#ifndef REALMODE_H #define REALMODE_H #include #include #include /* * Data structures and type definitions * */ FILE_LICENCE ( GPL2_OR_LATER ); /* * Declaration of variables in .data16 * * To place a variable in the .data16 segment, declare it using the * pattern: * * int __data16 ( foo ); * #define foo __use_data16 ( foo ); * * extern uint32_t __data16 ( bar ); * #define bar __use_data16 ( bar ); * * static long __data16 ( baz ) = 0xff000000UL; * #define baz __use_data16 ( baz ); * * i.e. take a normal declaration, add __data16() around the variable * name, and add a line saying "#define __use_data16 ( ) * * You can then access them just like any other variable, for example * * int x = foo + bar; * * This magic is achieved at a cost of only around 7 extra bytes per * group of accesses to .data16 variables. When using KEEP_IT_REAL, * there is no extra cost. * * You should place variables in .data16 when they need to be accessed * by real-mode code. Real-mode assembly (e.g. as created by * REAL_CODE()) can access these variables via the usual data segment. * You can therefore write something like * * static uint16_t __data16 ( foo ); * #define foo __use_data16 ( foo ) * * int bar ( void ) { * __asm__ __volatile__ ( REAL_CODE ( "int $0xff\n\t" * "movw %ax, foo" ) * : : ); * return foo; * } * * Variables may also be placed in .text16 using __text16 and * __use_text16. Some variables (e.g. chained interrupt vectors) fit * most naturally in .text16; most should be in .data16. * * If you have only a pointer to a magic symbol within .data16 or * .text16, rather than the symbol itself, you can attempt to extract * the underlying symbol name using __from_data16() or * __from_text16(). This is not for the faint-hearted; check the * assembler output to make sure that it's doing the right thing. */ /** * Copy data to base memory * * @v dest_seg Destination segment * @v dest_off Destination offset * @v src Source * @v len Length */ static inline __always_inline void copy_to_real ( unsigned int dest_seg, unsigned int dest_off, void *src, size_t n ) { copy_to_user ( real_to_user ( dest_seg, dest_off ), 0, src, n ); } /** * Copy data to base memory * * @v dest Destination * @v src_seg Source segment * @v src_off Source offset * @v len Length */ static inline __always_inline void copy_from_real ( void *dest, unsigned int src_seg, unsigned int src_off, size_t n ) { copy_from_user ( dest, real_to_user ( src_seg, src_off ), 0, n ); } /** * Write a single variable to base memory * * @v var Variable to write * @v dest_seg Destination segment * @v dest_off Destination offset */ #define put_real( var, dest_seg, dest_off ) \ copy_to_real ( (dest_seg), (dest_off), &(var), sizeof (var) ) /** * Read a single variable from base memory * * @v var Variable to read * @v src_seg Source segment * @v src_off Source offset */ #define get_real( var, src_seg, src_off ) \ copy_from_real ( &(var), (src_seg), (src_off), sizeof (var) ) /* * REAL_CODE ( asm_code_str ) * * This can be used in inline assembly to create a fragment of code * that will execute in real mode. For example: to write a character * to the BIOS console using INT 10, you would do something like: * * __asm__ __volatile__ ( REAL_CODE ( "int $0x16" ) * : "=a" ( character ) : "a" ( 0x0000 ) ); * */ #endif /* REALMODE_H */