When I use
BOOL for 32-bit, I get:
BOOL b1=8960; //b1 == NO bool b2=8960; //b2 == true
But for 64-bit, I get:
BOOL b1=8960; //b1 == YES bool b2=8960; //b2 == true
What has changed about
BOOL from 32-bit to 64-bit?
@TimBodeit is right, but it doesn't explain why ...
BOOL b1=8960; //b1 == NO
... evaluates to
NO on 32-bit iOS and why it evaluates to
YES on 64-bit iOS. Let's start from the same beginning.
ObjC BOOL definition
#if (TARGET_OS_IPHONE && __LP64__) || (__ARM_ARCH_7K__ >= 2) #define OBJC_BOOL_IS_BOOL 1 typedef bool BOOL; #else #define OBJC_BOOL_IS_CHAR 1 typedef signed char BOOL; // BOOL is explicitly signed so @encode(BOOL) == "c" rather than "C" // even if -funsigned-char is used. #endif
For 64-bit iOS or ARMv7k (watch) it's defined as
bool and for the rest as
ObjC BOOL YES and NO
Read Objective-C Literals, where you can find:
BOOLtype was simply a typedef for
signed char, and
NOwere macros that expand to
(BOOL)0respectively. To support
@NOexpressions, these macros are now defined using new language keywords in
#if __has_feature(objc_bool) #define YES __objc_yes #define NO __objc_no #else #define YES ((BOOL)1) #define NO ((BOOL)0) #endif
The compiler implicitly converts
(BOOL)0. The keywords are used to disambiguate BOOL and integer literals.
bool is a macro defined in
stdbool.h and it expands to
_Bool, which is a boolean type introduced in C99. It can store two values,
1. Nothing else. To be more precise,
stdbool.h defines four macros to use:
/* Don't define bool, true, and false in C++, except as a GNU extension. */ #ifndef __cplusplus #define bool _Bool #define true 1 #define false 0 #elif defined(__GNUC__) && !defined(__STRICT_ANSI__) /* Define _Bool, bool, false, true as a GNU extension. */ #define _Bool bool #define bool bool #define false false #define true true #endif #define __bool_true_false_are_defined 1
_Bool was introduced in C99 and it can hold the values
1. What's important is:
When a value is demoted to a
_Bool, the result is
0if the value equals
Now we know where this mess comes from and we can better understand what's going on.
64-bit iOS || ARMv7k
1, because the value doesn't equal
0. See (_Bool section).
signed char (values
If you're going to store
int values (
signed char, the value is unchanged per C99 18.104.22.168. Otherwise it is implementation defined (C99 quote):
Otherwise, the new type is signed and the value cannot be represented in it; either the result is implementation-defined or an implementation-defined signal is raised.
It means that clang can decide. To make it short, with the default settings, clang wraps it around (
And in the opposite direction:
signed char can store values in the range
127, it can store
0 as well. For example
signed char). And when your value
8960 is wrapped around ...
... it becomes
0 when stored in
signed char (
8960 is a multiple of
8960 % 256 == 0), thus it's
NO. The same applies to
512, ... multiples of
I strongly recommend using
BOOL and not relying on fancy C features like
int as a condition in
if, etc. That's the reason Swift has
false and you can't use
Int values in conditions where
Bool is expected. Just to avoid this mess ...
For 32-bit BOOL is a
signed char, whereas under 64-bit it is a
Definition of BOOL from
/// Type to represent a boolean value. #if (TARGET_OS_IPHONE && __LP64__) || TARGET_OS_WATCH #define OBJC_BOOL_IS_BOOL 1 typedef bool BOOL; #else #define OBJC_BOOL_IS_CHAR 1 typedef signed char BOOL; // BOOL is explicitly signed so @encode(BOOL) == "c" rather than "C" // even if -funsigned-char is used. #endif