// SPDX-License-Identifier: GPL-2.0+ /* * comedi/drivers/rtd520.c * Comedi driver for Real Time Devices (RTD) PCI4520/DM7520 * * COMEDI - Linux Control and Measurement Device Interface * Copyright (C) 2001 David A. Schleef */ /* * Driver: rtd520 * Description: Real Time Devices PCI4520/DM7520 * Devices: [Real Time Devices] DM7520HR-1 (DM7520), DM7520HR-8, * PCI4520 (PCI4520), PCI4520-8 * Author: Dan Christian * Status: Works. Only tested on DM7520-8. Not SMP safe. * * Configuration options: not applicable, uses PCI auto config */ /* * Created by Dan Christian, NASA Ames Research Center. * * The PCI4520 is a PCI card. The DM7520 is a PC/104-plus card. * Both have: * 8/16 12 bit ADC with FIFO and channel gain table * 8 bits high speed digital out (for external MUX) (or 8 in or 8 out) * 8 bits high speed digital in with FIFO and interrupt on change (or 8 IO) * 2 12 bit DACs with FIFOs * 2 bits output * 2 bits input * bus mastering DMA * timers: ADC sample, pacer, burst, about, delay, DA1, DA2 * sample counter * 3 user timer/counters (8254) * external interrupt * * The DM7520 has slightly fewer features (fewer gain steps). * * These boards can support external multiplexors and multi-board * synchronization, but this driver doesn't support that. * * Board docs: http://www.rtdusa.com/PC104/DM/analog%20IO/dm7520.htm * Data sheet: http://www.rtdusa.com/pdf/dm7520.pdf * Example source: http://www.rtdusa.com/examples/dm/dm7520.zip * Call them and ask for the register level manual. * PCI chip: http://www.plxtech.com/products/io/pci9080 * * Notes: * This board is memory mapped. There is some IO stuff, but it isn't needed. * * I use a pretty loose naming style within the driver (rtd_blah). * All externally visible names should be rtd520_blah. * I use camelCase for structures (and inside them). * I may also use upper CamelCase for function names (old habit). * * This board is somewhat related to the RTD PCI4400 board. * * I borrowed heavily from the ni_mio_common, ni_atmio16d, mite, and * das1800, since they have the best documented code. Driver cb_pcidas64.c * uses the same DMA controller. * * As far as I can tell, the About interrupt doesn't work if Sample is * also enabled. It turns out that About really isn't needed, since * we always count down samples read. */ /* * driver status: * * Analog-In supports instruction and command mode. * * With DMA, you can sample at 1.15Mhz with 70% idle on a 400Mhz K6-2 * (single channel, 64K read buffer). I get random system lockups when * using DMA with ALI-15xx based systems. I haven't been able to test * any other chipsets. The lockups happen soon after the start of an * acquistion, not in the middle of a long run. * * Without DMA, you can do 620Khz sampling with 20% idle on a 400Mhz K6-2 * (with a 256K read buffer). * * Digital-IO and Analog-Out only support instruction mode. */ #include #include #include #include "../comedi_pci.h" #include "comedi_8254.h" #include "plx9080.h" /* * Local Address Space 0 Offsets */ #define LAS0_USER_IO 0x0008 /* User I/O */ #define LAS0_ADC 0x0010 /* FIFO Status/Software A/D Start */ #define FS_DAC1_NOT_EMPTY BIT(0) /* DAC1 FIFO not empty */ #define FS_DAC1_HEMPTY BIT(1) /* DAC1 FIFO half empty */ #define FS_DAC1_NOT_FULL BIT(2) /* DAC1 FIFO not full */ #define FS_DAC2_NOT_EMPTY BIT(4) /* DAC2 FIFO not empty */ #define FS_DAC2_HEMPTY BIT(5) /* DAC2 FIFO half empty */ #define FS_DAC2_NOT_FULL BIT(6) /* DAC2 FIFO not full */ #define FS_ADC_NOT_EMPTY BIT(8) /* ADC FIFO not empty */ #define FS_ADC_HEMPTY BIT(9) /* ADC FIFO half empty */ #define FS_ADC_NOT_FULL BIT(10) /* ADC FIFO not full */ #define FS_DIN_NOT_EMPTY BIT(12) /* DIN FIFO not empty */ #define FS_DIN_HEMPTY BIT(13) /* DIN FIFO half empty */ #define FS_DIN_NOT_FULL BIT(14) /* DIN FIFO not full */ #define LAS0_UPDATE_DAC(x) (0x0014 + ((x) * 0x4)) /* D/Ax Update (w) */ #define LAS0_DAC 0x0024 /* Software Simultaneous Update (w) */ #define LAS0_PACER 0x0028 /* Software Pacer Start/Stop */ #define LAS0_TIMER 0x002c /* Timer Status/HDIN Software Trig. */ #define LAS0_IT 0x0030 /* Interrupt Status/Enable */ #define IRQM_ADC_FIFO_WRITE BIT(0) /* ADC FIFO Write */ #define IRQM_CGT_RESET BIT(1) /* Reset CGT */ #define IRQM_CGT_PAUSE BIT(3) /* Pause CGT */ #define IRQM_ADC_ABOUT_CNT BIT(4) /* About Counter out */ #define IRQM_ADC_DELAY_CNT BIT(5) /* Delay Counter out */ #define IRQM_ADC_SAMPLE_CNT BIT(6) /* ADC Sample Counter */ #define IRQM_DAC1_UCNT BIT(7) /* DAC1 Update Counter */ #define IRQM_DAC2_UCNT BIT(8) /* DAC2 Update Counter */ #define IRQM_UTC1 BIT(9) /* User TC1 out */ #define IRQM_UTC1_INV BIT(10) /* User TC1 out, inverted */ #define IRQM_UTC2 BIT(11) /* User TC2 out */ #define IRQM_DIGITAL_IT BIT(12) /* Digital Interrupt */ #define IRQM_EXTERNAL_IT BIT(13) /* External Interrupt */ #define IRQM_ETRIG_RISING BIT(14) /* Ext Trigger rising-edge */ #define IRQM_ETRIG_FALLING BIT(15) /* Ext Trigger falling-edge */ #define LAS0_CLEAR 0x0034 /* Clear/Set Interrupt Clear Mask */ #define LAS0_OVERRUN 0x0038 /* Pending interrupts/Clear Overrun */ #define LAS0_PCLK 0x0040 /* Pacer Clock (24bit) */ #define LAS0_BCLK 0x0044 /* Burst Clock (10bit) */ #define LAS0_ADC_SCNT 0x0048 /* A/D Sample counter (10bit) */ #define LAS0_DAC1_UCNT 0x004c /* D/A1 Update counter (10 bit) */ #define LAS0_DAC2_UCNT 0x0050 /* D/A2 Update counter (10 bit) */ #define LAS0_DCNT 0x0054 /* Delay counter (16 bit) */ #define LAS0_ACNT 0x0058 /* About counter (16 bit) */ #define LAS0_DAC_CLK 0x005c /* DAC clock (16bit) */ #define LAS0_8254_TIMER_BASE 0x0060 /* 8254 timer/counter base */ #define LAS0_DIO0 0x0070 /* Digital I/O Port 0 */ #define LAS0_DIO1 0x0074 /* Digital I/O Port 1 */ #define LAS0_DIO0_CTRL 0x0078 /* Digital I/O Control */ #define LAS0_DIO_STATUS 0x007c /* Digital I/O Status */ #define LAS0_BOARD_RESET 0x0100 /* Board reset */ #define LAS0_DMA0_SRC 0x0104 /* DMA 0 Sources select */ #define LAS0_DMA1_SRC 0x0108 /* DMA 1 Sources select */ #define LAS0_ADC_CONVERSION 0x010c /* A/D Conversion Signal select */ #define LAS0_BURST_START 0x0110 /* Burst Clock Start Trigger select */ #define LAS0_PACER_START 0x0114 /* Pacer Clock Start Trigger select */ #define LAS0_PACER_STOP 0x0118 /* Pacer Clock Stop Trigger select */ #define LAS0_ACNT_STOP_ENABLE 0x011c /* About Counter Stop Enable */ #define LAS0_PACER_REPEAT 0x0120 /* Pacer Start Trigger Mode select */ #define LAS0_DIN_START 0x0124 /* HiSpd DI Sampling Signal select */ #define LAS0_DIN_FIFO_CLEAR 0x0128 /* Digital Input FIFO Clear */ #define LAS0_ADC_FIFO_CLEAR 0x012c /* A/D FIFO Clear */ #define LAS0_CGT_WRITE 0x0130 /* Channel Gain Table Write */ #define LAS0_CGL_WRITE 0x0134 /* Channel Gain Latch Write */ #define LAS0_CG_DATA 0x0138 /* Digital Table Write */ #define LAS0_CGT_ENABLE 0x013c /* Channel Gain Table Enable */ #define LAS0_CG_ENABLE 0x0140 /* Digital Table Enable */ #define LAS0_CGT_PAUSE 0x0144 /* Table Pause Enable */ #define LAS0_CGT_RESET 0x0148 /* Reset Channel Gain Table */ #define LAS0_CGT_CLEAR 0x014c /* Clear Channel Gain Table */ #define LAS0_DAC_CTRL(x) (0x0150 + ((x) * 0x14)) /* D/Ax type/range */ #define LAS0_DAC_SRC(x) (0x0154 + ((x) * 0x14)) /* D/Ax update source */ #define LAS0_DAC_CYCLE(x) (0x0158 + ((x) * 0x14)) /* D/Ax cycle mode */ #define LAS0_DAC_RESET(x) (0x015c + ((x) * 0x14)) /* D/Ax FIFO reset */ #define LAS0_DAC_FIFO_CLEAR(x) (0x0160 + ((x) * 0x14)) /* D/Ax FIFO clear */ #define LAS0_ADC_SCNT_SRC 0x0178 /* A/D Sample Counter Source select */ #define LAS0_PACER_SELECT 0x0180 /* Pacer Clock select */ #define LAS0_SBUS0_SRC 0x0184 /* SyncBus 0 Source select */ #define LAS0_SBUS0_ENABLE 0x0188 /* SyncBus 0 enable */ #define LAS0_SBUS1_SRC 0x018c /* SyncBus 1 Source select */ #define LAS0_SBUS1_ENABLE 0x0190 /* SyncBus 1 enable */ #define LAS0_SBUS2_SRC 0x0198 /* SyncBus 2 Source select */ #define LAS0_SBUS2_ENABLE 0x019c /* SyncBus 2 enable */ #define LAS0_ETRG_POLARITY 0x01a4 /* Ext. Trigger polarity select */ #define LAS0_EINT_POLARITY 0x01a8 /* Ext. Interrupt polarity select */ #define LAS0_8254_CLK_SEL(x) (0x01ac + ((x) * 0x8)) /* 8254 clock select */ #define LAS0_8254_GATE_SEL(x) (0x01b0 + ((x) * 0x8)) /* 8254 gate select */ #define LAS0_UOUT0_SELECT 0x01c4 /* User Output 0 source select */ #define LAS0_UOUT1_SELECT 0x01c8 /* User Output 1 source select */ #define LAS0_DMA0_RESET 0x01cc /* DMA0 Request state machine reset */ #define LAS0_DMA1_RESET 0x01d0 /* DMA1 Request state machine reset */ /* * Local Address Space 1 Offsets */ #define LAS1_ADC_FIFO 0x0000 /* A/D FIFO (16bit) */ #define LAS1_HDIO_FIFO 0x0004 /* HiSpd DI FIFO (16bit) */ #define LAS1_DAC_FIFO(x) (0x0008 + ((x) * 0x4)) /* D/Ax FIFO (16bit) */ /* * Driver specific stuff (tunable) */ /* * We really only need 2 buffers. More than that means being much * smarter about knowing which ones are full. */ #define DMA_CHAIN_COUNT 2 /* max DMA segments/buffers in a ring (min 2) */ /* Target period for periodic transfers. This sets the user read latency. */ /* Note: There are certain rates where we give this up and transfer 1/2 FIFO */ /* If this is too low, efficiency is poor */ #define TRANS_TARGET_PERIOD 10000000 /* 10 ms (in nanoseconds) */ /* Set a practical limit on how long a list to support (affects memory use) */ /* The board support a channel list up to the FIFO length (1K or 8K) */ #define RTD_MAX_CHANLIST 128 /* max channel list that we allow */ /* * Board specific stuff */ #define RTD_CLOCK_RATE 8000000 /* 8Mhz onboard clock */ #define RTD_CLOCK_BASE 125 /* clock period in ns */ /* Note: these speed are slower than the spec, but fit the counter resolution*/ #define RTD_MAX_SPEED 1625 /* when sampling, in nanoseconds */ /* max speed if we don't have to wait for settling */ #define RTD_MAX_SPEED_1 875 /* if single channel, in nanoseconds */ #define RTD_MIN_SPEED 2097151875 /* (24bit counter) in nanoseconds */ /* min speed when only 1 channel (no burst counter) */ #define RTD_MIN_SPEED_1 5000000 /* 200Hz, in nanoseconds */ /* Setup continuous ring of 1/2 FIFO transfers. See RTD manual p91 */ #define DMA_MODE_BITS (\ PLX_LOCAL_BUS_16_WIDE_BITS \ | PLX_DMA_EN_READYIN_BIT \ | PLX_DMA_LOCAL_BURST_EN_BIT \ | PLX_EN_CHAIN_BIT \ | PLX_DMA_INTR_PCI_BIT \ | PLX_LOCAL_ADDR_CONST_BIT \ | PLX_DEMAND_MODE_BIT) #define DMA_TRANSFER_BITS (\ /* descriptors in PCI memory*/ PLX_DESC_IN_PCI_BIT \ /* interrupt at end of block */ | PLX_INTR_TERM_COUNT \ /* from board to PCI */ | PLX_XFER_LOCAL_TO_PCI) /* * Comedi specific stuff */ /* * The board has 3 input modes and the gains of 1,2,4,...32 (, 64, 128) */ static const struct comedi_lrange rtd_ai_7520_range = { 18, { /* +-5V input range gain steps */ BIP_RANGE(5.0), BIP_RANGE(5.0 / 2), BIP_RANGE(5.0 / 4), BIP_RANGE(5.0 / 8), BIP_RANGE(5.0 / 16), BIP_RANGE(5.0 / 32), /* +-10V input range gain steps */ BIP_RANGE(10.0), BIP_RANGE(10.0 / 2), BIP_RANGE(10.0 / 4), BIP_RANGE(10.0 / 8), BIP_RANGE(10.0 / 16), BIP_RANGE(10.0 / 32), /* +10V input range gain steps */ UNI_RANGE(10.0), UNI_RANGE(10.0 / 2), UNI_RANGE(10.0 / 4), UNI_RANGE(10.0 / 8), UNI_RANGE(10.0 / 16), UNI_RANGE(10.0 / 32), } }; /* PCI4520 has two more gains (6 more entries) */ static const struct comedi_lrange rtd_ai_4520_range = { 24, { /* +-5V input range gain steps */ BIP_RANGE(5.0), BIP_RANGE(5.0 / 2), BIP_RANGE(5.0 / 4), BIP_RANGE(5.0 / 8), BIP_RANGE(5.0 / 16), BIP_RANGE(5.0 / 32), BIP_RANGE(5.0 / 64), BIP_RANGE(5.0 / 128), /* +-10V input range gain steps */ BIP_RANGE(10.0), BIP_RANGE(10.0 / 2), BIP_RANGE(10.0 / 4), BIP_RANGE(10.0 / 8), BIP_RANGE(10.0 / 16), BIP_RANGE(10.0 / 32), BIP_RANGE(10.0 / 64), BIP_RANGE(10.0 / 128), /* +10V input range gain steps */ UNI_RANGE(10.0), UNI_RANGE(10.0 / 2), UNI_RANGE(10.0 / 4), UNI_RANGE(10.0 / 8), UNI_RANGE(10.0 / 16), UNI_RANGE(10.0 / 32), UNI_RANGE(10.0 / 64), UNI_RANGE(10.0 / 128), } }; /* Table order matches range values */ static const struct comedi_lrange rtd_ao_range = { 4, { UNI_RANGE(5), UNI_RANGE(10), BIP_RANGE(5), BIP_RANGE(10), } }; enum rtd_boardid { BOARD_DM7520, BOARD_PCI4520, }; struct rtd_boardinfo { const char *name; int range_bip10; /* start of +-10V range */ int range_uni10; /* start of +10V range */ const struct comedi_lrange *ai_range; }; static const struct rtd_boardinfo rtd520_boards[] = { [BOARD_DM7520] = { .name = "DM7520", .range_bip10 = 6, .range_uni10 = 12, .ai_range = &rtd_ai_7520_range, }, [BOARD_PCI4520] = { .name = "PCI4520", .range_bip10 = 8, .range_uni10 = 16, .ai_range = &rtd_ai_4520_range, }, }; struct rtd_private { /* memory mapped board structures */ void __iomem *las1; void __iomem *lcfg; long ai_count; /* total transfer size (samples) */ int xfer_count; /* # to transfer data. 0->1/2FIFO */ int flags; /* flag event modes */ unsigned int fifosz; /* 8254 Timer/Counter gate and clock sources */ unsigned char timer_gate_src[3]; unsigned char timer_clk_src[3]; }; /* bit defines for "flags" */ #define SEND_EOS 0x01 /* send End Of Scan events */ #define DMA0_ACTIVE 0x02 /* DMA0 is active */ #define DMA1_ACTIVE 0x04 /* DMA1 is active */ /* * Given a desired period and the clock period (both in ns), return the * proper counter value (divider-1). Sets the original period to be the * true value. * Note: you have to check if the value is larger than the counter range! */ static int rtd_ns_to_timer_base(unsigned int *nanosec, unsigned int flags, int base) { int divider; switch (flags & CMDF_ROUND_MASK) { case CMDF_ROUND_NEAREST: default: divider = DIV_ROUND_CLOSEST(*nanosec, base); break; case CMDF_ROUND_DOWN: divider = (*nanosec) / base; break; case CMDF_ROUND_UP: divider = DIV_ROUND_UP(*nanosec, base); break; } if (divider < 2) divider = 2; /* min is divide by 2 */ /* * Note: we don't check for max, because different timers * have different ranges */ *nanosec = base * divider; return divider - 1; /* countdown is divisor+1 */ } /* * Given a desired period (in ns), return the proper counter value * (divider-1) for the internal clock. Sets the original period to * be the true value. */ static int rtd_ns_to_timer(unsigned int *ns, unsigned int flags) { return rtd_ns_to_timer_base(ns, flags, RTD_CLOCK_BASE); } /* Convert a single comedi channel-gain entry to a RTD520 table entry */ static unsigned short rtd_convert_chan_gain(struct comedi_device *dev, unsigned int chanspec, int index) { const struct rtd_boardinfo *board = dev->board_ptr; unsigned int chan = CR_CHAN(chanspec); unsigned int range = CR_RANGE(chanspec); unsigned int aref = CR_AREF(chanspec); unsigned short r = 0; r |= chan & 0xf; /* Note: we also setup the channel list bipolar flag array */ if (range < board->range_bip10) { /* +-5 range */ r |= 0x000; r |= (range & 0x7) << 4; } else if (range < board->range_uni10) { /* +-10 range */ r |= 0x100; r |= ((range - board->range_bip10) & 0x7) << 4; } else { /* +10 range */ r |= 0x200; r |= ((range - board->range_uni10) & 0x7) << 4; } switch (aref) { case AREF_GROUND: /* on-board ground */ break; case AREF_COMMON: r |= 0x80; /* ref external analog common */ break; case AREF_DIFF: r |= 0x400; /* differential inputs */ break; case AREF_OTHER: /* ??? */ break; } return r; } /* Setup the channel-gain table from a comedi list */ static void rtd_load_channelgain_list(struct comedi_device *dev, unsigned int n_chan, unsigned int *list) { if (n_chan > 1) { /* setup channel gain table */ int ii; writel(0, dev->mmio + LAS0_CGT_CLEAR); writel(1, dev->mmio + LAS0_CGT_ENABLE); for (ii = 0; ii < n_chan; ii++) { writel(rtd_convert_chan_gain(dev, list[ii], ii), dev->mmio + LAS0_CGT_WRITE); } } else { /* just use the channel gain latch */ writel(0, dev->mmio + LAS0_CGT_ENABLE); writel(rtd_convert_chan_gain(dev, list[0], 0), dev->mmio + LAS0_CGL_WRITE); } } /* * Determine fifo size by doing adc conversions until the fifo half * empty status flag clears. */ static int rtd520_probe_fifo_depth(struct comedi_device *dev) { unsigned int chanspec = CR_PACK(0, 0, AREF_GROUND); unsigned int i; static const unsigned int limit = 0x2000; unsigned int fifo_size = 0; writel(0, dev->mmio + LAS0_ADC_FIFO_CLEAR); rtd_load_channelgain_list(dev, 1, &chanspec); /* ADC conversion trigger source: SOFTWARE */ writel(0, dev->mmio + LAS0_ADC_CONVERSION); /* convert samples */ for (i = 0; i < limit; ++i) { unsigned int fifo_status; /* trigger conversion */ writew(0, dev->mmio + LAS0_ADC); usleep_range(1, 1000); fifo_status = readl(dev->mmio + LAS0_ADC); if ((fifo_status & FS_ADC_HEMPTY) == 0) { fifo_size = 2 * i; break; } } if (i == limit) { dev_info(dev->class_dev, "failed to probe fifo size.\n"); return -EIO; } writel(0, dev->mmio + LAS0_ADC_FIFO_CLEAR); if (fifo_size != 0x400 && fifo_size != 0x2000) { dev_info(dev->class_dev, "unexpected fifo size of %i, expected 1024 or 8192.\n", fifo_size); return -EIO; } return fifo_size; } static int rtd_ai_eoc(struct comedi_device *dev, struct comedi_subdevice *s, struct comedi_insn *insn, unsigned long context) { unsigned int status; status = readl(dev->mmio + LAS0_ADC); if (status & FS_ADC_NOT_EMPTY) return 0; return -EBUSY; } static int rtd_ai_rinsn(struct comedi_device *dev, struct comedi_subdevice *s, struct comedi_insn *insn, unsigned int *data) { struct rtd_private *devpriv = dev->private; unsigned int range = CR_RANGE(insn->chanspec); int ret; int n; /* clear any old fifo data */ writel(0, dev->mmio + LAS0_ADC_FIFO_CLEAR); /* write channel to multiplexer and clear channel gain table */ rtd_load_channelgain_list(dev, 1, &insn->chanspec); /* ADC conversion trigger source: SOFTWARE */ writel(0, dev->mmio + LAS0_ADC_CONVERSION); /* convert n samples */ for (n = 0; n < insn->n; n++) { unsigned short d; /* trigger conversion */ writew(0, dev->mmio + LAS0_ADC); ret = comedi_timeout(dev, s, insn, rtd_ai_eoc, 0); if (ret) return ret; /* read data */ d = readw(devpriv->las1 + LAS1_ADC_FIFO); d >>= 3; /* low 3 bits are marker lines */ /* convert bipolar data to comedi unsigned data */ if (comedi_range_is_bipolar(s, range)) d = comedi_offset_munge(s, d); data[n] = d & s->maxdata; } /* return the number of samples read/written */ return n; } static int ai_read_n(struct comedi_device *dev, struct comedi_subdevice *s, int count) { struct rtd_private *devpriv = dev->private; struct comedi_async *async = s->async; struct comedi_cmd *cmd = &async->cmd; int ii; for (ii = 0; ii < count; ii++) { unsigned int range = CR_RANGE(cmd->chanlist[async->cur_chan]); unsigned short d; if (devpriv->ai_count == 0) { /* done */ d = readw(devpriv->las1 + LAS1_ADC_FIFO); continue; } d = readw(devpriv->las1 + LAS1_ADC_FIFO); d >>= 3; /* low 3 bits are marker lines */ /* convert bipolar data to comedi unsigned data */ if (comedi_range_is_bipolar(s, range)) d = comedi_offset_munge(s, d); d &= s->maxdata; if (!comedi_buf_write_samples(s, &d, 1)) return -1; if (devpriv->ai_count > 0) /* < 0, means read forever */ devpriv->ai_count--; } return 0; } static irqreturn_t rtd_interrupt(int irq, void *d) { struct comedi_device *dev = d; struct comedi_subdevice *s = dev->read_subdev; struct rtd_private *devpriv = dev->private; u32 overrun; u16 status; u16 fifo_status; if (!dev->attached) return IRQ_NONE; fifo_status = readl(dev->mmio + LAS0_ADC); /* check for FIFO full, this automatically halts the ADC! */ if (!(fifo_status & FS_ADC_NOT_FULL)) /* 0 -> full */ goto xfer_abort; status = readw(dev->mmio + LAS0_IT); /* if interrupt was not caused by our board, or handled above */ if (status == 0) return IRQ_HANDLED; if (status & IRQM_ADC_ABOUT_CNT) { /* sample count -> read FIFO */ /* * since the priority interrupt controller may have queued * a sample counter interrupt, even though we have already * finished, we must handle the possibility that there is * no data here */ if (!(fifo_status & FS_ADC_HEMPTY)) { /* FIFO half full */ if (ai_read_n(dev, s, devpriv->fifosz / 2) < 0) goto xfer_abort; if (devpriv->ai_count == 0) goto xfer_done; } else if (devpriv->xfer_count > 0) { if (fifo_status & FS_ADC_NOT_EMPTY) { /* FIFO not empty */ if (ai_read_n(dev, s, devpriv->xfer_count) < 0) goto xfer_abort; if (devpriv->ai_count == 0) goto xfer_done; } } } overrun = readl(dev->mmio + LAS0_OVERRUN) & 0xffff; if (overrun) goto xfer_abort; /* clear the interrupt */ writew(status, dev->mmio + LAS0_CLEAR); readw(dev->mmio + LAS0_CLEAR); comedi_handle_events(dev, s); return IRQ_HANDLED; xfer_abort: s->async->events |= COMEDI_CB_ERROR; xfer_done: s->async->events |= COMEDI_CB_EOA; /* clear the interrupt */ status = readw(dev->mmio + LAS0_IT); writew(status, dev->mmio + LAS0_CLEAR); readw(dev->mmio + LAS0_CLEAR); fifo_status = readl(dev->mmio + LAS0_ADC); overrun = readl(dev->mmio + LAS0_OVERRUN) & 0xffff; comedi_handle_events(dev, s); return IRQ_HANDLED; } static int rtd_ai_cmdtest(struct comedi_device *dev, struct comedi_subdevice *s, struct comedi_cmd *cmd) { int err = 0; unsigned int arg; /* Step 1 : check if triggers are trivially valid */ err |= comedi_check_trigger_src(&cmd->start_src, TRIG_NOW); err |= comedi_check_trigger_src(&cmd->scan_begin_src, TRIG_TIMER | TRIG_EXT); err |= comedi_check_trigger_src(&cmd->convert_src, TRIG_TIMER | TRIG_EXT); err |= comedi_check_trigger_src(&cmd->scan_end_src, TRIG_COUNT); err |= comedi_check_trigger_src(&cmd->stop_src, TRIG_COUNT | TRIG_NONE); if (err) return 1; /* Step 2a : make sure trigger sources are unique */ err |= comedi_check_trigger_is_unique(cmd->scan_begin_src); err |= comedi_check_trigger_is_unique(cmd->convert_src); err |= comedi_check_trigger_is_unique(cmd->stop_src); /* Step 2b : and mutually compatible */ if (err) return 2; /* Step 3: check if arguments are trivially valid */ err |= comedi_check_trigger_arg_is(&cmd->start_arg, 0); if (cmd->scan_begin_src == TRIG_TIMER) { /* Note: these are time periods, not actual rates */ if (cmd->chanlist_len == 1) { /* no scanning */ if (comedi_check_trigger_arg_min(&cmd->scan_begin_arg, RTD_MAX_SPEED_1)) { rtd_ns_to_timer(&cmd->scan_begin_arg, CMDF_ROUND_UP); err |= -EINVAL; } if (comedi_check_trigger_arg_max(&cmd->scan_begin_arg, RTD_MIN_SPEED_1)) { rtd_ns_to_timer(&cmd->scan_begin_arg, CMDF_ROUND_DOWN); err |= -EINVAL; } } else { if (comedi_check_trigger_arg_min(&cmd->scan_begin_arg, RTD_MAX_SPEED)) { rtd_ns_to_timer(&cmd->scan_begin_arg, CMDF_ROUND_UP); err |= -EINVAL; } if (comedi_check_trigger_arg_max(&cmd->scan_begin_arg, RTD_MIN_SPEED)) { rtd_ns_to_timer(&cmd->scan_begin_arg, CMDF_ROUND_DOWN); err |= -EINVAL; } } } else { /* external trigger */ /* should be level/edge, hi/lo specification here */ /* should specify multiple external triggers */ err |= comedi_check_trigger_arg_max(&cmd->scan_begin_arg, 9); } if (cmd->convert_src == TRIG_TIMER) { if (cmd->chanlist_len == 1) { /* no scanning */ if (comedi_check_trigger_arg_min(&cmd->convert_arg, RTD_MAX_SPEED_1)) { rtd_ns_to_timer(&cmd->convert_arg, CMDF_ROUND_UP); err |= -EINVAL; } if (comedi_check_trigger_arg_max(&cmd->convert_arg, RTD_MIN_SPEED_1)) { rtd_ns_to_timer(&cmd->convert_arg, CMDF_ROUND_DOWN); err |= -EINVAL; } } else { if (comedi_check_trigger_arg_min(&cmd->convert_arg, RTD_MAX_SPEED)) { rtd_ns_to_timer(&cmd->convert_arg, CMDF_ROUND_UP); err |= -EINVAL; } if (comedi_check_trigger_arg_max(&cmd->convert_arg, RTD_MIN_SPEED)) { rtd_ns_to_timer(&cmd->convert_arg, CMDF_ROUND_DOWN); err |= -EINVAL; } } } else { /* external trigger */ /* see above */ err |= comedi_check_trigger_arg_max(&cmd->convert_arg, 9); } err |= comedi_check_trigger_arg_is(&cmd->scan_end_arg, cmd->chanlist_len); if (cmd->stop_src == TRIG_COUNT) err |= comedi_check_trigger_arg_min(&cmd->stop_arg, 1); else /* TRIG_NONE */ err |= comedi_check_trigger_arg_is(&cmd->stop_arg, 0); if (err) return 3; /* step 4: fix up any arguments */ if (cmd->scan_begin_src == TRIG_TIMER) { arg = cmd->scan_begin_arg; rtd_ns_to_timer(&arg, cmd->flags); err |= comedi_check_trigger_arg_is(&cmd->scan_begin_arg, arg); } if (cmd->convert_src == TRIG_TIMER) { arg = cmd->convert_arg; rtd_ns_to_timer(&arg, cmd->flags); err |= comedi_check_trigger_arg_is(&cmd->convert_arg, arg); if (cmd->scan_begin_src == TRIG_TIMER) { arg = cmd->convert_arg * cmd->scan_end_arg; err |= comedi_check_trigger_arg_min( &cmd->scan_begin_arg, arg); } } if (err) return 4; return 0; } static int rtd_ai_cmd(struct comedi_device *dev, struct comedi_subdevice *s) { struct rtd_private *devpriv = dev->private; struct comedi_cmd *cmd = &s->async->cmd; int timer; /* stop anything currently running */ /* pacer stop source: SOFTWARE */ writel(0, dev->mmio + LAS0_PACER_STOP); writel(0, dev->mmio + LAS0_PACER); /* stop pacer */ writel(0, dev->mmio + LAS0_ADC_CONVERSION); writew(0, dev->mmio + LAS0_IT); writel(0, dev->mmio + LAS0_ADC_FIFO_CLEAR); writel(0, dev->mmio + LAS0_OVERRUN); /* start configuration */ /* load channel list and reset CGT */ rtd_load_channelgain_list(dev, cmd->chanlist_len, cmd->chanlist); /* setup the common case and override if needed */ if (cmd->chanlist_len > 1) { /* pacer start source: SOFTWARE */ writel(0, dev->mmio + LAS0_PACER_START); /* burst trigger source: PACER */ writel(1, dev->mmio + LAS0_BURST_START); /* ADC conversion trigger source: BURST */ writel(2, dev->mmio + LAS0_ADC_CONVERSION); } else { /* single channel */ /* pacer start source: SOFTWARE */ writel(0, dev->mmio + LAS0_PACER_START); /* ADC conversion trigger source: PACER */ writel(1, dev->mmio + LAS0_ADC_CONVERSION); } writel((devpriv->fifosz / 2 - 1) & 0xffff, dev->mmio + LAS0_ACNT); if (cmd->scan_begin_src == TRIG_TIMER) { /* scan_begin_arg is in nanoseconds */ /* find out how many samples to wait before transferring */ if (cmd->flags & CMDF_WAKE_EOS) { /* * this may generate un-sustainable interrupt rates * the application is responsible for doing the * right thing */ devpriv->xfer_count = cmd->chanlist_len; devpriv->flags |= SEND_EOS; } else { /* arrange to transfer data periodically */ devpriv->xfer_count = (TRANS_TARGET_PERIOD * cmd->chanlist_len) / cmd->scan_begin_arg; if (devpriv->xfer_count < cmd->chanlist_len) { /* transfer after each scan (and avoid 0) */ devpriv->xfer_count = cmd->chanlist_len; } else { /* make a multiple of scan length */ devpriv->xfer_count = DIV_ROUND_UP(devpriv->xfer_count, cmd->chanlist_len); devpriv->xfer_count *= cmd->chanlist_len; } devpriv->flags |= SEND_EOS; } if (devpriv->xfer_count >= (devpriv->fifosz / 2)) { /* out of counter range, use 1/2 fifo instead */ devpriv->xfer_count = 0; devpriv->flags &= ~SEND_EOS; } else { /* interrupt for each transfer */ writel((devpriv->xfer_count - 1) & 0xffff, dev->mmio + LAS0_ACNT); } } else { /* unknown timing, just use 1/2 FIFO */ devpriv->xfer_count = 0; devpriv->flags &= ~SEND_EOS; } /* pacer clock source: INTERNAL 8MHz */ writel(1, dev->mmio + LAS0_PACER_SELECT); /* just interrupt, don't stop */ writel(1, dev->mmio + LAS0_ACNT_STOP_ENABLE); /* BUG??? these look like enumerated values, but they are bit fields */ /* First, setup when to stop */ switch (cmd->stop_src) { case TRIG_COUNT: /* stop after N scans */ devpriv->ai_count = cmd->stop_arg * cmd->chanlist_len; if ((devpriv->xfer_count > 0) && (devpriv->xfer_count > devpriv->ai_count)) { devpriv->xfer_count = devpriv->ai_count; } break; case TRIG_NONE: /* stop when cancel is called */ devpriv->ai_count = -1; /* read forever */ break; } /* Scan timing */ switch (cmd->scan_begin_src) { case TRIG_TIMER: /* periodic scanning */ timer = rtd_ns_to_timer(&cmd->scan_begin_arg, CMDF_ROUND_NEAREST); /* set PACER clock */ writel(timer & 0xffffff, dev->mmio + LAS0_PCLK); break; case TRIG_EXT: /* pacer start source: EXTERNAL */ writel(1, dev->mmio + LAS0_PACER_START); break; } /* Sample timing within a scan */ switch (cmd->convert_src) { case TRIG_TIMER: /* periodic */ if (cmd->chanlist_len > 1) { /* only needed for multi-channel */ timer = rtd_ns_to_timer(&cmd->convert_arg, CMDF_ROUND_NEAREST); /* setup BURST clock */ writel(timer & 0x3ff, dev->mmio + LAS0_BCLK); } break; case TRIG_EXT: /* external */ /* burst trigger source: EXTERNAL */ writel(2, dev->mmio + LAS0_BURST_START); break; } /* end configuration */ /* * This doesn't seem to work. There is no way to clear an interrupt * that the priority controller has queued! */ writew(~0, dev->mmio + LAS0_CLEAR); readw(dev->mmio + LAS0_CLEAR); /* TODO: allow multiple interrupt sources */ /* transfer every N samples */ writew(IRQM_ADC_ABOUT_CNT, dev->mmio + LAS0_IT); /* BUG: start_src is ASSUMED to be TRIG_NOW */ /* BUG? it seems like things are running before the "start" */ readl(dev->mmio + LAS0_PACER); /* start pacer */ return 0; } static int rtd_ai_cancel(struct comedi_device *dev, struct comedi_subdevice *s) { struct rtd_private *devpriv = dev->private; /* pacer stop source: SOFTWARE */ writel(0, dev->mmio + LAS0_PACER_STOP); writel(0, dev->mmio + LAS0_PACER); /* stop pacer */ writel(0, dev->mmio + LAS0_ADC_CONVERSION); writew(0, dev->mmio + LAS0_IT); devpriv->ai_count = 0; /* stop and don't transfer any more */ writel(0, dev->mmio + LAS0_ADC_FIFO_CLEAR); return 0; } static int rtd_ao_eoc(struct comedi_device *dev, struct comedi_subdevice *s, struct comedi_insn *insn, unsigned long context) { unsigned int chan = CR_CHAN(insn->chanspec); unsigned int bit = (chan == 0) ? FS_DAC1_NOT_EMPTY : FS_DAC2_NOT_EMPTY; unsigned int status; status = readl(dev->mmio + LAS0_ADC); if (status & bit) return 0; return -EBUSY; } static int rtd_ao_insn_write(struct comedi_device *dev, struct comedi_subdevice *s, struct comedi_insn *insn, unsigned int *data) { struct rtd_private *devpriv = dev->private; unsigned int chan = CR_CHAN(insn->chanspec); unsigned int range = CR_RANGE(insn->chanspec); int ret; int i; /* Configure the output range (table index matches the range values) */ writew(range & 7, dev->mmio + LAS0_DAC_CTRL(chan)); for (i = 0; i < insn->n; ++i) { unsigned int val = data[i]; /* bipolar uses 2's complement values with an extended sign */ if (comedi_range_is_bipolar(s, range)) { val = comedi_offset_munge(s, val); val |= (val & ((s->maxdata + 1) >> 1)) << 1; } /* shift the 12-bit data (+ sign) to match the register */ val <<= 3; writew(val, devpriv->las1 + LAS1_DAC_FIFO(chan)); writew(0, dev->mmio + LAS0_UPDATE_DAC(chan)); ret = comedi_timeout(dev, s, insn, rtd_ao_eoc, 0); if (ret) return ret; s->readback[chan] = data[i]; } return insn->n; } static int rtd_dio_insn_bits(struct comedi_device *dev, struct comedi_subdevice *s, struct comedi_insn *insn, unsigned int *data) { if (comedi_dio_update_state(s, data)) writew(s->state & 0xff, dev->mmio + LAS0_DIO0); data[1] = readw(dev->mmio + LAS0_DIO0) & 0xff; return insn->n; } static int rtd_dio_insn_config(struct comedi_device *dev, struct comedi_subdevice *s, struct comedi_insn *insn, unsigned int *data) { int ret; ret = comedi_dio_insn_config(dev, s, insn, data, 0); if (ret) return ret; /* TODO support digital match interrupts and strobes */ /* set direction */ writew(0x01, dev->mmio + LAS0_DIO_STATUS); writew(s->io_bits & 0xff, dev->mmio + LAS0_DIO0_CTRL); /* clear interrupts */ writew(0x00, dev->mmio + LAS0_DIO_STATUS); /* port1 can only be all input or all output */ /* there are also 2 user input lines and 2 user output lines */ return insn->n; } static int rtd_counter_insn_config(struct comedi_device *dev, struct comedi_subdevice *s, struct comedi_insn *insn, unsigned int *data) { struct rtd_private *devpriv = dev->private; unsigned int chan = CR_CHAN(insn->chanspec); unsigned int max_src; unsigned int src; switch (data[0]) { case INSN_CONFIG_SET_GATE_SRC: /* * 8254 Timer/Counter gate sources: * * 0 = Not gated, free running (reset state) * 1 = Gated, off * 2 = Ext. TC Gate 1 * 3 = Ext. TC Gate 2 * 4 = Previous TC out (chan 1 and 2 only) */ src = data[2]; max_src = (chan == 0) ? 3 : 4; if (src > max_src) return -EINVAL; devpriv->timer_gate_src[chan] = src; writeb(src, dev->mmio + LAS0_8254_GATE_SEL(chan)); break; case INSN_CONFIG_GET_GATE_SRC: data[2] = devpriv->timer_gate_src[chan]; break; case INSN_CONFIG_SET_CLOCK_SRC: /* * 8254 Timer/Counter clock sources: * * 0 = 8 MHz (reset state) * 1 = Ext. TC Clock 1 * 2 = Ext. TX Clock 2 * 3 = Ext. Pacer Clock * 4 = Previous TC out (chan 1 and 2 only) * 5 = High-Speed Digital Input Sampling signal (chan 1 only) */ src = data[1]; switch (chan) { case 0: max_src = 3; break; case 1: max_src = 5; break; case 2: max_src = 4; break; default: return -EINVAL; } if (src > max_src) return -EINVAL; devpriv->timer_clk_src[chan] = src; writeb(src, dev->mmio + LAS0_8254_CLK_SEL(chan)); break; case INSN_CONFIG_GET_CLOCK_SRC: src = devpriv->timer_clk_src[chan]; data[1] = devpriv->timer_clk_src[chan]; data[2] = (src == 0) ? RTD_CLOCK_BASE : 0; break; default: return -EINVAL; } return insn->n; } static void rtd_reset(struct comedi_device *dev) { struct rtd_private *devpriv = dev->private; writel(0, dev->mmio + LAS0_BOARD_RESET); usleep_range(100, 1000); /* needed? */ writel(0, devpriv->lcfg + PLX_REG_INTCSR); writew(0, dev->mmio + LAS0_IT); writew(~0, dev->mmio + LAS0_CLEAR); readw(dev->mmio + LAS0_CLEAR); } /* * initialize board, per RTD spec * also, initialize shadow registers */ static void rtd_init_board(struct comedi_device *dev) { rtd_reset(dev); writel(0, dev->mmio + LAS0_OVERRUN); writel(0, dev->mmio + LAS0_CGT_CLEAR); writel(0, dev->mmio + LAS0_ADC_FIFO_CLEAR); writel(0, dev->mmio + LAS0_DAC_RESET(0)); writel(0, dev->mmio + LAS0_DAC_RESET(1)); /* clear digital IO fifo */ writew(0, dev->mmio + LAS0_DIO_STATUS); /* TODO: set user out source ??? */ } /* The RTD driver does this */ static void rtd_pci_latency_quirk(struct comedi_device *dev, struct pci_dev *pcidev) { unsigned char pci_latency; pci_read_config_byte(pcidev, PCI_LATENCY_TIMER, &pci_latency); if (pci_latency < 32) { dev_info(dev->class_dev, "PCI latency changed from %d to %d\n", pci_latency, 32); pci_write_config_byte(pcidev, PCI_LATENCY_TIMER, 32); } } static int rtd_auto_attach(struct comedi_device *dev, unsigned long context) { struct pci_dev *pcidev = comedi_to_pci_dev(dev); const struct rtd_boardinfo *board = NULL; struct rtd_private *devpriv; struct comedi_subdevice *s; int ret; if (context < ARRAY_SIZE(rtd520_boards)) board = &rtd520_boards[context]; if (!board) return -ENODEV; dev->board_ptr = board; dev->board_name = board->name; devpriv = comedi_alloc_devpriv(dev, sizeof(*devpriv)); if (!devpriv) return -ENOMEM; ret = comedi_pci_enable(dev); if (ret) return ret; dev->mmio = pci_ioremap_bar(pcidev, 2); devpriv->las1 = pci_ioremap_bar(pcidev, 3); devpriv->lcfg = pci_ioremap_bar(pcidev, 0); if (!dev->mmio || !devpriv->las1 || !devpriv->lcfg) return -ENOMEM; rtd_pci_latency_quirk(dev, pcidev); if (pcidev->irq) { ret = request_irq(pcidev->irq, rtd_interrupt, IRQF_SHARED, dev->board_name, dev); if (ret == 0) dev->irq = pcidev->irq; } ret = comedi_alloc_subdevices(dev, 4); if (ret) return ret; s = &dev->subdevices[0]; /* analog input subdevice */ s->type = COMEDI_SUBD_AI; s->subdev_flags = SDF_READABLE | SDF_GROUND | SDF_COMMON | SDF_DIFF; s->n_chan = 16; s->maxdata = 0x0fff; s->range_table = board->ai_range; s->len_chanlist = RTD_MAX_CHANLIST; s->insn_read = rtd_ai_rinsn; if (dev->irq) { dev->read_subdev = s; s->subdev_flags |= SDF_CMD_READ; s->do_cmd = rtd_ai_cmd; s->do_cmdtest = rtd_ai_cmdtest; s->cancel = rtd_ai_cancel; } s = &dev->subdevices[1]; /* analog output subdevice */ s->type = COMEDI_SUBD_AO; s->subdev_flags = SDF_WRITABLE; s->n_chan = 2; s->maxdata = 0x0fff; s->range_table = &rtd_ao_range; s->insn_write = rtd_ao_insn_write; ret = comedi_alloc_subdev_readback(s); if (ret) return ret; s = &dev->subdevices[2]; /* digital i/o subdevice */ s->type = COMEDI_SUBD_DIO; s->subdev_flags = SDF_READABLE | SDF_WRITABLE; /* we only support port 0 right now. Ignoring port 1 and user IO */ s->n_chan = 8; s->maxdata = 1; s->range_table = &range_digital; s->insn_bits = rtd_dio_insn_bits; s->insn_config = rtd_dio_insn_config; /* 8254 Timer/Counter subdevice */ s = &dev->subdevices[3]; dev->pacer = comedi_8254_mm_init(dev->mmio + LAS0_8254_TIMER_BASE, RTD_CLOCK_BASE, I8254_IO8, 2); if (!dev->pacer) return -ENOMEM; comedi_8254_subdevice_init(s, dev->pacer); dev->pacer->insn_config = rtd_counter_insn_config; rtd_init_board(dev); ret = rtd520_probe_fifo_depth(dev); if (ret < 0) return ret; devpriv->fifosz = ret; if (dev->irq) writel(PLX_INTCSR_PIEN | PLX_INTCSR_PLIEN, devpriv->lcfg + PLX_REG_INTCSR); return 0; } static void rtd_detach(struct comedi_device *dev) { struct rtd_private *devpriv = dev->private; if (devpriv) { /* Shut down any board ops by resetting it */ if (dev->mmio && devpriv->lcfg) rtd_reset(dev); if (dev->irq) free_irq(dev->irq, dev); if (dev->mmio) iounmap(dev->mmio); if (devpriv->las1) iounmap(devpriv->las1); if (devpriv->lcfg) iounmap(devpriv->lcfg); } comedi_pci_disable(dev); } static struct comedi_driver rtd520_driver = { .driver_name = "rtd520", .module = THIS_MODULE, .auto_attach = rtd_auto_attach, .detach = rtd_detach, }; static int rtd520_pci_probe(struct pci_dev *dev, const struct pci_device_id *id) { return comedi_pci_auto_config(dev, &rtd520_driver, id->driver_data); } static const struct pci_device_id rtd520_pci_table[] = { { PCI_VDEVICE(RTD, 0x7520), BOARD_DM7520 }, { PCI_VDEVICE(RTD, 0x4520), BOARD_PCI4520 }, { 0 } }; MODULE_DEVICE_TABLE(pci, rtd520_pci_table); static struct pci_driver rtd520_pci_driver = { .name = "rtd520", .id_table = rtd520_pci_table, .probe = rtd520_pci_probe, .remove = comedi_pci_auto_unconfig, }; module_comedi_pci_driver(rtd520_driver, rtd520_pci_driver); MODULE_AUTHOR("Comedi https://www.comedi.org"); MODULE_DESCRIPTION("Comedi low-level driver"); MODULE_LICENSE("GPL");