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1\part{Language}
2\label{part:lang}
3
4\chapter{Overview of CIVL-C}
5
6\section{Main Concepts}
7
8CIVL-C is an extension of a subset of the C11 dialect of C. It
9includes the most commonly-used elements of C, including most of the
10syntax, types, expressions, and statements. Missing are some of the
11more esoteric type qualifiers, bitwise operations (at least for now),
12and much of the standard library. Moreover, none of the C11 language
13elements dealing with concurrency are included, as CIVL-C has its own
14concurrency primitives.
15
16The keywords in CIVL-C not already in C begin with the symbol \cckey.
17This makes them readily identifiable and also prevents any naming
18conflicts with identifiers in C programs. This means that most legal
19C programs will also be legal CIVL-C programs.
20
21One of the most important features of CIVL-C not found in standard C
22is the ability to define functions in any scope. (Standard C allows
23function definitions only in the file scope.) This feature is also
24found in GNU C, the GNU extension of C.
25
26Another central CIVL-C feature is the ability to \emph{spawn}
27functions, i.e., run the function in a new \emph{process} (thread).
28
29\emph{Scopes} and \emph{processes} are the two central themes of
30CIVL-C. Each has a static and a dynamic aspect. The static scopes
31correspond to the lexical scopes in the program---typically, regions
32delimited by curly braces \lb \ldots \rb. At runtime, these scopes
33are \emph{instantiated} when control in a process reaches the
34beginning of the scope. Processes are created dynamically by
35\emph{spawning} functions; hence the functions are the static
36representation of processes.
37
38\section{Example Illustrating Scopes and Processes}
39
40To understand the static and dynamic nature of scopes and processes,
41and the relations between them, we consider the (artificial) example
42code of Figure \ref{fig:scopecodeex}. The static scopes in the scope
43are numbered from $0$ to $6$.
44
45\begin{figure}[t]
46 \centering
47 \includegraphics[scale=1.2]{scopeCodeExample}
48 \caption{CIVL-C code skeleton to illustrate scope hierarchy}
49 \label{fig:scopecodeex}
50\end{figure}
51
52\begin{figure}
53 \centering
54 \includegraphics[scale=1.2]{scopeStateExample}
55 \caption{Static scope tree and a state for example program}
56 \label{fig:scopestateex}
57\end{figure}
58
59The static scopes have a tree structure: one scope is a child of
60another if the first is immediately contained in the second. Scope 0,
61which is the file scope (or \emph{root} scope) is the root of this
62tree. The static scope tree is depicted in Figure
63\ref{fig:scopestateex} (left). Each scope is identified by its
64integer ID. Additionally, if the scope happens to be the scope of a
65function definition, the name of the function is included in this
66identifier. A node in this tree also shows the variables and
67functions declared in the scope. For brevity, we omit the \emph{proc}
68variables.
69
70We now look at what happens when this program executes. Figure
71\ref{fig:scopestateex} (right) illustrates a possible state of the
72program at one point in an execution. We now explain how
73this state is arrived at.
74
75First, there is an implicit \emph{root function} placed around the
76entire code. The body of the \emph{main} function becomes the body
77of the root function, and the \emph{main} function itself disappears.
78This minor transformation does not change the structure of the scope
79tree.
80
81Execution begins by spawning a process $p_0$ to execute the root
82function. This causes scope $0$ to be instantiated. An instance of a
83static scope is known as a \emph{dynamic scope}, or \emph{dyscopes}
84for short. The dynamic scopes are represented by the ovals with
85double borders on the right side of Figure \ref{fig:scopestateex}.
86Each dyscope specifies a value for every variable declared in the
87corresponding static scope. In this case, the value $3$ has been
88assigned to variable \texttt{x}.
89
90The state of process $p_0$ is represented by a \emph{call stack}
91(green). The entries on this stack are \emph{activation frames}.
92Each frame contains two data: a reference to a dyscope (indicated by
93blue arrows) and a current location (or programmer counter vaule) in
94the static scope corresponding to that dyscope (not shown). The
95dyscope defines the environment in which the process evaluates
96expressions and executes statements. The currently executing function
97of a process, corresponding to the top frame in the call stack, can
98``see'' only the variables in its dyscope and those of all the
99ancestors of its dyscope in the dyscope tree.
100
101Returning to the example, $p_0$ enters scope 6, instanitating that
102scope, and then spawns procedure \texttt{f}. This creates process
103$p_1$, with a new stack with a frame pointing to a dyscope
104corresponding to static scope 1. The new process proceed to run
105concurrently with $p_0$. Meanwhile, $p_0$ calls procedure \texttt{g},
106which pushes a new entry onto its call stack, and instantiates scope
1075. Hence $p_0$ has two entries on its stack: the bottom one pointing
108to the instance of scope 6, the top one pointing to the instance of
109scope 5.
110
111Meanwhile, assume $\texttt{x}>0$, so that $p_1$ takes the \emph{true}
112branch of the \texttt{if} statement, instantiating scope 3 under the
113instance of scope 1. It then spawns two copies of procedure
114\texttt{f1}, creating processes $p_2$ and $p_3$ and two instances of
115scope 2. Then $p_1$ spawns \texttt{f2}, creating process $p_4$ and an
116instance of scope 4. Note that the instance of scope 4 is a child of
117the instance of scope 3, since the (static) scope 4 is a child of
118scope 3. Finally, $p_1$ calls \texttt{f2}, pushing a new entry on its
119stack and creating another instance of scope 4. The final state
120arrived at is the one shown.
121
122There are few key points to understand:
123\begin{itemize}
124\item In any state, there is a mapping from the dyscope tree to the
125 static scope tree which maps a dyscope to the static scope of which
126 it is an instance. This mapping is a \emph{tree homomorphism},
127 i.e., if dyscope $u$ is a child of dyscope $v$, then the static
128 scope corresponding to $u$ is a child of the static scope
129 corresponding to $v$.
130\item A static scope may have any number of instances, including 0.
131\item Dynamic scopes are created when control enters the corresponding
132 static scope; they disappear from the state when they become
133 unreachable. A dyscope $v$ is ``reachable'' if some process has a
134 frame pointing to a dyscope $u$ and there is a path from $u$ up to
135 $v$ that follows the parent edges in the dyscope tree.
136\item Processes are created when functions are spawned; they disappear
137 from the state when their stack becomes empty (either because the
138 process terminates normally or invokes the \emph{exit} system
139 function).
140\end{itemize}
141
142\section{Structure of a CIVL-C program}
143
144A CIVL-C program is structured very much like a standard C program.
145In particular, a CIVL-C program may use the preprocessor directives
146specified in the C Standard, and with the same meaning. A source
147program is preprocessed, then parsed, resulting in a translation unit,
148just as with standard C. The main differences are the nesting of
149function definitions and the new primitives beginning with
150\texttt{\$}, which are described in detail in the remainder of this
151part of the manual.
152
153A CIVL-C program must begin with the line
154\begin{verbatim}
155#include <civlc.h>
156\end{verbatim}
157which includes the main CIVL-C header file, which declares all the
158types and other CIVL primitives.
159
160As usual, a translation unit consists of a sequence of variable
161declarations, function prototypes, and function definitions in file
162scope. In addition, \emph{assume} statements may occur in the file
163scope. These are used to state assumptions on the input values
164to a program.
165
166\chapter{Sequential Elements}
167
168In this chapter we describe the main sequential elements of the
169language. For the most part these are the same as in C.
170Primitives dealing with concurrency are introduced in Chapter
171\ref{chap:concurrency}.
172
173\section{Types}
174
175\subsection{Standard types inherited from C}
176
177The \texttt{civlc.cvh} defines standard types inherited from C.
178The boolean type is denoted \verb!_Bool!, as in C. Its values are $0$
179and $1$, which are also denoted by $\cfalse$ and $\ctrue$,
180respectively.
181
182There is one integer type, corresponding to the mathematical integers.
183Currently, all of the C integer types \texttt{int}, \texttt{long},
184\texttt{unsigned\ int}, \texttt{short}, etc., are mapped to the CIVL
185integer type.
186
187There is one real type, corresponding to the mathematical real
188numbers. Currently, all of the C real types \texttt{double},
189\texttt{float}, etc., are mapped to the CIVL real type.
190
191Array types, \texttt{struct} and \texttt{union} types, \texttt{char},
192and pointer types (including pointers to functions) are all exactly as
193in C.
194
195% \subsection{The heap type $\cheap$ and handles}
196
197% Unlike C, a CIVL-C program does not necessarily have access to a
198% single, global heap. Instead, there is a $\cheap$ type, and heaps may
199% be declared explicitly wherever they are needed. Hence a CIVL-C
200% program may have several heaps, and these may exist in different
201% scopes.
202
203% A heap is declared and created as follows:
204% \begin{verbatim}
205% $heap h = $heap_create();
206% \end{verbatim}
207% The function \verb!$heap_create()! creates a new empty heap in the
208% current scope and returns a \emph{handle} to that heap. A handle is
209% like a pointer: it is a reference to another object. However, a handle
210% is much more restricted than a general pointer. In particular, it
211% cannot be dereferenced (by the \ct{*} operator). The underlying heap
212% object can only be accessed by using a handle to it as an argument to
213% a system function.
214
215% Handles can be used in assignments and passed as arguments to functions.
216% For example, this declaration could follow the one above:
217% \begin{verbatim}
218% $heap h2=h;
219% \end{verbatim}
220% After executing this code, \ct{h2} and \ct{h} will be aliased, i.e., the two
221% handles will refer to the same heap object.
222
223% The heap object exists in the scope in which it is created. In
224% particular, it will disappear when that scope disappears, i.e., when
225% control reaches the right curly brace that defines the end of the
226% scope. At that point, any references into the heap become invalid.
227
228% The following system functions deal with heaps:
229% \begin{verbatim}
230% void* $malloc($heap h, int size);
231% void free(void *p)
232% \end{verbatim}
233% The first function is like C's \texttt{malloc}, except that you
234% specify the heap in which the allocation takes place.
235% This modifies the specified heap and returns a pointer to the new object.
236% The function can only occur in a context in which the type of the object is
237% specified, as in:
238% \begin{verbatim}
239% $heap h;
240% int n = 10;
241% double *p = (double*)$malloc(h, n*sizeof(double));
242% \end{verbatim}
243% The function \ct{free} is exactly the same as in C. Note that
244% \texttt{free} modifies the heap which was used to allocate \texttt{p}.
245
246
247\subsection{The bundle type: \cbundle}
248\label{subsec:bundleType}
249
250CIVL-C includes a type named \cbundle, declared in the CIVL-C standard header \texttt{bundle.cvh}. A bundle is basically a
251sequence of data, wrapped into an atomic package. A bundle is created
252using a function that specifies a region of memory. One can create a
253bundle from an array of integers, and another bundle from an array of
254reals. Both bundles have the same type, \cbundle. They can therefore
255be entered into an array of \cbundle, for example. Hence bundles are
256useful for mixing objects of different (even statically unknown) types
257into a single data structure. Later, the contents of a bundle can be
258extracted with another function that specifies a region of memory into
259which to unpack the bundle; if that memory does not have the right
260type to receive the contents of the bundle, a runtime error is
261generated. The bundle type and its functions are provided by the library \texttt{bundle.cvh}.
262
263The relevant functions for creating and manipulating bundles
264are given in Section \ref{subsec:bundleLibrary}.
265
266\subsection{The \cscope{} type}
267\label{sec:scopetype}
268
269An object of type $\cscope$ is a reference to a dynamic scope. It may
270be thought of as a ``dynamic scope ID, '' but it is not an integer and
271cannot be converted to an integer. Operations defined on scopes are
272discussed in Section \ref{sec:scopeexpr}.
273
274\subsection{The \crange{} and \cdomain{} types}
275
276CIVL-C provides certain abstract datatypes that are useful for
277representing iteration spaces of loops in an abstract way.
278
279First, there is a built-in type $\crange$. An object of this type
280represents an ordered set of integers. There are expressions for
281specifying range values; these are described in Section
282\ref{sec:range_expr}. Ranges are typically used as a step
283in constructing \emph{domains}, described next.
284
285A domain type is used to represent a set of tuples of integer values.
286Every tuple in a domain object has the same arity (i.e., number of
287components). The arity must be at least 1, and is called the
288\emph{dimension} of the domain object.
289
290For each integer constant expression $n$, there is a type
291\cdomainof{\(n\)}, representing domains of dimension $n$.
292% \texttt{\cdomain{}(}]\(n\)\texttt{)}
293The \emph{universal domain type}, denoted \cdomain{}, represents
294domains of all positive dimensions, i.e., it is the union over all
295$n\geq 1$ of \cdomainof{\(n\)}. In particular, each \cdomainof{\(n\)}
296is a subtype of \cdomain{}.
297
298There are expressions for specifying domain values; these are
299described in Section \ref{sec:domain_expr}. There are also certains
300statements that use domains, such as the ``CIVL-\emph{for}'' loop
301\cfor; see Section \ref{sec:cfor}.
302
303
304\section{Expressions}
305
306\subsection{Expressions inherited from C}
307
308The following C expressions are included in CIVL:
309\begin{itemize}
310\item \emph{constant} expressions
311\item \emph{identifier} expressions (\texttt{x})
312\item parenthetical expressions (\verb!(e)!)
313\item numerical \emph{addition} (\verb!a+b!), \emph{subtraction} (\verb!a-b!),
314 \emph{multiplication} (\verb!a*b!), \emph{division} (\verb!a/b!),
315 \emph{unary plus} (\verb!+a!), \emph{unary minus} (\verb!-a!),
316 \emph{integer division} (\verb!a/b!) and \emph{modulus} (\verb!a%b!),
317 all with their ideal mathematical interpretations
318\item array \emph{index} expressions (\verb!a[e]!) and struct or union
319 \emph{navigation} expressions (\verb!x.f!, \verb!p->f!)
320\item \emph{address-of} (\verb!&e!), pointer \emph{dereference} (\verb!*p!),
321 pointer \emph{addition} (\verb!p+i!) and \emph{subtraction} (\verb!p-q!)
322 expressions
323\item relational expressions (\verb!a==b!, \verb~a!=b~, \verb!a>=b!,
324 \verb!a<=b!, \verb!a<b!, \verb!a>b!)
325\item logical \emph{not} (\verb~!p~), \emph{and} (\verb!p&&q!), and
326 \emph{or} (\verb!p||q!)
327\item \emph{sizeof} a type (\verb!sizeof(t)!) or expression (\verb!sizeof(e)!)
328\item \emph{assignment} expressions (\verb!a=b!, \verb!a+=b!, \verb!a-=b!,
329 \verb!a*=b!, \verb!a/=b!, \verb!a%=b!, \verb!a++!, \verb!a--!)
330\item function \emph{calls} \verb!f(e1,...,en)!
331\item \emph{conditional} expressions (\verb!b ? e : f!).
332\item \emph{cast} expressions (\verb!(t)e!)
333\end{itemize}
334
335Bit-wise operations are not yet supported.
336
337\subsection{Scope expressions}
338\label{sec:scopeexpr}
339
340As mentioned in Section \ref{sec:scopetype}, CIVL-C provides a type
341\cscope. An object of this type is a reference to a dynamic scope.
342Several constants, expressions, and functions dealing with the
343\cscope{} type are also provided.
344
345The $\cscope$ type is like any other object type. It may be used as
346the element type of an array, a field in a structure or union, and so
347on. Expressions of type $\cscope$ may occur on the left or right-hand
348sides of assignments and as arguments in function calls just like any
349other expression. Two different variables of type $\cscope$ may be
350aliased, i.e., they may refer to the same dynamic scope.
351
352A dynamic scope $\delta$ is \emph{reachable} if there exists a path
353which starts from the dyscope referenced by some frame on the call
354stack of a process, follows the parent edges in the dyscope tree, and
355terminates in $\delta$. If a dyscope is not reachable, it can never
356become reachable, and it cannot have any effect on the subsequent
357execution of the program.
358
359Normally, a dynamic scope will eventually become unreachable. At some
360point after it becomes unreachable, it will be collected in a
361garbage-collection-like sweep, and any existing references to that
362scope will become \emph{undefined}. An object of type $\cscope$ is
363also undefined before it is initialized. Any use of an undefined
364value is reported as an error by CIVL, so it is important to be sure
365that a scope variable is defined before using it.
366
367
368\subsubsection{Checking if a dyscope is defined: \cscopedefined}
369
370The header \texttt{civlc.cvh} provides a function \cscopedefined{}, which checks if a given
371value of \cscope{} type is defined, as described in Section \ref{subsubsec:scopedefined}.
372
373\subsubsection{The constant \chere}
374
375A constant \chere{} exists in every scope. This constant has
376type \cscope{} and refers to the dynamic scope in which it is
377contained. For example,
378\begin{verbatim}
379 { // scope s
380 int *p = (int*)$malloc($here, n*sizeof(int));
381 }
382\end{verbatim}
383allocates an object consisting of $n$ ints in the scope $s$.
384
385\subsubsection{The constant \cscoperoot{}}
386
387There is a global constant \cscoperoot{} of type $\cscope$ which
388refers to the root dynamic scope.
389
390
391\subsubsection{Scope relational operators}
392
393Let $s_1$ and $s_2$ be expressions of type \cscope. The following are
394all CIVL-C expressions of boolean type:
395\begin{itemize}
396\item $s_1$ \ct{==} $s_2$. This is \emph{true} iff $s_1$ and $s_2$
397 refer to the same dynamic scope.
398\item $s_1$ \ct{!=} $s_2$. This is \emph{true} iff $s_1$ and $s_2$
399 refer to different dynamic scopes.
400\item $s_1$ \ct{<=} $s_2$. This is \emph{true} iff $s_1$ is equal to
401 or a descendant of $s_2$, i.e., $s_1$ is equal to or contained in $s_2$.
402\item $s_1$ \ct{<} $s_2$. This is \emph{true} iff $s_1$ is a strict
403 descendant of $s_2$, i.e., $s_1$ is contained in $s_2$ and is not
404 equal to $s_2$.
405\item $s_1$ \ct{>} $s_2$. This is equivalent to $s_2$ \ct{<} $s_1$.
406\item $s_1$ \ct{>=} $s_2$. This is equivalent to $s_2$ \ct{<=} $s_1$.
407\end{itemize}
408If $s_1$ or $s_2$ is undefined in any of these expressions, an error
409will be reported.
410
411\subsubsection{Scope parent function \texorpdfstring{\cscopeparent}{\$scope\_parent}}
412
413The CIVL-C header \texttt{scope.cvh} provides the function \cscopeparent{} that computes the immediate
414parent of a dynamic scope, as described in Section \ref{subsec:scopeLibrary}.
415
416\subsubsection{Lowest Common Ancestor: \ct{+}}
417
418The expression $s_1$ \ct{+} $s_2$, where $s_1$ and $s_2$ are
419expressions of type \cscope, evaluates to the lowest common ancestor
420of $s_1$ and $s_2$ in the dynamic scope tree. This is the smallest
421dynamic scope containing both $s_1$ and $s_2$.
422
423\subsubsection{The \cscopeof{} expression}
424
425Given any left-hand-side expression \ct{expr}, the expression
426\begin{verbatim}
427 $scopeof(expr)
428\end{verbatim}
429evaluates to the dynamic scope containing the object specified by
430\ct{expr}.
431
432The following example illustrates the semantics of the \cscopeof{}
433operator. All of the assertions hold:
434\begin{verbatim}
435{
436 $scope s1 = $here;
437 int x;
438 double a[10];
439
440 {
441 $scope s2 = $here;
442 int *p = &x;
443 double *q = &a[4];
444
445 assert($scopeof(x)==s1);
446 assert($scopeof(p)==s2);
447 assert($scopeof(*p)==s1);
448 assert($scopeof(a)==s1);
449 assert($scopeof(a[5])==s1);
450 assert($scopeof(q)==s2);
451 assert($scopeof(*q)==s1);
452 }
453}
454\end{verbatim}
455
456\subsection{Range and domain expressions}
457
458\subsubsection{Regular range expressions}
459\label{sec:range_expr}
460
461An expression of the form
462\begin{verbatim}
463 lo .. hi
464\end{verbatim}
465where \texttt{lo} and \texttt{hi} are integer expressions, represents
466the range consisting of the integers $\texttt{lo}, \texttt{lo}+1,
467\ldots, \texttt{hi}$ (in that order).
468
469An expression of the form
470\begin{verbatim}
471 lo .. hi # step
472\end{verbatim}
473where \texttt{lo}, \texttt{hi}, and \texttt{step} are integer
474expressions is interpreted as follows. If \texttt{step} is positive,
475it represents the range consisting of $\texttt{lo},
476\texttt{lo}+\texttt{step}, \texttt{lo}+2*\texttt{step}, \ldots$, up to
477and possibly including \texttt{hi}. To be precise, the infinite
478sequence is intersected with the set of integers less than or equal to
479\texttt{hi}.
480
481If \texttt{step} is negative, the expression represents the range
482consisting of $\texttt{hi}, \texttt{hi}+\texttt{step},
483\texttt{hi}+2*\texttt{step}, \ldots$, down to and possibly including
484\texttt{lo}. Precisely, the infinite sequence is intersected with the
485set of integers greater than or equal to \texttt{lo}.
486
487\subsubsection{Cartesian domain expressions}
488\label{sec:domain_expr}
489
490An expression of the form
491\begin{verbatim}
492 ($domain) { r1, ..., rn }
493\end{verbatim}
494where \texttt{r1}, \ldots, \texttt{rn} are $n$ expressions of type
495\crange, is a \emph{Cartesian domain expression}. It represents the
496domain of dimension $n$ which is the Cartesian product of the $n$
497ranges, i.e., it consists of all $n$-tuples $(x_1,\ldots,x_n)$ where
498$x_1\in\texttt{r1}$, \ldots, $x_n\in\texttt{rn}$. The order on the
499domain is the dictionary order on tuples. The type of this expression
500is \cdomainof{\(n\)}.
501
502When a Cartesian domain expression is used to initialize an object of
503domain type, the ``\texttt{(}\cdomain\texttt{)}'' may be omitted.
504For example:
505\begin{verbatim}
506 $domain(3) dom = { 0 .. 3, r2, 10 .. 2 # -2 };
507\end{verbatim}
508
509
510\section{Statements}
511
512\subsection{C Statements}
513
514The usual C statements are supported:
515\begin{itemize}
516\item \emph{no-op} (\ct{;})
517\item expression statements (\ct{e;})
518\item labeled statements, including \ct{case} and \ct{default} labels
519 (\ct{l: s})
520\item \emph{for} (\ct{for (init; cond; inc) s}), \emph{while}
521 (\ct{while (cond) s}) and \emph{do} (\ct{do s while (cond)})
522 loops
523\item compound statements (\lb \ct{s1;s2;} \ldots \rb)
524\item \texttt{if} and \verb!if! \ldots \verb!else!
525\item \verb!goto!
526\item \verb!switch!
527\item \verb!break!
528\item \verb!continue!
529\item \verb!return!
530\end{itemize}
531
532\subsection{Guards and nondeterminism}
533
534\subsubsection{Guarded commands: \cwhen}
535
536A guarded command is encoded in CIVL-C using a $\cwhen$ statement:
537\begin{verbatim}
538 $when (expr) stmt;
539\end{verbatim}
540All statements have a guard, either implicit or explicit. For most
541statements, the guard is \ctrue. The \cwhen{} statement allows one to
542attach an explicit guard to a statement.
543
544When \texttt{expr} is \emph{true}, the statement is enabled, otherwise
545it is disabled. A disabled statement is \emph{blocked}---it will not
546be scheduled for execution. When it is enabled, it may execute by
547moving control to the \texttt{stmt} and executing the first atomic
548action in the \texttt{stmt}.
549
550If \texttt{stmt} itself has a non-trivial guard, the guard of the
551\cwhen{} statement is effectively the conjunction of the \texttt{expr}
552and the guard of \texttt{stmt}.
553
554The evaluation of \texttt{expr} and the first atomic action of
555\texttt{stmt} effectively occur as a single atomic action. There is
556no guarantee that execution of \texttt{stmt} will continue atomically
557if it contains more than one atomic action, i.e., other processes may
558be scheduled.
559
560Examples:
561\begin{verbatim}
562 $when (s>0) s--;
563\end{verbatim}
564This will block until \texttt{s} is positive and then decrement
565\texttt{s}. The execution of \texttt{s--} is guaranteed to take place
566in an environment in which \texttt{s} is positive.
567
568\begin{verbatim}
569 $when (s>0) {s--; t++}
570\end{verbatim}
571The execution of \texttt{s--} must happen when \texttt{s>0}, but
572between \texttt{s--} and \texttt{t++}, other processes may execute.
573
574\begin{verbatim}
575 $when (s>0) $when (t>0) x=y*t;
576\end{verbatim}
577This blocks until both \texttt{x} and \texttt{t} are positive then
578executes the assignment in that state. It is equivalent to
579\begin{verbatim}
580 $when (s>0 && t>0) x=y*t;
581\end{verbatim}
582
583\subsubsection{Nondeterministic selection statement: \cchoose}
584
585A \cchoose{} statement has the form
586\begin{verbatim}
587 $choose {
588 stmt1;
589 stmt2;
590 ...
591 default: stmt
592 }
593\end{verbatim}
594The \texttt{default} clause is optional.
595
596The guards of the statements are evaluated and among those that are
597\emph{true}, one is chosen nondeterministically and executed. If none
598are \emph{true} and the \texttt{default} clause is present, it is
599chosen. The \texttt{default} clause will only be selected if all
600guards are \emph{false}. If no \texttt{default} clause is present and
601all guards are \emph{false}, the statement blocks. Hence the implicit
602guard of the \cchoose{} statement without a \texttt{default} clause is
603the disjunction of the guards of its sub-statements. The implicit
604guard of the \cchoose{} statement with a default clause is
605\emph{true}.
606
607Example: this shows how to encode a ``low-level'' CIVL guarded
608transition system:
609
610\begin{verbatim}
611 l1: $choose {
612 $when (x>0) {x--; goto l2;}
613 $when (x==0) {y=1; goto l3;}
614 default: {z=1; goto l4;}
615 }
616 l2: $choose {
617 ...
618 }
619 l3: $choose {
620 ...
621 }
622\end{verbatim}
623
624
625\subsubsection{Nondeterministic choice of integer:
626 \texorpdfstring{\cchooseint}{\$choose\_int}}
627The header \texttt{civlc.cvh} provides the function \cchooseint{} that returns an integer between 0 and the specified value
628in a nondeterministic way, as described in Section \ref{subsubsec:chooseint}.
629
630\subsection{Iteration using domains with \cfor}
631\label{sec:cfor}
632
633A \emph{CIVL-for} statement has the form
634\begin{verbatim}
635 $for (int i1, ..., in : dom) S
636\end{verbatim}
637where \texttt{i1}, \ldots, \texttt{in} are $n$ identifiers,
638\texttt{dom} is an expression of type \cdomainof{\(n\)}, and
639\texttt{S} is a statement. The identifiers declare $n$ variables of
640integer type. Control iterates over the values of the domain,
641assigning the integer variables the components of the current tuple in
642the domain at the start of each iteration. The scope of the variables
643extends to the end of \texttt{S}. The iterations takes place in the
644order specified by the domain, e.g., dictionary order for a Caretesian
645domain. Note that if a range expression can be used as \texttt{dom} here, which will be
646automatically converted to one dimensional domain. For example,
647 \begin{verbatim}
648 $for (int i1, ..., in : 0 .. 10) S
649\end{verbatim}
650is equivalent to
651\begin{verbatim}
652 $for (int i1, ..., in : ($domain(1){0 .. 10})) S
653\end{verbatim}
654
655
656Note that if a range expression can be used as \texttt{dom} here, which will be
657automatically converted to one dimensional domain. For example,
658 \begin{verbatim}
659 $for (int i1, ..., in : 0 .. 10) S
660\end{verbatim}
661is equivalent to
662\begin{verbatim}
663 $for (int i1, ..., in : ($domain(1)){0 .. 10}) S
664\end{verbatim}
665
666There is a also a parallel version of this construct, \cparfor,
667described in \ref{sec:parfor}.
668
669\section{Functions}
670\subsection{Abstract function: \cabstract}
671
672An abstract function declares a function without a body, and it has the form
673
674\begin{verbatim}
675 $abstract type function(list-of-parameters);
676\end{verbatim}
677
678It is required that the function should have a non-void return type and take at least one parameter.
679The return value of the function is evaluated symbolically using the actual arguments of the function call.
680
681\chapter{Concurrency}
682\label{chap:concurrency}
683
684\section{Process creation and management}
685
686\subsection{The process type: \cproc}
687
688This is a primitive object type and functions like any other primitive
689C type (e.g., \texttt{int}). An object of this type refers to a
690process. It can be thought of as a process ID, but it is not an
691integer and cannot be cast to one. It is analogous to the $\cscope$
692type for dynamic scopes.
693
694Certain expressions take an argument of \cproc{} type and some return
695something of \cproc{} type. The operators \verb!==! and \verb~!=~ may
696be used with two arguments of type \cproc{} to determine whether the
697two arguments refer to the same process.
698
699\subsection{Checking if a process is defined: \cprocdefined}
700
701An object of type \cproc{} is initially undefined, so a use of that
702object would result in an error. One can check whether a \cproc{}
703object is defined using the function \cprocdefined, declared by the header \texttt{civlc.cvh}, as
704described in Section \ref{subsubsec:procdefined}.
705
706\subsection{The \emph{self} process constant: \cself}
707
708This is a constant of type \cproc. It can be used wherever an argument
709of type \cproc{} is called for. It refers to the process that is
710evaluating the expression containing \cself.
711
712\subsection{The \emph{null} process constant: \cprocNull}
713
714This is a constant of type \cproc. It can be used wherever an argument
715of type \cproc{} is called for. It simply means that the object doesnt refer to any process.
716
717\subsection{Spawning a new process: \cspawn}
718
719A \emph{spawn} expression is an expression with side-effects. It
720spawns a new process and returns a reference to the new process, i.e.,
721an object of type \cproc. The syntax is the same as a procedure
722invocation with the keyword \cspawn{} inserted in front:
723\begin{verbatim}
724 $spawn f(expr1, ..., exprn)
725\end{verbatim}
726Typically the returned value is assigned to a variable, e.g.,
727\begin{verbatim}
728 $proc p = $spawn f(i);
729\end{verbatim}
730If the invoked function \texttt{f} returns a value, that value is
731simply ignored.
732
733\subsection{Waiting for process(es) to terminate: \cwait\ and \cwaitall}
734
735Once the system function \cwait(\cwaitall) provided by the CIVL-C standard header \texttt{civlc.cvh}
736gets invoked, it will not return until the specified process(es) terminates(terminate), as described in Sections \ref{subsubsec:wait} and
737\ref{subsubsec:wait}.
738
739\subsection{Terminating a process immediately: \cexit}
740Once the function \cexit\, declared in the header \texttt{civlc.cvh}, is called, the calling process terminates immediately, as described in Section \ref{subsubsec:exit}.
741
742\section{Atomicity}
743
744\subsection{Atom blocks: \catom} This defines a number of statements
745to be executed as a single atomic transition. An \catom~block has the
746following form:
747\begin{verbatim}
748 $atom {
749 stmt1;
750 stmt2;
751 ...
752 }
753\end{verbatim}
754
755The statements inside an \catom\ block are to be executed as one
756transition. It is required that the execution of the statements in an
757\catom\ block satisfy all of the following properties:
758\begin{enumerate}
759\item \emph{deterministic}: at each step in the execution of the atom
760 block, there must be at most one enabled statement;
761\item \emph{nonblocking}: at each step in the execution, there must be
762 at least one enabled statement, hence, together with (1), there must
763 be exactly one enabled statement;
764\item \emph{finite}: the execution of the atom block must terminate
765 after a finite number of steps; and
766\item \emph{isolated}: there are no jumps from outside the atom block
767 to inside the atom block, or from inside the atomc block to outside
768 of it.
769\end{enumerate}
770
771Violations of the \emph{deterministic}, \emph{nonblocking}, or
772\emph{isolated} properties will be reported either statically or
773dynamically. If the \emph{finite} property is violated, the
774verification may just run forever.
775
776Once the process enters an \catom\ block is said to be \emph{executing
777 atomly}. The process remains executing atomly until it reaches the
778terminating right brace of the block. Hence \emph{executing atomly}
779is a dynamic, not static condition. For example, the block might
780contain a function call which takes the process to a point in code
781which is not statically contained in an atom block; that process is
782nevertheless still executing atomly and is subject to the rules above.
783The process only stops executing atomly when that function call
784returns and control finally reaches the right curly brace at the end
785of the atom block (assuming the block is not contained in another atom
786block).
787
788\emph{Note:} \cwait\ or \cwaitall\ calls are not allowed in \catom\ blocks.
789The rationale for this is that there is never a way to know for
790certain that another process has terminated (until \cwait\ or \cwaitall\ has
791returned) so there is never a way to be certain the \cwait\ or \cwaitall call
792will not block. If one does occur in an \catom\ block, an error will
793be reported statically (if it can be detected statically) or
794dynamically (otherwise). Note that it is not always possible to
795detect this statically because the \catom\ block may contain a
796function call, and the function may contain \cwait\ or \cwaitall\ calls.
797
798\subsection{Atomic blocks: \catomic}
799
800The statements in an \emph{atomic} block will be executed without
801other processes interleaving, to the extent possible. It has the
802form:
803\begin{verbatim}
804 $atomic {
805 stmt1;
806 stmt2;
807 ...
808 }
809\end{verbatim}
810It is essentially a weaker form of \catom. Unlike \catom, there are
811no restrictions on the statements that can go inside an \catomic\
812block. A process executing an \catomic~block will try to execute the
813statements without interleaving with other processes, unless it
814becomes blocked. Unlike an \catom, the statements in an atomic block
815do not necessarily execute as a single transition; they may be spread
816out over multiple transitions.
817
818When no statement is enabled, the execution of the \catomic\ block
819will be interrupted. At this point, other processes are allowed to
820execute. Eventually, if the original process becomes enabled due to
821the actions of other processes, it may be scheduled again, in which
822case it regains atomicity and continues where it left off. For
823example, after executing the first loop, the process executing the
824following code will become blocked at the first \cwait\ or \cwaitall\ call:
825 \begin{verbatim}
826$atomic {
827 for (int i = 0; i < 5; i++) p[i] = $spawn foo(i);
828 for (int i = 0; i < 5; i++) $wait p[i];
829}
830\end{verbatim}
831Other processes will then execute. Eventually, if the process being
832waited on terminates, the original process becomes enabled and may be
833scheduled, in which case it regain atomicity, increments \texttt{i}
834and proceeds to the next $\cwait$ or \cwaitall\ call. This is in fact a common
835idiom for spawning and waiting on a set of processes.
836
837A process that enters an $\catomic$ block is said to be
838\emph{executing atomically}; it remains executing atomically until it
839reaches the closing curly brace.
840
841Both $\catom$ and $\catomic$ blocks can be nested arbitrarily, but
842$\catom$ overrides $\catomic$: a process that is executing atomly will
843continue executing atomly if it encounters an $\catomic$ statement;
844but a process executing atomically that encounters an $\catom$ will
845begin executing atomly.
846
847The atomic semantics are defined more precisely as follows: there is a
848single global variable called the \emph{atomic lock}. This variable
849can either be null (meaning the atomic lock is ``free''), or it can
850hold the PID of a process; that process is said to ``hold'' the atomic
851lock. Moreover, each process contains a special integer variable, its
852\emph{atomic counter}, which is initially 0. Every time a process
853enters an atomic block, it increments its atomic counter; every time
854it exits an atomic block, it decrements its counter. In order to
855increment its counter from $0$ to $1$, it must first wait for the
856atomic lock to become free, and then take the lock. When it
857decrements its counter from $1$ to $0$, it releases the atomic lock.
858When a process executing atomically becomes blocked, it releases the
859lock (without changing the value of its atomic counter).
860
861\section{Parallel loops with \cparfor}
862\label{sec:parfor}
863
864A parallel loop statement has the form
865\begin{verbatim}
866 $parfor (int i1, ..., in : dom) S
867\end{verbatim}
868The syntax is exactly the same as that for the sequential loop \cfor
869(Section \ref{sec:cfor}), only with \cparfor{} replacing \cfor.
870
871The semantics are as follows: when control reaches the loop, one
872process in spawned for each element of the domain. That process has
873local variables corresponding to the iteration variables, and those
874local variables are initialized with the components of the tuple for
875the element of the domain that process is assigned. Each process
876executes the statement \texttt{S} in this context. Finally, each of
877these processes is waited on at the end. In particular, there is an
878effective barrier at the end of the loop, and all the spawned
879processes disappear after this point.
880
881\section{Message-Passing}
882
883CIVL-C provides a number of additional primitives that can be used to
884model message-passing systems. This part of the language is built in
885two layers: the lower layer defines an abstract data type for
886representing messages; the higher layer defines an abstract data type
887of \emph{communicators} for managing sets of messages being
888transferred among some set of processes.
889
890\subsection{Messages: \cmessage}
891
892Messages are similar to bundles, but with some additional meta-data.
893The \emph{data} component of the message is the ``contents'' of the
894message and is formed and extracted much like a bundle. The meta-data
895consists of an integer identifier for the \emph{source} place of the
896message, an integer identifier for the message \emph{destination}
897place, and an integer \emph{tag} which can be used by a process to
898discriminate among messages for reception. This is very similar to
899MPI.
900
901The functions for creating, and extracting information from, messages
902are given in Section \ref{subsubsec:messaging}.
903
904\subsection{Communicators: \cgcomm{} and \ccomm}
905\label{sec:communicators}
906
907CIVL-C defines a \emph{global communicator} type $\cgcomm$ and a
908\emph{local communicator} type $\ccomm$. The global communicator is an
909abstraction for a ``communication universe'' that stores buffered
910messages and perhaps other data. The local communicator wraps
911together a reference to a global communicator and an integer
912\emph{place}. Most of the message-passing commands take a local
913communicator as an argument to specify the communication universe used
914for that operation and the place from which that operation will be
915executed. The communication universes are isolated from one
916another---a message sent on one can never be received using a
917different communicator, for example.
918
919The global communicator is the shared object that must be declared in
920a scope containing all scopes in which communication in that universe
921will take place. It is created by specifying the number of
922\emph{places} that will comprise the communicator. A place is an
923address to which messages may be sent or where they may be received.
924There is not necessarily a one-to-one correspondence between places and
925processes: many processes can use the same place.
926
927Local communicators are created (typically in some child scope of the
928scope in which the global communicator is declared) by specifying the
929gobal communicator to which the local one will be associated and the
930place ID. The local communicator will be used in most of the
931message-passing functions; it may be thought of as an ordered pair
932consisting of a reference to the global communicator and the integer
933place ID. The place ID must be in $[0,\texttt{size}-1]$, where
934\texttt{size} is the size of the global communicator. The place ID
935specifies the place in the global communication universe that will be
936occupied by the local communicator. The local communicator handle may
937be used by more than one process, but all of those processes will be
938viewed as occupying the same place. Only one call to \ccommcreate{}
939may occur for each gcomm-place pair.
940
941
942Both types ($\cgcomm$ and $\ccomm$) are handle types. When declared
943with a call to the corresponding creation function, they create an
944object in the specified scope and return a handle to that object. The
945object can only be accessed through the specified system functions
946that take this handle as an argument.
947
948 % This local communicator handle will be used as an
949 % * argument in most message-passing functions. The place must be in
950 % * [0,size-1] and specifies the place in the global communication universe
951 % * that will be occupied by the local communicator. The local communicator
952 % * handle may be used by more than one process, but all of those
953 % * processes will be viewed as occupying the same place.
954 % * Only one call to $comm_create may occur for each gcomm-place pair.
955
956The communicator interface is given in Sections \ref{subsubsec:gcomm} and \ref{subsubsec:comm}.
957
958Certain restrictions are enforced on some relations between the
959objects involved in a communication universe.
960
961Fix a \cgcomm{} object. This object corresponds to a single
962communication universe with, say, $n$ places. At any time, there can
963be \emph{at most one} \ccomm{} object associated to a given place. If
964a program attempts to create a \ccomm{} object with the same \cgcomm{}
965and place as an earlier created \ccomm{} object, a runtime error will
966occur. In particular, there can be at most $n$ \ccomm{} objects
967associated to the \cgcomm.
968
969The relation between processes and \ccomm{} objects is unconstrained.
970One process may use any number of \ccomm{} objects. (Of course, the
971process must have access to handles for those \ccomm{} objects.)
972Dually, a single \ccomm{} object may be used by any number of
973processes; this situation arises naturally when modeling a
974multi-threaded MPI program.
975
976\begin{figure}
977 \begin{small}
978\begin{verbatim}
979$gcomm gcomm = $gcomm_create($here, nprocs);
980void Process(int rank) {
981 $comm comm = $comm_create($here, gcomm, rank);
982
983 void Thread(int tid) {
984 ...$comm_enqueue(comm, msg)...
985 ...$comm_dequeue(comm, source, tag)...
986 }
987
988 for (int i=0; i<nthreads; i++) $spawn Thread(i);
989 ...
990 $comm_destroy(comm);
991}
992for (int i=0; i<nprocs; i++) $spawn Process(i);
993...
994$gcomm_destroy(gcomm);
995\end{verbatim}
996 \end{small}
997 \caption{Code skeleton for model of multithreaded MPI program
998 showing placement of global and local communicator objects}
999 \label{fig:mpi-threads-comm}
1000\end{figure}
1001
1002There is no special status given to the process which creates the
1003\ccomm{} object of a given place. Any process which can access a
1004handle for that \ccomm{} object can use it to send or receive
1005messages, regardless of whether that process was the one that created
1006the \ccomm{} object. However, users should be aware that verification
1007is likely to be most efficient when variables are declared as locally
1008as possible, so it is best to declare the \ccomm{} object in the
1009innermost scope possible. Figure \ref{fig:mpi-threads-comm}
1010illustrates an effective way to do this in the context of modeling a
1011multithreaded MPI program. In the code skeleton, each thread can
1012access the local communicator object of its process, but not that of
1013any other process.
1014
1015\subsection{Barriers: \cgbarrier{} and \cbarrier}
1016\label{sec:barriers}
1017
1018The CIVL-C header \texttt{concurrency.cvh} defines a \emph{global barrier} type $\cgbarrier$ and a
1019\emph{local barrier} type $\cbarrier$. They provide an implementation of
1020a barrier for concurrent programs.
1021
1022The global barrier is a shared object that must be declared in
1023a scope containing all scopes in which the barrier will be called.
1024 It is created by specifying the number of
1025\emph{places} that will comprise the barrier.
1026
1027Local barriers are created (typically in some child scope of the
1028scope in which the global barrier is declared) by specifying the
1029gobal barrier to which the local one will be associated and the
1030place ID. The local barrier will be used in the call to the barrier;
1031it may be thought of as an ordered pair
1032consisting of a reference to the global barrier and the integer
1033place ID. The place ID must be in $[0,\texttt{size}-1]$, where
1034\texttt{size} is the size of the global barrier.
1035Only one call to \cbarriercreate{}
1036may occur for each gbarrier-place pair.
1037
1038
1039Both types ($\cgbarrier$ and $\cbarrier$) are handle types. When declared
1040with a call to the corresponding creation function, they create an
1041object in the specified scope and return a handle to that object. The
1042object can only be accessed through the specified system functions
1043that take this handle as an argument. The barrier interface is presented in Section \ref{subsec:concurrencyLibrary}.
1044
1045\chapter{Specification}
1046
1047\section{Overview}
1048
1049Specification is the means by which one expresses what a program is
1050supposed to do, i.e., what it means for it to be correct.
1051
1052There are several specification mechanisms in CIVL-C. First, there are
1053the default properties: these are generic properties which are checked
1054by default in any program, and require no additional specification
1055effort. These properties include absence of deadlocks, division by 0,
1056illegal pointer dereferences, and out of bounds array indexes.
1057
1058Many more program-specific properties can be specified using
1059assertions. CIVL-C has a rich assertion language which extends the
1060language of boolean-valued C expressions. Assumptions are a
1061specification dual to assertions in that they restrict the set
1062of executions on which the assertions are checked.
1063
1064Functional equivalence is a power specification mechanism. In this
1065approach, two programs are provided, one playing the role of the
1066specification, the other the role of the implementation. The
1067implementation is correct if, for all inputs $x$, it produces the same
1068output as that produced by the specification on input $x$. In other
1069words, the two programs define the same function; this is sometimes
1070known as \emph{input-output equivalence}. In order to take this
1071approach, one must first have a way to specify what the inputs and
1072outputs of a programs are; CIVL-C provides special keywords for this.
1073
1074Procedure contracts are another powerful specification mechanisms.
1075These typically involve specifying preconditions and postconditions
1076for a function. The function is correct if, whenever it is called in a
1077state satisfying the precondition, when it returns the state will
1078satsify the postcondition. A program is correct if all its functions
1079satsify their contract.
1080
1081\section{Input-output signature}
1082
1083\subsection{Input type qualifier: \cinput}
1084
1085The declaration of a variable in the root scope may
1086include the type qualifier \cinput, e.g.,
1087\begin{verbatim}
1088 $input int n;
1089\end{verbatim}
1090This declares the variable to be an input variable, i.e., one which is
1091considered to be an input to the program. Such a variable is
1092initialized with an arbitrary (unconstrained) value of its type. When
1093using symbolic execution to verify a program, such a variable will be
1094assigned a unique symbolic constant of its type.
1095
1096In contrast, variables in the root scope which are not input variables
1097will instead be initialized with the ``undefined'' value. If an
1098undefined value is used in some way (such as in an argument to an
1099operator), an error occurs.
1100
1101In addition, input variables may only be read, never written to.
1102
1103Alternatively, it is also possible to specify a particular concrete
1104initial value for an input variable. This is done using a command
1105line argument when verifying or running the program.
1106
1107An input variable declaration may contain an initializer. The
1108semantics are as follows: if no command line value is specified for
1109the variable, the initializer is used to initialize the variable. If
1110a command line value is specified, the command line value is used and
1111the initializer is ignored.
1112
1113Input (and output) variables also play a key role when determining
1114whether two programs are functionally equivalent. Two programs are
1115considered functionally equivalent if, whenever they are given the
1116same inputs (i.e., corresponding \cinput{} variables are initialized
1117with the same values) they will produce the same outputs (i.e.,
1118corresponding \coutput{} variables will end up with the same values at
1119termination).
1120
1121\subsection{Output type qualifier: \coutput}
1122
1123A variable in the root scope may be declared with this type qualifier
1124to declare it to be an output variable. Output variables are ``dual''
1125to input variables. They may only be written to, never read. They
1126are used primarily in functional equivalence checking.
1127
1128\section{Assertions and assumptions}
1129\label{sec:assertionAndAssumption}
1130\subsection{Assertions: \cassert}
1131
1132The system function \cassert\ (provided by the \texttt{civlc} header) has the signature
1133\begin{verbatim}
1134void $assert(_Bool expr, ...);
1135\end{verbatim}
1136
1137It takes an boolean type expression and a number of optional expressions which are used to construct an error message.
1138Note that CIVL-C boolean expressions have a richer syntax than C
1139expressions, and may include universal or existential quantifiers
1140(see below), and the boolean values \ctrue{} and \cfalse{}.
1141
1142During verification, the assertion is checked. If it cannot be proved
1143that it must hold, a violation is reported. If additional arguments are present, then a specific message is printed as well if the assertion is violated. These
1144additional arguments are similar in form to those used in C's
1145\texttt{printf} statement: a format string, followed by some number of
1146arguments which are evaluated and substituted for successive codes in
1147the format string. For example,
1148\begin{verbatim}
1149 $assert(x<=B, "x-coordinate %f exceeds bound %f", x, B);
1150\end{verbatim}
1151
1152If \texttt{x=3} and \texttt{B=2}, then the above assertion will be violated and CIVL would print the error message ``x-coordinate 3 exceeds bound 2".
1153
1154\subsection{Assume statements: \cassume}
1155
1156The system function \cassume\ (provided by the \texttt{civlc} header) has the signature
1157\begin{verbatim}
1158void $assume(_Bool expr);
1159\end{verbatim}
1160
1161During verification, the given expression is assumed to hold. If
1162this leads to a contradiction on some execution, that execution is
1163simply ignored. It never reports a violation, it only restricts the
1164set of possible executions that will be explored by the verification
1165algorithm.
1166
1167Like an assertion call, an assume call can be used any place
1168a statement is expected. In addition, an assume call can be used
1169in file scope to place restrictions on the global variables of the
1170programs. For example,
1171\begin{verbatim}
1172$input int B;
1173$input int N;
1174$assume(0<=N && N<=B);
1175\end{verbatim}
1176declares \texttt{N} and \texttt{B} to be integer inputs and restricts
1177consideration to inputs satisfying $0\leq\texttt{N}\leq\texttt{B}$.
1178
1179
1180\section{Formulas}
1181
1182A formula is a boolean expression that can be used in an assert
1183statement, assume statement, procedure contract (below), or invariant.
1184Any ordinary C boolean expression is a formula. CIVL-C provides some
1185additional kinds of formulas, described below.
1186
1187\subsection{Implication: \cimplies}
1188
1189The binary operation \cimplies{} represents logical implication.
1190The expression \verb!p=>q! is equivalent to \verb~(!p)||q~.
1191
1192\subsection{Universal quantifier: \cforall}
1193
1194The universally quantified formula has the form
1195\begin{verbatim}
1196 $forall { type identifier | restriction} expr
1197\end{verbatim}
1198where \verb!type! is a type name (e.g., \texttt{int} or
1199\texttt{double}), \verb!identifier! is the name of the bound variable,
1200\verb!restriction! is a boolean expression which expresses some
1201restriction on the values that the bound variable can take, and
1202\verb!expr! is a formula. The universally quantified formula
1203holds iff for all values assignable to the bound variable
1204for which the restriction holds, the formula \ct{expr} holds.
1205
1206A variation on the construct above can be used in the special case
1207where the bound variable is to range over a finite interval
1208of integers. In this case the quantified formula may be written:
1209\begin{verbatim}
1210 $forall { type identifier=lower .. upper } expr
1211\end{verbatim}
1212where \ct{lower} and \ct{upper} are integer expressions.
1213
1214\subsection{Existential quantifier: \cexists}
1215
1216The syntax for existentially quantified expressions is exactly the
1217same as for universally quantified expressions, with \cexists{} in
1218place of \cforall{}.
1219
1220\section{Contracts}
1221
1222\subsection{Procedure contracts: \crequires{} and \censures{}}
1223The \crequires{} and \censures{} primitives are used to encode
1224procedure contracts. There are optional
1225elements that may occur in a procedure declaration or definition,
1226as follows. For a function prototype:
1227\begin{verbatim}
1228 T f(...)
1229 $requires expr;
1230 $ensures expr;
1231 ;
1232\end{verbatim}
1233For a function definition:
1234\begin{verbatim}
1235 T f(...)
1236 $requires expr;
1237 $ensures expr;
1238 {
1239 ...
1240 }
1241\end{verbatim}
1242The value \cresult{} may be used in post-conditions to refer
1243to the result returned by a procedure.
1244
1245\emph{Status}: parsed, but nothing is currently done with this
1246information.
1247
1248\subsection{Loop invariants: \cinvariant}
1249
1250This indicates a loop invariant. Each C loop
1251construct has an optional invariant clause as follows:
1252\begin{verbatim}
1253 while (expr) $invariant (expr) stmt
1254 for (e1; e2; e3) $invariant (expr) stmt
1255 do stmt while (expr) $invariant (expr) ;
1256\end{verbatim}
1257The invariant encodes the claim that if \texttt{expr} holds upon
1258entering the loop and the loop condition holds, then it will hold
1259after completion of execution of the loop body. The invariant is used
1260by certain verification techniques.
1261
1262\emph{Status:} parsed, but nothing is currently done with this
1263information.
1264
1265\section{Concurrency specification}
1266
1267\subsection{Remote expressions: \texttt{e@x}}.
1268
1269These have the form \verb!expr@x! and refer to a variable in another
1270process, e.g., \verb!procs[i]@x!. This special kind of expression is
1271used in collective expressions, which are used to formulate collective
1272assertions and invariants.
1273
1274The expression \verb!expr! must have \cproc{} type. The variable
1275\texttt{x} must be a statically visible variable in the context in
1276which it is occurs. When this expression is evaluated, the evaluation
1277context will be shifted to the process referred to by \texttt{expr}.
1278
1279\emph{Status}: not implemented.
1280
1281\subsection{Collective expressions: \ccollective}. These have the form
1282\begin{verbatim}
1283 $collective(proc_expr, int_expr) expr
1284\end{verbatim}
1285This is a collective expression over a set of processes. The
1286expression \texttt{proc{\U}expr} yields a pointer to the first element
1287of an array of \cproc. The expression \texttt{int{\U}expr} gives the
1288length of that array, i.e., the number of processes. Expression
1289\texttt{expr} is a boolean-valued expression; it may use remote
1290expressions to refer to variables in the processes specified in the
1291array. Example:
1292\begin{verbatim}
1293 $proc procs[N];
1294 ...
1295 $assert $collective(procs, N) i==procs[(pid+1)%N]@i ;
1296\end{verbatim}
1297
1298\emph{Status}: not implemented.
1299
1300\chapter{Pointers and Heaps}
1301\label{chap:pointers}
1302
1303CIVL-C supports pointers, using the same operators with the same
1304meanings as C (\texttt{\&}, \texttt{*}, pointer arithmetic). There is
1305also a heap in every scope, and system functions to allocate and
1306deallocate objects in the specified scope.
1307
1308\section{Memory functions: \texttt{memcpy}}
1309
1310The function \texttt{memcpy} is defined in the standard C library
1311\texttt{string.h} and works exactly the same in CIVL: it copies
1312data from the region pointed to by \ct{q} to that pointed to by
1313\ct{p}. The signature is
1314
1315\begin{verbatim}
1316 void memcpy(void *p, void *q, size_t size);
1317\end{verbatim}
1318
1319\section{Heaps, \cmalloc{} and \cfree}
1320
1321As mentioned above, each dynamic scope has an implicit heap on which
1322objects can be allocated and deallocated dynamically. The CIVL-C header
1323\texttt{civlc.cvh} provides the functions \cmalloc{} and \cfree{} for allocating and dealocating
1324memory, repectively, as described in Section \ref{subsubsec:mallocandfree}.
1325
1326% \section{Pointer types}
1327
1328% Given any object type $T$ and a static scope $s$ in a CIVL-C program,
1329% there is a type \emph{pointer-to-$T$-in-$s$}. The type is used to
1330% represent a pointer to a memory location of type $T$ in scope $s$ or a
1331% descendant of $s$ (i.e., some scope contained in $s$).
1332
1333% If scope $s_1$ is a descendant of $s_2$ (i.e., $s_1$ is lexically
1334% contained in $s_2$), the type \emph{pointer-to-$T$-in-$s_1$} is a
1335% subtype of \emph{pointer-to-$T$-in-$s_2$}. This means that any
1336% expression of the first type can be used wherever an object of the
1337% second type is expected. In particular, any expression $e$ of the
1338% subtype can be assigned to a left-hand-side expression of the
1339% supertype without explicit casts; also $e$ can be used as an argument
1340% to a function for which the corresponding parameter has the supertype.
1341
1342% The syntax for denoting this type adheres to the usual C syntax for
1343% denoting the type \emph{pointer-to-$T$} with the addition of a scope
1344% parameter within angular brackets immediately following the \texttt{*}
1345% token. For example, to declare a variable \texttt{p} of type
1346% \emph{pointer-to-$T$-in-$s$}, one writes
1347% \begin{verbatim}
1348% int *<s> p;
1349% \end{verbatim}
1350% If the scope modifier \texttt{<...>} is absent, the scope is taken to
1351% be the root scope $s_0$. The object has type
1352% \emph{pointer-to-$T$-in-$s_0$}, which is abreviated as
1353% \emph{pointer-to-$T$}. In this way, stanard C programs can be
1354% interpreted as CIVL-C programs.
1355
1356% \section{Address-of operator}
1357
1358% The address-of operator \texttt{\&} returns a pointer of the
1359% appropriate subtype using the innermost scope in which its left-hand-side
1360% argument is declared. For example
1361
1362% \begin{verbatim}
1363% {
1364% $scope s1 = $here();
1365% int x;
1366% double a[N];
1367% int *<s1> p = &x;
1368% double *<s1> q = &a[2];
1369% }
1370% \end{verbatim}
1371% is correct (in particular, it is type-correct) because \texttt{\&x}
1372% has type \emph{pointer-to-\texttt{int}-in-\texttt{s1}}, since
1373% \texttt{s1} is the scope in which \texttt{x} is declared.
1374
1375% Another pointer example:
1376% \begin{small}
1377% \begin{verbatim}
1378% { $scope s0 = $here();
1379% { $scope s1 = $here();
1380% double x;
1381% { $scope s2 = $here();
1382% double y;
1383% double *<s1> p;
1384% /* p can only point to something in s1 or descendant, for example, s2 */
1385% p = &x; // fine
1386% p = &y; // fine
1387% p = (double*)$malloc(s0, 10*sizeof(double)); // static type error
1388% }
1389% }
1390% }
1391% \end{verbatim}
1392% \end{small}
1393
1394% \section{Pointer addition and subtractions}
1395
1396% If \texttt{e} is an expression of type \emph{pointer-to-$T$-in-$s$}
1397% and \texttt{i} is an expression of integer type then \texttt{e+i} also
1398% has type \emph{pointer-to-$T$-in-$s$}. In other words, pointer
1399% addition cannot leave the scope of the original pointer. This
1400% reflects the fact that every object is contained in one scope, and
1401% pointer addition cannot leave the object.
1402
1403% Pointer subtraction is defined on two pointers of the same type, where
1404% ``same'' includes the scope. That is checked statically. As in C, it
1405% is only defined if the two pointers point to the same object. In
1406% CIVL-C, a runtime error will be thrown if they do not point to the
1407% same object.
1408
1409% \section{Semantics of scopes and pointer types}
1410
1411% A variable of type \cscope{} is treated like any other variable.
1412% It becomes part of the state when the scope in which it is declared
1413% is instantiated to form a dynamic scope. The variable is
1414% initialized at that time and its value cannot change.
1415
1416% Each time a dynamic scope is instantiated, it is assigned a unique ID
1417% number. The exactly value of the ID number is not relevant, it just
1418% has to be distince from any other scope ID number that currently
1419% exists in the state. This is the value that is assigned to the scope
1420% variable. Therefore, if a static scope contains a scope variable, and
1421% that scope is instantiated twice to form two distinct dynamic scopes,
1422% the values assigned to the two variables will be distinct.
1423
1424% A pointer value is an ordered pair $\langle \delta,r \rangle$, where
1425% $\delta$ is a dynamic scope ID and $r$ is a reference to a memory
1426% location in the static scope associated to $\delta$. (We will define
1427% the exact form of a reference later.)
1428
1429% When a dynamic scope is instantiated, each new variable created is
1430% assigned a \emph{dynamic type}. This is a refinement of the static
1431% type associated to the static variable. Every dynamic type
1432% is an instance of exactly one static type. The dynamic
1433% type of the newly instantiated variable is an instance of the
1434% static type of the static variable.
1435
1436% The dynamic pointer types have the form
1437% \emph{pointer-to-$t$-in-$\delta$}, where $t$ is a dynamic type and
1438% $\delta$ is a dynamic scope ID. For a program to be dynamically type
1439% safe, such a variable should hold only values of the form $\langle
1440% \delta, r\rangle$. In particular, the variable should never be
1441% assigned a value where the dynamic scope component is a different
1442% instance of the static scope $s$ associated to $\delta$.
1443
1444% \section{Pointer casts}
1445
1446% If scope $s_1$ is contained in scope $s_2$, an expression of type
1447% \emph{pointer-to-$T$-in-$s_1$} can always be cast to
1448% \emph{pointer-to-$T$-in-$s_2$},
1449% because the first is a subtype of the second. (As described above,
1450% the cast is unnecessary.)
1451
1452% The cast in the other direction is also allowed, but the dynamic type
1453% safety of that cast will only be checked at runtime. In particular, a
1454% runtime error will result if the cast attempts to cast the pointer
1455% value to a dynamic scope which does not contain (is an ancestor of)
1456% the dynamic scope component of the pointer value.
1457
1458% A type \emph{pointer-to-$T_1$-in-$s$} can be cast to a type
1459% \emph{pointer-to-$T_2$-in-$s$} according to the usual rules of C. In
1460% other words, usual casting rules apply as long as you don't change the
1461% scope.
1462
1463% \section{Scope-Parameterized Functions}
1464
1465% Coming soon. (Parsed, type checked, not currently used otherwise.)
1466
1467% \section{Scope-Parameterized Type Definitions}
1468
1469% Coming soon. (Ditto.)
1470
1471\chapter{Libraries}
1472
1473\section{Standard CIVL-C headers}
1474CIVL-C headers have the suffix \texttt{.cvh}. Here is the list of standard libraries provided by CIVL:
1475\begin{itemize}
1476\item \texttt{civlc} provides types and functions that are used frequently by CIVL-C programs;
1477\item \texttt{scope} provides utility functions related to dynamic scopes;
1478\item \texttt{pointer} provides utility functions dealing with pointers;
1479\item \texttt{seq} provides utility functions of sequences (realized as incomplete array in CIVL-C);
1480\item \texttt{concurrency} provides concurrency utilities such as the barrier;
1481\item \texttt{bundle} provides bundle types and methods;
1482\item \texttt{comm} provides communicators and methods;
1483%\item \texttt{civlmpi} provides CIVL-C types for MPI.
1484\end{itemize}
1485
1486\subsection{CIVL basics \texttt{civlc.cvh}}
1487\label{subsec:civlcLibrary}
1488The header \texttt{civlc.cvh} declares four types, three macros and several functions. The types declared are \texttt{size\_t}, \texttt{\$proc},
1489\texttt{\$scope} and \texttt{\$int\_iter}. The declared macros are \texttt{\$true}, \texttt{\$false} and \texttt{NULL}. The functions provided in this header
1490will be described in the following.
1491
1492\subsubsection{The \cassert\ and \cassume\ functions}
1493\label{subsubsec:wait}
1494The \cassert\ and \cassume \ functions have the following signatures
1495\begin{verbatim}
1496 void $assert(_Bool expr, ...);
1497 void $assume(_Bool expr);
1498\end{verbatim}
1499
1500Information about them could be found in Section~\ref{sec:assertionAndAssumption}.
1501
1502\subsubsection{The \cwait\ function}
1503\label{subsubsec:wait}
1504The \cwait\ function has signature
1505\begin{verbatim}
1506 void $wait($proc p);
1507\end{verbatim}
1508
1509When invoked, this function will not return until the process
1510referenced by \ct{p} has terminated. Note that $p$ can be any
1511expression of type \cproc{}, not just a variable.
1512
1513\subsubsection{The \cwaitall\ function}
1514\label{subsubsec:waitall}
1515The $\cwaitall$ function has signature
1516\begin{verbatim}
1517 void $waitall($proc *procs, int numProcs);
1518\end{verbatim}
1519When invoked, this function will not return until all the \ct{numProcs} processes
1520referenced by the memory specified by \ct{procs} have terminated.
1521
1522\subsubsection{The \cexit\ function}
1523\label{subsubsec:exit}
1524This function takes no arguments. It causes the
1525calling process to terminate immediately, regardless of the state of
1526its call stack:
1527\begin{verbatim}
1528 void $exit(void);
1529\end{verbatim}
1530
1531\subsubsection{The \cchooseint{} function}
1532\label{subsubsec:chooseint}
1533
1534The function \cchooseint{} has the following signature:
1535\begin{verbatim}
1536 int $choose_int(int n);
1537\end{verbatim}
1538This function takes as input a positive integer \texttt{n} and
1539nondeterministicaly returns an integer in the range
1540$[0,\texttt{n}-1]$.
1541
1542\subsubsection{The \cscopedefined{} function}
1543\label{subsubsec:scopedefined}
1544
1545The function \cscopedefined{} has signature
1546\begin{verbatim}
1547 _Bool $scope_defined($scope s);
1548\end{verbatim}
1549It returns \emph{true} if the dynamic scope specified by \texttt{s} is
1550defined, else it returns \emph{false}.
1551
1552\subsubsection{The \cprocdefined{} function}
1553\label{subsubsec:procdefined}
1554
1555The function \cprocdefined{} has signature
1556\begin{verbatim}
1557 _Bool $proc_defined($proc p);
1558\end{verbatim}
1559
1560It returns \ctrue if and only if the given object of \cproc{} type is defined.
1561
1562
1563\subsubsection{The heap-related functions: \cmalloc{} and \cfree}
1564\label{subsubsec:mallocandfree}
1565
1566The memory allocation function $\cmalloc$ is like C's \texttt{malloc}, but takes
1567an extra scope argument:
1568\begin{verbatim}
1569 void * $malloc($scope scope, int size);
1570\end{verbatim}
1571To allocate an object, one first needs a reference to the dynamic scope to be used.
1572
1573The function \cfree{} is used to deallocate a heap object;
1574it is just like C's \texttt{free}:
1575\begin{verbatim}
1576 void $free(void *p);
1577\end{verbatim}
1578An error is generated if the pointer is not one that was returned by
1579\cmalloc, or if it was already freed.
1580
1581\subsection{Scope utilities \texttt{scope.cvh}}
1582\label{subsec:scopeLibrary}
1583
1584The header \texttt{scope.cvh} declares one function: \texttt{\$scope\_parent}, which has signature
1585
1586\begin{verbatim}
1587 $scope $scope_parent($scope s);
1588\end{verbatim}
1589This function returns the parent dynamic scope of the dynamic scope referenced by
1590\ct{s}. If \ct{s} is the root dynamic scope, it returns the undefined
1591value of type $\cscope$.
1592
1593\subsection{Pointer utilities \texttt{pointer.cvh}}
1594\label{subsec:pointerLibrary}
1595The header \texttt{pointer.cvh} declares functions taking pointers as the arguments for different purposes, including:
1596\begin{itemize}
1597\item function \cequals{} for equality checking;
1598\item function \ccontains{} for membership testing;
1599\item function \texttt{\$translate\_ptr} for pointer translation;
1600\item function \ccopy{} for copying data through pointers.
1601\end{itemize}
1602
1603\subsubsection{The \cequals{} function}
1604
1605The \cequals{} function has the signature
1606\begin{verbatim}
1607 _Bool $equals(void *x, void *y);
1608\end{verbatim}
1609
1610This function takes two non-null pointers as input. If the two objects that the pointers refer to have the same value, then the
1611function returns \ctrue. Otherwise, it returns \cfalse.
1612
1613\subsubsection{The \ccontains{} function}
1614
1615The function \ccontains{} has the signature
1616\begin{verbatim}
1617 _Bool $contains(void *ptr1, void *ptr2);
1618\end{verbatim}
1619
1620This function takes two non-null pointers as input. If the object that the pointer \texttt{ptr1} points to contains the object pointed to by \texttt{ptr2}, then the
1621function returns \ctrue. Otherwise, it returns \cfalse. For example, given
1622\begin{verbatim}
1623 int a[10];
1624 struct foo {int x; double y} f;
1625 struct foo b[10];
1626
1627 // ... initialize a, f and b
1628\end{verbatim}
1629
1630Here are the results of several invocations of \ccontains:
1631
1632\begin{itemize}
1633\item \texttt{\ccontains(\&a, \&a[3])} returns \ctrue, since the array \texttt{a} contains the cell \texttt{a[3]};
1634\item \texttt{\ccontains(\&a[2], \&a[3])} returns \cfalse;
1635\item \texttt{\ccontains(\&a[2], \&a[2])} returns \ctrue, because the relation is relexive;
1636\item \texttt{\ccontains(\&f, \&f.y)} returns \ctrue, since the struct \texttt{f} contains its field \texttt{f.y};
1637\item \texttt{\ccontains(\&b, \&b[2].x)} returns \ctrue.
1638\end{itemize}
1639
1640\subsubsection{The \texttt{\$translate\_ptr} function}
1641The function \texttt{\$translate\_ptr} has the signature
1642\begin{verbatim}
1643 void * $translate_ptr(void *ptr, void *obj);
1644\end{verbatim}
1645
1646This function translates a pointer into one object (\texttt{ptr}) to a pointer into a different object (\texttt{obj}) with similar structure.
1647
1648For example:
1649\begin{verbatim}
1650 typedef struct node{
1651 int x;
1652 int y;
1653 } node;
1654 typedef struct point{
1655 double a;
1656 double b;
1657 double c;
1658 }point;
1659 node nodes[3];
1660 point points[5];
1661 ... // initialize nodes and points
1662 double *p = $translate_ptr(&(nodes[2].y), &points);
1663 // after the translation, p = &(points[2].b);
1664\end{verbatim}
1665
1666\subsubsection{The \ccopy{} function}
1667
1668The \ccopy{} function has the signature
1669\begin{verbatim}
1670 void $copy(void *ptr, void *value_ptr);
1671\end{verbatim}
1672
1673It copies the value pointed to by \texttt{value\_ptr} to the memory
1674location specified by \texttt{ptr}. This function is different from \texttt{memcpy} only in the way that
1675it can take pointers to (incomplete) array as the argument and copy the whole array to the other.
1676
1677\subsection{Sequence utilities \texttt{seq.cvh}}
1678\label{subsec:seqLibrary}
1679The header \texttt{seq.cvh} provides utility functions dealing with sequences. A sequence is realized as an incomplete array (i.e., an array with no extent specified) of any type \texttt{T}, which applies for all functions of \texttt{seq.cvh}. Functions declared in this header include:
1680\begin{itemize}
1681\item function \cseqinit{} for initializing sequences;
1682\item function \cseqlen{} for computing the length of a sequence;
1683\item function \cseqinsert{} for element insertion to a sequence;
1684\item function \cseqrm{} for element removal of a sequence.
1685\end{itemize}
1686
1687\subsubsection{The \cseqinit{} function}
1688
1689The \cseqinit{} function has the signature
1690\begin{verbatim}
1691 void $seq_init(void *seq, int count, void *value);
1692\end{verbatim}
1693
1694Given a pointer to a sequence of type \texttt{T}, this function sets that sequence to be an array of length \texttt{count} in which every element has the same value, specified by the given pointer \texttt{value}. The parameter \texttt{seq} has the type pointer-to-incomplete-array-of-T, \texttt{count} has any integer type and must be nonnegative, and \texttt{value} has the type pointer-to-T.
1695
1696\subsubsection{The \cseqlen{} function}
1697The \cseqlen{} function has the signature
1698\begin{verbatim}
1699 int $seq_length(void *seq);
1700\end{verbatim}
1701This function returns the length of the sequence pointed to by the pointer \texttt{seq}. The contract is that \texttt{seq} must be a pointer of a sequence of type \texttt{T}, i.e., \texttt{seq} should have the type pointer-to-incomplete-array-of-T.
1702
1703\subsubsection{The \cseqinsert{} function}
1704The \cseqinsert{} function has the signature
1705\begin{verbatim}
1706 void $seq_insert(void *seq, int index, void *values, int count);
1707\end{verbatim}
1708
1709Given a pointer to a sequence of type T, this function inserts \texttt{count} elements into the sequence starting at position
1710 \texttt{index}. The subsequence elements of the original sequence are shifted up, and the final length of the array will be its original length
1711plus \texttt{count}. The values to be inserted are taken from the region specified by \texttt{values}, which has type pointer-to-T.
1712
1713It is required that \texttt{0<=index<=length}, where length is the orginal length of the seqence. If \texttt{index=length}, this function appends the elements to the end of the array. If \texttt{index=0}, this inserts the elements at the beginning of the sequence. If \texttt{count=0}, this function is a no-op and \texttt{values} will never be evaluated (hence may be NULL).
1714
1715\subsubsection{The \cseqrm{} function}
1716The \cseqrm{} function has the signature
1717\begin{verbatim}
1718 void $seq_remove(void *seq, int index, void *values, int count);
1719\end{verbatim}
1720
1721This function removes \texttt{count} elements from the sequence of type T pointed to by \texttt{seq}, starting at position
1722\texttt{index}.
1723
1724If \texttt{values} is not NULL, the removed elements will be copied to the memory region beginning with \texttt{values}, which shoud have the type pointer-to-T. It is required that \texttt{0<=index<length} and \texttt{0<=count<=length-index}. If \texttt{count=0}, this function is a no-op.
1725
1726\subsection{Concurrency utilities \texttt{concurrency.cvh}}
1727\label{subsec:concurrencyLibrary}
1728
1729The header \texttt{concurrency.cvh} declares two types,, \cgbarrier{} and \cbarrier{}, and several functions dealing with barriers, including:
1730\begin{itemize}
1731\item functions \cgbarriercreate{} and \cbarriercreate{} for creating a new global and local barrier, repectively;
1732\item functions \cgbarrierdestroy{} and \cbarrierdestroy{} for destroying a global and local barriere, respectively;
1733\item function \cbarriercall{} for a barrier synchronization request.
1734\end{itemize}
1735
1736
1737\subsubsection{The \cgbarriercreate{} and \cbarriercreate{} functions}
1738The \cgbarriercreate{} function has the signature
1739
1740\begin{verbatim}
1741 $gbarrier $gbarrier_create($scope scope, int size);
1742\end{verbatim}
1743
1744It creates a new global object of the given \texttt{size}, puts it in the heap of the given dynamic \texttt{scope}, and returns a handle to the created \cgbarrier{} object.
1745\\~\\
1746The \cbarriercreate{} function has the signature
1747
1748\begin{verbatim}
1749 $barrier $barrier_create($scope scope, $gbarrier gbarrier, int place);
1750\end{verbatim}
1751
1752It creates a local barrier that joins the specified global barrier \texttt{gbarrier} with the id \texttt{place}. The new local barrier object is stored in the heap of the given dynamic \texttt{scope} , and a handle to that object is returned.
1753
1754\subsubsection{The \cgbarrierdestroy{} and \cbarrierdestroy{} functions}
1755
1756The \cgbarrierdestroy{} and \cbarrierdestroy{} functions has the signatures
1757
1758\begin{verbatim}
1759 void $gbarrier_destroy($gbarrier barrier);
1760 void $barrier_destroy($barrier barrier);
1761\end{verbatim}
1762
1763These functions deallocated the heap memory regions occupied by the specified \cgbarrier{} or \cbarrier{} object. They should be invoked before the corresponding dynamic scope becomes unreachable. Otherwise, a memory leak error will be reported.
1764
1765\subsubsection{The \cbarriercall{} function}
1766
1767The \cbarriercall{} function has the signature
1768
1769\begin{verbatim}
1770 void $barrier_call($barrier barrier);
1771\end{verbatim}
1772
1773When this funciton is called, the calling process will be blocked until all other processes associated with the same global barrier refered to by the given \texttt{barrier} have made the barrier call.
1774
1775\subsection{Bundle type and functions \texttt{bundle.cvh}}
1776\label{subsec:bundleLibrary}
1777
1778The header \texttt{bundle.cvh} defines the type \cbundle{} (see Section \ref{subsec:bundleType}) and several functions dealing with bundles:
1779\begin{itemize}
1780\item function \cbundlesize{} for computing the size of a bundle;
1781\item function \cbundlepack{} for composing a bundle from some given data;
1782\item function \cbundleunpack{} for extracting the data contained by a given bundle;
1783\item function \cbundleunpackapply{} for extacting the data contained by a given bundle and apply some operation to them.
1784\end{itemize}
1785
1786\subsubsection{The \cbundlesize{} function}
1787
1788The \cbundlesize{} function has the signature
1789\begin{verbatim}
1790 int $bundle_size($bundle b);
1791\end{verbatim}
1792
1793It takes a bundle and returns its size.
1794
1795\subsubsection{The \cbundlepack{} function}
1796
1797The \cbundlepack{} function has the signature
1798\begin{verbatim}
1799 $bundle $bundle_pack(void *ptr, int size);
1800\end{verbatim}
1801
1802This function creates a bundle from the memory region specified by \texttt{ptr} and \texttt{size}, copying the data into the new bundle, and returns the new bundle.
1803
1804\subsubsection{The \cbundleunpack{} function}
1805
1806The \cbundleunpack{} function has the signature
1807\begin{verbatim}
1808 void $bundle_unpack($bundle bundle, void *ptr);
1809\end{verbatim}
1810
1811Opposite to \cbundlepack, this function copies the data from the given \texttt{bundle} into the memory region specified by \texttt{ptr}.
1812
1813\subsubsection{The \cbundleunpackapply{} function}
1814
1815The \cbundleunpackapply{} function has the signature
1816\begin{verbatim}
1817 void $bundle_unpack_apply($bundle data, void *buf, int size, $operation op);
1818\end{verbatim}
1819
1820This function unpacks the bundle and applies the specified operation on the content of the bundle. For every binary operarion defined in operation, the content of the bundle will be used as the left operand and buf will be used as the right operand. The result of the operation is stored in buf once is it is done.
1821
1822
1823\subsection{Communicators \texttt{comm.cvh}}
1824\label{subsec:commLibrary}
1825
1826The header \texttt{comm.cvh} declares three types, two macros and a number of functions for communication. The two maros are \texttt{\$COMM\_ANY\_SOURCE} and \texttt{\$COMM\_ANY\_TAG}. The three types declared are \cmessage, \cgcomm{} and \ccomm.
1827
1828\subsubsection{Messaging functions}
1829\label{subsubsec:messaging}
1830
1831The function \cmessagesize{} returns the size of a given message and has the signature
1832
1833\begin{verbatim}
1834 int $message_size($message message);
1835\end{verbatim}
1836
1837\noindent The function \cmessagesource{} returns the source of a given message and has the signature
1838
1839\begin{verbatim}
1840 int $message_source($message message);
1841\end{verbatim}
1842
1843\noindent The function \cmessagedest{} returns the destination of a given message and has the signature
1844
1845\begin{verbatim}
1846 int $message_dest($message message);
1847\end{verbatim}
1848
1849\noindent The function \cmessagetag{} returns the tag of a given message and has the signature
1850
1851\begin{verbatim}
1852 int $message_tag($message message);
1853\end{verbatim}
1854
1855\noindent The function \cmessagepack{} has the signature
1856
1857\begin{verbatim}
1858 $message $message_pack(int source, int dest, int tag, void *data, int size);
1859\end{verbatim}
1860
1861This function creates a new message of the specified \texttt{source}, \texttt{dest} and \texttt{tag}, copying data from the memory region specified \texttt{data} and \texttt{size}, and returns the newly created message object.
1862\\~\\
1863\noindent The function \cmessageunpack{} has the signature
1864
1865\begin{verbatim}
1866 void $message_unpack($message message, void *buf, int size);
1867\end{verbatim}
1868
1869This function transfers data from \texttt{message} the memory region specified by \texttt{buf} and \texttt{size}, reproting an error if the size of the message exceeds the specified \texttt{size}.
1870
1871\subsubsection{\cgcomm{} functions}
1872\label{subsubsec:gcomm}
1873
1874\begin{verbatim}
1875/* Creates a new global communicator object and returns a handle to it.
1876 * The global communicator will have size communication places. The
1877 * global communicator defines a communication "universe" and encompasses
1878 * message buffers and all other components of the state associated to
1879 * message-passing. The new object will be allocated in the given scope. */
1880$gcomm $gcomm_create($scope s, int size);
1881
1882void $gcomm_destroy($gcomm gcomm); // Destroys the gcomm
1883
1884_Bool $gcomm_defined($gcomm gcomm); // Is the gcomm object defined?
1885\end{verbatim}
1886
1887\subsubsection{\ccomm{} functions}
1888\label{subsubsec:comm}
1889
1890\begin{verbatim}
1891
1892/* Creates a new local communicator object and returns a handle to it.
1893 * The new communicator will be affiliated with the specified global
1894 * communicator. The new object will be allocated in the given scope. */
1895$comm $comm_create($scope s, $gcomm gcomm, int place);
1896
1897void $comm_destroy($comm comm); // Destroys the comm
1898
1899_Bool $comm_defined($comm comm); // Is the comm object defined?
1900
1901/* Returns the size (number of places) in the global communicator associated
1902 * to the given comm. */
1903int $comm_size($comm comm);
1904
1905/* Returns the place of the local communicator. This is the same as the
1906 * place argument used to create the local communicator. */
1907int $comm_place($comm comm);
1908
1909/* Adds the message to the appropriate message queue in the communication
1910 * universe specified by the comm. The source of the message must equal
1911 * the place of the comm. */
1912void $comm_enqueue($comm comm, $message message);
1913
1914/* Returns true iff a matching message exists in the communication universe
1915 * specified by the comm. A message matches the arguments if the destination
1916 * of the message is the place of the comm, and the sources and tags match. */
1917_Bool $comm_probe($comm comm, int source, int tag);
1918
1919/* Finds the first matching message and returns it without modifying
1920 * the communication universe. If no matching message exists, returns a message
1921 * with source, dest, and tag all negative. */
1922$message $comm_seek($comm comm, int source, int tag);
1923
1924/* Finds the first matching message, removes it from the communicator,
1925 * and returns the message */
1926$message $comm_dequeue($comm comm, int source, int tag);
1927\end{verbatim}
1928
1929\section{C libraries}
1930
1931Each of the following libraries is at least partially implemented and can
1932be included in a CIVL-C program:
1933\begin{itemize}
1934\item \ct{assert}
1935 \begin{itemize}
1936 \item \verb!void assert(_Bool expr);!\\This is equivalent to an \cassert{} statement without error messages.
1937 \end{itemize}
1938\item \ct{math}
1939 \begin{itemize}
1940 \item \verb!double sqrt(double x);!
1941 \item \verb!double ceil(double x);!
1942 \item \verb!double exp(double x);!
1943 \end{itemize}
1944\item \ct{stdlib}
1945 \begin{itemize}
1946 \item \verb!size_t!
1947 \item \verb!void * malloc(size_t size);!\\
1948 This is equivalent to \verb!$malloc($root, size)!.
1949 \item \verb!void free(void * ptr);!\\
1950 This is identical to \verb!$free(ptr)!.
1951 \end{itemize}
1952\item \ct{stdbool}
1953 \begin{itemize}
1954 \item \verb!true!\\
1955 This is equivalent to \ctrue.
1956 \item \verb!false!\\
1957 This is equivalent to \cfalse.
1958 \end{itemize}
1959\item \ct{stddef}
1960 \begin{itemize}
1961 \item \verb!size_t!
1962 \item \verb!NULL!
1963 \end{itemize}
1964\item \ct{stdio}
1965 \begin{itemize}
1966 \item \verb!int printf(const char * restrict format, ...);!
1967 \end{itemize}
1968\item \ct{string}
1969 \begin{itemize}
1970 \item \verb!size_t!
1971 \item \verb!NULL!
1972 \item \verb!void memcpy(void * restrict dst, const void * restrict src, size_t n);!
1973 \end{itemize}
1974\end{itemize}
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