usbdrv/usbdrvasm18-crc.inc@93fe2226cbc8
usbdrv/usbdrvasm18-crc.inc
Thu, 16 Feb 2017 14:50:25 +0100
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- mbayer
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- Thu, 16 Feb 2017 14:50:25 +0100
- changeset 3
- 93fe2226cbc8
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Added schematics and PCB layout
/* Name: usbdrvasm18.inc * Project: V-USB, virtual USB port for Atmel's(r) AVR(r) microcontrollers * Author: Lukas Schrittwieser (based on 20 MHz usbdrvasm20.inc by Jeroen Benschop) * Creation Date: 2009-01-20 * Tabsize: 4 * Copyright: (c) 2008 by Lukas Schrittwieser and OBJECTIVE DEVELOPMENT Software GmbH * License: GNU GPL v2 (see License.txt), GNU GPL v3 or proprietary (CommercialLicense.txt) */ /* Do not link this file! Link usbdrvasm.S instead, which includes the * appropriate implementation! */ /* General Description: This file is the 18 MHz version of the asssembler part of the USB driver. It requires a 18 MHz crystal (not a ceramic resonator and not a calibrated RC oscillator). See usbdrv.h for a description of the entire driver. Since almost all of this code is timing critical, don't change unless you really know what you are doing! Many parts require not only a maximum number of CPU cycles, but even an exact number of cycles! */ ;max stack usage: [ret(2), YL, SREG, YH, [sofError], bitcnt(x5), shift, x1, x2, x3, x4, cnt, ZL, ZH] = 14 bytes ;nominal frequency: 18 MHz -> 12 cycles per bit ; Numbers in brackets are clocks counted from center of last sync bit ; when instruction starts ;register use in receive loop to receive the data bytes: ; shift assembles the byte currently being received ; x1 holds the D+ and D- line state ; x2 holds the previous line state ; cnt holds the number of bytes left in the receive buffer ; x3 holds the higher crc byte (see algorithm below) ; x4 is used as temporary register for the crc algorithm ; x5 is used for unstuffing: when unstuffing the last received bit is inverted in shift (to prevent further ; unstuffing calls. In the same time the corresponding bit in x5 is cleared to mark the bit as beening iverted ; zl lower crc value and crc table index ; zh used for crc table accesses ;-------------------------------------------------------------------------------------------------------------- ; CRC mods: ; table driven crc checker, Z points to table in prog space ; ZL is the lower crc byte, x3 is the higher crc byte ; x4 is used as temp register to store different results ; the initialization of the crc register is not 0xFFFF but 0xFE54. This is because during the receipt of the ; first data byte an virtual zero data byte is added to the crc register, this results in the correct initial ; value of 0xFFFF at beginning of the second data byte before the first data byte is added to the crc. ; The magic number 0xFE54 results form the crc table: At tabH[0x54] = 0xFF = crcH (required) and ; tabL[0x54] = 0x01 -> crcL = 0x01 xor 0xFE = 0xFF ; bitcnt is renamed to x5 and is used for unstuffing purposes, the unstuffing works like in the 12MHz version ;-------------------------------------------------------------------------------------------------------------- ; CRC algorithm: ; The crc register is formed by x3 (higher byte) and ZL (lower byte). The algorithm uses a 'reversed' form ; i.e. that it takes the least significant bit first and shifts to the right. So in fact the highest order ; bit seen from the polynomial devision point of view is the lsb of ZL. (If this sounds strange to you i ; propose a research on CRC :-) ) ; Each data byte received is xored to ZL, the lower crc byte. This byte now builds the crc ; table index. Next the new high byte is loaded from the table and stored in x4 until we have space in x3 ; (its destination). ; Afterwards the lower table is loaded from the table and stored in ZL (the old index is overwritten as ; we don't need it anymore. In fact this is a right shift by 8 bits.) Now the old crc high value is xored ; to ZL, this is the second shift of the old crc value. Now x4 (the temp reg) is moved to x3 and the crc ; calculation is done. ; Prior to the first byte the two CRC register have to be initialized to 0xFFFF (as defined in usb spec) ; however the crc engine also runs during the receipt of the first byte, therefore x3 and zl are initialized ; to a magic number which results in a crc value of 0xFFFF after the first complete byte. ; ; This algorithm is split into the extra cycles of the different bits: ; bit7: XOR the received byte to ZL ; bit5: load the new high byte to x4 ; bit6: load the lower xor byte from the table, xor zl and x3, store result in zl (=the new crc low value) ; move x4 (the new high byte) to x3, the crc value is ready ; macro POP_STANDARD ; 18 cycles pop ZH pop ZL pop cnt pop x5 pop x3 pop x2 pop x1 pop shift pop x4 endm macro POP_RETI ; 7 cycles pop YH pop YL out SREG, YL pop YL endm macro CRC_CLEANUP_AND_CHECK ; the last byte has already been xored with the lower crc byte, we have to do the table lookup and xor ; x3 is the higher crc byte, zl the lower one ldi ZH, hi8(usbCrcTableHigh);[+1] get the new high byte from the table lpm x2, Z ;[+2][+3][+4] ldi ZH, hi8(usbCrcTableLow);[+5] get the new low xor byte from the table lpm ZL, Z ;[+6][+7][+8] eor ZL, x3 ;[+7] xor the old high byte with the value from the table, x2:ZL now holds the crc value cpi ZL, 0x01 ;[+8] if the crc is ok we have a fixed remainder value of 0xb001 in x2:ZL (see usb spec) brne ignorePacket ;[+9] detected a crc fault -> paket is ignored and retransmitted by the host cpi x2, 0xb0 ;[+10] brne ignorePacket ;[+11] detected a crc fault -> paket is ignored and retransmitted by the host endm USB_INTR_VECTOR: ;order of registers pushed: YL, SREG, YH, [sofError], x4, shift, x1, x2, x3, x5, cnt, ZL, ZH push YL ;[-28] push only what is necessary to sync with edge ASAP in YL, SREG ;[-26] push YL ;[-25] push YH ;[-23] ;---------------------------------------------------------------------------- ; Synchronize with sync pattern: ;---------------------------------------------------------------------------- ;sync byte (D-) pattern LSb to MSb: 01010100 [1 = idle = J, 0 = K] ;sync up with J to K edge during sync pattern -- use fastest possible loops ;The first part waits at most 1 bit long since we must be in sync pattern. ;YL is guarenteed to be < 0x80 because I flag is clear. When we jump to ;waitForJ, ensure that this prerequisite is met. waitForJ: inc YL sbis USBIN, USBMINUS brne waitForJ ; just make sure we have ANY timeout waitForK: ;The following code results in a sampling window of < 1/4 bit which meets the spec. sbis USBIN, USBMINUS ;[-17] rjmp foundK ;[-16] sbis USBIN, USBMINUS rjmp foundK sbis USBIN, USBMINUS rjmp foundK sbis USBIN, USBMINUS rjmp foundK sbis USBIN, USBMINUS rjmp foundK sbis USBIN, USBMINUS rjmp foundK sbis USBIN, USBMINUS rjmp foundK sbis USBIN, USBMINUS rjmp foundK sbis USBIN, USBMINUS rjmp foundK #if USB_COUNT_SOF lds YL, usbSofCount inc YL sts usbSofCount, YL #endif /* USB_COUNT_SOF */ #ifdef USB_SOF_HOOK USB_SOF_HOOK #endif rjmp sofError foundK: ;[-15] ;{3, 5} after falling D- edge, average delay: 4 cycles ;bit0 should be at 30 (2.5 bits) for center sampling. Currently at 4 so 26 cylces till bit 0 sample ;use 1 bit time for setup purposes, then sample again. Numbers in brackets ;are cycles from center of first sync (double K) bit after the instruction push x4 ;[-14] ; [---] ;[-13] lds YL, usbInputBufOffset;[-12] used to toggle the two usb receive buffers ; [---] ;[-11] clr YH ;[-10] subi YL, lo8(-(usbRxBuf));[-9] [rx loop init] sbci YH, hi8(-(usbRxBuf));[-8] [rx loop init] push shift ;[-7] ; [---] ;[-6] ldi shift, 0x80 ;[-5] the last bit is the end of byte marker for the pid receiver loop clc ;[-4] the carry has to be clear for receipt of pid bit 0 sbis USBIN, USBMINUS ;[-3] we want two bits K (sample 3 cycles too early) rjmp haveTwoBitsK ;[-2] pop shift ;[-1] undo the push from before pop x4 ;[1] rjmp waitForK ;[3] this was not the end of sync, retry ; The entire loop from waitForK until rjmp waitForK above must not exceed two ; bit times (= 24 cycles). ;---------------------------------------------------------------------------- ; push more registers and initialize values while we sample the first bits: ;---------------------------------------------------------------------------- haveTwoBitsK: push x1 ;[0] push x2 ;[2] push x3 ;[4] crc high byte ldi x2, 1<<USBPLUS ;[6] [rx loop init] current line state is K state. D+=="1", D-=="0" push x5 ;[7] push cnt ;[9] ldi cnt, USB_BUFSIZE ;[11] ;-------------------------------------------------------------------------------------------------------------- ; receives the pid byte ; there is no real unstuffing algorithm implemented here as a stuffing bit is impossible in the pid byte. ; That's because the last four bits of the byte are the inverted of the first four bits. If we detect a ; unstuffing condition something went wrong and abort ; shift has to be initialized to 0x80 ;-------------------------------------------------------------------------------------------------------------- ; pid bit 0 - used for even more register saving (we need the z pointer) in x1, USBIN ;[0] sample line state andi x1, USBMASK ;[1] filter only D+ and D- bits eor x2, x1 ;[2] generate inverted of actual bit sbrc x2, USBMINUS ;[3] if the bit is set we received a zero sec ;[4] ror shift ;[5] we perform no unstuffing check here as this is the first bit mov x2, x1 ;[6] push ZL ;[7] ;[8] push ZH ;[9] ;[10] ldi x3, 0xFE ;[11] x3 is the high order crc value bitloopPid: in x1, USBIN ;[0] sample line state andi x1, USBMASK ;[1] filter only D+ and D- bits breq nse0 ;[2] both lines are low so handle se0 eor x2, x1 ;[3] generate inverted of actual bit sbrc x2, USBMINUS ;[4] set the carry if we received a zero sec ;[5] ror shift ;[6] ldi ZL, 0x54 ;[7] ZL is the low order crc value ser x4 ;[8] the is no bit stuffing check here as the pid bit can't be stuffed. if so ; some error occured. In this case the paket is discarded later on anyway. mov x2, x1 ;[9] prepare for the next cycle brcc bitloopPid ;[10] while 0s drop out of shift we get the next bit eor x4, shift ;[11] invert all bits in shift and store result in x4 ;-------------------------------------------------------------------------------------------------------------- ; receives data bytes and calculates the crc ; the last USBIN state has to be in x2 ; this is only the first half, due to branch distanc limitations the second half of the loop is near the end ; of this asm file ;-------------------------------------------------------------------------------------------------------------- rxDataStart: in x1, USBIN ;[0] sample line state (note: a se0 check is not useful due to bit dribbling) ser x5 ;[1] prepare the unstuff marker register eor x2, x1 ;[2] generates the inverted of the actual bit bst x2, USBMINUS ;[3] copy the bit from x2 bld shift, 0 ;[4] and store it in shift mov x2, shift ;[5] make a copy of shift for unstuffing check andi x2, 0xF9 ;[6] mask the last six bits, if we got six zeros (which are six ones in fact) breq unstuff0 ;[7] then Z is set now and we branch to the unstuffing handler didunstuff0: subi cnt, 1 ;[8] cannot use dec because it doesn't affect the carry flag brcs nOverflow ;[9] Too many bytes received. Ignore packet st Y+, x4 ;[10] store the last received byte ;[11] st needs two cycles ; bit1 in x2, USBIN ;[0] sample line state andi x1, USBMASK ;[1] check for se0 during bit 0 breq nse0 ;[2] andi x2, USBMASK ;[3] check se0 during bit 1 breq nse0 ;[4] eor x1, x2 ;[5] bst x1, USBMINUS ;[6] bld shift, 1 ;[7] mov x1, shift ;[8] andi x1, 0xF3 ;[9] breq unstuff1 ;[10] didunstuff1: nop ;[11] ; bit2 in x1, USBIN ;[0] sample line state andi x1, USBMASK ;[1] check for se0 (as there is nothing else to do here breq nOverflow ;[2] eor x2, x1 ;[3] generates the inverted of the actual bit bst x2, USBMINUS ;[4] bld shift, 2 ;[5] store the bit mov x2, shift ;[6] andi x2, 0xE7 ;[7] if we have six zeros here (which means six 1 in the stream) breq unstuff2 ;[8] the next bit is a stuffing bit didunstuff2: nop2 ;[9] ;[10] nop ;[11] ; bit3 in x2, USBIN ;[0] sample line state andi x2, USBMASK ;[1] check for se0 breq nOverflow ;[2] eor x1, x2 ;[3] bst x1, USBMINUS ;[4] bld shift, 3 ;[5] mov x1, shift ;[6] andi x1, 0xCF ;[7] breq unstuff3 ;[8] didunstuff3: nop ;[9] rjmp rxDataBit4 ;[10] ;[11] ; the avr branch instructions allow an offset of +63 insturction only, so we need this ; 'local copy' of se0 nse0: rjmp se0 ;[4] ;[5] ; the same same as for se0 is needed for overflow and StuffErr nOverflow: stuffErr: rjmp overflow unstuff0: ;[8] this is the branch delay of breq unstuffX andi x1, USBMASK ;[9] do an se0 check here (if the last crc byte ends with 5 one's we might end up here breq didunstuff0 ;[10] event tough the message is complete -> jump back and store the byte ori shift, 0x01 ;[11] invert the last received bit to prevent furhter unstuffing in x2, USBIN ;[0] we have some free cycles so we could check for bit stuffing errors andi x5, 0xFE ;[1] mark this bit as inverted (will be corrected before storing shift) eor x1, x2 ;[2] x1 and x2 have to be different because the stuff bit is always a zero andi x1, USBMASK ;[3] mask the interesting bits breq stuffErr ;[4] if the stuff bit is a 1-bit something went wrong mov x1, x2 ;[5] the next bit expects the last state to be in x1 rjmp didunstuff0 ;[6] ;[7] jump delay of rjmp didunstuffX unstuff1: ;[11] this is the jump delay of breq unstuffX in x1, USBIN ;[0] we have some free cycles so we could check for bit stuffing errors ori shift, 0x02 ;[1] invert the last received bit to prevent furhter unstuffing andi x5, 0xFD ;[2] mark this bit as inverted (will be corrected before storing shift) eor x2, x1 ;[3] x1 and x2 have to be different because the stuff bit is always a zero andi x2, USBMASK ;[4] mask the interesting bits breq stuffErr ;[5] if the stuff bit is a 1-bit something went wrong mov x2, x1 ;[6] the next bit expects the last state to be in x2 nop2 ;[7] ;[8] rjmp didunstuff1 ;[9] ;[10] jump delay of rjmp didunstuffX unstuff2: ;[9] this is the jump delay of breq unstuffX ori shift, 0x04 ;[10] invert the last received bit to prevent furhter unstuffing andi x5, 0xFB ;[11] mark this bit as inverted (will be corrected before storing shift) in x2, USBIN ;[0] we have some free cycles so we could check for bit stuffing errors eor x1, x2 ;[1] x1 and x2 have to be different because the stuff bit is always a zero andi x1, USBMASK ;[2] mask the interesting bits breq stuffErr ;[3] if the stuff bit is a 1-bit something went wrong mov x1, x2 ;[4] the next bit expects the last state to be in x1 nop2 ;[5] ;[6] rjmp didunstuff2 ;[7] ;[8] jump delay of rjmp didunstuffX unstuff3: ;[9] this is the jump delay of breq unstuffX ori shift, 0x08 ;[10] invert the last received bit to prevent furhter unstuffing andi x5, 0xF7 ;[11] mark this bit as inverted (will be corrected before storing shift) in x1, USBIN ;[0] we have some free cycles so we could check for bit stuffing errors eor x2, x1 ;[1] x1 and x2 have to be different because the stuff bit is always a zero andi x2, USBMASK ;[2] mask the interesting bits breq stuffErr ;[3] if the stuff bit is a 1-bit something went wrong mov x2, x1 ;[4] the next bit expects the last state to be in x2 nop2 ;[5] ;[6] rjmp didunstuff3 ;[7] ;[8] jump delay of rjmp didunstuffX ; the include has to be here due to branch distance restirctions #define __USE_CRC__ #include "asmcommon.inc" ; USB spec says: ; idle = J ; J = (D+ = 0), (D- = 1) ; K = (D+ = 1), (D- = 0) ; Spec allows 7.5 bit times from EOP to SOP for replies ; 7.5 bit times is 90 cycles. ...there is plenty of time sendNakAndReti: ldi x3, USBPID_NAK ;[-18] rjmp sendX3AndReti ;[-17] sendAckAndReti: ldi cnt, USBPID_ACK ;[-17] sendCntAndReti: mov x3, cnt ;[-16] sendX3AndReti: ldi YL, 20 ;[-15] x3==r20 address is 20 ldi YH, 0 ;[-14] ldi cnt, 2 ;[-13] ; rjmp usbSendAndReti fallthrough ;usbSend: ;pointer to data in 'Y' ;number of bytes in 'cnt' -- including sync byte [range 2 ... 12] ;uses: x1...x4, btcnt, shift, cnt, Y ;Numbers in brackets are time since first bit of sync pattern is sent usbSendAndReti: ; 12 cycles until SOP in x2, USBDDR ;[-12] ori x2, USBMASK ;[-11] sbi USBOUT, USBMINUS;[-10] prepare idle state; D+ and D- must have been 0 (no pullups) in x1, USBOUT ;[-8] port mirror for tx loop out USBDDR, x2 ;[-6] <- acquire bus ldi x2, 0 ;[-6] init x2 (bitstuff history) because sync starts with 0 ldi x4, USBMASK ;[-5] exor mask ldi shift, 0x80 ;[-4] sync byte is first byte sent txByteLoop: ldi bitcnt, 0x40 ;[-3]=[9] binary 01000000 txBitLoop: ; the loop sends the first 7 bits of the byte sbrs shift, 0 ;[-2]=[10] if we have to send a 1 don't change the line state eor x1, x4 ;[-1]=[11] out USBOUT, x1 ;[0] ror shift ;[1] ror x2 ;[2] transfers the last sent bit to the stuffing history didStuffN: nop ;[3] nop ;[4] cpi x2, 0xfc ;[5] if we sent six consecutive ones brcc bitstuffN ;[6] lsr bitcnt ;[7] brne txBitLoop ;[8] restart the loop while the 1 is still in the bitcount ; transmit bit 7 sbrs shift, 0 ;[9] eor x1, x4 ;[10] didStuff7: ror shift ;[11] out USBOUT, x1 ;[0] transfer bit 7 to the pins ror x2 ;[1] move the bit into the stuffing history cpi x2, 0xfc ;[2] brcc bitstuff7 ;[3] ld shift, y+ ;[4] get next byte to transmit dec cnt ;[5] decrement byte counter brne txByteLoop ;[7] if we have more bytes start next one ;[8] branch delay ;make SE0: cbr x1, USBMASK ;[8] prepare SE0 [spec says EOP may be 25 to 30 cycles] lds x2, usbNewDeviceAddr;[9] lsl x2 ;[11] we compare with left shifted address out USBOUT, x1 ;[0] <-- out SE0 -- from now 2 bits = 24 cycles until bus idle subi YL, 20 + 2 ;[1] Only assign address on data packets, not ACK/NAK in x3 sbci YH, 0 ;[2] ;2006-03-06: moved transfer of new address to usbDeviceAddr from C-Code to asm: ;set address only after data packet was sent, not after handshake breq skipAddrAssign ;[3] sts usbDeviceAddr, x2 ; if not skipped: SE0 is one cycle longer skipAddrAssign: ;end of usbDeviceAddress transfer ldi x2, 1<<USB_INTR_PENDING_BIT;[5] int0 occurred during TX -- clear pending flag USB_STORE_PENDING(x2) ;[6] ori x1, USBIDLE ;[7] in x2, USBDDR ;[8] cbr x2, USBMASK ;[9] set both pins to input mov x3, x1 ;[10] cbr x3, USBMASK ;[11] configure no pullup on both pins ldi x4, 4 ;[12] se0Delay: dec x4 ;[13] [16] [19] [22] brne se0Delay ;[14] [17] [20] [23] out USBOUT, x1 ;[24] <-- out J (idle) -- end of SE0 (EOP signal) out USBDDR, x2 ;[25] <-- release bus now out USBOUT, x3 ;[26] <-- ensure no pull-up resistors are active rjmp doReturn bitstuffN: eor x1, x4 ;[8] generate a zero ldi x2, 0 ;[9] reset the bit stuffing history nop2 ;[10] out USBOUT, x1 ;[0] <-- send the stuffing bit rjmp didStuffN ;[1] bitstuff7: eor x1, x4 ;[5] ldi x2, 0 ;[6] reset bit stuffing history clc ;[7] fill a zero into the shift register rol shift ;[8] compensate for ror shift at branch destination rjmp didStuff7 ;[9] ;[10] jump delay ;-------------------------------------------------------------------------------------------------------------- ; receives data bytes and calculates the crc ; second half of the data byte receiver loop ; most parts of the crc algorithm are here ;-------------------------------------------------------------------------------------------------------------- nOverflow2: rjmp overflow rxDataBit4: in x1, USBIN ;[0] sample line state andi x1, USBMASK ;[1] check for se0 breq nOverflow2 ;[2] eor x2, x1 ;[3] bst x2, USBMINUS ;[4] bld shift, 4 ;[5] mov x2, shift ;[6] andi x2, 0x9F ;[7] breq unstuff4 ;[8] didunstuff4: nop2 ;[9][10] nop ;[11] ; bit5 in x2, USBIN ;[0] sample line state ldi ZH, hi8(usbCrcTableHigh);[1] use the table for the higher byte eor x1, x2 ;[2] bst x1, USBMINUS ;[3] bld shift, 5 ;[4] mov x1, shift ;[5] andi x1, 0x3F ;[6] breq unstuff5 ;[7] didunstuff5: lpm x4, Z ;[8] load the higher crc xor-byte and store it for later use ;[9] lpm needs 3 cycles ;[10] ldi ZH, hi8(usbCrcTableLow);[11] load the lower crc xor byte adress ; bit6 in x1, USBIN ;[0] sample line state eor x2, x1 ;[1] bst x2, USBMINUS ;[2] bld shift, 6 ;[3] mov x2, shift ;[4] andi x2, 0x7E ;[5] breq unstuff6 ;[6] didunstuff6: lpm ZL, Z ;[7] load the lower xor crc byte ;[8] lpm needs 3 cycles ;[9] eor ZL, x3 ;[10] xor the old high crc byte with the low xor-byte mov x3, x4 ;[11] move the new high order crc value from temp to its destination ; bit7 in x2, USBIN ;[0] sample line state eor x1, x2 ;[1] bst x1, USBMINUS ;[2] bld shift, 7 ;[3] now shift holds the complete but inverted data byte mov x1, shift ;[4] andi x1, 0xFC ;[5] breq unstuff7 ;[6] didunstuff7: eor x5, shift ;[7] x5 marks all bits which have not been inverted by the unstuffing subs mov x4, x5 ;[8] keep a copy of the data byte it will be stored during next bit0 eor ZL, x4 ;[9] feed the actual byte into the crc algorithm rjmp rxDataStart ;[10] next byte ;[11] during the reception of the next byte this one will be fed int the crc algorithm unstuff4: ;[9] this is the jump delay of rjmp unstuffX ori shift, 0x10 ;[10] invert the last received bit to prevent furhter unstuffing andi x5, 0xEF ;[11] mark this bit as inverted (will be corrected before storing shift) in x2, USBIN ;[0] we have some free cycles so we could check for bit stuffing errors eor x1, x2 ;[1] x1 and x2 have to be different because the stuff bit is always a zero andi x1, USBMASK ;[2] mask the interesting bits breq stuffErr2 ;[3] if the stuff bit is a 1-bit something went wrong mov x1, x2 ;[4] the next bit expects the last state to be in x1 nop2 ;[5] ;[6] rjmp didunstuff4 ;[7] ;[8] jump delay of rjmp didunstuffX unstuff5: ;[8] this is the jump delay of rjmp unstuffX nop ;[9] ori shift, 0x20 ;[10] invert the last received bit to prevent furhter unstuffing andi x5, 0xDF ;[11] mark this bit as inverted (will be corrected before storing shift) in x1, USBIN ;[0] we have some free cycles so we could check for bit stuffing errors eor x2, x1 ;[1] x1 and x2 have to be different because the stuff bit is always a zero andi x2, USBMASK ;[2] mask the interesting bits breq stuffErr2 ;[3] if the stuff bit is a 1-bit something went wrong mov x2, x1 ;[4] the next bit expects the last state to be in x2 nop ;[5] rjmp didunstuff5 ;[6] ;[7] jump delay of rjmp didunstuffX unstuff6: ;[7] this is the jump delay of rjmp unstuffX nop2 ;[8] ;[9] ori shift, 0x40 ;[10] invert the last received bit to prevent furhter unstuffing andi x5, 0xBF ;[11] mark this bit as inverted (will be corrected before storing shift) in x2, USBIN ;[0] we have some free cycles so we could check for bit stuffing errors eor x1, x2 ;[1] x1 and x2 have to be different because the stuff bit is always a zero andi x1, USBMASK ;[2] mask the interesting bits breq stuffErr2 ;[3] if the stuff bit is a 1-bit something went wrong mov x1, x2 ;[4] the next bit expects the last state to be in x1 rjmp didunstuff6 ;[5] ;[6] jump delay of rjmp didunstuffX unstuff7: ;[7] this is the jump delay of rjmp unstuffX nop ;[8] nop ;[9] ori shift, 0x80 ;[10] invert the last received bit to prevent furhter unstuffing andi x5, 0x7F ;[11] mark this bit as inverted (will be corrected before storing shift) in x1, USBIN ;[0] we have some free cycles so we could check for bit stuffing errors eor x2, x1 ;[1] x1 and x2 have to be different because the stuff bit is always a zero andi x2, USBMASK ;[2] mask the interesting bits breq stuffErr2 ;[3] if the stuff bit is a 1-bit something went wrong mov x2, x1 ;[4] the next bit expects the last state to be in x2 rjmp didunstuff7 ;[5] ;[6] jump delay of rjmp didunstuff7 ; local copy of the stuffErr desitnation for the second half of the receiver loop stuffErr2: rjmp stuffErr ;-------------------------------------------------------------------------------------------------------------- ; The crc table follows. It has to be aligned to enable a fast loading of the needed bytes. ; There are two tables of 256 entries each, the low and the high byte table. ; Table values were generated with the following C code: /* #include <stdio.h> int main (int argc, char **argv) { int i, j; for (i=0; i<512; i++){ unsigned short crc = i & 0xff; for(j=0; j<8; j++) crc = (crc >> 1) ^ ((crc & 1) ? 0xa001 : 0); if((i & 7) == 0) printf("\n.byte "); printf("0x%02x, ", (i > 0xff ? (crc >> 8) : crc) & 0xff); if(i == 255) printf("\n"); } return 0; } // Use the following algorithm to compute CRC values: ushort computeCrc(uchar *msg, uchar msgLen) { uchar i; ushort crc = 0xffff; for(i = 0; i < msgLen; i++) crc = usbCrcTable16[lo8(crc) ^ msg[i]] ^ hi8(crc); return crc; } */ .balign 256 usbCrcTableLow: .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x00, 0xC1, 0x81, 0x40, 0x01, 0xC0, 0x80, 0x41 .byte 0x01, 0xC0, 0x80, 0x41, 0x00, 0xC1, 0x81, 0x40 ; .balign 256 usbCrcTableHigh: .byte 0x00, 0xC0, 0xC1, 0x01, 0xC3, 0x03, 0x02, 0xC2 .byte 0xC6, 0x06, 0x07, 0xC7, 0x05, 0xC5, 0xC4, 0x04 .byte 0xCC, 0x0C, 0x0D, 0xCD, 0x0F, 0xCF, 0xCE, 0x0E .byte 0x0A, 0xCA, 0xCB, 0x0B, 0xC9, 0x09, 0x08, 0xC8 .byte 0xD8, 0x18, 0x19, 0xD9, 0x1B, 0xDB, 0xDA, 0x1A .byte 0x1E, 0xDE, 0xDF, 0x1F, 0xDD, 0x1D, 0x1C, 0xDC .byte 0x14, 0xD4, 0xD5, 0x15, 0xD7, 0x17, 0x16, 0xD6 .byte 0xD2, 0x12, 0x13, 0xD3, 0x11, 0xD1, 0xD0, 0x10 .byte 0xF0, 0x30, 0x31, 0xF1, 0x33, 0xF3, 0xF2, 0x32 .byte 0x36, 0xF6, 0xF7, 0x37, 0xF5, 0x35, 0x34, 0xF4 .byte 0x3C, 0xFC, 0xFD, 0x3D, 0xFF, 0x3F, 0x3E, 0xFE .byte 0xFA, 0x3A, 0x3B, 0xFB, 0x39, 0xF9, 0xF8, 0x38 .byte 0x28, 0xE8, 0xE9, 0x29, 0xEB, 0x2B, 0x2A, 0xEA .byte 0xEE, 0x2E, 0x2F, 0xEF, 0x2D, 0xED, 0xEC, 0x2C .byte 0xE4, 0x24, 0x25, 0xE5, 0x27, 0xE7, 0xE6, 0x26 .byte 0x22, 0xE2, 0xE3, 0x23, 0xE1, 0x21, 0x20, 0xE0 .byte 0xA0, 0x60, 0x61, 0xA1, 0x63, 0xA3, 0xA2, 0x62 .byte 0x66, 0xA6, 0xA7, 0x67, 0xA5, 0x65, 0x64, 0xA4 .byte 0x6C, 0xAC, 0xAD, 0x6D, 0xAF, 0x6F, 0x6E, 0xAE .byte 0xAA, 0x6A, 0x6B, 0xAB, 0x69, 0xA9, 0xA8, 0x68 .byte 0x78, 0xB8, 0xB9, 0x79, 0xBB, 0x7B, 0x7A, 0xBA .byte 0xBE, 0x7E, 0x7F, 0xBF, 0x7D, 0xBD, 0xBC, 0x7C .byte 0xB4, 0x74, 0x75, 0xB5, 0x77, 0xB7, 0xB6, 0x76 .byte 0x72, 0xB2, 0xB3, 0x73, 0xB1, 0x71, 0x70, 0xB0 .byte 0x50, 0x90, 0x91, 0x51, 0x93, 0x53, 0x52, 0x92 .byte 0x96, 0x56, 0x57, 0x97, 0x55, 0x95, 0x94, 0x54 .byte 0x9C, 0x5C, 0x5D, 0x9D, 0x5F, 0x9F, 0x9E, 0x5E .byte 0x5A, 0x9A, 0x9B, 0x5B, 0x99, 0x59, 0x58, 0x98 .byte 0x88, 0x48, 0x49, 0x89, 0x4B, 0x8B, 0x8A, 0x4A .byte 0x4E, 0x8E, 0x8F, 0x4F, 0x8D, 0x4D, 0x4C, 0x8C .byte 0x44, 0x84, 0x85, 0x45, 0x87, 0x47, 0x46, 0x86 .byte 0x82, 0x42, 0x43, 0x83, 0x41, 0x81, 0x80, 0x40
