s;      !"#$%&'()*+,-./012345678 9:;<=>?@ABCDEFGHIJK L M N O P Q R S T U V W X Y Z [ \ ] ^ _ `abcdefghijklmno p q r s t u vwxyz{|}~       !"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz{|}~              !""""## Safe-Inferred   Safe-Inferred ETransform/format a text so that it is acceptable as a VHDL identifier  NoneTExternally defined primitive/A primitive that carries additional informationAdditional informationLA primitive that has a template that can be filled out by the backend renderName of the primitive  Either a  declaration or an  expression template. Primitive Definitions      None24EHJKM(A class that can generate unique numbersGet a new unique^Create a TH expression that returns the a formatted string containing the name of the module 4 is spliced into, and the line where it was spliced.$Cache the result of a monadic actionICache the result of a monadic action in a State 3 transformer layers downSpine-strict cache variant of  mkCachedT3IRun a State-action using the State that is stored in a higher-layer MonadFunctorial version of $%Functorial version of $&0Performs trace when first argument evaluates to Monadic version of '(Monadic version of ')6Composition of a unary function with a binary function)if-then-else as a function on an argument&Applicative version of 'GHC.Types.(:)'Safe indexing, returns a  if the index does not existBUnsafe indexing, return a custom error message when indexing fails 5Split the second list at the length of the first list"ceiling (log_2(c))%The key the action is associated with)The Lens to the HashMap that is the cacheThe action to cache%The key the action is associated with)The Lens to the HashMap that is the cacheThe action to cache+Lens to the State in the higher-layer monadThe State-action to perform !"#$%       !"%$# !" !"#$%None&hGenerate a set of primitives that are found in the primitive definition files in the given directories.'MParse a ByteString according to the given JSON template. Prints failures on stdout, and returns  if parsing fails.&/Directories to search for primitive definitions'Bytestring to parse&'&'&'None 2346M/ Type variable0 Term variable1Variables in CoreHW2Constructor for term variables4Constructor for type variables7Change the name of a variable/01234567 /01234567 14256530/7 /014256537None2346 TyCon reference Type Constructor9 The RHS of an Algebraic Datatype;The newtype DataCon<The argument type of the newtype DataCon in eta-reduced form, which is just the representation of the TyCon. The TyName's are the type-variables from the corresponding TyCon.>The DataCons of a TyCon?'To close the loop on the type hierarchy@Primitive TyConsA$Function TyCons (e.g. type families)B&List of: ([LHS match types], RHS type)CAlgorithmic DataConsDName of the TyConEKind of the TyConFNumber of type argumentsGDataCon definitionsH Create a Kind out of a TyConNameI&Does the TyCon look like a tuple TyConJ%Get the DataCons belonging to a TyCon% 9:;<=>?@ABCDEFG !"HIJ#$%&'()*+, 9:;<=>?@ABCDEFGHIJ CA@?DEFGDEFBDEFD 9=:>;<HIJ CA@?DEFGDEFBDEFD9=:>;< !"HIJ#$%&'()*+, None - Builtin Name. Builtin Name/ Builtin Name0 Builtin Name1 Builtin Kind2 Builtin Kind3 Builtin Kind4 Builtin Kind5 Builtin Type6 Builtin Type-./012347KLM89:56NOPKLMNOPKLMNOP-./012347KLM89:56NOP None2346Q Term LiteralU Determines the Type of a LiteralQRST;<U=>?@ABCQRSTUQTSRU QTSR;<U=>?@ABC None2346 8Data ConstructorVDataCon referenceW:Syntactical position of the DataCon in the type definitionYName of the DataConZ+Syntactical position in the type definition[Type of the 'DataCon\mUniversally quantified type-variables, these type variables are also part of the result type of the DataCon]Existentially quantified type-variables, these type variables are not part of the result of the DataCon, but only of the arguments.^Argument types_Given a DataCon and a list of types, the type variables of the DataCon type are substituted for the list of types. The argument types are returned.cThe list of types should be equal to the number of type variables, otherwise an error is reported.8VWXYZ[\]^DEFGH_IJKLMN 8VWXYZ[\]^_ 8XYZ[\]^VW_8XYZ[\]^VWDEFGH_IJKLMNNone2346(Term reference)DTerm representation in the CoreHW language: System F + LetRec + Case`+Patterns in the LHS of a case-decompositionaDefault patternbLiteral patterncVDatatype pattern, '[TyVar]' bind existentially-quantified type-variables of a DataCondBinding in a LetRec constructeECase-expression: subject, type of alternatives, list of alternativesfRecursive let-bindinggType-applicationh ApplicationiType-abstractionjTerm-abstractionk PrimitivelLiteralmDatatype constructornVariable reference'()`abcdefghijklmnOPQRSTUVWXYZ[\]^_`abcd()`abcdefghijklmn)nmlkjihgfe(d`cba() nmlkjihgfe`cbadOPQRSTUVWXYZ[\]^_`abcd NoneoSubstitutes types in a typepSubstitutes a type in a typeqSubstitutes kinds in a kindrSubstitutes a type in a termsSubstitutes types in a termtSubstitutes a term in a termuSubstitutes terms in a termopqrstuopqrstuopqrstuopqrstuNone 2346%*Reference to a Kind+Reference to a Type,The level above types-/Types in CoreHW: function and polymorphic types.Make a Type out of a TyConvEither a Kind or a Typew Literal TypeszType Constants{ Function type| TyCon type}An easier view on types~Neither of the above Applied TyCon Function type Type literalType ApplicationPolymorphic Type Type constant Type variableAn easier view on typesA transformation that renders Signal types transparentA view on types in which SignalU types and newtypes are transparent, and type functions are evaluated when possible.eZInstantiate and Apply the RHS/Original of a NewType with the given list of argument types3Make a function type of an argument and result typeDMake a TyCon Application out of a TyCon and a list of argument types6Split a TyCon Application in a TyCon and its argumentsfIs a type a Superkind?Determine the kind of a typeIs a type polymorphic?4Split a function type in an argument and result type^Split a poly-function type in a: list of type-binders and argument types, and the result type)Is a type a polymorphic or function type?/Is a type a polymorphic or function type under ?Is a type a function type?AApply a function type to an argument type and get the result type(Substitute the type variable of a type () with another typegCSplit a type application in the applied type and the argument typesB*+,-.vwxyz{|}~hijklmefngopqrstuvwxyz{|}~'*+,-./vwxyz{|}~'-}~z|{wyx,v*+/.6*+,-.vwyxz|{}~hijklmefngopqrstuvwxyz{|}~ None'Gives the free type-variables in a Type?Gives the free type-variables and free term-variables of a Term'Gives the free term-variables of a Term'Gives the free type-variables of a TermNoneGlobal function bindersNone 24#Pretty printing Show-like typeclass Print a Pretty thing to a String?7NoneKind environment/contextType environment/contextDetermine the type of a term>Split a (Type)Application in the applied term and it argumentsHSplit a (Type)Abstraction in the bound variables and the abstracted termGGet the result type of a polymorphic function given a list of arguments6Get the list of term-binders out of a DataType patternMake a type variableMake a term variable6Abstract a term over a list of term and type variables-Abstract a term over a list of term variables-Abstract a term over a list of type variables)Apply a list of types and terms to a termApply a list of terms to a termApply a list of types to a term!Does a term have a function type?0Does a term have a function or polymorphic type?Is a term a term-abstraction?"Is a term a recursive let-binding?Is a term a variable reference?!Is a term a datatype constructor?Is a term a primitive?,Make variable reference out of term variable0Make a term variable out of a variable referenceNone0B< Bit literalHigh-impedance UndefinedLowHighLiterals used in an expressionVector literalBoolean literal Bit literalNumber literal'Expression used in RHS of a declaration&Instantiation of a BlackBox expressionLeft e : tagToEnum, @Right e@: dataToTagSignal referenceDataCon applicationLiteral expressionExpression Modifier>See the expression in the context of a Vector append operationJSee expression in a DataCon context: (Type of the expression, DataCon tag)@Index the expression: (Type of expression,DataCon tag,Field Tag)Internals of a ComponentSignal declaration%Instantiation of blackbox declaration"Instantiation of another componentConditional signal assignment:Signal to assignScrutinized expressionVList of: (Maybe expression scrutinized expression is compared with,RHS of alternative)Signal assignment:Signal to assignAssigned expressionRepresentable hardware types9Reset type corresponding to clock with a specified period Clock type with specified period=Sum-of-Product type: Name and Constructor names + field types"Product type: Name and field types$Sum type: Name and Constructor names Vector type$Unsigned integer of a specified size"Signed integer of a specified size9Unsigned integer with specified (exclusive) upper bounderBitVector of a specified size Integer type Boolean type Empty type?Size indication of a type (e.g. bit-size or number of elements)!Component: base unit of a NetlistName of the componentBPorts that have no correspondence the original function definition Input ports Output portInternal declarationsSignal referenceState of the NetlistMonadGlobal bindersType environment/contextNumber of signal declarationsNumber of create componentsCached componentsPrimitive DefinitionsState for the * Monad#Hardcoded Type -> HWType translator TyCon cacheState for the * monad:Previously encountered HWTypesProduct type counter1Cache for previously generated product type names}Monad that caches generated components (StateT) and remembers hidden inputs of components that are being generated (WriterT)MIM  None24BState of a rewriting session!Number of applied transformations Global binders Supply of unique numbers "Hardcode Type -> HWType translator  TyCon cache %Hardcoded evaluator (delta-reduction)Context in which a term appearsSubject of a case-decompositionLRHS of a case-alternative with the variables bound by the pattern on the LHS9Body of a TyLambda-term with the abstracted type-variable2Body of a lambda-term with the abstracted variable)Body of a Let-binding with the bound LHS')RHS of a Let-binder with the sibling LHS''Function position of a type application#Argument position of an application#Function position of an application,Read-only environment of a rewriting sessionDebug Message Verbosity8Show all sub-expressions on which a rewrite is attempted/Show sub-expressions after a successful rewrite Names of applied transformations&Show completely normalized expressions Don't show debug messages'A ( action in the context of the ,(=Monadic action that transforms a term given a certain context)MTL convenience wrapper around ,,Monad that can do the same as -X and in addition keeps track if a transformation/rewrite has been successfully applied.-zMonad that keeps track how many transformations have been applied and can generate fresh variables and unique identifiers*      !"#$%&'()*+,-./)      !"#$%&'()*+,-.*     &%$#"! .-,/)*+('       !"#$%&'()*+,-./None 0 State of the ;2Global binders3*Cache of previously specialised functions:NKey: (name of the original function, argument position, specialised term/type)AElem: (name of specialised function,type of specialised function)42Cache of how many times a function was specialized5Number of time a function f can be specialized6,Cache of function where inlining took place:'Key: function where inlining took place=Elem: (functions which were inlined, number of times inlined)7Number of times a function f can be inlined in a function g8&Function which is currently normalized9A  Transform action in the context of the  RewriteMonad and ;:3RewriteSession with extra Normalisation information;?State monad that stores specialisation and inlining information0123456789:;<=>?@AB0123456789:;<=>?@AB012345678BA@?>=<;:9 0123456789:;<=>?@ABNoneBCqMonad that caches VHDL information and remembers hidden inputs of black boxes that are being generated (WriterT)FComponent instantiation hole. First argument indicates which function argument to instantiate. Second argument corresponds to output and input assignments, where the first element is the output assignment, and the subsequent elements are the consecutive input assignments.eThe LHS of the tuple is the name of the signal, while the RHS of the tuple is the type of the signalHElements of a blackbox contextI&Select element type from a vector typeJError value holeKType root holeLType declaration holeM Reset holeNVClock hole (Maybe clk corresponding to input, clk corresponding to output if Nothing)O Symbol holeP Literal holeQ Input holeR Output holeSComponent instantiation holeTConstantU)A BlackBox Template is a List of ElementsV\Either the name of the identifier, or a tuple of the identifier and the corresponding clockW8Context used to fill in the holes of a BlackBox templateYResult name and typeZArgument names and types[$Literal arguments (subset of inputs)\&Function arguments (subset of inputs):,(Blackbox Template,Partial Blackbox Concext)CDEFGHIJKLMNOPQRSTUVWXYZ[\CDEFGHIJKLMNOPQRSTUVWXYZ[\WXYZ[\VUHTSRQPONMLKJIFGCDECDEFGH TSRQPONMLKJIUVWXYZ[\None ]SParse a text as a BlackBoxTemplate, returns a list of errors in case parsing fails7Parse a BlackBoxTemplate (Declarations and Expressions)Parse a single Template Element!Parse the Text part of a Template)Parse a Declaration or Expression elementParse a Declaration#Parse the output tag of Declaration"Parse the input tag of DeclarationParse an Expression elementParse a bracketed text)Parse a token and eat trailing whitespace/Parse the expression part of Blackbox TemplatesParse an Expression or Text]]]]NoneM ^1Apply a transformation on the subtrees of an term_'Apply two transformations in succession`-Apply a transformation in a topdown traversalaOApply a transformation in a topdown traversal. Doesn't freshen bound variablesb.Apply a transformation in a bottomup traversalcPApply a transformation in a bottomup traversal. Doesn't freshen bound variablesd?Only apply the second transformation if the first one succeeds.e<Only apply the second transformation if the first one fails.f.Keep applying a transformation until it fails.h<Only traverse downwards when the assertion evaluates to true ^/Freshen variable references in abstracted terms+The transformation to apply to the subtrees_`abcdefgh ^_`abcdefgh ^_`abcdefgh ^_`abcdefgh_deNone lSplit a normalized term into: a list of arguments, a list of let-bindings, and a variable reference that is the body of the let-binding. Returns a String containing the error is the term was not in a normalized form.mConverts a Core type to a HWType given a function that translates certain builtin types. Errors if the Core type is not translatable.nKConverts a Core type to a HWType within the NetlistMonad; errors on failureo:Converts a Core type to a HWType within the NetlistMonad;  on failurep@Returns the name and period of the clock corresponding to a typeqConverts a Core type to a HWType given a function that translates certain builtin types. Returns a string containing the error message when the Core type is not translatable.rRConverts an algebraic Core type (split into a TyCon and its argument) to a HWType.s/Simple check if a TyCon is recursively defined.tnDetermines if a Core type is translatable to a HWType given a function that translates certain builtin types.u Determines the bitsize of a typev3Determines the bitsize of the constructor of a typew(Gives the length of length-indexed typesx}Gives the HWType corresponding to a term. Returns an error if the term has a Core type that is not translatable to a HWType.y_Turns a Core variable reference to a Netlist expression. Errors if the term is not a variable.zLUniquely rename all the variables and their references in a normalized term{Append a string to a name|Preserve the Netlist  and  when executing a monadic actionlmnop TyCon cacheqr#Hardcoded Type -> HWType translator TyCon cache9String representation of the Core type for error messages The TyConIts applied argumentsstuvwxyz{|}lmnopqrstuvwxyz{|}lmnopqrstuvwxyz{|}lmnopqrstuvwxyz{|}None CE~%Generate VHDL for a Netlist componentIGenerate a VHDL package containing type definitions for the given HWTypes'Convert a Netlist HWType to a VHDL type3Convert a Netlist HWType to the root of a VHDL type=Convert a Netlist HWType to an error VHDL value for that type5Turn a Netlist Declaration to a VHDL concurrent block0Turn a Netlist expression into a VHDL expression$~Enclose in parenthesis?Expr to convert~~$~None !Determine if the number of normalliteralqfunction inputs of a blackbox context at least matches the number of argument that is expected by the template.>Count the number of argument tags/holes in a blackbox template?Counter the number of literal tags/holes in a blackbox templateBCount the number of function instantiations in a blackbox templateuUpdate all the symbol references in a template, and increment the symbol counter for every newly encountered symbol.*Get the name of the clock of an identifierXRender a blackbox given a certain context. Returns a filled out template and a list of hidden9 inputs that must be added to the encompassing component. Render a single template elementFill out the template corresponding to an output/input assignment of a component instantiation, and turn it into a single identifier so it can be used for a new blackbox context.pGive a context and a tagged hole (of a template), returns part of the context that matches the tag of the hole. Template to check againstBlackbox to verifyBlackbox template Context used to fill in the hole   None  -./EHJKM1Lift an action working in the inner monad to the ,1Lift an action working in the inner monad to the -1Record if a transformation is succesfully applied"Perform a transformation on a Term,Evaluate a RewriteSession to its inner monad7Notify that a transformation has changed the expression^Identity function that additionally notifies that a transformation has changed the expression>Create a type and kind context out of a transformation contextaCreate a complete type and kind context out of the global binders and the transformation context3Make a new binder and variable reference for a termDMake a new binder and variable reference for either a term or a typeCMake a new, unique, identifier and corresponding variable reference@Inline the binders in a let-binding that have a certain propertySubstitute the RHS of the first set of Let-binders for references to the first set of Let-binders in: the second set of Let-binders and the additional termCalculate the localb free variable of an expression: the free variables that are not bound in the global environment.TLift the binders in a let-binding to a global function that have a certain propertyCreate a global function for a Let-binding and return a Let-binding where the RHS is a reference to the new global function applied to the free variables of the original RHS,Make a global function for a name-term tuple+Add a function to the set of global binders@Create a new name out of the given name, but with another unique=Test whether a term is a variable reference to a local binder5Determine if a term cannot be represented in hardware1Is the Context a Lambda/Term-abstraction context?+Make a binder that should not be referencedNMake a case-decomposition that extracts a field out of a (Sum-of-)Product type)Specialise an application on its argument)Specialise an application on its argument=Create binders and variable references for free variables in specArgName of the transformationTransformation to be appliedName of the transformationTransformation to performTerm to transform TyCon cacheName of the new binder Term to bind TyCon cacheName of the new binderType or Term to bindName of the identifier Property testLet-binders to substitute*Let-binders where substitution takes place)Expression where substitution takes place Property testName of the functionTerm bound to the function6Name with a proper unique and the type of the function#Name of the caller of this function TyCon cache7Transformation Context in which this function is calledSubject of the case-composition"Lens into previous specialisations$Lens into the specialisation history"Lens into the specialisation limit"Lens into previous specialisations Lens into specialisation history"Lens into the specialisation limit"Perform specialisation limit check Original term@Function part of the term, split into root and applied argumentsArgument to specialize onNone TADetermine if a function is already inlined in the context of the  NetlistMonad(Specialize under the Normalization MonadDetermine if a term is closed)Determine if a term represents a constant=Create a call graph for a set of global binders, given a rootIDetermine the sets of recursive components given the edges of a callgraph .List of functions that should not be inspectedGlobal bindersRoot of the call graph "(calling function,[called function)]Original BindersDependency GraphRecursive blockLambda-dropped BindersDependency GraphRecursive blockRecursive block dominatorOriginal BindersRecursive block dominatorRecursive block dominator rootBlock sank binder   None E2Generate the context for a BlackBox instantiation.>Instantiate a BlackBox template according to the given context:Create an template instantiation text for an argument termgCreate an template instantiation text for an argument term, given that the term is a literal. Returns  if the term is not a literal.Create an template instantiation text and a partial blackbox content for an argument term, given that the term is a function. Errors if the term is not a functionMInstantiate symbols references with a new symbol and increment symbol counter5Identifier binding the primitive/blackbox application/Arguments of the primitive/blackbox applicationTemplate to instantiate$Context to instantiate template withThe literal argument termBIdentifier binding the encompassing primitive/blackbox applicationThe function argument termNoneEiUGenerate an expression for a DataCon application occurring on the RHS of a let-binderjFGenerate an expression for a term occurring on the RHS of a let-binderk3Generate a component for a given function (caching)EGenerate a hierarchical netlist out of a set of global binders with  topEntity at the top.0Run a NetlistMonad action in a given environment)Generate a component for a given function0Generate a list of Declarations for a let-binderXGenerate a list of Declarations for a let-binder where the RHS is a function applicationi#HWType of the LHS of the let-binderApplied DataConDataCon Arguments@Returned expression and a list of generate BlackBox declarationsj!Type of the LHS of the let-binder Term to convert to an expression@Returned expression and a list of generate BlackBox declarationskName of the function$Starting value of the unique counterState for the * Monad(Starting number of the component counterGlobal bindersPrimitive definitions TyCon cache#Hardcoded Type -> HWType translator Symbol count Name of the  topEntityState for the * Monad(Starting number of the component counterGlobal bindersPrimitive Definitions TyCon cache"Hardcode Type -> HWType translator Action to runName of the functionCorresponding term$Starting value of the unique counterLHS of the let-binderRHS of the let-binderLHS of the let-binderName of the applied functionFunction argumentsijkkjiijkNone 4Inline non-recursive, non-representable let-bindings#Lift non-representable let-bindings"Specialize functions on their type8Specialize functions on their non-representable argument@Lift the let-bindings out of the subject of a Case-decompositionVMove a Case-decomposition from the subject of a Case-decomposition to the alternatives\Inline function with a non-representable result if it's the subject of a Case-decompositionSpecialize a Case-decomposition (replace by the RHS of an alternative) if the subject is (an application of) a DataCon; or if there is only a single alternative that doesn't reference variables bound by the pattern.lBring an application of a DataCon or Primitive in ANF, when the argument is is considered non-representablekEnsure that top-level lambda's eventually bind a let-expression of which the body is a variable-reference.Remove unused let-bindingsUInline let-bindings when the RHS is either a local variable reference or is constantInline nullary/closed functionsInline small functions4Specialise functions on arguments which are constant7Propagate arguments of application inwards; except for j' where the argument becomes let-bound.lTurn an expression into a modified ANF-form. As opposed to standard ANF, constants do not become let-bound.9Eta-expand top-level lambda's (DON'T use in a traversal!)Turn a normalized recursive function, where the recursive calls only pass along the unchanged original arguments, into let-recursive function. This means that all recursive calls are replaced by the same variable reference as found in the body of the top-level let-expression.+Inline a function with functional argumentsDSimplified CSE, only works on let-bindings, works from top to bottomNoneNormalisation transformation+Topdown traversal, stops upon first success None-Run a NormalizeSession in a given environment7Rewrite a term according to the provided transformation;Check if the call graph (second argument), starting at the topEnity (first argument) is non-recursive. Returns the list of normalized terms if call graph is indeed non-recursive, errors otherwise.`Perform general "clean up" of the normalized (non-recursive) function hierarchy. This includes:6Inlining functions that simply "wrap" another function Level of debug messages to print UniqueSupplyGlobal Binders#Hardcoded Type -> HWType translator TyCon cache%Hardcoded evaluator (delta-reduction)NormalizeSession to runTransformation to applyTerm to transform  topEntityList of normalized bindersVisitedGlobal bindersRoot of the call graph !NonehGenerate a VHDL testbench for a component given a set of stimuli and a set of matching expected outputs PrimitivesGlobal binders Stimuli Expected output Component to generate TB for"None2Create a set of .VHDL files for a set of functions)Pretty print Components to VHDL DocumentsPrepares the directory for writing VHDL files. This means creating the dir if it does not exist and removing all existing .vhdl files from it.)Writes a VHDL file to the given directorySet of functions Primitive / BlackBox Definitions TyCon cache Hardcoded - ->  translator%Hardcoded evaluator (delta-reduction)5Debug information level for the normalization process+,-./01123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]\^[_`a bcdefghijklmnopqrst u v w x y z { | } ~     {] 9 {b{       !"#$$% &'()*+,-./0123456789:; <=>??@ABCDEEFGHIJKLMNOPQRSTUVWXYZZ[\]^_`abcdefghijklmnopqrstuvwxyz{|}~              !""""######## # # # # #$% !$"$&#$%&'(')*+,-./0123456789:;<=>?@ABC 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 defghijkl;mnopqrstuvwxyz{|}~;*!!!!! clash-lib-0.4 CLaSH.UtilCLaSH.Netlist.IdCLaSH.Primitives.TypesCLaSH.Core.TyConCLaSH.Primitives.UtilCLaSH.Core.TermCLaSH.Core.TypeCLaSH.Core.VarCLaSH.Core.DataConCLaSH.Core.TysPrimCLaSH.Core.LiteralCLaSH.Core.SubstCLaSH.Core.FreeVarsCLaSH.Driver.TypesCLaSH.Core.PrettyCLaSH.Core.UtilCLaSH.Netlist.TypesCLaSH.Rewrite.TypesCLaSH.Normalize.TypesCLaSH.Netlist.BlackBox.TypesCLaSH.Netlist.BlackBox.ParserCLaSH.Rewrite.Combinators CLaSH.NetlistCLaSH.Netlist.UtilCLaSH.Netlist.VHDLCLaSH.Netlist.BlackBox.UtilCLaSH.Rewrite.UtilCLaSH.Normalize.UtilCLaSH.Netlist.BlackBoxCLaSH.Normalize.TransformationsCLaSH.Normalize.StrategyCLaSH.NormalizeCLaSH.Driver.TestbenchGen CLaSH.DriverPaths_clash_lib Control.Arrowfirstsecond Data.List partition mapAccumLVHDLMlens-4.6Control.Lens.TH makeLenses mkBasicId mkBasicId'stripDollarPrefixes PrimitiveprimTypeBlackBoxnametemplatePrimMap$fFromJSONPrimitive TyConNameTyCon MonadUnique getUniqueMcurLoc makeCached makeCachedT3 makeCachedT3S liftStatefirstMsecondMcombineMtraceIf partitionM mapAccumLMdot ifThenElse<:> indexMaybe indexNote splitAtListclashLibVersionclog2 $fOrdEmbed$fHashableName$fMonadUniqueStateTgeneratePrimMapdecodeAndReportTmNameTermKiNameTyNameKindType mkTyConTyTyVarIdVarvarTypevarNamevarKind modifyVarNameDataCon AlgTyConRhsNewTyCondataCon ntEtadRhs DataTyCondataConsSuperKindTyCon PrimTyConFunTyCon tyConSubstAlgTyCon tyConName tyConKind tyConArityalgTcRhs mkKindTyConisTupleTyConLike tyConDataConsliftedTypeKind typeNatKindtypeSymbolKind intPrimTy voidPrimTy tysPrimMapLiteralRationalLiteral StringLiteralIntegerLiteral literalTypeDcNameConTagMkDatadcNamedcTagdcType dcUnivTyVars dcExtTyVarsdcArgTysdataConInstArgTysPat DefaultPatLitPatDataPat LetBindingCaseLetrecTyAppAppTyLamLamPrimDatasubstTyssubstTy substKindWith substTyInTm substTysinTmsubstTmsubstTms KindOrTypeLitTySymTyNumTyConstTyArrowTypeView OtherTypeTyConAppFunTyAppTyForAllTyVarTytyView transparentTycoreViewmkFunTy mkTyConAppsplitTyConAppMtypeKindisPolyTy splitFunTy splitFunTyssplitFunForallTy isPolyFunTyisPolyFunCoreTyisFunTy applyFunTyapplyTy findFunSubst typeFreeVars termFreeVars termFreeIdstermFreeTyVars BindingMapPrettypprpprPrecshowDocDeltaGammatermType collectArgs collectBndrsapplyTypeToArgspatIdsmkTyVarmkId mkAbstractionmkTyLamsmkLamsmkAppsmkTmAppsmkTyAppsisFun isPolyFunisLamisLetisVarisConisPrimidToVarvarToIdtermSizeBitZULHVecLitBoolLitBitLitNumLitExpr BlackBoxEDataTag IdentifierModifier VecAppendDCIndexed DeclarationNetDecl BlackBoxDInstDeclCondAssignment AssignmentHWTypeResetClockSPProductSumVectorUnsignedSignedIndex BitVectorIntegerBoolVoidSize Component componentName hiddenPortsinputsoutput declarations NetlistState _bindings_varEnv _varCount _cmpCount _components _primitives _vhdlMState_typeTranslator_tcCache VHDLState NetlistMonad runNetlist$fNFDataDeclaration$fNFDataHWType$fHashableHWType$fNFDataComponentbindingscmpCount components primitivestcCachetypeTranslatorvarCountvarEnv vhdlMState RewriteState_transformCounter _uniqSupply _evaluator CoreContext CaseScrutCaseAlt TyLamBodyLamBodyLetBodyTyAppCAppArgAppFun RewriteEnvRE _dbgLevel DebugLevelDebugAll DebugApplied DebugName DebugFinal DebugNone evaluatortransformCounter uniqSupplyRewrite TransformRrunR RewriteMonadRewriteSessiondbgLevel$fMonadUniqueWriterTNormalizeState _normalized_specialisationCache_specialisationHistory_specialisationLimit_inlineHistory _inlineLimit_curFun NormRewriteNormalizeSessionNormalizeMonadcurFun inlineHistory inlineLimit normalizedspecialisationCachespecialisationHistoryspecialisationLimit BlackBoxMonadB runBlackBoxMDeclElementTypElemErrTypMTypRstClkSymIODCBlackBoxTemplateSyncIdentifierBlackBoxContextContextresult litInputs funInputsrunParseallR>->topdownRunsafeTopdownR bottomupRunsafeBottomupR!->>-!repeatRwhenR bottomupWhenRmkDcApplicationmkExpr genComponentsplitNormalizedunsafeCoreTypeToHWTypeunsafeCoreTypeToHWTypeMcoreTypeToHWTypeMsynchronizedClkcoreTypeToHWTypemkADT isRecursiveTyrepresentableTypetypeSizeconSize typeLength termHWType varToExprmkUniqueNormalized appendToNamepreserveVarEnv dcToLiteralgenVHDL mkTyPackagevhdlType vhdlTypeMarkvhdlTypeErrValueinstexprverifyBlackBoxContext countArgs countLits countFunssetSym clkSyncIdrenderBlackBox renderElemlineToIdentifier lineToTypemkSyncIdentifierliftRliftRSapply runRewriterunRewriteSession setChangedchanged contextEnvmkEnv mkTmBinderFor mkBinderFor mkInternalVar inlineBinderssubstituteBinders localFreeVars liftBinders liftBinding mkFunction addGlobalBindcloneVar isLocalVarisUntranslatableisLambdaBodyCtxmkWildValBindermkSelectorCase specialise specialise'specArgBndrsAndVarsalreadyInlined addNewInlinespecializeNormisClosed isConstant callGraphrecursiveComponentslambdaDropPrep lambdaDrop dominator blockSinkmkBlackBoxContext mkBlackBoxmkInput mkPrimitive mkLitInput mkFunInputinstantiateSym genNetlistrunNetlistMonad genComponentTmkDeclarationsmkFunApp bindNonRep liftNonReptypeSpec nonRepSpeccaseLetcaseCase inlineNonRepcaseCon nonRepANFtopLetdeadCodebindConstantVar 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