|~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |MOTOROLA MICROPROCESSOR & MEMORY TECHNOLOGY GROUP |M68000 Hi-Performance Microprocessor Division |M68060 Software Package |Production Release P1.00 -- October 10, 1994 | |M68060 Software Package Copyright © 1993, 1994 Motorola Inc. All rights reserved. | |THE SOFTWARE is provided on an "AS IS" basis and without warranty. |To the maximum extent permitted by applicable law, |MOTOROLA DISCLAIMS ALL WARRANTIES WHETHER EXPRESS OR IMPLIED, |INCLUDING IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE |and any warranty against infringement with regard to the SOFTWARE |(INCLUDING ANY MODIFIED VERSIONS THEREOF) and any accompanying written materials. | |To the maximum extent permitted by applicable law, |IN NO EVENT SHALL MOTOROLA BE LIABLE FOR ANY DAMAGES WHATSOEVER |(INCLUDING WITHOUT LIMITATION, DAMAGES FOR LOSS OF BUSINESS PROFITS, |BUSINESS INTERRUPTION, LOSS OF BUSINESS INFORMATION, OR OTHER PECUNIARY LOSS) |ARISING OF THE USE OR INABILITY TO USE THE SOFTWARE. |Motorola assumes no responsibility for the maintenance and support of the SOFTWARE. | |You are hereby granted a copyright license to use, modify, and distribute the SOFTWARE |so long as this entire notice is retained without alteration in any modified and/or |redistributed versions, and that such modified versions are clearly identified as such. |No licenses are granted by implication, estoppel or otherwise under any patents |or trademarks of Motorola, Inc. |~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ | os.s | | This file contains: | - example "Call-Out"s required by both the ISP and FPSP. | #include <linux/linkage.h> |################################ | EXAMPLE CALL-OUTS # | # | _060_dmem_write() # | _060_dmem_read() # | _060_imem_read() # | _060_dmem_read_byte() # | _060_dmem_read_word() # | _060_dmem_read_long() # | _060_imem_read_word() # | _060_imem_read_long() # | _060_dmem_write_byte() # | _060_dmem_write_word() # | _060_dmem_write_long() # | # | _060_real_trace() # | _060_real_access() # |################################ | | Each IO routine checks to see if the memory write/read is to/from user | or supervisor application space. The examples below use simple "move" | instructions for supervisor mode applications and call _copyin()/_copyout() | for user mode applications. | When installing the 060SP, the _copyin()/_copyout() equivalents for a | given operating system should be substituted. | | The addresses within the 060SP are guaranteed to be on the stack. | The result is that Unix processes are allowed to sleep as a consequence | of a page fault during a _copyout. | | Linux/68k: The _060_[id]mem_{read,write}_{byte,word,long} functions | (i.e. all the known length <= 4) are implemented by single moves | statements instead of (more expensive) copy{in,out} calls, if | working in user space | | _060_dmem_write(): | | Writes to data memory while in supervisor mode. | | INPUTS: | a0 - supervisor source address | a1 - user destination address | d0 - number of bytes to write | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode | OUTPUTS: | d1 - 0 = success, !0 = failure | .global _060_dmem_write _060_dmem_write: subq.l #1,%d0 btst #0x5,0x4(%a6) | check for supervisor state beqs user_write super_write: move.b (%a0)+,(%a1)+ | copy 1 byte dbra %d0,super_write | quit if --ctr < 0 clr.l %d1 | return success rts user_write: move.b (%a0)+,%d1 | copy 1 byte copyoutae: movs.b %d1,(%a1)+ dbra %d0,user_write | quit if --ctr < 0 clr.l %d1 | return success rts | | _060_imem_read(), _060_dmem_read(): | | Reads from data/instruction memory while in supervisor mode. | | INPUTS: | a0 - user source address | a1 - supervisor destination address | d0 - number of bytes to read | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode | OUTPUTS: | d1 - 0 = success, !0 = failure | .global _060_imem_read .global _060_dmem_read _060_imem_read: _060_dmem_read: subq.l #1,%d0 btst #0x5,0x4(%a6) | check for supervisor state beqs user_read super_read: move.b (%a0)+,(%a1)+ | copy 1 byte dbra %d0,super_read | quit if --ctr < 0 clr.l %d1 | return success rts user_read: copyinae: movs.b (%a0)+,%d1 move.b %d1,(%a1)+ | copy 1 byte dbra %d0,user_read | quit if --ctr < 0 clr.l %d1 | return success rts | | _060_dmem_read_byte(): | | Read a data byte from user memory. | | INPUTS: | a0 - user source address | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode | OUTPUTS: | d0 - data byte in d0 | d1 - 0 = success, !0 = failure | .global _060_dmem_read_byte _060_dmem_read_byte: clr.l %d0 | clear whole longword clr.l %d1 | assume success btst #0x5,0x4(%a6) | check for supervisor state bnes dmrbs | supervisor dmrbuae:movs.b (%a0),%d0 | fetch user byte rts dmrbs: move.b (%a0),%d0 | fetch super byte rts | | _060_dmem_read_word(): | | Read a data word from user memory. | | INPUTS: | a0 - user source address | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode | OUTPUTS: | d0 - data word in d0 | d1 - 0 = success, !0 = failure | | _060_imem_read_word(): | | Read an instruction word from user memory. | | INPUTS: | a0 - user source address | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode | OUTPUTS: | d0 - instruction word in d0 | d1 - 0 = success, !0 = failure | .global _060_dmem_read_word .global _060_imem_read_word _060_dmem_read_word: _060_imem_read_word: clr.l %d1 | assume success clr.l %d0 | clear whole longword btst #0x5,0x4(%a6) | check for supervisor state bnes dmrws | supervisor dmrwuae:movs.w (%a0), %d0 | fetch user word rts dmrws: move.w (%a0), %d0 | fetch super word rts | | _060_dmem_read_long(): | | | INPUTS: | a0 - user source address | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode | OUTPUTS: | d0 - data longword in d0 | d1 - 0 = success, !0 = failure | | _060_imem_read_long(): | | Read an instruction longword from user memory. | | INPUTS: | a0 - user source address | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode | OUTPUTS: | d0 - instruction longword in d0 | d1 - 0 = success, !0 = failure | .global _060_dmem_read_long .global _060_imem_read_long _060_dmem_read_long: _060_imem_read_long: clr.l %d1 | assume success btst #0x5,0x4(%a6) | check for supervisor state bnes dmrls | supervisor dmrluae:movs.l (%a0),%d0 | fetch user longword rts dmrls: move.l (%a0),%d0 | fetch super longword rts | | _060_dmem_write_byte(): | | Write a data byte to user memory. | | INPUTS: | a0 - user destination address | d0 - data byte in d0 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode | OUTPUTS: | d1 - 0 = success, !0 = failure | .global _060_dmem_write_byte _060_dmem_write_byte: clr.l %d1 | assume success btst #0x5,0x4(%a6) | check for supervisor state bnes dmwbs | supervisor dmwbuae:movs.b %d0,(%a0) | store user byte rts dmwbs: move.b %d0,(%a0) | store super byte rts | | _060_dmem_write_word(): | | Write a data word to user memory. | | INPUTS: | a0 - user destination address | d0 - data word in d0 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode | OUTPUTS: | d1 - 0 = success, !0 = failure | .global _060_dmem_write_word _060_dmem_write_word: clr.l %d1 | assume success btst #0x5,0x4(%a6) | check for supervisor state bnes dmwws | supervisor dmwwu: dmwwuae:movs.w %d0,(%a0) | store user word bras dmwwr dmwws: move.w %d0,(%a0) | store super word dmwwr: clr.l %d1 | return success rts | | _060_dmem_write_long(): | | Write a data longword to user memory. | | INPUTS: | a0 - user destination address | d0 - data longword in d0 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode | OUTPUTS: | d1 - 0 = success, !0 = failure | .global _060_dmem_write_long _060_dmem_write_long: clr.l %d1 | assume success btst #0x5,0x4(%a6) | check for supervisor state bnes dmwls | supervisor dmwluae:movs.l %d0,(%a0) | store user longword rts dmwls: move.l %d0,(%a0) | store super longword rts #if 0 |############################################### | | Use these routines if your kernel doesn't have _copyout/_copyin equivalents. | Assumes that D0/D1/A0/A1 are scratch registers. The _copyin/_copyout | below assume that the SFC/DFC have been set previously. | | Linux/68k: These are basically non-inlined versions of | memcpy_{to,from}fs, but without long-transfer optimization | Note: Assumed that SFC/DFC are pointing correctly to user data | space... Should be right, or are there any exceptions? | | int _copyout(supervisor_addr, user_addr, nbytes) | .global _copyout _copyout: move.l 4(%sp),%a0 | source move.l 8(%sp),%a1 | destination move.l 12(%sp),%d0 | count subq.l #1,%d0 moreout: move.b (%a0)+,%d1 | fetch supervisor byte copyoutae: movs.b %d1,(%a1)+ | store user byte dbra %d0,moreout | are we through yet? moveq #0,%d0 | return success rts | | int _copyin(user_addr, supervisor_addr, nbytes) | .global _copyin _copyin: move.l 4(%sp),%a0 | source move.l 8(%sp),%a1 | destination move.l 12(%sp),%d0 | count subq.l #1,%d0 morein: copyinae: movs.b (%a0)+,%d1 | fetch user byte move.b %d1,(%a1)+ | write supervisor byte dbra %d0,morein | are we through yet? moveq #0,%d0 | return success rts #endif |########################################################################### | | _060_real_trace(): | | This is the exit point for the 060FPSP when an instruction is being traced | and there are no other higher priority exceptions pending for this instruction | or they have already been processed. | | The sample code below simply executes an "rte". | .global _060_real_trace _060_real_trace: bral trap | | _060_real_access(): | | This is the exit point for the 060FPSP when an access error exception | is encountered. The routine below should point to the operating system | handler for access error exceptions. The exception stack frame is an | 8-word access error frame. | | The sample routine below simply executes an "rte" instruction which | is most likely the incorrect thing to do and could put the system | into an infinite loop. | .global _060_real_access _060_real_access: bral buserr | Execption handling for movs access to illegal memory .section .fixup,"ax" .even 1: moveq #-1,%d1 rts .section __ex_table,"a" .align 4 .long dmrbuae,1b .long dmrwuae,1b .long dmrluae,1b .long dmwbuae,1b .long dmwwuae,1b .long dmwluae,1b .long copyoutae,1b .long copyinae,1b .text