#include #include /* * Originally by Eric Biederman * * Heavily modified by Michael Brown * */ FILE_LICENCE ( GPL2_OR_LATER ); /* * The linker passes in the symbol _max_align, which is the alignment * that we must preserve, in bytes. * */ extern char _max_align[]; #define max_align ( ( unsigned int ) _max_align ) /* Linker symbols */ extern char _textdata[]; extern char _etextdata[]; /* within 1MB of 4GB is too close. * MAX_ADDR is the maximum address we can easily do DMA to. * * Not sure where this constraint comes from, but kept it from Eric's * old code - mcb30 */ #define MAX_ADDR (0xfff00000UL) /** * Relocate iPXE * * @v ebp Maximum address to use for relocation * @ret esi Current physical address * @ret edi New physical address * @ret ecx Length to copy * * This finds a suitable location for iPXE near the top of 32-bit * address space, and returns the physical address of the new location * to the prefix in %edi. */ __asmcall void relocate ( struct i386_all_regs *ix86 ) { struct memory_map memmap; unsigned long start, end, size, padded_size, max; unsigned long new_start, new_end; unsigned i; /* Get memory map and current location */ get_memmap ( &memmap ); start = virt_to_phys ( _textdata ); end = virt_to_phys ( _etextdata ); size = ( end - start ); padded_size = ( size + max_align - 1 ); DBG ( "Relocate: currently at [%lx,%lx)\n" "...need %lx bytes for %d-byte alignment\n", start, end, padded_size, max_align ); /* Determine maximum usable address */ max = MAX_ADDR; if ( ix86->regs.ebp < max ) { max = ix86->regs.ebp; DBG ( "Limiting relocation to [0,%lx)\n", max ); } /* Walk through the memory map and find the highest address * below 4GB that iPXE will fit into. */ new_end = end; for ( i = 0 ; i < memmap.count ; i++ ) { struct memory_region *region = &memmap.regions[i]; unsigned long r_start, r_end; DBG ( "Considering [%llx,%llx)\n", region->start, region->end); /* Truncate block to maximum address. This will be * less than 4GB, which means that we can get away * with using just 32-bit arithmetic after this stage. */ if ( region->start > max ) { DBG ( "...starts after max=%lx\n", max ); continue; } r_start = region->start; if ( region->end > max ) { DBG ( "...end truncated to max=%lx\n", max ); r_end = max; } else { r_end = region->end; } DBG ( "...usable portion is [%lx,%lx)\n", r_start, r_end ); /* If we have rounded down r_end below r_ start, skip * this block. */ if ( r_end < r_start ) { DBG ( "...truncated to negative size\n" ); continue; } /* Check that there is enough space to fit in iPXE */ if ( ( r_end - r_start ) < size ) { DBG ( "...too small (need %lx bytes)\n", size ); continue; } /* If the start address of the iPXE we would * place in this block is higher than the end address * of the current highest block, use this block. * * Note that this avoids overlaps with the current * iPXE, as well as choosing the highest of all viable * blocks. */ if ( ( r_end - size ) > new_end ) { new_end = r_end; DBG ( "...new best block found.\n" ); } } /* Calculate new location of iPXE, and align it to the * required alignemnt. */ new_start = new_end - padded_size; new_start += ( start - new_start ) & ( max_align - 1 ); new_end = new_start + size; DBG ( "Relocating from [%lx,%lx) to [%lx,%lx)\n", start, end, new_start, new_end ); /* Let prefix know what to copy */ ix86->regs.esi = start; ix86->regs.edi = new_start; ix86->regs.ecx = size; }