| |
| /********************************************************************* |
| * |
| * vlsi_ir.h: VLSI82C147 PCI IrDA controller driver for Linux |
| * |
| * Version: 0.5 |
| * |
| * Copyright (c) 2001-2003 Martin Diehl |
| * |
| * This program is free software; you can redistribute it and/or |
| * modify it under the terms of the GNU General Public License as |
| * published by the Free Software Foundation; either version 2 of |
| * the License, or (at your option) any later version. |
| * |
| * This program is distributed in the hope that it will be useful, |
| * but WITHOUT ANY WARRANTY; without even the implied warranty of |
| * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the |
| * GNU General Public License for more details. |
| * |
| * You should have received a copy of the GNU General Public License |
| * along with this program; if not, write to the Free Software |
| * Foundation, Inc., 59 Temple Place, Suite 330, Boston, |
| * MA 02111-1307 USA |
| * |
| ********************************************************************/ |
| |
| #ifndef IRDA_VLSI_FIR_H |
| #define IRDA_VLSI_FIR_H |
| |
| /* ================================================================ |
| * compatibility stuff |
| */ |
| |
| /* definitions not present in pci_ids.h */ |
| |
| #ifndef PCI_CLASS_WIRELESS_IRDA |
| #define PCI_CLASS_WIRELESS_IRDA 0x0d00 |
| #endif |
| |
| #ifndef PCI_CLASS_SUBCLASS_MASK |
| #define PCI_CLASS_SUBCLASS_MASK 0xffff |
| #endif |
| |
| /* in recent 2.5 interrupt handlers have non-void return value */ |
| #ifndef IRQ_RETVAL |
| typedef void irqreturn_t; |
| #define IRQ_NONE |
| #define IRQ_HANDLED |
| #define IRQ_RETVAL(x) |
| #endif |
| |
| /* some stuff need to check kernelversion. Not all 2.5 stuff was present |
| * in early 2.5.x - the test is merely to separate 2.4 from 2.5 |
| */ |
| #include <linux/version.h> |
| |
| #if LINUX_VERSION_CODE < KERNEL_VERSION(2,5,0) |
| |
| /* PDE() introduced in 2.5.4 */ |
| #ifdef CONFIG_PROC_FS |
| #define PDE(inode) ((inode)->i_private) |
| #endif |
| |
| /* irda crc16 calculation exported in 2.5.42 */ |
| #define irda_calc_crc16(fcs,buf,len) (GOOD_FCS) |
| |
| /* we use this for unified pci device name access */ |
| #define PCIDEV_NAME(pdev) ((pdev)->name) |
| |
| #else /* 2.5 or later */ |
| |
| /* whatever we get from the associated struct device - bus:slot:dev.fn id */ |
| #define PCIDEV_NAME(pdev) (pci_name(pdev)) |
| |
| #endif |
| |
| /* ================================================================ */ |
| |
| /* non-standard PCI registers */ |
| |
| enum vlsi_pci_regs { |
| VLSI_PCI_CLKCTL = 0x40, /* chip clock input control */ |
| VLSI_PCI_MSTRPAGE = 0x41, /* addr [31:24] for all busmaster cycles */ |
| VLSI_PCI_IRMISC = 0x42 /* mainly legacy UART related */ |
| }; |
| |
| /* ------------------------------------------ */ |
| |
| /* VLSI_PCI_CLKCTL: Clock Control Register (u8, rw) */ |
| |
| /* Three possible clock sources: either on-chip 48MHz PLL or |
| * external clock applied to EXTCLK pin. External clock may |
| * be either 48MHz or 40MHz, which is indicated by XCKSEL. |
| * CLKSTP controls whether the selected clock source gets |
| * connected to the IrDA block. |
| * |
| * On my HP OB-800 the BIOS sets external 40MHz clock as source |
| * when IrDA enabled and I've never detected any PLL lock success. |
| * Apparently the 14.3...MHz OSC input required for the PLL to work |
| * is not connected and the 40MHz EXTCLK is provided externally. |
| * At least this is what makes the driver working for me. |
| */ |
| |
| enum vlsi_pci_clkctl { |
| |
| /* PLL control */ |
| |
| CLKCTL_PD_INV = 0x04, /* PD#: inverted power down signal, |
| * i.e. PLL is powered, if PD_INV set */ |
| CLKCTL_LOCK = 0x40, /* (ro) set, if PLL is locked */ |
| |
| /* clock source selection */ |
| |
| CLKCTL_EXTCLK = 0x20, /* set to select external clock input, not PLL */ |
| CLKCTL_XCKSEL = 0x10, /* set to indicate EXTCLK is 40MHz, not 48MHz */ |
| |
| /* IrDA block control */ |
| |
| CLKCTL_CLKSTP = 0x80, /* set to disconnect from selected clock source */ |
| CLKCTL_WAKE = 0x08 /* set to enable wakeup feature: whenever IR activity |
| * is detected, PD_INV gets set(?) and CLKSTP cleared */ |
| }; |
| |
| /* ------------------------------------------ */ |
| |
| /* VLSI_PCI_MSTRPAGE: Master Page Register (u8, rw) and busmastering stuff */ |
| |
| #define DMA_MASK_USED_BY_HW 0xffffffff |
| #define DMA_MASK_MSTRPAGE 0x00ffffff |
| #define MSTRPAGE_VALUE (DMA_MASK_MSTRPAGE >> 24) |
| |
| /* PCI busmastering is somewhat special for this guy - in short: |
| * |
| * We select to operate using fixed MSTRPAGE=0, use ISA DMA |
| * address restrictions to make the PCI BM api aware of this, |
| * but ensure the hardware is dealing with real 32bit access. |
| * |
| * In detail: |
| * The chip executes normal 32bit busmaster cycles, i.e. |
| * drives all 32 address lines. These addresses however are |
| * composed of [0:23] taken from various busaddr-pointers |
| * and [24:31] taken from the MSTRPAGE register in the VLSI82C147 |
| * config space. Therefore _all_ busmastering must be |
| * targeted to/from one single 16MB (busaddr-) superpage! |
| * The point is to make sure all the allocations for memory |
| * locations with busmaster access (ring descriptors, buffers) |
| * are indeed bus-mappable to the same 16MB range (for x86 this |
| * means they must reside in the same 16MB physical memory address |
| * range). The only constraint we have which supports "several objects |
| * mappable to common 16MB range" paradigma, is the old ISA DMA |
| * restriction to the first 16MB of physical address range. |
| * Hence the approach here is to enable PCI busmaster support using |
| * the correct 32bit dma-mask used by the chip. Afterwards the device's |
| * dma-mask gets restricted to 24bit, which must be honoured somehow by |
| * all allocations for memory areas to be exposed to the chip ... |
| * |
| * Note: |
| * Don't be surprised to get "Setting latency timer..." messages every |
| * time when PCI busmastering is enabled for the chip. |
| * The chip has its PCI latency timer RO fixed at 0 - which is not a |
| * problem here, because it is never requesting _burst_ transactions. |
| */ |
| |
| /* ------------------------------------------ */ |
| |
| /* VLSI_PCIIRMISC: IR Miscellaneous Register (u8, rw) */ |
| |
| /* legacy UART emulation - not used by this driver - would require: |
| * (see below for some register-value definitions) |
| * |
| * - IRMISC_UARTEN must be set to enable UART address decoding |
| * - IRMISC_UARTSEL configured |
| * - IRCFG_MASTER must be cleared |
| * - IRCFG_SIR must be set |
| * - IRENABLE_PHYANDCLOCK must be asserted 0->1 (and hence IRENABLE_SIR_ON) |
| */ |
| |
| enum vlsi_pci_irmisc { |
| |
| /* IR transceiver control */ |
| |
| IRMISC_IRRAIL = 0x40, /* (ro?) IR rail power indication (and control?) |
| * 0=3.3V / 1=5V. Probably set during power-on? |
| * unclear - not touched by driver */ |
| IRMISC_IRPD = 0x08, /* transceiver power down, if set */ |
| |
| /* legacy UART control */ |
| |
| IRMISC_UARTTST = 0x80, /* UART test mode - "always write 0" */ |
| IRMISC_UARTEN = 0x04, /* enable UART address decoding */ |
| |
| /* bits [1:0] IRMISC_UARTSEL to select legacy UART address */ |
| |
| IRMISC_UARTSEL_3f8 = 0x00, |
| IRMISC_UARTSEL_2f8 = 0x01, |
| IRMISC_UARTSEL_3e8 = 0x02, |
| IRMISC_UARTSEL_2e8 = 0x03 |
| }; |
| |
| /* ================================================================ */ |
| |
| /* registers mapped to 32 byte PCI IO space */ |
| |
| /* note: better access all registers at the indicated u8/u16 size |
| * although some of them contain only 1 byte of information. |
| * some of them (particaluarly PROMPT and IRCFG) ignore |
| * access when using the wrong addressing mode! |
| */ |
| |
| enum vlsi_pio_regs { |
| VLSI_PIO_IRINTR = 0x00, /* interrupt enable/request (u8, rw) */ |
| VLSI_PIO_RINGPTR = 0x02, /* rx/tx ring pointer (u16, ro) */ |
| VLSI_PIO_RINGBASE = 0x04, /* [23:10] of ring address (u16, rw) */ |
| VLSI_PIO_RINGSIZE = 0x06, /* rx/tx ring size (u16, rw) */ |
| VLSI_PIO_PROMPT = 0x08, /* triggers ring processing (u16, wo) */ |
| /* 0x0a-0x0f: reserved / duplicated UART regs */ |
| VLSI_PIO_IRCFG = 0x10, /* configuration select (u16, rw) */ |
| VLSI_PIO_SIRFLAG = 0x12, /* BOF/EOF for filtered SIR (u16, ro) */ |
| VLSI_PIO_IRENABLE = 0x14, /* enable and status register (u16, rw/ro) */ |
| VLSI_PIO_PHYCTL = 0x16, /* physical layer current status (u16, ro) */ |
| VLSI_PIO_NPHYCTL = 0x18, /* next physical layer select (u16, rw) */ |
| VLSI_PIO_MAXPKT = 0x1a, /* [11:0] max len for packet receive (u16, rw) */ |
| VLSI_PIO_RCVBCNT = 0x1c /* current receive-FIFO byte count (u16, ro) */ |
| /* 0x1e-0x1f: reserved / duplicated UART regs */ |
| }; |
| |
| /* ------------------------------------------ */ |
| |
| /* VLSI_PIO_IRINTR: Interrupt Register (u8, rw) */ |
| |
| /* enable-bits: |
| * 1 = enable / 0 = disable |
| * interrupt condition bits: |
| * set according to corresponding interrupt source |
| * (regardless of the state of the enable bits) |
| * enable bit status indicates whether interrupt gets raised |
| * write-to-clear |
| * note: RPKTINT and TPKTINT behave different in legacy UART mode (which we don't use :-) |
| */ |
| |
| enum vlsi_pio_irintr { |
| IRINTR_ACTEN = 0x80, /* activity interrupt enable */ |
| IRINTR_ACTIVITY = 0x40, /* activity monitor (traffic detected) */ |
| IRINTR_RPKTEN = 0x20, /* receive packet interrupt enable*/ |
| IRINTR_RPKTINT = 0x10, /* rx-packet transfered from fifo to memory finished */ |
| IRINTR_TPKTEN = 0x08, /* transmit packet interrupt enable */ |
| IRINTR_TPKTINT = 0x04, /* last bit of tx-packet+crc shifted to ir-pulser */ |
| IRINTR_OE_EN = 0x02, /* UART rx fifo overrun error interrupt enable */ |
| IRINTR_OE_INT = 0x01 /* UART rx fifo overrun error (read LSR to clear) */ |
| }; |
| |
| /* we use this mask to check whether the (shared PCI) interrupt is ours */ |
| |
| #define IRINTR_INT_MASK (IRINTR_ACTIVITY|IRINTR_RPKTINT|IRINTR_TPKTINT) |
| |
| /* ------------------------------------------ */ |
| |
| /* VLSI_PIO_RINGPTR: Ring Pointer Read-Back Register (u16, ro) */ |
| |
| /* _both_ ring pointers are indices relative to the _entire_ rx,tx-ring! |
| * i.e. the referenced descriptor is located |
| * at RINGBASE + PTR * sizeof(descr) for rx and tx |
| * therefore, the tx-pointer has offset MAX_RING_DESCR |
| */ |
| |
| #define MAX_RING_DESCR 64 /* tx, rx rings may contain up to 64 descr each */ |
| |
| #define RINGPTR_RX_MASK (MAX_RING_DESCR-1) |
| #define RINGPTR_TX_MASK ((MAX_RING_DESCR-1)<<8) |
| |
| #define RINGPTR_GET_RX(p) ((p)&RINGPTR_RX_MASK) |
| #define RINGPTR_GET_TX(p) (((p)&RINGPTR_TX_MASK)>>8) |
| |
| /* ------------------------------------------ */ |
| |
| /* VLSI_PIO_RINGBASE: Ring Pointer Base Address Register (u16, ro) */ |
| |
| /* Contains [23:10] part of the ring base (bus-) address |
| * which must be 1k-alinged. [31:24] is taken from |
| * VLSI_PCI_MSTRPAGE above. |
| * The controller initiates non-burst PCI BM cycles to |
| * fetch and update the descriptors in the ring. |
| * Once fetched, the descriptor remains cached onchip |
| * until it gets closed and updated due to the ring |
| * processing state machine. |
| * The entire ring area is split in rx and tx areas with each |
| * area consisting of 64 descriptors of 8 bytes each. |
| * The rx(tx) ring is located at ringbase+0 (ringbase+64*8). |
| */ |
| |
| #define BUS_TO_RINGBASE(p) (((p)>>10)&0x3fff) |
| |
| /* ------------------------------------------ */ |
| |
| /* VLSI_PIO_RINGSIZE: Ring Size Register (u16, rw) */ |
| |
| /* bit mask to indicate the ring size to be used for rx and tx. |
| * possible values encoded bits |
| * 4 0000 |
| * 8 0001 |
| * 16 0011 |
| * 32 0111 |
| * 64 1111 |
| * located at [15:12] for tx and [11:8] for rx ([7:0] unused) |
| * |
| * note: probably a good idea to have IRCFG_MSTR cleared when writing |
| * this so the state machines are stopped and the RINGPTR is reset! |
| */ |
| |
| #define SIZE_TO_BITS(num) ((((num)-1)>>2)&0x0f) |
| #define TX_RX_TO_RINGSIZE(tx,rx) ((SIZE_TO_BITS(tx)<<12)|(SIZE_TO_BITS(rx)<<8)) |
| #define RINGSIZE_TO_RXSIZE(rs) ((((rs)&0x0f00)>>6)+4) |
| #define RINGSIZE_TO_TXSIZE(rs) ((((rs)&0xf000)>>10)+4) |
| |
| |
| /* ------------------------------------------ */ |
| |
| /* VLSI_PIO_PROMPT: Ring Prompting Register (u16, write-to-start) */ |
| |
| /* writing any value kicks the ring processing state machines |
| * for both tx, rx rings as follows: |
| * - active rings (currently owning an active descriptor) |
| * ignore the prompt and continue |
| * - idle rings fetch the next descr from the ring and start |
| * their processing |
| */ |
| |
| /* ------------------------------------------ */ |
| |
| /* VLSI_PIO_IRCFG: IR Config Register (u16, rw) */ |
| |
| /* notes: |
| * - not more than one SIR/MIR/FIR bit must be set at any time |
| * - SIR, MIR, FIR and CRC16 select the configuration which will |
| * be applied on next 0->1 transition of IRENABLE_PHYANDCLOCK (see below). |
| * - besides allowing the PCI interface to execute busmaster cycles |
| * and therefore the ring SM to operate, the MSTR bit has side-effects: |
| * when MSTR is cleared, the RINGPTR's get reset and the legacy UART mode |
| * (in contrast to busmaster access mode) gets enabled. |
| * - clearing ENRX or setting ENTX while data is received may stall the |
| * receive fifo until ENRX reenabled _and_ another packet arrives |
| * - SIRFILT means the chip performs the required unwrapping of hardware |
| * headers (XBOF's, BOF/EOF) and un-escaping in the _receive_ direction. |
| * Only the resulting IrLAP payload is copied to the receive buffers - |
| * but with the 16bit FCS still encluded. Question remains, whether it |
| * was already checked or we should do it before passing the packet to IrLAP? |
| */ |
| |
| enum vlsi_pio_ircfg { |
| IRCFG_LOOP = 0x4000, /* enable loopback test mode */ |
| IRCFG_ENTX = 0x1000, /* transmit enable */ |
| IRCFG_ENRX = 0x0800, /* receive enable */ |
| IRCFG_MSTR = 0x0400, /* master enable */ |
| IRCFG_RXANY = 0x0200, /* receive any packet */ |
| IRCFG_CRC16 = 0x0080, /* 16bit (not 32bit) CRC select for MIR/FIR */ |
| IRCFG_FIR = 0x0040, /* FIR 4PPM encoding mode enable */ |
| IRCFG_MIR = 0x0020, /* MIR HDLC encoding mode enable */ |
| IRCFG_SIR = 0x0010, /* SIR encoding mode enable */ |
| IRCFG_SIRFILT = 0x0008, /* enable SIR decode filter (receiver unwrapping) */ |
| IRCFG_SIRTEST = 0x0004, /* allow SIR decode filter when not in SIR mode */ |
| IRCFG_TXPOL = 0x0002, /* invert tx polarity when set */ |
| IRCFG_RXPOL = 0x0001 /* invert rx polarity when set */ |
| }; |
| |
| /* ------------------------------------------ */ |
| |
| /* VLSI_PIO_SIRFLAG: SIR Flag Register (u16, ro) */ |
| |
| /* register contains hardcoded BOF=0xc0 at [7:0] and EOF=0xc1 at [15:8] |
| * which is used for unwrapping received frames in SIR decode-filter mode |
| */ |
| |
| /* ------------------------------------------ */ |
| |
| /* VLSI_PIO_IRENABLE: IR Enable Register (u16, rw/ro) */ |
| |
| /* notes: |
| * - IREN acts as gate for latching the configured IR mode information |
| * from IRCFG and IRPHYCTL when IREN=reset and applying them when |
| * IREN gets set afterwards. |
| * - ENTXST reflects IRCFG_ENTX |
| * - ENRXST = IRCFG_ENRX && (!IRCFG_ENTX || IRCFG_LOOP) |
| */ |
| |
| enum vlsi_pio_irenable { |
| IRENABLE_PHYANDCLOCK = 0x8000, /* enable IR phy and gate the mode config (rw) */ |
| IRENABLE_CFGER = 0x4000, /* mode configuration error (ro) */ |
| IRENABLE_FIR_ON = 0x2000, /* FIR on status (ro) */ |
| IRENABLE_MIR_ON = 0x1000, /* MIR on status (ro) */ |
| IRENABLE_SIR_ON = 0x0800, /* SIR on status (ro) */ |
| IRENABLE_ENTXST = 0x0400, /* transmit enable status (ro) */ |
| IRENABLE_ENRXST = 0x0200, /* Receive enable status (ro) */ |
| IRENABLE_CRC16_ON = 0x0100 /* 16bit (not 32bit) CRC enabled status (ro) */ |
| }; |
| |
| #define IRENABLE_MASK 0xff00 /* Read mask */ |
| |
| /* ------------------------------------------ */ |
| |
| /* VLSI_PIO_PHYCTL: IR Physical Layer Current Control Register (u16, ro) */ |
| |
| /* read-back of the currently applied physical layer status. |
| * applied from VLSI_PIO_NPHYCTL at rising edge of IRENABLE_PHYANDCLOCK |
| * contents identical to VLSI_PIO_NPHYCTL (see below) |
| */ |
| |
| /* ------------------------------------------ */ |
| |
| /* VLSI_PIO_NPHYCTL: IR Physical Layer Next Control Register (u16, rw) */ |
| |
| /* latched during IRENABLE_PHYANDCLOCK=0 and applied at 0-1 transition |
| * |
| * consists of BAUD[15:10], PLSWID[9:5] and PREAMB[4:0] bits defined as follows: |
| * |
| * SIR-mode: BAUD = (115.2kHz / baudrate) - 1 |
| * PLSWID = (pulsetime * freq / (BAUD+1)) - 1 |
| * where pulsetime is the requested IrPHY pulse width |
| * and freq is 8(16)MHz for 40(48)MHz primary input clock |
| * PREAMB: don't care for SIR |
| * |
| * The nominal SIR pulse width is 3/16 bit time so we have PLSWID=12 |
| * fixed for all SIR speeds at 40MHz input clock (PLSWID=24 at 48MHz). |
| * IrPHY also allows shorter pulses down to the nominal pulse duration |
| * at 115.2kbaud (minus some tolerance) which is 1.41 usec. |
| * Using the expression PLSWID = 12/(BAUD+1)-1 (multiplied by two for 48MHz) |
| * we get the minimum acceptable PLSWID values according to the VLSI |
| * specification, which provides 1.5 usec pulse width for all speeds (except |
| * for 2.4kbaud getting 6usec). This is fine with IrPHY v1.3 specs and |
| * reduces the transceiver power which drains the battery. At 9.6kbaud for |
| * example this amounts to more than 90% battery power saving! |
| * |
| * MIR-mode: BAUD = 0 |
| * PLSWID = 9(10) for 40(48) MHz input clock |
| * to get nominal MIR pulse width |
| * PREAMB = 1 |
| * |
| * FIR-mode: BAUD = 0 |
| * PLSWID: don't care |
| * PREAMB = 15 |
| */ |
| |
| #define PHYCTL_BAUD_SHIFT 10 |
| #define PHYCTL_BAUD_MASK 0xfc00 |
| #define PHYCTL_PLSWID_SHIFT 5 |
| #define PHYCTL_PLSWID_MASK 0x03e0 |
| #define PHYCTL_PREAMB_SHIFT 0 |
| #define PHYCTL_PREAMB_MASK 0x001f |
| |
| #define PHYCTL_TO_BAUD(bwp) (((bwp)&PHYCTL_BAUD_MASK)>>PHYCTL_BAUD_SHIFT) |
| #define PHYCTL_TO_PLSWID(bwp) (((bwp)&PHYCTL_PLSWID_MASK)>>PHYCTL_PLSWID_SHIFT) |
| #define PHYCTL_TO_PREAMB(bwp) (((bwp)&PHYCTL_PREAMB_MASK)>>PHYCTL_PREAMB_SHIFT) |
| |
| #define BWP_TO_PHYCTL(b,w,p) ((((b)<<PHYCTL_BAUD_SHIFT)&PHYCTL_BAUD_MASK) \ |
| | (((w)<<PHYCTL_PLSWID_SHIFT)&PHYCTL_PLSWID_MASK) \ |
| | (((p)<<PHYCTL_PREAMB_SHIFT)&PHYCTL_PREAMB_MASK)) |
| |
| #define BAUD_BITS(br) ((115200/(br))-1) |
| |
| static inline unsigned |
| calc_width_bits(unsigned baudrate, unsigned widthselect, unsigned clockselect) |
| { |
| unsigned tmp; |
| |
| if (widthselect) /* nominal 3/16 puls width */ |
| return (clockselect) ? 12 : 24; |
| |
| tmp = ((clockselect) ? 12 : 24) / (BAUD_BITS(baudrate)+1); |
| |
| /* intermediate result of integer division needed here */ |
| |
| return (tmp>0) ? (tmp-1) : 0; |
| } |
| |
| #define PHYCTL_SIR(br,ws,cs) BWP_TO_PHYCTL(BAUD_BITS(br),calc_width_bits((br),(ws),(cs)),0) |
| #define PHYCTL_MIR(cs) BWP_TO_PHYCTL(0,((cs)?9:10),1) |
| #define PHYCTL_FIR BWP_TO_PHYCTL(0,0,15) |
| |
| /* quite ugly, I know. But implementing these calculations here avoids |
| * having magic numbers in the code and allows some playing with pulsewidths |
| * without risk to violate the standards. |
| * FWIW, here is the table for reference: |
| * |
| * baudrate BAUD min-PLSWID nom-PLSWID PREAMB |
| * 2400 47 0(0) 12(24) 0 |
| * 9600 11 0(0) 12(24) 0 |
| * 19200 5 1(2) 12(24) 0 |
| * 38400 2 3(6) 12(24) 0 |
| * 57600 1 5(10) 12(24) 0 |
| * 115200 0 11(22) 12(24) 0 |
| * MIR 0 - 9(10) 1 |
| * FIR 0 - 0 15 |
| * |
| * note: x(y) means x-value for 40MHz / y-value for 48MHz primary input clock |
| */ |
| |
| /* ------------------------------------------ */ |
| |
| |
| /* VLSI_PIO_MAXPKT: Maximum Packet Length register (u16, rw) */ |
| |
| /* maximum acceptable length for received packets */ |
| |
| /* hw imposed limitation - register uses only [11:0] */ |
| #define MAX_PACKET_LENGTH 0x0fff |
| |
| /* IrLAP I-field (apparently not defined elsewhere) */ |
| #define IRDA_MTU 2048 |
| |
| /* complete packet consists of A(1)+C(1)+I(<=IRDA_MTU) */ |
| #define IRLAP_SKB_ALLOCSIZE (1+1+IRDA_MTU) |
| |
| /* the buffers we use to exchange frames with the hardware need to be |
| * larger than IRLAP_SKB_ALLOCSIZE because we may have up to 4 bytes FCS |
| * appended and, in SIR mode, a lot of frame wrapping bytes. The worst |
| * case appears to be a SIR packet with I-size==IRDA_MTU and all bytes |
| * requiring to be escaped to provide transparency. Furthermore, the peer |
| * might ask for quite a number of additional XBOFs: |
| * up to 115+48 XBOFS 163 |
| * regular BOF 1 |
| * A-field 1 |
| * C-field 1 |
| * I-field, IRDA_MTU, all escaped 4096 |
| * FCS (16 bit at SIR, escaped) 4 |
| * EOF 1 |
| * AFAICS nothing in IrLAP guarantees A/C field not to need escaping |
| * (f.e. 0xc0/0xc1 - i.e. BOF/EOF - are legal values there) so in the |
| * worst case we have 4269 bytes total frame size. |
| * However, the VLSI uses 12 bits only for all buffer length values, |
| * which limits the maximum useable buffer size <= 4095. |
| * Note this is not a limitation in the receive case because we use |
| * the SIR filtering mode where the hw unwraps the frame and only the |
| * bare packet+fcs is stored into the buffer - in contrast to the SIR |
| * tx case where we have to pass frame-wrapped packets to the hw. |
| * If this would ever become an issue in real life, the only workaround |
| * I see would be using the legacy UART emulation in SIR mode. |
| */ |
| |
| #define XFER_BUF_SIZE MAX_PACKET_LENGTH |
| |
| /* ------------------------------------------ */ |
| |
| /* VLSI_PIO_RCVBCNT: Receive Byte Count Register (u16, ro) */ |
| |
| /* receive packet counter gets incremented on every non-filtered |
| * byte which was put in the receive fifo and reset for each |
| * new packet. Used to decide whether we are just in the middle |
| * of receiving |
| */ |
| |
| /* better apply the [11:0] mask when reading, as some docs say the |
| * reserved [15:12] would return 1 when reading - which is wrong AFAICS |
| */ |
| #define RCVBCNT_MASK 0x0fff |
| |
| /******************************************************************/ |
| |
| /* descriptors for rx/tx ring |
| * |
| * accessed by hardware - don't change! |
| * |
| * the descriptor is owned by hardware, when the ACTIVE status bit |
| * is set and nothing (besides reading status to test the bit) |
| * shall be done. The bit gets cleared by hw, when the descriptor |
| * gets closed. Premature reaping of descriptors owned be the chip |
| * can be achieved by disabling IRCFG_MSTR |
| * |
| * Attention: Writing addr overwrites status! |
| * |
| * ### FIXME: depends on endianess (but there ain't no non-i586 ob800 ;-) |
| */ |
| |
| struct ring_descr_hw { |
| volatile u16 rd_count; /* tx/rx count [11:0] */ |
| u16 reserved; |
| union { |
| u32 addr; /* [23:0] of the buffer's busaddress */ |
| struct { |
| u8 addr_res[3]; |
| volatile u8 status; /* descriptor status */ |
| } __attribute__((packed)) rd_s; |
| } __attribute((packed)) rd_u; |
| } __attribute__ ((packed)); |
| |
| #define rd_addr rd_u.addr |
| #define rd_status rd_u.rd_s.status |
| |
| /* ring descriptor status bits */ |
| |
| #define RD_ACTIVE 0x80 /* descriptor owned by hw (both TX,RX) */ |
| |
| /* TX ring descriptor status */ |
| |
| #define RD_TX_DISCRC 0x40 /* do not send CRC (for SIR) */ |
| #define RD_TX_BADCRC 0x20 /* force a bad CRC */ |
| #define RD_TX_PULSE 0x10 /* send indication pulse after this frame (MIR/FIR) */ |
| #define RD_TX_FRCEUND 0x08 /* force underrun */ |
| #define RD_TX_CLRENTX 0x04 /* clear ENTX after this frame */ |
| #define RD_TX_UNDRN 0x01 /* TX fifo underrun (probably PCI problem) */ |
| |
| /* RX ring descriptor status */ |
| |
| #define RD_RX_PHYERR 0x40 /* physical encoding error */ |
| #define RD_RX_CRCERR 0x20 /* CRC error (MIR/FIR) */ |
| #define RD_RX_LENGTH 0x10 /* frame exceeds buffer length */ |
| #define RD_RX_OVER 0x08 /* RX fifo overrun (probably PCI problem) */ |
| #define RD_RX_SIRBAD 0x04 /* EOF missing: BOF follows BOF (SIR, filtered) */ |
| |
| #define RD_RX_ERROR 0x7c /* any error in received frame */ |
| |
| /* the memory required to hold the 2 descriptor rings */ |
| #define HW_RING_AREA_SIZE (2 * MAX_RING_DESCR * sizeof(struct ring_descr_hw)) |
| |
| /******************************************************************/ |
| |
| /* sw-ring descriptors consists of a bus-mapped transfer buffer with |
| * associated skb and a pointer to the hw entry descriptor |
| */ |
| |
| struct ring_descr { |
| struct ring_descr_hw *hw; |
| struct sk_buff *skb; |
| void *buf; |
| }; |
| |
| /* wrappers for operations on hw-exposed ring descriptors |
| * access to the hw-part of the descriptors must use these. |
| */ |
| |
| static inline int rd_is_active(struct ring_descr *rd) |
| { |
| return ((rd->hw->rd_status & RD_ACTIVE) != 0); |
| } |
| |
| static inline void rd_activate(struct ring_descr *rd) |
| { |
| rd->hw->rd_status |= RD_ACTIVE; |
| } |
| |
| static inline void rd_set_status(struct ring_descr *rd, u8 s) |
| { |
| rd->hw->rd_status = s; /* may pass ownership to the hardware */ |
| } |
| |
| static inline void rd_set_addr_status(struct ring_descr *rd, dma_addr_t a, u8 s) |
| { |
| /* order is important for two reasons: |
| * - overlayed: writing addr overwrites status |
| * - we want to write status last so we have valid address in |
| * case status has RD_ACTIVE set |
| */ |
| |
| if ((a & ~DMA_MASK_MSTRPAGE)>>24 != MSTRPAGE_VALUE) { |
| IRDA_ERROR("%s: pci busaddr inconsistency!\n", __FUNCTION__); |
| dump_stack(); |
| return; |
| } |
| |
| a &= DMA_MASK_MSTRPAGE; /* clear highbyte to make sure we won't write |
| * to status - just in case MSTRPAGE_VALUE!=0 |
| */ |
| rd->hw->rd_addr = cpu_to_le32(a); |
| wmb(); |
| rd_set_status(rd, s); /* may pass ownership to the hardware */ |
| } |
| |
| static inline void rd_set_count(struct ring_descr *rd, u16 c) |
| { |
| rd->hw->rd_count = cpu_to_le16(c); |
| } |
| |
| static inline u8 rd_get_status(struct ring_descr *rd) |
| { |
| return rd->hw->rd_status; |
| } |
| |
| static inline dma_addr_t rd_get_addr(struct ring_descr *rd) |
| { |
| dma_addr_t a; |
| |
| a = le32_to_cpu(rd->hw->rd_addr); |
| return (a & DMA_MASK_MSTRPAGE) | (MSTRPAGE_VALUE << 24); |
| } |
| |
| static inline u16 rd_get_count(struct ring_descr *rd) |
| { |
| return le16_to_cpu(rd->hw->rd_count); |
| } |
| |
| /******************************************************************/ |
| |
| /* sw descriptor rings for rx, tx: |
| * |
| * operations follow producer-consumer paradigm, with the hw |
| * in the middle doing the processing. |
| * ring size must be power of two. |
| * |
| * producer advances r->tail after inserting for processing |
| * consumer advances r->head after removing processed rd |
| * ring is empty if head==tail / full if (tail+1)==head |
| */ |
| |
| struct vlsi_ring { |
| struct pci_dev *pdev; |
| int dir; |
| unsigned len; |
| unsigned size; |
| unsigned mask; |
| atomic_t head, tail; |
| struct ring_descr *rd; |
| }; |
| |
| /* ring processing helpers */ |
| |
| static inline struct ring_descr *ring_last(struct vlsi_ring *r) |
| { |
| int t; |
| |
| t = atomic_read(&r->tail) & r->mask; |
| return (((t+1) & r->mask) == (atomic_read(&r->head) & r->mask)) ? NULL : &r->rd[t]; |
| } |
| |
| static inline struct ring_descr *ring_put(struct vlsi_ring *r) |
| { |
| atomic_inc(&r->tail); |
| return ring_last(r); |
| } |
| |
| static inline struct ring_descr *ring_first(struct vlsi_ring *r) |
| { |
| int h; |
| |
| h = atomic_read(&r->head) & r->mask; |
| return (h == (atomic_read(&r->tail) & r->mask)) ? NULL : &r->rd[h]; |
| } |
| |
| static inline struct ring_descr *ring_get(struct vlsi_ring *r) |
| { |
| atomic_inc(&r->head); |
| return ring_first(r); |
| } |
| |
| /******************************************************************/ |
| |
| /* our private compound VLSI-PCI-IRDA device information */ |
| |
| typedef struct vlsi_irda_dev { |
| struct pci_dev *pdev; |
| struct net_device_stats stats; |
| |
| struct irlap_cb *irlap; |
| |
| struct qos_info qos; |
| |
| unsigned mode; |
| int baud, new_baud; |
| |
| dma_addr_t busaddr; |
| void *virtaddr; |
| struct vlsi_ring *tx_ring, *rx_ring; |
| |
| struct timeval last_rx; |
| |
| spinlock_t lock; |
| struct semaphore sem; |
| |
| u8 resume_ok; |
| struct proc_dir_entry *proc_entry; |
| |
| } vlsi_irda_dev_t; |
| |
| /********************************************************/ |
| |
| /* the remapped error flags we use for returning from frame |
| * post-processing in vlsi_process_tx/rx() after it was completed |
| * by the hardware. These functions either return the >=0 number |
| * of transfered bytes in case of success or the negative (-) |
| * of the or'ed error flags. |
| */ |
| |
| #define VLSI_TX_DROP 0x0001 |
| #define VLSI_TX_FIFO 0x0002 |
| |
| #define VLSI_RX_DROP 0x0100 |
| #define VLSI_RX_OVER 0x0200 |
| #define VLSI_RX_LENGTH 0x0400 |
| #define VLSI_RX_FRAME 0x0800 |
| #define VLSI_RX_CRC 0x1000 |
| |
| /********************************************************/ |
| |
| #endif /* IRDA_VLSI_FIR_H */ |
| |