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C02/doc/small-c.txt

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Types
char — 8 bit data element
int — 16 bit data element
Declarations
type name — declares name to be element
type *name — declares name to be pointer to element of specified type
type name[] — syntactically identical to above pointer declaration
type name[constant] — declares an array of "constant” size where
each array element is of specified type
Constants
Decimal number.
Single or pair of ASCII characters enclosed in single quotes,
such as a or T X .
String enclosed in double quotes, such as “this is a string”.
The value such a constant yields is a pointer to the first character
of the string which the compiler stores in memory.
Function Calls
Defined as any expression followed by an open paren. Thus, a function
can be to a named routine, such as “print()” , or to the results of some
expression, such as “1000()” (which calls location 1000 decimal), or
“array[i]()” which calls the location whose value is found in array[i] .
Subscripted elements.
Either an array name or a pointer may be subscripted to refer to the
appropriate element. Subscripts are assumed to start from zero. Therefore,
legal expressions are:
array [0] - the first element in array,
array [x+31] — the element at the address given by adding x to 31
and then to array,
pointer [i] — the elemen t at the address given by adding i to the
contents of pointer.
Only single dimensions are allowed. Subscripting either an integer array
or a pointer to an integer will cause the subscript expression to be
doubled. Therefore, if you declare “int *ptr”, the expression “ptr[3]”
refers to the element at ptr+6.
Unary Expression Operators
"-" — forms the twos complement of the expression (minus).
“*” — refers to the element pointed to by the expression
(providing the expression is a pointer).
“&” — evaluates the address of the given expression, providing
it hasone. Hence, &count yields the address of the element
“count”. &1000 is an error.
“&” — increments the expression by one. If this appears before the
expression, it increments before using it. If it appears after
it, it will increment it after. Only values (expressions which
can appear on the left-hand side of an equal sign) are allowed.
Hence, assuming “count” contains a 5, ++count would evaluate to
a 6, and “count” would contain a 6. Likewise, count++ would
evaluate to a 5, and count would contain a 6. 1000++ is illegal.
If this operator is applied to an integer pointer, it will
increment by 2.
"--" — decrements the expression by one. This works just like ++ but
subtracts one rather than adding.
Binary Operators
“+” — adds the two expressions (i.e. count + total)
"-" — subtracts the two expressions.
“*” — multiplies the two expressions.
“/” — divides the first expression by the second.
"%" — yields the remainder after dividing the first expression
by the second (modulo).
“|” — yields the logical inclusive “or” of the two expressions.
"^" — yields the logical exclusive “or” of the two expressions.
"&" — yields the logical “and” of the two expressions.
“=” — assigns the value of the expression on the right to the one
on the left. Since evaluation is done right to left in this
case, syntaxes like "x = y = z" are legal.
Comparison Operators
“==” — tests for equality.
“==” — tests for inequality.
“<” — tests for less than.
“>” — tests for greater than.
“<=” — tests for less than or equal to
“>=” — tests for greater than or equal to
Comparisons involving a pointer (which is an address) are done
as unsigned compares. All other compares are signed.
Statements
expression; An expression, no matter how complex, is considered
a simple statement.
if (expression); If the expression is non-zero, the statement
is executed , otherwise it isnt.
if (expression) statement; else statement; This form of the “if”
statement allows the “else” clause. As is the case with most
“dangling else” ambiguities, all “else" statements pair with
the nearest unmatched “if".
while (expression) statement; The statement is performed until
the expression becomes zero. Since the test is made before the
statement is executed the first time, it need not be executed
at all.
break; This statement will cause control to be transferred out
of the inner-most “while” loop.
continue; This statement, used within a “while” loop, will transfer
control back to the top of the loop.
return; This statement does an immediate return from the current
function . If a function does not end with this statement, one
is performed regardless.
return expression; This statement allows a function to return a
value explicitly.
; A semicolon by itself is considered a null statement which does
nothing but take the place of a statement. You see this in forms
such as: “while (*iptr++ = *jptr++);” where the test itself
contains all the necessary parts of the statement.
{statement; statement;. . . ; statement;} The use of curly brackets
(“{ }”) around any group of simple statements is considered a
compound statement. A compound statement can be used anywhere a
simple statement can. For example:
while (1) {x = 3; y = 10; funct(33);}
or
if (x< y)
{ print(x);
total (x);
--x;
}
else
{ type(“all done”);
x = y;
}
Pseudo-ops
#include filename — Anywhere this statement appears in the program,
the indicated filename will be opened and inserted. The “included”
file may not contain an “#include” statement.
#define name string — This statement will cause the given name to
be replaced by the string throughout the entire program . Normally,
it is used to define constants, such as:
#define tablesize 1000
#define maxlength 8
But it can also be used for any sort of text:
#define jprint 3crs print(12); print(12); print(l2);
The replacem ent is purely on a text level, and error checking will
be performed only after the replacement.
#asm . . . #endasm — This structure is not supported by standard C,
but it was a feature I felt I needed. It may appear anywhere a statement
would, but it passes everything between the word “#asm” and the word
“#endasm” right through the parser without intervention. It is intended
to be used to pass assembly language code through the parsing mechanism.
Since it counts as a single statement, allowable (and expected) forms are:
if (x < y)
#asm
LHLD TOTAL
CALL ADD
CNC ERROR
#end asm
else return;
This pseudo-op conceivably allows an entire assembly language program to
be passed through the compiler. Its intent is to allow machine dependent
features (like the 8080s “IN” and “OUT” instructions to be used without
writing separate programs).