/******************************************************************************* * * (c) 1999 by Computone Corporation * ******************************************************************************** * * * PACKAGE: Linux tty Device Driver for IntelliPort family of multiport * serial I/O controllers. * * DESCRIPTION: High-level interface code for the device driver. Uses the * Extremely Low Level Interface Support (i2ellis.c). Provides an * interface to the standard loadware, to support drivers or * application code. (This is included source code, not a separate * compilation module.) * *******************************************************************************/ //------------------------------------------------------------------------------ // Note on Strategy: // Once the board has been initialized, it will interrupt us when: // 1) It has something in the fifo for us to read (incoming data, flow control // packets, or whatever). // 2) It has stripped whatever we have sent last time in the FIFO (and // consequently is ready for more). // // Note also that the buffer sizes declared in i2lib.h are VERY SMALL. This // worsens performance considerably, but is done so that a great many channels // might use only a little memory. //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ // Revision History: // // 0.00 - 4/16/91 --- First Draft // 0.01 - 4/29/91 --- 1st beta release // 0.02 - 6/14/91 --- Changes to allow small model compilation // 0.03 - 6/17/91 MAG Break reporting protected from interrupts routines with // in-line asm added for moving data to/from ring buffers, // replacing a variety of methods used previously. // 0.04 - 6/21/91 MAG Initial flow-control packets not queued until // i2_enable_interrupts time. Former versions would enqueue // them at i2_init_channel time, before we knew how many // channels were supposed to exist! // 0.05 - 10/12/91 MAG Major changes: works through the ellis.c routines now; // supports new 16-bit protocol and expandable boards. // - 10/24/91 MAG Most changes in place and stable. // 0.06 - 2/20/92 MAG Format of CMD_HOTACK corrected: the command takes no // argument. // 0.07 -- 3/11/92 MAG Support added to store special packet types at interrupt // level (mostly responses to specific commands.) // 0.08 -- 3/30/92 MAG Support added for STAT_MODEM packet // 0.09 -- 6/24/93 MAG i2Link... needed to update number of boards BEFORE // turning on the interrupt. // 0.10 -- 6/25/93 MAG To avoid gruesome death from a bad board, we sanity check // some incoming. // // 1.1 - 12/25/96 AKM Linux version. // - 10/09/98 DMC Revised Linux version. //------------------------------------------------------------------------------ //************ //* Includes * //************ #include #include "i2lib.h" //*********************** //* Function Prototypes * //*********************** static void i2QueueNeeds(i2eBordStrPtr, i2ChanStrPtr, int); static i2ChanStrPtr i2DeQueueNeeds(i2eBordStrPtr, int ); static void i2StripFifo(i2eBordStrPtr); static void i2StuffFifoBypass(i2eBordStrPtr); static void i2StuffFifoFlow(i2eBordStrPtr); static void i2StuffFifoInline(i2eBordStrPtr); static int i2RetryFlushOutput(i2ChanStrPtr); // Not a documented part of the library routines (careful...) but the Diagnostic // i2diag.c finds them useful to help the throughput in certain limited // single-threaded operations. static void iiSendPendingMail(i2eBordStrPtr); static void serviceOutgoingFifo(i2eBordStrPtr); // Functions defined in ip2.c as part of interrupt handling static void do_input(void *); static void do_status(void *); //*************** //* Debug Data * //*************** #ifdef DEBUG_FIFO unsigned char DBGBuf[0x4000]; unsigned short I = 0; static void WriteDBGBuf(char *s, unsigned char *src, unsigned short n ) { char *p = src; // XXX: We need a spin lock here if we ever use this again while (*s) { // copy label DBGBuf[I] = *s++; I = I++ & 0x3fff; } while (n--) { // copy data DBGBuf[I] = *p++; I = I++ & 0x3fff; } } static void fatality(i2eBordStrPtr pB ) { int i; for (i=0;i= ' ' && DBGBuf[i] <= '~') { printk(" %c ",DBGBuf[i]); } else { printk(" . "); } } printk("\n"); printk("Last index %x\n",I); } #endif /* DEBUG_FIFO */ //******** //* Code * //******** static inline int i2Validate ( i2ChanStrPtr pCh ) { //ip2trace(pCh->port_index, ITRC_VERIFY,ITRC_ENTER,2,pCh->validity, // (CHANNEL_MAGIC | CHANNEL_SUPPORT)); return ((pCh->validity & (CHANNEL_MAGIC_BITS | CHANNEL_SUPPORT)) == (CHANNEL_MAGIC | CHANNEL_SUPPORT)); } //****************************************************************************** // Function: iiSendPendingMail(pB) // Parameters: Pointer to a board structure // Returns: Nothing // // Description: // If any outgoing mail bits are set and there is outgoing mailbox is empty, // send the mail and clear the bits. //****************************************************************************** static inline void iiSendPendingMail(i2eBordStrPtr pB) { if (pB->i2eOutMailWaiting && (!pB->i2eWaitingForEmptyFifo) ) { if (iiTrySendMail(pB, pB->i2eOutMailWaiting)) { /* If we were already waiting for fifo to empty, * or just sent MB_OUT_STUFFED, then we are * still waiting for it to empty, until we should * receive an MB_IN_STRIPPED from the board. */ pB->i2eWaitingForEmptyFifo |= (pB->i2eOutMailWaiting & MB_OUT_STUFFED); pB->i2eOutMailWaiting = 0; pB->SendPendingRetry = 0; } else { /* The only time we hit this area is when "iiTrySendMail" has failed. That only occurs when the outbound mailbox is still busy with the last message. We take a short breather to let the board catch up with itself and then try again. 16 Retries is the limit - then we got a borked board. /\/\|=mhw=|\/\/ */ if( ++pB->SendPendingRetry < 16 ) { init_timer( &(pB->SendPendingTimer) ); pB->SendPendingTimer.expires = jiffies + 1; pB->SendPendingTimer.function = (void*)(unsigned long)iiSendPendingMail; pB->SendPendingTimer.data = (unsigned long)pB; add_timer( &(pB->SendPendingTimer) ); } else { printk( KERN_ERR "IP2: iiSendPendingMail unable to queue outbound mail\n" ); } } } } //****************************************************************************** // Function: i2InitChannels(pB, nChannels, pCh) // Parameters: Pointer to Ellis Board structure // Number of channels to initialize // Pointer to first element in an array of channel structures // Returns: Success or failure // // Description: // // This function patches pointers, back-pointers, and initializes all the // elements in the channel structure array. // // This should be run after the board structure is initialized, through having // loaded the standard loadware (otherwise it complains). // // In any case, it must be done before any serious work begins initializing the // irq's or sending commands... // //****************************************************************************** static int i2InitChannels ( i2eBordStrPtr pB, int nChannels, i2ChanStrPtr pCh) { int index, stuffIndex; i2ChanStrPtr *ppCh; if (pB->i2eValid != I2E_MAGIC) { COMPLETE(pB, I2EE_BADMAGIC); } if (pB->i2eState != II_STATE_STDLOADED) { COMPLETE(pB, I2EE_BADSTATE); } LOCK_INIT(&pB->read_fifo_spinlock); LOCK_INIT(&pB->write_fifo_spinlock); LOCK_INIT(&pB->Dbuf_spinlock); LOCK_INIT(&pB->Bbuf_spinlock); LOCK_INIT(&pB->Fbuf_spinlock); // NO LOCK needed yet - this is init pB->i2eChannelPtr = pCh; pB->i2eChannelCnt = nChannels; pB->i2Fbuf_strip = pB->i2Fbuf_stuff = 0; pB->i2Dbuf_strip = pB->i2Dbuf_stuff = 0; pB->i2Bbuf_strip = pB->i2Bbuf_stuff = 0; pB->SendPendingRetry = 0; memset ( pCh, 0, sizeof (i2ChanStr) * nChannels ); for (index = stuffIndex = 0, ppCh = (i2ChanStrPtr *)(pB->i2Fbuf); nChannels && index < ABS_MOST_PORTS; index++) { if ( !(pB->i2eChannelMap[index >> 4] & (1 << (index & 0xf)) ) ) { continue; } LOCK_INIT(&pCh->Ibuf_spinlock); LOCK_INIT(&pCh->Obuf_spinlock); LOCK_INIT(&pCh->Cbuf_spinlock); LOCK_INIT(&pCh->Pbuf_spinlock); // NO LOCK needed yet - this is init // Set up validity flag according to support level if (pB->i2eGoodMap[index >> 4] & (1 << (index & 0xf)) ) { pCh->validity = CHANNEL_MAGIC | CHANNEL_SUPPORT; } else { pCh->validity = CHANNEL_MAGIC; } pCh->pMyBord = pB; /* Back-pointer */ // Prepare an outgoing flow-control packet to send as soon as the chance // occurs. if ( pCh->validity & CHANNEL_SUPPORT ) { pCh->infl.hd.i2sChannel = index; pCh->infl.hd.i2sCount = 5; pCh->infl.hd.i2sType = PTYPE_BYPASS; pCh->infl.fcmd = 37; pCh->infl.asof = 0; pCh->infl.room = IBUF_SIZE - 1; pCh->whenSendFlow = (IBUF_SIZE/5)*4; // when 80% full // The following is similar to calling i2QueueNeeds, except that this // is done in longhand, since we are setting up initial conditions on // many channels at once. pCh->channelNeeds = NEED_FLOW; // Since starting from scratch pCh->sinceLastFlow = 0; // No bytes received since last flow // control packet was queued stuffIndex++; *ppCh++ = pCh; // List this channel as needing // initial flow control packet sent } // Don't allow anything to be sent until the status packets come in from // the board. pCh->outfl.asof = 0; pCh->outfl.room = 0; // Initialize all the ring buffers pCh->Ibuf_stuff = pCh->Ibuf_strip = 0; pCh->Obuf_stuff = pCh->Obuf_strip = 0; pCh->Cbuf_stuff = pCh->Cbuf_strip = 0; memset( &pCh->icount, 0, sizeof (struct async_icount) ); pCh->hotKeyIn = HOT_CLEAR; pCh->channelOptions = 0; pCh->bookMarks = 0; init_waitqueue_head(&pCh->pBookmarkWait); init_waitqueue_head(&pCh->open_wait); init_waitqueue_head(&pCh->close_wait); init_waitqueue_head(&pCh->delta_msr_wait); // Set base and divisor so default custom rate is 9600 pCh->BaudBase = 921600; // MAX for ST654, changed after we get pCh->BaudDivisor = 96; // the boxids (UART types) later pCh->dataSetIn = 0; pCh->dataSetOut = 0; pCh->wopen = 0; pCh->throttled = 0; pCh->speed = CBR_9600; pCh->flags = 0; pCh->ClosingDelay = 5*HZ/10; pCh->ClosingWaitTime = 30*HZ; // Initialize task queue objects INIT_WORK(&pCh->tqueue_input, do_input, pCh); INIT_WORK(&pCh->tqueue_status, do_status, pCh); #ifdef IP2DEBUG_TRACE pCh->trace = ip2trace; #endif ++pCh; --nChannels; } // No need to check for wrap here; this is initialization. pB->i2Fbuf_stuff = stuffIndex; COMPLETE(pB, I2EE_GOOD); } //****************************************************************************** // Function: i2DeQueueNeeds(pB, type) // Parameters: Pointer to a board structure // type bit map: may include NEED_INLINE, NEED_BYPASS, or NEED_FLOW // Returns: // Pointer to a channel structure // // Description: Returns pointer struct of next channel that needs service of // the type specified. Otherwise returns a NULL reference. // //****************************************************************************** static i2ChanStrPtr i2DeQueueNeeds(i2eBordStrPtr pB, int type) { unsigned short queueIndex; unsigned long flags; i2ChanStrPtr pCh = NULL; switch(type) { case NEED_INLINE: WRITE_LOCK_IRQSAVE(&pB->Dbuf_spinlock,flags); if ( pB->i2Dbuf_stuff != pB->i2Dbuf_strip) { queueIndex = pB->i2Dbuf_strip; pCh = pB->i2Dbuf[queueIndex]; queueIndex++; if (queueIndex >= CH_QUEUE_SIZE) { queueIndex = 0; } pB->i2Dbuf_strip = queueIndex; pCh->channelNeeds &= ~NEED_INLINE; } WRITE_UNLOCK_IRQRESTORE(&pB->Dbuf_spinlock,flags); break; case NEED_BYPASS: WRITE_LOCK_IRQSAVE(&pB->Bbuf_spinlock,flags); if (pB->i2Bbuf_stuff != pB->i2Bbuf_strip) { queueIndex = pB->i2Bbuf_strip; pCh = pB->i2Bbuf[queueIndex]; queueIndex++; if (queueIndex >= CH_QUEUE_SIZE) { queueIndex = 0; } pB->i2Bbuf_strip = queueIndex; pCh->channelNeeds &= ~NEED_BYPASS; } WRITE_UNLOCK_IRQRESTORE(&pB->Bbuf_spinlock,flags); break; case NEED_FLOW: WRITE_LOCK_IRQSAVE(&pB->Fbuf_spinlock,flags); if (pB->i2Fbuf_stuff != pB->i2Fbuf_strip) { queueIndex = pB->i2Fbuf_strip; pCh = pB->i2Fbuf[queueIndex]; queueIndex++; if (queueIndex >= CH_QUEUE_SIZE) { queueIndex = 0; } pB->i2Fbuf_strip = queueIndex; pCh->channelNeeds &= ~NEED_FLOW; } WRITE_UNLOCK_IRQRESTORE(&pB->Fbuf_spinlock,flags); break; default: printk(KERN_ERR "i2DeQueueNeeds called with bad type:%x\n",type); break; } return pCh; } //****************************************************************************** // Function: i2QueueNeeds(pB, pCh, type) // Parameters: Pointer to a board structure // Pointer to a channel structure // type bit map: may include NEED_INLINE, NEED_BYPASS, or NEED_FLOW // Returns: Nothing // // Description: // For each type of need selected, if the given channel is not already in the // queue, adds it, and sets the flag indicating it is in the queue. //****************************************************************************** static void i2QueueNeeds(i2eBordStrPtr pB, i2ChanStrPtr pCh, int type) { unsigned short queueIndex; unsigned long flags; // We turn off all the interrupts during this brief process, since the // interrupt-level code might want to put things on the queue as well. switch (type) { case NEED_INLINE: WRITE_LOCK_IRQSAVE(&pB->Dbuf_spinlock,flags); if ( !(pCh->channelNeeds & NEED_INLINE) ) { pCh->channelNeeds |= NEED_INLINE; queueIndex = pB->i2Dbuf_stuff; pB->i2Dbuf[queueIndex++] = pCh; if (queueIndex >= CH_QUEUE_SIZE) queueIndex = 0; pB->i2Dbuf_stuff = queueIndex; } WRITE_UNLOCK_IRQRESTORE(&pB->Dbuf_spinlock,flags); break; case NEED_BYPASS: WRITE_LOCK_IRQSAVE(&pB->Bbuf_spinlock,flags); if ((type & NEED_BYPASS) && !(pCh->channelNeeds & NEED_BYPASS)) { pCh->channelNeeds |= NEED_BYPASS; queueIndex = pB->i2Bbuf_stuff; pB->i2Bbuf[queueIndex++] = pCh; if (queueIndex >= CH_QUEUE_SIZE) queueIndex = 0; pB->i2Bbuf_stuff = queueIndex; } WRITE_UNLOCK_IRQRESTORE(&pB->Bbuf_spinlock,flags); break; case NEED_FLOW: WRITE_LOCK_IRQSAVE(&pB->Fbuf_spinlock,flags); if ((type & NEED_FLOW) && !(pCh->channelNeeds & NEED_FLOW)) { pCh->channelNeeds |= NEED_FLOW; queueIndex = pB->i2Fbuf_stuff; pB->i2Fbuf[queueIndex++] = pCh; if (queueIndex >= CH_QUEUE_SIZE) queueIndex = 0; pB->i2Fbuf_stuff = queueIndex; } WRITE_UNLOCK_IRQRESTORE(&pB->Fbuf_spinlock,flags); break; case NEED_CREDIT: pCh->channelNeeds |= NEED_CREDIT; break; default: printk(KERN_ERR "i2QueueNeeds called with bad type:%x\n",type); break; } return; } //****************************************************************************** // Function: i2QueueCommands(type, pCh, timeout, nCommands, pCs,...) // Parameters: type - PTYPE_BYPASS or PTYPE_INLINE // pointer to the channel structure // maximum period to wait // number of commands (n) // n commands // Returns: Number of commands sent, or -1 for error // // get board lock before calling // // Description: // Queues up some commands to be sent to a channel. To send possibly several // bypass or inline commands to the given channel. The timeout parameter // indicates how many HUNDREDTHS OF SECONDS to wait until there is room: // 0 = return immediately if no room, -ive = wait forever, +ive = number of // 1/100 seconds to wait. Return values: // -1 Some kind of nasty error: bad channel structure or invalid arguments. // 0 No room to send all the commands // (+) Number of commands sent //****************************************************************************** static int i2QueueCommands(int type, i2ChanStrPtr pCh, int timeout, int nCommands, cmdSyntaxPtr pCs0,...) { int totalsize = 0; int blocksize; int lastended; cmdSyntaxPtr *ppCs; cmdSyntaxPtr pCs; int count; int flag; i2eBordStrPtr pB; unsigned short maxBlock; unsigned short maxBuff; short bufroom; unsigned short stuffIndex; unsigned char *pBuf; unsigned char *pInsert; unsigned char *pDest, *pSource; unsigned short channel; int cnt; unsigned long flags = 0; rwlock_t *lock_var_p = NULL; // Make sure the channel exists, otherwise do nothing if ( !i2Validate ( pCh ) ) { return -1; } ip2trace (CHANN, ITRC_QUEUE, ITRC_ENTER, 0 ); pB = pCh->pMyBord; // Board must also exist, and THE INTERRUPT COMMAND ALREADY SENT if (pB->i2eValid != I2E_MAGIC || pB->i2eUsingIrq == IRQ_UNDEFINED) { return -2; } // If the board has gone fatal, return bad, and also hit the trap routine if // it exists. if (pB->i2eFatal) { if ( pB->i2eFatalTrap ) { (*(pB)->i2eFatalTrap)(pB); } return -3; } // Set up some variables, Which buffers are we using? How big are they? switch(type) { case PTYPE_INLINE: flag = INL; maxBlock = MAX_OBUF_BLOCK; maxBuff = OBUF_SIZE; pBuf = pCh->Obuf; break; case PTYPE_BYPASS: flag = BYP; maxBlock = MAX_CBUF_BLOCK; maxBuff = CBUF_SIZE; pBuf = pCh->Cbuf; break; default: return -4; } // Determine the total size required for all the commands totalsize = blocksize = sizeof(i2CmdHeader); lastended = 0; ppCs = &pCs0; for ( count = nCommands; count; count--, ppCs++) { pCs = *ppCs; cnt = pCs->length; // Will a new block be needed for this one? // Two possible reasons: too // big or previous command has to be at the end of a packet. if ((blocksize + cnt > maxBlock) || lastended) { blocksize = sizeof(i2CmdHeader); totalsize += sizeof(i2CmdHeader); } totalsize += cnt; blocksize += cnt; // If this command had to end a block, then we will make sure to // account for it should there be any more blocks. lastended = pCs->flags & END; } for (;;) { // Make sure any pending flush commands go out before we add more data. if ( !( pCh->flush_flags && i2RetryFlushOutput( pCh ) ) ) { // How much room (this time through) ? switch(type) { case PTYPE_INLINE: lock_var_p = &pCh->Obuf_spinlock; WRITE_LOCK_IRQSAVE(lock_var_p,flags); stuffIndex = pCh->Obuf_stuff; bufroom = pCh->Obuf_strip - stuffIndex; break; case PTYPE_BYPASS: lock_var_p = &pCh->Cbuf_spinlock; WRITE_LOCK_IRQSAVE(lock_var_p,flags); stuffIndex = pCh->Cbuf_stuff; bufroom = pCh->Cbuf_strip - stuffIndex; break; default: return -5; } if (--bufroom < 0) { bufroom += maxBuff; } ip2trace (CHANN, ITRC_QUEUE, 2, 1, bufroom ); // Check for overflow if (totalsize <= bufroom) { // Normal Expected path - We still hold LOCK break; /* from for()- Enough room: goto proceed */ } } ip2trace (CHANN, ITRC_QUEUE, 3, 1, totalsize ); // Prepare to wait for buffers to empty WRITE_UNLOCK_IRQRESTORE(lock_var_p,flags); serviceOutgoingFifo(pB); // Dump what we got if (timeout == 0) { return 0; // Tired of waiting } if (timeout > 0) timeout--; // So negative values == forever if (!in_interrupt()) { schedule_timeout_interruptible(1); // short nap } else { // we cannot sched/sleep in interrrupt silly return 0; } if (signal_pending(current)) { return 0; // Wake up! Time to die!!! } ip2trace (CHANN, ITRC_QUEUE, 4, 0 ); } // end of for(;;) // At this point we have room and the lock - stick them in. channel = pCh->infl.hd.i2sChannel; pInsert = &pBuf[stuffIndex]; // Pointer to start of packet pDest = CMD_OF(pInsert); // Pointer to start of command // When we start counting, the block is the size of the header for (blocksize = sizeof(i2CmdHeader), count = nCommands, lastended = 0, ppCs = &pCs0; count; count--, ppCs++) { pCs = *ppCs; // Points to command protocol structure // If this is a bookmark request command, post the fact that a bookmark // request is pending. NOTE THIS TRICK ONLY WORKS BECAUSE CMD_BMARK_REQ // has no parameters! The more general solution would be to reference // pCs->cmd[0]. if (pCs == CMD_BMARK_REQ) { pCh->bookMarks++; ip2trace (CHANN, ITRC_DRAIN, 30, 1, pCh->bookMarks ); } cnt = pCs->length; // If this command would put us over the maximum block size or // if the last command had to be at the end of a block, we end // the existing block here and start a new one. if ((blocksize + cnt > maxBlock) || lastended) { ip2trace (CHANN, ITRC_QUEUE, 5, 0 ); PTYPE_OF(pInsert) = type; CHANNEL_OF(pInsert) = channel; // count here does not include the header CMD_COUNT_OF(pInsert) = blocksize - sizeof(i2CmdHeader); stuffIndex += blocksize; if(stuffIndex >= maxBuff) { stuffIndex = 0; pInsert = pBuf; } pInsert = &pBuf[stuffIndex]; // Pointer to start of next pkt pDest = CMD_OF(pInsert); blocksize = sizeof(i2CmdHeader); } // Now we know there is room for this one in the current block blocksize += cnt; // Total bytes in this command pSource = pCs->cmd; // Copy the command into the buffer while (cnt--) { *pDest++ = *pSource++; } // If this command had to end a block, then we will make sure to account // for it should there be any more blocks. lastended = pCs->flags & END; } // end for // Clean up the final block by writing header, etc PTYPE_OF(pInsert) = type; CHANNEL_OF(pInsert) = channel; // count here does not include the header CMD_COUNT_OF(pInsert) = blocksize - sizeof(i2CmdHeader); stuffIndex += blocksize; if(stuffIndex >= maxBuff) { stuffIndex = 0; pInsert = pBuf; } // Updates the index, and post the need for service. When adding these to // the queue of channels, we turn off the interrupt while doing so, // because at interrupt level we might want to push a channel back to the // end of the queue. switch(type) { case PTYPE_INLINE: pCh->Obuf_stuff = stuffIndex; // Store buffer pointer WRITE_UNLOCK_IRQRESTORE(&pCh->Obuf_spinlock,flags); pB->debugInlineQueued++; // Add the channel pointer to list of channels needing service (first // come...), if it's not already there. i2QueueNeeds(pB, pCh, NEED_INLINE); break; case PTYPE_BYPASS: pCh->Cbuf_stuff = stuffIndex; // Store buffer pointer WRITE_UNLOCK_IRQRESTORE(&pCh->Cbuf_spinlock,flags); pB->debugBypassQueued++; // Add the channel pointer to list of channels needing service (first // come...), if it's not already there. i2QueueNeeds(pB, pCh, NEED_BYPASS); break; } ip2trace (CHANN, ITRC_QUEUE, ITRC_RETURN, 1, nCommands ); return nCommands; // Good status: number of commands sent } //****************************************************************************** // Function: i2GetStatus(pCh,resetBits) // Parameters: Pointer to a channel structure // Bit map of status bits to clear // Returns: Bit map of current status bits // // Description: // Returns the state of data set signals, and whether a break has been received, // (see i2lib.h for bit-mapped result). resetBits is a bit-map of any status // bits to be cleared: I2_BRK, I2_PAR, I2_FRA, I2_OVR,... These are cleared // AFTER the condition is passed. If pCh does not point to a valid channel, // returns -1 (which would be impossible otherwise. //****************************************************************************** static int i2GetStatus(i2ChanStrPtr pCh, int resetBits) { unsigned short status; i2eBordStrPtr pB; ip2trace (CHANN, ITRC_STATUS, ITRC_ENTER, 2, pCh->dataSetIn, resetBits ); // Make sure the channel exists, otherwise do nothing */ if ( !i2Validate ( pCh ) ) return -1; pB = pCh->pMyBord; status = pCh->dataSetIn; // Clear any specified error bits: but note that only actual error bits can // be cleared, regardless of the value passed. if (resetBits) { pCh->dataSetIn &= ~(resetBits & (I2_BRK | I2_PAR | I2_FRA | I2_OVR)); pCh->dataSetIn &= ~(I2_DDCD | I2_DCTS | I2_DDSR | I2_DRI); } ip2trace (CHANN, ITRC_STATUS, ITRC_RETURN, 1, pCh->dataSetIn ); return status; } //****************************************************************************** // Function: i2Input(pChpDest,count) // Parameters: Pointer to a channel structure // Pointer to data buffer // Number of bytes to read // Returns: Number of bytes read, or -1 for error // // Description: // Strips data from the input buffer and writes it to pDest. If there is a // collosal blunder, (invalid structure pointers or the like), returns -1. // Otherwise, returns the number of bytes read. //****************************************************************************** static int i2Input(i2ChanStrPtr pCh) { int amountToMove; unsigned short stripIndex; int count; unsigned long flags = 0; ip2trace (CHANN, ITRC_INPUT, ITRC_ENTER, 0); // Ensure channel structure seems real if ( !i2Validate( pCh ) ) { count = -1; goto i2Input_exit; } WRITE_LOCK_IRQSAVE(&pCh->Ibuf_spinlock,flags); // initialize some accelerators and private copies stripIndex = pCh->Ibuf_strip; count = pCh->Ibuf_stuff - stripIndex; // If buffer is empty or requested data count was 0, (trivial case) return // without any further thought. if ( count == 0 ) { WRITE_UNLOCK_IRQRESTORE(&pCh->Ibuf_spinlock,flags); goto i2Input_exit; } // Adjust for buffer wrap if ( count < 0 ) { count += IBUF_SIZE; } // Don't give more than can be taken by the line discipline amountToMove = pCh->pTTY->receive_room; if (count > amountToMove) { count = amountToMove; } // How much could we copy without a wrap? amountToMove = IBUF_SIZE - stripIndex; if (amountToMove > count) { amountToMove = count; } // Move the first block pCh->pTTY->ldisc.receive_buf( pCh->pTTY, &(pCh->Ibuf[stripIndex]), NULL, amountToMove ); // If we needed to wrap, do the second data move if (count > amountToMove) { pCh->pTTY->ldisc.receive_buf( pCh->pTTY, pCh->Ibuf, NULL, count - amountToMove ); } // Bump and wrap the stripIndex all at once by the amount of data read. This // method is good regardless of whether the data was in one or two pieces. stripIndex += count; if (stripIndex >= IBUF_SIZE) { stripIndex -= IBUF_SIZE; } pCh->Ibuf_strip = stripIndex; // Update our flow control information and possibly queue ourselves to send // it, depending on how much data has been stripped since the last time a // packet was sent. pCh->infl.asof += count; if ((pCh->sinceLastFlow += count) >= pCh->whenSendFlow) { pCh->sinceLastFlow -= pCh->whenSendFlow; WRITE_UNLOCK_IRQRESTORE(&pCh->Ibuf_spinlock,flags); i2QueueNeeds(pCh->pMyBord, pCh, NEED_FLOW); } else { WRITE_UNLOCK_IRQRESTORE(&pCh->Ibuf_spinlock,flags); } i2Input_exit: ip2trace (CHANN, ITRC_INPUT, ITRC_RETURN, 1, count); return count; } //****************************************************************************** // Function: i2InputFlush(pCh) // Parameters: Pointer to a channel structure // Returns: Number of bytes stripped, or -1 for error // // Description: // Strips any data from the input buffer. If there is a collosal blunder, // (invalid structure pointers or the like), returns -1. Otherwise, returns the // number of bytes stripped. //****************************************************************************** static int i2InputFlush(i2ChanStrPtr pCh) { int count; unsigned long flags; // Ensure channel structure seems real if ( !i2Validate ( pCh ) ) return -1; ip2trace (CHANN, ITRC_INPUT, 10, 0); WRITE_LOCK_IRQSAVE(&pCh->Ibuf_spinlock,flags); count = pCh->Ibuf_stuff - pCh->Ibuf_strip; // Adjust for buffer wrap if (count < 0) { count += IBUF_SIZE; } // Expedient way to zero out the buffer pCh->Ibuf_strip = pCh->Ibuf_stuff; // Update our flow control information and possibly queue ourselves to send // it, depending on how much data has been stripped since the last time a // packet was sent. pCh->infl.asof += count; if ( (pCh->sinceLastFlow += count) >= pCh->whenSendFlow ) { pCh->sinceLastFlow -= pCh->whenSendFlow; WRITE_UNLOCK_IRQRESTORE(&pCh->Ibuf_spinlock,flags); i2QueueNeeds(pCh->pMyBord, pCh, NEED_FLOW); } else { WRITE_UNLOCK_IRQRESTORE(&pCh->Ibuf_spinlock,flags); } ip2trace (CHANN, ITRC_INPUT, 19, 1, count); return count; } //****************************************************************************** // Function: i2InputAvailable(pCh) // Parameters: Pointer to a channel structure // Returns: Number of bytes available, or -1 for error // // Description: // If there is a collosal blunder, (invalid structure pointers or the like), // returns -1. Otherwise, returns the number of bytes stripped. Otherwise, // returns the number of bytes available in the buffer. //****************************************************************************** #if 0 static int i2InputAvailable(i2ChanStrPtr pCh) { int count; // Ensure channel structure seems real if ( !i2Validate ( pCh ) ) return -1; // initialize some accelerators and private copies READ_LOCK_IRQSAVE(&pCh->Ibuf_spinlock,flags); count = pCh->Ibuf_stuff - pCh->Ibuf_strip; READ_UNLOCK_IRQRESTORE(&pCh->Ibuf_spinlock,flags); // Adjust for buffer wrap if (count < 0) { count += IBUF_SIZE; } return count; } #endif //****************************************************************************** // Function: i2Output(pCh, pSource, count) // Parameters: Pointer to channel structure // Pointer to source data // Number of bytes to send // Returns: Number of bytes sent, or -1 for error // // Description: // Queues the data at pSource to be sent as data packets to the board. If there // is a collosal blunder, (invalid structure pointers or the like), returns -1. // Otherwise, returns the number of bytes written. What if there is not enough // room for all the data? If pCh->channelOptions & CO_NBLOCK_WRITE is set, then // we transfer as many characters as we can now, then return. If this bit is // clear (default), routine will spin along until all the data is buffered. // Should this occur, the 1-ms delay routine is called while waiting to avoid // applications that one cannot break out of. //****************************************************************************** static int i2Output(i2ChanStrPtr pCh, const char *pSource, int count, int user ) { i2eBordStrPtr pB; unsigned char *pInsert; int amountToMove; int countOriginal = count; unsigned short channel; unsigned short stuffIndex; unsigned long flags; int rc = 0; int bailout = 10; ip2trace (CHANN, ITRC_OUTPUT, ITRC_ENTER, 2, count, user ); // Ensure channel structure seems real if ( !i2Validate ( pCh ) ) return -1; // initialize some accelerators and private copies pB = pCh->pMyBord; channel = pCh->infl.hd.i2sChannel; // If the board has gone fatal, return bad, and also hit the trap routine if // it exists. if (pB->i2eFatal) { if (pB->i2eFatalTrap) { (*(pB)->i2eFatalTrap)(pB); } return -1; } // Proceed as though we would do everything while ( count > 0 ) { // How much room in output buffer is there? READ_LOCK_IRQSAVE(&pCh->Obuf_spinlock,flags); amountToMove = pCh->Obuf_strip - pCh->Obuf_stuff - 1; READ_UNLOCK_IRQRESTORE(&pCh->Obuf_spinlock,flags); if (amountToMove < 0) { amountToMove += OBUF_SIZE; } // Subtract off the headers size and see how much room there is for real // data. If this is negative, we will discover later. amountToMove -= sizeof (i2DataHeader); // Don't move more (now) than can go in a single packet if ( amountToMove > (int)(MAX_OBUF_BLOCK - sizeof(i2DataHeader)) ) { amountToMove = MAX_OBUF_BLOCK - sizeof(i2DataHeader); } // Don't move more than the count we were given if (amountToMove > count) { amountToMove = count; } // Now we know how much we must move: NB because the ring buffers have // an overflow area at the end, we needn't worry about wrapping in the // middle of a packet. // Small WINDOW here with no LOCK but I can't call Flush with LOCK // We would be flushing (or ending flush) anyway ip2trace (CHANN, ITRC_OUTPUT, 10, 1, amountToMove ); if ( !(pCh->flush_flags && i2RetryFlushOutput(pCh) ) && amountToMove > 0 ) { WRITE_LOCK_IRQSAVE(&pCh->Obuf_spinlock,flags); stuffIndex = pCh->Obuf_stuff; // Had room to move some data: don't know whether the block size, // buffer space, or what was the limiting factor... pInsert = &(pCh->Obuf[stuffIndex]); // Set up the header CHANNEL_OF(pInsert) = channel; PTYPE_OF(pInsert) = PTYPE_DATA; TAG_OF(pInsert) = 0; ID_OF(pInsert) = ID_ORDINARY_DATA; DATA_COUNT_OF(pInsert) = amountToMove; // Move the data if ( user ) { rc = copy_from_user((char*)(DATA_OF(pInsert)), pSource, amountToMove ); } else { memcpy( (char*)(DATA_OF(pInsert)), pSource, amountToMove ); } // Adjust pointers and indices pSource += amountToMove; pCh->Obuf_char_count += amountToMove; stuffIndex += amountToMove + sizeof(i2DataHeader); count -= amountToMove; if (stuffIndex >= OBUF_SIZE) { stuffIndex = 0; } pCh->Obuf_stuff = stuffIndex; WRITE_UNLOCK_IRQRESTORE(&pCh->Obuf_spinlock,flags); ip2trace (CHANN, ITRC_OUTPUT, 13, 1, stuffIndex ); } else { // Cannot move data // becuz we need to stuff a flush // or amount to move is <= 0 ip2trace(CHANN, ITRC_OUTPUT, 14, 3, amountToMove, pB->i2eFifoRemains, pB->i2eWaitingForEmptyFifo ); // Put this channel back on queue // this ultimatly gets more data or wakes write output i2QueueNeeds(pB, pCh, NEED_INLINE); if ( pB->i2eWaitingForEmptyFifo ) { ip2trace (CHANN, ITRC_OUTPUT, 16, 0 ); // or schedule if (!in_interrupt()) { ip2trace (CHANN, ITRC_OUTPUT, 61, 0 ); schedule_timeout_interruptible(2); if (signal_pending(current)) { break; } continue; } else { ip2trace (CHANN, ITRC_OUTPUT, 62, 0 ); // let interrupt in = WAS restore_flags() // We hold no lock nor is irq off anymore??? break; } break; // from while(count) } else if ( pB->i2eFifoRemains < 32 && !pB->i2eTxMailEmpty ( pB ) ) { ip2trace (CHANN, ITRC_OUTPUT, 19, 2, pB->i2eFifoRemains, pB->i2eTxMailEmpty ); break; // from while(count) } else if ( pCh->channelNeeds & NEED_CREDIT ) { ip2trace (CHANN, ITRC_OUTPUT, 22, 0 ); break; // from while(count) } else if ( --bailout) { // Try to throw more things (maybe not us) in the fifo if we're // not already waiting for it. ip2trace (CHANN, ITRC_OUTPUT, 20, 0 ); serviceOutgoingFifo(pB); //break; CONTINUE; } else { ip2trace (CHANN, ITRC_OUTPUT, 21, 3, pB->i2eFifoRemains, pB->i2eOutMailWaiting, pB->i2eWaitingForEmptyFifo ); break; // from while(count) } } } // End of while(count) i2QueueNeeds(pB, pCh, NEED_INLINE); // We drop through either when the count expires, or when there is some // count left, but there was a non-blocking write. if (countOriginal > count) { ip2trace (CHANN, ITRC_OUTPUT, 17, 2, countOriginal, count ); serviceOutgoingFifo( pB ); } ip2trace (CHANN, ITRC_OUTPUT, ITRC_RETURN, 2, countOriginal, count ); return countOriginal - count; } //****************************************************************************** // Function: i2FlushOutput(pCh) // Parameters: Pointer to a channel structure // Returns: Nothing // // Description: // Sends bypass command to start flushing (waiting possibly forever until there // is room), then sends inline command to stop flushing output, (again waiting // possibly forever). //****************************************************************************** static inline void i2FlushOutput(i2ChanStrPtr pCh) { ip2trace (CHANN, ITRC_FLUSH, 1, 1, pCh->flush_flags ); if (pCh->flush_flags) return; if ( 1 != i2QueueCommands(PTYPE_BYPASS, pCh, 0, 1, CMD_STARTFL) ) { pCh->flush_flags = STARTFL_FLAG; // Failed - flag for later ip2trace (CHANN, ITRC_FLUSH, 2, 0 ); } else if ( 1 != i2QueueCommands(PTYPE_INLINE, pCh, 0, 1, CMD_STOPFL) ) { pCh->flush_flags = STOPFL_FLAG; // Failed - flag for later ip2trace (CHANN, ITRC_FLUSH, 3, 0 ); } } static int i2RetryFlushOutput(i2ChanStrPtr pCh) { int old_flags = pCh->flush_flags; ip2trace (CHANN, ITRC_FLUSH, 14, 1, old_flags ); pCh->flush_flags = 0; // Clear flag so we can avoid recursion // and queue the commands if ( old_flags & STARTFL_FLAG ) { if ( 1 == i2QueueCommands(PTYPE_BYPASS, pCh, 0, 1, CMD_STARTFL) ) { old_flags = STOPFL_FLAG; //Success - send stop flush } else { old_flags = STARTFL_FLAG; //Failure - Flag for retry later } ip2trace (CHANN, ITRC_FLUSH, 15, 1, old_flags ); } if ( old_flags & STOPFL_FLAG ) { if (1 == i2QueueCommands(PTYPE_INLINE, pCh, 0, 1, CMD_STOPFL)) { old_flags = 0; // Success - clear flags } ip2trace (CHANN, ITRC_FLUSH, 16, 1, old_flags ); } pCh->flush_flags = old_flags; ip2trace (CHANN, ITRC_FLUSH, 17, 1, old_flags ); return old_flags; } //****************************************************************************** // Function: i2DrainOutput(pCh,timeout) // Parameters: Pointer to a channel structure // Maximum period to wait // Returns: ? // // Description: // Uses the bookmark request command to ask the board to send a bookmark back as // soon as all the data is completely sent. //****************************************************************************** static void i2DrainWakeup(i2ChanStrPtr pCh) { ip2trace (CHANN, ITRC_DRAIN, 10, 1, pCh->BookmarkTimer.expires ); pCh->BookmarkTimer.expires = 0; wake_up_interruptible( &pCh->pBookmarkWait ); } static void i2DrainOutput(i2ChanStrPtr pCh, int timeout) { wait_queue_t wait; i2eBordStrPtr pB; ip2trace (CHANN, ITRC_DRAIN, ITRC_ENTER, 1, pCh->BookmarkTimer.expires); pB = pCh->pMyBord; // If the board has gone fatal, return bad, // and also hit the trap routine if it exists. if (pB->i2eFatal) { if (pB->i2eFatalTrap) { (*(pB)->i2eFatalTrap)(pB); } return; } if ((timeout > 0) && (pCh->BookmarkTimer.expires == 0 )) { // One per customer (channel) init_timer( &(pCh->BookmarkTimer) ); pCh->BookmarkTimer.expires = jiffies + timeout; pCh->BookmarkTimer.function = (void*)(unsigned long)i2DrainWakeup; pCh->BookmarkTimer.data = (unsigned long)pCh; ip2trace (CHANN, ITRC_DRAIN, 1, 1, pCh->BookmarkTimer.expires ); add_timer( &(pCh->BookmarkTimer) ); } i2QueueCommands( PTYPE_INLINE, pCh, -1, 1, CMD_BMARK_REQ ); init_waitqueue_entry(&wait, current); add_wait_queue(&(pCh->pBookmarkWait), &wait); set_current_state( TASK_INTERRUPTIBLE ); serviceOutgoingFifo( pB ); schedule(); // Now we take our interruptible sleep on // Clean up the queue set_current_state( TASK_RUNNING ); remove_wait_queue(&(pCh->pBookmarkWait), &wait); // if expires == 0 then timer poped, then do not need to del_timer if ((timeout > 0) && pCh->BookmarkTimer.expires && time_before(jiffies, pCh->BookmarkTimer.expires)) { del_timer( &(pCh->BookmarkTimer) ); pCh->BookmarkTimer.expires = 0; ip2trace (CHANN, ITRC_DRAIN, 3, 1, pCh->BookmarkTimer.expires ); } ip2trace (CHANN, ITRC_DRAIN, ITRC_RETURN, 1, pCh->BookmarkTimer.expires ); return; } //****************************************************************************** // Function: i2OutputFree(pCh) // Parameters: Pointer to a channel structure // Returns: Space in output buffer // // Description: // Returns -1 if very gross error. Otherwise returns the amount of bytes still // free in the output buffer. //****************************************************************************** static int i2OutputFree(i2ChanStrPtr pCh) { int amountToMove; unsigned long flags; // Ensure channel structure seems real if ( !i2Validate ( pCh ) ) { return -1; } READ_LOCK_IRQSAVE(&pCh->Obuf_spinlock,flags); amountToMove = pCh->Obuf_strip - pCh->Obuf_stuff - 1; READ_UNLOCK_IRQRESTORE(&pCh->Obuf_spinlock,flags); if (amountToMove < 0) { amountToMove += OBUF_SIZE; } // If this is negative, we will discover later amountToMove -= sizeof(i2DataHeader); return (amountToMove < 0) ? 0 : amountToMove; } static void ip2_owake( PTTY tp) { i2ChanStrPtr pCh; if (tp == NULL) return; pCh = tp->driver_data; ip2trace (CHANN, ITRC_SICMD, 10, 2, tp->flags, (1 << TTY_DO_WRITE_WAKEUP) ); wake_up_interruptible ( &tp->write_wait ); if ( ( tp->flags & (1 << TTY_DO_WRITE_WAKEUP) ) && tp->ldisc.write_wakeup ) { (tp->ldisc.write_wakeup) ( tp ); ip2trace (CHANN, ITRC_SICMD, 11, 0 ); } } static inline void set_baud_params(i2eBordStrPtr pB) { int i,j; i2ChanStrPtr *pCh; pCh = (i2ChanStrPtr *) pB->i2eChannelPtr; for (i = 0; i < ABS_MAX_BOXES; i++) { if (pB->channelBtypes.bid_value[i]) { if (BID_HAS_654(pB->channelBtypes.bid_value[i])) { for (j = 0; j < ABS_BIGGEST_BOX; j++) { if (pCh[i*16+j] == NULL) break; (pCh[i*16+j])->BaudBase = 921600; // MAX for ST654 (pCh[i*16+j])->BaudDivisor = 96; } } else { // has cirrus cd1400 for (j = 0; j < ABS_BIGGEST_BOX; j++) { if (pCh[i*16+j] == NULL) break; (pCh[i*16+j])->BaudBase = 115200; // MAX for CD1400 (pCh[i*16+j])->BaudDivisor = 12; } } } } } //****************************************************************************** // Function: i2StripFifo(pB) // Parameters: Pointer to a board structure // Returns: ? // // Description: // Strips all the available data from the incoming FIFO, identifies the type of // packet, and either buffers the data or does what needs to be done. // // Note there is no overflow checking here: if the board sends more data than it // ought to, we will not detect it here, but blindly overflow... //****************************************************************************** // A buffer for reading in blocks for unknown channels static unsigned char junkBuffer[IBUF_SIZE]; // A buffer to read in a status packet. Because of the size of the count field // for these things, the maximum packet size must be less than MAX_CMD_PACK_SIZE static unsigned char cmdBuffer[MAX_CMD_PACK_SIZE + 4]; // This table changes the bit order from MSR order given by STAT_MODEM packet to // status bits used in our library. static char xlatDss[16] = { 0 | 0 | 0 | 0 , 0 | 0 | 0 | I2_CTS , 0 | 0 | I2_DSR | 0 , 0 | 0 | I2_DSR | I2_CTS , 0 | I2_RI | 0 | 0 , 0 | I2_RI | 0 | I2_CTS , 0 | I2_RI | I2_DSR | 0 , 0 | I2_RI | I2_DSR | I2_CTS , I2_DCD | 0 | 0 | 0 , I2_DCD | 0 | 0 | I2_CTS , I2_DCD | 0 | I2_DSR | 0 , I2_DCD | 0 | I2_DSR | I2_CTS , I2_DCD | I2_RI | 0 | 0 , I2_DCD | I2_RI | 0 | I2_CTS , I2_DCD | I2_RI | I2_DSR | 0 , I2_DCD | I2_RI | I2_DSR | I2_CTS }; static inline void i2StripFifo(i2eBordStrPtr pB) { i2ChanStrPtr pCh; int channel; int count; unsigned short stuffIndex; int amountToRead; unsigned char *pc, *pcLimit; unsigned char uc; unsigned char dss_change; unsigned long bflags,cflags; // ip2trace (ITRC_NO_PORT, ITRC_SFIFO, ITRC_ENTER, 0 ); while (HAS_INPUT(pB)) { // ip2trace (ITRC_NO_PORT, ITRC_SFIFO, 2, 0 ); // Process packet from fifo a one atomic unit WRITE_LOCK_IRQSAVE(&pB->read_fifo_spinlock,bflags); // The first word (or two bytes) will have channel number and type of // packet, possibly other information pB->i2eLeadoffWord[0] = iiReadWord(pB); switch(PTYPE_OF(pB->i2eLeadoffWord)) { case PTYPE_DATA: pB->got_input = 1; // ip2trace (ITRC_NO_PORT, ITRC_SFIFO, 3, 0 ); channel = CHANNEL_OF(pB->i2eLeadoffWord); /* Store channel */ count = iiReadWord(pB); /* Count is in the next word */ // NEW: Check the count for sanity! Should the hardware fail, our death // is more pleasant. While an oversize channel is acceptable (just more // than the driver supports), an over-length count clearly means we are // sick! if ( ((unsigned int)count) > IBUF_SIZE ) { pB->i2eFatal = 2; WRITE_UNLOCK_IRQRESTORE(&pB->read_fifo_spinlock,bflags); return; /* Bail out ASAP */ } // Channel is illegally big ? if ((channel >= pB->i2eChannelCnt) || (NULL==(pCh = ((i2ChanStrPtr*)pB->i2eChannelPtr)[channel]))) { iiReadBuf(pB, junkBuffer, count); WRITE_UNLOCK_IRQRESTORE(&pB->read_fifo_spinlock,bflags); break; /* From switch: ready for next packet */ } // Channel should be valid, then // If this is a hot-key, merely post its receipt for now. These are // always supposed to be 1-byte packets, so we won't even check the // count. Also we will post an acknowledgement to the board so that // more data can be forthcoming. Note that we are not trying to use // these sequences in this driver, merely to robustly ignore them. if(ID_OF(pB->i2eLeadoffWord) == ID_HOT_KEY) { pCh->hotKeyIn = iiReadWord(pB) & 0xff; WRITE_UNLOCK_IRQRESTORE(&pB->read_fifo_spinlock,bflags); i2QueueCommands(PTYPE_BYPASS, pCh, 0, 1, CMD_HOTACK); break; /* From the switch: ready for next packet */ } // Normal data! We crudely assume there is room for the data in our // buffer because the board wouldn't have exceeded his credit limit. WRITE_LOCK_IRQSAVE(&pCh->Ibuf_spinlock,cflags); // We have 2 locks now stuffIndex = pCh->Ibuf_stuff; amountToRead = IBUF_SIZE - stuffIndex; if (amountToRead > count) amountToRead = count; // stuffIndex would have been already adjusted so there would // always be room for at least one, and count is always at least // one. iiReadBuf(pB, &(pCh->Ibuf[stuffIndex]), amountToRead); pCh->icount.rx += amountToRead; // Update the stuffIndex by the amount of data moved. Note we could // never ask for more data than would just fit. However, we might // have read in one more byte than we wanted because the read // rounds up to even bytes. If this byte is on the end of the // packet, and is padding, we ignore it. If the byte is part of // the actual data, we need to move it. stuffIndex += amountToRead; if (stuffIndex >= IBUF_SIZE) { if ((amountToRead & 1) && (count > amountToRead)) { pCh->Ibuf[0] = pCh->Ibuf[IBUF_SIZE]; amountToRead++; stuffIndex = 1; } else { stuffIndex = 0; } } // If there is anything left over, read it as well if (count > amountToRead) { amountToRead = count - amountToRead; iiReadBuf(pB, &(pCh->Ibuf[stuffIndex]), amountToRead); pCh->icount.rx += amountToRead; stuffIndex += amountToRead; } // Update stuff index pCh->Ibuf_stuff = stuffIndex; WRITE_UNLOCK_IRQRESTORE(&pCh->Ibuf_spinlock,cflags); WRITE_UNLOCK_IRQRESTORE(&pB->read_fifo_spinlock,bflags); #ifdef USE_IQ schedule_work(&pCh->tqueue_input); #else do_input(pCh); #endif // Note we do not need to maintain any flow-control credits at this // time: if we were to increment .asof and decrement .room, there // would be no net effect. Instead, when we strip data, we will // increment .asof and leave .room unchanged. break; // From switch: ready for next packet case PTYPE_STATUS: ip2trace (ITRC_NO_PORT, ITRC_SFIFO, 4, 0 ); count = CMD_COUNT_OF(pB->i2eLeadoffWord); iiReadBuf(pB, cmdBuffer, count); // We can release early with buffer grab WRITE_UNLOCK_IRQRESTORE(&pB->read_fifo_spinlock,bflags); pc = cmdBuffer; pcLimit = &(cmdBuffer[count]); while (pc < pcLimit) { channel = *pc++; ip2trace (channel, ITRC_SFIFO, 7, 2, channel, *pc ); /* check for valid channel */ if (channel < pB->i2eChannelCnt && (pCh = (((i2ChanStrPtr*)pB->i2eChannelPtr)[channel])) != NULL ) { dss_change = 0; switch (uc = *pc++) { /* Breaks and modem signals are easy: just update status */ case STAT_CTS_UP: if ( !(pCh->dataSetIn & I2_CTS) ) { pCh->dataSetIn |= I2_DCTS; pCh->icount.cts++; dss_change = 1; } pCh->dataSetIn |= I2_CTS; break; case STAT_CTS_DN: if ( pCh->dataSetIn & I2_CTS ) { pCh->dataSetIn |= I2_DCTS; pCh->icount.cts++; dss_change = 1; } pCh->dataSetIn &= ~I2_CTS; break; case STAT_DCD_UP: ip2trace (channel, ITRC_MODEM, 1, 1, pCh->dataSetIn ); if ( !(pCh->dataSetIn & I2_DCD) ) { ip2trace (CHANN, ITRC_MODEM, 2, 0 ); pCh->dataSetIn |= I2_DDCD; pCh->icount.dcd++; dss_change = 1; } pCh->dataSetIn |= I2_DCD; ip2trace (channel, ITRC_MODEM, 3, 1, pCh->dataSetIn ); break; case STAT_DCD_DN: ip2trace (channel, ITRC_MODEM, 4, 1, pCh->dataSetIn ); if ( pCh->dataSetIn & I2_DCD ) { ip2trace (channel, ITRC_MODEM, 5, 0 ); pCh->dataSetIn |= I2_DDCD; pCh->icount.dcd++; dss_change = 1; } pCh->dataSetIn &= ~I2_DCD; ip2trace (channel, ITRC_MODEM, 6, 1, pCh->dataSetIn ); break; case STAT_DSR_UP: if ( !(pCh->dataSetIn & I2_DSR) ) { pCh->dataSetIn |= I2_DDSR; pCh->icount.dsr++; dss_change = 1; } pCh->dataSetIn |= I2_DSR; break; case STAT_DSR_DN: if ( pCh->dataSetIn & I2_DSR ) { pCh->dataSetIn |= I2_DDSR; pCh->icount.dsr++; dss_change = 1; } pCh->dataSetIn &= ~I2_DSR; break; case STAT_RI_UP: if ( !(pCh->dataSetIn & I2_RI) ) { pCh->dataSetIn |= I2_DRI; pCh->icount.rng++; dss_change = 1; } pCh->dataSetIn |= I2_RI ; break; case STAT_RI_DN: // to be compat with serial.c //if ( pCh->dataSetIn & I2_RI ) //{ // pCh->dataSetIn |= I2_DRI; // pCh->icount.rng++; // dss_change = 1; //} pCh->dataSetIn &= ~I2_RI ; break; case STAT_BRK_DET: pCh->dataSetIn |= I2_BRK; pCh->icount.brk++; dss_change = 1; break; // Bookmarks? one less request we're waiting for case STAT_BMARK: pCh->bookMarks--; if (pCh->bookMarks <= 0 ) { pCh->bookMarks = 0; wake_up_interruptible( &pCh->pBookmarkWait ); ip2trace (channel, ITRC_DRAIN, 20, 1, pCh->BookmarkTimer.expires ); } break; // Flow control packets? Update the new credits, and if // someone was waiting for output, queue him up again. case STAT_FLOW: pCh->outfl.room = ((flowStatPtr)pc)->room - (pCh->outfl.asof - ((flowStatPtr)pc)->asof); ip2trace (channel, ITRC_STFLW, 1, 1, pCh->outfl.room ); if (pCh->channelNeeds & NEED_CREDIT) { ip2trace (channel, ITRC_STFLW, 2, 1, pCh->channelNeeds); pCh->channelNeeds &= ~NEED_CREDIT; i2QueueNeeds(pB, pCh, NEED_INLINE); if ( pCh->pTTY ) ip2_owake(pCh->pTTY); } ip2trace (channel, ITRC_STFLW, 3, 1, pCh->channelNeeds); pc += sizeof(flowStat); break; /* Special packets: */ /* Just copy the information into the channel structure */ case STAT_STATUS: pCh->channelStatus = *((debugStatPtr)pc); pc += sizeof(debugStat); break; case STAT_TXCNT: pCh->channelTcount = *((cntStatPtr)pc); pc += sizeof(cntStat); break; case STAT_RXCNT: pCh->channelRcount = *((cntStatPtr)pc); pc += sizeof(cntStat); break; case STAT_BOXIDS: pB->channelBtypes = *((bidStatPtr)pc); pc += sizeof(bidStat); set_baud_params(pB); break; case STAT_HWFAIL: i2QueueCommands (PTYPE_INLINE, pCh, 0, 1, CMD_HW_TEST); pCh->channelFail = *((failStatPtr)pc); pc += sizeof(failStat); break; /* No explicit match? then * Might be an error packet... */ default: switch (uc & STAT_MOD_ERROR) { case STAT_ERROR: if (uc & STAT_E_PARITY) { pCh->dataSetIn |= I2_PAR; pCh->icount.parity++; } if (uc & STAT_E_FRAMING){ pCh->dataSetIn |= I2_FRA; pCh->icount.frame++; } if (uc & STAT_E_OVERRUN){ pCh->dataSetIn |= I2_OVR; pCh->icount.overrun++; } break; case STAT_MODEM: // the answer to DSS_NOW request (not change) pCh->dataSetIn = (pCh->dataSetIn & ~(I2_RI | I2_CTS | I2_DCD | I2_DSR) ) | xlatDss[uc & 0xf]; wake_up_interruptible ( &pCh->dss_now_wait ); default: break; } } /* End of switch on status type */ if (dss_change) { #ifdef USE_IQ schedule_work(&pCh->tqueue_status); #else do_status(pCh); #endif } } else /* Or else, channel is invalid */ { // Even though the channel is invalid, we must test the // status to see how much additional data it has (to be // skipped) switch (*pc++) { case STAT_FLOW: pc += 4; /* Skip the data */ break; default: break; } } } // End of while (there is still some status packet left) break; default: // Neither packet? should be impossible ip2trace (ITRC_NO_PORT, ITRC_SFIFO, 5, 1, PTYPE_OF(pB->i2eLeadoffWord) ); break; } // End of switch on type of packets } //while(board HAS_INPUT) ip2trace (ITRC_NO_PORT, ITRC_SFIFO, ITRC_RETURN, 0 ); // Send acknowledgement to the board even if there was no data! pB->i2eOutMailWaiting |= MB_IN_STRIPPED; return; } //****************************************************************************** // Function: i2Write2Fifo(pB,address,count) // Parameters: Pointer to a board structure, source address, byte count // Returns: bytes written // // Description: // Writes count bytes to board io address(implied) from source // Adjusts count, leaves reserve for next time around bypass cmds //****************************************************************************** static int i2Write2Fifo(i2eBordStrPtr pB, unsigned char *source, int count,int reserve) { int rc = 0; unsigned long flags; WRITE_LOCK_IRQSAVE(&pB->write_fifo_spinlock,flags); if (!pB->i2eWaitingForEmptyFifo) { if (pB->i2eFifoRemains > (count+reserve)) { pB->i2eFifoRemains -= count; iiWriteBuf(pB, source, count); pB->i2eOutMailWaiting |= MB_OUT_STUFFED; rc = count; } } WRITE_UNLOCK_IRQRESTORE(&pB->write_fifo_spinlock,flags); return rc; } //****************************************************************************** // Function: i2StuffFifoBypass(pB) // Parameters: Pointer to a board structure // Returns: Nothing // // Description: // Stuffs as many bypass commands into the fifo as possible. This is simpler // than stuffing data or inline commands to fifo, since we do not have // flow-control to deal with. //****************************************************************************** static inline void i2StuffFifoBypass(i2eBordStrPtr pB) { i2ChanStrPtr pCh; unsigned char *pRemove; unsigned short stripIndex; unsigned short packetSize; unsigned short paddedSize; unsigned short notClogged = 1; unsigned long flags; int bailout = 1000; // Continue processing so long as there are entries, or there is room in the // fifo. Each entry represents a channel with something to do. while ( --bailout && notClogged && (NULL != (pCh = i2DeQueueNeeds(pB,NEED_BYPASS)))) { WRITE_LOCK_IRQSAVE(&pCh->Cbuf_spinlock,flags); stripIndex = pCh->Cbuf_strip; // as long as there are packets for this channel... while (stripIndex != pCh->Cbuf_stuff) { pRemove = &(pCh->Cbuf[stripIndex]); packetSize = CMD_COUNT_OF(pRemove) + sizeof(i2CmdHeader); paddedSize = ROUNDUP(packetSize); if (paddedSize > 0) { if ( 0 == i2Write2Fifo(pB, pRemove, paddedSize,0)) { notClogged = 0; /* fifo full */ i2QueueNeeds(pB, pCh, NEED_BYPASS); // Put back on queue break; // Break from the channel } } #ifdef DEBUG_FIFO WriteDBGBuf("BYPS", pRemove, paddedSize); #endif /* DEBUG_FIFO */ pB->debugBypassCount++; pRemove += packetSize; stripIndex += packetSize; if (stripIndex >= CBUF_SIZE) { stripIndex = 0; pRemove = pCh->Cbuf; } } // Done with this channel. Move to next, removing this one from // the queue of channels if we cleaned it out (i.e., didn't get clogged. pCh->Cbuf_strip = stripIndex; WRITE_UNLOCK_IRQRESTORE(&pCh->Cbuf_spinlock,flags); } // Either clogged or finished all the work #ifdef IP2DEBUG_TRACE if ( !bailout ) { ip2trace (ITRC_NO_PORT, ITRC_ERROR, 1, 0 ); } #endif } //****************************************************************************** // Function: i2StuffFifoFlow(pB) // Parameters: Pointer to a board structure // Returns: Nothing // // Description: // Stuffs as many flow control packets into the fifo as possible. This is easier // even than doing normal bypass commands, because there is always at most one // packet, already assembled, for each channel. //****************************************************************************** static inline void i2StuffFifoFlow(i2eBordStrPtr pB) { i2ChanStrPtr pCh; unsigned short paddedSize = ROUNDUP(sizeof(flowIn)); ip2trace (ITRC_NO_PORT, ITRC_SFLOW, ITRC_ENTER, 2, pB->i2eFifoRemains, paddedSize ); // Continue processing so long as there are entries, or there is room in the // fifo. Each entry represents a channel with something to do. while ( (NULL != (pCh = i2DeQueueNeeds(pB,NEED_FLOW)))) { pB->debugFlowCount++; // NO Chan LOCK needed ??? if ( 0 == i2Write2Fifo(pB,(unsigned char *)&(pCh->infl),paddedSize,0)) { break; } #ifdef DEBUG_FIFO WriteDBGBuf("FLOW",(unsigned char *) &(pCh->infl), paddedSize); #endif /* DEBUG_FIFO */ } // Either clogged or finished all the work ip2trace (ITRC_NO_PORT, ITRC_SFLOW, ITRC_RETURN, 0 ); } //****************************************************************************** // Function: i2StuffFifoInline(pB) // Parameters: Pointer to a board structure // Returns: Nothing // // Description: // Stuffs as much data and inline commands into the fifo as possible. This is // the most complex fifo-stuffing operation, since there if now the channel // flow-control issue to deal with. //****************************************************************************** static inline void i2StuffFifoInline(i2eBordStrPtr pB) { i2ChanStrPtr pCh; unsigned char *pRemove; unsigned short stripIndex; unsigned short packetSize; unsigned short paddedSize; unsigned short notClogged = 1; unsigned short flowsize; unsigned long flags; int bailout = 1000; int bailout2; ip2trace (ITRC_NO_PORT, ITRC_SICMD, ITRC_ENTER, 3, pB->i2eFifoRemains, pB->i2Dbuf_strip, pB->i2Dbuf_stuff ); // Continue processing so long as there are entries, or there is room in the // fifo. Each entry represents a channel with something to do. while ( --bailout && notClogged && (NULL != (pCh = i2DeQueueNeeds(pB,NEED_INLINE))) ) { WRITE_LOCK_IRQSAVE(&pCh->Obuf_spinlock,flags); stripIndex = pCh->Obuf_strip; ip2trace (CHANN, ITRC_SICMD, 3, 2, stripIndex, pCh->Obuf_stuff ); // as long as there are packets for this channel... bailout2 = 1000; while ( --bailout2 && stripIndex != pCh->Obuf_stuff) { pRemove = &(pCh->Obuf[stripIndex]); // Must determine whether this be a data or command packet to // calculate correctly the header size and the amount of // flow-control credit this type of packet will use. if (PTYPE_OF(pRemove) == PTYPE_DATA) { flowsize = DATA_COUNT_OF(pRemove); packetSize = flowsize + sizeof(i2DataHeader); } else { flowsize = CMD_COUNT_OF(pRemove); packetSize = flowsize + sizeof(i2CmdHeader); } flowsize = CREDIT_USAGE(flowsize); paddedSize = ROUNDUP(packetSize); ip2trace (CHANN, ITRC_SICMD, 4, 2, pB->i2eFifoRemains, paddedSize ); // If we don't have enough credits from the board to send the data, // flag the channel that we are waiting for flow control credit, and // break out. This will clean up this channel and remove us from the // queue of hot things to do. ip2trace (CHANN, ITRC_SICMD, 5, 2, pCh->outfl.room, flowsize ); if (pCh->outfl.room <= flowsize) { // Do Not have the credits to send this packet. i2QueueNeeds(pB, pCh, NEED_CREDIT); notClogged = 0; break; // So to do next channel } if ( (paddedSize > 0) && ( 0 == i2Write2Fifo(pB, pRemove, paddedSize, 128))) { // Do Not have room in fifo to send this packet. notClogged = 0; i2QueueNeeds(pB, pCh, NEED_INLINE); break; // Break from the channel } #ifdef DEBUG_FIFO WriteDBGBuf("DATA", pRemove, paddedSize); #endif /* DEBUG_FIFO */ pB->debugInlineCount++; pCh->icount.tx += flowsize; // Update current credits pCh->outfl.room -= flowsize; pCh->outfl.asof += flowsize; if (PTYPE_OF(pRemove) == PTYPE_DATA) { pCh->Obuf_char_count -= DATA_COUNT_OF(pRemove); } pRemove += packetSize; stripIndex += packetSize; ip2trace (CHANN, ITRC_SICMD, 6, 2, stripIndex, pCh->Obuf_strip); if (stripIndex >= OBUF_SIZE) { stripIndex = 0; pRemove = pCh->Obuf; ip2trace (CHANN, ITRC_SICMD, 7, 1, stripIndex ); } } /* while */ if ( !bailout2 ) { ip2trace (CHANN, ITRC_ERROR, 3, 0 ); } // Done with this channel. Move to next, removing this one from the // queue of channels if we cleaned it out (i.e., didn't get clogged. pCh->Obuf_strip = stripIndex; WRITE_UNLOCK_IRQRESTORE(&pCh->Obuf_spinlock,flags); if ( notClogged ) { ip2trace (CHANN, ITRC_SICMD, 8, 0 ); if ( pCh->pTTY ) { ip2_owake(pCh->pTTY); } } } // Either clogged or finished all the work if ( !bailout ) { ip2trace (ITRC_NO_PORT, ITRC_ERROR, 4, 0 ); } ip2trace (ITRC_NO_PORT, ITRC_SICMD, ITRC_RETURN, 1,pB->i2Dbuf_strip); } //****************************************************************************** // Function: serviceOutgoingFifo(pB) // Parameters: Pointer to a board structure // Returns: Nothing // // Description: // Helper routine to put data in the outgoing fifo, if we aren't already waiting // for something to be there. If the fifo has only room for a very little data, // go head and hit the board with a mailbox hit immediately. Otherwise, it will // have to happen later in the interrupt processing. Since this routine may be // called both at interrupt and foreground time, we must turn off interrupts // during the entire process. //****************************************************************************** static void serviceOutgoingFifo(i2eBordStrPtr pB) { // If we aren't currently waiting for the board to empty our fifo, service // everything that is pending, in priority order (especially, Bypass before // Inline). if ( ! pB->i2eWaitingForEmptyFifo ) { i2StuffFifoFlow(pB); i2StuffFifoBypass(pB); i2StuffFifoInline(pB); iiSendPendingMail(pB); } } //****************************************************************************** // Function: i2ServiceBoard(pB) // Parameters: Pointer to a board structure // Returns: Nothing // // Description: // Normally this is called from interrupt level, but there is deliberately // nothing in here specific to being called from interrupt level. All the // hardware-specific, interrupt-specific things happen at the outer levels. // // For example, a timer interrupt could drive this routine for some sort of // polled operation. The only requirement is that the programmer deal with any // atomiticity/concurrency issues that result. // // This routine responds to the board's having sent mailbox information to the // host (which would normally cause an interrupt). This routine reads the // incoming mailbox. If there is no data in it, this board did not create the // interrupt and/or has nothing to be done to it. (Except, if we have been // waiting to write mailbox data to it, we may do so. // // Based on the value in the mailbox, we may take various actions. // // No checking here of pB validity: after all, it shouldn't have been called by // the handler unless pB were on the list. //****************************************************************************** static inline int i2ServiceBoard ( i2eBordStrPtr pB ) { unsigned inmail; unsigned long flags; /* This should be atomic because of the way we are called... */ if (NO_MAIL_HERE == ( inmail = pB->i2eStartMail ) ) { inmail = iiGetMail(pB); } pB->i2eStartMail = NO_MAIL_HERE; ip2trace (ITRC_NO_PORT, ITRC_INTR, 2, 1, inmail ); if (inmail != NO_MAIL_HERE) { // If the board has gone fatal, nothing to do but hit a bit that will // alert foreground tasks to protest! if ( inmail & MB_FATAL_ERROR ) { pB->i2eFatal = 1; goto exit_i2ServiceBoard; } /* Assuming no fatal condition, we proceed to do work */ if ( inmail & MB_IN_STUFFED ) { pB->i2eFifoInInts++; i2StripFifo(pB); /* There might be incoming packets */ } if (inmail & MB_OUT_STRIPPED) { pB->i2eFifoOutInts++; WRITE_LOCK_IRQSAVE(&pB->write_fifo_spinlock,flags); pB->i2eFifoRemains = pB->i2eFifoSize; pB->i2eWaitingForEmptyFifo = 0; WRITE_UNLOCK_IRQRESTORE(&pB->write_fifo_spinlock,flags); ip2trace (ITRC_NO_PORT, ITRC_INTR, 30, 1, pB->i2eFifoRemains ); } serviceOutgoingFifo(pB); } ip2trace (ITRC_NO_PORT, ITRC_INTR, 8, 0 ); exit_i2ServiceBoard: return 0; }