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public static Assign ( |
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| left | An |
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| right | An |
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| Результат | ||
/// <summary>
/// From control flow perspective it "calls" the proc.
/// </summary>
internal static void SetProcCallRule(
MetaObjectBuilder /*!*/ metaBuilder,
Expression /*!*/ procExpression, // proc object
Expression /*!*/ selfExpression, // self passed to the proc
Expression callingMethodExpression, // RubyLambdaMethodInfo passed to the proc via BlockParam
CallArguments /*!*/ args // user arguments passed to the proc
)
{
var bfcVariable = metaBuilder.GetTemporary(typeof(BlockParam), "#bfc");
var resultVariable = metaBuilder.GetTemporary(typeof(object), "#result");
metaBuilder.Result = AstFactory.Block(
Ast.Assign(bfcVariable,
(callingMethodExpression != null) ?
Methods.CreateBfcForMethodProcCall.OpCall(
AstUtils.Convert(procExpression, typeof(Proc)),
callingMethodExpression
) :
Methods.CreateBfcForProcCall.OpCall(
AstUtils.Convert(procExpression, typeof(Proc))
)
),
Ast.Assign(resultVariable, AstFactory.YieldExpression(
args.GetSimpleArgumentExpressions(),
args.GetSplattedArgumentExpression(),
args.GetRhsArgumentExpression(),
bfcVariable,
selfExpression
)),
Methods.MethodProcCall.OpCall(bfcVariable, resultVariable),
resultVariable
);
}
public void Factorial()
{
var value = LinqExpression.Parameter(typeof(int), "value");
var result = LinqExpression.Parameter(typeof(int), "result");
var label = LinqExpression.Label(typeof(int), "label");
var one = LinqExpression.Constant(1);
var expression = LinqExpression.Block(
new[] { result },
LinqExpression.Assign(
result,
one),
LinqExpression.Loop(
LinqExpression.Condition(
LinqExpression.GreaterThan(
value,
one),
LinqExpression.MultiplyAssign(
result,
LinqExpression.PostDecrementAssign(
value)),
LinqExpression.Break(
label,
result),
typeof(void)),
label));
ShouldRoundrip(expression);
}
public LambdaExpression CreateLambda(Type from, Type to)
{
var fromParameters = from.GetTypeInfo().GenericTypeArguments;
var toParameters = to.GetTypeInfo().GenericTypeArguments;
var converters = fromParameters
.Zip(toParameters, (f, t) => Ref.GetLambda(f, t))
.ToArray();
var input = Ex.Parameter(from, "input");
var res = toParameters.Select(t => Ex.Parameter(typeof(ConversionResult <>).MakeGenericType(t))).ToArray();
var conversion = res.Select((r, i) =>
Ex.Assign(res[i], converters[i].ApplyTo(Ex.PropertyOrField(input, $"Item{i + 1}")))).ToArray();
var conversionSuccesful = Enumerable.Aggregate(res, (Ex)Ex.Constant(true),
(c, p) => Ex.MakeBinary(Et.AndAlso, c, Ex.Property(p, nameof(IConversionResult.IsSuccessful))));
var block = Ex.Block(res,
Ex.Block(conversion),
Ex.Condition(conversionSuccesful,
Result(to,
Ex.Call(Creator(to), Enumerable.Select(res, p => Ex.Property(p, nameof(IConversionResult.Result))))),
NoResult(to)));
var lambda = Ex.Lambda(block, input);
return(lambda);
}
Exp Assign(List <Token> expr, Exp value)
{
if (expr.Count == 1)
{
Token tok = expr[0];
if (tok.Type == TokenType.Identifier)
{
if (Local != null)
{
if (Local.TryGetValue(tok.Value, out Exp id))
{
return(Exp.Assign(id, value));
}
else
{
var var = Exp.Variable(typeof(Object), tok.Value);
Local.Add(var);
return(Exp.Assign(var, value));
}
/* if 'name' is not present in the 'Local' dictionary defines
* new local variable instead of accessing 'Global' (by default)
*/
}
else
{
return(Exp.Assign(GlobalAccess(tok.Value), value));
}
}
}
else
{
Token tok = expr[^ 1]; // last
private static Func <int[], int[]> GenerateCopyExpression()
{
var ctor = typeof(int[]).GetConstructor(new[] { typeof(int) });
var get = typeof(int[]).GetMethod("Get", new[] { typeof(int) });
var set = typeof(int[]).GetMethod("Set", new[] { typeof(int), typeof(int) });
var p1 = Exp.Parameter(typeof(int[]));
var v1 = Exp.Variable(typeof(int[]));
var v2 = Exp.Variable(typeof(int));
var @break = Exp.Label();
var block = Exp.Block(
new[] { v1, v2 },
Exp.Assign(v1, Exp.New(ctor, Exp.Property(p1, "Length"))),
Exp.Assign(v2, Exp.Constant(0)),
Exp.Loop(
Exp.IfThenElse(
Exp.LessThan(v2, Exp.Property(p1, "Length")),
Exp.Block(
Exp.Call(v1, set, v2, Exp.Call(p1, get, v2)),
Exp.AddAssign(v2, Exp.Constant(1))
),
Exp.Break(@break)
),
@break),
v1
);
return(Exp.Lambda <Func <int[], int[]> >(block, new ParameterExpression[] { p1 }).Compile());
}
internal bool AddSplattedArgumentTest(object value, Expression /*!*/ expression, out int listLength, out ParameterExpression /*!*/ listVariable)
{
if (value == null)
{
AddRestriction(Ast.Equal(expression, Ast.Constant(null)));
}
else
{
// test exact type:
AddTypeRestriction(value.GetType(), expression);
List <object> list = value as List <object>;
if (list != null)
{
Type type = typeof(List <object>);
listLength = list.Count;
listVariable = GetTemporary(type, "#list");
AddCondition(Ast.Equal(
Ast.Property(Ast.Assign(listVariable, Ast.Convert(expression, type)), type.GetProperty("Count")),
Ast.Constant(list.Count))
);
return(true);
}
}
listLength = -1;
listVariable = null;
return(false);
}
public static Func <TExArgCtx, TEx <float> > PivotShift <S>(Func <EEx <float>, TEx <float>[], TEx <float> > shifter,
Func <TExArgCtx, TEx <float> > sharpness, Func <TExArgCtx, TEx <float> > pivot,
Func <TExArgCtx, TEx <float> > f1, Func <TExArgCtx, TEx <float> > f2, string pivotVar) where S : TEx, new()
{
if (pivotVar == "t" || pivotVar == "p" || pivotVar == "x")
{
return(t => {
var pivotT = t.MakeCopyForType <S>(out var currEx, out var pivotEx);
return Ex.Block(new ParameterExpression[] { pivotEx },
Ex.Assign(pivotEx, currEx),
Ex.Assign(pivotVar.Into <Func <TExArgCtx, TEx <float> > >()(pivotT), pivot(t)),
shifter(sharpness(t), new TEx <float>[] { f1(t), f1(pivotT).Add(f2(t).Sub(f2(pivotT))) })
);
});
}
else if (pivotVar[0] == Parser.SM_REF_KEY_C)
{
var let = pivotVar.Substring(1);
return(t => shifter(sharpness(t), new TEx <float>[] {
f1(t), f2(t).Add(
ReflectEx.Let <float, float>(let, pivot, () => f1(t).Sub(f2(t)), t)
)
}));
}
else
{
throw new Exception($"{pivotVar} is not a valid pivoting target.");
}
}
private LambdaExpression toDictLambda(Type from, Type to)
{
var valueType = recordCreator.GetValueType(to);
var recType = typeof(IRecord <>).MakeGenericType(valueType);
var set = recType.GetTypeInfo().GetDeclaredMethod(nameof(IRecord <object> .SetValue));
var input = Ex.Parameter(from, "input");
var tmp = Ex.Parameter(typeof(ConversionResult <>).MakeGenericType(valueType), "tmp");
var res = Ex.Parameter(typeof(IDictionary <,>).MakeGenericType(typeof(string), valueType), "res");
var rec = Ex.Parameter(recType, "rec");
var getters = GetReadablePropertiesForType(from);
var converters = getters.Select(g => Ref.GetLambda(g.PropertyType, valueType));
var end = Ex.Label(typeof(ConversionResult <>).MakeGenericType(to));
var block = Ex.Block(new[] { tmp, res, rec },
Ex.Assign(res, Ex.New(GetParameterlessConstructor(to))),
Ex.Assign(rec, recordCreator.Creator(to).ApplyTo(res)),
Ex.IfThen(Ex.MakeBinary(ExpressionType.Equal, rec, Ex.Default(rec.Type)), Ex.Goto(end, NoResult(to))),
Ex.Block(getters.Zip(converters, (g, c) => new { g, c })
.Select(x =>
Ex.Block(
Ex.Assign(tmp, x.c.ApplyTo(Ex.Property(input, x.g))),
Ex.IfThenElse(Ex.Property(tmp, nameof(IConversionResult.IsSuccessful)),
Ex.Call(rec, set, Ex.Constant(x.g.Name), Ex.Property(tmp, nameof(IConversionResult.Result))),
Ex.Goto(end, NoResult(to)))))),
Ex.Label(end, Result(to, Ex.Convert(res, to))));
return(Ex.Lambda(block, input));
}
/// <summary>
/// Invariant: bex is linearized.
/// </summary>
private BlockExpression AssignBlockResultToTemp(BlockExpression bex, ParameterExpression pex)
{
var exprs = bex.Expressions.ToArray();
exprs[exprs.Length - 1] = Ex.Assign(pex, exprs[exprs.Length - 1]);
return(Ex.Block(bex.Variables, exprs));
}
public LinqExpr ReDeclInit <T>(string Name, T Init)
{
LinqExpr p = ReDecl(typeof(T), Name);
code.Add(LinqExpr.Assign(p, LinqExpr.Constant(Init)));
return(p);
}
// Pseudocode:
//string input =>
//{
// R result = 0;
// for (int i = input.Length - 1; i >= 0; i--)
// {
// result <<= 6;
// var m = _invMap[input[i]];
// if (m == 0xff)
// return default(ConversionResult<R>);
// result += m;
// }
// return new ConversionResult<R>(result);
//}
private LambdaExpression fromLambda(Type to)
{
var stringthis = typeof(string).GetTypeInfo().DeclaredProperties.First(p => p.GetIndexParameters().Length == 1 && p.GetIndexParameters()[0].ParameterType == typeof(int));
var input = Ex.Parameter(typeof(string), "input");
var result = Ex.Parameter(to, "result");
var i = Ex.Parameter(typeof(int), "i");
var m = Ex.Parameter(typeof(byte), "m");
var loopstart = Ex.Label("loopstart");
var end = Ex.Label(typeof(ConversionResult <>).MakeGenericType(to), "end");
var loop = Ex.Block(
Ex.Label(loopstart),
Ex.IfThen(Ex.MakeBinary(ExpressionType.LessThan, i, Ex.Constant(0)),
Ex.Goto(end, Result(to, result))),
Ex.LeftShiftAssign(result, Ex.Constant(6)),
Ex.Assign(m, Ex.ArrayIndex(Ex.Constant(_invMap), Ex.Convert(Ex.MakeIndex(input, stringthis, new[] { i }), typeof(int)))),
Ex.IfThen(Ex.MakeBinary(ExpressionType.Equal, m, Ex.Constant((byte)0xff)),
Ex.Goto(end, NoResult(to))),
Ex.AddAssign(result, Ex.Convert(m, result.Type)),
Ex.PostDecrementAssign(i),
Ex.Goto(loopstart));
var block = Ex.Block(new[] { result, i, m },
Ex.Assign(result, Ex.Convert(Ex.Constant(0), to)),
Ex.Assign(i, Ex.MakeBinary(ExpressionType.Subtract, Ex.Property(input, nameof(string.Length)), Ex.Constant(1))),
loop,
Ex.Label(end, NoResult(to)));
return(Ex.Lambda(block, input));
}
public LambdaExpression CreateLambda(Type from, Type to)
{
var toParameters = to.GetTypeInfo().GenericTypeArguments;
var tupa = toParameters.Length;
var input = Ex.Parameter(from, "input");
var converters = toParameters.Select(p => Ref.GetLambda(typeof(string), p)).ToArray();
var res = toParameters.Select(p => Ex.Parameter(typeof(ConversionResult <>).MakeGenericType(p))).ToArray();
var end = Ex.Label(typeof(ConversionResult <>).MakeGenericType(to), "end");
var indexer = typeof(string[]).GetTypeInfo().GetDeclaredProperty("Item");
var split = Ex.Parameter(typeof(string[]), "split");
var conversion = Ex.Block(converters.Select((c, i) =>
Ex.Block(
Ex.Assign(res[i],
c.ApplyTo(Ex.MakeIndex(split, indexer, new[] { Ex.MakeBinary(Et.Add, Ex.Constant(i), Ex.MakeBinary(Et.Subtract, Ex.Property(split, nameof(Array.Length)), Ex.Constant(tupa))) }))),
Ex.IfThen(Ex.Not(Ex.Property(res[i], nameof(IConversionResult.IsSuccessful))),
Ex.Goto(end, NoResult(to))))));
var block = Ex.Block(new[] { split },
Ex.Assign(split, Ex.Call(input, nameof(string.Split), Type.EmptyTypes, _separator)),
Ex.Condition(Ex.MakeBinary(Et.LessThan, Ex.Property(split, nameof(Array.Length)), Ex.Constant(tupa)),
NoResult(to),
Ex.Block(res,
Ex.IfThen(Ex.MakeBinary(Et.GreaterThan, Ex.Property(split, nameof(Array.Length)), Ex.Constant(tupa)),
Ex.Assign(Ex.ArrayAccess(split, Ex.MakeBinary(Et.Subtract, Ex.Property(split, nameof(Array.Length)), Ex.Constant(tupa))),
Ex.Call(typeof(string), nameof(string.Join), Type.EmptyTypes, _separatorString,
Ex.Call(typeof(Enumerable), nameof(Enumerable.Take), new[] { typeof(string) }, split,
Ex.MakeBinary(Et.Add, Ex.Constant(1), Ex.MakeBinary(Et.Subtract, Ex.Property(split, nameof(Array.Length)), Ex.Constant(tupa))))))),
conversion,
Ex.Label(end, Result(to, Ex.Call(Creator(to), res.Select(r => Ex.Property(r, nameof(IConversionResult.Result)))))))));
var lambda = Ex.Lambda(block, input);
return(lambda);
}
protected override object VisitAssignment(Assignment A)
{
LinqExpr value = target.Compile(A.Value);
switch (A.Operator)
{
case Operator.Add: target.Add(LinqExpr.AddAssign(target.LookUp(A.Assign), value)); break;
case Operator.Subtract: target.Add(LinqExpr.SubtractAssign(target.LookUp(A.Assign), value)); break;
case Operator.Multiply: target.Add(LinqExpr.MultiplyAssign(target.LookUp(A.Assign), value)); break;
case Operator.Divide: target.Add(LinqExpr.DivideAssign(target.LookUp(A.Assign), value)); break;
case Operator.Power: target.Add(LinqExpr.PowerAssign(target.LookUp(A.Assign), value)); break;
case Operator.And: target.Add(LinqExpr.AndAssign(target.LookUp(A.Assign), value)); break;
case Operator.Or: target.Add(LinqExpr.OrAssign(target.LookUp(A.Assign), value)); break;
case Operator.Equal:
LinqExpr x = target.LookUp(A.Assign);
if (x == null)
{
x = target.DeclInit(A.Assign, A.Value);
}
target.Add(LinqExpr.Assign(x, value));
break;
default: throw new NotImplementedException("Operator not implemented for assignment.");
}
return(null);
}
public ParamExpr DeclInit <T>(Scope Scope, string Name, T Init)
{
ParamExpr p = Decl(Scope.Local, typeof(T), Name);
code.Add(LinqExpr.Assign(p, LinqExpr.Constant(Init)));
return(p);
}
// Generate expression to swap a and b, using t as a temporary.
private static LinqExpr Swap(LinqExpr a, LinqExpr b, LinqExpr t)
{
return(LinqExpr.Block(
LinqExpr.Assign(t, a),
LinqExpr.Assign(a, b),
LinqExpr.Assign(b, t)));
}
/// <summary>
/// Takes current result and wraps it into try-filter(MethodUnwinder)-finally block that ensures correct "break" behavior for
/// Ruby method calls with a block given in arguments.
///
/// Sets up a RFC frame similarly to MethodDeclaration.
/// </summary>
internal static void ApplyBlockFlowHandlingInternal(MetaObjectBuilder /*!*/ metaBuilder, CallArguments /*!*/ args)
{
// TODO (improvement):
// We don't special case null block here, although we could (we would need a test for that then).
// We could also statically know (via call-site flag) that the current method is not a proc-converter (passed by ref),
// which would make such calls faster.
if (metaBuilder.Error || !args.Signature.HasBlock)
{
return;
}
Expression rfcVariable = metaBuilder.GetTemporary(typeof(RuntimeFlowControl), "#rfc");
ParameterExpression methodUnwinder = metaBuilder.GetTemporary(typeof(MethodUnwinder), "#unwinder");
Expression resultVariable = metaBuilder.GetTemporary(typeof(object), "#result");
metaBuilder.Result = Ast.Block(
// initialize frame (RFC):
Ast.Assign(rfcVariable, Methods.CreateRfcForMethod.OpCall(AstUtils.Convert(args.GetBlockExpression(), typeof(Proc)))),
AstUtils.Try(
Ast.Assign(resultVariable, metaBuilder.Result)
).Filter(methodUnwinder, Ast.Equal(Ast.Field(methodUnwinder, MethodUnwinder.TargetFrameField), rfcVariable),
// return unwinder.ReturnValue;
Ast.Assign(resultVariable, Ast.Field(methodUnwinder, MethodUnwinder.ReturnValueField))
).Finally(
// we need to mark the RFC dead snce the block might escape and break later:
Ast.Assign(Ast.Field(rfcVariable, RuntimeFlowControl.IsActiveMethodField), Ast.Constant(false))
),
resultVariable
);
}
private LambdaExpression fromEnumerableLambda(Type from)
{
var input = Ex.Parameter(from, "input");
var eType = from.GetTypeInfo().ImplementedInterfaces
.Where(i => i.GenericTypeArguments.Length == 1 && i.GetGenericTypeDefinition() == typeof(IEnumerable <>))
.Select(i => i.GenericTypeArguments[0]).SingleOrDefault()
?? from.GetTypeInfo().GenericTypeArguments[0];
var res = Ex.Parameter(typeof(string), "res");
var result = Ex.Block(new[] { res },
Ex.Assign(res, Ex.Call((from mi in typeof(string).GetTypeInfo().GetDeclaredMethods(nameof(string.Join))
where mi.GetGenericArguments().Length == 1
let par = mi.GetParameters()
where par.Length == 2 &&
par[0].ParameterType == typeof(string) &&
par[1].ParameterType == typeof(IEnumerable <>).MakeGenericType(mi.GetGenericArguments()[0])
select mi).Single().MakeGenericMethod(eType),
Ex.Constant(Separators[0].ToString()), input)),
Ex.Condition(Ex.MakeBinary(Et.Equal, Ex.Property(res, nameof(string.Length)), Ex.Constant(0)),
NoResult(typeof(string)),
Result(typeof(string), res)));
var block = Ex.Condition(Ex.MakeBinary(Et.Equal, input, Ex.Default(from)),
NoResult(typeof(string)),
result);
var lambda = Ex.Lambda(block, input);
return(lambda);
}
/// <summary>
/// Declare and initialize a new variable.
/// </summary>
/// <typeparam name="T"></typeparam>
/// <param name="Name"></param>
/// <param name="Init"></param>
/// <returns></returns>
public ParamExpr DeclInit <T>(Scope Scope, string Name, LinqExpr Init)
{
ParamExpr p = Decl(Scope, typeof(T), Name);
code.Add(LinqExpr.Assign(p, Init));
return(p);
}
public ParamExpr DeclInit(Scope Scope, Expression Expr, Expression Init)
{
ParamExpr d = Decl(Scope, Expr);
Add(LinqExpr.Assign(d, Compile(Init)));
return(d);
}
// Define a function for running the simulation of a population system S with timestep
// dt. The number of timesteps and the data buffer are parameters of the defined function.
static Func <int, double[, ], int> DefineSimulate(double dt, PopulationSystem S)
{
CodeGen code = new CodeGen();
// Define a parameter for the current population x, and define mappings to the
// expressions defined above.
LinqExpr N = code.Decl <int>(Scope.Parameter, "N");
LinqExpr Data = code.Decl <double[, ]>(Scope.Parameter, "Data");
// Loop over the sample range requested. Note that this loop is a 'runtime' loop,
// while the rest of the loops nested in the body of this loop are 'compile time' loops.
LinqExpr n = code.DeclInit <int>("n", 1);
code.For(
() => { },
LinqExpr.LessThan(n, N),
() => code.Add(LinqExpr.PostIncrementAssign(n)),
() =>
{
// Define expressions representing the population of each species.
List <Expression> x = new List <Expression>();
for (int i = 0; i < S.N; ++i)
{
// Define a variable xi.
Expression xi = "x" + i.ToString();
x.Add(xi);
// xi = Data[n, i].
code.DeclInit(xi, LinqExpr.ArrayAccess(Data, LinqExpr.Subtract(n, LinqExpr.Constant(1)), LinqExpr.Constant(i)));
}
for (int i = 0; i < S.N; ++i)
{
// This list is the elements of the sum representing the i'th
// row of f, i.e. r_i + (A*x)_i.
Expression dx_dt = 1;
for (int j = 0; j < S.N; ++j)
{
dx_dt -= S.A[i, j] * x[j];
}
// Define dx_i/dt = x_i * f_i(x), as per the Lotka-Volterra equations.
dx_dt *= x[i] * S.r[i];
// Euler's method for x(t) is: x(t) = x(t - h) + h * x'(t - h).
Expression integral = x[i] + dt * dx_dt;
// Data[n, i] = Data[n - 1, i] + dt * dx_dt;
code.Add(LinqExpr.Assign(
LinqExpr.ArrayAccess(Data, n, LinqExpr.Constant(i)),
code.Compile(integral)));
}
});
code.Return(N);
// Compile the generated code.
LinqExprs.Expression <Func <int, double[, ], int> > expr = code.Build <Func <int, double[, ], int> >();
return(expr.Compile());
}
public void MiscellaneousExpression_Block()
{
var variable = Expr.Variable(typeof(bool));
var block = Expr.Block(Expr.Assign(variable, Expr.Constant(true)), variable);
UnsupportedExpr(Property.Active, active => Expr.Equal(active, block), ExpressionType.Block);
}
public static ExCoordF CartesianRot(ExTP erv) => (c, s, bpi, nrv, fxy) => {
var v2 = new TExV2();
return(Ex.Block(new ParameterExpression[] { v2 },
Ex.Assign(v2, erv(bpi)),
fxy(Ex.Subtract(Ex.Multiply(c, v2.x), Ex.Multiply(s, v2.y)),
Ex.Add(Ex.Multiply(s, v2.x), Ex.Multiply(c, v2.y))),
Expression.Empty()
));
};
/// <summary>
/// Home towards a target location at a fixed speed.
/// </summary>
/// <remarks>
/// Use with StopSampling to home for only a few seconds.
/// <para>This is primarily for use with non-rotational velocity.
/// Rotational use creates: contracting spirals (0,90), circle around player [90], expanding spiral (90,180).</para>
/// </remarks>
/// <param name="speed">Speed</param>
/// <param name="location">Target location</param>
/// <returns></returns>
public static ExTP VHome(ExBPY speed, ExTP location)
{
TExV2 l = new TExV2();
return(bpi => Ex.Block(new ParameterExpression[] { l },
Ex.Assign(l, location(bpi).Sub(bpi.loc)),
l.Mul(Ex.Divide(speed(bpi), Sqrt(Ex.Add(SqrMag(l), EPS))))
));
}
/// <summary>
/// Derive a Vector2 from a Vector3 by dropping the Z-component.
/// </summary>
public static ExTP TP(ExTP3 xyz)
{
var v3 = TExV3.Variable();
return(bpi => Ex.Block(new ParameterExpression[] { v3 },
Ex.Assign(v3, xyz(bpi)),
ExUtils.V2(v3.x, v3.y)
));
}
private static Func <PluginMetadata, object> MakeCreateFunc(Type type, string name)
{ // TODO: what do i want the visibiliy of Init methods to be?
var ctors = type.GetConstructors(BindingFlags.Public | BindingFlags.Instance)
.Select(c => (c, attr: c.GetCustomAttribute <InitAttribute>()))
.NonNull(t => t.attr)
.OrderByDescending(t => t.c.GetParameters().Length)
.Select(t => t.c).ToArray();
if (ctors.Length > 1)
{
Logger.loader.Warn($"Plugin {name} has multiple [Init] constructors. Picking the one with the most parameters.");
}
bool usingDefaultCtor = false;
var ctor = ctors.FirstOrDefault();
if (ctor == null)
{ // this is a normal case
usingDefaultCtor = true;
ctor = type.GetConstructor(Type.EmptyTypes);
if (ctor == null)
{
throw new InvalidOperationException($"{type.FullName} does not expose a public default constructor and has no constructors marked [Init]");
}
}
var initMethods = type.GetMethods(BindingFlags.Public | BindingFlags.Instance)
.Select(m => (m, attr: m.GetCustomAttribute <InitAttribute>()))
.NonNull(t => t.attr).Select(t => t.m).ToArray();
// verify that they don't have lifecycle attributes on them
foreach (var method in initMethods)
{
var attrs = method.GetCustomAttributes(typeof(IEdgeLifecycleAttribute), false);
if (attrs.Length != 0)
{
throw new InvalidOperationException($"Method {method} on {type.FullName} has both an [Init] attribute and a lifecycle attribute.");
}
}
var metaParam = Expression.Parameter(typeof(PluginMetadata), "meta");
var objVar = ExpressionEx.Variable(type, "objVar");
var persistVar = ExpressionEx.Variable(typeof(object), "persistVar");
var createExpr = Expression.Lambda <Func <PluginMetadata, object> >(
ExpressionEx.Block(new[] { objVar, persistVar },
initMethods
.Select(m => PluginInitInjector.InjectedCallExpr(m.GetParameters(), metaParam, persistVar, es => Expression.Call(objVar, m, es)))
.Prepend(ExpressionEx.Assign(objVar,
usingDefaultCtor
? Expression.New(ctor)
: PluginInitInjector.InjectedCallExpr(ctor.GetParameters(), metaParam, persistVar, es => Expression.New(ctor, es))))
.Append(Expression.Convert(objVar, typeof(object)))),
metaParam);
// TODO: since this new system will be doing a f**k load of compilation, maybe add FastExpressionCompiler
return(createExpr.Compile());
}
Exp Call(Exp obj, string name, Exp arg0)
{
return(Exp.Call(obj, Callvirt, Exp.Constant(name),
Exp.Block
(
Exp.Assign(Exp.Field(arg1, "self"), obj),
Exp.Assign(Exp.ArrayAccess(Exp.Field(arg1, "Input"), Exp.Constant(0)), arg0),
arg1
)));
}
public static TEx <T> Let <T, L>(string alias, Func <TExArgCtx, TEx <L> > content, Func <TEx <T> > inner, TExArgCtx applier)
{
var variabl = V <L>();
using var let = applier.Let(alias, variabl);
return(Ex.Block(new[] { variabl },
Ex.Assign(variabl, content(applier)),
inner()
));
}
internal static Expression InjectedCallExpr(ParameterInfo[] initParams, Expression meta, Expression persistVar, Func <IEnumerable <Expression>, Expression> exprGen)
{
var arr = ExpressionEx.Variable(typeof(object[]), "initArr");
return(ExpressionEx.Block(new[] { arr },
ExpressionEx.Assign(arr, Expression.Call(InjectMethod, Expression.Constant(initParams), meta, persistVar)),
exprGen(initParams
.Select(p => p.ParameterType)
.Select((t, i) => (Expression)Expression.Convert(
Expression.ArrayIndex(arr, Expression.Constant(i)), t)))));
}
/// <summary>
/// Multiply the x-component of a parametric equation by a function of input.
/// </summary>
/// <param name="f">Function of input</param>
/// <param name="tp">Parametric equation</param>
/// <returns></returns>
public static ExTP MultiplyX(ExBPY f, ExTP tp)
{
var v = TExV2.Variable();
var by = ExUtils.VFloat();
return(bpi => Ex.Block(
new[] { v, by },
Ex.Assign(v, tp(bpi)),
MulAssign(v.x, f(bpi)),
v
));
}
/// <summary>
/// Add a function of input to the y-component of a parametric equation.
/// </summary>
/// <param name="f">Function of input</param>
/// <param name="tp">Parametric equation</param>
/// <returns></returns>
public static ExTP AddY(ExBPY f, ExTP tp)
{
var v = TExV2.Variable();
var by = ExUtils.VFloat();
return(bpi => Ex.Block(
new[] { v, by },
Ex.Assign(v, tp(bpi)),
ExUtils.AddAssign(v.y, f(bpi)),
v
));
}