correctly produces:
```smt2
(declare-type-var A)
(declare-fun f (A) A)
(assert ...)
```
The output round-trips cleanly through the Z3 parser.
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
The `api_datalog` unit test was failing in CI with `"the logic has
already been set"`. Two consecutive regression tests shared a single
`Z3_context`, but both called `Z3_eval_smtlib2_string` with `(set-logic
HORN)` — the second call always fails because context logic state is
permanent.
## Changes
- **`src/test/api_datalog.cpp`**: Give each
`Z3_eval_smtlib2_string`-based regression test its own
`Z3_config`/`Z3_context`, destroyed immediately after the test block.
The outer context is retained only for the two tests that don't invoke
the SMT-LIB evaluator.
```cpp
// Before: both blocks shared `ctx`, second (set-logic HORN) always errored
Z3_string response = Z3_eval_smtlib2_string(ctx, chc1); // sets HORN logic
Z3_string response = Z3_eval_smtlib2_string(ctx, chc2); // ERROR: logic already set
// After: each block owns its context
Z3_config cfg2 = Z3_mk_config();
Z3_context ctx2 = Z3_mk_context(cfg2);
Z3_del_config(cfg2);
Z3_string response = Z3_eval_smtlib2_string(ctx2, chc2);
Z3_del_context(ctx2);
```
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
`z3_add_install_tactic_rule` unconditionally called `file(WRITE)` during
CMake configure, updating `install_tactic.deps`'s mtime on every
reconfiguration — even when the content was identical. Since
`install_tactic.cpp` lists `install_tactic.deps` as a dependency, any
CMake reconfigure (e.g. touching `src/api/ml/CMakeLists.txt`) caused a
full rebuild of the tactic installation target.
## Change
- **`cmake/z3_add_component.cmake` — `z3_add_install_tactic_rule`**:
Replace unconditional `file(WRITE)` with a read-and-compare guard; the
deps file is only rewritten when its content actually changes.
```cmake
# Before
file(WRITE "${CMAKE_CURRENT_BINARY_DIR}/install_tactic.deps" ${_tactic_header_files})
# After
set(_install_tactic_deps_file "${CMAKE_CURRENT_BINARY_DIR}/install_tactic.deps")
if (EXISTS "${_install_tactic_deps_file}")
file(READ "${_install_tactic_deps_file}" _install_tactic_deps_old)
else()
set(_install_tactic_deps_old "")
endif()
if (NOT _install_tactic_deps_old STREQUAL "${_tactic_header_files}")
file(WRITE "${_install_tactic_deps_file}" "${_tactic_header_files}")
endif()
```
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
The TPTP frontend was not forcing `pi.avoid_skolems=false`, so TPTP
problems could be solved with the default pattern-inference behavior
instead of the intended frontend-specific setting. This change applies
the override directly to the solver used by TPTP runs.
- **What changed**
- After constructing the TPTP solver, the frontend now sets
`pi.avoid_skolems=false` via solver parameters before `check_sat`.
- The override is scoped to the TPTP solver instance instead of mutating
process-global parameter state.
- **Why this shape**
- Keeps the TPTP behavior explicit at the point where the solver is
created.
- Avoids leaking the parameter change into unrelated solver contexts.
- **Code sketch**
```c++
ctx.set_solver_factory(mk_smt_strategic_solver_factory());
params_ref solver_params;
solver_params.set_bool("pi.avoid_skolems", false);
ctx.get_solver()->updt_params(solver_params);
```
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
`check-sat-using qe` was reported to return `unsat` on a satisfiable
quantified-real formula, while a subsequent `check-sat` on the same
assertion returned `sat`. This PR adds focused regression coverage for
that shape to prevent reintroduction.
- **Regression coverage for the reported formula**
- Added `test_qe_regression_4175()` in `src/test/quant_solve.cpp`.
- Parses and quantifier-eliminates:
```smt2
(forall ((b Real)) (= (= r1 b) (= b 0)))
```
- **Behavioral oracle encoded in the test**
- Verifies the QE result is satisfiable under `r1 = 0`.
- Verifies the QE result is unsatisfiable under `r1 != 0`.
- This captures the intended semantics of the original formula and
guards against the unsound `unsat` outcome from the QE path.
- **Integration**
- Wires the new regression into `tst_quant_solve()` so it runs with
existing quantifier-solver test coverage.
Example snippet from the new test logic:
```cpp
solver.assert_expr(result);
solver.assert_expr(m.mk_eq(r1, zero));
VERIFY(l_true == solver.check());
solver.assert_expr(result);
solver.assert_expr(m.mk_not(m.mk_eq(r1, zero)));
VERIFY(l_false == solver.check());
```
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
Spacer crashed in quantifier-elimination projection on certain HORN
inputs when model evaluation produced arithmetic expressions that were
not plain numerals. The failure was an assertion in
`spacer_qe_project.cpp` during sign/offset computation for projected
literals.
- **Projection robustness in Spacer arithmetic QE**
- Updated numeral extraction in `src/muz/spacer/spacer_qe_project.cpp`
from `is_numeral` to `is_extended_numeral` at all model-evaluation sites
used by projection.
- This covers evaluated arithmetic forms (e.g., normalized arithmetic
expressions) that are semantically numeric but not syntactic numerals,
preventing assertion failures in disequality/equality handling and bound
selection.
- **Regression coverage for the crashing HORN shape**
- Added a focused regression in `src/test/api_datalog.cpp` that
evaluates the reported Spacer/HORN input pattern through
`Z3_eval_smtlib2_string`.
- The test exercises the exact QE/projection path that previously
triggered the assertion.
```cpp
// Before
VERIFY(a.is_numeral(val, r));
// After
VERIFY(a.is_extended_numeral(val, r));
```
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
Multiple agentic workflows were failing at runtime with
`MODULE_NOT_FOUND` for `merge_awf_model_multipliers.cjs` under
`${RUNNER_TEMP}/gh-aw/actions`. The lock workflows had stale generated
runtime steps that no longer matched the current `gh-aw` actions bundle.
- **Root cause**
- Generated `.lock.yml` workflows referenced a removed script:
- `node "${RUNNER_TEMP}/gh-aw/actions/merge_awf_model_multipliers.cjs"`
- **Change**
- Recompiled all agentic workflow sources (`.github/workflows/*.md`)
with current `gh aw` tooling.
- Checked in regenerated lock artifacts:
- `.github/workflows/*.lock.yml`
- `.github/aw/actions-lock.json`
- Result: stale `merge_awf_model_multipliers.cjs` invocations were
eliminated from generated workflows.
- **Representative diff shape**
```yaml
# removed from generated lock workflows
- GH_AW_MODEL_MULTIPLIERS_PATH="/tmp/gh-aw/model_multipliers.json" \
node "${RUNNER_TEMP}/gh-aw/actions/merge_awf_model_multipliers.cjs"
```
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
This PR adds a first-class Python API helper for expressing regex
constraints in familiar Python regex syntax and translating them into Z3
regex terms. The translator is implemented as a separate module
(`z3regex.py`) as requested, keeping regex conversion logic isolated
from core API files.
- **New Python regex translator module**
- Adds `src/api/python/z3/z3regex.py`.
- Introduces `regex_to_re(pattern, flags=0, ctx=None)` to convert parsed
Python regex constructs into Z3 regex expressions.
- Supports core regular constructs (literals, classes/ranges,
alternation, grouping, quantifiers, categories, wildcard).
- Raises `NotImplementedError` for unsupported non-regular constructs
(e.g., features outside regular languages).
- **API/package integration**
- Exposes the module via `src/api/python/z3/__init__.py`.
- Includes `z3/z3regex.py` in Python binding file copy/install flow in
`src/api/python/CMakeLists.txt`.
- **Doctest entrypoint support**
- Extends `src/api/python/z3test.py` with `z3regex` mode so translator
doctests can be run consistently with existing Python API doctest flows.
```python
from z3 import *
from z3.z3regex import regex_to_re
x = String("x")
r = regex_to_re(r"(ab|cd)+\d{2}")
s = Solver()
s.add(InRe(x, r))
```
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
The Nightly release occasionally exposed a mismatch between the commit
shown on the release page and the downloaded “Source code” archive. Root
cause was non-deterministic `Nightly` tag/release state during publish.
- **Deterministic Nightly tag lifecycle**
- Serialize Nightly workflow runs with a dedicated concurrency group to
prevent overlapping tag/release mutations.
- Replace best-effort cleanup with explicit release-exists checks and
failure-on-cleanup-error behavior.
- Remove orphan `Nightly` tags even when no release exists.
- **Pin release to the exact workflow commit**
- Force-update `Nightly` to `${{ github.sha }}` and push it before
release creation.
- Verify remote tag SHA (including annotated-tag dereference shape)
matches `${{ github.sha }}`.
- Create release with `--verify-tag` so source archives are generated
from the validated tag, not an implicit/stale target.
- **Workflow behavior change (deploy section)**
```yaml
concurrency:
group: nightly-release
cancel-in-progress: false
```
```bash
git tag -f Nightly "${{ github.sha }}"
git push --force origin refs/tags/Nightly
gh release create Nightly --verify-tag ...
```
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
Creating and disposing `Context` instances causes unbounded native
memory growth (~12 GB for 100k contexts) because `NativeContext` had no
finalizer — if `Dispose()` was never called, the native Z3 context
leaked permanently. Additionally, both `Context` and `NativeContext` had
delegate lifetime and thread-safety issues in their disposal paths.
## `NativeContext.cs`
- **Add missing finalizer** `~NativeContext() { Dispose(); }` — the root
cause of permanent leaks when callers don't explicitly dispose
- **Atomic disposal** via `Interlocked.Exchange(ref m_ctx, IntPtr.Zero)`
— prevents double-free when `Dispose()` is called concurrently (e.g.
user code + finalizer race)
- **Delegate lifetime** — capture `errHandler` locally +
`GC.KeepAlive(errHandler)` after `Z3_del_context`; the GC could
otherwise collect the error handler callback before the native
destructor finishes
- **Remove dead code** — `GC.SuppressFinalize` in `InitContext()` and
`GC.ReRegisterForFinalize` in `Dispose()` were both no-ops (no finalizer
existed); the latter would have caused infinite finalization with the
new finalizer
- **GC memory pressure** — `GC.AddMemoryPressure(8MB)` on init /
`GC.RemoveMemoryPressure(8MB)` on dispose, guarded by
`m_memPressureAdded` flag, so the GC schedules finalizers promptly when
contexts accumulate
## `Context.cs`
- **Thread-safe disposal** — capture `ctx` and `errHandler` inside the
existing `lock(this)` block; previously both were read outside the lock,
allowing two concurrent callers to both capture the same non-zero `ctx`
and double-free it
- **Delegate lifetime** — same `errHandler` + `GC.KeepAlive` pattern as
`NativeContext`
- **`GC.SuppressFinalize` placement** — moved inside the `if (m_ctx !=
IntPtr.Zero)` block, before cleanup, per .NET best practice
- **GC memory pressure** — same add/remove pattern, conditioned on
`!is_external` via `m_memPressureAdded` flag
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
Unit tests relied on `SASSERT()` which is a no-op in release builds
(`DEBUG_CODE` wrapper), silently skipping all assertions outside debug
mode. Several test files were also gated behind `#ifdef _WINDOWS`,
making them dead code on Linux/macOS CI.
## Changes
- **`SASSERT` → `ENSURE` in 20 test files (200 occurrences)**: `ENSURE`
maps to `VERIFY` and always executes regardless of build type, ensuring
test assertions are active in both debug and release builds.
- **`src/test/diff_logic.cpp`**: Removed `#ifdef _WINDOWS` wrapping the
entire file. No Windows-specific APIs were used; the guard only
prevented compilation on non-Windows platforms.
- **`src/test/dl_product_relation.cpp`**: Removed `#ifdef _WINDOWS`
guard around `tst_dl_product_relation()`. The function body has no
platform dependencies.
- **`src/test/sat_local_search.cpp`**: Replaced `sscanf_s`
(MSVC-specific) with portable `sscanf`; added return-value check to
detect malformed input. Previously, `build_instance()` unconditionally
returned `false` on non-Windows, making the SAT local search test a
no-op on Linux/macOS.
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
`Z3_API_LOG_SYNC` uses `std::mutex` to serialize API log writes across
threads. When combined with `Z3_SINGLE_THREADED`, all mutex operations
become no-ops (`SINGLE_THREAD` define strips them), silently defeating
the synchronization.
## Changes
- **`CMakeLists.txt`**: Emit `FATAL_ERROR` when both
`Z3_API_LOG_SYNC=ON` and `Z3_SINGLE_THREADED=ON` are set:
```
CMake Error: Z3_API_LOG_SYNC requires threading support and cannot be
combined with Z3_SINGLE_THREADED
```
- **`README-CMake.md`**: Expand `Z3_API_LOG_SYNC` description to clarify
its purpose and document the incompatibility with `Z3_SINGLE_THREADED`.
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
…158)
rule_manager::mk_query eliminates gaps in de Bruijn indices caused by
unused quantified variables via a substitution that renumbers the
remaining variables contiguously. This was done in a single pass, but
var_subst applies the rewriter, which can simplify away further variable
occurrences (e.g. collapsing ite terms such as (ite true a b) or (ite c
x x)), introducing new gaps. The leftover null sort was then
dereferenced, asserting in debug and segfaulting in release.
Iterate the gap-elimination until the free variables are contiguous.
Each iteration either compacts the indices or strictly reduces the set
of used variables, so it terminates.
Fixes the crash reported for:
(assert (forall ((a Bool)(b Bool)(d (_ BitVec 1))(e (_ BitVec 1))(f (_
BitVec 1))(g Bool))
(= (= f (ite a (_ bv0 1) (ite true (_ bv0 1) (ite b e e)))) g)))
(check-sat-using horn)
Co-authored-by: Copilot <223556219+Copilot@users.noreply.github.com>
`std::format` (C++20 `<format>`) pulls in `std::to_chars` for
floating-point formatting, which is only available on macOS 13.3+. The
Mac x64 CI job was targeting macOS 13.0, causing build errors in
`src/ast/`.
## Changes
Updated `nightly.yml` to raise the macOS deployment target for the x64
build:
- **`MACOSX_DEPLOYMENT_TARGET`**: `"13.0"` → `"13.3"` in the
`mac-build-x64` job
- **`--os` flag**: `osx-13.0` → `osx-13.3` in the `mk_unix_dist.py`
invocation
This matches the existing `mac-build-arm64` job, which already targets
macOS 13.3, and allows `std::format` to be used freely in `src/ast/`
without workarounds.
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
Z3 4.16.0 introduced a cube-and-conquer parallel solver that regressed
easy QF_LIRA problems from <1s to hanging indefinitely. Workers start
with a 1000-conflict budget and multiply by 1.5× on each timeout, but
after ~38 escalations the `unsigned` cast overflows, causing the budget
to oscillate chaotically (e.g. 3.27B → 618M → 927M → … never reaching a
stable large value). For sub-cubes that require more conflicts than any
value in the oscillation window, the worker loops forever.
## Changes
- **`src/smt/smt_parallel.h`** – `update_max_thread_conflicts()`:
replace raw `(unsigned)(mul * val)` cast with saturating arithmetic that
caps at `UINT_MAX`, eliminating the UB and the oscillation:
```cpp
// Before – UB when product > UINT_MAX, budget oscillates after ~38
escalations
m_config.m_threads_max_conflicts =
(unsigned)(m_config.m_max_conflict_mul *
m_config.m_threads_max_conflicts);
// After – saturates at UINT_MAX
double next = m_config.m_max_conflict_mul *
m_config.m_threads_max_conflicts;
m_config.m_threads_max_conflicts = (next >= (double)UINT_MAX) ? UINT_MAX
: (unsigned)next;
```
- **`src/solver/parallel_tactical.cpp`** – Identical
saturating-arithmetic fix in the `parallel_tactical2` worker's
`update_max_thread_conflicts()`, which is the code path actually
exercised for QF_LIRA problems.
- **`src/smt/smt_parallel.cpp`** – Worker's initial per-cube conflict
budget is now sourced from `m_smt_params.m_threads_max_conflicts` (the
user-visible `smt.threads.max_conflicts` parameter) instead of being
hardcoded to 1000, so users who leave the parameter at its default get
an unlimited initial budget matching Z3 4.12.x portfolio behaviour.
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
Co-authored-by: Nikolaj Bjorner <nbjorner@microsoft.com>
## Problem
Maximizing/minimizing under a **strict** inequality has a delta-rational
optimum. For
```smt2
(declare-const r Real)
(assert (< r 1))
(maximize r)
(check-sat)
(get-objectives)
```
the optimum is the supremum `1 - epsilon`, but z3 reported `r = 0`.
The same defect makes shared-symbol objectives report a value matching
**neither the model nor the true optimum** (issue #10028 follow-up).
Minimal reproducer — a 6-mark Golomb ruler (a `>32`-arg `distinct`, so
the objective is coupled to EUF) with a strict real objective `obj >
x5`, whose true optimum is `17 + epsilon`:
| case | before | after |
|---|---|---|
| `maximize r`, `r < 1` | `0` ❌ | `1 - epsilon` ✅ |
| `minimize r`, `r > 1` | `0` ❌ | `1 + epsilon` ✅ |
| Golomb `minimize obj`, `obj > x5` | `35/2` / `7+eps` ❌ | `17 +
epsilon` ✅ |
## Root cause
`check_bound` validates the LP hint by asserting `objective >= optimum`.
For a supremum `1 - epsilon` this is a **lower** bound whose value
carries a **negative** infinitesimal `(1, -1)`.
No `lconstraint_kind` can express that. The kind->infinitesimal map only
yields the *matching-sign* cases — `GT` -> lower `(r, +1)`, `LT` ->
upper `(r, -1)` — or zero (`GE`/`LE`). The opposite-sign lower bound
`(r, -1)` (i.e. `r >= r0 - delta`) is a *relaxation* that no strict
inequality produces. `opt_solver::mk_ge` therefore projected the
`-epsilon` away, turning `r >= 1 - epsilon` into the over-strong,
unsatisfiable `r >= 1`; validation failed and the strictly smaller
current model value was reported instead.
## Fix — carry the infinitesimal faithfully through the bound pipeline
- **`lp_api::bound`** gains an `eps` component so `get_value` returns
the true delta value (no spurious rational fixed-variable equality is
propagated to EUF).
- **`lar_base_constraint`** stores its right-hand side as a
delta-rational `impq` pair; `rhs()` returns the rational component,
`bound_eps()` the infinitesimal one.
- **`lar_solver`** bound activation/update threads the whole `impq`
bound, so a lower bound `(r, -1)` can be asserted. `constraint_holds`
accounts for it using the **same** strict-bounds delta that flattens the
model, computed **once per model**.
- **`theory_lra::mk_ge`** builds a *fresh* predicate for the `(r, -1)`
lower bound (to avoid colliding with an already-internalized `v >= r`
literal) and attaches `eps = -1`. **`opt_solver::mk_ge`** passes the
unprojected value to `theory_lra` / `theory_mi_arith` /
`theory_inf_arith` (whose bounds are already `inf_rational`).
The pair machinery is what makes the supremum both representable
(optimum `1 - epsilon`) and validatable; the reported witness model
remains the flattened rational (`find_delta_for_strict_bounds`),
consistent with the existing epsilon semantics.
## Validation
- Strict optima correct: `1-eps`, `1+eps`, bounded `2<r<5 -> 5-eps`, and
lex/box variants.
- Integer optima and the #10028 shared-symbol cases unchanged (Golomb
n=6/7/8 -> 17/25/34, consistent with the model).
- Unit tests **92/92** (release); no new debug-suite failures.
- Opt regression corpus (73 files, `model_validate=true`)
**byte-identical** to baseline.
Co-authored-by: Copilot <223556219+Copilot@users.noreply.github.com>
---------
Co-authored-by: Copilot <223556219+Copilot@users.noreply.github.com>
Co-authored-by: Nikolaj Bjorner <nbjorner@microsoft.com>
The Nightly **Mac ARM64 Build** job fails on current Xcode/libc++
because `std::format` pulls floating-point formatting paths that require
`std::to_chars` availability from macOS 13.3+. The job was still
compiling with a 13.0 deployment target.
- **Root cause**
- ARM64 nightly job used:
- `MACOSX_DEPLOYMENT_TARGET=13.0`
- `mk_unix_dist.py --os=osx-13.0`
- This mismatched the effective libc++ requirements in the runner
toolchain.
- **Workflow change**
- Updated only `.github/workflows/nightly.yml` for `mac-build-arm64`:
- `MACOSX_DEPLOYMENT_TARGET: "13.0" -> "13.3"`
- `--os=osx-13.0 -> --os=osx-13.3`
- **Resulting behavior**
- ARM64 nightly build target now aligns with the minimum OS level
required by the formatting code paths used by current compilation units.
```yaml
# .github/workflows/nightly.yml (mac-build-arm64)
env:
MACOSX_DEPLOYMENT_TARGET: "13.3"
- name: Build
run: python scripts/mk_unix_dist.py --dotnet-key=$GITHUB_WORKSPACE/resources/z3.snk --arch=arm64 --os=osx-13.3
```
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
## Summary
Hoists loop-invariant matrix reads out of the hot inner loop of
`pivot_column_non_fractional` in the Hermite Normal Form (HNF)
computation used by z3's linear-arithmetic integer solver. The
arithmetic is unchanged; the patch only removes repeated
permutation-indexed `mpq` accesses from an O(n2) elimination loop.
## Hotspot
`lp::hnf_calc::pivot_column_non_fractional<M>` (`src/math/lp/hnf.h:130`)
performs the Bareiss-style fraction-free Gaussian elimination step over
a matrix `m`:
```cpp
for (unsigned j = r + 1; j < m.column_count(); ++j)
for (unsigned i = r + 1; i < m.row_count(); ++i)
m[i][j] = (r > 0) ? (m[r][r]*m[i][j] - m[i][r]*m[r][j]) / m[r-1][r-1]
: (m[r][r]*m[i][j] - m[i][r]*m[r][j]);
```
For `general_matrix`, every `m[a][b]` builds a temporary `ref_row` and
performs two permutation-array indirections (row and column permutation
lookups in `src/math/lp/general_matrix.h`) before the underlying vector
access. Inside this double loop the terms `m[r][r]`, `m[r-1][r-1]` and
`m[r][j]` are re-read on every iteration even though they are invariant,
so those redundant indexed reads dominate the loop cost.
## Change and complexity argument
Rows `<= r` are never written by this loop — it only assigns `m[i][j]`
for `i > r`, `j > r` — so the three pivot entries in rows `<= r` are
loop-invariant:
- `m[r][r]` and `m[r-1][r-1]` are invariant across **both** loops → bind
`m[r][r]` to a reference and take a pointer to `m[r-1][r-1]` once before
the outer loop. The pointer is `nullptr` when `r == 0`, which also
encodes the existing "no division" case with a single branch.
- `m[r][j]` is invariant across the inner `i` loop → hoist it to a
reference at the top of the outer `j` loop.
- `m[i][j]` is bound to a reference so it is indexed once per iteration
instead of three times (two reads + one write).
This turns **O(n2)** repeated permutation-indexed `mpq` reads into
**O(1)/O(n)** hoisted reads. The operands, operation order, and division
are identical to the original, so the computed matrix is bit-for-bit the
same.
## Measurements
Profiled with callgrind (z3 built with the same configuration,
`model_validate=true`) on a representative integer-arithmetic problem
that exercises the HNF cut generator:
- Target function instructions: **6,793,150,548 → 6,241,093,226**
(0.9187×; its share of total drops 15.2% → 14.5%).
- Total program instructions: **44,727,385,309 → 43,036,726,143**
(0.9622×).
- Wall-clock: **5.53s → 4.89s (~11.6% faster)**.
- Differential correctness preserved: identical solver output before and
after the change.
## Logic class
Integer linear arithmetic — the HNF-based cut generation path in the
`lp` int-solver.
<!-- gh-aw-workflow-id: coz3-deepperf-fix -->
Co-authored-by: Copilot <223556219+Copilot@users.noreply.github.com>
Details in original PR: https://github.com/Z3Prover/z3/pull/10007
---------
---------
Signed-off-by: Nikolaj Bjorner <nbjorner@microsoft.com>
Co-authored-by: Can Cebeci <can.cebeci99@gmail.com>
Co-authored-by: Can Cebeci <t-cancebeci@microsoft.com>
The Ubuntu `python make - MT` job was failing in unit tests because the
debug-time well-sorted check could invalidate freshly constructed
assertion expressions during solver entry. This surfaced as crashes in
`theory_dl` and `seq_rewriter`, not as logic bugs in those tests.
- **Root cause**
- `is_well_sorted` traversed the input through a temporary
`expr_ref`/`subterms` wrapper.
- For freshly built assertions passed directly into `assert_expr`, that
temporary ownership could drop the last refcount during validation and
free the AST before the solver used it.
- **Change**
- Reworked the traversal in `src/ast/well_sorted.cpp` to walk raw
`expr*` nodes explicitly.
- The checker now validates subterms without taking transient ownership
of the asserted expression.
- **Effect**
- Debug validation remains intact.
- Temporary formulas survive the well-sorted check, so assertion-time
validation no longer corrupts the caller’s AST.
- **Representative change**
```cpp
ptr_vector<expr> todo;
expr_mark visited;
todo.push_back(e);
while (!todo.empty()) {
expr* term = todo.back();
todo.pop_back();
if (visited.is_marked(term))
continue;
visited.mark(term, true);
if (is_app(term)) {
for (expr* arg : *to_app(term))
if (!visited.is_marked(arg))
todo.push_back(arg);
check_app(to_app(term));
}
else if (is_var(term)) {
check_var(to_var(term));
}
else if (is_quantifier(term)) {
check_quantifier(to_quantifier(term));
}
}
```
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
## Summary
Fixes a completeness regression where `elim_uncnstr` was silently
disabled for ordinary (non-polymorphic) goals, detected by the
`snapshot-regression` corpus.
- **Originating discussion:**
https://github.com/Z3Prover/bench/discussions/3054
- **Benchmark:** `iss-6260/small-2.smt2` (corpus `Z3Prover/bench`,
`inputs/issues/iss-6260/`)
- **Divergence:** recorded oracle `sat` → current z3 produces `unknown`
### Divergence diff
```diff
--- small-2.expected.out (expected)
+++ produced (current z3)
@@ -1,3 +1,3 @@
-sat
+unknown
(error "line 17 column 0: unexpected character")
(error "line 17 column 1: unexpected character")
```
(The `(error ...)` lines are expected: the benchmark contains a stray
```` ``` ```` fence on line 17. Only the `sat` → `unknown` change is the
regression.)
## Root cause
`git bisect` over the regression window pins the flip to commit
`208cc5686` ("fix build"), which added `|| m().has_type_vars()` to the
`elim_uncnstr_tactic` guard and an equivalent `if (m.has_type_vars())
return;` to the `elim_unconstrained` simplifier.
`ast_manager::has_type_vars()` is a **manager-wide, sticky** flag: it is
set to `true` as soon as *any* type variable is created, and is never
reset. In particular `finite_set_decl_plugin::init()` creates type
variables `A`/`B` to define its polymorphic signatures. Those type
variables never occur in the user's assertions, but once the finite_set
plugin is initialized — which happens while processing this benchmark —
the flag is globally `true` (confirmed by instrumenting `mk_type_var`:
the only type vars created for this benchmark are the finite_set
signature vars `A` and `B`).
As a result `elim_uncnstr` bails out for goals that contain **no**
polymorphic terms at all, i.e. it is effectively disabled. Unconstrained
subterms that used to be eliminated now reach the theory solvers.
For this benchmark the (single) assertion is `(not (xor (>= x 0) (>= x1
0) (>= x 0) x4 (str.contains ...)))`. The duplicated `(>= x 0)` cancels
(`a xor a = false`), and the free Boolean `x4` can fix the parity
regardless of the value of the `str.contains` term, so the goal is
trivially `sat`. That `str.contains`/`str.replace_re` subterm is
unconstrained and was previously removed by `elim_uncnstr`; without that
elimination it reaches `theory_seq`, which marks `str.replace_re` as
unhandled and gives up in `final_check` → `unknown` (`incomplete (theory
seq)`).
## Fix
Make the guard precise. Keep `has_type_vars()` as a cheap pre-filter
(matching existing usage in `ast_translation.cpp` and
`ast_manager::has_type_var`), but only bail out when the goal / asserted
formulas **actually** contain type-variable typed terms, using the
existing `polymorphism::util::has_type_vars(expr*)`.
This preserves the polymorphism crash-protection (goals with genuine
type-variable terms still skip `elim_uncnstr`) while restoring
`elim_uncnstr` for the vast majority of goals that merely triggered a
polymorphic-plugin initialization. Both twin guards (the `elim_uncnstr`
tactic and the `elim_unconstrained` simplifier) are fixed consistently.
## Validation
Built this checkout and re-ran the benchmark (step 5 of the fixer
workflow):
- `./configure && make -C build -j$(nproc)` — Z3 version 4.17.0.
- Unpatched master reproduced the divergence: `z3 -T:20
iss-6260/small-2.smt2` → `unknown`.
- After the fix, `z3 -T:20 inputs/issues/iss-6260/small-2.smt2` produces
**exactly** the recorded oracle:
```
sat
(error "line 17 column 0: unexpected character")
(error "line 17 column 1: unexpected character")
(error "line 17 column 2: unexpected character")
```
- Regression sanity checks: sibling `iss-6260/small.smt2` unchanged
(`sat`); plain arithmetic unconstrained goals unchanged; polymorphic
goals with genuine type-variable terms (including `declare-type-var` and
forcing `(check-sat-using (then elim-uncnstr smt))`) still solve without
crashing — the guard still fires for those.
Opened as a **draft** for human review.
> Generated by [Fix a Z3 snapshot-regression
divergence](https://github.com/Z3Prover/bench/actions/runs/28844840657)
· 861.2 AIC · ⌖ 45.8 AIC · ⊞ 8.9K ·
[◷](https://github.com/search?q=repo%3AZ3Prover%2Fz3+%22gh-aw-workflow-id%3A+snapshot-regression-fixer%22&type=pullrequests)
<!-- gh-aw-agentic-workflow: Fix a Z3 snapshot-regression divergence,
engine: copilot, version: 1.0.63, model: claude-opus-4.8, id:
28844840657, workflow_id: snapshot-regression-fixer, run:
https://github.com/Z3Prover/bench/actions/runs/28844840657 -->
<!-- gh-aw-workflow-id: snapshot-regression-fixer -->
<!-- gh-aw-workflow-call-id: Z3Prover/bench/snapshot-regression-fixer
-->
Co-authored-by: Copilot <223556219+Copilot@users.noreply.github.com>
This patch fixes a corner case where quantifier conflicts can create
fresh terms that aren't marked as relevant.
I couldn't easily produce a minimal query that this patch turns stable,
nor did the patch stabilize the query I have been working on, but I
think the example below still illustrates the problem:
```
(set-option :auto_config false)
(set-option :type_check true)
(set-option :smt.case_split 3)
(set-option :smt.mbqi false)
(declare-fun R (Int) Bool)
(declare-fun S (Int) Bool)
(declare-fun dummy (Int) Bool)
(assert (or (R 0) (dummy 0)))
(assert (forall ((x Int)) (!
(and (not (R x)) (not (S x)))
:pattern ((R x))
:qid not_r_not_s
)))
(assert (forall ((x Int)) (!
(S x)
:pattern ((S x))
:qid s_true
)))
(check-sat)
```
The query is unstable (due to the same interaction between relevancy and
triggers in https://github.com/Z3Prover/z3/issues/7444): if the solver
assigns `(dummy 0)` first, it returns `unknown`.
If the solver assigns `(R 0)` first, we would expect an `unsat`. The
current implementation returns `unknown` because `not_r_not_s` leads to
a quantifier conflict, which creates `S(x)` without marking it (or any
of its ancestors) as relevant.
---------
Co-authored-by: Can Cebeci <t-cancebeci@microsoft.com>
Co-authored-by: Nikolaj Bjorner <nbjorner@microsoft.com>
This removes the temporary `lp.batch_explain_fixed_in_row` knob added
with the recent LP changes. The batched fixed-column explanation path is
kept as the only implementation, matching the follow-up review comments.
- **Problem**
- The new LP setting exposed a temporary fallback path that is no longer
needed.
- Keeping both paths added parameter surface area and settings plumbing
without a lasting behavioral distinction.
- **Changes**
- **Remove parameter definition**
- Delete `lp.batch_explain_fixed_in_row` from LP parameter generation.
- **Remove settings plumbing**
- Drop the stored field, accessor methods, and parameter update wiring
from `lp_settings`.
- **Keep batched explanation as default behavior**
- Remove the runtime branch in `lar_solver::explain_fixed_in_row`.
- Always linearize fixed-column witnesses together in a single
dependency pass.
- **Resulting simplification**
- The solver no longer carries a dead configuration toggle for fixed-row
explanation.
- The batched dependency-linearization path remains intact and is now
the sole code path.
```c++
void lar_solver::explain_fixed_in_row(unsigned row, explanation& ex) {
auto& witnesses = m_imp->m_tmp_witnesses;
witnesses.reset();
for (auto const& c : get_row(row)) {
if (!column_is_fixed(c.var()))
continue;
const column& ul = m_imp->m_columns[c.var()];
witnesses.push_back(ul.lower_bound_witness());
witnesses.push_back(ul.upper_bound_witness());
}
m_imp->m_tmp_dependencies.reset();
m_imp->m_dependencies.linearize(witnesses, m_imp->m_tmp_dependencies);
for (auto ci : m_imp->m_tmp_dependencies)
ex.push_back(ci);
}
```
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
Co-authored-by: Nikolaj Bjorner <nbjorner@microsoft.com>