; PupAlEtha.asm - Pup Alto Ethernet driver (assembly-language code)
; Contains initial portion of Ethernet interrupt handler, plus
; StartEther procedure. These are hand-coded to minimize
; turnaround time for the half-duplex Alto Ethernet interface.
; Copyright Xerox Corporation 1979, 1980
; Last modified March 9, 1980 5:15 PM by Taft
.ent etherProlog
.ent StartEther
.ent EtherPupFilter
.bextz EtherInterrupt
.bext pbiFreeQ
.bext lenEtherPacket
.srel
etherProlog: .etherProlog
StartEther: .StartEther
EtherPupFilter: .EtherPupFilter
.zrel
EtherInterruptEntry: .EtherInterruptEntry
.nrel
; *** constants duplicated in PupAlEth.decl ***
packetLength = 6 ; offset of PBI.packetLength
etherPacket = 7 ; PBI offset of first word of packet
etherType = 8. ; offset of EtherPBI.type
pupLength = 9. ; offset of PBI.pup.length
typePup = 1000 ; ethernet type meaning "I'm a Pup"
; *** NDB offsets - see EtherNDB structure in PupAlEth.decl ***
lastEPLoc = 14. ; EPLoc for most recent interrupt
lastEELoc = 15. ; EELoc for most recent interrupt
lastEIB = 16. ; -> input PBI for most recent interrupt
eIB = 17. ; -> input PBI or 0 if none
eOB = 18. ; -> output PBI or 0 if none
eState = 19. ; -1: xmting, 0: off, 1: rcving
ePLoc = 20. ; -> Post location
eBLoc = 21. ; -> Interrupt bit mask location
eELoc = 22. ; -> EOT count location, Posted
eLLoc = 23. ; -> Load location (mask)
eICLoc = 24. ; -> Input count location
eIPLoc = 25. ; -> Input pointer location
eOCLoc = 26. ; -> Output count location
eOPLoc = 27. ; -> Output pointer location
eHLoc = 28. ; -> Host Address location
outCmd = 29. ; SIO bits to start transmitter
inCmd = 30. ; SIO bits to start receiver
resetCmd = 31. ; SIO bits to reset hardware & firmware
; prolog in 32.-38.
save3 = 38. ; ac3 temp
savedID = 39. ; entry to normal bcpl interrupt handler
stack = 40. ; ac2 temp
�
; The state of the Ethernet interface is represented as follows:
; if eState is zero, the interface is idle; if nonzero, active.
; 1 means the receiver has been started; -1 means the transmitter.
; If eIB is nonzero, an input buffer is set up.
; If eOB is nonzero, an output buffer is set up.
; If an input or output buffer is not set up, then eICLoc or eOCLoc
; (respectively) must be zero.
; When the interface is started, ePLoc is set to zero. Hence
; eState nonzero and ePLoc zero means that the interface is
; presently turned on and has not yet posted.
; When the receiver is started, the first word of the input packet
; buffer is zeroed. The idea is that if a packet starts to arrive,
; it will set this word nonzero, thereby indicating that receipt
; of a packet is in progress.
; Ethernet interrupt prolog -- copied into each NDB
; Must match prolog field in EtherNDB
.etherProlog:
; EtherNDB.asmProlog:
sta 3 .+6 ; save3
lda 3 .+4 ; ndb
jmp @EtherInterruptEntry
; EtherNDB.bcplProlog:
lda 0 .+2 ; ndb
jmp @EtherInterrupt
�
; The NDB for the interrupting interface is in AC3.
; The former contents of ac3 is in the ndb.
; After saving all necessary state for the current Ethernet post
; condition, we attempt to get the receiver turned on as
; quickly as possible, then branch to the normal (BCPL) interrupt
; handler for more leisurely cleanup.
; ** Must be careful not to clobber the carry bit **
.EtherInterruptEntry: ; AC3/ ndb
sta 0 save0
lda 0 @ePLoc 3 ; Ethernet post word
sta 0 lastEPLoc 3 ; Save for later
snz 0 0 ; Has Ethernet posted?
jmp ethin6 ; No, manually-initiated interrupt
sta 2 save2
lda 2 c177400 ; Post code = 0 (input done)?
and 2 0 szr
jmp ethin1 ; No, can re-use input buffer
lda 2 eIB 3 ; Yes, get eIB just completed
sta 2 lastEIB 3 ; Save it away
lda 2 @eELoc 3 ; Save ending word count also
sta 2 lastEELoc 3
jmp ethin2
ethin1: lda 2 eIB 3 ; Get current input pbi
sz 2 2 ; Skip if none set up
jmp ethin3 ; Have one, go use buffer
ethin2: lda 2 @.pbiFreeQ ; None yet, get pbiFreeQ header
lda 0 0 2 ; Get pointer to head pbi
snz 0 0 ; Skip if have one
jmp ethin4 ; No pbi's available
sta 0 eIB 3 ; Got one, store pointer
lda 0 @eIB 3 ; Get successor
sta 0 0 2 ; Put at head of pbiFreeQ
lda 2 eIB 3
lda 0 .etherPacket ; Offset of packet in pbi
add 2 0 ; Make pointer to packet
sta 0 @eIPLoc 3 ; Store for interface
lda 0 @.lenEtherPacket ; Maximum packet length
sta 0 @eICLoc 3
; AC2/ pbi to use for input.
ethin3: subc 0 0 ; won't clobber carry bit
sta 0 etherPacket 2 ; Zero first word of packet
sta 0 @ePLoc 3 ; Zero post location
lda 0 inCmd 3
sio ; Start up input
lda 0 c1 ; Set state to "Receiver on"
; Now continue on to the normal BCPL interrupt entry sequence.
; Note that this piece of code is invisible to EtherInterrupt,
; which returns directly to the interrupt handler.
ethin5: sta 0 eState 3 ; Update software state
lda 2 save2
ethin6: lda 0 savedID 3 ; Interrupt handler entry address
sta 0 ethin7 ; ----+
lda 0 save0 ; |
lda 3 save3 3 ; |
jmp @.+1 ; |
ethin7: 0 ; <---+
; Here if no input pbi and pbiFreeQ empty. AC0/ 0
ethin4: sta 0 @ePLoc 3 ; Zero post location
sta 0 eIB 3 ; Note no buffer set up now
sta 0 @eICLoc 3 ; Prevent input-under-output
jmp ethin5
save0: 0
save2: 0
�
; StartEther(ndb)
; Called from interrupt level after processing of a packet is
; complete and new input and/or output packets have been set up.
; This procedure ensures that the transmitter is turned
; on if there is a pbi to be sent and there is not already a packet
; pouring into the receiver. If there is no output, it turns on
; the receiver if necessary. It is assumed that the interface is
; already on if eState is nonzero.
.StartEther:
sta 3 1 2 ; Return address
mov 0 3 ; ndb
sta 2 stack 3 ; Need two index registers
lda 1 eState 3 ; Get current software state
movl# 1 1 szc ; Already transmitting?
jmp return ; Yes, nothing to do
lda 0 resetCmd 3 ; Constant used below
lda 2 eOB 3 ; Is there an output pbi set up?
snz 2 2
jmp start4 ; No, go check input
mov 1 2 snr ; Yes, is receiver already on?
jmp start2 ; No, go start transmitter
; We want to transmit but the receiver is now on.
; Check whether a packet is now being received, and do not
; disturb the interface if so.
lda 1 @eBLoc 3 ; Save mask for later restoration
lda 2 @eIPLoc 3 ; Check first word of packet
lda 2 0 2
sz 2 2 ; Packet now being received?
jmp return ; Yes, defer output
; Reset interface and start transmitter.
; We must be careful not to cause an interrupt.
; ac0/ etherResetCommand, ac1/ etherMask, ac2/ 0
sta 2 @eBLoc 3 ; Zero interrupt bit mask location
sio ; Reset the interface
sta 1 @eBLoc 3 ; Put back regular mask
start2: sta 2 @ePLoc 3 ; Zero post location
sta 2 @eLLoc 3 ; Initialize load to zero
lda 0 outCmd 3
sio ; Start transmitter
mkminusone 0 0 ; Note that we are now transmitting
jmp start5
; Here if there is no output to be sent.
; See whether we need to turn on the receiver.
; ac1/ software state
start4: lda 2 eIB 3 ; Get current input buffer
snz 1 1 ; Is interface already on?
snz 2 2 ; No, is there an input buffer?
jmp return ; Already on or no buffer, done
; The interface is now off and an input buffer is set up.
; Start the receiver. ac1/ 0, ac2/ pbi
sta 1 etherPacket 2 ; Zero first word of packet
sta 1 @ePLoc 3 ; Zero post location
lda 0 inCmd 3
sio ; Start up input
mkone 0 0 ; Note that we are now receiving
start5: sta 0 eState 3
return: lda 2 stack 3
lda 3 1 2
jmp 1 3
�
.pbiFreeQ: pbiFreeQ
.etherPacket: etherPacket
.lenEtherPacket: lenEtherPacket
c1: 1
c177400: 177400
; EtherPupFilter(pbi)
; hand-coded to avoid procedure call overhead at interrupt level
; = (pbi>>PBI.pup.length+5) rshift 1 eq pbi>>PBI.packetLength &
; pbi>>EtherPBI.type eq typePup
.EtherPupFilter:
sta 3 1 2
mov 0 3
lda 0 pupLength 3
lda 1 c5
addzr 1 0
lda 1 packetLength 3
se 0 1
jmp rfalse
lda 0 etherType 3
lda 1 .typePup
se 0 1
rfalse: mkzero 0 0 skp
mkminusone 0 0
lda 3 1 2
jmp 1 3
c5: 5
.typePup: typePup
.end