This was originally published as a side bar to an article I wrote in Linux Journal , issue 110, June 2003. I found it when someone asked about what this macro does on the #kernelnewbies irc channel and dug it up from their site. I've put it here, and updated it a bit, adding more information, as it's good to have around. I need to eventually put up all of my Linux Journal articles on my site to prevent them from ever going stale.)
What exactly does the weird Linux kernel container_of()
macro do? This macro
is defined as:
#define container_of(ptr, type, member) ({ /
const typeof( ((type *)0)->member ) *__mptr = (ptr);
(type *)( (char *)__mptr - offsetof(type,member) );})
To help explain pointer mess, let us go through the steps of what it is doing.
In the include/linux/i2c.h
file, the to_i2c_driver()
macro is defined as:
container_of(d, struct i2c_driver, driver)
and is used in code as:
i2c_drv = to_i2c_driver(drv);
where dev
is a pointer to a struct device_driver
.
Replacing the above code with the first macro expansion produces:
i2c_drv = container_of(drv, struct i2c_driver, driver);
Then, the next level of expansion creates:
i2c_drv = ({
const typeof( ((struct i2c_driver *)0)->driver) *__mptr = drv;
(struct i2c_driver *)( (char *)__mptr - offsetof(struct i2c_driver, driver));
})
To simplify this, remember that driver
is a variable within the i2c_driver
function. The first line of the macro sets up a pointer that points to the
struct device_driver
passed to the code. The second line of the macro finds
the real location in memory of the struct i2c_driver
that we want to access.
So with the type of the driver
variable known, the macro can be reduced to:
i2c_drv = ({
const struct device driver *__mptr = drv;
(struct i2c_driver *)( (char *)__mptr - offsetof(struct i2c_driver, driver));
})
To show this using real numbers, say the i2c_driver structure looks like:
struct i2c_driver {
char name[32];
struct device_driver driver;
};
The location of the driver variable usually is 32 bytes into the structure, depending on the packing rules of the compiler at the time. For more information on how to see where variables are located in structures, see my article Writing Portable Device Drivers in the May/June 2002 issue of Embedded Linux Journal.
So, if the drv
pointer is at location 0xc0101020
, the __mptr
variable is
assigned that location in the first line of the macro. Then, the offset of the
driver variable is subtracted from this address, giving us the value
0xc0101000
. This would be assigned to the variable on the left side of the
original assignment, i2c_drv
.
Putting these values into the macro, it then is reduced to:
i2c_drv = ({
const struct device_driver *__mptr = drv;
(struct i2c_driver *)( (char *)__mptr - 0x20);
})
which is then evaluated at runtime by the processor as a simple subtraction on a pointer, which should be quite fast.
In order to do this kind of pointer manipulation, the code has to know the type of pointer being passed to it. The driver core only passes in the type of driver structure registered with it, so this type of manipulation is safe. This also prevents other parts of the kernel from modifying the unique fields of the structure used to control the subsystem's code.
posted Fri, 18 Feb 2005 in [/linux ]