reduce_mod_char
tactic #
Define the reduce_mod_char
tactic, which traverses expressions looking for numerals n
,
such that the type of n
is a ring of (positive) characteristic p
, and reduces these
numerals modulo p
, to lie between 0
and p
.
Implementation #
The main entry point is ReduceModChar.derive
, which uses simp
to traverse expressions and
calls matchAndNorm
on each subexpression.
The type of each subexpression is matched syntactically to determine if it is a ring with positive
characteristic in typeToCharP
. Using syntactic matching should be faster than trying to infer
a CharP
instance on each subexpression.
The actual reduction happens in normIntNumeral
. This is written to be compatible with norm_num
so it can serve as a drop-in replacement for some norm_num
-based routines (specifically, the
intended use is as an option for the ring
tactic).
In addition to the main functionality, we call normNeg
and normNegCoeffMul
to replace negation
with multiplication by p - 1
, and simp lemmas tagged @[reduce_mod_char]
to clean up the
resulting expression: e.g. 1 * X + 0
becomes X
.
Given an integral expression e : t
such that t
is a ring of characteristic n
,
reduce e
modulo n
.
Equations
- One or more equations did not get rendered due to their size.
Instances For
Given an expression (-e) : t
such that t
is a ring of characteristic n
,
simplify this to (n - 1) * e
.
This should be called only when normIntNumeral
fails, because normIntNumeral
would otherwise
be more useful by evaluating -e
mod n
to an actual numeral.
Equations
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Instances For
Given an expression -(a * b) : t
such that t
is a ring of characteristic n
,
and a
is a numeral, simplify this to ((n - 1) * a) * b
.
Equations
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Instances For
A TypeToCharPResult α
indicates if α
can be determined to be a ring of characteristic p
.
- intLike: {u : Lean.Level} → {α : Q(Type u)} → (n : Q(ℕ)) → (instRing : Q(Ring «$α»)) → Q(CharP «$α» «$n») → Tactic.ReduceModChar.TypeToCharPResult α
- failure: {u : Lean.Level} → {α : Q(Type u)} → Tactic.ReduceModChar.TypeToCharPResult α
Instances For
Equations
- Tactic.ReduceModChar.instInhabitedTypeToCharPResult = { default := Tactic.ReduceModChar.TypeToCharPResult.failure }
Determine the characteristic of a ring from the type.
This should be fast, so this pattern-matches on the type, rather than searching for a
CharP
instance.
Use typeToCharP (expensive := true)
to do more work in finding the characteristic,
in particular it will search for a CharP
instance in the context.
Given an expression e
, determine whether it is a numeric expression in characteristic n
,
and if so, reduce e
modulo n
.
This is not a norm_num
plugin because it does not match on the syntax of e
,
rather it matches on the type of e
.
Use matchAndNorm (expensive := true)
to do more work in finding the characteristic of
the type of e
.
Equations
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Instances For
Reduce all numeric subexpressions of e
modulo their characteristic.
Use derive (expensive := true)
to do more work in finding the characteristic of
the type of e
.
Equations
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Instances For
Reduce all numeric subexpressions of the goal modulo their characteristic.
Equations
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Instances For
Reduce all numeric subexpressions of the given hypothesis modulo their characteristic.
Equations
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Instances For
The tactic reduce_mod_char
looks for numeric expressions in characteristic p
and reduces these to lie between 0
and p
.
For example:
example : (5 : ZMod 4) = 1 := by reduce_mod_char
example : (X ^ 2 - 3 * X + 4 : (ZMod 4)[X]) = X ^ 2 + X := by reduce_mod_char
It also handles negation, turning it into multiplication by p - 1
,
and similarly subtraction.
This tactic uses the type of the subexpression to figure out if it is indeed of positive
characteristic, for improved performance compared to trying to synthesise a CharP
instance.
The variant reduce_mod_char!
also tries to use CharP R n
hypotheses in the context.
(Limitations of the typeclass system mean the tactic can't search for a CharP R n
instance if
n
is not yet known; use have : CharP R n := inferInstance; reduce_mod_char!
as a workaround.)
Equations
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Instances For
The tactic reduce_mod_char
looks for numeric expressions in characteristic p
and reduces these to lie between 0
and p
.
For example:
example : (5 : ZMod 4) = 1 := by reduce_mod_char
example : (X ^ 2 - 3 * X + 4 : (ZMod 4)[X]) = X ^ 2 + X := by reduce_mod_char
It also handles negation, turning it into multiplication by p - 1
,
and similarly subtraction.
This tactic uses the type of the subexpression to figure out if it is indeed of positive
characteristic, for improved performance compared to trying to synthesise a CharP
instance.
The variant reduce_mod_char!
also tries to use CharP R n
hypotheses in the context.
(Limitations of the typeclass system mean the tactic can't search for a CharP R n
instance if
n
is not yet known; use have : CharP R n := inferInstance; reduce_mod_char!
as a workaround.)
Equations
- One or more equations did not get rendered due to their size.