Chapter 22 Micromega: tactics for solving arithmetic goals over ordered rings

Frédéric Besson and Evgeny Makarov

22.1 Short description of the tactics

The Psatz module (Require Import Psatz.) gives access to several tactics for solving arithmetic goals over Z, Q, and R:¹

lia is a decision procedure for linear integer arithmetic (see Section 22.5);
nia is an incomplete proof procedure for integer non-linear arithmetic (see Section 22.6);
lra is a decision procedure for linear (real or rational) arithmetic goals (see Section 22.3);
psatz D n where D is Z or Q or R, and n is an optional integer limiting the proof search depth is is an incomplete proof procedure for non-linear arithmetic. It is based on John Harrison’s HOL Light driver to the external prover csdp². Note that the csdp driver is generating a proof cache which makes it possible to rerun scripts even without csdp (see Section 22.4).

The tactics solve propositional formulas parameterized by atomic arithmetic expressions interpreted over a domain D ∈ {ℤ, ℚ, ℝ }. The syntax of the formulas is the following:

F	::=	A ∣ P ∣ True ∣ False ∣ F₁ ∧ F₂ ∣ F₁ ∨ F₂ ∣ F₁ ↔ F₂ ∣ F₁ → F₂ ∣ ¬ F
A	::=	p₁ = p₂ ∣ p₁ > p₂ ∣ p₁ < p₂ ∣ p₁ ≥ p₂ ∣ p₁ ≤ p₂
p	::=	c ∣ x ∣ −p ∣ p₁ − p₂ ∣ p₁ + p₂ ∣ p₁ × p₂ ∣ p `^` n

where c is a numeric constant, x∈ D is a numeric variable, the operators −, +, × are respectively subtraction, addition, product, p ^n is exponentiation by a constant n, P is an arbitrary proposition. For Q, equality is not Leibniz equality = but the equality of rationals ==.

For Z (resp. Q ), c ranges over integer constants (resp. rational constants). For R, the tactic recognizes as real constants the following expressions:

c ::= R0 | R1 | Rmul(c,c) | Rplus(c,c) | Rminus(c,c) | IZR z | IQR q
    | Rdiv(c,c) | Rinv c

where z is a constant in Z and q is a constant in Q. This includes integer constants written using the decimal notation i.e., c%R.

22.2 Positivstellensatz refutations

The name psatz is an abbreviation for positivstellensatz – literally positivity theorem – which generalizes Hilbert’s nullstellensatz. It relies on the notion of Cone. Given a (finite) set of polynomials S, Cone(S) is inductively defined as the smallest set of polynomials closed under the following rules:

p ∈ S

p ∈ Cone(S)

p² ∈ Cone(S)

p₁ ∈ Cone(S) p₂ ∈ Cone(S) ⑅ ∈ {+,*}

p₁ ⑅ p₂ ∈ Cone(S)

The following theorem provides a proof principle for checking that a set of polynomial inequalities does not have solutions.³

Theorem 1 Let S be a set of polynomials.
If −1 belongs to Cone(S) then the conjunction ∧_{p ∈ S} p≥ 0 is unsatisfiable.

A proof based on this theorem is called a positivstellensatz refutation. The tactics work as follows. Formulas are normalized into conjunctive normal form ∧_i C_i where C_i has the general form (∧_{j∈ S_i} p_j ⑅ 0) → False) and ⑅ ∈ {>,≥,=} for D∈ {ℚ,ℝ} and ⑅ ∈ {≥, =} for ℤ. For each conjunct C_i, the tactic calls a oracle which searches for −1 within the cone. Upon success, the oracle returns a cone expression that is normalized by the ring tactic (see chapter 25) and checked to be −1.

22.3 lra: a decision procedure for linear real and rational arithmetic

The lra tactic is searching for linear refutations using Fourier elimination.⁴ As a result, this tactic explores a subset of the Cone defined as

LinCone(S) =

⎧
⎪
⎨
⎪
⎩

∑

p ∈ S

α_p × p

⎪
⎪
⎪
⎪

α_p are positive constants

⎫
⎪
⎬
⎪
⎭

The deductive power of lra is the combined deductive power of ring_simplify and fourier. There is also an overlap with the field tactic e.g., x = 10 * x / 10 is solved by lra.

22.4 psatz: a proof procedure for non-linear arithmetic

The psatz tactic explores the Cone by increasing degrees – hence the depth parameter n. In theory, such a proof search is complete – if the goal is provable the search eventually stops. Unfortunately, the external oracle is using numeric (approximate) optimization techniques that might miss a refutation.

To illustrate the working of the tactic, consider we wish to prove the following Coq goal.

Coq < Goal forall x, -x^2 >= 0 -> x - 1 >= 0 -> False.

Such a goal is solved by intro x; psatz Z 2. The oracle returns the cone expression 2 × (x−1) + (x−1) × (x−1) + −x² (polynomial hypotheses are printed in bold). By construction, this expression belongs to Cone({−x², x −1}). Moreover, by running ring we obtain −1. By Theorem 1, the goal is valid.

22.5 lia: a tactic for linear integer arithmetic

The tactic lia offers an alternative to the omega and romega tactic (see Chapter 21). Roughly speaking, the deductive power of lia is the combined deductive power of ring_simplify and omega. However, it solves linear goals that omega and romega do not solve, such as the following so-called omega nightmare [130].

Coq < Goal forall x y,
27 <= 11 * x + 13 * y <= 45 ->
-10 <= 7 * x - 9 * y <= 4 -> False.

The estimation of the relative efficiency of lia vs omega and romega is under evaluation.

High level view of lia.

Over ℝ, positivstellensatz refutations are a complete proof principle.⁵ However, this is not the case over ℤ. Actually, positivstellensatz refutations are not even sufficient to decide linear integer arithmetic. The canonical example is 2 * x = 1 -> False which is a theorem of ℤ but not a theorem of ℝ. To remedy this weakness, the lia tactic is using recursively a combination of:

linear positivstellensatz refutations;
cutting plane proofs;
case split.

Cutting plane proofs

are a way to take into account the discreetness of ℤ by rounding up (rational) constants up-to the closest integer.

Theorem 2 Let p be an integer and c a rational constant.

p ≥ c ⇒ p ≥ ⌈ c ⌉

For instance, from 2 x = 1 we can deduce

x ≥ 1/2 which cut plane is x ≥ ⌈ 1/2 ⌉ = 1;
x ≤ 1/2 which cut plane is x ≤ ⌊ 1/2 ⌋ = 0.

By combining these two facts (in normal form) x − 1 ≥ 0 and −x ≥ 0, we conclude by exhibiting a positivstellensatz refutation: −1 ≡ x−1 + −x ∈ Cone({x−1,x}).

Cutting plane proofs and linear positivstellensatz refutations are a complete proof principle for integer linear arithmetic.

Case split

enumerates over the possible values of an expression.

Theorem 3 Let p be an integer and c₁ and c₂ integer constants.

c₁ ≤ p ≤ c₂ ⇒

∨

x ∈ [c₁,c₂]

p = x

Our current oracle tries to find an expression e with a small range [c₁,c₂]. We generate c₂ − c₁ subgoals which contexts are enriched with an equation e = i for i ∈ [c₁,c₂] and recursively search for a proof.

22.6 nia: a proof procedure for non-linear integer arithmetic

The nia tactic is an experimental proof procedure for non-linear integer arithmetic. The tactic performs a limited amount of non-linear reasoning before running the linear prover of lia. This pre-processing does the following:

If the context contains an arithmetic expression of the form e[x²] where x is a monomial, the context is enriched with x²≥ 0;
For all pairs of hypotheses e₁≥ 0, e₂ ≥ 0, the context is enriched with e₁ × e₂ ≥ 0.

After pre-processing, the linear prover of lia searches for a proof by abstracting monomials by variables.

1: Support for nat and N is obtained by pre-processing the goal with the zify tactic.
2: Sources and binaries can be found at https://projects.coin-or.org/Csdp
3: Variants deal with equalities and strict inequalities.
4: More efficient linear programming techniques could equally be employed.
5: In practice, the oracle might fail to produce such a refutation.