Changes in / [27fefeb6:321f55d]
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Jenkins/FullBuild (modified) (3 diffs)
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doc/aaron_comp_II/comp_II.tex (modified) (12 diffs)
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doc/aaron_comp_II/conversion_dag.eps (deleted)
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doc/aaron_comp_II/conversion_dag.odg (deleted)
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doc/aaron_comp_II/resolution_dag.eps (deleted)
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doc/aaron_comp_II/resolution_dag.odg (deleted)
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src/GenPoly/Box.cc (modified) (9 diffs)
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src/GenPoly/GenPoly.cc (modified) (3 diffs)
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src/GenPoly/GenPoly.h (modified) (2 diffs)
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src/GenPoly/InstantiateGeneric.cc (modified) (10 diffs)
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src/GenPoly/ScrubTyVars.cc (modified) (4 diffs)
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src/GenPoly/ScrubTyVars.h (modified) (3 diffs)
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src/SymTab/Autogen.cc (modified) (1 diff)
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src/examples/gc_no_raii/src/gc.h (modified) (1 diff)
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src/examples/gc_no_raii/test/gctest.c (modified) (1 diff)
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Jenkins/FullBuild
r27fefeb6 r321f55d 99 99 //attach the build log to the email 100 100 catch (Exception caughtError) { 101 echo('error caught')102 103 101 //rethrow error later 104 102 err = caughtError 105 103 106 104 //Store the result of the build log 107 currentBuild.result = 'FAILURE'105 currentBuild.result = "${status_prefix} FAILURE".trim() 108 106 109 107 //Send email to notify the failure 110 promote_ failure_email()108 promote_email(currentBuild.result) 111 109 } 112 110 … … 123 121 124 122 //Email notification on a full build failure 125 def promote_failure_email() { 126 echo('notifying users') 127 123 def promote_email(String status) { 128 124 //Since tokenizer doesn't work, figure stuff out from the environnement variables and command line 129 125 //Configurations for email format … … 138 134 - Status -------------------------------------------------------------- 139 135 140 PROMOTE FAILURE 136 PROMOTE FAILURE - ${status} 141 137 """ 142 138 -
doc/aaron_comp_II/comp_II.tex
r27fefeb6 r321f55d 37 37 \setlength{\headsep}{0.25in} 38 38 39 \usepackage{caption}40 \usepackage{subcaption}41 42 39 %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% 43 40 … … 64 61 65 62 %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% 66 67 \newcommand{\bigO}[1]{O\!\left( #1 \right)}68 63 69 64 \begin{document} … … 121 116 The ©identity© function above can be applied to any complete object type (or ``©otype©''). 122 117 The type variable ©T© is transformed into a set of additional implicit parameters to ©identity© which encode sufficient information about ©T© to create and return a variable of that type. 123 The current \CFA implementation passes the size and alignment of the type represented by an ©otype© parameter, as well as an assignment operator, constructor, copy constructor and destructor. 124 Here, the runtime cost of polymorphism is spread over each polymorphic call, due to passing more arguments to polymorphic functions; preliminary experiments have shown this overhead to be similar to \CC virtual function calls. 125 Determining if packaging all polymorphic arguments to a function into a virtual function table would reduce the runtime overhead of polymorphic calls is an open research question. 118 The current \CFA implementation passes the size and alignment of the type represented by an ©otype© parameter, as well as an assignment operator, constructor, copy constructor and destructor. 126 119 127 120 Since bare polymorphic types do not provide a great range of available operations, \CFA also provides a \emph{type assertion} mechanism to provide further information about a type: … … 136 129 double magic = four_times(10.5); // T is bound to double, uses (1) to satisfy type assertion 137 130 \end{lstlisting} 138 These type assertions may be either variable or function declarations thatdepend on a polymorphic type variable.139 ©four_times© can only be called with an argument for which there exists a function named ©twice© that can take that argument and return another value of the same type; a pointer to the appropriate ©twice© function ispassed as an additional implicit parameter to the call to ©four_times©.131 These type assertions may be either variable or function declarations which depend on a polymorphic type variable. 132 ©four_times© can only be called with an argument for which there exists a function named ©twice© that can take that argument and return another value of the same type; a pointer to the appropriate ©twice© function will be passed as an additional implicit parameter to the call to ©four_times©. 140 133 141 134 Monomorphic specializations of polymorphic functions can themselves be used to satisfy type assertions. 142 For instance, ©twice© could have been defined using the \CFA syntax for operator overloading as:143 \begin{lstlisting} 144 forall(otype S | { ®S ?+?(S, S);®})135 For instance, ©twice© could have been defined as below, using the \CFA syntax for operator overloading: 136 \begin{lstlisting} 137 forall(otype S | { S ?+?(S, S); }) 145 138 S twice(S x) { return x + x; } // (2) 146 139 \end{lstlisting} 147 This version of ©twice© w orksfor any type ©S© that has an addition operator defined for it, and it could have been used to satisfy the type assertion on ©four_times©.140 This version of ©twice© will work for any type ©S© that has an addition operator defined for it, and it could have been used to satisfy the type assertion on ©four_times©. 148 141 The compiler accomplishes this by creating a wrapper function calling ©twice // (2)© with ©S© bound to ©double©, then providing this wrapper function to ©four_times©\footnote{©twice // (2)© could also have had a type parameter named ©T©; \CFA specifies renaming of the type parameters, which would avoid the name conflict with the type variable ©T© of ©four_times©.}. 149 142 150 143 Finding appropriate functions to satisfy type assertions is essentially a recursive case of expression resolution, as it takes a name (that of the type assertion) and attempts to match it to a suitable declaration in the current scope. 151 If a polymorphic function can be used to satisfy one of its own type assertions, this recursion may not terminate, as it is possible that function isexamined as a candidate for its own type assertion unboundedly repeatedly.152 To avoid infinite loops, the current CFA compiler imposes a fixed limit on the possible depth of recursion, similar to that employed by most \CC compilers for template expansion; this restriction means that there are some semantically well-typed expressions thatcannot be resolved by CFA.153 One area of potential improvement this project proposes to investigate is the possibility of using the compiler's knowledge of the current set of declarations to more precicely determine when further type assertion satisfaction recursion doesnot produce a well-typed expression.144 If a polymorphic function can be used to satisfy one of its own type assertions, this recursion may not terminate, as it is possible that function will be examined as a candidate for its own type assertion unboundedly repeatedly. 145 To avoid infinite loops, the current CFA compiler imposes a fixed limit on the possible depth of recursion, similar to that employed by most \CC compilers for template expansion; this restriction means that there are some semantically well-typed expressions which cannot be resolved by CFA. 146 One area of potential improvement this project proposes to investigate is the possibility of using the compiler's knowledge of the current set of declarations to more precicely determine when further type assertion satisfaction recursion will not produce a well-typed expression. 154 147 155 148 \subsubsection{Traits} 156 149 \CFA provides \emph{traits} as a means to name a group of type assertions, as in the example below: 157 150 \begin{lstlisting} 158 ®trait has_magnitude(otype T)®{151 trait has_magnitude(otype T) { 159 152 bool ?<?(T, T); // comparison operator for T 160 153 T -?(T); // negation operator for T … … 175 168 \end{lstlisting} 176 169 177 Semantically, traits are simply a named lists of type assertions, but they may be used for many of the same purposes that interfaces in Java or abstract base classes in \CC are used for.170 Semantically, a trait is merely a named list of type assertions, but they can be used in many of the same situations where an interface in Java or an abstract base class in \CC would be used. 178 171 Unlike Java interfaces or \CC base classes, \CFA types do not explicitly state any inheritance relationship to traits they satisfy; this can be considered a form of structural inheritance, similar to interface implementation in Go, as opposed to the nominal inheritance model of Java and \CC. 179 Nominal inheritance can be simulated with traits using marker variables or functions: 180 \begin{lstlisting} 181 trait nominal(otype T) { 182 ®T is_nominal;® 183 }; 184 185 int is_nominal; // int now satisfies the nominal trait 186 { 187 char is_nominal; // char satisfies the nominal trait 188 } 189 // char no longer satisfies the nominal trait here 190 \end{lstlisting} 191 192 Traits, however, are significantly more powerful than nominal-inheritance interfaces; firstly, due to the scoping rules of the declarations which satisfy a trait's type assertions, a type may not satisfy a trait everywhere that the type is declared, as with ©char© and the ©nominal© trait above. 193 Secondly, traits may be used to declare a relationship between multiple types, a property which may be difficult or impossible to represent in nominal-inheritance type systems: 194 \begin{lstlisting} 195 trait pointer_like(®otype Ptr, otype El®) { 196 lvalue El *?(Ptr); // Ptr can be dereferenced into a modifiable value of type El 197 } 198 199 struct list { 200 int value; 201 list *next; // may omit "struct" on type names 202 }; 203 204 typedef list* list_iterator; 205 206 lvalue int *?( list_iterator it ) { 207 return it->value; 208 } 209 \end{lstlisting} 210 211 In the example above, ©(list_iterator, int)© satisfies ©pointer_like© by the given function, and ©(list_iterator, list)© also satisfies ©pointer_like© by the built-in pointer dereference operator. 212 While a nominal-inheritance system with associated types could model one of those two relationships by making ©El© an associated type of ©Ptr© in the ©pointer_like© implementation, few such systems could model both relationships simultaneously. 213 214 The flexibility of \CFA's implicit trait satisfaction mechanism provides user programmers with a great deal of power, but also blocks some optimization approaches for expression resolution. 215 The ability of types to begin to or cease to satisfy traits when declarations go into or out of scope makes caching of trait satisfaction judgements difficult, and the ability of traits to take multiple type parameters could lead to a combinatorial explosion of work in any attempt to pre-compute trait satisfaction relationships. 216 On the other hand, the addition of a nominal inheritance mechanism to \CFA's type system or replacement of \CFA's trait satisfaction system with a more object-oriented inheritance model and investigation of possible expression resolution optimizations for such a system may be an interesting avenue of further research. 172 % TODO talk about modelling of nominal inheritance with structural inheritance, possibility of investigating some resolver algorithms that require nominal 217 173 218 174 \subsection{Name Overloading} 219 In C, no more than one variable or function in the same scope may share the same name\footnote{Technically, C has multiple separated namespaces, one holding ©struct©, ©union©, and ©enum© tags, one holding labels, one holding typedef names, variable, function, and enumerator identifiers, and one for each ©struct© or ©union© type holding the field names.}, and variable or function declarations in inner scopes with the same name as a declaration in an outer scope hide the outer declaration. 220 This makes finding the proper declaration to match to a variable expression or function application a simple matter of symbol table lookup, which can be easily and efficiently implemented. 221 \CFA, on the other hand, allows overloading of variable and function names, so long as the overloaded declarations do not have the same type, avoiding the multiplication of variable and function names for different types common in the C standard library, as in the following example: 222 \begin{lstlisting} 223 #include <limits.h> 224 225 int max(int a, int b) { return a < b ? b : a; } // (1) 226 double max(double a, double b) { return a < b ? b : a; } // (2) 227 228 int max = INT_MAX; // (3) 229 double max = DBL_MAX; // (4) 230 231 max(7, -max); // uses (1) and (3), by matching int type of 7 232 max(max, 3.14); // uses (2) and (4), by matching double type of 3.14 233 234 max(max, -max); // ERROR: ambiguous 235 int m = max(max, -max); // uses (1) and (3) twice, by return type 236 \end{lstlisting} 237 238 The presence of name overloading in \CFA means that simple table lookup is insufficient to match identifiers to declarations, and a type matching algorithm must be part of expression resolution. 175 In C, no more than one function or variable in the same scope may share the same name, and function or variable declarations in inner scopes with the same name as a declaration in an outer scope hide the outer declaration. 176 This makes finding the proper declaration to match to a function application or variable expression a simple matter of symbol table lookup, which can be easily and efficiently implemented. 177 \CFA, on the other hand, allows overloading of variable and function names, so long as the overloaded declarations do not have the same type, avoiding the multiplication of function names for different types common in the C standard library, as in the following example: 178 \begin{lstlisting} 179 int three = 3; 180 double three = 3.0; 181 182 int thrice(int i) { return i * three; } // uses int three 183 double thrice(double d) { return d * three; } // uses double three 184 185 // thrice(three); // ERROR: ambiguous 186 int nine = thrice(three); // uses int thrice and three, based on return type 187 double nine = thrice(three); // uses double thrice and three, based on return type 188 \end{lstlisting} 189 190 The presence of name overloading in \CFA means that simple table lookup is not sufficient to match identifiers to declarations, and a type matching algorithm must be part of expression resolution. 239 191 240 192 \subsection{Implicit Conversions} … … 242 194 C does not have a traditionally-defined inheritance hierarchy of types, but the C standard's rules for the ``usual arithmetic conversions'' define which of the built-in types are implicitly convertable to which other types, and the relative cost of any pair of such conversions from a single source type. 243 195 \CFA adds to the usual arithmetic conversions rules for determining the cost of binding a polymorphic type variable in a function call; such bindings are cheaper than any \emph{unsafe} (narrowing) conversion, \eg ©int© to ©char©, but more expensive than any \emph{safe} (widening) conversion, \eg ©int© to ©double©. 244 245 196 The expression resolution problem, then, is to find the unique minimal-cost interpretation of each expression in the program, where all identifiers must be matched to a declaration and implicit conversions or polymorphic bindings of the result of an expression may increase the cost of the expression. 246 Note that which subexpression interpretation is minimal-cost may require contextual information to disambiguate. 247 For instance, in the example in the previous subsection, ©max(max, -max)© cannot be unambiguously resolved, but ©int m = max(max, -max);© has a single minimal-cost resolution. 248 ©int m = (int)max((double)max, -(double)max)© is also be a valid interpretation, but is not minimal-cost due to the unsafe cast from the ©double© result of ©max© to ©int© (the two ©double© casts function as type ascriptions selecting ©double max© rather than casts from ©int max© to ©double©, and as such are zero-cost). 197 Note that which subexpression interpretation is minimal-cost may require contextual information to disambiguate. 249 198 250 199 \subsubsection{User-generated Implicit Conversions} … … 252 201 Such a conversion system should be simple for user programmers to utilize, and fit naturally with the existing design of implicit conversions in C; ideally it would also be sufficiently powerful to encode C's usual arithmetic conversions itself, so that \CFA only has one set of rules for conversions. 253 202 254 Ditchfield ~\cite{Ditchfield:conversions} has laid out a framework for using polymorphic-conversion-constructor functions to create a directed acyclic graph (DAG) of conversions.203 Ditchfield\cite{Ditchfield:conversions} has laid out a framework for using polymorphic conversion constructor functions to create a directed acyclic graph (DAG) of conversions. 255 204 A monomorphic variant of these functions can be used to mark a conversion arc in the DAG as only usable as the final step in a conversion. 256 205 With these two types of conversion arcs, separate DAGs can be created for the safe and the unsafe conversions, and conversion cost can be represented as path length through the DAG. 257 \begin{figure}[h] 258 \centering 259 \includegraphics{conversion_dag} 260 \caption{A portion of the implicit conversion DAG for built-in types.} 261 \end{figure} 262 As can be seen in the example DAG above, there are either safe or unsafe paths between each of the arithmetic types listed; the ``final'' arcs are important both to avoid creating cycles in the signed-unsigned conversions, and to disambiguate potential diamond conversions (\eg, if the ©int© to ©unsigned int© conversion was not marked final there would be two length-two paths from ©int© to ©unsigned long©, and it would be impossible to choose which one; however, since the ©unsigned int© to ©unsigned long© arc can not be traversed after the final ©int© to ©unsigned int© arc, there is a single unambiguous conversion path from ©int© to ©unsigned long©). 263 264 Open research questions on this topic include: 265 \begin{itemize} 266 \item Can a conversion graph be generated that represents each allowable conversion in C with a unique minimal-length path such that the path lengths accurately represent the relative costs of the conversions? 267 \item Can such a graph representation can be usefully augmented to include user-defined types as well as built-in types? 268 \item Can the graph can be efficiently represented and used in the expression resolver? 269 \end{itemize} 206 Open research questions on this topic include whether a conversion graph can be generated that represents each allowable conversion in C with a unique minimal-length path, such that the path lengths accurately represent the relative costs of the conversions, whether such a graph representation can be usefully augmented to include user-defined types as well as built-in types, and whether the graph can be efficiently represented and included in the expression resolver. 270 207 271 208 \subsection{Constructors and Destructors} 272 209 Rob Shluntz, a current member of the \CFA research team, has added constructors and destructors to \CFA. 273 Each type has an overridable default-generated zero-argument constructor, copy constructor, assignment operator, and destructor; for ©struct© types these functions each call their equivalents on each field of the ©struct©.210 Each type has an overridable default-generated zero-argument constructor, copy constructor, assignment operator, and destructor; for struct types these functions each call their equivalents on each field of the struct. 274 211 This affects expression resolution because an ©otype© type variable ©T© implicitly adds four type assertions, one for each of these four functions, so assertion resolution is pervasive in \CFA polymorphic functions, even those without any explicit type assertions. 275 The following example shows the implicitly-generated code in green:276 \begin{lstlisting}277 struct kv {278 int key;279 char *value;280 };281 282 ¢void ?{}(kv *this) {283 ?{}(&this->key);284 ?{}(&this->value);285 }286 void ?{}(kv *this, kv that) {287 ?{}(&this->key, that.key);288 ?{}(&this->value, that.value);289 }290 kv ?=?(kv *this, kv that) {291 ?=?(&this->key, that.key);292 ?=?(&this->value, that.value);293 return *this;294 }295 void ^?{}(kv *this) {296 ^?{}(&this->key);297 ^?{}(&this->value);298 }¢299 300 forall(otype T ¢| { void ?{}(T*); void ?{}(T*, T); T ?=?(T*, T); void ^?{}(T*); }¢)301 void foo(T);302 \end{lstlisting}303 212 304 213 \subsection{Generic Types} 305 214 I have already added a generic type capability to \CFA, designed to efficiently and naturally integrate with \CFA's existing polymorphic functions. 306 A generic type can be declared by placing a ©forall© specifier on a ©struct© or ©union©declaration, and instantiated using a parenthesized list of types after the type name:215 A generic type can be declared by placing a ©forall© specifier on a struct or union declaration, and instantiated using a parenthesized list of types after the type name: 307 216 \begin{lstlisting} 308 217 forall(otype R, otype S) struct pair { … … 320 229 The default-generated constructors, destructor and assignment operator for a generic type are polymorphic functions with the same list of type parameters as the generic type definition. 321 230 322 Aside from giving users the ability to create more parameterized types than just the built-in pointer, array and function types, the combination of generic types with polymorphic functions and implicit conversions makes the edge case where the resolver may enter an infinite loop much more common, as in the following code example: 323 \begin{lstlisting} 324 forall(otype T) struct box { T x; }; 325 326 void f(void*); // (1) 327 328 forall(otype S) 329 void f(box(S)* b) { // (2) 330 f(®(void*)0®); 331 } 332 \end{lstlisting} 333 334 The loop in the resolver happens as follows: 231 Aside from giving users the ability to create more parameterized types than just the built-in pointer, array and function types, the combination of generic types with polymorphic functions and implicit conversions makes the edge case where a polymorphic function can match its own assertions much more common, as follows: 335 232 \begin{itemize} 336 \item Since there is an implicit conversion from ©void*© to any pointer type, the highlighted expression can be interpreted as either a ©void*©, matching ©f // (1)©, or a ©box(S)*© for some type ©S©, matching ©f // (2)©. 337 \item To determine the cost of the ©box(S)© interpretation, a type must be found for ©S© which satisfies the ©otype© implicit type assertions (assignment operator, default and copy constructors, and destructor); one option is ©box(S2)© for some type ©S2©. 338 \item The assignment operator, default and copy constructors, and destructor of ©box(T)© are also polymorphic functions, each of which require the type parameter ©T© to have an assignment operator, default and copy constructors, and destructor. When choosing an interpretation for ©S2©, one option is ©box(S3)©, for some type ©S3©. 339 \item The previous step repeats until stopped, with four times as much work performed at each step. 233 \item Given an expression in an untyped context, such as a top-level function call with no assignment of return values, apply a polymorphic implicit conversion to the expression that can produce multiple types (the built-in conversion from ©void*© to any other pointer type is one, but not the only). 234 \item When attempting to use a generic type with ©otype© parameters (such as ©box© above) for the result type of the expression, the resolver will also need to decide what type to use for the ©otype© parameters on the constructors and related functions, and will have no constraints on what they may be. 235 \item Attempting to match some yet-to-be-determined specialization of the generic type to this ©otype© parameter will create a recursive case of the default constructor, \etc matching their own type assertions, creating an unboundedly deep nesting of the generic type inside itself. 340 236 \end{itemize} 341 This problem can occur in any resolution context where a polymorphic function that can satisfy its own type assertions is required for a possible interpretation of an expression with no constraints on its type, and is thus not limited to combinations of generic types with ©void*© conversions, though constructors for generic types often satisfy their own assertions and a polymorphic conversion such as the ©void*© conversion to a polymorphic variable can create an expression with no constraints on its type. 342 As discussed above, the \CFA expression resolver must handle this possible infinite recursion somehow, and it occurs fairly naturally in code like the above that uses generic types. 237 As discussed above, any \CFA expression resolver must handle this possible infinite recursion somehow, but the combination of generic types with other language features makes this particular edge case occur somewhat frequently in user code. 343 238 344 239 \subsection{Tuple Types} 345 \CFA adds \emph{tuple types} to C, a syntactic facility for referring to lists of values anonymously orwith a single identifier.346 A n identifiermay name a tuple, and a function may return one.240 \CFA adds \emph{tuple types} to C, a facility for referring to multiple values with a single identifier. 241 A variable may name a tuple, and a function may return one. 347 242 Particularly relevantly for resolution, a tuple may be implicitly \emph{destructured} into a list of values, as in the call to ©swap© below: 348 243 \begin{lstlisting} … … 353 248 354 249 x = swap( x ); // destructure [char, char] x into two elements of parameter list 355 // can not use int x for parameter, not enough arguments to swap250 // can't use int x for parameter, not enough arguments to swap 356 251 \end{lstlisting} 357 252 Tuple destructuring means that the mapping from the position of a subexpression in the argument list to the position of a paramter in the function declaration is not straightforward, as some arguments may be expandable to different numbers of parameters, like ©x© above. … … 361 256 Given some type ©T©, a ©T&© (``reference to ©T©'') is essentially an automatically dereferenced pointer; with these semantics most of the C standard's discussions of lvalues can be expressed in terms of references instead, with the benefit of being able to express the difference between the reference and non-reference version of a type in user code. 362 257 References preserve C's existing qualifier-dropping lvalue-to-rvalue conversion (\eg a ©const volatile int&© can be implicitly converted to a bare ©int©); the reference proposal also adds a rvalue-to-lvalue conversion to \CFA, implemented by storing the value in a new compiler-generated temporary and passing a reference to the temporary. 363 These two conversions can chain, producing a qualifier-dropping conversion for references, for instance converting a reference to a ©const int© into a reference to a non-©const int© by copying the originally refered to value into a fresh temporary and taking a reference to this temporary, as below: 364 \begin{lstlisting} 365 const int magic = 42; 366 367 void inc_print( int& x ) { printf("%d\n", ++x); } 368 369 print_inc( magic ); // legal; implicitly generated code in green below: 370 371 ¢int tmp = magic;¢ // copies to safely strip const-qualifier 372 ¢print_inc( tmp );¢ // tmp is incremented, magic is unchanged 373 \end{lstlisting} 258 These two conversions can chain, producing a qualifier-dropping conversion for references, for instance converting a reference to a ©const int© into a reference to a non-©const int© by copying the originally refered to value into a fresh temporary and taking a reference to this temporary. 374 259 These reference conversions may also chain with the other implicit type conversions. 375 260 The main implication of this for expression resolution is the multiplication of available implicit conversions, though in a restricted context that may be able to be treated efficiently as a special case. 376 261 377 \subsection{ SpecialLiteral Types}378 Another proposal currently under consideration for the \CFA type-system is assigning special types to the literal values ©0© and ©1©. 379 Implicit conversions from these types allow ©0© and ©1© to be considered as values of many different types, depending on context, allowing expression desugarings like ©if ( x ) {}© $\Rightarrow$ ©if ( x != 0 ) {}© to be implemented efficiently and precicely.380 This approachis a generalization of C's existing behaviour of treating ©0© as either an integer zero or a null pointer constant, and treating either of those values as boolean false.381 The main implication for expression resolution is that the frequently encountered expressions ©0© and ©1© may have a largenumber of valid interpretations.262 \subsection{Literal Types} 263 Another proposal currently under consideration for the \CFA type-system is assigning special types to the literal values ©0© and ©1©.%, say ©zero_t© and ©one_t©. 264 Implicit conversions from these types would allow ©0© and ©1© to be considered as values of many different types, depending on context, allowing expression desugarings like ©if ( x ) {}© $\Rightarrow$ ©if ( x != 0 ) {}© to be implemented efficiently and precicely. 265 This is a generalization of C's existing behaviour of treating ©0© as either an integer zero or a null pointer constant, and treating either of those values as boolean false. 266 The main implication for expression resolution is that the frequently encountered expressions ©0© and ©1© may have a significant number of valid interpretations. 382 267 383 268 \subsection{Deleted Function Declarations} … … 386 271 int somefn(char) = delete; 387 272 \end{lstlisting} 388 This feature is typically used in \CCeleven to make a type non-copyable by deleting its copy constructor and assignment operator, or forbidding some interpretations of a polymorphic function by specifically deleting the forbidden overloads.389 273 To add a similar feature to \CFA would involve including the deleted function declarations in expression resolution along with the normal declarations, but producing a compiler error if the deleted function was the best resolution. 390 274 How conflicts should be handled between resolution of an expression to both a deleted and a non-deleted function is a small but open research question. 391 275 392 276 \section{Expression Resolution} 393 The expression resolution problem is determining an optimal match between some combination of argument interpretations and the parameter list of some overloaded instance of a function; the argument interpretations are produced by recursive invocations of expression resolution, where the base case is zero-argument functions (which are, for purposes of this discussion, semantically equivalent to named variables or constant literal expressions). 394 Assuming that the matching between a function's parameter list and a combination of argument interpretations can be done in $\bigO{p^k}$ time, where $p$ is the number of parameters and $k$ is some positive number, if there are $\bigO{i}$ valid interpretations for each subexpression, there will be $\bigO{i}$ candidate functions and $\bigO{i^p}$ possible argument combinations for each expression, so for a single recursive call expression resolution takes $\bigO{i^{p+1} \cdot p^k}$ time if it must compare all combinations, or $\bigO{i(p+1) \cdot p^k}$ time if argument-parameter matches can be chosen independently of each other. 395 Given these bounds, resolution of a single top-level expression tree of depth $d$ takes $\bigO{i^{p+1} \cdot p^{k \cdot d}}$ time under full-combination matching, or $\bigO{i(p+1) \cdot p^{k \cdot d}}$ time for independent-parameter matching\footnote{A call tree has leaves at depth $\bigO{d}$, and each internal node has $\bigO{p}$ fan-out, producing $\bigO{p^d}$ total recursive calls.}. 396 397 Expression resolution is somewhat unavoidably exponential in $d$, the depth of the expression tree, and if arguments cannot be matched to parameters independently of each other, expression resolution is also exponential in $p$. 398 However, both $d$ and $p$ are fixed by the user programmer, and generally bounded by reasonably small constants. 399 $k$, on the other hand, is mostly dependent on the representation of types in the system and the efficiency of type assertion checking; if a candidate argument combination can be compared to a function parameter list in linear time in the length of the list (\ie $k = 1$), then the $p^{k \cdot d}$ factor is linear in the input size of the source code for the expression, otherwise the resolution algorithm exibits sub-linear performance scaling on code containing more-deeply nested expressions. 277 The expression resolution problem is essentially to determine an optimal matching between some combination of argument interpretations and the parameter list of some overloaded instance of a function; the argument interpretations are produced by recursive invocations of expression resolution, where the base case is zero-argument functions (which are, for purposes of this discussion, semantically equivalent to named variables or constant literal expressions). 278 Assuming that the matching between a function's parameter list and a combination of argument interpretations can be done in $O(p^k)$ time, where $p$ is the number of parameters and $k$ is some positive number, if there are $O(i)$ valid interpretations for each subexpression, there will be $O(i)$ candidate functions and $O(i^p)$ possible argument combinations for each expression, so a single recursive call to expression resolution will take $O(i^{p+1} \cdot p^k)$ time if it compares all combinations. 279 Given this bound, resolution of a single top-level expression tree of depth $d$ takes $O(i^{p+1} \cdot p^{k \cdot d})$ time\footnote{The call tree will have leaves at depth $O(d)$, and each internal node will have $O(p)$ fan-out, producing $O(p^d)$ total recursive calls.}. 280 Expression resolution is somewhat unavoidably exponential in $p$, the number of function parameters, and $d$, the depth of the expression tree, but these values are fixed by the user programmer, and generally bounded by reasonably small constants. 281 $k$, on the other hand, is mostly dependent on the representation of types in the system and the efficiency of type assertion checking; if a candidate argument combination can be compared to a function parameter list in linear time in the length of the list (\ie $k = 1$), then the $p^{k \cdot d}$ term is linear in the input size of the source code for the expression, otherwise the resolution algorithm will exibit sub-linear performance scaling on code containing more-deeply nested expressions. 400 282 The number of valid interpretations of any subexpression, $i$, is bounded by the number of types in the system, which is possibly infinite, though practical resolution algorithms for \CFA must be able to place some finite bound on $i$, possibly at the expense of type-system completeness. 401 283 402 The research goal of this project is to develop a performant expression resolver for \CFA; this analysis suggests t hreeprimary areas of investigation to accomplish that end.403 The first area of investigation is efficient argument-parameter matching; Bilson~\cite{Bilson03} mentions significant optimization opportunities available in the current literature to improve on the existing CFA compiler.284 The research goal of this project is to develop a performant expression resolver for \CFA; this analysis suggests two primary areas of investigation to accomplish that end. 285 The first is efficient argument-parameter matching; Bilson\cite{Bilson03} mentions significant optimization opportunities available in the current literature to improve on the existing CFA compiler. 404 286 %TODO: look up and lit review 405 The second area of investigation is minimizing dependencies between argument-parameter matches; the current CFA compiler attempts to match entire argument combinations against functions at once, potentially attempting to match the same argument against the same parameter multiple times. 406 Whether the feature set of \CFA admits an expression resolution algorithm where arguments can be matched to parameters independently of other arguments in the same function application is an area of open research; polymorphic type paramters produce enough of a cross-argument dependency that the problem is not trivial. 407 If cross-argument resolution dependencies cannot be completely eliminated, effective caching strategies to reduce duplicated work between equivalent argument-parameter matches in different combinations may mitigate the asymptotic defecits of the whole-combination matching approach. 408 The final area of investigation is heuristics and algorithmic approaches to reduce the number of argument interpretations considered in the common case; if argument-parameter matches cannot be made independent, even small reductions in $i$ should yield significant reductions in the $i^{p+1}$ resolver runtime factor. 409 287 The second, and likely more fruitful, area of investigation is heuristics and algorithmic approaches to reduce the number of argument interpretations considered in the common case; given the large ($p+1$) exponent on number of interpretations considered in the runtime analysis, even small reductions here could have a significant effect on overall resolver runtime. 410 288 The discussion below presents a number of largely orthagonal axes for expression resolution algorithm design to be investigated, noting prior work where applicable. 411 Though some of the proposed improvements to the expression resolution algorithm are based on heuristics rather than asymptoticly superior algorithms, it should be noted that user programmers often employ idioms and other programming patterns to reduce the mental burden of producing correct code, and if these patterns can be identified and exploited by the compiler then the significant reduction in expression resolution time for common, idiomatic expressions should result in lower total compilation time even for code including difficult-to-resolve expressions that push the expression resolver to its theoretical worst case.412 289 413 290 \subsection{Argument-Parameter Matching} 414 The first axis for consideration is argument-parameter matching direction --- whether the type matching for a candidate function to a set of candidate arguments is directed by the argument types or the parameter types. 415 All expression resolution algorithms form a DAG of interpretations, some explicitly, some implicitly; in this DAG, arcs point from function-call interpretations to argument interpretations, as below: 416 \begin{figure}[h] 417 \centering 418 \begin{subfigure}[h]{2in} 419 \begin{lstlisting} 420 int *p; // $p_i$ 421 char *p; // $p_c$ 422 423 double *f(int*, int*); // $f_d$ 424 char *f(char*, char*); // $f_c$ 425 426 f( f( p, p ), p ); 427 \end{lstlisting} 428 \end{subfigure}~\begin{subfigure}[h]{2in} 429 \includegraphics{resolution_dag} 430 \end{subfigure} 431 \caption{Resolution DAG for a simple expression. Functions that do not have a valid argument matching are covered with an \textsf{X}.}\label{fig:res_dag} 432 \end{figure} 433 434 Note that some interpretations may be part of more than one super-interpretation, as with $p_i$ in the bottom row, while some valid subexpression interpretations, like $f_d$ in the middle row, are not used in any interpretation of their containing expression. 435 436 \subsubsection{Argument-directed (Bottom-up)} 437 Baker's algorithm for expression resolution~\cite{Baker82} pre-computes argument candidates, from the leaves of the expression tree up. 291 The first axis we consider is argument-parameter matching --- whether the type matching for a candidate function to a set of candidate arguments is directed by the argument types or the parameter types. 292 293 \subsubsection{Argument-directed (``Bottom-up'')} 294 Baker's algorithm for expression resolution\cite{Baker82} pre-computes argument candidates, from the leaves of the expression tree up. 438 295 For each candidate function, Baker attempts to match argument types to parameter types in sequence, failing if any parameter cannot be matched. 439 296 440 Bilson ~\cite{Bilson03} similarly pre-computes argument candidates in the original \CFA compiler, but then explicitly enumerates all possible argument combinations for a multi-parameter function; these argument combinations are matched to the parameter types of the candidate function as a unit rather than individual arguments.441 This approach is less efficient than Baker's approach, as the same argument may be compared to the same parameter many times, but allows a more straightforward handling of polymorphic type-binding and multiple return-types.442 It is possible the efficiency losses here relative to Baker could be significantly reduced by keeping a memoized cache of argument-parameter type comparisons and reading previously-seen argument-parameter matches from this cache rather than recomputing them.443 444 \subsubsection{Parameter-directed ( Top-down)}445 Unlike Baker and Bilson, Cormack's algorithm ~\cite{Cormack81} requests argument candidates thatmatch the type of each parameter of each candidate function, from the top-level expression down; memoization of these requests is presented as an optimization.297 Bilson\cite{Bilson03} similarly pre-computes argument candidates in the original \CFA compiler, but then explicitly enumerates all possible argument combinations for a multi-parameter function; these argument combinations are matched to the parameter types of the candidate function as a unit rather than individual arguments. 298 This is less efficient than Baker's approach, as the same argument may be compared to the same parameter many times, but allows a more straightforward handling of polymorphic type binding and multiple return types. 299 It is possible the efficiency losses here relative to Baker could be significantly reduced by application of memoization to the argument-parameter type comparisons. 300 301 \subsubsection{Parameter-directed (``Top-down'')} 302 Unlike Baker and Bilson, Cormack's algorithm\cite{Cormack81} requests argument candidates which match the type of each parameter of each candidate function, from the top-level expression down; memoization of these requests is presented as an optimization. 446 303 As presented, this algorithm requires the result of the expression to have a known type, though an algorithm based on Cormack's could reasonably request a candidate set of any return type, though such a set may be quite large. 447 304 448 305 \subsubsection{Hybrid} 449 306 This proposal includes the investigation of hybrid top-down/bottom-up argument-parameter matching. 450 A reasonable hybrid approach might take a top-down approach when the expression to be matched has a fixed type, and a bottom-up approach in untyped contexts. 451 This approach may involve switching from one type to another at different levels of the expression tree. 452 For instance: 307 A reasonable hybrid approach might be to take a top-down approach when the expression to be matched is known to have a fixed type, and a bottom-up approach in untyped contexts. 308 This may include switches from one type to another at different levels of the expression tree, for instance: 453 309 \begin{lstlisting} 454 310 forall(otype T) … … 459 315 int x = f( f( '!' ) ); 460 316 \end{lstlisting} 461 The outer call to ©f© must have a return type that is (implicitly convertable to) ©int©, so a top-down approach is used to select \textit{(1)} as the proper interpretation of ©f©. \textit{(1)}'s parameter ©x©, however, is an unbound type variable, and can thus take a value of any complete type, providing no guidance for the choice of candidate for the inner call to ©f©. The leaf expression ©'!'©, however, determines a zero-cost interpretation of the inner ©f© as \textit{(2)}, providing a minimal-cost expression resolution where ©T© is bound to ©void*©. 462 463 Deciding when to switch between bottom-up and top-down resolution to minimize wasted work in a hybrid algorithm is a necessarily heuristic process, and though finding good heuristics for which subexpressions to swich matching strategies on is an open question, one reasonable approach might be to set a threshold $t$ for the number of candidate functions, and to use top-down resolution for any subexpression with fewer than $t$ candidate functions, to minimize the number of unmatchable argument interpretations computed, but to use bottom-up resolution for any subexpression with at least $t$ candidate functions, to reduce duplication in argument interpretation computation between the different candidate functions. 464 465 \subsubsection{Common Subexpression Caching} 466 With any of these argument-parameter approaches, it may be a useful optimization to cache the resolution results for common subexpressions; in Figure~\ref{fig:res_dag} this optimization would result in the list of interpretations $[p_c, p_i]$ for ©p© only being calculated once, and re-used for each of the three instances of ©p©. 317 Here, the outer call to ©f© must have a return type that is (implicitly convertable to) ©int©, so a top-down approach could be used to select \textit{(1)} as the proper interpretation of ©f©. \textit{(1)}'s parameter ©x© here, however, is an unbound type variable, and can thus take a value of any complete type, providing no guidance for the choice of candidate for the inner ©f©. The leaf expression ©'!'©, however, gives us a zero-cost interpretation of the inner ©f© as \textit{(2)}, providing a minimal-cost expression resolution where ©T© is bound to ©void*©. 318 319 Deciding when to switch between bottom-up and top-down resolution in a hybrid algorithm is a necessarily heuristic process, and though finding good heuristics for it is an open question, one reasonable approach might be to switch from top-down to bottom-up when the number of candidate functions exceeds some threshold. 467 320 468 321 \subsection{Implicit Conversion Application} 469 Baker's and Cormack'salgorithms do not account for implicit conversions\footnote{Baker does briefly comment on an approach for handling implicit conversions.}; both assume that there is at most one valid interpretation of a given expression for each distinct type.322 Baker's\cite{Baker82} and Cormack's\cite{Cormack81} algorithms do not account for implicit conversions\footnote{Baker does briefly comment on an approach for handling implicit conversions.}; both assume that there is at most one valid interpretation of a given expression for each distinct type. 470 323 Integrating implicit conversion handling into their algorithms provides some choice of implementation approach. 471 324 -
src/GenPoly/Box.cc
r27fefeb6 r321f55d 104 104 Type *replaceWithConcrete( ApplicationExpr *appExpr, Type *type, bool doClone = true ); 105 105 /// wraps a function application returning a polymorphic type with a new temporary for the out-parameter return value 106 Expression *add DynRetParam( ApplicationExpr *appExpr, FunctionType *function, ReferenceToType *polyType, std::list< Expression *>::iterator &arg );106 Expression *addPolyRetParam( ApplicationExpr *appExpr, FunctionType *function, ReferenceToType *polyType, std::list< Expression *>::iterator &arg ); 107 107 Expression *applyAdapter( ApplicationExpr *appExpr, FunctionType *function, std::list< Expression *>::iterator &arg, const TyVarMap &exprTyVars ); 108 108 void boxParam( Type *formal, Expression *&arg, const TyVarMap &exprTyVars ); … … 661 661 // process polymorphic return value 662 662 retval = 0; 663 if ( is DynRet( functionDecl->get_functionType() ) && functionDecl->get_linkage() == LinkageSpec::Cforall ) {663 if ( isPolyRet( functionDecl->get_functionType() ) && functionDecl->get_linkage() == LinkageSpec::Cforall ) { 664 664 retval = functionDecl->get_functionType()->get_returnVals().front(); 665 665 … … 868 868 } 869 869 870 Expression *Pass1::add DynRetParam( ApplicationExpr *appExpr, FunctionType *function, ReferenceToType *dynType, std::list< Expression *>::iterator &arg ) {870 Expression *Pass1::addPolyRetParam( ApplicationExpr *appExpr, FunctionType *function, ReferenceToType *polyType, std::list< Expression *>::iterator &arg ) { 871 871 assert( env ); 872 Type *concrete = replaceWithConcrete( appExpr, dynType );872 Type *concrete = replaceWithConcrete( appExpr, polyType ); 873 873 // add out-parameter for return value 874 874 return addRetParam( appExpr, function, concrete, arg ); … … 877 877 Expression *Pass1::applyAdapter( ApplicationExpr *appExpr, FunctionType *function, std::list< Expression *>::iterator &arg, const TyVarMap &tyVars ) { 878 878 Expression *ret = appExpr; 879 // if ( ! function->get_returnVals().empty() && isPolyType( function->get_returnVals().front()->get_type(), tyVars ) ) { 880 if ( isDynRet( function, tyVars ) ) { 879 if ( ! function->get_returnVals().empty() && isPolyType( function->get_returnVals().front()->get_type(), tyVars ) ) { 881 880 ret = addRetParam( appExpr, function, function->get_returnVals().front()->get_type(), arg ); 882 881 } // if … … 969 968 // actually make the adapter type 970 969 FunctionType *adapter = adaptee->clone(); 971 // if ( ! adapter->get_returnVals().empty() && isPolyType( adapter->get_returnVals().front()->get_type(), tyVars ) ) { 972 if ( isDynRet( adapter, tyVars ) ) { 970 if ( ! adapter->get_returnVals().empty() && isPolyType( adapter->get_returnVals().front()->get_type(), tyVars ) ) { 973 971 makeRetParm( adapter ); 974 972 } // if … … 1032 1030 addAdapterParams( adapteeApp, arg, param, adapterType->get_parameters().end(), realParam, tyVars ); 1033 1031 bodyStmt = new ExprStmt( noLabels, adapteeApp ); 1034 // } else if ( isPolyType( adaptee->get_returnVals().front()->get_type(), tyVars ) ) { 1035 } else if ( isDynType( adaptee->get_returnVals().front()->get_type(), tyVars ) ) { 1032 } else if ( isPolyType( adaptee->get_returnVals().front()->get_type(), tyVars ) ) { 1036 1033 // return type T 1037 1034 if ( (*param)->get_name() == "" ) { … … 1280 1277 TyVarMap exprTyVars( (TypeDecl::Kind)-1 ); 1281 1278 makeTyVarMap( function, exprTyVars ); 1282 ReferenceToType * dynRetType = isDynRet( function, exprTyVars);1283 1284 if ( dynRetType ) {1285 ret = add DynRetParam( appExpr, function, dynRetType, arg );1279 ReferenceToType *polyRetType = isPolyRet( function ); 1280 1281 if ( polyRetType ) { 1282 ret = addPolyRetParam( appExpr, function, polyRetType, arg ); 1286 1283 } else if ( needsAdapter( function, scopeTyVars ) ) { 1287 1284 // std::cerr << "needs adapter: "; … … 1293 1290 arg = appExpr->get_args().begin(); 1294 1291 1295 passTypeVars( appExpr, dynRetType, arg, exprTyVars );1292 passTypeVars( appExpr, polyRetType, arg, exprTyVars ); 1296 1293 addInferredParams( appExpr, function, arg, exprTyVars ); 1297 1294 … … 1580 1577 1581 1578 // move polymorphic return type to parameter list 1582 if ( is DynRet( funcType ) ) {1579 if ( isPolyRet( funcType ) ) { 1583 1580 DeclarationWithType *ret = funcType->get_returnVals().front(); 1584 1581 ret->set_type( new PointerType( Type::Qualifiers(), ret->get_type() ) ); -
src/GenPoly/GenPoly.cc
r27fefeb6 r321f55d 23 23 24 24 namespace GenPoly { 25 bool needsAdapter( FunctionType *adaptee, const TyVarMap &tyVars ) { 26 if ( ! adaptee->get_returnVals().empty() && isPolyType( adaptee->get_returnVals().front()->get_type(), tyVars ) ) { 27 return true; 28 } // if 29 for ( std::list< DeclarationWithType* >::const_iterator innerArg = adaptee->get_parameters().begin(); innerArg != adaptee->get_parameters().end(); ++innerArg ) { 30 if ( isPolyType( (*innerArg)->get_type(), tyVars ) ) { 31 return true; 32 } // if 33 } // for 34 return false; 35 } 36 37 ReferenceToType *isPolyRet( FunctionType *function ) { 38 if ( ! function->get_returnVals().empty() ) { 39 TyVarMap forallTypes( (TypeDecl::Kind)-1 ); 40 makeTyVarMap( function, forallTypes ); 41 return (ReferenceToType*)isPolyType( function->get_returnVals().front()->get_type(), forallTypes ); 42 } // if 43 return 0; 44 } 45 25 46 namespace { 26 47 /// Checks a parameter list for polymorphic parameters; will substitute according to env if present … … 43 64 return false; 44 65 } 45 46 /// Checks a parameter list for dynamic-layout parameters from tyVars; will substitute according to env if present47 bool hasDynParams( std::list< Expression* >& params, const TyVarMap &tyVars, const TypeSubstitution *env ) {48 for ( std::list< Expression* >::iterator param = params.begin(); param != params.end(); ++param ) {49 TypeExpr *paramType = dynamic_cast< TypeExpr* >( *param );50 assert(paramType && "Aggregate parameters should be type expressions");51 if ( isDynType( paramType->get_type(), tyVars, env ) ) return true;52 }53 return false;54 }55 66 } 56 67 … … 90 101 } 91 102 return 0; 92 }93 94 Type *isDynType( Type *type, const TyVarMap &tyVars, const TypeSubstitution *env ) {95 type = replaceTypeInst( type, env );96 97 if ( TypeInstType *typeInst = dynamic_cast< TypeInstType * >( type ) ) {98 auto var = tyVars.find( typeInst->get_name() );99 if ( var != tyVars.end() && var->second == TypeDecl::Any ) {100 return type;101 }102 } else if ( StructInstType *structType = dynamic_cast< StructInstType* >( type ) ) {103 if ( hasDynParams( structType->get_parameters(), tyVars, env ) ) return type;104 } else if ( UnionInstType *unionType = dynamic_cast< UnionInstType* >( type ) ) {105 if ( hasDynParams( unionType->get_parameters(), tyVars, env ) ) return type;106 }107 return 0;108 }109 110 ReferenceToType *isDynRet( FunctionType *function, const TyVarMap &forallTypes ) {111 if ( function->get_returnVals().empty() ) return 0;112 113 return (ReferenceToType*)isDynType( function->get_returnVals().front()->get_type(), forallTypes );114 }115 116 ReferenceToType *isDynRet( FunctionType *function ) {117 if ( function->get_returnVals().empty() ) return 0;118 119 TyVarMap forallTypes( (TypeDecl::Kind)-1 );120 makeTyVarMap( function, forallTypes );121 return (ReferenceToType*)isDynType( function->get_returnVals().front()->get_type(), forallTypes );122 }123 124 bool needsAdapter( FunctionType *adaptee, const TyVarMap &tyVars ) {125 // if ( ! adaptee->get_returnVals().empty() && isPolyType( adaptee->get_returnVals().front()->get_type(), tyVars ) ) {126 // return true;127 // } // if128 if ( isDynRet( adaptee, tyVars ) ) return true;129 130 for ( std::list< DeclarationWithType* >::const_iterator innerArg = adaptee->get_parameters().begin(); innerArg != adaptee->get_parameters().end(); ++innerArg ) {131 // if ( isPolyType( (*innerArg)->get_type(), tyVars ) ) {132 if ( isDynType( (*innerArg)->get_type(), tyVars ) ) {133 return true;134 } // if135 } // for136 return false;137 103 } 138 104 -
src/GenPoly/GenPoly.h
r27fefeb6 r321f55d 31 31 namespace GenPoly { 32 32 typedef ErasableScopedMap< std::string, TypeDecl::Kind > TyVarMap; 33 34 /// A function needs an adapter if it returns a polymorphic value or if any of its 35 /// parameters have polymorphic type 36 bool needsAdapter( FunctionType *adaptee, const TyVarMap &tyVarr ); 37 38 /// true iff function has polymorphic return type 39 ReferenceToType *isPolyRet( FunctionType *function ); 33 40 34 41 /// Replaces a TypeInstType by its referrent in the environment, if applicable … … 40 47 /// returns polymorphic type if is polymorphic type in tyVars, NULL otherwise; will look up substitution in env if provided 41 48 Type *isPolyType( Type *type, const TyVarMap &tyVars, const TypeSubstitution *env = 0 ); 42 43 /// returns dynamic-layout type if is dynamic-layout type in tyVars, NULL otherwise; will look up substitution in env if provided44 Type *isDynType( Type *type, const TyVarMap &tyVars, const TypeSubstitution *env = 0 );45 46 /// true iff function has dynamic-layout return type under the given type variable map47 ReferenceToType *isDynRet( FunctionType *function, const TyVarMap &tyVars );48 49 /// true iff function has dynamic-layout return type under the type variable map generated from its forall-parameters50 ReferenceToType *isDynRet( FunctionType *function );51 52 /// A function needs an adapter if it returns a dynamic-layout value or if any of its parameters have dynamic-layout type53 bool needsAdapter( FunctionType *adaptee, const TyVarMap &tyVarr );54 49 55 50 /// returns polymorphic type if is pointer to polymorphic type, NULL otherwise; will look up substitution in env if provided -
src/GenPoly/InstantiateGeneric.cc
r27fefeb6 r321f55d 24 24 #include "GenPoly.h" 25 25 #include "ScopedMap.h" 26 #include "ScopedSet.h"27 26 28 27 #include "ResolvExpr/typeops.h" … … 123 122 } 124 123 }; 125 126 /// Possible options for a given specialization of a generic type127 enum class genericType {128 dtypeStatic, ///< Concrete instantiation based solely on {d,f}type-to-void conversions129 concrete, ///< Concrete instantiation requiring at least one parameter type130 dynamic ///< No concrete instantiation131 };132 133 genericType& operator |= ( genericType& gt, const genericType& ht ) {134 switch ( gt ) {135 case genericType::dtypeStatic:136 gt = ht;137 break;138 case genericType::concrete:139 if ( ht == genericType::dynamic ) { gt = genericType::dynamic; }140 break;141 case genericType::dynamic:142 // nothing possible143 break;144 }145 return gt;146 }147 124 148 125 /// Mutator pass that replaces concrete instantiations of generic types with actual struct declarations, scoped appropriately … … 150 127 /// Map of (generic type, parameter list) pairs to concrete type instantiations 151 128 InstantiationMap< AggregateDecl, AggregateDecl > instantiations; 152 /// Set of types which are dtype-only generic (and therefore have static layout)153 ScopedSet< AggregateDecl* > dtypeStatics;154 129 /// Namer for concrete types 155 130 UniqueName typeNamer; 156 131 157 132 public: 158 GenericInstantiator() : DeclMutator(), instantiations(), dtypeStatics(),typeNamer("_conc_") {}133 GenericInstantiator() : DeclMutator(), instantiations(), typeNamer("_conc_") {} 159 134 160 135 virtual Type* mutate( StructInstType *inst ); … … 172 147 /// Wrap instantiation insertion for unions 173 148 void insert( UnionInstType *inst, const std::list< TypeExpr* > &typeSubs, UnionDecl *decl ) { instantiations.insert( inst->get_baseUnion(), typeSubs, decl ); } 174 175 /// Strips a dtype-static aggregate decl of its type parameters, marks it as stripped176 void stripDtypeParams( AggregateDecl *base, std::list< TypeDecl* >& baseParams, const std::list< TypeExpr* >& typeSubs );177 149 }; 178 150 … … 182 154 } 183 155 184 /// Makes substitutions of params into baseParams; returns dtypeStatic if there is a concrete instantiation based only on {d,f}type-to-void conversions, 185 /// concrete if there is a concrete instantiation requiring at least one parameter type, and dynamic if there is no concrete instantiation 156 //////////////////////////////////////// GenericInstantiator ////////////////////////////////////////////////// 157 158 /// Possible options for a given specialization of a generic type 159 enum class genericType { 160 dtypeStatic, ///< Concrete instantiation based solely on {d,f}type-to-void conversions 161 concrete, ///< Concrete instantiation requiring at least one parameter type 162 dynamic ///< No concrete instantiation 163 }; 164 165 genericType& operator |= ( genericType& gt, const genericType& ht ) { 166 switch ( gt ) { 167 case genericType::dtypeStatic: 168 gt = ht; 169 break; 170 case genericType::concrete: 171 if ( ht == genericType::dynamic ) { gt = genericType::dynamic; } 172 break; 173 case genericType::dynamic: 174 // nothing possible 175 break; 176 } 177 return gt; 178 } 179 180 /// Makes substitutions of params into baseParams; returns true if all parameters substituted for a concrete type 186 181 genericType makeSubstitutions( const std::list< TypeDecl* >& baseParams, const std::list< Expression* >& params, std::list< TypeExpr* >& out ) { 187 182 genericType gt = genericType::dtypeStatic; … … 228 223 } 229 224 230 /// Substitutes types of members according to baseParams => typeSubs, working in-place231 void substituteMembers( std::list< Declaration* >& members, const std::list< TypeDecl* >& baseParams, const std::list< TypeExpr* >& typeSubs ) {232 // substitute types into new members233 TypeSubstitution subs( baseParams.begin(), baseParams.end(), typeSubs.begin() );234 for ( std::list< Declaration* >::iterator member = members.begin(); member != members.end(); ++member ) {235 subs.apply(*member);236 }237 }238 239 /// Strips the instances's type parameters240 void stripInstParams( ReferenceToType *inst ) {241 deleteAll( inst->get_parameters() );242 inst->get_parameters().clear();243 }244 245 void GenericInstantiator::stripDtypeParams( AggregateDecl *base, std::list< TypeDecl* >& baseParams, const std::list< TypeExpr* >& typeSubs ) {246 substituteMembers( base->get_members(), baseParams, typeSubs );247 248 deleteAll( baseParams );249 baseParams.clear();250 251 dtypeStatics.insert( base );252 }253 254 225 Type* GenericInstantiator::mutate( StructInstType *inst ) { 255 226 // mutate subtypes … … 260 231 // exit early if no need for further mutation 261 232 if ( inst->get_parameters().empty() ) return inst; 262 263 // check for an already-instantiatiated dtype-static type 264 if ( dtypeStatics.find( inst->get_baseStruct() ) != dtypeStatics.end() ) { 265 stripInstParams( inst ); 266 return inst; 267 } 268 233 assert( inst->get_baseParameters() && "Base struct has parameters" ); 234 269 235 // check if type can be concretely instantiated; put substitutions into typeSubs 270 assert( inst->get_baseParameters() && "Base struct has parameters" );271 236 std::list< TypeExpr* > typeSubs; 272 237 genericType gt = makeSubstitutions( *inst->get_baseParameters(), inst->get_parameters(), typeSubs ); 273 238 switch ( gt ) { 274 case genericType::dtypeStatic: 275 stripDtypeParams( inst->get_baseStruct(), *inst->get_baseParameters(), typeSubs ); 276 stripInstParams( inst ); 277 break; 278 279 case genericType::concrete: { 239 case genericType::dtypeStatic: // TODO strip params off original decl and reuse here 240 case genericType::concrete: 241 { 280 242 // make concrete instantiation of generic type 281 243 StructDecl *concDecl = lookup( inst, typeSubs ); … … 312 274 // exit early if no need for further mutation 313 275 if ( inst->get_parameters().empty() ) return inst; 314 315 // check for an already-instantiatiated dtype-static type 316 if ( dtypeStatics.find( inst->get_baseUnion() ) != dtypeStatics.end() ) { 317 stripInstParams( inst ); 318 return inst; 319 } 276 assert( inst->get_baseParameters() && "Base union has parameters" ); 320 277 321 278 // check if type can be concretely instantiated; put substitutions into typeSubs 322 assert( inst->get_baseParameters() && "Base union has parameters" );323 279 std::list< TypeExpr* > typeSubs; 324 280 genericType gt = makeSubstitutions( *inst->get_baseParameters(), inst->get_parameters(), typeSubs ); 325 281 switch ( gt ) { 326 case genericType::dtypeStatic: 327 stripDtypeParams( inst->get_baseUnion(), *inst->get_baseParameters(), typeSubs ); 328 stripInstParams( inst ); 329 break; 330 282 case genericType::dtypeStatic: // TODO strip params off original decls and reuse here 331 283 case genericType::concrete: 332 284 { … … 359 311 DeclMutator::doBeginScope(); 360 312 instantiations.beginScope(); 361 dtypeStatics.beginScope();362 313 } 363 314 … … 365 316 DeclMutator::doEndScope(); 366 317 instantiations.endScope(); 367 dtypeStatics.endScope();368 318 } 369 319 -
src/GenPoly/ScrubTyVars.cc
r27fefeb6 r321f55d 45 45 46 46 Type * ScrubTyVars::mutateAggregateType( Type *ty ) { 47 if ( shouldScrub( ty) ) {47 if ( isPolyType( ty, tyVars ) ) { 48 48 PointerType *ret = new PointerType( Type::Qualifiers(), new VoidType( ty->get_qualifiers() ) ); 49 49 delete ty; … … 63 63 Expression * ScrubTyVars::mutate( SizeofExpr *szeof ) { 64 64 // sizeof( T ) => _sizeof_T parameter, which is the size of T 65 if ( Type * dynType = shouldScrub( szeof->get_type() ) ) {66 Expression *expr = new NameExpr( sizeofName( mangleType( dynType ) ) );65 if ( Type *polyType = isPolyType( szeof->get_type() ) ) { 66 Expression *expr = new NameExpr( sizeofName( mangleType( polyType ) ) ); 67 67 return expr; 68 68 } else { … … 73 73 Expression * ScrubTyVars::mutate( AlignofExpr *algnof ) { 74 74 // alignof( T ) => _alignof_T parameter, which is the alignment of T 75 if ( Type * dynType = shouldScrub( algnof->get_type() ) ) {76 Expression *expr = new NameExpr( alignofName( mangleType( dynType ) ) );75 if ( Type *polyType = isPolyType( algnof->get_type() ) ) { 76 Expression *expr = new NameExpr( alignofName( mangleType( polyType ) ) ); 77 77 return expr; 78 78 } else { … … 82 82 83 83 Type * ScrubTyVars::mutate( PointerType *pointer ) { 84 // // special case of shouldScrub that takes all TypeInstType pointer bases, even if they're not dynamic 85 // Type *base = pointer->get_base(); 86 // Type *dynType = 0; 87 // if ( dynamicOnly ) { 88 // if ( TypeInstType *typeInst = dynamic_cast< TypeInstType* >( base ) ) { 89 // if ( tyVars.find( typeInst->get_name() ) != tyVars.end() ) { dynType = typeInst; } 90 // } else { 91 // dynType = isDynType( base, tyVars ); 92 // } 93 // } else { 94 // dynType = isPolyType( base, tyVars ); 95 // } 96 // if ( dynType ) { 97 if ( Type *dynType = shouldScrub( pointer->get_base() ) ) { 98 Type *ret = dynType->acceptMutator( *this ); 84 if ( Type *polyType = isPolyType( pointer->get_base(), tyVars ) ) { 85 Type *ret = polyType->acceptMutator( *this ); 99 86 ret->get_qualifiers() += pointer->get_qualifiers(); 100 87 pointer->set_base( 0 ); -
src/GenPoly/ScrubTyVars.h
r27fefeb6 r321f55d 27 27 class ScrubTyVars : public Mutator { 28 28 public: 29 ScrubTyVars( const TyVarMap &tyVars , bool dynamicOnly = false ): tyVars( tyVars ), dynamicOnly( dynamicOnly) {}29 ScrubTyVars( const TyVarMap &tyVars ): tyVars( tyVars ) {} 30 30 31 31 /// For all polymorphic types with type variables in `tyVars`, replaces generic types, dtypes, and ftypes with the appropriate void type, … … 33 33 template< typename SynTreeClass > 34 34 static SynTreeClass *scrub( SynTreeClass *target, const TyVarMap &tyVars ); 35 36 /// For all dynamic-layout types with type variables in `tyVars`, replaces generic types, dtypes, and ftypes with the appropriate void type,37 /// and sizeof/alignof expressions with the proper variable38 template< typename SynTreeClass >39 static SynTreeClass *scrubDynamic( SynTreeClass *target, const TyVarMap &tyVars );40 35 41 36 virtual Type* mutate( TypeInstType *typeInst ); … … 47 42 48 43 private: 49 /// Returns the type if it should be scrubbed, NULL otherwise.50 Type* shouldScrub( Type *ty ) {51 return dynamicOnly ? isDynType( ty, tyVars ) : isPolyType( ty, tyVars );52 // if ( ! dynamicOnly ) return isPolyType( ty, tyVars );53 //54 // if ( TypeInstType *typeInst = dynamic_cast< TypeInstType* >( ty ) ) {55 // return tyVars.find( typeInst->get_name() ) != tyVars.end() ? ty : 0;56 // }57 //58 // return isDynType( ty, tyVars );59 }60 61 44 /// Mutates (possibly generic) aggregate types appropriately 62 45 Type* mutateAggregateType( Type *ty ); 63 46 64 const TyVarMap &tyVars; ///< Type variables to scrub 65 bool dynamicOnly; ///< only scrub the types with dynamic layout? [false] 47 const TyVarMap &tyVars; 66 48 }; 67 49 50 /* static class method */ 68 51 template< typename SynTreeClass > 69 52 SynTreeClass * ScrubTyVars::scrub( SynTreeClass *target, const TyVarMap &tyVars ) { 70 53 ScrubTyVars scrubber( tyVars ); 71 return static_cast< SynTreeClass * >( target->acceptMutator( scrubber ) );72 }73 74 template< typename SynTreeClass >75 SynTreeClass * ScrubTyVars::scrubDynamic( SynTreeClass *target, const TyVarMap &tyVars ) {76 ScrubTyVars scrubber( tyVars, true );77 54 return static_cast< SynTreeClass * >( target->acceptMutator( scrubber ) ); 78 55 } -
src/SymTab/Autogen.cc
r27fefeb6 r321f55d 174 174 175 175 void makeStructMemberOp( ObjectDecl * dstParam, Expression * src, DeclarationWithType * field, FunctionDecl * func, TypeSubstitution & genericSubs, bool isDynamicLayout, bool forward = true ) { 176 //if ( isDynamicLayout && src ) {177 //genericSubs.apply( src );178 //}176 if ( isDynamicLayout && src ) { 177 genericSubs.apply( src ); 178 } 179 179 180 180 ObjectDecl * returnVal = NULL; -
src/examples/gc_no_raii/src/gc.h
r27fefeb6 r321f55d 7 7 static inline gcpointer(T) gcmalloc() 8 8 { 9 gcpointer(T) ptr = { gc_allocate(sizeof(T)) }; 10 ptr{}; 9 gcpointer(T) ptr; 10 void* address = gc_allocate(sizeof(T)); 11 (&ptr){ address }; 12 ctor(&ptr, address); 11 13 gc_conditional_collect(); 12 14 return ptr; 13 15 } 14 15 forall(otype T)16 static inline void gcmalloc(gcpointer(T)* ptr)17 {18 ptr{ gc_allocate(sizeof(T)) };19 (*ptr){};20 gc_conditional_collect();21 } -
src/examples/gc_no_raii/test/gctest.c
r27fefeb6 r321f55d 8 8 sout | "Bonjour au monde!\n"; 9 9 10 for(int i = 0; i < 1000000; i++) { 11 gcpointer(int) anInt; 12 gcmalloc(&anInt); 13 } 10 gcpointer(int) anInt = gcmalloc(); 14 11 }
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