нУЁh*  │k  q<°                   	  
                                               !  "  #  $  %  &  '  (  )  *  +  ,  -  .  	/  
0  1  2  3  4  5  6  7  8  9  :  ;  <  =  >  ?  @  A  B  C  D  E  F  G  H  I  J  K  L  M  N  O  P  Q  R  S  T  U  V  W  X  Y  Z  [  \  ]  ^  _  `  a  b  c  d  e  f  g  h  i  j  k  l  m  n  o  p  q  r  s  t  u  v  w  x  y  z  {  |  }  ~    ─  │  ┌  ┐  └  ┘  ├  ┤  ┬  ┴  ┼  ▀  ▄  █  ▌  ▐  ░  ▒  ▓  ⌠  ■  ∙  √  ≈  ≤  ≥     ⌡  °  ²  ·  ÷  ═  ║  ╒  ё  є  ╔  і  ї  ╗  ╘  ╙  ╚  ╛  ґ  ў  ╞  ╟  ╠  ╡  Ё  Є  ╣  І  Ї  ╦  ╧  ╨  ╩  ╪  Ґ  Ў  ©  ю  а  б  ц  д  е  ф  г  х  и  й  к  л  м  н  о  п  я  р  с  т  у  ж  в  ь  ы  з  ш  э  щ  ч  ъ  Ю  А  Б  Ц  Д  Е  Ф  Г  Х  И  Й  К  Л  М  Н  О  П  Я  Р  С  Т  У  Ж  В  Ь  Ы  З  Ш  Э  Щ  Ч  Ъ  ─  │  ┌  ┐  └  ┘  ├  ┤  ┬  ┴  ┼  ▀  ▄  █  ▌  ▐  ░  ▒  ▓  ⌠  ■  ∙  √  ≈  ≤  ≥     ⌡  °  ²  ·  ÷  ═  ║  ╒  ё  є  ╔  і  ї  ╗  ╘  ╙  ╚  ╛  ґ  ў  ╞  ╟  ╠  ╡  Ё  Є  ╣  І  Ї  ╦  ╧  ╨  ╩  ╪  Ґ  Ў  ©  ю  а  б  ц  д  е  ф  г  х  и  й  к  л  м  н  о  п  я  р  с  т  у  ж  в  ь  ы  з  ш  э  щ  ч  ъ  Ю  А  Б  Ц  Д  Е  Ф  Г  Х  И  Й  К  Л  М  Н  О  П  Я  Р  С  Т  У  Ж  В  Ь  Ы  З  Ш  Э  Щ  Ч  Ъ  ─  │  ┌  ┐  └  ┘  ├  ┤  ┬  ┴  ┼  ▀  ▄  █  ▌  ▐  ░  ▒  ▓  ⌠  ■  ∙  √  ≈  ≤  ≥     ⌡  °  ²  ·  ÷  ═  ║  ╒  ё  є  ╔  і  ї  ╗  ╘  ╙  ╚  ╛  ґ  ў  ╞  ╟  ╠  ╡  Ё  Є  ╣  І  Ї  ╦  ╧  ╨  ╩  ╪  Ґ  Ў  ©  ю  а  б  ц  д  е  ф  г  х  и  й  к  л  м  н  о  п  я  р  с  т  у  ж  в  ь  ы  з  ш  э  щ  ч  ъ  Ю  А  Б  Ц  Д  Е  Ф  Г  Х  И  Й  К  Л  М  Н  О  П  Я  Р  С  Т  У  Ж  В  Ь  Ы  З  Ш  Э  Щ  Ч  Ъ  ─  │  ┌  ┐  └  ┘  ├  ┤  ┬  ┴  ┼  ▀  ▄  █  ▌  ▐  ░  ▒  ▓  ⌠  ■  ∙  √  ≈  ≤  ≥     ⌡  °  ²  ·  ÷  ═  ║  ╒  ё  є  ╔  і  ї  ╗  ╘  ╙  ╚  ╛  ґ  ў  ╞  ╟  ╠  ╡  Ё  Є  ╣  І  Ї  ╦  ╧  ╨  ╩  ╪  Ґ  Ў  ©  ю  а  б  ц  д  е  ф  г  х  и  й  к  л  м  н  о  п  я  р  с  т  у  ж  в  ь  ы  з  ш  э  щ  ч  ъ  Ю  А  Б  Ц  Д  Е  Ф  Г  Х  И  Й  К  Л  М  Н  О  П  Я  Р  С  Т  У  Ж  В  Ь  Ы  З  Ш  Э  Щ  Ч  Ъ  ─  │  ┌  ┐  └  ┘  ├  ┤  ┬  ┴  ┼  ▀  ▄  █  ▌  ▐  ░  ▒  ▓  ⌠  ■  ∙  √  ≈  ≤  ≥     ⌡  2.6.0         Safe-Inferred")1ш   ▌ hasmtlibLift a  °. hasmtlibThe true constant.
   =    ² hasmtlibThe false constant.
   =    · hasmtlibLogical conjunction. hasmtlib#Logical disjunction (inclusive or). hasmtlibLogical implication. hasmtlib(Logical implication with arrow reversed.$forall x y. (x ==> y) === (y <== x)
 hasmtlibLogical equivalence.	 hasmtlibLogical negation.
 hasmtlibExclusive-or. hasmtlib*The logical conjunction of several values. hasmtlib*The logical disjunction of several values. hasmtlib2The negated logical conjunction of several values.  =  	 .   hasmtlib2The negated logical disjunction of several values.  =  	 .   hasmtlibи The logical conjunction of the mapping of a function over several values. hasmtlibи The logical disjunction of the mapping of a function over several values. hasmtlibDefined bitwise  
	 
	 320 0  4
4         Safe-Inferred")1ш   ² hasmtlibд AllC ensures that a list of constraints is applied to a poly-kinded  ÷ k:AllC '[]       k = ()
AllC (c ': cs) k = (c k, AllC cs k)
            Safe-Inferred")1ш   ┘ hasmtlibф Render values to their sequential SMTLib2-Lisp form, represented as a  ═  ║. hasmtlib9Render values to their SMTLib2-Lisp form, represented as  ║.            Safe-Inferred")1х ш   д  %&'(%&'(           Safe-Inferred")1ш   И) hasmtlibA  ╒" for Bitwuzla.
   Requires binary bitwuzla to be in path.Р As of v0.5 Bitwuzla uses Cadical as SAT-Solver by default.
   Make sure it's default SAT-Solver binary - probably cadical - is in path too. ))           Safe-Inferred")1ш   i* hasmtlibA  ╒ for CVC5.
   Requires binary cvc5 to be in path. **           Safe-Inferred")1ш   N+ hasmtlibA  ╒! for MathSAT.
   Requires binary mathsat to be in path., hasmtlibA  ╒% for OptiMathSAT.
   Requires binary optimathsat to be in path. +,+,           Safe-Inferred")1ш   ж- hasmtlibA  ╒! for OpenSMT.
   Requires binary opensmt to be in path. --    	       Safe-Inferred")1ш   ]. hasmtlibA  ╒ for Yices.
   Requires binary 
yices-smt2 to be in path. ..    
       Safe-Inferred")1ш   ы/ hasmtlibA  ╒ for Z3.
   Requires binary z3 to be in path. //           Safe-Inferred	")1ш   W0 hasmtlibп A map-like array with a default constant value and partially overwritten values.4 hasmtlibкClass that allows access to a map-like array where any value is either the default value or an overwritten values.
   Every index has a value by default.
   Values at indices can be overwritten manually.'Based on McCarthy`s basic array theory.)Therefore the following axioms must hold:	*forall A i x: arrSelect (store A i x) == xк forall A i j x: i /= j ==> (arrSelect (arrStore A i x) j === arrSelect A j)9 hasmtlibWrapper for  5 which hides the  ё 0321487659@A4876590321A@           Safe-Inferred	"()1ю н ш   лC hasmtlibLength-indexed bitvector ( є ) carrying a phantom type-level  K╞.
   Most significant bit is first (index 0) for unsigned bitvectors.
   Signed bitvectors have their sign bit first (index 0) and their most significant bit second (index 1).F hasmtlibCompute singleton  H from it's promoted type  K.H hasmtlibSingleton for  K.K hasmtlib?Type of Bitvector encoding - used as promoted type (data-kind).N hasmtlibWrapper for  G which takes a  ё.O hasmtlibWrapper for  G which takes a  ёд  and some ballast.
   This is helpful for singing on values of type  C where the ballst is a  ╔.P hasmtlibConvert  C with any encoding  K to  L.Q hasmtlibConvert  C with any encoding  K to  M. KLMHIJFGNOCDEPQRSTKLMHIJFGNOCDEPQRST           Safe-Inferred")1ш   2j hasmtlibOptions for SMT-Solvers.k hasmtlib$Print "success" after each operationl hasmtlib>Produce a satisfying assignment after each successful checkSatm hasmtlibIncremental solvingn hasmtlib=Custom options. First String is the option, second its value. jnmlkjnmlk           Safe-Inferred	 ")1ш У   !Ot hasmtlib-An existential wrapper that hides some known  │.u hasmtlib'An existential wrapper that hides some  │ and a list of  іs holding for it.w hasmtlibCompute singleton  y from it's promoted type  │.y hasmtlibSingleton for  │.─ hasmtlib0Injective type-family that computes the Haskell  ÷ of an  │.│ hasmtlib5Sorts in SMTLib2 - used as promoted type (data-kind).┌ hasmtlibSort of Bool┐ hasmtlibSort of Int└ hasmtlibSort of Real┘ hasmtlib5Sort of BitVec with type of encoding enc and length n├ hasmtlib)Sort of Array with indices k and values v┤ hasmtlibSort of String┬ hasmtlibWrapper for  x which takes a  ё. tuvwxy~}|{z─│┤├┘└┐┌┬│┤├┘└┐┌─y~}|{zwx┬uvt           Safe-Inferred")1ш   "╘√ hasmtlibA wrapper for values of  │6s.
   This wraps a Haskell-value into the SMT-Context.² hasmtlib-Unwraps a Haskell-value from the SMT-Context- √.· hasmtlib+Wraps a Haskell-value into the SMT-Context- √. 	√≈≤≥ ⌡°·²	√≈≤≥ ⌡°·²           Safe-Inferred"()1=ю н ш   ::*і hasmtlib<An internal SMT variable with a phantom-type which holds an  ї as it's identifier.ґ hasmtlib!Compare two as as SMT-Expression.9You can derive an instance of this class if your type is  ╗.г x <- var @RealSort
y <- var
assert $ x >? y
assert $ x === min' 42 100
╡ hasmtlib*Test two as on equality as SMT-Expression.9You can derive an instance of this class if your type is  ╗.й     x <- var @RealType
    y <- var
    assert $ y === x && not (y /== x)
Ё hasmtlib5Test whether two values are equal in the SMT-Problem.Є hasmtlib9Test whether two values are not equal in the SMT-Problem.╣ hasmtlib1If condition (p :: b) then (t :: a) else (f :: a)ite true "1" "2"    "1"ite false 100 42    42Ї hasmtlibп An SMT-Expression.
   For building expressions use the corresponding instances:   ,  ╘,  ╡, ...╠With a lot of criminal energy you may build invalid expressions regarding the SMTLib Version 2.6 - Specification.
   Therefore it is highly recommended to rely on the instances.О hasmtlibд Just v if quantified var has been created already, Nothing otherwiseП hasmtlibд Just v if quantified var has been created already, Nothing otherwiseР hasmtlibв Indicates whether an expression is a leaf.
   All non-recursive contructors form leafs.С hasmtlib!Minimum of two as SMT-Expression.Т hasmtlib!Maximum of two as SMT-Expression.У hasmtlib4Test multiple expressions on equality within in the SMT	-Problem.Ж hasmtlib8Test multiple expressions on distinctness within in the SMT	-Problem.В hasmtlib,A universal quantification for any specific  │Г .
   If the type cannot be inferred, apply a type-annotation.
   Nested quantifiers are also supported.Usage:м   assert $
     for_all @IntSort $ x ->
        x + 0 === x && 0 + x === x
  The lambdas xх  is all-quantified here.
   It will only be scoped for the lambdas body.Ь hasmtlib/An existential quantification for any specific  │Ф 
   If the type cannot be inferred, apply a type-annotation.
   Nested quantifiers are also supported.Usage:ш   assert $
     for_all @(BvSort 8) $ x ->
         exists $ y ->
           x - y === 0
  The lambdas yр  is existentially quantified here.
   It will only be scoped for the lambdas body.Ы hasmtlibSelect a value from an array.З hasmtlibStore a value in an array.Ш hasmtlibц Logically shift left the first expression by the second expression.Э hasmtlibд Logically shift right the first expression by the second expression.Щ hasmtlibи Arithmetically shift right the first expression by the second expression.Ч hasmtlibConcats two bitvectors.Ъ hasmtlibConverts an expression of type  ┐	 to type  └.─ hasmtlibConverts an expression of type  └	 to type  ┐.│ hasmtlib%Checks whether an expression of type  └! may be safely converted to type  ┐.┌ hasmtlibLength of a string.┐ hasmtlib┼Singleton string containing a character at given position
   or empty string when position is out of range.
   The leftmost position is 0.└ hasmtlib(strSubstring s i n)8 evaluates to the longest (unscattered) substring
   of s of length at most n starting at position i).
   It evaluates to the empty string if n is negative or i is not in
   the interval [0,l-1] where l is the length of s.┘ hasmtlib+First string is a prefix of second one.
   (str.prefixof s t) is true iff s is a prefix of t.├ hasmtlib+First string is a suffix of second one.
   (str.suffixof s t) is true iff s is a suffix of t.┤ hasmtlib$First string contains second one
   (str.contains s t) iff s
 contains t.┬ hasmtlibУ Index of first occurrence of second string in first one starting at the position specified by the third argument.
   (str.indexof s t i), with 0 <= i <= |s|/ is the position of the first
   occurrence of t in s at or after position i, if any.
   Otherwise, it is -1. Note that the result is i
 whenever i is within
   the range [0, |s|] and t
 is empty.┴ hasmtlib(str.replace s t t')ю  is the string obtained by replacing the first
   occurrence of t in s, if any, by t'. Note that if t' is empty, the
   result is to prepend t' to s; also, if t does not occur in s then
   the result is s.┼ hasmtlib(str.replace_all s t t≥@) is s if tц  is the empty string. Otherwise, it
   is the string obtained from s! by replacing all occurrences of t in s
   by t≥@к , starting with the first occurrence and proceeding in left-to-right order.▓ hasmtlib#Caution for quantified expressions:  ╙ю  will only be applied if quantification has taken place already.⌠ hasmtlib#Caution for quantified expressions:  &ю  will only be applied if quantification has taken place already.° hasmtlibThis instance is partial for testBit and popCount-, it's only intended for use with constants ( ╧).² hasmtlibThis instance is partial for testBit and popCount-, it's only intended for use with constants ( ╧).║ hasmtlibThis instance is partial for  ╚6, this method is only intended for use with constants.╒ hasmtlibThis instance is partial for  ╛6, this method is only intended for use with constants.ё hasmtlibThis instance is partial for  ґ6, this method is only intended for use with constants.є hasmtlibМ Not part of the SMTLib standard Version 2.6.
   Some solvers support it. At least valid for CVC5 and MathSAT. Й ії╗Я√≈≤≥ ⌡°²·Їб©имйп╨╧ф╦╩╪ҐЎюацдегхклноярстужвьызшэщчъЮАБЦДЕФГХИЙКЛМНОПР╣І╡ЁЄґ╠╟╞ўСТУЖВЬЫЗШЭЩЧЪ─│┌┐└┘├┤┬┴┼Й ії╗Я√≈≤≥ ⌡°²·Їб©имйп╨╧ф╦╩╪ҐЎюацдегхклноярстужвьызшэщчъЮАБЦДЕФГХИЙКЛМНОПР╣І╡ЁЄґ╠╟╞ўСТУЖВЬЫЗШЭЩЧЪ─│┌┐└┘├┤┬┴┼ ў4╞4╟4╠4Ё4Є4         Safe-Inferred")1ю ш Д   >ы
≈ hasmtlib!A solution for a single variable.≥ hasmtlibA variable in the SMT-Problem  hasmtlib-An assignment for this variable in a solution⌡ hasmtlibNewtype for  ў  √( so we can use it as right-hand-side of  ╞.² hasmtlibA Solution is a dependent map  ╞ from  ys t to  ў t.· hasmtlibResults of check-sat commands.╒ hasmtlib9Function that turns a state into a result and a solution.╙ hasmtlib-An existential wrapper that hides some known  │	 with an  ╟  ─╚ hasmtlibAlias class for constraint  ╟ ( ─ t)ў hasmtlib	Create a  ² from some  ≈s. ≈ ≥≤⌡°²·║÷═╒╙╚╛ґў╒·║÷═²⌡°≈ ≥≤ґ╛╚╙ў           Safe-Inferred")1ш   Aw╟ hasmtlibWrapper for  ╠ which takes a  ё.╠ hasmtlibп Out of many bool-expressions build a formula which encodes how many of them are true.╡ hasmtlibю Out of many bool-expressions build a formula which encodes that at most k of them are true.Ё hasmtlibю Out of many bool-expressions build a formula which encodes that at least k of them are true.Є hasmtlibю Out of many bool-expressions build a formula which encodes that exactly k of them are true. ╟╠╡ЁЄ╟╠╡ЁЄ           Safe-Inferred
"()1=ш Д   C[╧ hasmtlib)Lift values to SMT-Values or decode them.9You can derive an instance of this class if your type is  ╗.╨ hasmtlibResult of decoding a.╩ hasmtlib$Decode a value using given solution.╪ hasmtlibEncode a value as constant.Ґ hasmtlibComputes a default  ╨  ÷ by distributing  ╨ to it's type arguments.ы hasmtlibDecode and evaluate expressions 	╣╦ЇІ╧╩╪╨Ґ	Ґ╧╩╪╨╣╦ЇІ           Safe-Inferred")1ш Д   P╙з hasmtlibA  ╠Ф  that holds an OMT-Problem.
   An OMT-Problem is a 'SMT-Problem' with additional optimization targets.ш hasmtlib8Minimizes a numerical expression within the OMT-Problem. For example, below minimization:.x <- var @IntSort
assert $ x >? -2
minimize x

will give x := -1 as solution.э hasmtlib8Maximizes a numerical expression within the OMT-Problem. For example, below maximization: x <- var @(BvSort 8)
maximize x

will give x := 11111111 as solution.щ hasmtlibв Asserts a soft boolean expression.
   May take a weight and an identifier for grouping.ь For example, below a soft constraint with weight 2.0 and identifier "myId" for grouping:9x <- var @BoolSort
assertSoft x (Just 2.0) (Just "myId")
+Omitting the weight will default it to 1.0.	x <- var BoolSort
y <- var 1BoolSort
assertSoft x
assertSoft y (Just "myId")
ч hasmtlibA  Д! that allows incremental solving.ъ hasmtlib6Push a new context (one) to the solvers context-stack.Ю hasmtlib%Pop the solvers context-stack by one.А hasmtlib%Run check-sat on the current problem.Б hasmtlibЛ Run get-model on the current problem.
   This can be used to decode temporary models within the SMT-Problem.иx <- var @RealSort
y <- var
assert $ x >? y && y <? (-1)
res <- checkSat
case res of
  Unsat -> print "Unsat. Cannot get model."
  r     -> do
    model <- getModel
    liftIO $ print $ decode model x
Ц hasmtlibц Evaluate any expressions value in the solvers model.
   Requires a  ║ or  ═ check-sat response beforehand.Н x <- var @RealSort
assert $ x >? 10
res <- checkSat
case res of
  Unsat -> print "Unsat. Cannot get value for xы ."
  r     -> do
    x' <- getValue x
    liftIO $ print $ show r ++ ": x = " ++ show x'
Д hasmtlibA  ╠ that holds an SMT-Problem.Е hasmtlibу Construct a variable.
   This is mainly intended for internal use.
   In the API use  Ф	 instead.2x :: SMTVar RealType <- smtvar' (Proxy @RealType)
Ф hasmtlib#Construct a variable as expression.-x :: Expr RealType <- var' (Proxy @RealType)
Г hasmtlibAssert a boolean expression.8x :: Expr IntType <- var @IntType
assert $ x + 5 === 42
Х hasmtlibSet an SMT-Solver-Option.setOption $ Incremental True
И hasmtlib(Set the logic for the SMT-Solver to use.setLogic "QF_LRA"
Й hasmtlibWrapper for  Ф which hides the  ё.К hasmtlibWrapper for  Е which hides the  ёа .
   This is mainly intended for internal use.
   In the API use  Й	 instead.Л hasmtlibCreate a constant.constant True    Constant (BoolValue True)"let x :: Integer = 10 ; constant x    Constant (IntValue 10)constant @IntType 5    Constant (IntValue 5)constant @(BvType 8) 5    Constant (BvValue 0000101)М hasmtlibб Maybe assert a boolean expression.
   Asserts given expression if  ╡ is a  Ё.
   Does nothing otherwise.Н hasmtlib°Assign quantified variables to all quantified subexpressions of an expression.
   This shall only be used internally.
   Usually before rendering an assert.О hasmtlib
First run  А
 and then  Б on the current problem.П hasmtlibLike  щ, but forces a weight and omits the group-id. зщэшчЦБАЮъДИХФЕГЙКЛМНОПДИХФЕГЙКЛМНчЦБАЮъОзщэшП           Trustworthy")1ш   UМ
Я hasmtlib5States that can share expressions by comparing their  Єs.Р hasmtlibа A constraint on the monad used when asserting the shared node in  Т.С hasmtlibA  ╣ on a mapping between a  Є
 and it's  Ї we may share.Т hasmtlibо Asserts that a node-expression is represented by it's auxiliary node-variable: nodeExpr :: Expr t === nodeVar.
   Also gives access to the  Є of the original expression.У hasmtlib?Sets the mode used for sharing common expressions. Defaults to  Ь.Ж hasmtlibMode used for sharing.В hasmtlib(Common expressions are not shared at allЬ hasmtlib%Expressions that resolve to the same  Є are sharedЫ hasmtlib▐Shares all possible sub-expressions in given expression.
   Replaces each node in the expression-tree with an auxiliary variable.
   All nodes x y where $makeStableName x == makeStableName yп  are replaced with the same auxiliary variable.
   Therefore this creates a DAG.З hasmtlibўReturns an auxiliary variable representing this expression node.
   If such a shared auxiliary variable exists already, returns that.
   Otherwise creates one and returns it. 
ЯРУСТЖВЬЫЗ
ЯРУСТЖВЬЫЗ           Safe-Inferred	")1ш   WгЩ hasmtlibThe state of the SMT-problem.Ъ hasmtlibLast Id assigned to a new var─ hasmtlibAll constructed variables│ hasmtlibAll asserted formulas┌ hasmtlibLogic for the SMT-Solver┐ hasmtlib*All manually configured SMT-Solver-Options└ hasmtlibHow to share common expressions┘ hasmtlibMapping between a  Є
 and it's  Ї we may share Щ┘└┐┌│─ЪЧ├┤┬┴┼▀▄█▌▐░Щ┘└┐┌│─ЪЧ▄▀┼┴┬┤├█▌▐░           Safe-Inferred
")1ш Д   ZЇ∙ hasmtlibб An assertion of a booolean expression in OMT that may be weighted.≈ hasmtlibThe underlying soft formula≤ hasmtlibWeight of the soft formula≥ hasmtlibGroup-Id of the soft formula⌡ hasmtlibThe state of the OMT-problem.² hasmtlibThe underlying  Щ-Problem· hasmtlibAll expressions to minimize÷ hasmtlibAll expressions to maximize═ hasmtlib*All soft assertions of boolean expressions║ hasmtlibф A newtype for numerical expressions that are target of a maximization.є hasmtlibф A newtype for numerical expressions that are target of a minimization. ∙≥≤≈√⌡═÷·²°║ё╒єі╔ї╗╘╙╚╛ґ∙≥≤≈√╘╗їєі╔║ё╒⌡═÷·²°ґ╛╚╙           Safe-Inferred")1в ы ш   [H  ІЇ╦╧╨╩╪ҐЎ©юабцдефгхийклмнопярстІЇ╦╧╨╩╪ҐЎ©юабцдефгхийклмнопярст           Safe-Inferred
")1ш Д   ^Му hasmtlibA pipe to the solver.
   If  І is  ЇЎ then all commands that do not expect an answer are sent to the queue.
   All commands that expect an answer have the queue to be sent to the solver before sending the command itself.
   If  І is not  Ї2, all commands are sent to the solver immediately.в hasmtlibLast Id assigned to a new varь hasmtlibLogic for the SMT-Solverы hasmtlibHow to share common expressionsз hasmtlibMapping between a  Є
 and it's  Ї we may shareш hasmtlibIndex of each  ═ ( Є' ()) is incremental stack height where  Є0 representing auxiliary var that has been sharedэ hasmtlibActive pipe to the backendщ hasmtlibFlag if pipe shall debug ущэшзыьвжчъЮАБЦДущэшзыьвжДЦБАЮъч           Safe-Inferred")1ш   hъ	И hasmtlibData that can have a  І which may be debugged.Й hasmtlibCreate a datum with a  І& and a 'Bool for whether to debug the  І.К hasmtlib К solver prob solves a SMT problem prob with the given
 solver". It returns a pair consisting of:	A  · that indicates if prob is satisfiable ( ║),
    unsatisfiable ( ÷9), or if the solver could not determine any
    results ( ═).A  ╨/ answer that was decoded using the solution to prob6. Note
    that this answer is only meaningful if the  · is  ║ or  ═" and
    the answer value is in a  Ё.&Here is a small example of how to use  К:е import Language.Hasmtlib

main :: IO ()
main = do
  res <- solveWith ;SMT (solver cvc5) $ do
    setLogic "QF_LIA"

    x <- var 8IntSort

    assert $ x >? 0

    return x

  print res
Л hasmtlibгPipes an SMT-problem interactively to the solver.
   Enables incremental solving by default.
   Here is a small example of how to use it for solving a problem utilizing the solvers incremental stack:┴import Language.Hasmtlib
import Control.Monad.IO.Class

main :: IO ()
main = do
  cvc5Living <- interactiveSolver cvc5
  interactiveWith Щ Pipe cvc5Living $ do
    setOption $ Incremental True
    setOption $ ProduceModels True
    setLogic "QF_LIA"

    x <- var ╛IntSort

    assert $ x >? 0

    (res, sol) <- solve
    liftIO $ print res
    liftIO $ print $ decode sol x

    push
    y <- var @IntSort

    assert $ y <? 0
    assert $ x === y

    res' <- checkSat
    liftIO $ print res'
    pop

    res'' <- checkSat
    liftIO $ print res''

  return ()
М hasmtlibLike  Л< but it prints all communication with the solver to console.Н hasmtlibъ Solves the current problem with respect to a minimal solution for a given numerical expression.б Does not rely on MaxSMT/OMT.
   Instead uses iterative refinement.0If you want access to intermediate results, use  О	 instead.О hasmtlibLike  Н) but with access to intermediate results.П hasmtlibъ Solves the current problem with respect to a maximal solution for a given numerical expression.б Does not rely on MaxSMT/OMT.
   Instead uses iterative refinement.0If you want access to intermediate results, use  Я	 instead.Я hasmtlibLike  П) but with access to intermediate results. 	ИЙКЛМНОПЯ	ИЙКЛМНОПЯ           Safe-Inferred")1ш   l▒	С hasmtlib,A type holding actions for debugging states.У hasmtlibDebug the entire stateЖ hasmtlib#Debug the linewise-rendered problemВ hasmtlib#Debug the solvers raw response for (check-sat)Ь hasmtlib#Debug the solvers raw response for (get-model)Ы hasmtlib
Creates a  ╒ from a  ╒.З hasmtlibCreates a debugging  ╒ from a  ╒.Ш hasmtlibъ Creates an interactive session with a solver by creating and returning an alive process-handle  ╦%.
   Queues commands by default, see  Ї.Э hasmtlibA  ╒а  which holds an external process with a SMT-Solver.
   This will:	Encode the  Щ	-problem,0Start a new external process for the SMT-Solver,#Send the problem to the SMT-Solver,#Wait for an answer and parse it and-close the process and clean up all resources. 
СЬВЖУТЫЗШЭ
ЫЗШСЬВЖУТЭ           Safe-Inferred")1=ш   n║│ hasmtlibс Construct a variable datum of a data-type by creating variables for all its fields.9You can derive an instance of this class if your type is  ╗! and has exactly one constructor.х    data V3 a = V3 a a a deriving Generic
   instance Variable a => V3 a
/varV3 :: V3 (Expr RealType) <- variable ; varV36    V3 (Expr RealType) (Expr RealType) (Expr RealType)┐ hasmtlibWrapper for  ┌ which takes a  ё Ъ─│┌┐│┌┐Ъ─           Safe-Inferred")1ш   nБ  йДГЕФХИчъЮАБЦзшэщЙЛКМНОПЩЧЪ─│┌┐└┘▀├┼┤▄┬┴█░▐▌⌡°²·÷═∙√≈≤≥є╔і║╒ё╙ґ╛╚ї╘╗ужвьызшэщДчъЦБЮАЇб©имйп╨╧ф╦╩╪ҐЎюацдегхклноярстужвьызшэщчъЮАБЦДЕФГХИЙКЛМНОП√≈≤≥ ⌡°ії╗╣І╡ЁЄґ╠╟╞ўЗЫУЯ²·РСТЖВЬШЭЩЧЪ─│┌┐└┘├┤┬┴┼ИЙКЛМНОПЯjklmn│┌┐└┘├┤─yz{|}~wxuvt┬·═÷║╒²⌡°≈≤≥ ╚╙ўґ╛4567801239@ACDEKLMFGHIJNOPQRST 	
╧╨╪╩Ґ╨╣ІЇ╦І╠╡Є╟Ё│┌Ъ─┐СТУЖВЬЫЗЭШ)*/.-+,ЖВЬУЖВЬУ  ╧         !   "   #   $   %   &   '   (   )   *   +   ,   -   .   /   0   1   2  3  4   5  6   7   8   9   :   ;   <   =   >   ?   @   A   B   C  D   E   F   G   H   I   J   K   L  	 M  
 N  O  O   P   Q  R   S   T   U   V   W   X   Y   Z   [   \   ]   ^   _   `  a  a   b  c   d  e  f  g  h  i  j   k   l   m   n   o   p   q   r   s   t   u   v   w   x   y   z   {   |   }   ~      ─   │   ┌   ┐   └   ┘   ├  ┤  ┬  ┴  ┼  ▀   ▄   █   ▌   ▐   ░  ▒  ▓  ▓  ⌠   ■  ∙  √  ≈  ≤  ≥     ⌡  °  ²  ·  ÷  ═  ║  ╒  ё   є   ╔   і   ї   ╗   ╘   ╙   ╚   ╛   ґ   ў   ╞   ╟   ╠  ╡  Ё  Є  ╣  І  Ї  ╦   ╧   ╨   ╩   ╪   Ґ   Ў   ©   ю   а  б  б   ц   д   е   ф   г  х   и   й   к   л  м   н   о  п   я  р  с  т  у  ж  в  ь  ы  з  ш  э  щ  ч  ъ  Ю  А  Б  Ц  Д  Е  Ф  Г  Х  И  Й  К  Л  М  Н  О  П  Я  Р  С  Т  У  Ж  В  Ь  Ы  З  Ш  Э  Щ  Ч  Ъ  ─  │  ┌  ┐  └  ┘  ├  ┤  ┬  ┴  ┼  ▀   ▄   █   ▌   ▐   ░   ▒   ▓   ⌠   ■   ∙   √   ≈   ≤   ≥       ⌡   °   ²   ·   ÷   ═   ║   ╒   ё   є   ╔   і   ї   ╗   ╘   ╙   ╚   ╛   ґ   ў   ╞   ╟   ╠   ╡   Ё   Є   ╣   І   Ї   ╦   ╧   ╨   ╩   ╪   Ґ   Ў   ©   ю   а   б   ц   д   е   ф   г   х   и   й   к   л   м   н   о   п   я   р   с   т   у   ж   в   ь   ы   з   ш   э   щ   ч   ъ   Ю   А   Б   Ц   Д   Е   Ф   Г   Х   И   Й   К   Л   М   Н   О   П   Я   Р   С   Т   У   Ж   В   Ь   Ы   З   Ш   Э   Щ   Ч   Ъ   ─   │   ┌   ┐   └   ┘   ├   ┤   ┬   ┴   ┼   ▀   ▄   █   ▌   ▐   ░   ▒   ▓   ⌠   ■   ∙   √   ≈   ≤   ≥       ⌡   °   ²   ·   ÷   ═   ║   ╒   ё   є   ╔   і   ї   ╗   ╘   ╙   ╚   ╛   ґ   ў   ╞   ╟   ╠  ╡  ╡   Ё   Є  ╣  ╣  І  Ї  ╦  ╧  ╨  ╩   ╪   Ґ   Ў   ©   ю   а   б  ц  д   е   ф   г   х   и   й   к   л   м  н  о   п   я  р  с   т   у  ж   в   ь   ы   з   ш   э   щ   ч   ъ   Ю   А   Б   Ц   Д   Е   Ф   Г   Х   И   Й   К   Л   М   Н   О   П   Я   Р  С   Т   У   Ж  В   Ь   Ы   З   Ш   Э  Щ   Ч   Ъ   ─   │   ┌   ┐   └   ┘   ├   ┤   ┬   ┴  ┼  ▀   ▄   █   ▌  ▐  ░  ▒   ▓   ⌠   ■   ∙  √  √   ≈   ≤   ≥       ⌡   °   ²   ·   ÷   ═   ║   ╒   ▄   ё   є   ╔   і   ї   ╗   ╘   ╙   ╚  ╛  ╛   ґ   ў   ╞   ╟  ╠  ╠   ╡   Ё   Є   ╣  І  І   Ї  ╦  ╦   ╧   ╨   ╩   ╪   Ґ   Ў   ©   ю   а   б   ц   д   е   ф   г   х   и   й   к   л   м   н   о   п   я   р   с   ┐   ┘   т   у   ж   в   ь   ы   з   ш   э   щ   ч   ъ   Ю   А   Б   Ц   Д   Е  Ф  Ф   Г   Х   И   Й   К   Л   М   Н   О   П   Я   Р   С   Т   У   Ж   В   Ь  Ы   З   Ш   Э   Щ   Ч   Ъ   ─   │   ┌  ┐  ┐   └   ┘   ├   ┤   ┬   ┴   ┼   ▀   ▄   █  ▌   ▐  ░   ▒   ▓   ⌠   ■   ∙   √   ≈   ≤   ≥       ⌡   °   ²   ·   ÷   ═   ║   ╒   ё   є   ╔   і   ї   ╗   ╘   ╙ ╚╛ґ ╚╛ў ╚╛╞ ╚╛╟ ╠╡Ё Є╣І Ї╦╧ ╨╩╪ ҐЎ© ╨юа ╚╛б ╚╛ц ╨де ╨фг хи й ╨к л ╨м н ╨к о ╠пя рст ╚уж вьы ╨зш ╨зэ ╨щч хъЮ АБ╩ АБЦ Ї╦ДЕhasmtlib-2.6.0-inplaceLanguage.Hasmtlib.Boolean%Language.Hasmtlib.Internal.Constraint!Language.Hasmtlib.Internal.Render$Language.Hasmtlib.Internal.Uniplate1!Language.Hasmtlib.Solver.BitwuzlaLanguage.Hasmtlib.Solver.CVC5 Language.Hasmtlib.Solver.MathSAT Language.Hasmtlib.Solver.OpenSMTLanguage.Hasmtlib.Solver.YicesLanguage.Hasmtlib.Solver.Z3Language.Hasmtlib.Type.ArrayMapLanguage.Hasmtlib.Type.BitvecLanguage.Hasmtlib.Type.OptionLanguage.Hasmtlib.Type.SMTSortLanguage.Hasmtlib.Type.ValueLanguage.Hasmtlib.Type.ExprLanguage.Hasmtlib.Type.SolutionLanguage.Hasmtlib.CountingLanguage.Hasmtlib.CodecLanguage.Hasmtlib.Type.MonadSMT"Language.Hasmtlib.Internal.SharingLanguage.Hasmtlib.Type.SMTLanguage.Hasmtlib.Type.OMT!Language.Hasmtlib.Internal.ParserLanguage.Hasmtlib.Type.PipeLanguage.Hasmtlib.Type.SolverLanguage.Hasmtlib.Solver.CommonLanguage.Hasmtlib.VariablehasmtlibLanguage.HasmtlibBooleanbooltruefalse&&||==><==<==>notxorandornandnorallany$fBooleanVector$fBooleanBit$fBooleanBoolAllC	RenderSeq	renderSeqRenderrenderrenderUnaryrenderBinaryrenderTernary
renderNary$fRenderText$fRenderBuilder$fRenderList$fRenderChar$fRenderDouble$fRenderInteger$fRenderNatural$fRenderBool	Uniplate1	uniplate1transformM1
lazyParaM1bitwuzlacvc5mathsatoptimathsatopensmtyicesz3
ConstArray	_arrConst_storedArrayMapasConst'	viewConst	arrSelectarrStoreasConst$fShowConstArray$fEqConstArray$fOrdConstArray$fFunctorConstArray$fFoldableConstArray$fTraversableConstArrayarrConststored$fArrayMapConstArraykvBitvecunBitvec
KnownBvEnc	bvEncSingSBvEnc	SUnsignedSSignedBvEncUnsignedSigned
bvEncSing'bvEncSing''
asUnsignedasSignedbitvecConcatbitvecFromListNbitvecFromListN'$fGCompareBvEncSBvEnc$fGEqBvEncSBvEnc$fKnownBvEncSigned$fKnownBvEncUnsigned$fIntegralBitvec$fRealBitvec$fEnumBitvec$fBoundedBitvec$fNumBitvec$fBitsBitvec$fRenderBitvec$fShowBitvec
$fEqBitvec$fOrdBitvec$fBooleanBitvec$fShowBvEnc	$fEqBvEnc
$fOrdBvEnc$fOrdSBvEnc
$fEqSBvEnc$fShowSBvEnc	SMTOptionPrintSuccessProduceModelsIncrementalCustom$fRenderSMTOption$fShowSMTOption$fEqSMTOption$fOrdSMTOption$fDataSMTOptionSomeKnownSMTSortSomeSMTSortKnownSMTSortsortSingSSMTSortSIntSort	SRealSort	SBoolSortSBvSort
SArraySortSStringSortHaskellTypeSMTSortBoolSortIntSortRealSortBvSort	ArraySort
StringSort	sortSing'$fRenderSSMTSort$fKnownSMTSortStringSort$fKnownSMTSortArraySort$fKnownSMTSortBvSort$fKnownSMTSortBoolSort$fKnownSMTSortRealSort$fKnownSMTSortIntSort$fGCompareSMTSortSSMTSort$fGEqSMTSortSSMTSort$fShowSomeSMTSort$fOrdSSMTSort$fEqSSMTSort$fShowSSMTSortValueIntValue	RealValue	BoolValueBvValue
ArrayValueStringValueunwrapValue	wrapValue$fBooleanValue$fFractionalValue
$fNumValue$fGCompareSMTSortValue$fGEqSMTSortValue
$fOrdValue	$fEqValueSMTVar_varId$fShowSMTVar$fGenericSMTVar
$fEqSMTVar$fOrdSMTVar	Orderable<=?>=?<?>?	Equatable===/==IteableiteExprVarConstantPlusMinusNegMulAbsModRemIDivDivLTHLTHEEQUDistinctGTHEGTHNotAndOrImplXorPiSqrtExpSinCosTanAsinAcosAtanToRealToIntIsIntIteBvNandBvNorBvShLBvLShRBvAShRBvConcatBvRotLBvRotR	ArrSelectArrStore	StrConcat	StrLengthStrAtStrSubstringStrPrefixOfStrSuffixOfStrContains
StrIndexOf
StrReplaceStrReplaceAllForAllExistsvarIdisLeafmin'max'equaldistinctfor_allexistsselectstorebvShLbvLShRbvAShRbvConcat
toRealSort	toIntSort	isIntSort	strLengthstrAtstrSubstringstrPrefixOfstrSuffixOfstrContains
strIndexOf
strReplacestrReplaceAll$fShowValue$fRenderSMTVar$fGCompareSMTSortExpr$fGEqSMTSortExpr	$fOrdExpr$fEqExpr$fGNFDataSMTSortExpr$fPlatedExpr$fUniplate1SMTSortExpr:
$fIxedExpr$fIxedExpr0
$fShowExpr$fRenderExpr$fRenderValue$fIsStringExpr$fMonoidExpr$fSemigroupExpr
$fBitsExpr$fBitsExpr0$fBoundedExpr$fBoundedExpr0$fBooleanExpr$fIntegralExpr
$fEnumExpr
$fRealExpr$fFloatingExpr$fFractionalExpr$fSuffixedExpr$fPrefixedExpr$fIteableExpr(,,,,,,,)$fIteableExpr(,,,,,,)$fIteableExpr(,,,,,)$fIteableExpr(,,,,)$fIteableExpr(,,,)$fIteableExpr(,,)$fIteableExpr(,)$fIteableExpr()$fIteableExprIdentity$fIteableExprDual$fIteableExprLast$fIteableExprFirst$fIteableExprProduct$fIteableExprSum$fIteableExprTree$fIteableExprSeq$fIteableExprMaybe$fIteableExprList$fIteableBoola$fIteableExprExpr$fGEquatablekM1$fGEquatablek:+:$fGEquatablek:*:$fGEquatablekV1$fGEquatablekU1$fAsEmptyExpr$fBooleanExpr0$fEquatableIdentity$fEquatableDual$fEquatableLast$fEquatableFirst$fEquatableProduct$fEquatableSum$fEquatableEither$fEquatableMaybe$fEquatableTree$fEquatableList$fEquatable(,,,,,,,)$fEquatable(,,,,,,)$fEquatable(,,,,,)$fEquatable(,,,,)$fEquatable(,,,)$fEquatable(,,)$fEquatable(,)$fEquatableBool$fEquatableOrdering$fEquatableDouble$fEquatableFloat$fEquatableChar$fEquatableInt64$fEquatableInt32$fEquatableInt16$fEquatableInt8$fEquatableWord64$fEquatableWord32$fEquatableWord16$fEquatableWord8$fEquatableWord$fEquatableNatural$fEquatableInteger$fEquatableInt$fEquatableVoid$fEquatable()$fGEquatablekK1$fEquatableExpr$fGOrderablekM1$fGOrderablek:+:$fGOrderablek:*:$fGOrderablekV1$fGOrderablekU1$fSnocExprExprExprExpr$fConsExprExprExprExpr	$fNumExpr$fOrderableIdentity$fOrderableDual$fOrderableLast$fOrderableFirst$fOrderableProduct$fOrderableSum$fOrderableEither$fOrderableMaybe$fOrderableTree$fOrderableList$fOrderable(,,,,,,,)$fOrderable(,,,,,,)$fOrderable(,,,,,)$fOrderable(,,,,)$fOrderable(,,,)$fOrderable(,,)$fOrderable(,)$fOrderableBool$fOrderableOrdering$fOrderableDouble$fOrderableFloat$fOrderableChar$fOrderableInt64$fOrderableInt32$fOrderableInt16$fOrderableInt8$fOrderableWord64$fOrderableWord32$fOrderableWord16$fOrderableWord8$fOrderableWord$fOrderableNatural$fOrderableInteger$fOrderableInt$fOrderableVoid$fOrderable()$fGOrderablekK1$fOrderableExpr	SMTVarSol_solVar_solValIntValueMapSolutionResultUnsatUnknownSatSolver$fShowSMTVarSol$fShowIntValueMap$fSemigroupIntValueMap$fMonoidIntValueMap$fShowResult
$fEqResult$fOrdResultSomeKnownOrdSMTSortOrdHaskellTypesolValsolVarfromSomeVarSols$fOrdHaskellTypetcount'countatMostatLeastexactlyGCodecGDecodedgdecodegencodeCodecDecodeddecodeencodeDefaultDecoded
$fGCodecM1$fGCodec:+:$fGCodec:*:
$fGCodecV1
$fGCodecU1
$fGCodecK1
$fCodecMap
$fCodecSeq$fCodecIntMap$fCodecIdentity$fCodecDual$fCodecLast$fCodecFirst$fCodecProduct
$fCodecSum$fCodecEither$fCodecTree$fCodecMaybe$fCodecList$fCodec(,,,,,,,)$fCodec(,,,,,,)$fCodec(,,,,,)$fCodec(,,,,)$fCodec(,,,)$fCodec(,,)
$fCodec(,)	$fCodec()$fCodecExprMonadOMTminimizemaximize
assertSoftMonadIncrSMTpushpopcheckSatgetModelgetValueMonadSMTsmtvar'var'assert	setOptionsetLogicvarsmtvarconstantassertMaybequantifysolveassertSoftWeightedSharingSharingMonad	stableMapassertSharedNodesetSharingModeSharingModeNoneStableNames
runSharingshare$fDefaultSharingMode$fShowSharingModeSMT
_lastVarId_vars	_formulas_mlogic_options_sharingMode
_stableMapformulas	lastVarIdmlogicoptionssharingModevarsrenderSetLogicrenderDeclareVarrenderAssert
renderVars$fRenderSeqSMT$fMonadSMTSMTm$fSharingSMT$fDefaultSMTSoftFormula_formula_mWeight	_mGroupId$fShowSoftFormulaOMT_smt_targetMinimize_targetMaximize_softFormulasMaximize
_targetMaxMinimize
_targetMinformulamGroupIdmWeightsmtsoftFormulastargetMaximizetargetMinimize$fRenderSeqOMT$fRenderMaximize$fRenderMinimize$fRenderSoftFormula$fMonadOMTOMTm$fMonadSMTOMTm$fSharingOMT$fDefaultOMTanswerParserresultParseranyModelParserdefaultModelParsersmt2ModelParserparseSomeSolparseSomeSortparseSomeBitVecSortparseSomeArraySort
parseExpr'	parseExprconstantExpranyBitvectorbinBitvectorhexBitvectorliteralBitvector
constArrayparseSmtStringunarybinaryternarynarysmtPianyValuenegativeValueparseRatioDoubleparseToRealDouble	parseBoolgetValueParserPipe_lastPipeVarId_mPipeLogic_pipeSharingMode_pipeStableMap_incrSharedAuxs_pipeSolver_isDebuggingincrSharedAuxsisDebugginglastPipeVarId
mPipeLogicpipeSharingMode
pipeSolverpipeStableMap$fMonadOMTPipem$fMonadIncrSMTPipem$fMonadSMTPipem$fSharingPipe
WithSolver
withSolver	solveWithinteractiveWithdebugInteractiveWithsolveMinimizedsolveMinimizedDebugsolveMaximizedsolveMaximizedDebug$fWithSolverPipeDebugger
debugStatedebugProblemdebugResultResponsedebugModelResponsesolverdebuginteractiveSolverprocessSolver$fDefaultDebugger$fDefaultDebugger0	GVariable	gvariableVariablevariable	variable'$fGVariablekM1$fGVariablek:*:$fGVariablekU1$fGVariablekK1$fVariableEither$fVariableMaybe$fVariableCompose$fVariableAlt$fVariableConst$fVariableIdentity$fVariableDual$fVariableLast$fVariableFirst$fVariableProduct$fVariableSum$fVariable(,,,,,,,)$fVariable(,,,,,,)$fVariable(,,,,,)$fVariable(,,,,)$fVariable(,,,)$fVariable(,,)$fVariable(,)$fVariable()$fVariableExprghc-prim	GHC.TypesBoolTrueFalseTypecontainers-0.6.7Data.Sequence.InternalSeqbytestring-0.11.5.3 Data.ByteString.Builder.InternalBuilderэ smtlib-backends-process-0.3-ced344d257887c763fdf1a6be0ba4c19d8ef3ee1de2affb9ac8b08f16f58b0f0SMTLIB.Backends.ProcessConfigbase
Data.ProxyProxyс vector-sized-1.6.1-c9fdb915100265aac20f1d1870580d53bbedb32b8e891a4d45609f8990d34e6fData.Vector.Unboxed.SizedVectorGHC.TypeNatsNat
ConstraintIntGHC.GenericsGenericGHC.NumNumк lens-5.3.2-cac4da5abd419cc536b4e6a9de4e8725350f2529490c0b98093bc2ddbae79e1dControl.Lens.PlatedplateGHC.Real	toIntegerGHC.EnumfromEnum
toRationalData.IntMap.InternalIntMapж dependent-map-0.4.0.0-e30eba93f1fe5e2e255996a0586d338cf42a9564b4352a57e1532b6a6f7c704bData.Dependent.Map.InternalDMapGHC.ClassesOrd	mtl-2.3.1Control.Monad.State.Class
MonadState	GHC.MaybeMaybeJustGHC.StableName
StableNameControl.Lens.TypeLens'т smtlib-backends-0.4-36b7c32d9b849b5840ac2a4dea6977cb1b78c701dc4e32239363fba866136ee9SMTLIB.BackendsQueuingHandle