inline-c-0.9.1.10: Write Haskell source files including C code inline. No FFI required.
Safe HaskellSafe-Inferred
LanguageHaskell2010

Language.C.Inline.Internal

Synopsis

Context handling

setContext :: Context -> Q () Source #

Sets the Context for the current module. This function, if called, must be called before any of the other TH functions in this module. Fails if that's not the case.

getContext :: Q Context Source #

Gets the current Context. Also makes sure that the current module is initialised.

Substitution

substitute :: [(String, String -> String)] -> Q a -> Q a Source #

Define macros that can be used in the nested Template Haskell expression. Macros can be used as @MACRO_NAME(input) in inline-c quotes, and will transform their input with the given function. They can be useful for passing in types when defining Haskell instances for C++ template types.

getHaskellType :: Bool -> String -> TypeQ Source #

Given a C type name, return the Haskell type in Template Haskell. The first parameter controls whether function pointers should be mapped as pure or IO functions.

Emitting and invoking C code

The functions in this section let us access more the C file associated with the current module. They can be used to build additional features on top of the basic machinery. All of inline-c is based upon the functions defined here.

Emitting C code

emitVerbatim :: String -> DecsQ Source #

Simply appends some string to the module's C file. Use with care.

emitBlock :: QuasiQuoter Source #

Simply appends some string of block to the module's C file. Use with care.

Inlining C code

We use the Code data structure to represent some C code that we want to emit to the module's C file and immediately generate a foreign call to. For this reason, Code includes both some C definition, and enough information to be able to generate a foreign call -- specifically the name of the function to call and the Haskell type.

All the quasi-quoters work by constructing a Code and calling inlineCode.

data Code Source #

Data type representing a list of C definitions with a typed and named entry function.

We use it as a basis to inline and call C code.

Constructors

Code 

Fields

inlineCode :: Code -> ExpQ Source #

Inlines a piece of code inline. The resulting Exp will have the type specified in the codeType.

In practice, this function outputs the C code to the module's C file, and then inserts a foreign call of type codeType calling the provided codeFunName.

Example:

c_add :: Int -> Int -> Int
c_add = $(do
  here <- TH.location
  inlineCode $ Code
    TH.Unsafe                   -- Call safety
    (Just here)
    [t| Int -> Int -> Int |]    -- Call type
    "francescos_add"            -- Call name
    -- C Code
    "int francescos_add(int x, int y) { int z = x + y; return z; }")

inlineExp Source #

Arguments

:: Safety

Safety of the foreign call

-> Loc

The location to report

-> TypeQ

Type of the foreign call

-> Type CIdentifier

Return type of the C expr

-> [(CIdentifier, Type CIdentifier)]

Parameters of the C expr

-> String

The C expression

-> ExpQ 

Same as inlineCItems, but with a single expression.

c_cos :: Double -> Double
c_cos = $(do
  here <- TH.location
  inlineExp
    TH.Unsafe
    here
    [t| Double -> Double |]
    (quickCParser_ "double" parseType)
    [("x", quickCParser_ "double" parseType)]
    "cos(x)")

inlineItems Source #

Arguments

:: Safety

Safety of the foreign call

-> Bool

Whether to return as a FunPtr or not

-> Maybe String

Optional postfix for the generated name

-> Loc

The location to report

-> TypeQ

Type of the foreign call

-> Type CIdentifier

Return type of the C expr

-> [(CIdentifier, Type CIdentifier)]

Parameters of the C expr

-> String

The C items

-> ExpQ 

Same as inlineCode, but accepts a string containing a list of C statements instead instead than a full-blown Code. A function containing the provided statement will be automatically generated.

c_cos :: Double -> Double
c_cos = $(do
 here <- TH.location
 inlineItems
  TH.Unsafe
  False
  Nothing
  here
  [t| Double -> Double |]
  (quickCParser_ "double" parseType)
  [("x", quickCParser_ "double" parseType)]
  "return cos(x);")

Parsing

These functions are used to parse the anti-quotations. They're exposed for testing purposes, you really should not use them.

data SomeEq Source #

Instances

Instances details
Show SomeEq Source # 
Instance details

Defined in Language.C.Inline.Internal

Eq SomeEq Source # 
Instance details

Defined in Language.C.Inline.Internal

Methods

(==) :: SomeEq -> SomeEq -> Bool #

(/=) :: SomeEq -> SomeEq -> Bool #

toSomeEq :: (Eq a, Typeable a) => a -> SomeEq Source #

parseTypedC Source #

Arguments

:: forall m. CParser HaskellIdentifier m 
=> Bool 
-> AntiQuoters 
-> m ParseTypedC

Returns the return type, the captured variables, and the body.

runParserInQ :: Hashable ident => String -> CParserContext ident -> (forall m. CParser ident m => m a) -> Q a Source #

splitTypedC :: String -> (String, String, Int) Source #

Returns the type and the body separately.

Line directives

lineDirective :: Loc -> String Source #

Tell the C compiler where the next line came from.

Example:

@@ there <- location f (unlines [ lineDirective $(here) , "generated_code_user_did_not_write()" , lineDirective there ] ++ userCode ]) @@

Use lineDirective $(C.here) when generating code, so that any errors or warnings report the location of the generating haskell module, rather than tangentially related user code that doesn't contain the actual problem.

here :: ExpQ Source #

Get the location of the code you're looking at, for use with lineDirective; place before generated code that user did not write.

Utility functions for writing quasiquoters

genericQuote Source #

Arguments

:: Purity 
-> (Loc -> TypeQ -> Type CIdentifier -> [(CIdentifier, Type CIdentifier)] -> String -> ExpQ)

Function building an Haskell expression, see inlineExp for guidance on the other args.

-> QuasiQuoter