{-# LANGUAGE BlockArguments #-}
{-# LANGUAGE CPP #-}
{-# LANGUAGE DefaultSignatures #-}
{-# LANGUAGE DerivingStrategies #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE FunctionalDependencies #-}
{-# LANGUAGE GeneralizedNewtypeDeriving #-}
{-# LANGUAGE QuasiQuotes #-}
{-# LANGUAGE TemplateHaskell #-}
{-# LANGUAGE TypeFamilies #-}
{-# OPTIONS_GHC -Wno-redundant-constraints #-}
#ifdef __GHCIDE__
# define NIX_IS_AT_LEAST(mm,m,p) 1
#endif
module Hercules.CNix.Expr
( init,
setTalkative,
setDebug,
setGlobalOption,
setOption,
setExtraStackOverflowHandlerToSleep,
initThread,
allowThreads,
runGcRegisteredThread,
logInfo,
withEvalState,
withEvalStateConduit,
addAllowedPath,
addInternalAllowedPaths,
evalFile,
newStrings,
appendString,
evalArgs,
autoCallFunction,
isDerivation,
isFunctor,
getRecurseForDerivations,
getAttr,
mkNullableRawValue,
getAttrs,
getDrvFile,
getAttrBool,
getList,
getAttrList,
valueFromExpressionString,
callFunction,
apply,
mkPath,
getFlakeFromFlakeRef,
getLocalFlake,
getFlakeFromGit,
getFlakeFromArchiveUrl,
ToRawValue(..),
ToValue(..),
FromValue(..),
ViaJSON(..),
RawValue,
rawValueType,
module Hercules.CNix.Store,
module Hercules.CNix.Expr.Typed,
type EvalState,
)
where
import Conduit
import qualified Data.Aeson as A
import Data.Coerce (coerce)
import qualified Data.HashMap.Lazy as H
import qualified Data.Map as M
import qualified Data.Scientific as Sci
import Data.Vector (Vector)
import qualified Data.Vector as V
import Foreign (nullPtr)
import qualified Foreign.C.String
import Hercules.CNix.Encapsulation (moveToForeignPtrWrapper)
import Hercules.CNix.Expr.Context
import Hercules.CNix.Expr.Raw
import Hercules.CNix.Expr.Typed
import Hercules.CNix.Store
import Hercules.CNix.Store.Context
import qualified Language.C.Inline.Cpp as C
import qualified Language.C.Inline.Cpp.Exception as C
import Paths_hercules_ci_cnix_expr (getDataFileName)
import Protolude hiding (evalState)
import System.Directory (makeAbsolute)
import Data.Aeson.KeyMap (toMapText)
C.context (Hercules.CNix.Store.Context.context <> Hercules.CNix.Expr.Context.evalContext)
C.verbatim "#define GC_THREADS 1"
C.include "<stdio.h>"
C.include "<cstring>"
C.include "<math.h>"
C.include "<nix/config.h>"
C.include "<nix/shared.hh>"
C.include "<nix/eval.hh>"
C.include "<nix/eval-inline.hh>"
C.include "<nix/store-api.hh>"
C.include "<nix/common-eval-args.hh>"
C.include "<nix/get-drvs.hh>"
C.include "<nix/derivations.hh>"
C.include "<nix/globals.hh>"
C.include "<nix/flake/flake.hh>"
C.include "<nix/flake/flakeref.hh>"
#if NIX_IS_AT_LEAST(2,19,0)
C.include "<nix/args/root.hh>"
#endif
C.include "hercules-ci-cnix/expr.hxx"
C.include "<gc/gc.h>"
C.include "<gc/gc_cpp.h>"
C.include "<gc/gc_allocator.h>"
C.using "namespace nix"
C.verbatim "\nGC_API void GC_CALL GC_throw_bad_alloc() { throw std::bad_alloc(); }\n"
init :: IO ()
init :: IO ()
init =
IO () -> IO ()
forall (f :: * -> *) a. Functor f => f a -> f ()
void
[C.throwBlock| void {
nix::initNix();
nix::initGC();
#if NIX_IS_AT_LEAST(2,15,0)
globalConfig.set("extra-experimental-features", "flakes");
#else
#if NIX_IS_AT_LEAST(2,5,0)
std::set<nix::ExperimentalFeature> features(nix::settings.experimentalFeatures.get());
features.insert(nix::ExperimentalFeature::Flakes);
#else
Strings features(nix::settings.experimentalFeatures.get());
features.push_back("flakes");
#endif
nix::settings.experimentalFeatures.assign(features);
#endif
} |]
initThread :: IO ()
initThread =
void
[C.throwBlock| void {
nix::detectStackOverflow();
}|]
allowThreads :: IO ()
allowThreads =
void
[C.block| void {
GC_allow_register_threads();
}|]
runGcRegisteredThread :: IO a -> IO a
runGcRegisteredThread io =
runInBoundThread do
bracket
start
(const end)
(const io)
where
start =
do
initThread
[C.block| void {
struct GC_stack_base sb;
int r = GC_get_stack_base(&sb);
assert(r == GC_SUCCESS);
GC_register_my_thread(&sb);
}|]
pass
end =
do
[C.block| void {
GC_unregister_my_thread();
}|]
pass
setExtraStackOverflowHandlerToSleep :: IO ()
setExtraStackOverflowHandlerToSleep =
#if NIX_IS_AT_LEAST(2,12,0)
void
[C.throwBlock| void {
nix::stackOverflowHandler = [](siginfo_t *info, void *ctx) {
Error error("stack overflow");
logError(error.info());
// This is risky for a signal handler.
// Note that the original thread is now in a permanently blocked state
// so we can easily create a deadlock.
// Allow the rest of the process to continue for a bit.
sleep(1);
_exit(1);
};
}|]
#else
pass
#endif
setTalkative :: IO ()
setTalkative =
[C.throwBlock| void {
nix::verbosity = nix::lvlTalkative;
} |]
setDebug :: IO ()
setDebug =
[C.throwBlock| void {
nix::verbosity = nix::lvlVomit;
} |]
setGlobalOption :: Text -> Text -> IO ()
setGlobalOption opt value = do
let optionStr = encodeUtf8 opt
valueStr = encodeUtf8 value
[C.throwBlock| void {
globalConfig.set($bs-cstr:optionStr, $bs-cstr:valueStr);
}|]
setOption :: Text -> Text -> IO ()
setOption opt value = do
let optionStr = encodeUtf8 opt
valueStr = encodeUtf8 value
[C.throwBlock| void {
settings.set($bs-cstr:optionStr, $bs-cstr:valueStr);
}|]
logInfo :: Text -> IO ()
logInfo t = do
let bstr = encodeUtf8 t
[C.throwBlock| void {
printInfo($bs-cstr:bstr);
}|]
newEvalState :: MonadIO m => Store -> m (Ptr EvalState)
newEvalState (Store store) = liftIO
#if NIX_IS_AT_LEAST(2,17,0)
[C.throwBlock| EvalState* {
nix::SearchPath searchPaths;
return new EvalState(searchPaths, *$(refStore* store));
} |]
#else
[C.throwBlock| EvalState* {
Strings searchPaths;
return new EvalState(searchPaths, *$(refStore* store));
} |]
#endif
deleteEvalState :: MonadIO m => (Ptr EvalState) -> m ()
deleteEvalState st = liftIO [C.throwBlock| void { delete $(EvalState* st); } |]
withEvalState ::
Store ->
(Ptr EvalState -> IO a) ->
IO a
withEvalState store = bracket (newEvalState store) deleteEvalState
withEvalStateConduit ::
MonadResource m =>
Store ->
(Ptr EvalState -> ConduitT i o m r) ->
ConduitT i o m r
withEvalStateConduit store = bracketP (newEvalState store) deleteEvalState
addAllowedPath :: Ptr EvalState -> ByteString -> IO ()
addAllowedPath evalState path =
[C.throwBlock| void {
std::string path = std::string($bs-ptr:path, $bs-len:path);
EvalState &evalState = *$(EvalState *evalState);
#if NIX_IS_AT_LEAST(2,20,0)
evalState.allowPath(path);
#else
if (evalState.allowedPaths) {
evalState.allowedPaths->insert(path);
}
#endif
}|]
addInternalAllowedPaths :: Ptr EvalState -> IO ()
addInternalAllowedPaths evalState = do
addAllowedPath evalState . encodeUtf8 . toS =<< getDataFileName "vendor/flake-compat"
evalFile :: Ptr EvalState -> FilePath -> IO RawValue
evalFile evalState filename = do
filename' <- Foreign.C.String.newCString filename
mkRawValue
=<< [C.throwBlock| Value* {
EvalState & state = *$(EvalState *evalState);
Value value;
auto cstr = $(const char *filename');
#if NIX_IS_AT_LEAST(2,19,0)
SourcePath path {state.rootPath(CanonPath(cstr))};
#elif NIX_IS_AT_LEAST(2,16,0)
SourcePath path = CanonPath(cstr);
#else
std::string path = cstr;
#endif
state.evalFile(path, value);
return new (NoGC) Value(value);
}|]
newStrings :: IO (Ptr Strings)
newStrings = [C.exp| Strings* { new (NoGC) Strings() }|]
appendString :: Ptr Strings -> ByteString -> IO ()
appendString ss s =
[C.block| void {
$(Strings *ss)->push_back(std::string($bs-ptr:s, $bs-len:s));
}|]
#if NIX_IS_AT_LEAST(2,19,0)
C.verbatim "struct EvalArgs : nix::RootArgs, nix::MixEvalArgs { };"
#else
C.verbatim "struct EvalArgs : nix::MixEvalArgs { };"
#endif
evalArgs :: Ptr EvalState -> [ByteString] -> IO (Value NixAttrs)
evalArgs evalState args = do
argsStrings <- newStrings
forM_ args $ appendString argsStrings
fmap unsafeAssertType . mkRawValue
=<< [C.throwBlock| Value * {
Strings *args = $(Strings *argsStrings);
struct EvalArgs evalArgs;
Bindings *autoArgs;
EvalState &state = *$(EvalState *evalState);
evalArgs.parseCmdline(*args);
autoArgs = evalArgs.getAutoArgs(state);
if (!autoArgs) {
throw nix::Error("Could not evaluate automatic arguments");
}
Value *r = new (NoGC) Value ();
r->mkAttrs(autoArgs);
return r;
}|]
autoCallFunction :: Ptr EvalState -> RawValue -> Value NixAttrs -> IO RawValue
autoCallFunction evalState (RawValue fun) (Value (RawValue autoArgs)) =
mkRawValue
=<< [C.throwBlock| Value* {
Value result;
$(EvalState *evalState)->autoCallFunction(
*$(Value *autoArgs)->attrs,
*$(Value *fun),
result);
return new (NoGC) Value (result);
}|]
isDerivation :: Ptr EvalState -> RawValue -> IO Bool
isDerivation evalState (RawValue v) =
(CInt
0 CInt -> CInt -> Bool
forall a. Eq a => a -> a -> Bool
/=)
(CInt -> Bool) -> IO CInt -> IO Bool
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
<$> [C.throwBlock| int {
if ($(Value *v) == NULL) { throw std::invalid_argument("forceValue value must be non-null"); }
$(EvalState *evalState)->forceValue(*$(Value *v), nix::noPos);
return $(EvalState *evalState)->isDerivation(*$(Value *v));
}|]
isFunctor :: Ptr EvalState -> RawValue -> IO Bool
isFunctor evalState (RawValue v) =
(0 /=)
<$> [C.throwBlock| int {
if ($(Value *v) == NULL) { throw std::invalid_argument("forceValue value must be non-null"); }
return $(EvalState *evalState)->isFunctor(*$(Value *v));
}|]
getRecurseForDerivations :: Ptr EvalState -> Value NixAttrs -> IO Bool
getRecurseForDerivations evalState (Value (RawValue v)) =
(0 /=)
<$> [C.throwBlock| int {
Value *v = $(Value *v);
EvalState &evalState = *$(EvalState *evalState);
Bindings::iterator iter = v->attrs->find(evalState.sRecurseForDerivations);
if (iter == v->attrs->end()) {
return 0;
} else {
// Previously this bool was unpacked manually and included a special
// case to return true when it is not a bool. That logic was added
// because an empty attrset was found here, observed in
// nixpkgs master 67e2de195a4aa0a50ffb1e1ba0b4fb531dca67dc
#if NIX_IS_AT_LEAST(2,14,0)
return evalState.forceBool(*iter->value, iter->pos, "while evaluating whether to traverse into an attribute set to find more derivations");
#elif NIX_IS_AT_LEAST(2,9,0)
return evalState.forceBool(*iter->value, iter->pos);
#else
return evalState.forceBool(*iter->value, *iter->pos);
#endif
}
} |]
getAttr :: Ptr EvalState -> Value NixAttrs -> ByteString -> IO (Maybe RawValue)
getAttr evalState (Value (RawValue v)) k =
mkNullableRawValue
=<< [C.throwBlock| Value *{
Value &v = *$(Value *v);
EvalState &evalState = *$(EvalState *evalState);
Symbol k = evalState.symbols.create($bs-cstr:k);
Bindings::iterator iter = v.attrs->find(k);
if (iter == v.attrs->end()) {
return nullptr;
} else {
return iter->value;
}
}|]
mkNullableRawValue :: Ptr Value' -> IO (Maybe RawValue)
mkNullableRawValue p | p == nullPtr = pure Nothing
mkNullableRawValue p = Just <$> mkRawValue p
getAttrs :: Ptr EvalState -> Value NixAttrs -> IO (Map ByteString RawValue)
getAttrs evalState (Value (RawValue v)) = do
begin <- [C.exp| Attr *{ $(Value *v)->attrs->begin() }|]
end <- [C.exp| Attr *{ $(Value *v)->attrs->end() }|]
let gather :: Map ByteString RawValue -> Ptr Attr' -> IO (Map ByteString RawValue)
gather acc i | i == end = pure acc
gather acc i = do
#if NIX_IS_AT_LEAST(2,9,0)
name <- unsafeMallocBS [C.block| const char *{
EvalState &evalState = *$(EvalState *evalState);
SymbolStr str = evalState.symbols[$(Attr *i)->name];
return strdup(static_cast<std::string>(str).c_str());
}|]
#else
name <- unsafeMallocBS [C.exp| const char *{ strdup(static_cast<std::string>($(Attr *i)->name).c_str()) } |]
#endif
value <- mkRawValue =<< [C.exp| Value *{ new (NoGC) Value(*$(Attr *i)->value) } |]
let acc' = M.insert name value acc
seq acc' pass
gather acc' =<< [C.exp| Attr *{ &$(Attr *i)[1] }|]
gather mempty begin
getDrvFile :: MonadIO m => Ptr EvalState -> RawValue -> m StorePath
getDrvFile evalState (RawValue v) = liftIO do
moveToForeignPtrWrapper
=<< [C.throwBlock| nix::StorePath *{
EvalState &state = *$(EvalState *evalState);
auto drvInfo = getDerivation(state, *$(Value *v), false);
if (!drvInfo)
throw EvalError("Not a valid derivation");
#if NIX_IS_AT_LEAST(2,7,0)
StorePath storePath = drvInfo->requireDrvPath();
#else
std::string drvPath = drvInfo->queryDrvPath();
StorePath storePath = state.store->parseStorePath(drvPath);
#endif
// write it (?)
auto drv = state.store->derivationFromPath(storePath);
return new StorePath(storePath);
}|]
getAttrBool :: Ptr EvalState -> Value NixAttrs -> ByteString -> IO (Either SomeException (Maybe Bool))
getAttrBool evalState attrset attrName = do
attrMaybe <- getAttr evalState attrset attrName
attrMaybe & maybe (pure (Right Nothing)) \attr -> do
match evalState attr >>= \case
Left e -> do
pure $ Left e
Right (IsBool r) -> do
b <- getBool r
pure $ Right (Just b)
Right _ -> do
pure $ Right Nothing
getList :: Value NixList -> IO [RawValue]
getList (Value (RawValue nixList)) = do
len <- [C.exp| int { $(Value *nixList)->listSize() }|]
let getElem i = mkRawValue =<< [C.exp| Value * { $(Value *nixList)->listElems()[$(int i)] }|]
for [0 .. (len - 1)] \i -> do
getElem i
getAttrList :: Ptr EvalState -> Value NixAttrs -> ByteString -> IO (Either SomeException (Maybe [RawValue]))
getAttrList evalState attrset attrName = do
attrMaybe <- getAttr evalState attrset attrName
attrMaybe & maybe (pure (Right Nothing)) \attr -> do
match evalState attr >>= \case
Left e -> do
pure $ Left e
Right (IsList r) -> do
b <- getList r
pure $ Right (Just b)
Right _ -> do
pure $ Right Nothing
valueFromExpressionString ::
Ptr EvalState ->
ByteString ->
ByteString ->
IO RawValue
valueFromExpressionString evalState s basePath = do
mkRawValue
=<< [C.throwBlock| Value *{
EvalState &evalState = *$(EvalState *evalState);
std::string basePathStr = std::string($bs-ptr:basePath, $bs-len:basePath);
#if NIX_IS_AT_LEAST(2,19,0)
SourcePath basePath {evalState.rootPath(CanonPath(basePathStr))};
#elif NIX_IS_AT_LEAST(2,16,0)
SourcePath basePath = CanonPath(basePathStr);
#else
auto & basePath = basePathStr;
#endif
Expr *expr = evalState.parseExprFromString(std::string($bs-ptr:s, $bs-len:s), basePath);
Value *r = new (NoGC) Value();
evalState.eval(expr, *r);
return r;
}|]
callFunction :: Ptr EvalState -> RawValue -> RawValue -> IO RawValue
callFunction evalState (RawValue f) (RawValue a) = do
mkRawValue
=<< [C.throwBlock| Value *{
EvalState &evalState = *$(EvalState *evalState);
Value *r = new (NoGC) Value();
evalState.callFunction(*$(Value *f), *$(Value *a), *r, noPos);
return r;
}|]
apply :: RawValue -> RawValue -> IO RawValue
apply (RawValue f) (RawValue a) = do
mkRawValue
=<< [C.throwBlock| Value *{
Value *r = new (NoGC) Value();
r->mkApp($(Value *f), $(Value *a));
return r;
}|]
mkPath :: Ptr EvalState -> ByteString -> IO (Value NixPath)
mkPath evalState path =
Value
<$> ( mkRawValue
=<< [C.throwBlock| Value *{
EvalState & state = *$(EvalState *evalState);
Value *r = new (NoGC) Value();
std::string s($bs-ptr:path, $bs-len:path);
#if NIX_IS_AT_LEAST(2,19,0)
r->mkPath(state.rootPath(CanonPath(s)));
#else
r->mkPath(s.c_str());
#endif
return r;
}|]
)
getFlakeFromFlakeRef :: Ptr EvalState -> ByteString -> IO RawValue
getFlakeFromFlakeRef evalState flakeRef = do
[C.throwBlock| Value *{
EvalState &evalState = *$(EvalState *evalState);
Value *r = new (NoGC) Value();
std::string flakeRefStr($bs-ptr:flakeRef, $bs-len:flakeRef);
auto flakeRef = nix::parseFlakeRef(flakeRefStr, {}, true);
nix::flake::callFlake(evalState,
nix::flake::lockFlake(evalState, flakeRef,
nix::flake::LockFlags {
.updateLockFile = false,
.useRegistries = false,
#if NIX_IS_AT_LEAST(2,13,0)
.allowUnlocked = false,
#else
.allowMutable = false,
#endif
}),
*r);
return r;
}|]
>>= mkRawValue
getLocalFlake :: Ptr EvalState -> Text -> IO RawValue
getLocalFlake evalState path = do
absPath <- encodeUtf8 . toS <$> makeAbsolute (toS path)
mkRawValue
=<< [C.throwBlock| Value *{
EvalState &evalState = *$(EvalState *evalState);
Value *r = new (NoGC) Value();
std::string path($bs-ptr:absPath, $bs-len:absPath);
auto flakeRef = nix::parseFlakeRef(path, {}, true);
nix::flake::callFlake(evalState,
nix::flake::lockFlake(evalState, flakeRef,
nix::flake::LockFlags {
.updateLockFile = false,
.useRegistries = false,
#if NIX_IS_AT_LEAST(2,13,0)
.allowUnlocked = false,
#else
.allowMutable = false,
#endif
}),
*r);
return r;
}|]
getFlakeFromGit :: Ptr EvalState -> Text -> Text -> Text -> IO RawValue
getFlakeFromGit evalState url ref rev =
let
urlb = encodeUtf8 url
refb = encodeUtf8 ref
revb = encodeUtf8 rev
in [C.throwBlock| Value *{
EvalState &evalState = *$(EvalState *evalState);
Value *r = new (NoGC) Value();
std::string url($bs-ptr:urlb, $bs-len:urlb);
std::string ref($bs-ptr:refb, $bs-len:refb);
std::string rev($bs-ptr:revb, $bs-len:revb);
fetchers::Attrs attrs;
attrs.emplace("type", "git");
attrs.emplace("url", url);
attrs.emplace("ref", ref);
attrs.emplace("rev", rev);
auto flakeRef = nix::FlakeRef::fromAttrs(attrs);
nix::flake::callFlake(evalState,
nix::flake::lockFlake(evalState, flakeRef,
nix::flake::LockFlags {
.updateLockFile = false,
.useRegistries = false,
#if NIX_IS_AT_LEAST(2,13,0)
.allowUnlocked = false,
#else
.allowMutable = false,
#endif
}),
*r);
return r;
}|]
>>= mkRawValue
getFlakeFromArchiveUrl :: Ptr EvalState -> Text -> IO RawValue
getFlakeFromArchiveUrl evalState url = do
srcArgs <-
toRawValue evalState $
("url" :: ByteString) =: url
fn <- valueFromExpressionString evalState "builtins.fetchTarball" "/"
pValue <- apply fn srcArgs
p <- assertType evalState pValue
p' <- getStringIgnoreContext p
getFlakeFromFlakeRef evalState p'
traverseWithKey_ :: Applicative f => (k -> a -> f ()) -> Map k a -> f ()
traverseWithKey_ f = M.foldrWithKey (\k a more -> f k a *> more) (pure ())
class ToRawValue a where
toRawValue :: Ptr EvalState -> a -> IO RawValue
default toRawValue :: ToValue a => Ptr EvalState -> a -> IO RawValue
toRawValue evalState a = rtValue <$> toValue evalState a
class ToRawValue a => ToValue a where
type NixTypeFor a :: Type
toValue :: Ptr EvalState -> a -> IO (Value (NixTypeFor a))
class FromValue n a | a -> n where
fromValue :: Value NixInt -> IO NixInt
fromValue :: Value n -> IO a
instance FromValue Bool Bool where
fromValue = getBool
instance FromValue NixList [RawValue] where
fromValue = getList
instance FromValue NixInt Int64 where
fromValue = getInt
instance ToRawValue RawValue where
toRawValue _ = pure
instance forall (a :: Type). ToRawValue (Value a)
instance forall (a :: Type). ToValue (Value a) where
type NixTypeFor (Value a) = a
toValue _ = pure
instance ToRawValue C.CBool
instance ToValue C.CBool where
type NixTypeFor C.CBool = Bool
toValue _ b =
coerce
<$> [C.block| Value *{
Value *r = new (NoGC) Value();
r->mkBool($(bool b));
return r;
}|]
instance ToRawValue Bool
instance ToValue Bool where
type NixTypeFor Bool = Bool
toValue :: Ptr EvalState -> NixInt -> IO (Value (NixTypeFor NixInt))
toValue es False = toValue es (0 :: C.CBool)
toValue es True = toValue es (1 :: C.CBool)
instance ToRawValue Int64
instance ToValue Int64 where
type NixTypeFor Int64 = NixInt
toValue _ i =
coerce
<$> [C.block| Value *{
Value *r = new (NoGC) Value();
r->mkInt($(int64_t i));
return r;
}|]
instance ToRawValue Int
instance ToValue Int where
type NixTypeFor Int = NixInt
toValue es i = toValue es (fromIntegral i :: Int64)
instance ToRawValue C.CDouble
instance ToValue C.CDouble where
type NixTypeFor C.CDouble = NixFloat
toValue _ f =
coerce
<$> [C.block| Value *{
Value *r = new (NoGC) Value();
r->mkFloat($(double f));
return r;
}|]
instance ToRawValue Double
instance ToValue Double where
type NixTypeFor Double = NixFloat
toValue es f = toValue es (fromRational (toRational f) :: C.CDouble)
instance ToValue ByteString where
type NixTypeFor ByteString = NixString
toValue _ s =
coerce
<$> [C.block| Value *{
Value *r = new (NoGC) Value();
std::string_view s($bs-ptr:s, $bs-len:s);
// If empty, the pointer may be invalid; don't use it.
if (s.size() == 0) {
r->mkString("");
}
else {
r->mkString(GC_STRNDUP(s.data(), s.size()));
}
return r;
}|]
instance ToRawValue ByteString
instance ToRawValue Text
instance ToValue Text where
type NixTypeFor Text = NixString
toValue es s = toValue es (encodeUtf8 s)
instance ToRawValue a => ToRawValue (Map ByteString a)
#if NIX_IS_AT_LEAST(2,6,0)
withBindingsBuilder :: Integral n => Ptr EvalState -> n -> (Ptr BindingsBuilder' -> IO ()) -> IO (Value NixAttrs)
withBindingsBuilder evalState n f = do
withBindingsBuilder' evalState n \bb -> do
f bb
v <- [C.block| Value* {
auto v = new (NoGC) Value();
v->mkAttrs(*$(BindingsBuilder *bb));
return v;
}|]
Value <$> mkRawValue v
withBindingsBuilder' :: Integral n => Ptr EvalState -> n -> (Ptr BindingsBuilder' -> IO a) -> IO a
withBindingsBuilder' evalState n =
let l :: C.CInt
l = fromIntegral n
in
bracket
[C.block| BindingsBuilder* {
auto &evalState = *$(EvalState *evalState);
return new BindingsBuilder(evalState, evalState.allocBindings($(int l)));
}|]
\bb -> [C.block| void { delete $(BindingsBuilder *bb); }|]
#endif
instance ToRawValue a => ToValue (Map ByteString a) where
type NixTypeFor (Map ByteString a) = NixAttrs
#if NIX_IS_AT_LEAST(2,6,0)
toValue evalState attrs = withBindingsBuilder evalState (length attrs) \bb -> do
attrs & traverseWithKey_ \k a -> do
RawValue aRaw <- toRawValue evalState a
[C.block| void {
EvalState &evalState = *$(EvalState *evalState);
std::string k($bs-ptr:k, $bs-len:k);
Value &a = *$(Value *aRaw);
$(BindingsBuilder *bb)->alloc(evalState.symbols.create(k)) = a;
}|]
#else
toValue evalState attrs = do
let l :: C.CInt
l = fromIntegral (length attrs)
v <-
[C.block| Value* {
EvalState &evalState = *$(EvalState *evalState);
Value *v = new (NoGC) Value();
evalState.mkAttrs(*v, $(int l));
return v;
}|]
attrs & traverseWithKey_ \k a -> do
RawValue aRaw <- toRawValue evalState a
[C.block| void {
EvalState &evalState = *$(EvalState *evalState);
std::string k($bs-ptr:k, $bs-len:k);
Value &a = *$(Value *aRaw);
*evalState.allocAttr(*$(Value *v), evalState.symbols.create(k)) = a;
}|]
[C.block| void {
$(Value *v)->attrs->sort();
}|]
Value <$> mkRawValue v
#endif
instance ToRawValue a => ToRawValue (Map Text a)
instance ToRawValue a => ToValue (Map Text a) where
type NixTypeFor (Map Text a) = NixAttrs
toValue :: Ptr EvalState -> Map Text a -> IO (Value (NixTypeFor (Map Text a)))
toValue Ptr EvalState
evalState Map Text a
attrs = Ptr EvalState
-> Map ByteString a -> IO (Value (NixTypeFor (Map ByteString a)))
forall a.
ToValue a =>
Ptr EvalState -> a -> IO (Value (NixTypeFor a))
toValue Ptr EvalState
evalState ((Text -> ByteString) -> Map Text a -> Map ByteString a
forall k2 k1 a. Ord k2 => (k1 -> k2) -> Map k1 a -> Map k2 a
M.mapKeys Text -> ByteString
encodeUtf8 Map Text a
attrs)
mkNull :: IO RawValue
mkNull :: IO RawValue
mkNull =
Ptr Value' -> RawValue
forall a b. Coercible a b => a -> b
coerce
(Ptr Value' -> RawValue) -> IO (Ptr Value') -> IO RawValue
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
<$> IO (Ptr Value')
[C.block| Value* {
Value *v = new (NoGC) Value();
v->mkNull();
return v;
}|]
instance ToRawValue A.Value where
toRawValue :: Ptr EvalState -> Value -> IO RawValue
toRawValue Ptr EvalState
es (A.Bool Bool
b) = Ptr EvalState -> Bool -> IO RawValue
forall a. ToRawValue a => Ptr EvalState -> a -> IO RawValue
toRawValue Ptr EvalState
es Bool
b
toRawValue Ptr EvalState
es (A.String Text
s) = Ptr EvalState -> Text -> IO RawValue
forall a. ToRawValue a => Ptr EvalState -> a -> IO RawValue
toRawValue Ptr EvalState
es Text
s
toRawValue Ptr EvalState
es (A.Object Object
fs) = Ptr EvalState -> Map Text Value -> IO RawValue
forall a. ToRawValue a => Ptr EvalState -> a -> IO RawValue
toRawValue Ptr EvalState
es (Map Text Value -> IO RawValue) -> Map Text Value -> IO RawValue
forall a b. (a -> b) -> a -> b
$ Object -> Map Text Value
forall v. KeyMap v -> Map Text v
toMapText Object
fs
toRawValue Ptr EvalState
_es Value
A.Null = IO RawValue
mkNull
toRawValue Ptr EvalState
es (A.Number Scientific
n) | Just NixInt
i <- Scientific -> Maybe NixInt
forall i. (Integral i, Bounded i) => Scientific -> Maybe i
Sci.toBoundedInteger Scientific
n = Ptr EvalState -> NixInt -> IO RawValue
forall a. ToRawValue a => Ptr EvalState -> a -> IO RawValue
toRawValue Ptr EvalState
es (NixInt
i :: Int64)
toRawValue Ptr EvalState
es (A.Number Scientific
f) = Ptr EvalState -> Double -> IO RawValue
forall a. ToRawValue a => Ptr EvalState -> a -> IO RawValue
toRawValue Ptr EvalState
es (Scientific -> Double
forall a. RealFloat a => Scientific -> a
Sci.toRealFloat Scientific
f :: Double)
toRawValue Ptr EvalState
es (A.Array Array
a) = Ptr EvalState -> Array -> IO RawValue
forall a. ToRawValue a => Ptr EvalState -> a -> IO RawValue
toRawValue Ptr EvalState
es Array
a
newtype ViaJSON a = ViaJSON {forall a. ViaJSON a -> a
fromViaJSON :: a}
deriving newtype (ViaJSON a -> ViaJSON a -> Bool
(ViaJSON a -> ViaJSON a -> Bool)
-> (ViaJSON a -> ViaJSON a -> Bool) -> Eq (ViaJSON a)
forall a. Eq a => ViaJSON a -> ViaJSON a -> Bool
forall a. (a -> a -> Bool) -> (a -> a -> Bool) -> Eq a
$c== :: forall a. Eq a => ViaJSON a -> ViaJSON a -> Bool
== :: ViaJSON a -> ViaJSON a -> Bool
$c/= :: forall a. Eq a => ViaJSON a -> ViaJSON a -> Bool
/= :: ViaJSON a -> ViaJSON a -> Bool
Eq, Eq (ViaJSON a)
Eq (ViaJSON a)
-> (ViaJSON a -> ViaJSON a -> Ordering)
-> (ViaJSON a -> ViaJSON a -> Bool)
-> (ViaJSON a -> ViaJSON a -> Bool)
-> (ViaJSON a -> ViaJSON a -> Bool)
-> (ViaJSON a -> ViaJSON a -> Bool)
-> (ViaJSON a -> ViaJSON a -> ViaJSON a)
-> (ViaJSON a -> ViaJSON a -> ViaJSON a)
-> Ord (ViaJSON a)
ViaJSON a -> ViaJSON a -> Bool
ViaJSON a -> ViaJSON a -> Ordering
ViaJSON a -> ViaJSON a -> ViaJSON a
forall a.
Eq a
-> (a -> a -> Ordering)
-> (a -> a -> Bool)
-> (a -> a -> Bool)
-> (a -> a -> Bool)
-> (a -> a -> Bool)
-> (a -> a -> a)
-> (a -> a -> a)
-> Ord a
forall {a}. Ord a => Eq (ViaJSON a)
forall a. Ord a => ViaJSON a -> ViaJSON a -> Bool
forall a. Ord a => ViaJSON a -> ViaJSON a -> Ordering
forall a. Ord a => ViaJSON a -> ViaJSON a -> ViaJSON a
$ccompare :: forall a. Ord a => ViaJSON a -> ViaJSON a -> Ordering
compare :: ViaJSON a -> ViaJSON a -> Ordering
$c< :: forall a. Ord a => ViaJSON a -> ViaJSON a -> Bool
< :: ViaJSON a -> ViaJSON a -> Bool
$c<= :: forall a. Ord a => ViaJSON a -> ViaJSON a -> Bool
<= :: ViaJSON a -> ViaJSON a -> Bool
$c> :: forall a. Ord a => ViaJSON a -> ViaJSON a -> Bool
> :: ViaJSON a -> ViaJSON a -> Bool
$c>= :: forall a. Ord a => ViaJSON a -> ViaJSON a -> Bool
>= :: ViaJSON a -> ViaJSON a -> Bool
$cmax :: forall a. Ord a => ViaJSON a -> ViaJSON a -> ViaJSON a
max :: ViaJSON a -> ViaJSON a -> ViaJSON a
$cmin :: forall a. Ord a => ViaJSON a -> ViaJSON a -> ViaJSON a
min :: ViaJSON a -> ViaJSON a -> ViaJSON a
Ord, ReadPrec [ViaJSON a]
ReadPrec (ViaJSON a)
Int -> ReadS (ViaJSON a)
ReadS [ViaJSON a]
(Int -> ReadS (ViaJSON a))
-> ReadS [ViaJSON a]
-> ReadPrec (ViaJSON a)
-> ReadPrec [ViaJSON a]
-> Read (ViaJSON a)
forall a. Read a => ReadPrec [ViaJSON a]
forall a. Read a => ReadPrec (ViaJSON a)
forall a. Read a => Int -> ReadS (ViaJSON a)
forall a. Read a => ReadS [ViaJSON a]
forall a.
(Int -> ReadS a)
-> ReadS [a] -> ReadPrec a -> ReadPrec [a] -> Read a
$creadsPrec :: forall a. Read a => Int -> ReadS (ViaJSON a)
readsPrec :: Int -> ReadS (ViaJSON a)
$creadList :: forall a. Read a => ReadS [ViaJSON a]
readList :: ReadS [ViaJSON a]
$creadPrec :: forall a. Read a => ReadPrec (ViaJSON a)
readPrec :: ReadPrec (ViaJSON a)
$creadListPrec :: forall a. Read a => ReadPrec [ViaJSON a]
readListPrec :: ReadPrec [ViaJSON a]
Read, Int -> ViaJSON a -> ShowS
[ViaJSON a] -> ShowS
ViaJSON a -> FilePath
(Int -> ViaJSON a -> ShowS)
-> (ViaJSON a -> FilePath)
-> ([ViaJSON a] -> ShowS)
-> Show (ViaJSON a)
forall a. Show a => Int -> ViaJSON a -> ShowS
forall a. Show a => [ViaJSON a] -> ShowS
forall a. Show a => ViaJSON a -> FilePath
forall a.
(Int -> a -> ShowS) -> (a -> FilePath) -> ([a] -> ShowS) -> Show a
$cshowsPrec :: forall a. Show a => Int -> ViaJSON a -> ShowS
showsPrec :: Int -> ViaJSON a -> ShowS
$cshow :: forall a. Show a => ViaJSON a -> FilePath
show :: ViaJSON a -> FilePath
$cshowList :: forall a. Show a => [ViaJSON a] -> ShowS
showList :: [ViaJSON a] -> ShowS
Show)
instance A.ToJSON a => ToRawValue (ViaJSON a) where
toRawValue :: Ptr EvalState -> ViaJSON a -> IO RawValue
toRawValue Ptr EvalState
es (ViaJSON a
a) = Ptr EvalState -> Value -> IO RawValue
forall a. ToRawValue a => Ptr EvalState -> a -> IO RawValue
toRawValue Ptr EvalState
es (a -> Value
forall a. ToJSON a => a -> Value
A.toJSON a
a)
hmTraverseWithKey_ :: Applicative f => (k -> a -> f ()) -> H.HashMap k a -> f ()
hmTraverseWithKey_ :: forall (f :: * -> *) k a.
Applicative f =>
(k -> a -> f ()) -> HashMap k a -> f ()
hmTraverseWithKey_ k -> a -> f ()
f = (k -> a -> f () -> f ()) -> f () -> HashMap k a -> f ()
forall k v a. (k -> v -> a -> a) -> a -> HashMap k v -> a
H.foldrWithKey (\k
k a
a f ()
more -> k -> a -> f ()
f k
k a
a f () -> f () -> f ()
forall a b. f a -> f b -> f b
forall (f :: * -> *) a b. Applicative f => f a -> f b -> f b
*> f ()
more) (() -> f ()
forall a. a -> f a
forall (f :: * -> *) a. Applicative f => a -> f a
pure ())
instance ToRawValue a => ToRawValue (H.HashMap Text a)
instance ToRawValue a => ToValue (H.HashMap Text a) where
type NixTypeFor (H.HashMap Text a) = NixAttrs
#if NIX_IS_AT_LEAST(2,6,0)
toValue :: Ptr EvalState
-> HashMap Text a -> IO (Value (NixTypeFor (HashMap Text a)))
toValue Ptr EvalState
evalState HashMap Text a
attrs = Ptr EvalState
-> Int -> (Ptr BindingsBuilder' -> IO ()) -> IO (Value NixAttrs)
forall n.
Integral n =>
Ptr EvalState
-> n -> (Ptr BindingsBuilder' -> IO ()) -> IO (Value NixAttrs)
withBindingsBuilder Ptr EvalState
evalState (HashMap Text a -> Int
forall a. HashMap Text a -> Int
forall (t :: * -> *) a. Foldable t => t a -> Int
length HashMap Text a
attrs) \Ptr BindingsBuilder'
bb -> do
HashMap Text a
attrs HashMap Text a -> (HashMap Text a -> IO ()) -> IO ()
forall a b. a -> (a -> b) -> b
& (Text -> a -> IO ()) -> HashMap Text a -> IO ()
forall (f :: * -> *) k a.
Applicative f =>
(k -> a -> f ()) -> HashMap k a -> f ()
hmTraverseWithKey_ \Text
k' a
a -> do
RawValue Ptr Value'
aRaw <- Ptr EvalState -> a -> IO RawValue
forall a. ToRawValue a => Ptr EvalState -> a -> IO RawValue
toRawValue Ptr EvalState
evalState a
a
let k :: ByteString
k = Text -> ByteString
encodeUtf8 Text
k'
[C.block| void {
EvalState &evalState = *$(EvalState *evalState);
std::string k($bs-ptr:k, $bs-len:k);
Value &a = *$(Value *aRaw);
$(BindingsBuilder *bb)->alloc(evalState.symbols.create(k)) = a;
}|]
#else
toValue evalState attrs = do
let l :: C.CInt
l = fromIntegral (length attrs)
v <-
[C.block| Value* {
EvalState &evalState = *$(EvalState *evalState);
Value *v = new (NoGC) Value();
evalState.mkAttrs(*v, $(int l));
return v;
}|]
attrs & hmTraverseWithKey_ \k' a -> do
RawValue aRaw <- toRawValue evalState a
let k = encodeUtf8 k'
[C.block| void {
EvalState &evalState = *$(EvalState *evalState);
std::string k($bs-ptr:k, $bs-len:k);
Value &a = *$(Value *aRaw);
*evalState.allocAttr(*$(Value *v), evalState.symbols.create(k)) = a;
}|]
[C.block| void {
$(Value *v)->attrs->sort();
}|]
Value <$> mkRawValue v
#endif
instance ToRawValue a => ToRawValue (Vector a)
instance ToRawValue a => ToValue (Vector a) where
type NixTypeFor (Vector a) = NixList
toValue :: Ptr EvalState -> Vector a -> IO (Value (NixTypeFor (Vector a)))
toValue Ptr EvalState
evalState Vector a
vec =
Value Any -> Value NixList
forall a b. Coercible a b => a -> b
coerce (Value Any -> Value NixList)
-> IO (Value Any) -> IO (Value NixList)
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
<$> do
let l :: C.CInt
l :: CInt
l = Int -> CInt
forall a b. (Integral a, Num b) => a -> b
fromIntegral (Vector a -> Int
forall a. Vector a -> Int
forall (t :: * -> *) a. Foldable t => t a -> Int
length Vector a
vec)
Ptr Value'
v <-
[C.block| Value* {
EvalState &evalState = *$(EvalState *evalState);
Value *v = new (NoGC) Value();
evalState.mkList(*v, $(int l));
return v;
}|]
Vector a
vec Vector a -> (Vector a -> IO ()) -> IO ()
forall a b. a -> (a -> b) -> b
& (Int -> a -> IO ()) -> Vector a -> IO ()
forall (m :: * -> *) a b.
Monad m =>
(Int -> a -> m b) -> Vector a -> m ()
V.imapM_ \Int
i a
a -> do
RawValue Ptr Value'
aRaw <- Ptr EvalState -> a -> IO RawValue
forall a. ToRawValue a => Ptr EvalState -> a -> IO RawValue
toRawValue Ptr EvalState
evalState a
a
let ix :: CInt
ix = Int -> CInt
forall a b. (Integral a, Num b) => a -> b
fromIntegral Int
i
[C.block| void {
Value &v = *$(Value *v);
v.listElems()[$(int ix)] = $(Value *aRaw);
}|]
RawValue -> Value Any
forall a. RawValue -> Value a
Value (RawValue -> Value Any) -> IO RawValue -> IO (Value Any)
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
<$> Ptr Value' -> IO RawValue
mkRawValue Ptr Value'
v
instance ToRawValue a => ToRawValue [a]
instance ToRawValue a => ToValue [a] where
type NixTypeFor [a] = NixList
toValue :: Ptr EvalState -> [a] -> IO (Value (NixTypeFor [a]))
toValue Ptr EvalState
es [a]
l = Ptr EvalState -> Vector a -> IO (Value (NixTypeFor (Vector a)))
forall a.
ToValue a =>
Ptr EvalState -> a -> IO (Value (NixTypeFor a))
toValue Ptr EvalState
es ([a] -> Vector a
forall a. [a] -> Vector a
V.fromList [a]
l)