Transitivity conversion: given two conversions (which take an
expression e
and returns (e', ⊢ e = e')
), produces another
conversion that combines them with transitivity, treating failures
as reflexivity conversions.
traverse f e
applies the monadic function f
to the direct descendants of e
.
mfoldl f a e
folds the monadic function f
over the subterms of the expression e
,
with initial value a
.
kreplace e old new
replaces all occurrences of the expression old
in e
with new
. The occurrences of old
in e
are determined using keyed matching
with transparency md
; see kabstract
for details. If unify
is true,
we may assign metavariables in e
as we match subterms of e
against old
.
pre.contains_sorry_aux nm
checks whether sorry
occurs in the value of the declaration nm
or (recusively) in any declarations occurring in the value of nm
with namespace pre
.
Auxiliary function for name.contains_sorry
.
nm.contains_sorry
checks whether sorry
occurs in the value of the declaration nm
or
in any declarations nm._proof_i
(or to be more precise: any declaration in namespace nm
).
See also expr.contains_sorry
.
get_state
returns the underlying state inside an interaction monad, from within that monad.
set_state
sets the underlying state inside an interaction monad, from within that monad.
run_with_state state tac
applies tac
to the given state state
and returns the result,
subsequently restoring the original state.
If tac
fails, then run_with_state
does too.
join' [a,b,c]
produces the format object abc
.
It differs from format.join
by using format.nil
instead of ""
for the empty list.
intercalate x [a, b, c]
produces the format object a.x.b.x.c
,
where .
represents format.join
.
soft_break
is similar to line
. Whereas in group (x ++ line ++ y ++ line ++ z)
the result either fits on one line or in three, x ++ soft_break ++ y ++ soft_break ++ z
each line break is decided independently
Format a list as a comma separated list, without any brackets.
format a list
by separating elements with soft_break
instead of line
add_local_consts_as_local_hyps vars
add the given list vars
of expr.local_const
s to the
tactic state. This is harder than it sounds, since the list of local constants which we have
been passed can have dependencies between their types.
For example, suppose we have two local constants n : ℕ
and h : n = 3
. Then we cannot blindly
add h
as a local hypothesis, since we need the n
to which it refers to be the n
created as
a new local hypothesis, not the old local constant n
with the same name. Of course, these
dependencies can be nested arbitrarily deep.
If the list of passed local constants have types which depend on one another (which can only
happen by hand-crafting the expr
s manually), this function will loop forever.
Compute the arity of explicit arguments of type
.
Compute the arity of explicit arguments of fn
's type.
For e = f x₁ ... xₙ
, get_app_fn_args_whnf e
returns (f, [x₁, ..., xₙ])
. e
is normalised as necessary; for example:
get_app_fn_args_whnf `(let f := g x in f y) = (`(g), [`(x), `(y)])
The returned expression is in whnf, but the arguments are generally not.
get_app_fn_whnf e md unfold_ginductive
is like expr.get_app_fn e
but e
is
normalised as necessary (with transparency md
). unfold_ginductive
controls
whether constructors of generalised inductive types are unfolded. The returned
expression is in whnf.
get_app_fn_const_whnf e md unfold_ginductive
expects that e = C x₁ ... xₙ
,
where C
is a constant, after normalisation with transparency md
. If so, the
name of C
is returned. Otherwise the tactic fails. unfold_ginductive
controls whether constructors of generalised inductive types are unfolded.
get_app_args_whnf e md unfold_ginductive
is like expr.get_app_args e
but e
is normalised as necessary (with transparency md
). unfold_ginductive
controls whether constructors of generalised inductive types are unfolded. The
returned expressions are not necessarily in whnf.
pis loc_consts f
is used to create a pi expression whose body is f
.
loc_consts
should be a list of local constants. The function will abstract these local
constants from f
and bind them with pi binders.
For example, if a, b
are local constants with types Ta, Tb
,
pis [a, b] `(f a b)
will return the expression
Π (a : Ta) (b : Tb), f a b
.
lambdas loc_consts f
is used to create a lambda expression whose body is f
.
loc_consts
should be a list of local constants. The function will abstract these local
constants from f
and bind them with lambda binders.
For example, if a, b
are local constants with types Ta, Tb
,
lambdas [a, b] `(f a b)
will return the expression
λ (a : Ta) (b : Tb), f a b
.
mk_theorem n ls t e
creates a theorem declaration with name n
, universe parameters named
ls
, type t
, and body e
.
eval_expr' α e
attempts to evaluate the expression e
in the type α
.
This is a variant of eval_expr
in core. Due to unexplained behavior in the VM, in rare
situations the latter will fail but the former will succeed.
mk_fresh_name
returns identifiers starting with underscores,
which are not legal when emitted by tactic programs. mk_user_fresh_name
turns the useful source of random names provided by mk_fresh_name
into
names which are usable by tactic programs.
The returned name has four components which are all strings.
has_attribute' attr_name decl_name
checks
whether decl_name
exists and has attribute attr_name
.
local_decls
returns a dictionary mapping names to their corresponding declarations.
Covers all declarations from the current file.
get_decls_from
returns a dictionary mapping names to their
corresponding declarations. Covers all declarations the files listed
in fs
, with the current file listed as none
.
The path of the file names is expected to be relative to
the root of the project (i.e. the location of leanpkg.toml
when it
is present); e.g. "src/tactic/core.lean"
Possible issue: get_decls_from
uses get_cwd
, the current working
directory, which may not always point at the root of the project.
It would work better if it searched for the root directory or,
better yet, if Lean exposed its path information.
If {nm}_{n}
doesn't exist in the environment, returns that, otherwise tries {nm}_{n+1}
Return a name which doesn't already exist in the environment. If nm
doesn't exist, it
returns that, otherwise it tries nm_2
, nm_3
, ...
Returns a pair (e, t)
, where e ← mk_const d.to_name
, and t = d.type
but with universe params updated to match the fresh universe metavariables in e
.
This should have the same effect as just
do e ← mk_const d.to_name,
t ← infer_type e,
return (e, t)
but is hopefully faster.
Replace every universe metavariable in an expression with a universe parameter.
(This is useful when making new declarations.)
mk_local n
creates a dummy local variable with name n
.
The type of this local constant is a constant with name n
, so it is very unlikely to be
a meaningful expression.
Update the type of a local constant or metavariable. For local constants and
metavariables obtained via, for example, tactic.get_local
, the type stored in
the expression is not necessarily the same as the type returned by infer_type
.
This tactic, given a local constant or metavariable, updates the stored type to
match the output of infer_type
. If the input is not a local constant or
metavariable, update_type
does nothing.
elim_gen_prod n e _ ns
with e
an expression of type psigma _
, applies cases
on e
n
times and uses ns
to name the resulting variables. Returns a triple: list of new variables,
remaining term and unused variable names.
Given elab_def
, a tactic to solve the current goal,
extract_def n trusted elab_def
will create an auxiliary definition named n
and use it
to close the goal. If trusted
is false, it will be a meta definition.
Runs a tactic for a result, reverting the state after completion.
Runs a tactic for a result, reverting the state after completion or error.
Given a tactic tac
that takes an expression
and returns a new expression and a proof of equality,
use that tactic to change the type of the hypotheses listed in hs
,
as well as the goal if tgt = tt
.
Returns tt
if any types were successfully changed.
revert_after e
reverts all local constants after local constant e
.
revert_target_deps
reverts all local constants on which the target depends (recursively).
Returns the number of local constants that have been reverted.
generalize' e n
generalizes the target with respect to e
. It creates a new local constant
with name n
of the same type as e
and replaces all occurrences of e
by n
.
generalize'
is similar to generalize
but also succeeds when e
does not occur in the
goal, in which case it just calls assert
.
In contrast to generalize
it already introduces the generalized variable.
intron_no_renames n
calls intro
n
times, using the pretty-printing name
provided by the binder to name the new local constant.
Unlike intron
, it does not rename introduced constants if the names shadow existing constants.
get_univ_level t
returns the universe level of a type t
Various tactics related to local definitions (local constants of the form x : α := t
) #
We call t
the value of x
.
local_def_value e
returns the value of the expression e
, assuming that e
has been defined
locally using a let
expression. Otherwise it fails.
is_local_def e
succeeds when e
is a local definition (a local constant of the form
e : α := t
) and otherwise fails.
Returns the local definitions from the context. A local definition is a
local constant of the form e : α := t
. The local definitions are returned in
the order in which they appear in the context.
partition_local_deps vs
, with vs
a list of local constants,
reorders vs
in the order they appear in the local context together
with the variables that follow them. If local context is [a,b,c,d,e,f]
,
and that we call partition_local_deps [d,b]
, we get [[d,e,f], [b,c]]
.
The head of each list is one of the variables given as a parameter.
clear_value [e₀, e₁, e₂, ...]
clears the body of the local definitions e₀
, e₁
, e₂
, ...
changing them into regular hypotheses. A hypothesis e : α := t
is changed to e : α
. The order of
locals e₀
, e₁
, e₂
does not matter as a permutation will be chosen so as to preserve type
correctness. This tactic is called clearbody
in Coq.
context_has_local_def
is true iff there is at least one local definition in
the context.
context_upto_hyp_has_local_def h
is true iff any of the hypotheses in the
context up to and including h
is a local definition.
If the expression h
is a local variable with type x = t
or t = x
, where x
is a local
constant, tactic.subst' h
substitutes x
by t
everywhere in the main goal and then clears h
.
If h
is another local variable, then we find a local constant with type h = t
or t = h
and
substitute t
for h
.
This is like tactic.subst
, but fails with a nicer error message if the substituted variable is a
local definition. It is trickier to fix this in core, since tactic.is_local_def
is in mathlib.
A variant of simplify_bottom_up
. Given a tactic post
for rewriting subexpressions,
simp_bottom_up post e
tries to rewrite e
starting at the leaf nodes. Returns the resulting
expression and a proof of equality.
Creates an instance_cache
for the type α
.
If n
is the name of a type class with one parameter, get c n
tries to find an instance of
n c.α
by checking the cache c
. If there is no entry in the cache, it tries to find the instance
via type class resolution, and updates the cache.
If e
is a pi
expression that binds an instance-implicit variable of type n
,
append_typeclasses e c l
searches c
for an instance p
of type n
and returns p :: l
.
Creates the application n c.α p l
, where p
is a type class instance found in the cache c
.
c.of_nat n
creates the c.α
-valued numeral expression corresponding to n
.
c.of_int n
creates the c.α
-valued numeral expression corresponding to n
.
The output is either a numeral or the negation of a numeral.
A variation on assert
where a (possibly incomplete)
proof of the assertion is provided as a parameter.
(h,gs) ← local_proof `h p tac
creates a local h : p
and
use tac
to (partially) construct a proof for it. gs
is the
list of remaining goals in the proof of h
.
The benefits over assert are:
- unlike with
h ← assert `h p, tac
,h
cannot be used bytac
; - when
tac
does not complete the proof ofh
, returning the list of goals allows one to write a tactic usingh
and with the confidence that a proof will not boil over to goals left over from the proof ofh
, unlike what would be the case when usingtactic.swap
.
var_names e
returns a list of the unique names of the initial pi bindings in e
.
When struct_n
is the name of a structure type,
subobject_names struct_n
returns two lists of names (instances, fields)
.
The names in instances
are the projections from struct_n
to the structures that it extends
(assuming it was defined with old_structure_cmd false
).
The names in fields
are the standard fields of struct_n
.
expanded_field_list struct_n
produces a list of the names of the fields of the structure
named struct_n
. These are returned as pairs of names (prefix, name)
, where the full name
of the projection is prefix.name
.
struct_n
cannot be a synonym for a structure
, it must be itself a structure
Returns the only goal, or fails if there isn't just one goal.
This makes sure that the execution of the tactic does not change the tactic state. This can be helpful while using rewrite, apply, or expr munging. Remember to instantiate your metavariables before you're done!
Constructs a list of tactic expr
given a list of p-expressions, as follows:
- if the p-expression is the name of a theorem, use
i_to_expr_for_apply
on it - if the p-expression is a user attribute, add all the theorems with this attribute to the list.
We need to return a list of tactic expr
, rather than just expr
, because these expressions
will be repeatedly applied against goals, and we need to ensure that metavariables don't get stuck.
apply_rules hs n
: apply the list of rules hs
(given as pexpr) and assumption
on the
first goal and the resulting subgoals, iteratively, at most n
times.
Unlike solve_by_elim
, apply_rules
does not do any backtracking, and just greedily applies
a lemma from the list until it can't.
replace h p
elaborates the pexpr p
, clears the existing hypothesis named h
from the local
context, and adds a new hypothesis named h
. The type of this hypothesis is the type of p
.
Fails if there is nothing named h
in the local context.
- to_apply_cfg : tactic.apply_cfg
- use_symmetry : bool
- use_exfalso : bool
Configuration options for apply_any
:
use_symmetry
: ifapply_any
fails to apply any lemma, callsymmetry
and try again.use_exfalso
: ifapply_any
fails to apply any lemma, callexfalso
and try again.apply
: specify an alternative totactic.apply
; usuallyapply := tactic.eapply
.
This is a version of apply_any
that takes a list of tactic expr
s instead of expr
s,
and evaluates these as thunks before trying to apply them.
We need to do this to avoid metavariables getting stuck during subsequent rounds of apply
.
apply_any lemmas
tries to apply one of the list lemmas
to the current goal.
apply_any lemmas opt
allows control over how lemmas are applied.
opt
has fields:
use_symmetry
: if no lemma applies, callsymmetry
and try again. (Defaults tott
.)use_exfalso
: if no lemma applies, callexfalso
and try again. (Defaults tott
.)apply
: use a tactic other thantactic.apply
(e.g.tactic.fapply
ortactic.eapply
).
apply_any lemmas tac
calls the tactic tac
after a successful application.
Defaults to skip
. This is used, for example, by solve_by_elim
to arrange
recursive invocations of apply_any
.
Try to apply a hypothesis from the local context to the goal.
change_core e none
is equivalent to change e
. It tries to change the goal to e
and fails
if this is not a definitional equality.
change_core e (some h)
assumes h
is a local constant, and tries to change the type of h
to e
by reverting h
, changing the goal, and reintroducing hypotheses.
Returns a list of all metavariables in the current partial proof. This can differ from the list of goals, since the goals can be manually edited.
sorry_if_contains_sorry
will solve any goal already containing sorry
in its type with sorry
,
and fail otherwise.
Succeeds only if the current goal is a proposition.
Succeeds only if we can construct an instance showing the current goal is a subsingleton type.
Succeeds only if the current goal is "terminal",
in the sense that no other goals depend on it
(except possibly through shared metavariables; see independent_goal
).
Succeeds only if the current goal is "independent", in the sense that no other goals depend on it, even through shared meta-variables.
Apply a tactic as many times as possible, collecting the results in a list. Fail if the tactic does not succeed at least once.
Introduces one or more variables and returns the new local constants.
Fails if intro
cannot be applied.
Run a tactic "under binders", by running intros
before, and revert
afterwards.
Run a tactic "under binders", by running intros
before, and revert
afterwards.
Try all the tactics in a list, each time starting at the original tactic_state
,
returning the list of successful results,
and reverting to the original tactic_state
.
Try all the tactics in a list, each time starting at the original tactic_state
,
returning the list of successful results sorted by
the value produced by a subsequent execution of the sort_by
tactic,
and reverting to the original tactic_state
.
Just like split
, fsplit
applies the constructor when the type of the target is
an inductive data type with one constructor.
However it does not reorder goals or invoke auto_param
tactics.
Just like split
, fsplit
applies the constructor when the type of the target is
an inductive data type with one constructor.
However it does not reorder goals or invoke auto_param
tactics.
Calls injection
on each hypothesis, and then, for each hypothesis on which injection
succeeds, clears the old hypothesis.
Calls injection
on each hypothesis, and then, for each hypothesis on which injection
succeeds, clears the old hypothesis.
Calls cases
on every local hypothesis, succeeding if
it succeeds on at least one hypothesis.
find_local t
returns a local constant with type t, or fails if none exists.
Instantiates metavariables that appear in the current goal.
Instantiates metavariables in all goals.
emit_command_here str
behaves as if the string str
were placed as a user command at the
current line.
Inner recursion for emit_code_here
.
emit_code_here str
behaves as if the string str
were placed at the current location in
source code.
run_parser p
is like run_cmd
but for the parser monad. It executes parser p
at the
top level, giving access to operations like emit_code_here
.
get_current_namespace
returns the current namespace (it could be name.anonymous
).
This function deserves a C++ implementation in core lean, and will fail if it is not called from
the body of a command (i.e. anywhere else that the lean.parser
monad can be invoked).
get_variables
returns a list of existing variable names, along with their types and binder
info.
get_included_variables
returns those variables v
returned by get_variables
which have been
"included" by an include v
statement and are not (yet) omit
ed.
From the lean.parser
monad, synthesize a tactic_state
which includes all of the local
variables referenced in es : list pexpr
, and those variables which have been include
ed in the
local context---precisely those variables which would be ambiently accessible if we were in a
tactic-mode block where the goals had types es.mmap to_expr
, for example.
Returns a new ts : tactic_state
with these local variables added, and
mappings : list (expr × expr)
, for which pairs (var, hyp)
correspond to an existing variable
var
and the local hypothesis hyp
which was added to the tactic state ts
as a result.
Hole command used to fill in a structure's field when specifying an instance.
In the following:
invoking the hole command "Instance Stub" ("Generate a skeleton for the structure under construction.") produces:
Like resolve_name
except when the list of goals is
empty. In that situation resolve_name
fails whereas
resolve_name'
simply proceeds on a dummy goal
Strips unnecessary prefixes from a name, e.g. if a namespace is open.
Hole command used to generate a match
expression.
In the following:
invoking hole command "Match Stub" ("Generate a list of equations for a match
expression")
produces:
meta def foo (e : expr) : tactic unit :=
match e with
| (expr.var a) := _
| (expr.sort a) := _
| (expr.const a a_1) := _
| (expr.mvar a a_1 a_2) := _
| (expr.local_const a a_1 a_2 a_3) := _
| (expr.app a a_1) := _
| (expr.lam a a_1 a_2 a_3) := _
| (expr.pi a a_1 a_2 a_3) := _
| (expr.elet a a_1 a_2 a_3) := _
| (expr.macro a a_1) := _
end
Invoking hole command "Equations Stub" ("Generate a list of equations for a recursive definition") in the following:
produces:
meta def foo : expr → tactic unit
| (expr.var a) := _
| (expr.sort a) := _
| (expr.const a a_1) := _
| (expr.mvar a a_1 a_2) := _
| (expr.local_const a a_1 a_2 a_3) := _
| (expr.app a a_1) := _
| (expr.lam a a_1 a_2 a_3) := _
| (expr.pi a a_1 a_2 a_3) := _
| (expr.elet a a_1 a_2 a_3) := _
| (expr.macro a a_1) := _
A similar result can be obtained by invoking "Equations Stub" on the following:
meta def foo : expr → tactic unit := -- don't forget to erase `:=`!!
| (expr.var a) := _
| (expr.sort a) := _
| (expr.const a a_1) := _
| (expr.mvar a a_1 a_2) := _
| (expr.local_const a a_1 a_2 a_3) := _
| (expr.app a a_1) := _
| (expr.lam a a_1 a_2 a_3) := _
| (expr.pi a a_1 a_2 a_3) := _
| (expr.elet a a_1 a_2 a_3) := _
| (expr.macro a a_1) := _
This command lists the constructors that can be used to satisfy the expected type.
Invoking "List Constructors" ("Show the list of constructors of the expected type") in the following hole:
def foo : ℤ ⊕ ℕ :=
{! !}
produces:
and will display:
Makes the declaration classical.prop_decidable
available to type class inference.
This asserts that all propositions are decidable, but does not have computational content.
Given two expressions e₀
and e₁
, return the expression `(%%e₀ ↔ %%e₁)
.
From a lemma of the shape ∀ x, f (g x) = h x
derive an auxiliary lemma of the form f ∘ g = h
for reasoning about higher-order functions.
A user attribute that applies to lemmas of the shape ∀ x, f (g x) = h x
.
It derives an auxiliary lemma of the form f ∘ g = h
for reasoning about higher-order functions.
Copies a definition into the tactic.interactive
namespace to make it usable
in proof scripts. It allows one to write
@[interactive]
meta def my_tactic := ...
instead of
meta def my_tactic := ...
run_cmd add_interactive [``my_tactic]
```
Similar to existsi
, use l
will use entries in l
to instantiate existential obligations
at the beginning of a target. Unlike existsi
, the pexprs in l
are elaborated with respect to
the expected type.
example : ∃ x : ℤ, x = x :=
by tactic.use ``(42)
See the doc string for tactic.interactive.use
for more information.
clear_aux_decl
clears all expressions from the local context that represent aux decls.
apply_at e h
applies implication e
on hypothesis h
and replaces h
with the result.
symmetry_hyp h
applies symmetry
on hypothesis h
.
setup_tactic_parser
is a user command that opens the namespaces used in writing
interactive tactics, and declares the local postfix notation ?
for optional
and *
for many
.
It does not use the namespace
command, so it will typically be used after
namespace tactic.interactive
.
finally tac finalizer
runs tac
first, then runs finalizer
even if
tac
fails. finally tac finalizer
fails if either tac
or finalizer
fails.
on_exception handler tac
runs tac
first, and then runs handler
only if tac
failed.
decorate_error add_msg tac
prepends add_msg
to an exception produced by tac
trace_error msg t
executes the tactic t
. If t
fails, traces msg
and the failure message
of t
.
trace_if_enabled `n msg
traces the message msg
only if tracing is enabled for the name n
.
Create new names registered for tracing with declare_trace n
.
Then use set_option trace.n true/false
to enable or disable tracing for n
.
Construct a Try this: refine ...
or Try this: exact ...
string which would construct g
.
Representation of a proof goal that lends itself to comparison. The following goal:
l₀ : T,
l₁ : T
⊢ ∀ v : T, foo
is represented as
(2, ∀ l₀ l₁ v : T, foo)
The number 2 indicates that first the two bound variables of the
∀
are actually local constant. Comparing two such goals with =
rather than =ₐ
or is_def_eq
tells us that proof script should
not see the difference between the two.
proof state made of multiple goal
meant for comparing
the result of running different tactics
create a packaged_goal
corresponding to the current goal
goal_of_mvar g
, with g
a meta variable, creates a
packaged_goal
corresponding to g
interpretted as a proof goal
get_proof_state
lists the user visible goal for each goal
of the current state and for each goal, abstracts all of the
meta variables of the other gaols.
This produces a list of goals in the form of ℕ × expr
where
the expr
encodes the following proof state:
2 goals
l₁ : t₁,
l₂ : t₂,
l₃ : t₃
⊢ tgt₁
⊢ tgt₂
as
[ (3, ∀ (mv : tgt₁) (mv : tgt₂) (l₁ : t₁) (l₂ : t₂) (l₃ : t₃), tgt₁),
(0, ∀ (mv : tgt₁) (mv : tgt₂), tgt₂) ]
with 2 goals, the first 2 bound variables encode the meta variable of all the goals, the next 3 (in the first goal) and 0 (in the second goal) are the local constants.
This representation allows us to compare goals and proof states while ignoring information like the unique name of local constants and the equality or difference of meta variables that encode the same goal.
Run tac
in a disposable proof state and return the state.
See proof_state
, goal
and get_proof_state
.
mk
lifts fmt : format
to the tactic monad (pformat
).
an alias for pp
.
See format!
in init/meta/interactive_base.lean
.
The main differences are that pp
is called instead of to_fmt
and that we can use
arguments of type tactic α
in the quotations.
Now, consider the following:
e ← to_expr ``(3 + 7),
trace format!"{e}" -- outputs `has_add.add.{0} nat nat.has_add
-- (bit1.{0} nat nat.has_one nat.has_add (has_one.one.{0} nat nat.has_one)) ...`
trace pformat!"{e}" -- outputs `3 + 7`
The difference is significant. And now, the following is expressible:
e ← to_expr ``(3 + 7),
trace pformat!"{e} : {infer_type e}" -- outputs `3 + 7 : ℕ`
See also: trace!
and fail!
The combination of pformat
and fail
.
The combination of pformat
and trace
.
A hackish way to get the src
directory of any project.
Requires as argument any declaration name n
in that project, and k
, the number of characters
in the path of the file where n
is declared not part of the src
directory.
Example: For mathlib_dir_locator
this is the length of tactic/project_dir.lean
, so 23
.
Note: does not work in the file where n
is declared.
A hackish way to get the src
directory of mathlib.
Checks whether a declaration with the given name is declared in mathlib.
If you want to run this tactic many times, you should use environment.is_prefix_of_file
instead,
since it is expensive to execute get_mathlib_dir
many times.
Assumes pi_expr
is of the form Π x1 ... xn, _
.
Creates a pexpr of the form Π x1 ... xn, func (arg x1 ... xn)
.
All arguments (implicit and explicit) to arg
should be supplied.
If func
is a pexpr
representing a function that takes an argument a
,
get_pexpr_arg_arity_with_tgt func tgt
returns the arity of a
.
When tgt
is a pi
expr, func
is elaborated in a context
with the domain of tgt
.
Examples:
import_private foo from bar
finds a private declaration foo
in the same file as bar
and creates a local notation to refer to it.
import_private foo
looks for foo
in all imported files.
When possible, make foo
non-private rather than using this feature.
The command mk_simp_attribute simp_name "description"
creates a simp set with name simp_name
.
Lemmas tagged with @[simp_name]
will be included when simp with simp_name
is called.
mk_simp_attribute simp_name none
will use a default description.
Appending the command with with attr1 attr2 ...
will include all declarations tagged with
attr1
, attr2
, ... in the new simp set.
This command is preferred to using run_cmd mk_simp_attr `simp_name
since it adds a doc string
to the attribute that is defined. If you need to create a simp set in a file where this command is
not available, you should use
run_cmd mk_simp_attr `simp_name
run_cmd add_doc_string `simp_attr.simp_name "Description of the simp set here"
Given a user attribute name attr_name
, get_user_attribute_name attr_name
returns
the name of the declaration that defines this attribute.
Fails if there is no user attribute with this name.
Example: get_user_attribute_name `norm_cast
returns `norm_cast.norm_cast_attr
A tactic to set either a basic attribute or a user attribute.
If the user attribute has a parameter, the default value will be used.
This tactic raises an error if there is no inhabited
instance for the parameter type.
find_defeq red m e
looks for a key in m
that is defeq to e
(up to transparency red
),
and returns the value associated with this key if it exists.
Otherwise, it fails.