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In the codevision compiler for Atmel processors, there is a possibility to specify the storage address of a global variable, for example

int a @0x100; // will place the variable at the address 0x100 in RAM

Of course, as per standard C, variables can be initialized upon declaration

int a=42;

However, I did not find any possibility to do them both. int a @0x100 = 42 or int a = 42 @0x100; don't work, they cause compiler errors.

You might ask why it is so important to do it, because one could simply have

int a @0x100;

int main()
    a = 42;

However, if I have variables in the EEPROM, I need to initialize them, because this is the only way to automatically generate the eeprom file with the values in it. I can't assign those values later, because in that case it would actually write the values into the eeprom at each start of the program.

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Which particular Atmel processor family? Does this thread help… ? – Martin Thompson Aug 2 '12 at 10:04
ATmega, but the eeprom handling is the same. The thread only describes in more detail what I wrote in my last paragraph (if I assign a value to an eeprom variable at declaration eeprom int a=42; it means that this value will be added to the generated eeprom file which will only be written once to the device. It will not be actually written to the eeprom every time the program starts, a very nice feature). If I had assigned the value in a separate command, it would be compiled to a write instruction to the eeprom. Thanks for the link, I'll try asking there if I don't get anything usable here. – vsz Aug 2 '12 at 11:33
Please explain what you are actually trying to do, it sounds like you have gone down the wrong path for something that can be done. Atmel has nothing to do with any of this. Do you want to control a value that is in eeprom space at a specific address? Do you want to control a value that is in a register/memory that is not in eeprom? if the latter do you want to control the address so that your program once started can have a variable that points at that register/memory location (that is not in eeprom)? – dwelch Aug 5 '12 at 11:40
@dwelch: the same eeprom file will be used by multiple programs. I want to guarantee that the same thing will be read in all of the programs. – vsz Aug 5 '12 at 11:46
up vote 2 down vote accepted

While I know of no way to directly assign an EEPROM variable to a specific address and initialize it, I found this link very helpful: EEPROM data at fixed address.

The solution I used was that of declaring a struct in EEPROM and having all EEPROM variables in your program be a member of that struct. The order you define the members of the struct will be the order they are placed in the EEPROM address space by the linker. Since the struct will be the only global EEPROM declaration it is safe to say it will be addressed to address 0x0000. Therefore, you will know the address of each EEPROM variable.


 typedef eeprom struct EEvars
    eeprom char    foo1;   // will be located at EEPROM address 0x0000
    eeprom char    foo2;   // will be located at EEPROM address 0x0001
    eeprom short   foo3;   // will be located at EEPROM address 0x0002
    eeprom long    foo4;   // will be located at EEPROM address 0x0004
    eeprom char[3] fooArr; // fooArr[0] @ 0x0008; fooArr[1] @ 0x0009; 
                           // fooArr[2] @ 0x000A 

You can then initialize the variables in the declaration of the structure. When you compile, this will create the .eep file with the initialized values at the known EEPROM addresses.

eeprom EEVARS eepromInit = {0xAA, 0xBB, 0xCCDD, 0xEEEEFFFF, {0xF0, 0xF1, 0xF2}};

This works especially well in scenarios where the bootloader section of the AVR is used to upgrade the FLASH and the new program needs to access the stored EEPROM variables. It even allows you to add EEPROM variables across software updates as long as you add them to the end of the struct so as not to disturb the addresses of those variables already established.

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I know what you're talking about and have had the same problem myself. The issue is that using the @ symbol with an address inline with the variable itself is a bolt-on addition to most toolchains. While it's supported for a lot of embedded toolchains so you can explicitly call out where SFRs or other registers are located, it's not a normal behavior for standard C.

While I'm not familiar with the particular compiler you're using, I do know that most compilers provide a more complex way of specifying the memory map. The ATmega series from Atmel for example provides the capability of specifying custom memory section in the project settings. On a GNU toolchain for example, these sections are used as part of the variable declarations by using the section attribute with the variable:


For the ATmega series you locate any memory in EEPROM by including on the same line as your variable declaration (either before or after, so long as it comes before the '=' in an assignment) the text:


If you'd like to guarantee that the specific memory address in EEPROM is set to a value as part of your binary image, so it only gets programmed once when the image is first written, you can declare a custom memory section in your project settings (it's under the "Memory Settings" of the "Toolchain" settings if you're developing in Atmel Studio).

For example, I've done exactly what you describe with a block of data by declaring section ".tune_data" in the EEPROM portion of the memory settings (following provided documentation as to address offsets, etc) then declaring a variable like the following:

const __attribute__((__section__(".tune_data))) Tune_Data_s as_tune_data = { <all_my_data> };

Clearly it's going to be slightly different since you're not using a GNU compiler and may not be using Atmel Studio. If you look into it however, pretty much every toolchain for embedded programming provides some way to declare a custom memory section that can then be attached to a variable in the code via a pragma (or attribute for GNU toolchains). The specification should be available through a command-line argument and/or modification of a standard linkerscript with a command-line options to specify a non-default linkerscript. I know the second method is the standard and only way to do it on an IAR provided toolchain.

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You can use pointer that point to an absolute address:

volatile int *pa = (int *) 0x100;

Then you can use the dereferencing operator * to access the value at that address like so:

int value = *pa;


*pa = 0x10;

Edit: There is no way of declaring a variable to point to a specific area and at the same time assign a value to that area. Not unless the compiler has extensions that allow it.

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This is just another way of doing int a @0x100; (and it's dangerous, because the compiler might allocate something else at that address). How will it initialize the value at that address? Besides, as stated in the question, it's most important in the case of eeprom variables. – vsz Aug 2 '12 at 5:37
@vsz Compilers for embedded systems are very strict when it comes to memory and memory locations. Embedded systems have specific areas for heap, stack and other data segments. Only if the system is miss-configured will the compiler use memory address ranges it's not supposed to. – Joachim Pileborg Aug 2 '12 at 5:44
and int a @0x100; is not supported by ANSI C as far as I know. Of course the AVR compilers (both codevision and AVR-GCC and possibly others) have extensions for this purpose. – vsz Aug 2 '12 at 5:53
@dwelch: but this is not what I want to do. This answer shows how to use a variable that sits at an exact memory location, fine. But this same thing is achieved by my example: int a @0x100;, which is a special feature of the AVR compiler. And safer, because in the pointer solution, a different, normal variable could also be mapped automatically at the same address. What I seek is to both have an absolute address and initialize the variable the same time, because initialization is the only way I know for the EEPROM to be initialized only once, and not at every start of the program. – vsz Aug 5 '12 at 12:19
@dwelch: no, it's the same as in the beginning. I don't want two addresses pointing to each other. I want one variable, which is guaranteed to be sitting at a predefined memory location, AND is initialized. I can do the "guaranteed location" with int a @0x100; and I can do the initialization with int a = 42; However I want to do both, and I found no way to do it. int a = 42 @0x100; or int a @0x100 = 42; and other permutations cause syntax errors. I only told that I need it for the eeprom to justify why I need this. Otherwise int a @0x100; a=42; would be fine. – vsz Aug 5 '12 at 18:41

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