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[/] [eco32/] [trunk/] [binutils/] [include/] [README] - Blame information for rev 89

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Format of Object and Executable Files
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-------------------------------------
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0) General
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The "a.out" file format is used as format for assembler output
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("object files") as well as for linker output ("executable files").
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The difference of these two is the size of certain sections of
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the file being zero in case of executable files.
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The file consists of a header and up to 6 sections:
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  - code
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  - initialized data
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  - code relocation records
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  - data relocation records
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  - symbol table records
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  - symbol string storage
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1) Header
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The header specifies the sizes of all following sections,
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but has itself a fixed length (and is always present):
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typedef struct {
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  unsigned int magic;           /* must be EXEC_MAGIC */
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  unsigned int csize;           /* size of code in bytes */
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  unsigned int dsize;           /* size of initialized data in bytes */
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  unsigned int bsize;           /* size of uninitialized data in bytes */
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  unsigned int crsize;          /* size of code relocation info in bytes */
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  unsigned int drsize;          /* size of data relocation info in bytes */
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  unsigned int symsize;         /* size of symbol table in bytes */
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  unsigned int strsize;         /* size of string space in bytes */
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} ExecHeader;
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The magic number is used to distinguish executable files from
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other file types. This field must have the value EXEC_MAGIC.
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The code size is given in bytes, but is always a multiple of 4.
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This is the exact size of the code section in the executable file.
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For the code size in memory see "executing an executable" below.
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The initialized data size is given in bytes, but is always a
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multiple of 4. This is the exact size of the initialized data
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section in the executable file. For the data size in memory see
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"executing an executable" below.
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The uninitialized data size is given in bytes, but is always a
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multiple of 4. There is no corresponding section to this value
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contained within the executable. See "executing an executable"
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below for the semantics of this value.
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The code relocation info size is given in bytes, but is always
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a multiple of sizeof(RelocRecord). These records describe the
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changes to be applied to the code section during the link step.
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This size is zero if the file is an executable.
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The data relocation info size is given in bytes, but is always
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a multiple of sizeof(RelocRecord). These records describe the
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changes to be applied to the data section during the link step.
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This size is zero if the file is an executable.
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The size of the symbol table is given in bytes, but is always
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a multiple of sizeof(SymbolRecord). The symbol table contains
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information about symbols which are exported from or imported
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into this object file. It is mainly used during the link step
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and may not be present (size = 0) if the file is an executable.
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The string space is used to store the names of the symbols in
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the symbol table.
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2) Code/Initialized Data
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These sections contain the instructions and the initialized data
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of the program, respectively.
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3) Code/Data Relocation Records
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The relocation records have the following structure:
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typedef struct {
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  unsigned int offset;          /* where to relocate */
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  int method;                   /* how to relocate */
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  int value;                    /* additive part of value */
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  int base;                     /* if MSB = 0: segment number */
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                                /* if MSB = 1: symbol table index */
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} RelocRecord;
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The offset gives the position where the relocation has to be done,
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in the form of a byte offset from the beginning of the section.
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The method determines how the relocation is performed, and must
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be one of the following constants:
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METHOD_H16      /* write 16 bits with high part of value */
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METHOD_L16      /* write 16 bits with low part of value */
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METHOD_R16      /* write 16 bits with value relative to PC */
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METHOD_R26      /* write 26 bits with value relative to PC */
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METHOD_W32      /* write full 32 bit word with value */
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"Value" and "base" together are used to compute the final value of
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the relocated code or data item. The value is added to the value of
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the base. The base is either the start address of a segment in memory,
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or the value of an imported symbol. In the former case, which is marked
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by an MSB of 0, the base is specified as one of the following constants:
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SEGMENT_ABS     /* absolute values */
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SEGMENT_CODE    /* code segment */
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SEGMENT_DATA    /* initialized data segment */
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SEGMENT_BSS     /* uninitialized data segment */
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In the latter case, which is marked by an MSB of 1, the remaining bits
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specify the index of the symbol in the symbol table.
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4) Symbol Table Records
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For every symbol which is imported into or exported from the current
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object file, there is a corresponding symbol table record:
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typedef struct {
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  unsigned int name;            /* offset in string space */
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  int type;                     /* if MSB = 0: the symbol's segment */
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                                /* if MSB = 1: the symbol is undefined */
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  int value;                    /* if symbol defined: the symbol's value */
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                                /* if symbol not defined: meaningless */
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} SymbolRecord;
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The name of the symbol is given as an offset into the string space.
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If the "type" has an MSB of 0, the symbol is defined here (i.e.,
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it is exported), and the "type" specifies the segment (for the
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segment constants see above) in which the symbol is defined, while
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the "value" holds its value. Otherwise, the symbol is not defined
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here (i.e., it is imported), and the "value" has no meaning.
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5) Symbol String Storage
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The strings are null-terminated and stored without any padding.
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6) Executing an Executable
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When an executable file is loaded into memory for execution, three
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logical segments are set up: the code segment, the data segment (with
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initialized data, followed by uninitialized data, which starts off
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as all 0), and a stack.
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The code segment begins at address 0 in virtual memory and is loaded
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with the contents of the code section from the executable file.
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The data segment begins at the next page boundary (multiple of 4 KB)
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after the code segment. It is loaded with the contents of the data
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section from the executable file and is followed immediately by the
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"uninitialized data", which must be zeroed by the loader. The data
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area is expanded upwards as requested by explicit "brk" system calls.
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The stack is located in the highest possible locations in the virtual
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address space, which are accessible in user mode, and thus expanding
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downwards from (but excluding) the address 0x80000000. It is extended
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automatically by the operating system.

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