Understanding weird logical operators in smalltalk - smalltalk

So my problem is the following:
When char = 0
boolean = char ~= 0 & char ~= 256
evaluates to true and if I invert the statements like so:
boolean = char ~= 256 & char ~= 0
I get false.
What's happening?. I am expecting false on both cases.

As #Uko said, you must understand the precedence of messages: all binary messages (+ = < & ~= etc..) are evaluated from left to right.
Thus you evaluate:
(((boolean = char) ~= 256) & char) ~= 0
I think you were after:
boolean := (char ~= 256) & (char ~= 0).
So what happens with your expression ?
booleanis presumably unitialized (thus nil)
char is 0.
boolean = char is false.
false ~= 256 is true.
true & char is char (see below why)
char ~= 0 is false (since char = 0)
If you invert 0 and 256, only the last step changes and awnswer true.
The interesting part is the implementation of message & in class True: it probably does not assert that the parameter is a Boolean and looks like:
& aBoolean
^aBoolean
If you pass something that is not a Boolean, (like 0 in your case), it will return this thing, whatever surprising it can be...
If you use an IDE (Squeak/Pharo/Visualworks/Dolphin... but not gnu Smalltalk) I suggest you use the menu Debug It and evaluate the expression step by step in the Debugger.
Last, note that char is probably not a good name in Smalltalk context: it might be misleading. Indeed, if it holds 0, it's rather an Integer, not a Character.

There is something we are repeating in some answers that I think deserves further clarification. We say evaluation proceeds from left to right. True, but the actual semantics of messages is:
First evaluate the receiver, then the arguments in order; finally send the message.
Since the Smalltalk VM is stack based, this rule means that:
The receiver is evaluated first and the result is pushed on the stack.
The arguments are evaluated in order and their results pushed on the stack.
The message is sent
Item 3 means that the method that the send invokes will find the receiver and the arguments in the stack, in the order defined above.
For instance, in
a := 1.
b := 2.
b := a - (a := b)
variable b will evaluate to (1 - (a := 2)) = -1 and a to 2. Why? Because by the time the assignment a := b is evaluated the receiver a of the subtraction has already been pushed with the value it had at that time, i.e., 1.
Note also that this semantics must be preserved even if the VM happens to use registers instead of the stack. The reason is that evaluations must preserve the semantics, and therefore the order. This fact has an impact on the optimizations that the native code may implement.
It is interesting to observe that this semantics along with the precedence unary > binary > keyword support polymorphism in a simple way. A language that gives more precedence to, say, * than + assumes that * is a multiplication and + an addition. In Smalltalk, however, it is up to the programmer to decide the meaning of these (and any other) selectors without the syntax getting in the way of the actual semantics.
My point here is that "left to right" comes from the fact that we write Smalltalk in English, which is read from "left to right". If we implemented Smalltalk using a language that people read from "right to left" this rule would be contradicted. The actual definition, the one that will remain unchanged, is the one expressed in items 1, 2 and 3 above, which comes from the stack metaphor.

Related

Find first bit set and unset it atomically

I'm looking for instructions (x86 machine) or optimization for the following line of code:
lock()
int x = ffs(words); // find first bit that set
long words = unset(x, words); // unset the bit "x" in "words"
unlock()
I don't know how to do this without locking.
If words is an unsigned type, then the non-atomic computation can be done as follows:
words &= ~-words;
Or, equivalently
words &= words - 1;
That works because in -words (assuming 2's-complement, which unsigned types must use), the least-significant 1 and all the 0s to the right of it are unchanged, while all the bits to the left of the least significant 1 are inverted. So words & ~-words will be identical to words except for the least significant 1.
However, in order to do that atomically, you'll either need to use a lock as indicated in the question, or you'll need to do a spin-loop around an atomic compare-and-exchange.

Why does the unary bit inversion operator not invert the value of a BOOL?

I want to invert the value of a BOOL every time I detect a tap. The default value of the BOOL is NO and the first time I tap it inverts it to YES. On subsequent taps the value stays as YES.
#property(nonatomic, assign) BOOL isDayOrNight; //property in timeDayChart object.
self.timeDayChart.isDayOrNight = ~self.timeDayChart.isDayOrNight; //This is done in a VC.
I had to change it to this:
self.timeDayChart.isDayOrNight = !self.timeDayChart.isDayOrNight;
to achieve my desired results. I would like to know why ~ did not work as expected.
BOOL is defined as a signed char in objc.h:
typedef signed char BOOL;
and YES and NO are defined like so:
#define YES (BOOL)1
#define NO (BOOL)0
So ~YES is -2, which is not the same as NO.
In (Objective-)C(++) when a Boolean value is required, such as in an if or as an operand to &&, actually take an integer value and interpret 0 as false and non-zero as true. The logical, relational and equality operators all also return integers, using 0 for false and 1 for true.
Objective-C's BOOL is a synonym for signed char, which is an integer type, while NO and YES are defined as 0 and 1 respectively.
As you correctly state ~ is the bit inversion operator. If you invert any integer containing both 0's and 1's the result will also do so. Any value containing a 1 bit is treated as true, and inverting any such value other than all 1's produces a value with at least one 1 bit which is also interpreted as true.
If you start with all 0's then repeated inversion should go all 1's, all 0's, all 1's - which is true, false, true etc. (but not YES, NO, YES, etc.). So if you are starting with 0 then either you are not always using inversion or you are testing explicitly for YES rather than true.
However what you should be using, as you figured out, is ! - logical negation - which maps 0 to 1 and non-0 to 0 and so handles "true" values other than 1 correctly.
HTH
Find a book about the C language. Check what it says about the ~ operator and the ! operator. ~ inverts all bits in an integer, and BOOL is defined as an integer type. So NO = all bits zero will be changed to all bits set, which is not the same as YES, and YES = all bits zero except the last bit = 1 will be changed to all bits set except the last bit = 0.
You are better off using this idiom to toggle a BOOL value:
self.timeDayChart.isDay = self.timeDayChart.isDay ? NO : YES;
(I deliberately changed the naming of your property)

Kindly explain me this code of increment decrement operator [duplicate]

#include <stdio.h>
int main(void)
{
int i = 0;
i = i++ + ++i;
printf("%d\n", i); // 3
i = 1;
i = (i++);
printf("%d\n", i); // 2 Should be 1, no ?
volatile int u = 0;
u = u++ + ++u;
printf("%d\n", u); // 1
u = 1;
u = (u++);
printf("%d\n", u); // 2 Should also be one, no ?
register int v = 0;
v = v++ + ++v;
printf("%d\n", v); // 3 (Should be the same as u ?)
int w = 0;
printf("%d %d\n", ++w, w); // shouldn't this print 1 1
int x[2] = { 5, 8 }, y = 0;
x[y] = y ++;
printf("%d %d\n", x[0], x[1]); // shouldn't this print 0 8? or 5 0?
}
C has the concept of undefined behavior, i.e. some language constructs are syntactically valid but you can't predict the behavior when the code is run.
As far as I know, the standard doesn't explicitly say why the concept of undefined behavior exists. In my mind, it's simply because the language designers wanted there to be some leeway in the semantics, instead of i.e. requiring that all implementations handle integer overflow in the exact same way, which would very likely impose serious performance costs, they just left the behavior undefined so that if you write code that causes integer overflow, anything can happen.
So, with that in mind, why are these "issues"? The language clearly says that certain things lead to undefined behavior. There is no problem, there is no "should" involved. If the undefined behavior changes when one of the involved variables is declared volatile, that doesn't prove or change anything. It is undefined; you cannot reason about the behavior.
Your most interesting-looking example, the one with
u = (u++);
is a text-book example of undefined behavior (see Wikipedia's entry on sequence points).
Most of the answers here quoted from C standard emphasizing that the behavior of these constructs are undefined. To understand why the behavior of these constructs are undefined, let's understand these terms first in the light of C11 standard:
Sequenced: (5.1.2.3)
Given any two evaluations A and B, if A is sequenced before B, then the execution of A shall precede the execution of B.
Unsequenced:
If A is not sequenced before or after B, then A and B are unsequenced.
Evaluations can be one of two things:
value computations, which work out the result of an expression; and
side effects, which are modifications of objects.
Sequence Point:
The presence of a sequence point between the evaluation of expressions A and B implies that every value computation and side effect associated with A is sequenced before every value computation and side effect associated with B.
Now coming to the question, for the expressions like
int i = 1;
i = i++;
standard says that:
6.5 Expressions:
If a side effect on a scalar object is unsequenced relative to either a different side effect on the same scalar object or a value computation using the value of the same scalar object, the behavior is undefined. [...]
Therefore, the above expression invokes UB because two side effects on the same object i is unsequenced relative to each other. That means it is not sequenced whether the side effect by assignment to i will be done before or after the side effect by ++.
Depending on whether assignment occurs before or after the increment, different results will be produced and that's the one of the case of undefined behavior.
Lets rename the i at left of assignment be il and at the right of assignment (in the expression i++) be ir, then the expression be like
il = ir++ // Note that suffix l and r are used for the sake of clarity.
// Both il and ir represents the same object.
An important point regarding Postfix ++ operator is that:
just because the ++ comes after the variable does not mean that the increment happens late. The increment can happen as early as the compiler likes as long as the compiler ensures that the original value is used.
It means the expression il = ir++ could be evaluated either as
temp = ir; // i = 1
ir = ir + 1; // i = 2 side effect by ++ before assignment
il = temp; // i = 1 result is 1
or
temp = ir; // i = 1
il = temp; // i = 1 side effect by assignment before ++
ir = ir + 1; // i = 2 result is 2
resulting in two different results 1 and 2 which depends on the sequence of side effects by assignment and ++ and hence invokes UB.
I think the relevant parts of the C99 standard are 6.5 Expressions, §2
Between the previous and next sequence point an object shall have its stored value
modified at most once by the evaluation of an expression. Furthermore, the prior value
shall be read only to determine the value to be stored.
and 6.5.16 Assignment operators, §4:
The order of evaluation of the operands is unspecified. If an attempt is made to modify
the result of an assignment operator or to access it after the next sequence point, the
behavior is undefined.
Just compile and disassemble your line of code, if you are so inclined to know how exactly it is you get what you are getting.
This is what I get on my machine, together with what I think is going on:
$ cat evil.c
void evil(){
int i = 0;
i+= i++ + ++i;
}
$ gcc evil.c -c -o evil.bin
$ gdb evil.bin
(gdb) disassemble evil
Dump of assembler code for function evil:
0x00000000 <+0>: push %ebp
0x00000001 <+1>: mov %esp,%ebp
0x00000003 <+3>: sub $0x10,%esp
0x00000006 <+6>: movl $0x0,-0x4(%ebp) // i = 0 i = 0
0x0000000d <+13>: addl $0x1,-0x4(%ebp) // i++ i = 1
0x00000011 <+17>: mov -0x4(%ebp),%eax // j = i i = 1 j = 1
0x00000014 <+20>: add %eax,%eax // j += j i = 1 j = 2
0x00000016 <+22>: add %eax,-0x4(%ebp) // i += j i = 3
0x00000019 <+25>: addl $0x1,-0x4(%ebp) // i++ i = 4
0x0000001d <+29>: leave
0x0000001e <+30>: ret
End of assembler dump.
(I... suppose that the 0x00000014 instruction was some kind of compiler optimization?)
The behavior can't really be explained because it invokes both unspecified behavior and undefined behavior, so we can not make any general predictions about this code, although if you read Olve Maudal's work such as Deep C and Unspecified and Undefined sometimes you can make good guesses in very specific cases with a specific compiler and environment but please don't do that anywhere near production.
So moving on to unspecified behavior, in draft c99 standard section6.5 paragraph 3 says(emphasis mine):
The grouping of operators and operands is indicated by the syntax.74) Except as specified
later (for the function-call (), &&, ||, ?:, and comma operators), the order of evaluation of subexpressions and the order in which side effects take place are both unspecified.
So when we have a line like this:
i = i++ + ++i;
we do not know whether i++ or ++i will be evaluated first. This is mainly to give the compiler better options for optimization.
We also have undefined behavior here as well since the program is modifying variables(i, u, etc..) more than once between sequence points. From draft standard section 6.5 paragraph 2(emphasis mine):
Between the previous and next sequence point an object shall have its stored value
modified at most once by the evaluation of an expression. Furthermore, the prior value
shall be read only to determine the value to be stored.
it cites the following code examples as being undefined:
i = ++i + 1;
a[i++] = i;
In all these examples the code is attempting to modify an object more than once in the same sequence point, which will end with the ; in each one of these cases:
i = i++ + ++i;
^ ^ ^
i = (i++);
^ ^
u = u++ + ++u;
^ ^ ^
u = (u++);
^ ^
v = v++ + ++v;
^ ^ ^
Unspecified behavior is defined in the draft c99 standard in section 3.4.4 as:
use of an unspecified value, or other behavior where this International Standard provides
two or more possibilities and imposes no further requirements on which is chosen in any
instance
and undefined behavior is defined in section 3.4.3 as:
behavior, upon use of a nonportable or erroneous program construct or of erroneous data,
for which this International Standard imposes no requirements
and notes that:
Possible undefined behavior ranges from ignoring the situation completely with unpredictable results, to behaving during translation or program execution in a documented manner characteristic of the environment (with or without the issuance of a diagnostic message), to terminating a translation or execution (with the issuance of a diagnostic message).
Another way of answering this, rather than getting bogged down in arcane details of sequence points and undefined behavior, is simply to ask, what are they supposed to mean? What was the programmer trying to do?
The first fragment asked about, i = i++ + ++i, is pretty clearly insane in my book. No one would ever write it in a real program, it's not obvious what it does, there's no conceivable algorithm someone could have been trying to code that would have resulted in this particular contrived sequence of operations. And since it's not obvious to you and me what it's supposed to do, it's fine in my book if the compiler can't figure out what it's supposed to do, either.
The second fragment, i = i++, is a little easier to understand. Someone is clearly trying to increment i, and assign the result back to i. But there are a couple ways of doing this in C. The most basic way to add 1 to i, and assign the result back to i, is the same in almost any programming language:
i = i + 1
C, of course, has a handy shortcut:
i++
This means, "add 1 to i, and assign the result back to i". So if we construct a hodgepodge of the two, by writing
i = i++
what we're really saying is "add 1 to i, and assign the result back to i, and assign the result back to i". We're confused, so it doesn't bother me too much if the compiler gets confused, too.
Realistically, the only time these crazy expressions get written is when people are using them as artificial examples of how ++ is supposed to work. And of course it is important to understand how ++ works. But one practical rule for using ++ is, "If it's not obvious what an expression using ++ means, don't write it."
We used to spend countless hours on comp.lang.c discussing expressions like these and why they're undefined. Two of my longer answers, that try to really explain why, are archived on the web:
Why doesn't the Standard define what these do?
Doesn't operator precedence determine the order of evaluation?
See also question 3.8 and the rest of the questions in section 3 of the C FAQ list.
Often this question is linked as a duplicate of questions related to code like
printf("%d %d\n", i, i++);
or
printf("%d %d\n", ++i, i++);
or similar variants.
While this is also undefined behaviour as stated already, there are subtle differences when printf() is involved when comparing to a statement such as:
x = i++ + i++;
In the following statement:
printf("%d %d\n", ++i, i++);
the order of evaluation of arguments in printf() is unspecified. That means, expressions i++ and ++i could be evaluated in any order. C11 standard has some relevant descriptions on this:
Annex J, unspecified behaviours
The order in which the function designator, arguments, and
subexpressions within the arguments are evaluated in a function call
(6.5.2.2).
3.4.4, unspecified behavior
Use of an unspecified value, or other behavior where this
International Standard provides two or more possibilities and imposes
no further requirements on which is chosen in any instance.
EXAMPLE An example of unspecified behavior is the order in which the
arguments to a function are evaluated.
The unspecified behaviour itself is NOT an issue. Consider this example:
printf("%d %d\n", ++x, y++);
This too has unspecified behaviour because the order of evaluation of ++x and y++ is unspecified. But it's perfectly legal and valid statement. There's no undefined behaviour in this statement. Because the modifications (++x and y++) are done to distinct objects.
What renders the following statement
printf("%d %d\n", ++i, i++);
as undefined behaviour is the fact that these two expressions modify the same object i without an intervening sequence point.
Another detail is that the comma involved in the printf() call is a separator, not the comma operator.
This is an important distinction because the comma operator does introduce a sequence point between the evaluation of their operands, which makes the following legal:
int i = 5;
int j;
j = (++i, i++); // No undefined behaviour here because the comma operator
// introduces a sequence point between '++i' and 'i++'
printf("i=%d j=%d\n",i, j); // prints: i=7 j=6
The comma operator evaluates its operands left-to-right and yields only the value of the last operand. So in j = (++i, i++);, ++i increments i to 6 and i++ yields old value of i (6) which is assigned to j. Then i becomes 7 due to post-increment.
So if the comma in the function call were to be a comma operator then
printf("%d %d\n", ++i, i++);
will not be a problem. But it invokes undefined behaviour because the comma here is a separator.
For those who are new to undefined behaviour would benefit from reading What Every C Programmer Should Know About Undefined Behavior to understand the concept and many other variants of undefined behaviour in C.
This post: Undefined, unspecified and implementation-defined behavior is also relevant.
While it is unlikely that any compilers and processors would actually do so, it would be legal, under the C standard, for the compiler to implement "i++" with the sequence:
In a single operation, read `i` and lock it to prevent access until further notice
Compute (1+read_value)
In a single operation, unlock `i` and store the computed value
While I don't think any processors support the hardware to allow such a thing to be done efficiently, one can easily imagine situations where such behavior would make multi-threaded code easier (e.g. it would guarantee that if two threads try to perform the above sequence simultaneously, i would get incremented by two) and it's not totally inconceivable that some future processor might provide a feature something like that.
If the compiler were to write i++ as indicated above (legal under the standard) and were to intersperse the above instructions throughout the evaluation of the overall expression (also legal), and if it didn't happen to notice that one of the other instructions happened to access i, it would be possible (and legal) for the compiler to generate a sequence of instructions that would deadlock. To be sure, a compiler would almost certainly detect the problem in the case where the same variable i is used in both places, but if a routine accepts references to two pointers p and q, and uses (*p) and (*q) in the above expression (rather than using i twice) the compiler would not be required to recognize or avoid the deadlock that would occur if the same object's address were passed for both p and q.
While the syntax of the expressions like a = a++ or a++ + a++ is legal, the behaviour of these constructs is undefined because a shall in C standard is not obeyed. C99 6.5p2:
Between the previous and next sequence point an object shall have its stored value modified at most once by the evaluation of an expression. [72] Furthermore, the prior value shall be read only to determine the value to be stored [73]
With footnote 73 further clarifying that
This paragraph renders undefined statement expressions such as
i = ++i + 1;
a[i++] = i;
while allowing
i = i + 1;
a[i] = i;
The various sequence points are listed in Annex C of C11 (and C99):
The following are the sequence points described in 5.1.2.3:
Between the evaluations of the function designator and actual arguments in a function call and the actual call. (6.5.2.2).
Between the evaluations of the first and second operands of the following operators: logical AND && (6.5.13); logical OR || (6.5.14); comma , (6.5.17).
Between the evaluations of the first operand of the conditional ? : operator and whichever of the second and third operands is evaluated (6.5.15).
The end of a full declarator: declarators (6.7.6);
Between the evaluation of a full expression and the next full expression to be evaluated. The following are full expressions: an initializer that is not part of a compound literal (6.7.9); the expression in an expression statement (6.8.3); the controlling expression of a selection statement (if or switch) (6.8.4); the controlling expression of a while or do statement (6.8.5); each of the (optional) expressions of a for statement (6.8.5.3); the (optional) expression in a return statement (6.8.6.4).
Immediately before a library function returns (7.1.4).
After the actions associated with each formatted input/output function conversion specifier (7.21.6, 7.29.2).
Immediately before and immediately after each call to a comparison function, and also between any call to a comparison function and any movement of the objects passed as arguments to that call (7.22.5).
The wording of the same paragraph in C11 is:
If a side effect on a scalar object is unsequenced relative to either a different side effect on the same scalar object or a value computation using the value of the same scalar object, the behavior is undefined. If there are multiple allowable orderings of the subexpressions of an expression, the behavior is undefined if such an unsequenced side effect occurs in any of the orderings.84)
You can detect such errors in a program by for example using a recent version of GCC with -Wall and -Werror, and then GCC will outright refuse to compile your program. The following is the output of gcc (Ubuntu 6.2.0-5ubuntu12) 6.2.0 20161005:
% gcc plusplus.c -Wall -Werror -pedantic
plusplus.c: In function ‘main’:
plusplus.c:6:6: error: operation on ‘i’ may be undefined [-Werror=sequence-point]
i = i++ + ++i;
~~^~~~~~~~~~~
plusplus.c:6:6: error: operation on ‘i’ may be undefined [-Werror=sequence-point]
plusplus.c:10:6: error: operation on ‘i’ may be undefined [-Werror=sequence-point]
i = (i++);
~~^~~~~~~
plusplus.c:14:6: error: operation on ‘u’ may be undefined [-Werror=sequence-point]
u = u++ + ++u;
~~^~~~~~~~~~~
plusplus.c:14:6: error: operation on ‘u’ may be undefined [-Werror=sequence-point]
plusplus.c:18:6: error: operation on ‘u’ may be undefined [-Werror=sequence-point]
u = (u++);
~~^~~~~~~
plusplus.c:22:6: error: operation on ‘v’ may be undefined [-Werror=sequence-point]
v = v++ + ++v;
~~^~~~~~~~~~~
plusplus.c:22:6: error: operation on ‘v’ may be undefined [-Werror=sequence-point]
cc1: all warnings being treated as errors
The important part is to know what a sequence point is -- and what is a sequence point and what isn't. For example the comma operator is a sequence point, so
j = (i ++, ++ i);
is well-defined, and will increment i by one, yielding the old value, discard that value; then at comma operator, settle the side effects; and then increment i by one, and the resulting value becomes the value of the expression - i.e. this is just a contrived way to write j = (i += 2) which is yet again a "clever" way to write
i += 2;
j = i;
However, the , in function argument lists is not a comma operator, and there is no sequence point between evaluations of distinct arguments; instead their evaluations are unsequenced with regard to each other; so the function call
int i = 0;
printf("%d %d\n", i++, ++i, i);
has undefined behaviour because there is no sequence point between the evaluations of i++ and ++i in function arguments, and the value of i is therefore modified twice, by both i++ and ++i, between the previous and the next sequence point.
The C standard says that a variable should only be assigned at most once between two sequence points. A semi-colon for instance is a sequence point.
So every statement of the form:
i = i++;
i = i++ + ++i;
and so on violate that rule. The standard also says that behavior is undefined and not unspecified. Some compilers do detect these and produce some result but this is not per standard.
However, two different variables can be incremented between two sequence points.
while(*src++ = *dst++);
The above is a common coding practice while copying/analysing strings.
In https://stackoverflow.com/questions/29505280/incrementing-array-index-in-c someone asked about a statement like:
int k[] = {0,1,2,3,4,5,6,7,8,9,10};
int i = 0;
int num;
num = k[++i+k[++i]] + k[++i];
printf("%d", num);
which prints 7... the OP expected it to print 6.
The ++i increments aren't guaranteed to all complete before the rest of the calculations. In fact, different compilers will get different results here. In the example you provided, the first 2 ++i executed, then the values of k[] were read, then the last ++i then k[].
num = k[i+1]+k[i+2] + k[i+3];
i += 3
Modern compilers will optimize this very well. In fact, possibly better than the code you originally wrote (assuming it had worked the way you had hoped).
Your question was probably not, "Why are these constructs undefined behavior in C?". Your question was probably, "Why did this code (using ++) not give me the value I expected?", and someone marked your question as a duplicate, and sent you here.
This answer tries to answer that question: why did your code not give you the answer you expected, and how can you learn to recognize (and avoid) expressions that will not work as expected.
I assume you've heard the basic definition of C's ++ and -- operators by now, and how the prefix form ++x differs from the postfix form x++. But these operators are hard to think about, so to make sure you understood, perhaps you wrote a tiny little test program involving something like
int x = 5;
printf("%d %d %d\n", x, ++x, x++);
But, to your surprise, this program did not help you understand — it printed some strange, inexplicable output, suggesting that maybe ++ does something completely different, not at all what you thought it did.
Or, perhaps you're looking at a hard-to-understand expression like
int x = 5;
x = x++ + ++x;
printf("%d\n", x);
Perhaps someone gave you that code as a puzzle. This code also makes no sense, especially if you run it — and if you compile and run it under two different compilers, you're likely to get two different answers! What's up with that? Which answer is correct? (And the answer is that both of them are, or neither of them are.)
As you've heard by now, these expressions are undefined, which means that the C language makes no guarantee about what they'll do. This is a strange and unsettling result, because you probably thought that any program you could write, as long as it compiled and ran, would generate a unique, well-defined output. But in the case of undefined behavior, that's not so.
What makes an expression undefined? Are expressions involving ++ and -- always undefined? Of course not: these are useful operators, and if you use them properly, they're perfectly well-defined.
For the expressions we're talking about, what makes them undefined is when there's too much going on at once, when we can't tell what order things will happen in, but when the order matters to the result we'll get.
Let's go back to the two examples I've used in this answer. When I wrote
printf("%d %d %d\n", x, ++x, x++);
the question is, before actually calling printf, does the compiler compute the value of x first, or x++, or maybe ++x? But it turns out we don't know. There's no rule in C which says that the arguments to a function get evaluated left-to-right, or right-to-left, or in some other order. So we can't say whether the compiler will do x first, then ++x, then x++, or x++ then ++x then x, or some other order. But the order clearly matters, because depending on which order the compiler uses, we'll clearly get a different series of numbers printed out.
What about this crazy expression?
x = x++ + ++x;
The problem with this expression is that it contains three different attempts to modify the value of x: (1) the x++ part tries to take x's value, add 1, store the new value in x, and return the old value; (2) the ++x part tries to take x's value, add 1, store the new value in x, and return the new value; and (3) the x = part tries to assign the sum of the other two back to x. Which of those three attempted assignments will "win"? Which of the three values will actually determine the final value of x? Again, and perhaps surprisingly, there's no rule in C to tell us.
You might imagine that precedence or associativity or left-to-right evaluation tells you what order things happen in, but they do not. You may not believe me, but please take my word for it, and I'll say it again: precedence and associativity do not determine every aspect of the evaluation order of an expression in C. In particular, if within one expression there are multiple different spots where we try to assign a new value to something like x, precedence and associativity do not tell us which of those attempts happens first, or last, or anything.
So with all that background and introduction out of the way, if you want to make sure that all your programs are well-defined, which expressions can you write, and which ones can you not write?
These expressions are all fine:
y = x++;
z = x++ + y++;
x = x + 1;
x = a[i++];
x = a[i++] + b[j++];
x[i++] = a[j++] + b[k++];
x = *p++;
x = *p++ + *q++;
These expressions are all undefined:
x = x++;
x = x++ + ++x;
y = x + x++;
a[i] = i++;
a[i++] = i;
printf("%d %d %d\n", x, ++x, x++);
And the last question is, how can you tell which expressions are well-defined, and which expressions are undefined?
As I said earlier, the undefined expressions are the ones where there's too much going at once, where you can't be sure what order things happen in, and where the order matters:
If there's one variable that's getting modified (assigned to) in two or more different places, how do you know which modification happens first?
If there's a variable that's getting modified in one place, and having its value used in another place, how do you know whether it uses the old value or the new value?
As an example of #1, in the expression
x = x++ + ++x;
there are three attempts to modify x.
As an example of #2, in the expression
y = x + x++;
we both use the value of x, and modify it.
So that's the answer: make sure that in any expression you write, each variable is modified at most once, and if a variable is modified, you don't also attempt to use the value of that variable somewhere else.
One more thing. You might be wondering how to "fix" the undefined expressions I started this answer by presenting.
In the case of printf("%d %d %d\n", x, ++x, x++);, it's easy — just write it as three separate printf calls:
printf("%d ", x);
printf("%d ", ++x);
printf("%d\n", x++);
Now the behavior is perfectly well defined, and you'll get sensible results.
In the case of x = x++ + ++x, on the other hand, there's no way to fix it. There's no way to write it so that it has guaranteed behavior matching your expectations — but that's okay, because you would never write an expression like x = x++ + ++x in a real program anyway.
A good explanation about what happens in this kind of computation is provided in the document n1188 from the ISO W14 site.
I explain the ideas.
The main rule from the standard ISO 9899 that applies in this situation is 6.5p2.
Between the previous and next sequence point an object shall have its stored value modified at most once by the evaluation of an expression. Furthermore, the prior value shall be read only to determine the value to be stored.
The sequence points in an expression like i=i++ are before i= and after i++.
In the paper that I quoted above it is explained that you can figure out the program as being formed by small boxes, each box containing the instructions between 2 consecutive sequence points. The sequence points are defined in annex C of the standard, in the case of i=i++ there are 2 sequence points that delimit a full-expression. Such an expression is syntactically equivalent with an entry of expression-statement in the Backus-Naur form of the grammar (a grammar is provided in annex A of the Standard).
So the order of instructions inside a box has no clear order.
i=i++
can be interpreted as
tmp = i
i=i+1
i = tmp
or as
tmp = i
i = tmp
i=i+1
because both all these forms to interpret the code i=i++ are valid and because both generate different answers, the behavior is undefined.
So a sequence point can be seen by the beginning and the end of each box that composes the program [the boxes are atomic units in C] and inside a box the order of instructions is not defined in all cases. Changing that order one can change the result sometimes.
EDIT:
Other good source for explaining such ambiguities are the entries from c-faq site (also published as a book) , namely here and here and here .
The reason is that the program is running undefined behavior. The problem lies in the evaluation order, because there is no sequence points required according to C++98 standard ( no operations is sequenced before or after another according to C++11 terminology).
However if you stick to one compiler, you will find the behavior persistent, as long as you don't add function calls or pointers, which would make the behavior more messy.
Using Nuwen MinGW 15 GCC 7.1 you will get:
#include<stdio.h>
int main(int argc, char ** argv)
{
int i = 0;
i = i++ + ++i;
printf("%d\n", i); // 2
i = 1;
i = (i++);
printf("%d\n", i); //1
volatile int u = 0;
u = u++ + ++u;
printf("%d\n", u); // 2
u = 1;
u = (u++);
printf("%d\n", u); //1
register int v = 0;
v = v++ + ++v;
printf("%d\n", v); //2
}
How does GCC work? it evaluates sub expressions at a left to right order for the right hand side (RHS) , then assigns the value to the left hand side (LHS) . This is exactly how Java and C# behave and define their standards. (Yes, the equivalent software in Java and C# has defined behaviors). It evaluate each sub expression one by one in the RHS Statement in a left to right order; for each sub expression: the ++c (pre-increment) is evaluated first then the value c is used for the operation, then the post increment c++).
according to GCC C++: Operators
In GCC C++, the precedence of the operators controls the order in
which the individual operators are evaluated
the equivalent code in defined behavior C++ as GCC understands:
#include<stdio.h>
int main(int argc, char ** argv)
{
int i = 0;
//i = i++ + ++i;
int r;
r=i;
i++;
++i;
r+=i;
i=r;
printf("%d\n", i); // 2
i = 1;
//i = (i++);
r=i;
i++;
i=r;
printf("%d\n", i); // 1
volatile int u = 0;
//u = u++ + ++u;
r=u;
u++;
++u;
r+=u;
u=r;
printf("%d\n", u); // 2
u = 1;
//u = (u++);
r=u;
u++;
u=r;
printf("%d\n", u); // 1
register int v = 0;
//v = v++ + ++v;
r=v;
v++;
++v;
r+=v;
v=r;
printf("%d\n", v); //2
}
Then we go to Visual Studio. Visual Studio 2015, you get:
#include<stdio.h>
int main(int argc, char ** argv)
{
int i = 0;
i = i++ + ++i;
printf("%d\n", i); // 3
i = 1;
i = (i++);
printf("%d\n", i); // 2
volatile int u = 0;
u = u++ + ++u;
printf("%d\n", u); // 3
u = 1;
u = (u++);
printf("%d\n", u); // 2
register int v = 0;
v = v++ + ++v;
printf("%d\n", v); // 3
}
How does Visual Studio work, it takes another approach, it evaluates all pre-increments expressions in first pass, then uses variables values in the operations in second pass, assign from RHS to LHS in third pass, then at last pass it evaluates all the post-increment expressions in one pass.
So the equivalent in defined behavior C++ as Visual C++ understands:
#include<stdio.h>
int main(int argc, char ** argv)
{
int r;
int i = 0;
//i = i++ + ++i;
++i;
r = i + i;
i = r;
i++;
printf("%d\n", i); // 3
i = 1;
//i = (i++);
r = i;
i = r;
i++;
printf("%d\n", i); // 2
volatile int u = 0;
//u = u++ + ++u;
++u;
r = u + u;
u = r;
u++;
printf("%d\n", u); // 3
u = 1;
//u = (u++);
r = u;
u = r;
u++;
printf("%d\n", u); // 2
register int v = 0;
//v = v++ + ++v;
++v;
r = v + v;
v = r;
v++;
printf("%d\n", v); // 3
}
as Visual Studio documentation states at Precedence and Order of Evaluation:
Where several operators appear together, they have equal precedence and are evaluated according to their associativity. The operators in the table are described in the sections beginning with Postfix Operators.

regarding if(condition) in ARM 7

Is it not a good practice to put long condition in if statement like
if(((FIO2PIN & 0x00001000)>>12))
which will give result as 0/1 at the end in ARM7?
Is that so that I can only check for 0 or 1 in if condition?
For example
if(x!=0)
or
if(x==1)??
indirectly (FIO2PIN & 0x00001000)>>12 will also give some value at the end which might be 0/1 depending on FIO2PIN status right?
The expression ((FIO2PIN & 0x00001000)>>12) is an integer expression and is implicitly cast to a boolean by the if(...), where zero is false and non-zero is true.
There is nothing wrong with that in the sense that it is entirely unambiguous as far as the compiler and language definition are concerned, but I prefer to use only explicitly boolean expressions in conditional statements - in order to make the intent of the programmer clear. That is easily done by explicitly comparing the result with zero; in this case:
if( ((FIO2PIN & 0x00001000) >> 12) != 0 )
However, the shift is entirely unnecessary in either case, because any non-zero value will be accepted as true (which is why you should always compare with zero - or nothing at all). So:
if( FIO2PIN & 0x00001000 )
or
if( (FIO2PIN & 0x00001000) != 0 )
are equally valid - the latter being my preference.
As mentioned, any non-zero value will be accepted as true while only zero is false, so where x is an integer expression, the test x == 1 is a dangerous one, and you should use x != 0 instead.
The if statement will be true if the expression is non-zero. So shifting right by twelve bits is not necessary in your example. Because (FIO2PIN & 0x00001000) is non-zero whenever ((FIO2PIN & 0x00001000) >> 12) is non-zero. In other words, it doesn't matter which bit is non-zero. The if statement will test true if any bit is non-zero.
In my opinion, using a complex expression within an if statement could be bad practice if the expression is so complex that it is difficult for a developer to understand or maintain. But otherwise, as long as the expression is correct, then the compiler should sort it out and you shouldn't need to worry whether it is too complex for the compiler.

== Operator and operands

I want to check whether a value is equal to 1. Is there any difference in the following lines of code
Evaluated value == 1
1 == evaluated value
in terms of the compiler execution
In most languages it's the same thing.
People often do 1 == evaluated value because 1 is not an lvalue. Meaning that you can't accidentally do an assignment.
Example:
if(x = 6)//bug, but no compiling error
{
}
Instead you could force a compiling error instead of a bug:
if(6 = x)//compiling error
{
}
Now if x is not of int type, and you're using something like C++, then the user could have created an operator==(int) override which takes this question to a new meaning. The 6 == x wouldn't compile in that case but the x == 6 would.
It depends on the programming language.
In Ruby, Smalltalk, Self, Newspeak, Ioke and many other single-dispatch object-oriented programming languages, a == b is actually a message send. In Ruby, for example, it is equivalent to a.==(b). What this means, is that when you write a == b, then the method == in the class of a is executed, but when you write b == a, then the method in the class of b is executed. So, it's obviously not the same thing:
class A; def ==(other) false end; end
class B; def ==(other) true end; end
a, b = A.new, B.new
p a == b # => false
p b == a # => true
No, but the latter syntax will give you a compiler error if you accidentally type
if (1 = evaluatedValue)
Note that today any decent compiler will warn you if you write
if (evaluatedValue = 1)
so it is mostly relevant for historical reasons.
Depends on the language.
In Prolog or Erlang, == is written = and is a unification rather than an assignment (you're asserting that the values are equal, rather then testing that they are equal or forcing them to be equal), so you can use it for an assertion if the left hand side is a constant, as explained here.
So X = 3 would unify the variable X and the value 3, whereas 3 = X would attempt to unify the constant 3 with the current value of X, and be equivalent of assert(x==3) in imperative languages.
It's the same thing
In general, it hardly matters whether you use,
Evaluated value == 1 OR 1 == evaluated value.
Use whichever appears more readable to you. I prefer if(Evaluated value == 1) because it looks more readable to me.
And again, I'd like to quote a well known scenario of string comparison in java.
Consider a String str which you have to compare with say another string "SomeString".
str = getValueFromSomeRoutine();
Now at runtime, you are not sure if str would be NULL. So to avoid exception you'll write
if(str!=NULL)
{
if(str.equals("SomeString")
{
//do stuff
}
}
to avoid the outer null check you could just write
if ("SomeString".equals(str))
{
//do stuff
}
Though this is less readable which again depends on the context, this saves you an extra if.
For this and similar questions can I suggest you find out for yourself by writing a little code, running it through your compiler and viewing the emitted asembler output.
For example, for the GNU compilers, you do this with the -S flag. For the VS compilers, the most convenient route is to run your test program in the debugger and then use the assembeler debugger view.
Sometimes in C++ they do different things, if the evaluated value is a user type and operator== is defined. Badly.
But that's very rarely the reason anyone would choose one way around over the other: if operator== is not commutative/symmetric, including if the type of the value has a conversion from int, then you have A Problem that probably wants fixing rather than working around. Brian R. Bondy's answer, and others, are probably on the mark for why anyone worries about it in practice.
But the fact remains that even if operator== is commutative, the compiler might not do exactly the same thing in each case. It will (by definition) return the same result, but it might do things in a slightly different order, or whatever.
if value == 1
if 1 == value
Is exactly the same, but if you accidentally do
if value = 1
if 1 = value
The first one will work while the 2nd one will produce an error.
They are the same. Some people prefer putting the 1 first, to void accidentally falling into the trap of typing
evaluated value = 1
which could be painful if the value on the left hand side is assignable. This is a common "defensive" pattern in C, for instance.
In C languages it's common to put the constant or magic number first so that if you forget one of the "=" of the equality check (==) then the compiler won't interpret this as an assignment.
In java, you cannot do an assignment within a boolean expression, and so for Java, it is irrelevant which order the equality operands are written in; The compiler should flag an error anyway.