/* * DAHDI Telephony Interface * * Written by Mark Spencer * Based on previous works, designs, and architectures conceived and * written by Jim Dixon . * * Copyright (C) 2001 Jim Dixon / Zapata Telephony. * Copyright (C) 2001 - 2012 Digium, Inc. * * All rights reserved. * */ /* * See http://www.asterisk.org for more information about * the Asterisk project. Please do not directly contact * any of the maintainers of this project for assistance; * the project provides a web site, mailing lists and IRC * channels for your use. * * This program is free software, distributed under the terms of * the GNU General Public License Version 2 as published by the * Free Software Foundation. See the LICENSE file included with * this program for more details. */ /*! * \file * \brief DAHDI kernel interface definitions */ #ifndef _DAHDI_KERNEL_H #define _DAHDI_KERNEL_H #include #include #include #include #include #include #include #include #include #ifdef CONFIG_DAHDI_NET #include #endif #ifdef CONFIG_DAHDI_PPP #include #include #include #endif #include #include #include #if LINUX_VERSION_CODE >= KERNEL_VERSION(2, 6, 29) #define HAVE_NET_DEVICE_OPS #endif #define DAHDI_HAVE_PROC_OPS /* __dev* were removed in 3.8. They still have effect in 2.6.18. */ #ifndef __devinit # define __devinit # define __devinitdata # define __devexit # define __devexit_p(x) x #endif /*! Default chunk size for conferences and such -- static right now, might make variable sometime. 8 samples = 1 ms = most frequent service interval possible for a USB device */ #define DAHDI_CHUNKSIZE 8 #define DAHDI_MIN_CHUNKSIZE DAHDI_CHUNKSIZE #define DAHDI_DEFAULT_CHUNKSIZE DAHDI_CHUNKSIZE #define DAHDI_MAX_CHUNKSIZE DAHDI_CHUNKSIZE #define DAHDI_CB_SIZE (1 << 3) /* DAHDI operates at 8Khz by default */ #define DAHDI_MS_TO_SAMPLES(ms) ((ms) * 8) #define DAHDI_MSECS_PER_CHUNK (DAHDI_CHUNKSIZE/DAHDI_MS_TO_SAMPLES(1)) #define RING_DEBOUNCE_TIME 2000 /*!< 2000 ms ring debounce time */ typedef struct { int32_t gain; int32_t a1; int32_t a2; int32_t b1; int32_t b2; int32_t z1; int32_t z2; } biquad2_state_t; typedef struct { biquad2_state_t notch; int notch_level; int channel_level; int tone_present; int tone_cycle_duration; int good_cycles; int hit; } echo_can_disable_detector_state_t; struct sf_detect_state { long x1; long x2; long y1; long y2; long e1; long e2; int samps; int lastdetect; }; struct dahdi_tone_state { int v1_1; int v2_1; int v3_1; int v1_2; int v2_2; int v3_2; int modulate; }; /*! \brief Conference queue structure */ struct confq { u_char buffer[DAHDI_CHUNKSIZE * DAHDI_CB_SIZE]; u_char *buf[DAHDI_CB_SIZE]; int inbuf; int outbuf; }; struct dahdi_chan; struct dahdi_echocan_state; /*! Features a DAHDI echo canceler (software or hardware) can provide to the DAHDI core. */ struct dahdi_echocan_features { /*! Able to detect CED tone (2100 Hz with phase reversals) in the transmit direction. * If the echocan can detect this tone, it may report it it as an event (see * the events.CED_tx_detected field of dahdi_echocan_state), and if it will automatically * disable itself or its non-linear processor, then the NLP_automatic feature flag should also * be set so that the DAHDI core doesn't bother trying to do so. */ u32 CED_tx_detect:1; /*! Able to detect CED tone (2100 Hz with phase reversals) in the receive direction. * If the echocan can detect this tone, it may report it it as an event (see * the events.CED_rx_detected field of dahdi_echocan_state), and if it will automatically * disable itself or its non-linear processor, then the NLP_automatic flag feature should also * be set so that the DAHDI core doesn't bother trying to do so. */ u32 CED_rx_detect:1; /*! Able to detect CNG tone (1100 Hz) in the transmit direction. */ u32 CNG_tx_detect:1; /*! Able to detect CNG tone (1100 Hz) in the receive direction. */ u32 CNG_rx_detect:1; /*! If the echocan's NLP can be enabled and disabled without requiring destruction * and recreation of the state structure, this feature flag should be set and the * echocan_NLP_toggle field of the dahdi_echocan_ops structure should be filled with a * pointer to the function to perform that operation. */ u32 NLP_toggle:1; /*! If the echocan will automatically disable itself (or even just its NLP) based on * detection of a CED tone in either direction, this feature flag should be set (along * with the tone detection feature flags). */ u32 NLP_automatic:1; }; /*! Operations (methods) that can be performed on a DAHDI echo canceler instance (state * structure) after it has been created, by either a software or hardware echo canceller. * The echo canceler must populate the owner field of the dahdi_echocan_state structure * with a pointer to the relevant operations structure for that instance. */ struct dahdi_echocan_ops { /*! \brief Free an echocan state structure. * \param[in,out] ec Pointer to the state structure to free. * * \return Nothing. */ void (*echocan_free)(struct dahdi_chan *chan, struct dahdi_echocan_state *ec); /*! \brief Process an array of audio samples through the echocan. * \param[in,out] ec Pointer to the state structure. * \param[in,out] isig The receive direction data (will be modified). * \param[in] iref The transmit direction data. * \param[in] size The number of elements in the isig and iref arrays. * * Note: This function can also return events in the events field of the * dahdi_echocan_state structure. If it can do so, then the echocan does * not need to provide the echocan_events function. * * \return Nothing. */ void (*echocan_process)(struct dahdi_echocan_state *ec, short *isig, const short *iref, u32 size); /*! \brief Retrieve events from the echocan. * \param[in,out] ec Pointer to the state structure. * * * If any events have occurred, the events field of the dahdi_echocan_state * structure should be updated to include them. * * \return Nothing. */ void (*echocan_events)(struct dahdi_echocan_state *ec); /*! \brief Feed a sample (and its position) for echocan training. * \param[in,out] ec Pointer to the state structure. * \param[in] pos The tap position to be 'trained'. * \param[in] val The receive direction sample for the specified tap position. * * \retval Zero if training should continue. * \retval Non-zero if training is complete. */ int (*echocan_traintap)(struct dahdi_echocan_state *ec, int pos, short val); /*! \brief Enable or disable non-linear processing (NLP) in the echocan. * \param[in,out] ec Pointer to the state structure. * \param[in] enable Zero to disable, non-zero to enable. * * \return Nothing. */ void (*echocan_NLP_toggle)(struct dahdi_echocan_state *ec, unsigned int enable); #ifdef CONFIG_DAHDI_ECHOCAN_PROCESS_TX /*! \brief Process an array of TX audio samples. * * \return Nothing. */ void (*echocan_process_tx)(struct dahdi_echocan_state *ec, short *tx, u32 size); #endif }; /*! A factory for creating instances of software echo cancelers to be used on DAHDI channels. */ struct dahdi_echocan_factory { /*! Get the name of the factory. */ const char *(*get_name)(const struct dahdi_chan *chan); /*! Pointer to the module that owns this factory; the module's reference count will be * incremented/decremented by the DAHDI core as needed. */ struct module *owner; /*! \brief Function to create an instance of the echocan. * \param[in] ecp Structure defining parameters to be used for the instance creation. * \param[in] p Pointer to the beginning of an (optional) array of user-defined parameters. * \param[out] ec Pointer to the state structure that is created, if any. * * \retval Zero on success. * \retval Non-zero on failure (return value will be returned to userspace so it should be a * standard error number). */ int (*echocan_create)(struct dahdi_chan *chan, struct dahdi_echocanparams *ecp, struct dahdi_echocanparam *p, struct dahdi_echocan_state **ec); }; /*! \brief Register an echo canceler factory with the DAHDI core. * \param[in] ec Pointer to the dahdi_echocan_factory structure to be registered. * * \retval Zero on success. * \retval Non-zero on failure (return value will be a standard error number). */ int dahdi_register_echocan_factory(const struct dahdi_echocan_factory *ec); /*! \brief Unregister a previously-registered echo canceler factory from the DAHDI core. * \param[in] ec Pointer to the dahdi_echocan_factory structure to be unregistered. * * \return Nothing. */ void dahdi_unregister_echocan_factory(const struct dahdi_echocan_factory *ec); enum dahdi_echocan_mode { __ECHO_MODE_MUTE = 1 << 8, ECHO_MODE_IDLE = 0, ECHO_MODE_PRETRAINING = 1 | __ECHO_MODE_MUTE, ECHO_MODE_STARTTRAINING = 2 | __ECHO_MODE_MUTE, ECHO_MODE_AWAITINGECHO = 3 | __ECHO_MODE_MUTE, ECHO_MODE_TRAINING = 4 | __ECHO_MODE_MUTE, ECHO_MODE_ACTIVE = 5, ECHO_MODE_FAX = 6, }; /*! An instance of a DAHDI echo canceler (software or hardware). */ struct dahdi_echocan_state { /*! Pointer to a dahdi_echocan_ops structure of operations that can be * performed on this instance. */ const struct dahdi_echocan_ops *ops; /*! State data used by the DAHDI core's CED detector for the transmit * direction, if needed. */ echo_can_disable_detector_state_t txecdis; /*! State data used by the DAHDI core's CED detector for the receive * direction, if needed. */ echo_can_disable_detector_state_t rxecdis; /*! Features offered by the echo canceler that provided this instance. */ struct dahdi_echocan_features features; struct { /*! The mode the echocan is currently in. */ enum dahdi_echocan_mode mode; /*! The last tap position that was fed to the echocan's training function. */ u32 last_train_tap; /*! How many samples to wait before beginning the training operation. */ u32 pretrain_timer; } status; /*! This structure contains event flags, allowing the echocan to report * events that occurred as it processed the transmit and receive streams * of samples. Each call to the echocan_process operation for this * instance may report events, so the structure should be cleared before * calling that operation. */ union dahdi_echocan_events { u32 all; struct { /*! CED tone was detected in the transmit direction. If the * echocan automatically disables its NLP when this occurs, * it must also signal the NLP_auto_disabled event during the *same* * call to echocan_process that reports the CED detection. */ u32 CED_tx_detected:1; /*! CED tone was detected in the receive direction. If the * echocan automatically disables its NLP when this occurs, * it must also signal the NLP_auto_disabled event during the *same* * call to echocan_process that reports the CED detection. */ u32 CED_rx_detected:1; /*! CNG tone was detected in the transmit direction. */ u32 CNG_tx_detected:1; /*! CNG tone was detected in the receive direction. */ u32 CNG_rx_detected:1; /*! The echocan disabled its NLP automatically. */ u32 NLP_auto_disabled:1; /*! The echocan enabled its NLP automatically. */ u32 NLP_auto_enabled:1; } bit; } events; }; struct dahdi_chan { #ifdef CONFIG_DAHDI_NET /*! \note Must be first */ struct dahdi_hdlc *hdlcnetdev; #endif #ifdef CONFIG_DAHDI_PPP struct ppp_channel *ppp; struct tasklet_struct ppp_calls; int do_ppp_wakeup; int do_ppp_error; struct sk_buff_head ppp_rq; #endif #ifdef BUFFER_DEBUG int statcount; int lastnumbufs; #endif spinlock_t lock; struct mutex mutex; char name[40]; /* Specified by DAHDI */ /*! \brief DAHDI channel number */ int channo; int chanpos; unsigned long flags; long rxp1; long rxp2; long rxp3; int txtone; int tx_v2; int tx_v3; int v1_1; int v2_1; int v3_1; int toneflags; struct sf_detect_state rd; struct dahdi_chan *master; /*!< Our Master channel (could be us) */ /*! \brief Next slave (if appropriate) */ struct dahdi_chan *nextslave; u_char *writechunk; /*!< Actual place to write to */ u_char swritechunk[DAHDI_MAX_CHUNKSIZE]; /*!< Buffer to be written */ u_char *readchunk; /*!< Actual place to read from */ u_char sreadchunk[DAHDI_MAX_CHUNKSIZE]; /*!< Preallocated static area */ short *readchunkpreec; /* Channel from which to read when DACSed. */ struct dahdi_chan *dacs_chan; /*! Pointer to tx and rx gain tables */ const u_char *rxgain; const u_char *txgain; /* Specified by driver, readable by DAHDI */ void *pvt; /*!< Private channel data */ struct file *file; /*!< File structure */ #ifdef CONFIG_DAHDI_MIRROR struct dahdi_chan *rxmirror; /*!< channel we mirror reads to */ struct dahdi_chan *txmirror; /*!< channel we mirror writes to */ struct dahdi_chan *srcmirror; /*!< channel we mirror from */ #endif /* CONFIG_DAHDI_MIRROR */ struct dahdi_span *span; /*!< Span we're a member of */ int sig; /*!< Signalling */ int sigcap; /*!< Capability for signalling */ __u32 chan_alarms; /*!< alarms status */ wait_queue_head_t waitq; /* Used only by DAHDI -- NO DRIVER SERVICEABLE PARTS BELOW */ /* Buffer declarations */ u_char *readbuf[DAHDI_MAX_NUM_BUFS]; /*!< read buffer */ int inreadbuf; int outreadbuf; u_char *writebuf[DAHDI_MAX_NUM_BUFS]; /*!< write buffers */ int inwritebuf; int outwritebuf; int blocksize; /*!< Block size */ int eventinidx; /*!< out index in event buf (circular) */ int eventoutidx; /*!< in index in event buf (circular) */ unsigned int eventbuf[DAHDI_MAX_EVENTSIZE]; /*!< event circ. buffer */ int readn[DAHDI_MAX_NUM_BUFS]; /*!< # of bytes ready in read buf */ int readidx[DAHDI_MAX_NUM_BUFS]; /*!< current read pointer */ int writen[DAHDI_MAX_NUM_BUFS]; /*!< # of bytes ready in write buf */ int writeidx[DAHDI_MAX_NUM_BUFS]; /*!< current write pointer */ int numbufs; /*!< How many buffers in channel */ int txbufpolicy; /*!< Buffer policy */ int txdisable; /*!< Disable transmitter */ /* Tone zone stuff */ struct dahdi_zone *curzone; /*!< Zone for selecting tones */ struct dahdi_tone *curtone; /*!< Current tone we're playing (if any) */ int tonep; /*!< Current position in tone */ struct dahdi_tone_state ts; /*!< Tone state */ /* Pulse dial stuff */ int pdialcount; /*!< pulse dial count */ /*! Ring cadence */ int ringcadence[DAHDI_MAX_CADENCE]; int firstcadencepos; /*!< Where to restart ring cadence */ /* Digit string dialing stuff */ int digitmode; /*!< What kind of tones are we sending? */ char txdialbuf[DAHDI_MAX_DTMF_BUF]; int dialing; int afterdialingtimer; int cadencepos; /*!< Where in the cadence we are */ /* I/O Mask */ unsigned int iomask; /*! I/O Mux signal mask */ /* HDLC state machines */ struct fasthdlc_state txhdlc; struct fasthdlc_state rxhdlc; int infcs; /* Conferencing stuff */ int confna; /*! conference number (alias) */ int _confn; /*! Actual conference number */ int confmode; /*! conference mode */ int confmute; /*! conference mute mode */ struct dahdi_chan *conf_chan; /* Incoming and outgoing conference chunk queues for communicating between DAHDI master time and other boards */ struct confq confin; struct confq confout; short getlin[DAHDI_MAX_CHUNKSIZE]; /*!< Last transmitted samples */ unsigned char getraw[DAHDI_MAX_CHUNKSIZE]; /*!< Last received raw data */ short putlin[DAHDI_MAX_CHUNKSIZE]; /*!< Last received samples */ unsigned char putraw[DAHDI_MAX_CHUNKSIZE]; /*!< Last received raw data */ short conflast[DAHDI_MAX_CHUNKSIZE]; /*!< Last conference sample -- base part of channel */ short conflast1[DAHDI_MAX_CHUNKSIZE]; /*!< Last conference sample -- pseudo part of channel */ short conflast2[DAHDI_MAX_CHUNKSIZE]; /*!< Previous last conference sample -- pseudo part of channel */ /*! The echo canceler module that should be used to create an instance when this channel needs one */ const struct dahdi_echocan_factory *ec_factory; /*! The echo canceler module that owns the instance currently on this channel, if one is present */ const struct dahdi_echocan_factory *ec_current; /*! The state data of the echo canceler instance in use */ struct dahdi_echocan_state *ec_state; /* RBS timings */ int prewinktime; /*!< pre-wink time (ms) */ int preflashtime; /*!< pre-flash time (ms) */ int winktime; /*!< wink time (ms) */ int flashtime; /*!< flash time (ms) */ int starttime; /*!< start time (ms) */ int rxwinktime; /*!< rx wink time (ms) */ int rxflashtime; /*!< rx flash time (ms) */ int debouncetime; /*!< FXS GS sig debounce time (ms) */ int pulsebreaktime; /*!< pulse line open time (ms) */ int pulsemaketime; /*!< pulse line closed time (ms) */ int pulseaftertime; /*!< pulse time between digits (ms) */ /*! RING debounce timer */ int ringdebtimer; /*! RING trailing detector to make sure a RING is really over */ int ringtrailer; /* PULSE digit receiver stuff */ int pulsecount; int pulsetimer; /* RBS timers */ int itimerset; /*!< what the itimer was set to last */ int itimer; int otimer; /* RBS state */ int gotgs; int txstate; int rxsig; int txsig; int rxsigstate; /* non-RBS rx state */ int rxhooksig; int txhooksig; int kewlonhook; /*! Idle signalling if CAS signalling */ int idlebits; int deflaw; /*! 1 = mulaw, 2=alaw, 0=undefined */ short *xlaw; #ifdef OPTIMIZE_CHANMUTE int chanmute; /*!< no need for PCM data */ #endif #ifdef CONFIG_CALC_XLAW unsigned char (*lineartoxlaw)(short a); #else unsigned char *lin2x; #endif struct device chan_device; /*!< Kernel object for this chan */ #define dev_to_chan(dev) container_of(dev, struct dahdi_chan, chan_device) }; #ifdef CONFIG_DAHDI_NET struct dahdi_hdlc { struct net_device *netdev; struct dahdi_chan *chan; }; #endif /*! Define the maximum block size */ #define DAHDI_MAX_BLOCKSIZE 8192 #define DAHDI_DEFAULT_WINKTIME 150 /*!< 150 ms default wink time */ #define DAHDI_DEFAULT_FLASHTIME 750 /*!< 750 ms default flash time */ #define DAHDI_DEFAULT_PREWINKTIME 50 /*!< 50 ms before wink */ #define DAHDI_DEFAULT_PREFLASHTIME 50 /*!< 50 ms before flash */ #define DAHDI_DEFAULT_STARTTIME 1500 /*!< 1500 ms of start */ #define DAHDI_DEFAULT_RINGTIME 2000 /*!< 2000 ms of ring on (start, FXO) */ #if 0 #define DAHDI_DEFAULT_RXWINKTIME 250 /*!< 250ms longest rx wink */ #endif #define DAHDI_DEFAULT_RXWINKTIME 300 /*!< 300ms longest rx wink (to work with the Atlas) */ #define DAHDI_DEFAULT_RXFLASHTIME 1250 /*!< 1250ms longest rx flash */ #define DAHDI_DEFAULT_DEBOUNCETIME 600 /*!< 600ms of FXS GS signalling debounce */ #define DAHDI_DEFAULT_PULSEMAKETIME 50 /*!< 50 ms of line closed when dial pulsing */ #define DAHDI_DEFAULT_PULSEBREAKTIME 50 /*!< 50 ms of line open when dial pulsing */ #define DAHDI_DEFAULT_PULSEAFTERTIME 750 /*!< 750ms between dial pulse digits */ #define DAHDI_MINPULSETIME (15 * 8) /*!< 15 ms minimum */ #ifdef SHORT_FLASH_TIME #define DAHDI_MAXPULSETIME (80 * 8) /*!< we need 80 ms, not 200ms, as we have a short flash */ #else #define DAHDI_MAXPULSETIME (200 * 8) /*!< 200 ms maximum */ #endif #define DAHDI_PULSETIMEOUT ((DAHDI_MAXPULSETIME / 8) + 50) #define DAHDI_RINGTRAILER (50 * 8) /*!< Don't consider a ring "over" until it's been gone at least this much time */ #define DAHDI_LOOPCODE_TIME 10000 /*!< send loop codes for 10 secs */ #define DAHDI_ALARMSETTLE_TIME 5000 /*!< allow alarms to settle for 5 secs */ #define DAHDI_AFTERSTART_TIME 500 /*!< 500ms after start */ #define DAHDI_RINGOFFTIME 4000 /*!< Turn off ringer for 4000 ms */ #define DAHDI_KEWLTIME 500 /*!< 500ms for kewl pulse */ #define DAHDI_AFTERKEWLTIME 300 /*!< 300ms after kewl pulse */ #define DAHDI_MAX_PRETRAINING 1000 /*!< 1000ms max pretraining time */ #ifdef FXSFLASH #define DAHDI_FXSFLASHMINTIME 450 /*!< min 450ms */ #define DAHDI_FXSFLASHMAXTIME 550 /*!< max 550ms */ #endif struct dahdi_chardev { const char *name; __u8 minor; }; int dahdi_register_chardev(struct dahdi_chardev *dev); int dahdi_unregister_chardev(struct dahdi_chardev *dev); /*! \brief defines for transmit signalling */ enum dahdi_txsig { DAHDI_TXSIG_ONHOOK, /*!< On hook */ DAHDI_TXSIG_OFFHOOK, /*!< Off hook */ DAHDI_TXSIG_START, /*!< Start / Ring */ DAHDI_TXSIG_KEWL, /*!< Drop battery if possible */ /*! Leave this as the last entry */ DAHDI_TXSIG_TOTAL, }; enum dahdi_rxsig { DAHDI_RXSIG_ONHOOK, DAHDI_RXSIG_OFFHOOK, DAHDI_RXSIG_START, DAHDI_RXSIG_RING, DAHDI_RXSIG_INITIAL }; enum { /* Span flags */ DAHDI_FLAGBIT_REGISTERED= 0, DAHDI_FLAGBIT_RUNNING = 1, DAHDI_FLAGBIT_RBS = 12, /*!< Span uses RBS signalling */ /* Channel flags */ DAHDI_FLAGBIT_DTMFDECODE= 2, /*!< Channel supports native DTMF decode */ DAHDI_FLAGBIT_MFDECODE = 3, /*!< Channel supports native MFr2 decode */ DAHDI_FLAGBIT_ECHOCANCEL= 4, /*!< Channel supports native echo cancellation */ DAHDI_FLAGBIT_HDLC = 5, /*!< Perform HDLC */ #ifdef CONFIG_DAHDI_NET DAHDI_FLAGBIT_NETDEV = 6, /*!< Send to network */ #endif DAHDI_FLAGBIT_CLEAR = 8, /*!< Clear channel */ DAHDI_FLAGBIT_AUDIO = 9, /*!< Audio mode channel */ DAHDI_FLAGBIT_OPEN = 10, /*!< Channel is open */ DAHDI_FLAGBIT_FCS = 11, /*!< Calculate FCS */ /* Reserve 12 for uniqueness with span flags */ DAHDI_FLAGBIT_LINEAR = 13, /*!< Talk to user space in linear */ DAHDI_FLAGBIT_PPP = 14, /*!< PPP is available */ DAHDI_FLAGBIT_T1PPP = 15, DAHDI_FLAGBIT_SIGFREEZE = 16, /*!< Freeze signalling */ DAHDI_FLAGBIT_NOSTDTXRX = 17, /*!< Do NOT do standard transmit and receive on every interrupt */ DAHDI_FLAGBIT_LOOPED = 18, /*!< Loopback the receive data from the channel to the transmit */ DAHDI_FLAGBIT_MTP2 = 19, /*!< Repeats last message in buffer and also discards repeating messages sent to us */ DAHDI_FLAGBIT_HDLC56 = 20, /*!< Sets the given channel (if in HDLC mode) to use 56K HDLC instead of 64K */ DAHDI_FLAGBIT_BUFEVENTS = 21, /*!< Report buffer events */ DAHDI_FLAGBIT_TXUNDERRUN = 22, /*!< Transmit underrun condition */ DAHDI_FLAGBIT_RXOVERRUN = 23, /*!< Receive overrun condition */ DAHDI_FLAGBIT_DEVFILE = 25, /*!< Channel has a sysfs dev file */ }; #ifdef CONFIG_DAHDI_NET /** * have_netdev() - Return true if a channel has an associated network device. * @chan: Then channel to check. * */ static inline int dahdi_have_netdev(const struct dahdi_chan *chan) { return test_bit(DAHDI_FLAGBIT_NETDEV, &chan->flags); } #else static inline int dahdi_have_netdev(const struct dahdi_chan *chan) { return 0; } #endif struct dahdi_count { u32 fe; /*!< Framing error counter */ u32 cv; /*!< Coding violations counter */ u32 bpv; /*!< Bipolar Violation counter */ u32 crc4; /*!< CRC4 error counter */ u32 ebit; /*!< current E-bit error count */ u32 fas; /*!< current FAS error count */ u32 be; /*!< current bit error count */ u32 prbs; /*!< current PRBS detected pattern */ u32 errsec; /*!< errored seconds */ u32 timingslips; /*!< Clock slips */ }; /* map flagbits to flag masks */ #define DAHDI_FLAG(x) (1 << (DAHDI_FLAGBIT_ ## x)) /*! This is a redefinition of the flags from above to allow use of the * legacy drivers that do not use the kernel atomic bit testing and * changing routines. * * See the above descriptions for DAHDI_FLAGBIT_.... for documentation * about function. */ /* Span flags */ #define DAHDI_FLAG_REGISTERED DAHDI_FLAG(REGISTERED) #define DAHDI_FLAG_RUNNING DAHDI_FLAG(RUNNING) #define DAHDI_FLAG_RBS DAHDI_FLAG(RBS) /* Channel flags */ #define DAHDI_FLAG_DTMFDECODE DAHDI_FLAG(DTMFDECODE) #define DAHDI_FLAG_MFDECODE DAHDI_FLAG(MFDECODE) #define DAHDI_FLAG_ECHOCANCEL DAHDI_FLAG(ECHOCANCEL) #define DAHDI_FLAG_HDLC DAHDI_FLAG(HDLC) /* #define DAHDI_FLAG_NETDEV DAHDI_FLAG(NETDEV) */ #define DAHDI_FLAG_CLEAR DAHDI_FLAG(CLEAR) #define DAHDI_FLAG_AUDIO DAHDI_FLAG(AUDIO) #define DAHDI_FLAG_OPEN DAHDI_FLAG(OPEN) #define DAHDI_FLAG_FCS DAHDI_FLAG(FCS) /* Reserve 12 for uniqueness with span flags */ #define DAHDI_FLAG_LINEAR DAHDI_FLAG(LINEAR) #define DAHDI_FLAG_PPP DAHDI_FLAG(PPP) #define DAHDI_FLAG_T1PPP DAHDI_FLAG(T1PPP) #define DAHDI_FLAG_SIGFREEZE DAHDI_FLAG(SIGFREEZE) #define DAHDI_FLAG_NOSTDTXRX DAHDI_FLAG(NOSTDTXRX) #define DAHDI_FLAG_LOOPED DAHDI_FLAG(LOOPED) #define DAHDI_FLAG_MTP2 DAHDI_FLAG(MTP2) #define DAHDI_FLAG_HDLC56 DAHDI_FLAG(HDLC56) #define DAHDI_FLAG_BUFEVENTS DAHDI_FLAG(BUFEVENTS) #define DAHDI_FLAG_TXUNDERRUN DAHDI_FLAG(TXUNDERRUN) #define DAHDI_FLAG_RXOVERRUN DAHDI_FLAG(RXOVERRUN) enum spantypes { SPANTYPE_INVALID = 0, SPANTYPE_ANALOG_FXS, SPANTYPE_ANALOG_FXO, SPANTYPE_ANALOG_MIXED, SPANTYPE_DIGITAL_E1, SPANTYPE_DIGITAL_T1, SPANTYPE_DIGITAL_J1, SPANTYPE_DIGITAL_BRI_NT, SPANTYPE_DIGITAL_BRI_TE, SPANTYPE_DIGITAL_BRI_SOFT, SPANTYPE_DIGITAL_DYNAMIC, }; const char *dahdi_spantype2str(enum spantypes st); enum spantypes dahdi_str2spantype(const char *name); const char *dahdi_lineconfig_bit_name(int lineconfig_bit); ssize_t lineconfig_str(int lineconfig, char buf[], size_t size); struct file; struct dahdi_span_ops { struct module *owner; /*!< Which module is exporting this span. */ /* ==== Span Callback Operations ==== */ /*! Req: Set the requested chunk size. This is the unit in which you must report results for conferencing, etc */ int (*setchunksize)(struct dahdi_span *span, int chunksize); /*! Opt: Configure the span (if appropriate) */ int (*spanconfig)(struct file *file, struct dahdi_span *span, struct dahdi_lineconfig *lc); /*! Opt: Start the span */ int (*startup)(struct file *file, struct dahdi_span *span); /*! Opt: Shutdown the span */ int (*shutdown)(struct dahdi_span *span); /*! Opt: Enable maintenance modes */ int (*maint)(struct dahdi_span *span, int mode); #ifdef DAHDI_SYNC_TICK /*! Opt: send sync to spans. Called in hard_irq context with chan_lock * held.*/ void (*sync_tick)(struct dahdi_span *span, int is_master); #endif /* ==== Channel Callback Operations ==== */ /*! Opt: Set signalling type (if appropriate) */ int (*chanconfig)(struct file *file, struct dahdi_chan *chan, int sigtype); /*! Opt: Prepare a channel for I/O */ int (*open)(struct dahdi_chan *chan); /*! Opt: Close channel for I/O */ int (*close)(struct dahdi_chan *chan); /*! Opt: IOCTL */ int (*ioctl)(struct dahdi_chan *chan, unsigned int cmd, unsigned long data); /* Okay, now we get to the signalling. You have several options: */ /* Option 1: If you're a T1 like interface, you can just provide a rbsbits function and we'll assert robbed bits for you. Be sure to set the DAHDI_FLAG_RBS in this case. */ /*! Opt: If the span uses A/B bits, set them here */ int (*rbsbits)(struct dahdi_chan *chan, int bits); /*! Option 2: If you don't know about sig bits, but do have their equivalents (i.e. you can disconnect battery, detect off hook, generate ring, etc directly) then you can just specify a sethook function, and we'll call you with appropriate hook states to set. Still set the DAHDI_FLAG_RBS in this case as well */ int (*hooksig)(struct dahdi_chan *chan, enum dahdi_txsig hookstate); /*! Option 3: If you can't use sig bits, you can write a function which handles the individual hook states */ int (*sethook)(struct dahdi_chan *chan, int hookstate); /*! Opt: Used to tell an onboard HDLC controller that there is data ready to transmit */ void (*hdlc_hard_xmit)(struct dahdi_chan *chan); /*! If the watchdog detects no received data, it will call the watchdog routine */ int (*watchdog)(struct dahdi_span *span, int cause); #ifdef DAHDI_AUDIO_NOTIFY /*! Opt: audio is used, don't optimize out */ int (*audio_notify)(struct dahdi_chan *chan, int yes); #endif /*! Opt: Enable preechocan stream from inline HW echocanceler. */ int (*enable_hw_preechocan)(struct dahdi_chan *chan); /*! Opt: Disable preechocan stream from inline HW echocanceler. */ void (*disable_hw_preechocan)(struct dahdi_chan *chan); /*! Opt: Dacs the contents of chan2 into chan1 if possible */ int (*dacs)(struct dahdi_chan *chan1, struct dahdi_chan *chan2); /*! Opt: Provide echo cancellation on a channel */ int (*echocan_create)(struct dahdi_chan *chan, struct dahdi_echocanparams *ecp, struct dahdi_echocanparam *p, struct dahdi_echocan_state **ec); /*! Opt: Provide the name of the echo canceller on a channel */ const char *(*echocan_name)(const struct dahdi_chan *chan); /*! When using "assigned spans", this function is called back when this * span has been assigned with the system. */ void (*assigned)(struct dahdi_span *span); /*! Called when the spantype / linemode is changed before the span is * assigned a number. */ int (*set_spantype)(struct dahdi_span *span, enum spantypes st); }; /** * dahdi_device - Represents a device that can contain one or more spans. * * @spans: List of child spans. * @manufacturer: Device manufacturer. * @location: The location of this device. This should not change if * the device is replaced (e.g: in the same PCI slot) * @hardware_id: The hardware_id of this device (NULL for devices without * a hardware_id). This should not change if the device is * relocated to a different location (e.g: different PCI slot) * @devicetype: What type of device this is. * @irqmisses: Count of "interrupt misses" for this device. * */ struct dahdi_device { struct list_head spans; const char *manufacturer; const char *location; const char *hardware_id; const char *devicetype; struct device dev; unsigned int irqmisses; ktime_t registration_time; }; struct dahdi_span { spinlock_t lock; char name[40]; /*!< Span name */ char desc[80]; /*!< Span description */ enum spantypes spantype; /*!< span type */ int deflaw; /*!< Default law (DAHDI_MULAW or DAHDI_ALAW) */ int alarms; /*!< Pending alarms on span */ unsigned long flags; u8 cannot_provide_timing:1; int lbo; /*!< Span Line-Buildout */ int lineconfig; /*!< Span line configuration */ int linecompat; /*!< Span line compatibility (0 for analog spans)*/ int channels; /*!< Number of channels in span */ int txlevel; /*!< Tx level */ int rxlevel; /*!< Rx level */ int syncsrc; /*!< current sync src (gets copied here) */ struct dahdi_count count; /*!< Performance and Error counters */ int maintstat; /*!< Maintenance state */ int mainttimer; /*!< Maintenance timer */ struct dahdi_chan **chans; /*!< Member channel structures */ const struct dahdi_span_ops *ops; /*!< span callbacks. */ /* Used by DAHDI only -- no user servicable parts inside */ int spanno; /*!< Span number for DAHDI */ int offset; /*!< Offset within a given card */ int lastalarms; /*!< Previous alarms */ #ifdef CONFIG_DAHDI_WATCHDOG int watchcounter; int watchstate; #endif #ifdef CONFIG_PROC_FS struct proc_dir_entry *proc_entry; #endif struct list_head spans_node; struct dahdi_device *parent; struct list_head device_node; struct device *span_device; }; struct dahdi_transcoder_channel { void *pvt; struct dahdi_transcoder *parent; wait_queue_head_t ready; __u32 built_fmts; #define DAHDI_TC_FLAG_BUSY 1 #define DAHDI_TC_FLAG_CHAN_BUILT 2 #define DAHDI_TC_FLAG_NONBLOCK 3 #define DAHDI_TC_FLAG_DATA_WAITING 4 unsigned long flags; u32 dstfmt; u32 srcfmt; }; int dahdi_is_sync_master(const struct dahdi_span *span); struct dahdi_span *get_master_span(void); void set_master_span(int spanno); static inline int dahdi_tc_is_built(struct dahdi_transcoder_channel *dtc) { return test_bit(DAHDI_TC_FLAG_CHAN_BUILT, &dtc->flags); } static inline void dahdi_tc_set_built(struct dahdi_transcoder_channel *dtc) { set_bit(DAHDI_TC_FLAG_CHAN_BUILT, &dtc->flags); } static inline void dahdi_tc_clear_built(struct dahdi_transcoder_channel *dtc) { clear_bit(DAHDI_TC_FLAG_CHAN_BUILT, &dtc->flags); } static inline int dahdi_tc_is_nonblock(struct dahdi_transcoder_channel *dtc) { return test_bit(DAHDI_TC_FLAG_NONBLOCK, &dtc->flags); } static inline void dahdi_tc_set_nonblock(struct dahdi_transcoder_channel *dtc) { set_bit(DAHDI_TC_FLAG_NONBLOCK, &dtc->flags); } static inline void dahdi_tc_clear_nonblock(struct dahdi_transcoder_channel *dtc) { clear_bit(DAHDI_TC_FLAG_NONBLOCK, &dtc->flags); } static inline int dahdi_tc_is_data_waiting(struct dahdi_transcoder_channel *dtc) { return test_bit(DAHDI_TC_FLAG_DATA_WAITING, &dtc->flags); } static inline int dahdi_tc_is_busy(struct dahdi_transcoder_channel *dtc) { return test_bit(DAHDI_TC_FLAG_BUSY, &dtc->flags); } static inline void dahdi_tc_set_busy(struct dahdi_transcoder_channel *dtc) { set_bit(DAHDI_TC_FLAG_BUSY, &dtc->flags); } static inline void dahdi_tc_clear_busy(struct dahdi_transcoder_channel *dtc) { clear_bit(DAHDI_TC_FLAG_BUSY, &dtc->flags); } static inline void dahdi_tc_set_data_waiting(struct dahdi_transcoder_channel *dtc) { set_bit(DAHDI_TC_FLAG_DATA_WAITING, &dtc->flags); } static inline void dahdi_tc_clear_data_waiting(struct dahdi_transcoder_channel *dtc) { clear_bit(DAHDI_TC_FLAG_DATA_WAITING, &dtc->flags); } struct dahdi_transcoder { struct list_head active_list_node; struct list_head registration_list_node; char name[80]; int numchannels; unsigned int srcfmts; unsigned int dstfmts; struct file_operations fops; int (*allocate)(struct dahdi_transcoder_channel *channel); int (*release)(struct dahdi_transcoder_channel *channel); /* Transcoder channels */ struct dahdi_transcoder_channel channels[0]; }; #define DAHDI_WATCHDOG_NOINTS (1 << 0) #define DAHDI_WATCHDOG_INIT 1000 #define DAHDI_WATCHSTATE_UNKNOWN 0 #define DAHDI_WATCHSTATE_OK 1 #define DAHDI_WATCHSTATE_RECOVERING 2 #define DAHDI_WATCHSTATE_FAILED 3 struct dahdi_dynamic { char addr[40]; char dname[20]; int err; struct kref kref; long rxjif; unsigned short txcnt; unsigned short rxcnt; struct dahdi_device *ddev; struct dahdi_span span; struct dahdi_chan *chans[256]; struct dahdi_dynamic_driver *driver; void *pvt; int timing; int master; unsigned char *msgbuf; struct device *dev; struct list_head list; }; struct dahdi_dynamic_driver { /*! Driver name (e.g. Eth) */ const char *name; /*! Driver description */ const char *desc; /*! Create a new transmission pipe */ int (*create)(struct dahdi_dynamic *d, const char *address); /*! Destroy a created transmission pipe */ void (*destroy)(struct dahdi_dynamic *d); /*! Transmit a given message */ void (*transmit)(struct dahdi_dynamic *d, u8 *msg, size_t msglen); /*! Flush any pending messages */ int (*flush)(void); struct list_head list; struct module *owner; /*! Numberic id of next device created by this driver. */ unsigned int id; }; /*! \brief Receive a dynamic span message */ void dahdi_dynamic_receive(struct dahdi_span *span, unsigned char *msg, int msglen); /*! \brief Register a dynamic driver */ int dahdi_dynamic_register_driver(struct dahdi_dynamic_driver *driver); /*! \brief Unregister a dynamic driver */ void dahdi_dynamic_unregister_driver(struct dahdi_dynamic_driver *driver); int _dahdi_receive(struct dahdi_span *span); /*! Receive on a span. The DAHDI interface will handle all the calculations for all member channels of the span, pulling the data from the readchunk buffer */ static inline int dahdi_receive(struct dahdi_span *span) { unsigned long flags; int ret; local_irq_save(flags); ret = _dahdi_receive(span); local_irq_restore(flags); return ret; } int _dahdi_transmit(struct dahdi_span *span); /*! Prepare writechunk buffers on all channels for this span */ static inline int dahdi_transmit(struct dahdi_span *span) { unsigned long flags; int ret; local_irq_save(flags); ret = _dahdi_transmit(span); local_irq_restore(flags); return ret; } static inline int dahdi_is_digital_span(const struct dahdi_span *s) { return (s->linecompat > 0); } static inline int dahdi_is_t1_span(const struct dahdi_span *s) { return (s->linecompat & (DAHDI_CONFIG_D4 | DAHDI_CONFIG_ESF | DAHDI_CONFIG_B8ZS)) > 0; } static inline int dahdi_is_e1_span(const struct dahdi_span *s) { return dahdi_is_digital_span(s) && !dahdi_is_t1_span(s); } /*! Abort the buffer currently being receive with event "event" */ void dahdi_hdlc_abort(struct dahdi_chan *ss, int event); /*! Indicate to DAHDI that the end of frame was received and rotate buffers */ void dahdi_hdlc_finish(struct dahdi_chan *ss); /*! Put a chunk of data into the current receive buffer */ void dahdi_hdlc_putbuf(struct dahdi_chan *ss, unsigned char *rxb, int bytes); /*! Get a chunk of data from the current transmit buffer. Returns -1 if no data * is left to send, 0 if there is data remaining in the current message to be sent * and 1 if the currently transmitted message is now done */ int dahdi_hdlc_getbuf(struct dahdi_chan *ss, unsigned char *bufptr, unsigned int *size); /*! Register a device. Returns 0 on success, -1 on failure. */ struct dahdi_device *dahdi_create_device(void); int dahdi_register_device(struct dahdi_device *ddev, struct device *parent); void dahdi_unregister_device(struct dahdi_device *ddev); void dahdi_free_device(struct dahdi_device *ddev); void dahdi_init_span(struct dahdi_span *span); /*! Allocate / free memory for a transcoder */ struct dahdi_transcoder *dahdi_transcoder_alloc(int numchans); void dahdi_transcoder_free(struct dahdi_transcoder *ztc); /*! \brief Register a transcoder */ int dahdi_transcoder_register(struct dahdi_transcoder *tc); /*! \brief Unregister a transcoder */ int dahdi_transcoder_unregister(struct dahdi_transcoder *tc); /*! \brief Alert a transcoder */ int dahdi_transcoder_alert(struct dahdi_transcoder_channel *ztc); /*! \brief Gives a name to an LBO */ const char *dahdi_lboname(int lbo); /*! \brief Tell DAHDI about changes in received rbs bits */ void dahdi_rbsbits(struct dahdi_chan *chan, int bits); /*! \brief Tell DAHDI abou changes in received signalling */ void dahdi_hooksig(struct dahdi_chan *chan, enum dahdi_rxsig rxsig); /*! \brief Queue an event on a channel */ void dahdi_qevent_nolock(struct dahdi_chan *chan, int event); /*! \brief Queue an event on a channel, locking it first */ void dahdi_qevent_lock(struct dahdi_chan *chan, int event); /*! \brief Notify a change possible change in alarm status on a channel */ void dahdi_alarm_channel(struct dahdi_chan *chan, int alarms); /*! \brief Notify a change possible change in alarm status on a span */ void dahdi_alarm_notify(struct dahdi_span *span); /*! \brief Initialize a tone state */ void dahdi_init_tone_state(struct dahdi_tone_state *ts, struct dahdi_tone *zt); /*! \brief Get a given MF tone struct, suitable for dahdi_tone_nextsample. */ struct dahdi_tone *dahdi_mf_tone(const struct dahdi_chan *chan, char digit, int digitmode); /*! \brief Convert signalling bits to human readable string */ const char *sigstr(int sig); /*! \brief Convert alarm bits to human readable string */ int fill_alarm_string(char *buf, int count, int alarms); /* Echo cancel a receive and transmit chunk for a given channel. This should be called by the low-level driver as close to the interface as possible. ECHO CANCELLATION IS NO LONGER AUTOMATICALLY DONE AT THE DAHDI LEVEL. dahdi_ec_chunk will not echo cancel if it should not be doing so. rxchunk is modified in-place */ void __dahdi_ec_chunk(struct dahdi_chan *ss, u8 *rxchunk, const u8 *preecchunk, const u8 *txchunk); static inline void _dahdi_ec_chunk(struct dahdi_chan *chan, u8 *rxchunk, const u8 *txchunk) { __dahdi_ec_chunk(chan, rxchunk, rxchunk, txchunk); } static inline void dahdi_ec_chunk(struct dahdi_chan *ss, unsigned char *rxchunk, const unsigned char *txchunk) { unsigned long flags; local_irq_save(flags); _dahdi_ec_chunk(ss, rxchunk, txchunk); local_irq_restore(flags); } void _dahdi_ec_span(struct dahdi_span *span); static inline void dahdi_ec_span(struct dahdi_span *span) { unsigned long flags; local_irq_save(flags); _dahdi_ec_span(span); local_irq_restore(flags); } extern struct file_operations *dahdi_transcode_fops; int dahdi_get_auto_assign_spans(void); /* Don't use these directly -- they're not guaranteed to be there. */ extern short __dahdi_mulaw[256]; extern short __dahdi_alaw[256]; #ifdef CONFIG_CALC_XLAW u_char __dahdi_lineartoulaw(short a); u_char __dahdi_lineartoalaw(short a); #else extern u_char __dahdi_lin2mu[16384]; extern u_char __dahdi_lin2a[16384]; #endif struct dahdi_dynamic_ops { struct module *owner; int (*ioctl)(unsigned int cmd, unsigned long data); }; /*! \brief Used by dynamic DAHDI -- don't use directly */ void dahdi_set_dynamic_ops(const struct dahdi_dynamic_ops *ops); /*! \brief Used by DAHDI HPEC module -- don't use directly */ void dahdi_set_hpec_ioctl(int (*func)(unsigned int cmd, unsigned long data)); /*! \brief Used privately by DAHDI. Avoid touching directly */ struct dahdi_tone { int fac1; int init_v2_1; int init_v3_1; int fac2; int init_v2_2; int init_v3_2; int tonesamples; /*!< How long to play this tone before going to the next (in samples) */ struct dahdi_tone *next; /* Next tone in this sequence */ int modulate; }; static inline short dahdi_tone_nextsample(struct dahdi_tone_state *ts, struct dahdi_tone *zt) { /* follow the curves, return the sum */ int p; ts->v1_1 = ts->v2_1; ts->v2_1 = ts->v3_1; ts->v3_1 = (zt->fac1 * ts->v2_1 >> 15) - ts->v1_1; ts->v1_2 = ts->v2_2; ts->v2_2 = ts->v3_2; ts->v3_2 = (zt->fac2 * ts->v2_2 >> 15) - ts->v1_2; /* Return top 16 bits */ if (!ts->modulate) return ts->v3_1 + ts->v3_2; /* we are modulating */ p = ts->v3_2 - 32768; if (p < 0) p = -p; p = ((p * 9) / 10) + 1; return (ts->v3_1 * p) >> 15; } static inline short dahdi_txtone_nextsample(struct dahdi_chan *ss) { /* follow the curves, return the sum */ ss->v1_1 = ss->v2_1; ss->v2_1 = ss->v3_1; ss->v3_1 = (ss->txtone * ss->v2_1 >> 15) - ss->v1_1; return ss->v3_1; } /* These are the right functions to use. */ #define DAHDI_MULAW(a) (__dahdi_mulaw[(a)]) #define DAHDI_ALAW(a) (__dahdi_alaw[(a)]) #define DAHDI_XLAW(a,c) (c->xlaw[(a)]) #ifdef CONFIG_CALC_XLAW #define DAHDI_LIN2MU(a) (__dahdi_lineartoulaw((a))) #define DAHDI_LIN2A(a) (__dahdi_lineartoalaw((a))) #define DAHDI_LIN2X(a,c) ((c)->lineartoxlaw((a))) #else /* Use tables */ #define DAHDI_LIN2MU(a) (__dahdi_lin2mu[((unsigned short)(a)) >> 2]) #define DAHDI_LIN2A(a) (__dahdi_lin2a[((unsigned short)(a)) >> 2]) /* Manipulate as appropriate for x-law */ #define DAHDI_LIN2X(a,c) ((c)->lin2x[((unsigned short)(a)) >> 2]) #endif /* CONFIG_CALC_XLAW */ /* Data formats for capabilities and frames alike (from Asterisk) */ /*! G.723.1 compression */ #define DAHDI_FORMAT_G723_1 (1 << 0) /*! GSM compression */ #define DAHDI_FORMAT_GSM (1 << 1) /*! Raw mu-law data (G.711) */ #define DAHDI_FORMAT_ULAW (1 << 2) /*! Raw A-law data (G.711) */ #define DAHDI_FORMAT_ALAW (1 << 3) /*! ADPCM (G.726, 32kbps) */ #define DAHDI_FORMAT_G726 (1 << 4) /*! ADPCM (IMA) */ #define DAHDI_FORMAT_ADPCM (1 << 5) /*! Raw 16-bit Signed Linear (8000 Hz) PCM */ #define DAHDI_FORMAT_SLINEAR (1 << 6) /*! LPC10, 180 samples/frame */ #define DAHDI_FORMAT_LPC10 (1 << 7) /*! G.729A audio */ #define DAHDI_FORMAT_G729A (1 << 8) /*! SpeeX Free Compression */ #define DAHDI_FORMAT_SPEEX (1 << 9) /*! iLBC Free Compression */ #define DAHDI_FORMAT_ILBC (1 << 10) /*! Maximum audio format */ #define DAHDI_FORMAT_MAX_AUDIO (1 << 15) /*! Maximum audio mask */ #define DAHDI_FORMAT_AUDIO_MASK ((1 << 16) - 1) #if LINUX_VERSION_CODE < KERNEL_VERSION(5, 6, 0) #undef DAHDI_HAVE_PROC_OPS #if LINUX_VERSION_CODE < KERNEL_VERSION(4, 15, 0) #ifndef TIMER_DATA_TYPE #define TIMER_DATA_TYPE unsigned long #endif #if LINUX_VERSION_CODE < KERNEL_VERSION(4, 13, 0) #ifdef RHEL_RELEASE_VERSION #if RHEL_RELEASE_CODE > RHEL_RELEASE_VERSION(7, 5) #define DAHDI_HAVE_TIMER_SETUP #undef TIMER_DATA_TYPE #define TIMER_DATA_TYPE struct timer_list * #endif #endif #ifndef DAHDI_HAVE_TIMER_SETUP /** * timer_setup - Added in 4.13.0. We can make a direct translation to the * setup_timer interface since DAHDI does not pass any flags to any of the * timer_setup functions. * */ static inline void timer_setup(struct timer_list *timer, void (*timer_callback)(TIMER_DATA_TYPE data), unsigned long flags) { WARN_ON(flags != 0); setup_timer(timer, timer_callback, (TIMER_DATA_TYPE)timer); } #define from_timer(var, callback_timer, timer_fieldname) \ container_of((struct timer_list *)(callback_timer), \ typeof(*var), timer_fieldname) #endif #if LINUX_VERSION_CODE < KERNEL_VERSION(4, 11, 0) #define refcount_read atomic_read #if LINUX_VERSION_CODE < KERNEL_VERSION(4, 10, 0) #define dahdi_ktime_equal ktime_equal #if LINUX_VERSION_CODE < KERNEL_VERSION(4, 0, 0) #ifdef RHEL_RELEASE_VERSION #if RHEL_RELEASE_CODE >= RHEL_RELEASE_VERSION(6, 8) #define DAHDI_HAVE_KTIME_MS_DELTA #endif #endif #ifndef DAHDI_HAVE_KTIME_MS_DELTA static inline s64 dahdi_ktime_to_ms(const ktime_t kt) { struct timeval tv = ktime_to_timeval(kt); return (s64) tv.tv_sec * MSEC_PER_SEC + tv.tv_usec / USEC_PER_MSEC; } static inline s64 ktime_ms_delta(const ktime_t later, const ktime_t earlier) { return dahdi_ktime_to_ms(ktime_sub(later, earlier)); } #else #undef DAHDI_HAVE_KTIME_MS_DELTA #endif #if LINUX_VERSION_CODE < KERNEL_VERSION(3, 16, 0) /* DAHDI only was using the xxx_clear_bit variants. */ #ifndef smp_mb__before_atomic #define smp_mb__before_atomic smp_mb__before_clear_bit #endif #ifndef smp_mb__after_atomic #define smp_mb__after_atomic smp_mb__after_clear_bit #endif #if LINUX_VERSION_CODE < KERNEL_VERSION(3, 10, 0) #ifdef RHEL_RELEASE_VERSION #if RHEL_RELEASE_CODE < RHEL_RELEASE_VERSION(6, 5) #ifdef CONFIG_PROC_FS #include static inline void *PDE_DATA(const struct inode *inode) { return PDE(inode)->data; } #endif #endif #else #ifdef CONFIG_PROC_FS #include static inline void *PDE_DATA(const struct inode *inode) { return PDE(inode)->data; } #endif #endif #if LINUX_VERSION_CODE < KERNEL_VERSION(2, 6, 31) #define KERN_CONT "" #endif /* 2.6.31 */ #endif /* 3.10.0 */ #endif /* 3.16.0 */ #endif /* 4.0.0 */ #endif /* 4.10.0 */ #endif /* 4.11.0 */ #endif /* 4.13.0 */ #endif /* 4.15.0 */ #endif /* 5.6 */ #ifndef TIMER_DATA_TYPE #define TIMER_DATA_TYPE struct timer_list * #endif #ifndef dahdi_ktime_equal static inline int dahdi_ktime_equal(const ktime_t cmp1, const ktime_t cmp2) { return cmp1 == cmp2; } #endif #ifndef DEFINE_SPINLOCK #define DEFINE_SPINLOCK(x) spinlock_t x = SPIN_LOCK_UNLOCKED #endif #ifndef DEFINE_SEMAPHORE #define DEFINE_SEMAPHORE(name) \ struct semaphore name = __SEMAPHORE_INITIALIZER(name, 1) #endif #ifndef DEFINE_MUTEX struct mutex { struct semaphore sem; }; #define DEFINE_MUTEX(name) \ struct mutex name = { \ .sem = __SEMAPHORE_INITIALIZER((name).sem, 1), \ } #define mutex_lock(_x) down(&(_x)->sem) #define mutex_unlock(_x) up(&(_x)->sem) #define mutex_init(_x) sema_init(&(_x)->sem, 1) #endif #ifndef DEFINE_PCI_DEVICE_TABLE #define DEFINE_PCI_DEVICE_TABLE(_x) \ const struct pci_device_id _x[] __devinitdata #endif #ifndef DMA_BIT_MASK #define DMA_BIT_MASK(n) (((n) == 64) ? ~0ULL : ((1ULL<<(n))-1)) #endif /* WARN_ONCE first showed up in the kernel in 2.6.27 but it may have been * backported. */ #ifndef WARN_ONCE #define WARN_ONCE(condition, format...) WARN_ON_ONCE(condition) #endif #define DAHDI_CTL 0 #define DAHDI_TRANSCODE 250 #define DAHDI_TIMER 253 #define DAHDI_CHANNEL 254 #define DAHDI_PSEUDO 255 /* prink-wrapper macros */ #define module_printk(level, fmt, args...) \ printk(level "%s: " fmt, THIS_MODULE->name, ## args) #define DAHDI_PRINTK(level, category, fmt, ...) \ printk(KERN_ ## level "%s%s-%s: " fmt, #level, category, \ THIS_MODULE->name, ## __VA_ARGS__) #define span_printk(level, category, span, fmt, ...) \ printk(KERN_ ## level "%s%s-%s: span-%d: " fmt, #level, \ category, THIS_MODULE->name, (span)->spanno, ## __VA_ARGS__) #define chan_printk(level, category, chan, fmt, ...) \ printk(KERN_ ## level "%s%s-%s: chan-%d: " fmt, #level, \ category, THIS_MODULE->name, (chan)->channo, ## __VA_ARGS__) #define dahdi_err(fmt, ...) DAHDI_PRINTK(ERR, "", fmt, ## __VA_ARGS__) #define span_info(span, fmt, ...) span_printk(INFO, "", span, fmt, \ ## __VA_ARGS__) #define span_notice(span, fmt, ...) span_printk(NOTICE, "", span, fmt, \ ## __VA_ARGS__) #define span_err(span, fmt, ...) span_printk(ERR, "", span, fmt, \ ## __VA_ARGS__) #define chan_notice(chan, fmt, ...) chan_printk(NOTICE, "", chan, fmt, \ ## __VA_ARGS__) #define chan_err(chan, fmt, ...) chan_printk(ERR, "", chan, fmt, \ ## __VA_ARGS__) #ifndef pr_fmt #define pr_fmt(fmt) KBUILD_MODNAME ": " fmt #endif #ifndef pr_err #define pr_err(fmt, ...) \ printk(KERN_ERR pr_fmt(fmt), ##__VA_ARGS__) #endif #ifndef pr_warning #define pr_warning(fmt, ...) \ printk(KERN_WARNING pr_fmt(fmt), ##__VA_ARGS__) #endif #ifndef pr_warn #define pr_warn pr_warning #endif #ifndef pr_notice #define pr_notice(fmt, ...) \ printk(KERN_NOTICE pr_fmt(fmt), ##__VA_ARGS__) #endif #ifndef pr_info #define pr_info(fmt, ...) \ printk(KERN_INFO pr_fmt(fmt), ##__VA_ARGS__) #endif /* If KBUILD_MODNAME is not defined in a compilation unit, then the dev_dbg * macro will not work properly. */ #ifndef KBUILD_MODNAME #undef dev_dbg #ifdef DEBUG #define dev_dbg dev_info #else #define dev_dbg(...) do { } while (0) #endif #endif /* The dbg_* ones use a magical variable 'debug' and the user should be * aware of that. */ #ifdef DAHDI_PRINK_MACROS_USE_debug #ifndef BIT /* added in 2.6.24 */ #define BIT(i) (1UL << (i)) #endif /* Standard debug bit values. Any module may define others. They must * be of the form DAHDI_DBG_* */ #define DAHDI_DBG_GENERAL BIT(0) #define DAHDI_DBG_ASSIGN BIT(1) #define DAHDI_DBG_DEVICES BIT(7) /* instantiation/destruction etc. */ #define dahdi_dbg(bits, fmt, ...) \ ((void)((debug & (DAHDI_DBG_ ## bits)) && DAHDI_PRINTK(DEBUG, \ "-" #bits, "%s: " fmt, __func__, ## __VA_ARGS__))) #define span_dbg(bits, span, fmt, ...) \ ((void)((debug & (DAHDI_DBG_ ## bits)) && \ span_printk(DEBUG, "-" #bits, span, "%s: " \ fmt, __func__, ## __VA_ARGS__))) #define chan_dbg(bits, chan, fmt, ...) \ ((void)((debug & (DAHDI_DBG_ ## bits)) && \ chan_printk(DEBUG, "-" #bits, chan, \ "%s: " fmt, __func__, ## __VA_ARGS__))) #define dahdi_dev_dbg(bits, dev, fmt, ...) \ do { if (debug & (DAHDI_DBG_ ## bits)) { \ dev_printk(KERN_DEBUG, dev, \ "DBG-%s(%s): " fmt, #bits, __func__, ## __VA_ARGS__); \ } } while (0) #endif /* DAHDI_PRINK_MACROS_USE_debug */ #endif /* _DAHDI_KERNEL_H */