# How to replace ⋀ and ⟹ with ∀ and ⟶ in assumption

I'm an Isabelle newbie, and I'm a little (actually, a lot) confused about the relationship between ⋀ and ∀, and between ⟹ and ⟶.

I have the following goal (which is a highly simplified version of something that I've ended up with in a real proof):

``````⟦⋀x. P x ⟹ P z; P y⟧ ⟹ P z
``````

which I want to prove by specialising x with y to get ⟦P y ⟹ P z; P y⟧ ⟹ P z, and then using modus ponens. This works for proving the very similar-looking:

``````⟦∀x. P x ⟶ P z; P y⟧ ⟹ P z
``````

but I can't get it to work for the goal above.

Is there a way of converting the former goal into the latter? If not, is this because they are logically different statements, in which case can someone help me understand the difference?

-

The two premises `!!x. P x ==> P y` and `ALL x. P x --> P y` are logically equivalent is shown by the following proof

``````lemma
"(⋀x. P x ⟹ P y) ≡ (Trueprop (∀x. P x ⟶ P y))"
``````

When I tried the same kind of reasoning for your example proof I ran into a problem however. I intended to do the following proof

``````lemma
"⟦⋀x. P x ⟹ P z; P y⟧ ⟹ P z"
apply (subst (asm) atomize_imp)
apply (unfold atomize_all)
apply (drule spec [of _ y])
apply (erule rev_mp)
apply assumption
done
``````

but at `unfold atomize_all` I get

``````Failed to apply proof method:
``````

When trying to explicitly instantiate the lemma I get a more clear error message, i.e.,

``````apply (unfold atomize_all [of "λx. P x ⟶ P z"])
``````

yields

``````Type unification failed: Variable 'a::{} not of sort type
``````

This I find strange, since as far as I know every type variable should be of sort `type`. We can solve this issue by adding an explicit sort constraint:

``````lemma
"⟦⋀x::_::type. P x ⟹ P z; P y⟧ ⟹ P z"
``````

Then the proof works as shown above.

Cutting a long story short. I usually work with `Isar` structured proofs instead of `apply` scripts. Then such issues are often avoided. For your statement I would actually do

``````lemma
"⟦⋀x. P x ⟹ P z; P y⟧ ⟹ P z"
proof -
assume *: "⋀x. P x ⟹ P z"
and **: "P y"
from * [OF **] show ?thesis .
qed
``````

Or maybe more idiomatic

``````lemma
assumes *: "⋀x. P x ⟹ P z"
and **: "P y"
shows "P z"
using * [OF **] .
``````
-
Thank you! Lots here for me to digest, but `atomize_imp` and `atomize_all` were exactly what I needed to make progress, and I don't run into that strange error in my case. I haven't looked at any structured proofs yet, but I shall be doing soon. –  jchl Jan 29 '14 at 15:10
The atomize rules are OK to explore the situation, and learn about certain internals of Isabelle/Pure vs. Isabelle/HOL. In real application you should see them rarely: ending up in the wrong logical corner just means statements and proofs should be written differently. –  Makarius Feb 2 '14 at 21:55

C.Sternagel answered your title question "How?", which satisfied your last sentence, but I go ahead and fill in some details based on his answer, to try to "help [you] understand the difference".

It can be confusing that there is `==>` and `-->`, meta-implication and HOL-implication, and that they both have the properties of logical implication. (I don't say much about `!!` and `!`, meta-all and HOL-all, because what's said about `==>` and `-->` can be mostly be transferred to them.)

(NOTE: I convert graphical characters to equivalent ASCII when I can, to make sure they display correctly in all browsers.)

First, I give some references:

• [1] Isabelle/Isar Reference manual.
• [2] HOL/HOL.thy
• [3] Logic in Computer Science, by Huth and Ryan
• [4] Wiki sequent entry.
• [5] Wiki intuitionistic logic entry.

If you understand a few basics, there's nothing that confusing about the fact that there is both `==>` and `-->`. Much of the confusion departs, and what's left is just the work of digging through the details about what particular source statements mean, such as the formula of C.Sternagel's first lemma.

``````"(!!x. P x ==> P y) == (Trueprop (!x. P x --> P y))"
``````

C.Sternagel stopped taking the time to give me important answers, but the formula he gives you above is similar to one he gave me a while ago, to convince me that all free variables in a formula are universally quantified.

Short answer: The difference between `==>` and `-->` is that `==>` (somewhat) plays the part of the turnstile symbol, `|-`, of a non-generalized sequent in which there is only one conclusion on the right-hand side. That is, `==>`, the meta-logic implication operator of Isabelle/Pure, is used to define the Isabelle/HOL implication object-logic operator `-->`, as shown by `impI` in the following `axiomatization` in `HOL.thy` [2].

``````(*line 56*)
typedecl bool
judgment
Trueprop :: "bool => prop"

(*line 166*)
axiomatization where
impI: "(P ==> Q) ==> P-->Q" and
mp: "[| P-->Q;  P |] ==> Q" and

iff: "(P-->Q) --> (Q-->P) --> (P=Q)" and
True_or_False: "(P=True) | (P=False)"
``````

Above, I show the definition of three other axioms: `mp` (modus ponuns), `iff`, and `True_or_False` (law of excluded middle). I do that to repeatedly show how `==>` is used to define the axioms and operators of the HOL logic. I also threw in the `judgement` to show that some of the sequent vocabulary is used in the language Isar.

I also show the axiom `True_or_False` to show that the Isabelle/HOL logic has an axiom which Isabelle/Pure doesn't have, the law of excluded middle [5]. This is huge in answering your question "what is the difference?"

It was a recent answer by A.Lochbihler that finally gave meaning, for me, to "intuitionistic" [5]. I had repeatedly seen "intuitionistic" in the Isabelle literature, but it didn't sink in.

If you can understand the differences in the next source, then you can see that there's a big difference between `==>` and `-->`, and between types `prop` and `bool`, where `prop` is the type of meta-logic propositions, as opposed to `bool`, which is the type of the HOL logic proposition. In the HOL object-logic, `False` implies any proposition `Q::bool`. However, `False::bool` doesn't imply any proposition `Q::prop`.

The type `prop` is a big part of the meta-logic team `!!`, `==>`, and `==`.

``````theorem "(!!P. P::bool) == Trueprop (False::bool)"
by(rule equal_intr_rule, auto)

theorem HOL_False_meta_implies_any_prop_Q:
"(!!P. P::bool) ==> PROP Q"
(*Currently, trying by(auto) will hang my machine due to blast, which is know
to be a problem, and supposedly is fixed in the current repository. With
`Auto methods` on in the options, it tries `auto`, thus it will hang it.*)
oops

theorem HOL_False_meta_implies_any_bool_Q:
"(!!P. P::bool) ==> Q::bool"
by(rule meta_allE)

theorem HOL_False_obj_implies_any_bool_Q:
"(!P. P::bool) --> Q::bool"
by(auto)
``````

When you understand that Isabelle/Pure meta-logic `==>` is used to define the HOL logic, and other differences, such as that the meta-logic is weaker because of no excluded middle, then you understand that there are significant differences between the meta-operators, `!!`, `==>`, and `==`, in comparison to the HOL object-logic operators, `!`, `-->`, and `=`.

From here, I put in more details, partly to convince any expert that I'm not totally abusing the word `sequent`, where my use here is based primarily on how it's used in reference [3, Huth and Ryan].

## Attempting to not write a book

I throw in some quotes and references to show that there's a relationship between sequents and `==>`.

From my research, I can't see that the word "sequent" is standardized. As far as I can tell, in [3.pg 5], Huth and Ryan use "sequent" to mean a sequent which has only has one conclusion on the right-hand side.

...This intention we denote by

phi1, phi2, ..., phiN |- psi

This expression is called a sequent; it is valid if a proof can be found.

A more narrow definition of sequent, in which the right-hand side has only one conclusion, matches up very nicely with the use of `==>`.

We can blame L.Paulson for confusing us by separating the meta-logic from the object-logic, though we can thank him for giving us a larger logical playground.

Maybe to keep from clashing with the common definition of a sequent, as in [4, Wiki], he uses the phrase `natural deduction sequent calculus` in various places in the literature. In any case, the use of `==>` is completely related to implementing natural deduction rules in the logic of Isabelle/HOL.

Even with generalized sequents, L.Paulson prefers the `==>` notation:

You asked about differences. I throw in some source related to C.Sternagel's answer, along with the `impI` axiomatization again:

``````(*line 166*)
axiomatization where
impI: "(P ==> Q) ==> P-->Q"

(*706*)
lemma --"atomize_all [atomize]:"
"(!!x. P x) == Trueprop (ALL x. P x)"
by(rule atomize_all)

(*715*)
lemma --"atomize_imp [atomize]:"
"(A ==> B) == Trueprop (A --> B)"
by(rule atomize_imp)

(*line 304*)
lemma --"allI:"
assumes "!!x::'a. P(x)"
shows "ALL x. P(x)"
by(auto simp only: assms allI
``````

I put `impI` in structured proof format:

``````lemma impI_again:
assumes "P ==> Q"
shows "P --> Q"
``````

Now, consider `==>` to be the use of the sequent turnstile, and `shows` to be the sequent notation horizontal bar, then you have the following sequent:

``````P |- Q
-------
P --> Q
``````

This is the natural deduction implication introduction rule, as the axiom name says, `impI` (Cornell Lecture 15).

The Big Guys have been on top of all of this for a long time. See [1, Section 2.1, page 27] for an overview of `!!`, `==>`, and `==`. In particular, it says

The Pure logic [38, 39] is an intuitionistic fragment of higher-order logic [13]. In type-theoretic parlance, there are three levels of lambda-calculus with corresponding arrows `=>`/!!/==>`...

One general significance of the statement is that in the use of Isabelle/HOL, you are using two logics, a meta-logic and an object-logic, where those two terms come from L.Paulson, and where "intuitionistic" is a key defining point of the meta-logic.

See also [1, Section 9.4.1, Simulating sequents by natural deduction, pg 206]. According to M.Wenzel on the IsaUsersList, L.Paulson wrote this section. On page 205, Paulson first takes the definition of a sequent to be the generalized definition. On page 206, he then shows how you can line up one type of sequent with the use of `==>`, which is by negating every proposition on the right-hand side of a sequent, except for one of them.

That, by all appearances, is a horn clause, which I know nothing about.

It seems obvious to me that using `==>` is the use of a limited form of sequents. In any event, that's how I think of it, and thinking that way has given me an understanding of the differences between `==>` and `-->`, along with the fact that the meta-logic has no excluded middle.

If A.Lochbhiler wouldn't have pointed out the absence of an excluded middle, I wouldn't have seen an important difference of what's possible with `==>`, and what's possible with `-->`.

Maybe C.Sternagel will start back again to give me some of his important answers.

-

Others have already explained some of the reasons behind the difference between meta-logic and logic, but missed the simple tactic `apply atomize`:

``````lemma "⟦⋀(x::'a). P x ⟹ P z ; P y⟧ ⟹ P z"
apply atomize
``````

which yields the goal:

``````⟦ ∀x. P x ⟶ P z; P y ⟧ ⟹ P z
``````

as desired.

(The additional type constraint `⋀(x::'a)` is required for the reasons mentioned by chris.)

-
I'd already stumbled across `atomize`, and found it to do what I wanted in a case where `atomize_imp` and `atomize_all` didn't. However, the fact that there's no mention of this (nor `atomize_imp`/`atomize_all` for that matter) in the Isabelle tutorial lead me to think that I must be doing something wrong... –  jchl Jan 30 '14 at 12:42
A common convention is to write rules using HOL operators (such as `∀x. P x`), and then use the attribute `[rule_format]` to convert the operators in their meta-logical equivalents. I personally prefer the approach of writing the rule I want, and then using `apply atomize` to start working on it. I don't think there is anything "wrong" with this, just a matter of preference. –  davidg Feb 3 '14 at 3:01

There is a lot of text already, so just a few brief notes:

Isabelle/Pure is minimal-higher order logic with the main connectives ⋀ and ⟹ to lay out Natural Deduction rules in a declarative way. The system knows how to compose them by basic means, e.g. in Isar proofs, proof methods like `rule`, attributes like `OF`.

Isabelle/HOL is full higher-order logic, with the full set of predicate logic connectives, e.g. ∀ ∃ ∧ ∨ ¬ ⟶ ⟷, and much more library material. Canonical introduction rules like `allI`, `allE`, `exI`, `exE` etc. for these connectives explain formally how the reaosoning works wrt. the Pure framework. HOL ∀ and ⟶ somehow correspond to Pure ⋀ and ⟹, but they are of different category and should not be thrown into the same box.

Note that apart from the basic `thm` command to print such theorems, it occasionally helps to use `print_statement` to get an Isar reading of these Natural Deduction reasoning forms.

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