| Author | Tokens | Token Proportion | Commits | Commit Proportion |
|---|---|---|---|---|
| Dave Penkler | 8345 | 96.47% | 4 | 21.05% |
| Michael Rubin | 176 | 2.03% | 7 | 36.84% |
| Nihar Chaithanya | 64 | 0.74% | 1 | 5.26% |
| Arnd Bergmann | 22 | 0.25% | 2 | 10.53% |
| Ma Ke | 21 | 0.24% | 1 | 5.26% |
| Paul Retourné | 19 | 0.22% | 1 | 5.26% |
| Nathan Chancellor | 1 | 0.01% | 1 | 5.26% |
| everestkc | 1 | 0.01% | 1 | 5.26% |
| Luke Yang | 1 | 0.01% | 1 | 5.26% |
| Total | 8650 | 19 |
// SPDX-License-Identifier: GPL-2.0 /*************************************************************************** * GPIB Driver for fmh_gpib_core, see * https://github.com/fmhess/fmh_gpib_core * * More specifically, it is a driver for the hardware arrangement described by * src/examples/fmh_gpib_top.vhd in the fmh_gpib_core repository. * * Author: Frank Mori Hess <fmh6jj@gmail.com> * Copyright: (C) 2006, 2010, 2015 Fluke Corporation * (C) 2017 Frank Mori Hess ***************************************************************************/ #define pr_fmt(fmt) KBUILD_MODNAME ": " fmt #define dev_fmt pr_fmt #define DRV_NAME KBUILD_MODNAME #include "fmh_gpib.h" #include "gpibP.h" #include <linux/delay.h> #include <linux/device.h> #include <linux/dma-mapping.h> #include <linux/module.h> #include <linux/of.h> #include <linux/platform_device.h> #include <linux/slab.h> MODULE_LICENSE("GPL"); MODULE_DESCRIPTION("GPIB Driver for fmh_gpib_core"); MODULE_AUTHOR("Frank Mori Hess <fmh6jj@gmail.com>"); static irqreturn_t fmh_gpib_interrupt(int irq, void *arg); static int fmh_gpib_attach_holdoff_all(struct gpib_board *board, const struct gpib_board_config *config); static int fmh_gpib_attach_holdoff_end(struct gpib_board *board, const struct gpib_board_config *config); static void fmh_gpib_detach(struct gpib_board *board); static int fmh_gpib_pci_attach_holdoff_all(struct gpib_board *board, const struct gpib_board_config *config); static int fmh_gpib_pci_attach_holdoff_end(struct gpib_board *board, const struct gpib_board_config *config); static void fmh_gpib_pci_detach(struct gpib_board *board); static int fmh_gpib_config_dma(struct gpib_board *board, int output); static irqreturn_t fmh_gpib_internal_interrupt(struct gpib_board *board); static struct platform_driver fmh_gpib_platform_driver; static struct pci_driver fmh_gpib_pci_driver; // wrappers for interface functions static int fmh_gpib_read(struct gpib_board *board, u8 *buffer, size_t length, int *end, size_t *bytes_read) { struct fmh_priv *priv = board->private_data; return nec7210_read(board, &priv->nec7210_priv, buffer, length, end, bytes_read); } static int fmh_gpib_write(struct gpib_board *board, u8 *buffer, size_t length, int send_eoi, size_t *bytes_written) { struct fmh_priv *priv = board->private_data; return nec7210_write(board, &priv->nec7210_priv, buffer, length, send_eoi, bytes_written); } static int fmh_gpib_command(struct gpib_board *board, u8 *buffer, size_t length, size_t *bytes_written) { struct fmh_priv *priv = board->private_data; return nec7210_command(board, &priv->nec7210_priv, buffer, length, bytes_written); } static int fmh_gpib_take_control(struct gpib_board *board, int synchronous) { struct fmh_priv *priv = board->private_data; return nec7210_take_control(board, &priv->nec7210_priv, synchronous); } static int fmh_gpib_go_to_standby(struct gpib_board *board) { struct fmh_priv *priv = board->private_data; return nec7210_go_to_standby(board, &priv->nec7210_priv); } static int fmh_gpib_request_system_control(struct gpib_board *board, int request_control) { struct fmh_priv *priv = board->private_data; struct nec7210_priv *nec_priv = &priv->nec7210_priv; return nec7210_request_system_control(board, nec_priv, request_control); } static void fmh_gpib_interface_clear(struct gpib_board *board, int assert) { struct fmh_priv *priv = board->private_data; nec7210_interface_clear(board, &priv->nec7210_priv, assert); } static void fmh_gpib_remote_enable(struct gpib_board *board, int enable) { struct fmh_priv *priv = board->private_data; nec7210_remote_enable(board, &priv->nec7210_priv, enable); } static int fmh_gpib_enable_eos(struct gpib_board *board, u8 eos_byte, int compare_8_bits) { struct fmh_priv *priv = board->private_data; return nec7210_enable_eos(board, &priv->nec7210_priv, eos_byte, compare_8_bits); } static void fmh_gpib_disable_eos(struct gpib_board *board) { struct fmh_priv *priv = board->private_data; nec7210_disable_eos(board, &priv->nec7210_priv); } static unsigned int fmh_gpib_update_status(struct gpib_board *board, unsigned int clear_mask) { struct fmh_priv *priv = board->private_data; return nec7210_update_status(board, &priv->nec7210_priv, clear_mask); } static int fmh_gpib_primary_address(struct gpib_board *board, unsigned int address) { struct fmh_priv *priv = board->private_data; return nec7210_primary_address(board, &priv->nec7210_priv, address); } static int fmh_gpib_secondary_address(struct gpib_board *board, unsigned int address, int enable) { struct fmh_priv *priv = board->private_data; return nec7210_secondary_address(board, &priv->nec7210_priv, address, enable); } static int fmh_gpib_parallel_poll(struct gpib_board *board, u8 *result) { struct fmh_priv *priv = board->private_data; return nec7210_parallel_poll(board, &priv->nec7210_priv, result); } static void fmh_gpib_parallel_poll_configure(struct gpib_board *board, u8 configuration) { struct fmh_priv *priv = board->private_data; nec7210_parallel_poll_configure(board, &priv->nec7210_priv, configuration); } static void fmh_gpib_parallel_poll_response(struct gpib_board *board, int ist) { struct fmh_priv *priv = board->private_data; nec7210_parallel_poll_response(board, &priv->nec7210_priv, ist); } static void fmh_gpib_local_parallel_poll_mode(struct gpib_board *board, int local) { struct fmh_priv *priv = board->private_data; if (local) { write_byte(&priv->nec7210_priv, AUX_I_REG | LOCAL_PPOLL_MODE_BIT, AUXMR); } else { /* * For fmh_gpib_core, remote parallel poll config mode is unaffected by the * state of the disable bit of the parallel poll register (unlike the tnt4882). * So, we don't need to worry about that. */ write_byte(&priv->nec7210_priv, AUX_I_REG | 0x0, AUXMR); } } static void fmh_gpib_serial_poll_response2(struct gpib_board *board, u8 status, int new_reason_for_service) { struct fmh_priv *priv = board->private_data; unsigned long flags; const int MSS = status & request_service_bit; const int reqt = MSS && new_reason_for_service; const int reqf = MSS == 0; spin_lock_irqsave(&board->spinlock, flags); if (reqt) { priv->nec7210_priv.srq_pending = 1; clear_bit(SPOLL_NUM, &board->status); } else if (reqf) { priv->nec7210_priv.srq_pending = 0; } if (reqt) { /* * It may seem like a race to issue reqt before updating * the status byte, but it is not. The chip does not * issue the reqt until the SPMR is written to at * a later time. */ write_byte(&priv->nec7210_priv, AUX_REQT, AUXMR); } else if (reqf) { write_byte(&priv->nec7210_priv, AUX_REQF, AUXMR); } /* * We need to always zero bit 6 of the status byte before writing it to * the SPMR to insure we are using * serial poll mode SP1, and not accidentally triggering mode SP3. */ write_byte(&priv->nec7210_priv, status & ~request_service_bit, SPMR); spin_unlock_irqrestore(&board->spinlock, flags); } static u8 fmh_gpib_serial_poll_status(struct gpib_board *board) { struct fmh_priv *priv = board->private_data; return nec7210_serial_poll_status(board, &priv->nec7210_priv); } static void fmh_gpib_return_to_local(struct gpib_board *board) { struct fmh_priv *priv = board->private_data; struct nec7210_priv *nec_priv = &priv->nec7210_priv; write_byte(nec_priv, AUX_RTL2, AUXMR); udelay(1); write_byte(nec_priv, AUX_RTL, AUXMR); } static int fmh_gpib_line_status(const struct gpib_board *board) { int status = VALID_ALL; int bsr_bits; struct fmh_priv *e_priv; struct nec7210_priv *nec_priv; e_priv = board->private_data; nec_priv = &e_priv->nec7210_priv; bsr_bits = read_byte(nec_priv, BUS_STATUS_REG); if ((bsr_bits & BSR_REN_BIT) == 0) status |= BUS_REN; if ((bsr_bits & BSR_IFC_BIT) == 0) status |= BUS_IFC; if ((bsr_bits & BSR_SRQ_BIT) == 0) status |= BUS_SRQ; if ((bsr_bits & BSR_EOI_BIT) == 0) status |= BUS_EOI; if ((bsr_bits & BSR_NRFD_BIT) == 0) status |= BUS_NRFD; if ((bsr_bits & BSR_NDAC_BIT) == 0) status |= BUS_NDAC; if ((bsr_bits & BSR_DAV_BIT) == 0) status |= BUS_DAV; if ((bsr_bits & BSR_ATN_BIT) == 0) status |= BUS_ATN; return status; } static int fmh_gpib_t1_delay(struct gpib_board *board, unsigned int nano_sec) { struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; unsigned int retval; retval = nec7210_t1_delay(board, nec_priv, nano_sec); if (nano_sec <= 350) { write_byte(nec_priv, AUX_HI_SPEED, AUXMR); retval = 350; } else { write_byte(nec_priv, AUX_LO_SPEED, AUXMR); } return retval; } static int lacs_or_read_ready(struct gpib_board *board) { const struct fmh_priv *e_priv = board->private_data; const struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; int retval = 0; unsigned long flags; spin_lock_irqsave(&board->spinlock, flags); retval = test_bit(LACS_NUM, &board->status) || test_bit(READ_READY_BN, &nec_priv->state); spin_unlock_irqrestore(&board->spinlock, flags); return retval; } static int wait_for_read(struct gpib_board *board) { struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; int retval = 0; if (wait_event_interruptible(board->wait, lacs_or_read_ready(board) || test_bit(DEV_CLEAR_BN, &nec_priv->state) || test_bit(TIMO_NUM, &board->status))) retval = -ERESTARTSYS; if (test_bit(TIMO_NUM, &board->status)) retval = -ETIMEDOUT; if (test_and_clear_bit(DEV_CLEAR_BN, &nec_priv->state)) retval = -EINTR; return retval; } static int wait_for_rx_fifo_half_full_or_end(struct gpib_board *board) { struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; int retval = 0; if (wait_event_interruptible(board->wait, (fifos_read(e_priv, FIFO_CONTROL_STATUS_REG) & RX_FIFO_HALF_FULL) || test_bit(RECEIVED_END_BN, &nec_priv->state) || test_bit(DEV_CLEAR_BN, &nec_priv->state) || test_bit(TIMO_NUM, &board->status))) retval = -ERESTARTSYS; if (test_bit(TIMO_NUM, &board->status)) retval = -ETIMEDOUT; if (test_and_clear_bit(DEV_CLEAR_BN, &nec_priv->state)) retval = -EINTR; return retval; } /* * Wait until the gpib chip is ready to accept a data out byte. */ static int wait_for_data_out_ready(struct gpib_board *board) { struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; int retval = 0; if (wait_event_interruptible(board->wait, (test_bit(TACS_NUM, &board->status) && (read_byte(nec_priv, EXT_STATUS_1_REG) & DATA_OUT_STATUS_BIT)) || test_bit(DEV_CLEAR_BN, &nec_priv->state) || test_bit(TIMO_NUM, &board->status))) retval = -ERESTARTSYS; if (test_bit(TIMO_NUM, &board->status)) retval = -ETIMEDOUT; if (test_and_clear_bit(DEV_CLEAR_BN, &nec_priv->state)) retval = -EINTR; return retval; } static void fmh_gpib_dma_callback(void *arg) { struct gpib_board *board = arg; struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; unsigned long flags; spin_lock_irqsave(&board->spinlock, flags); nec7210_set_reg_bits(nec_priv, IMR1, HR_DOIE | HR_DIIE, HR_DOIE | HR_DIIE); wake_up_interruptible(&board->wait); fmh_gpib_internal_interrupt(board); clear_bit(DMA_WRITE_IN_PROGRESS_BN, &nec_priv->state); clear_bit(DMA_READ_IN_PROGRESS_BN, &nec_priv->state); spin_unlock_irqrestore(&board->spinlock, flags); } /* * returns true when all the bytes of a write have been transferred to * the chip and successfully transferred out over the gpib bus. */ static int fmh_gpib_all_bytes_are_sent(struct fmh_priv *e_priv) { if (fifos_read(e_priv, FIFO_XFER_COUNTER_REG) & fifo_xfer_counter_mask) return 0; if ((read_byte(&e_priv->nec7210_priv, EXT_STATUS_1_REG) & DATA_OUT_STATUS_BIT) == 0) return 0; return 1; } static int fmh_gpib_dma_write(struct gpib_board *board, u8 *buffer, size_t length, size_t *bytes_written) { struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; unsigned long flags; int retval = 0; dma_addr_t address; struct dma_async_tx_descriptor *tx_desc; *bytes_written = 0; if (WARN_ON_ONCE(length > e_priv->dma_buffer_size)) return -EFAULT; dmaengine_terminate_all(e_priv->dma_channel); memcpy(e_priv->dma_buffer, buffer, length); address = dma_map_single(board->dev, e_priv->dma_buffer, length, DMA_TO_DEVICE); if (dma_mapping_error(board->dev, address)) dev_err(board->gpib_dev, "dma mapping error in dma write!\n"); /* program dma controller */ retval = fmh_gpib_config_dma(board, 1); if (retval) goto cleanup; tx_desc = dmaengine_prep_slave_single(e_priv->dma_channel, address, length, DMA_MEM_TO_DEV, DMA_PREP_INTERRUPT | DMA_CTRL_ACK); if (!tx_desc) { dev_err(board->gpib_dev, "failed to allocate dma transmit descriptor\n"); retval = -ENOMEM; goto cleanup; } tx_desc->callback = fmh_gpib_dma_callback; tx_desc->callback_param = board; spin_lock_irqsave(&board->spinlock, flags); fifos_write(e_priv, length & fifo_xfer_counter_mask, FIFO_XFER_COUNTER_REG); fifos_write(e_priv, TX_FIFO_DMA_REQUEST_ENABLE | TX_FIFO_CLEAR, FIFO_CONTROL_STATUS_REG); nec7210_set_reg_bits(nec_priv, IMR1, HR_DOIE, 0); nec7210_set_reg_bits(nec_priv, IMR2, HR_DMAO, HR_DMAO); dmaengine_submit(tx_desc); dma_async_issue_pending(e_priv->dma_channel); clear_bit(WRITE_READY_BN, &nec_priv->state); set_bit(DMA_WRITE_IN_PROGRESS_BN, &nec_priv->state); spin_unlock_irqrestore(&board->spinlock, flags); // suspend until message is sent if (wait_event_interruptible(board->wait, fmh_gpib_all_bytes_are_sent(e_priv) || test_bit(BUS_ERROR_BN, &nec_priv->state) || test_bit(DEV_CLEAR_BN, &nec_priv->state) || test_bit(TIMO_NUM, &board->status))) retval = -ERESTARTSYS; if (test_bit(TIMO_NUM, &board->status)) retval = -ETIMEDOUT; if (test_and_clear_bit(DEV_CLEAR_BN, &nec_priv->state)) retval = -EINTR; if (test_and_clear_bit(BUS_ERROR_BN, &nec_priv->state)) retval = -EIO; // disable board's dma nec7210_set_reg_bits(nec_priv, IMR2, HR_DMAO, 0); fifos_write(e_priv, 0, FIFO_CONTROL_STATUS_REG); dmaengine_terminate_all(e_priv->dma_channel); // make sure fmh_gpib_dma_callback got called if (test_bit(DMA_WRITE_IN_PROGRESS_BN, &nec_priv->state)) fmh_gpib_dma_callback(board); *bytes_written = length - (fifos_read(e_priv, FIFO_XFER_COUNTER_REG) & fifo_xfer_counter_mask); if (WARN_ON_ONCE(*bytes_written > length)) return -EFAULT; cleanup: dma_unmap_single(board->dev, address, length, DMA_TO_DEVICE); return retval; } static int fmh_gpib_accel_write(struct gpib_board *board, u8 *buffer, size_t length, int send_eoi, size_t *bytes_written) { struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; size_t remainder = length; size_t transfer_size; ssize_t retval = 0; size_t dma_remainder = remainder; if (!e_priv->dma_channel) { dev_err(board->gpib_dev, "No dma channel available, cannot do accel write."); return -ENXIO; } *bytes_written = 0; if (length < 1) return 0; smp_mb__before_atomic(); clear_bit(DEV_CLEAR_BN, &nec_priv->state); // XXX FIXME smp_mb__after_atomic(); if (send_eoi) --dma_remainder; while (dma_remainder > 0) { size_t num_bytes; retval = wait_for_data_out_ready(board); if (retval < 0) break; transfer_size = (e_priv->dma_buffer_size < dma_remainder) ? e_priv->dma_buffer_size : dma_remainder; retval = fmh_gpib_dma_write(board, buffer, transfer_size, &num_bytes); *bytes_written += num_bytes; if (retval < 0) break; dma_remainder -= num_bytes; remainder -= num_bytes; buffer += num_bytes; if (need_resched()) schedule(); } if (retval < 0) return retval; // handle sending of last byte with eoi if (send_eoi) { size_t num_bytes; if (WARN_ON_ONCE(remainder != 1)) return -EFAULT; /* * wait until we are sure we will be able to write the data byte * into the chip before we send AUX_SEOI. This prevents a timeout * scenario where we send AUX_SEOI but then timeout without getting * any bytes into the gpib chip. This will result in the first byte * of the next write having a spurious EOI set on the first byte. */ retval = wait_for_data_out_ready(board); if (retval < 0) return retval; write_byte(nec_priv, AUX_SEOI, AUXMR); retval = fmh_gpib_dma_write(board, buffer, remainder, &num_bytes); *bytes_written += num_bytes; if (retval < 0) return retval; remainder -= num_bytes; } return 0; } static int fmh_gpib_get_dma_residue(struct dma_chan *chan, dma_cookie_t cookie) { struct dma_tx_state state; int result; result = dmaengine_pause(chan); if (result < 0) { pr_err("dma pause failed?\n"); return result; } dmaengine_tx_status(chan, cookie, &state); /* * dma330 hardware doesn't support resume, so dont call this * method unless the dma transfer is done. */ return state.residue; } static int wait_for_tx_fifo_half_empty(struct gpib_board *board) { struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; int retval = 0; if (wait_event_interruptible(board->wait, (test_bit(TACS_NUM, &board->status) && (fifos_read(e_priv, FIFO_CONTROL_STATUS_REG) & TX_FIFO_HALF_EMPTY)) || test_bit(DEV_CLEAR_BN, &nec_priv->state) || test_bit(TIMO_NUM, &board->status))) retval = -ERESTARTSYS; if (test_bit(TIMO_NUM, &board->status)) retval = -ETIMEDOUT; if (test_and_clear_bit(DEV_CLEAR_BN, &nec_priv->state)) retval = -EINTR; return retval; } /* * supports writing a chunk of data whose length must fit into the hardware'd xfer counter, * called in a loop by fmh_gpib_fifo_write() */ static int fmh_gpib_fifo_write_countable(struct gpib_board *board, u8 *buffer, size_t length, int send_eoi, size_t *bytes_written) { struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; int retval = 0; unsigned int remainder; *bytes_written = 0; if (WARN_ON_ONCE(length > fifo_xfer_counter_mask)) return -EFAULT; fifos_write(e_priv, length & fifo_xfer_counter_mask, FIFO_XFER_COUNTER_REG); fifos_write(e_priv, TX_FIFO_CLEAR, FIFO_CONTROL_STATUS_REG); nec7210_set_reg_bits(nec_priv, IMR1, HR_DOIE, 0); nec7210_set_reg_bits(nec_priv, IMR2, HR_DMAO, HR_DMAO); remainder = length; while (remainder > 0) { int i; fifos_write(e_priv, TX_FIFO_HALF_EMPTY_INTERRUPT_ENABLE, FIFO_CONTROL_STATUS_REG); retval = wait_for_tx_fifo_half_empty(board); if (retval < 0) goto cleanup; for (i = 0; i < fmh_gpib_half_fifo_size(e_priv) && remainder > 0; ++i) { unsigned int data_value = *buffer; if (send_eoi && remainder == 1) data_value |= FIFO_DATA_EOI_FLAG; fifos_write(e_priv, data_value, FIFO_DATA_REG); ++buffer; --remainder; } } // suspend until last byte is sent nec7210_set_reg_bits(nec_priv, IMR1, HR_DOIE, HR_DOIE); if (wait_event_interruptible(board->wait, fmh_gpib_all_bytes_are_sent(e_priv) || test_bit(BUS_ERROR_BN, &nec_priv->state) || test_bit(DEV_CLEAR_BN, &nec_priv->state) || test_bit(TIMO_NUM, &board->status))) retval = -ERESTARTSYS; if (test_bit(TIMO_NUM, &board->status)) retval = -ETIMEDOUT; if (test_and_clear_bit(DEV_CLEAR_BN, &nec_priv->state)) retval = -EINTR; if (test_and_clear_bit(BUS_ERROR_BN, &nec_priv->state)) retval = -EIO; cleanup: nec7210_set_reg_bits(nec_priv, IMR1, HR_DOIE, 0); nec7210_set_reg_bits(nec_priv, IMR2, HR_DMAO, 0); fifos_write(e_priv, 0, FIFO_CONTROL_STATUS_REG); *bytes_written = length - (fifos_read(e_priv, FIFO_XFER_COUNTER_REG) & fifo_xfer_counter_mask); if (WARN_ON_ONCE(*bytes_written > length)) return -EFAULT; return retval; } static int fmh_gpib_fifo_write(struct gpib_board *board, u8 *buffer, size_t length, int send_eoi, size_t *bytes_written) { struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; size_t remainder = length; size_t transfer_size; ssize_t retval = 0; *bytes_written = 0; if (length < 1) return 0; clear_bit(DEV_CLEAR_BN, &nec_priv->state); // XXX FIXME while (remainder > 0) { size_t num_bytes; int last_pass; retval = wait_for_data_out_ready(board); if (retval < 0) break; if (fifo_xfer_counter_mask < remainder) { // round transfer size to a multiple of half fifo size transfer_size = (fifo_xfer_counter_mask / fmh_gpib_half_fifo_size(e_priv)) * fmh_gpib_half_fifo_size(e_priv); last_pass = 0; } else { transfer_size = remainder; last_pass = 1; } retval = fmh_gpib_fifo_write_countable(board, buffer, transfer_size, last_pass && send_eoi, &num_bytes); *bytes_written += num_bytes; if (retval < 0) break; remainder -= num_bytes; buffer += num_bytes; if (need_resched()) schedule(); } return retval; } static int fmh_gpib_dma_read(struct gpib_board *board, u8 *buffer, size_t length, int *end, size_t *bytes_read) { struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; int retval = 0; unsigned long flags; int residue; int wait_retval; dma_addr_t bus_address; struct dma_async_tx_descriptor *tx_desc; dma_cookie_t dma_cookie; *bytes_read = 0; *end = 0; if (length == 0) return 0; bus_address = dma_map_single(board->dev, e_priv->dma_buffer, length, DMA_FROM_DEVICE); if (dma_mapping_error(board->dev, bus_address)) dev_err(board->gpib_dev, "dma mapping error in dma read!"); /* program dma controller */ retval = fmh_gpib_config_dma(board, 0); if (retval) { dma_unmap_single(board->dev, bus_address, length, DMA_FROM_DEVICE); return retval; } tx_desc = dmaengine_prep_slave_single(e_priv->dma_channel, bus_address, length, DMA_DEV_TO_MEM, DMA_PREP_INTERRUPT | DMA_CTRL_ACK); if (!tx_desc) { dev_err(board->gpib_dev, "failed to allocate dma transmit descriptor\n"); dma_unmap_single(board->dev, bus_address, length, DMA_FROM_DEVICE); return -EIO; } tx_desc->callback = fmh_gpib_dma_callback; tx_desc->callback_param = board; spin_lock_irqsave(&board->spinlock, flags); // enable nec7210 dma fifos_write(e_priv, length & fifo_xfer_counter_mask, FIFO_XFER_COUNTER_REG); fifos_write(e_priv, RX_FIFO_DMA_REQUEST_ENABLE | RX_FIFO_CLEAR, FIFO_CONTROL_STATUS_REG); nec7210_set_reg_bits(nec_priv, IMR1, HR_DIIE, 0); nec7210_set_reg_bits(nec_priv, IMR2, HR_DMAI, HR_DMAI); dma_cookie = dmaengine_submit(tx_desc); dma_async_issue_pending(e_priv->dma_channel); set_bit(DMA_READ_IN_PROGRESS_BN, &nec_priv->state); spin_unlock_irqrestore(&board->spinlock, flags); // wait for data to transfer wait_retval = wait_event_interruptible(board->wait, test_bit(DMA_READ_IN_PROGRESS_BN, &nec_priv->state) == 0 || test_bit(RECEIVED_END_BN, &nec_priv->state) || test_bit(DEV_CLEAR_BN, &nec_priv->state) || test_bit(TIMO_NUM, &board->status)); if (wait_retval) retval = -ERESTARTSYS; if (test_bit(TIMO_NUM, &board->status)) retval = -ETIMEDOUT; if (test_bit(DEV_CLEAR_BN, &nec_priv->state)) retval = -EINTR; // stop the dma transfer nec7210_set_reg_bits(nec_priv, IMR2, HR_DMAI, 0); fifos_write(e_priv, 0, FIFO_CONTROL_STATUS_REG); /* * give time for pl330 to transfer any in-flight data, since * pl330 will throw it away when dmaengine_pause is called. */ usleep_range(10, 15); residue = fmh_gpib_get_dma_residue(e_priv->dma_channel, dma_cookie); if (WARN_ON_ONCE(residue > length || residue < 0)) return -EFAULT; *bytes_read += length - residue; dmaengine_terminate_all(e_priv->dma_channel); // make sure fmh_gpib_dma_callback got called if (test_bit(DMA_READ_IN_PROGRESS_BN, &nec_priv->state)) fmh_gpib_dma_callback(board); dma_unmap_single(board->dev, bus_address, length, DMA_FROM_DEVICE); memcpy(buffer, e_priv->dma_buffer, *bytes_read); /* Manually read any dregs out of fifo. */ while ((fifos_read(e_priv, FIFO_CONTROL_STATUS_REG) & RX_FIFO_EMPTY) == 0) { if ((*bytes_read) >= length) { dev_err(board->dev, "unexpected extra bytes in rx fifo, discarding! bytes_read=%d length=%d residue=%d\n", (int)(*bytes_read), (int)length, (int)residue); break; } buffer[(*bytes_read)++] = fifos_read(e_priv, FIFO_DATA_REG) & fifo_data_mask; } /* * If we got an end interrupt, figure out if it was * associated with the last byte we dma'd or with a * byte still sitting on the cb7210. */ spin_lock_irqsave(&board->spinlock, flags); if (*bytes_read > 0 && test_bit(READ_READY_BN, &nec_priv->state) == 0) { /* * If there is no byte sitting on the cb7210 and we * saw an end, we need to deal with it now */ if (test_and_clear_bit(RECEIVED_END_BN, &nec_priv->state)) *end = 1; } spin_unlock_irqrestore(&board->spinlock, flags); return retval; } static void fmh_gpib_release_rfd_holdoff(struct gpib_board *board, struct fmh_priv *e_priv) { struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; unsigned int ext_status_1; unsigned long flags; spin_lock_irqsave(&board->spinlock, flags); ext_status_1 = read_byte(nec_priv, EXT_STATUS_1_REG); /* * if there is an end byte sitting on the chip, don't release * holdoff. We want it left set after we read out the end * byte. */ if ((ext_status_1 & (DATA_IN_STATUS_BIT | END_STATUS_BIT)) != (DATA_IN_STATUS_BIT | END_STATUS_BIT)) { if (ext_status_1 & RFD_HOLDOFF_STATUS_BIT) write_byte(nec_priv, AUX_FH, AUXMR); /* * Check if an end byte raced in before we executed the AUX_FH command. * If it did, we want to make sure the rfd holdoff is in effect. The end * byte can arrive since * AUX_RFD_HOLDOFF_ASAP doesn't immediately force the acceptor handshake * to leave ACRS. */ if ((read_byte(nec_priv, EXT_STATUS_1_REG) & (RFD_HOLDOFF_STATUS_BIT | DATA_IN_STATUS_BIT | END_STATUS_BIT)) == (DATA_IN_STATUS_BIT | END_STATUS_BIT)) { write_byte(nec_priv, AUX_RFD_HOLDOFF_ASAP, AUXMR); set_bit(RFD_HOLDOFF_BN, &nec_priv->state); } else { clear_bit(RFD_HOLDOFF_BN, &nec_priv->state); } } spin_unlock_irqrestore(&board->spinlock, flags); } static int fmh_gpib_accel_read(struct gpib_board *board, u8 *buffer, size_t length, int *end, size_t *bytes_read) { struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; size_t remain = length; size_t transfer_size; int retval = 0; size_t dma_nbytes; unsigned long flags; smp_mb__before_atomic(); clear_bit(DEV_CLEAR_BN, &nec_priv->state); // XXX FIXME smp_mb__after_atomic(); *end = 0; *bytes_read = 0; retval = wait_for_read(board); if (retval < 0) return retval; fmh_gpib_release_rfd_holdoff(board, e_priv); while (remain > 0) { transfer_size = (e_priv->dma_buffer_size < remain) ? e_priv->dma_buffer_size : remain; retval = fmh_gpib_dma_read(board, buffer, transfer_size, end, &dma_nbytes); remain -= dma_nbytes; buffer += dma_nbytes; *bytes_read += dma_nbytes; if (*end) break; if (retval < 0) break; if (need_resched()) schedule(); } spin_lock_irqsave(&board->spinlock, flags); if (test_bit(RFD_HOLDOFF_BN, &nec_priv->state) == 0) { write_byte(nec_priv, AUX_RFD_HOLDOFF_ASAP, AUXMR); set_bit(RFD_HOLDOFF_BN, &nec_priv->state); } spin_unlock_irqrestore(&board->spinlock, flags); return retval; } /* * Read a chunk of data whose length is within the limits of the hardware's * xfer counter. Called in a loop from fmh_gpib_fifo_read(). */ static int fmh_gpib_fifo_read_countable(struct gpib_board *board, u8 *buffer, size_t length, int *end, size_t *bytes_read) { struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; int retval = 0; *bytes_read = 0; *end = 0; if (length == 0) return 0; fifos_write(e_priv, length & fifo_xfer_counter_mask, FIFO_XFER_COUNTER_REG); fifos_write(e_priv, RX_FIFO_CLEAR, FIFO_CONTROL_STATUS_REG); nec7210_set_reg_bits(nec_priv, IMR1, HR_DIIE, 0); nec7210_set_reg_bits(nec_priv, IMR2, HR_DMAI, HR_DMAI); while (*bytes_read < length && *end == 0) { int i; fifos_write(e_priv, RX_FIFO_HALF_FULL_INTERRUPT_ENABLE, FIFO_CONTROL_STATUS_REG); retval = wait_for_rx_fifo_half_full_or_end(board); if (retval < 0) goto cleanup; for (i = 0; i < fmh_gpib_half_fifo_size(e_priv) && *end == 0; ++i) { unsigned int data_value; data_value = fifos_read(e_priv, FIFO_DATA_REG); buffer[(*bytes_read)++] = data_value & fifo_data_mask; if (data_value & FIFO_DATA_EOI_FLAG) *end = 1; } } cleanup: // stop the transfer nec7210_set_reg_bits(nec_priv, IMR2, HR_DMAI, 0); fifos_write(e_priv, 0, FIFO_CONTROL_STATUS_REG); /* Manually read any dregs out of fifo. */ while ((fifos_read(e_priv, FIFO_CONTROL_STATUS_REG) & RX_FIFO_EMPTY) == 0) { unsigned int data_value; if ((*bytes_read) >= length) { dev_err(board->dev, "unexpected extra bytes in rx fifo, discarding! bytes_read=%d length=%d\n", (int)(*bytes_read), (int)length); break; } data_value = fifos_read(e_priv, FIFO_DATA_REG); buffer[(*bytes_read)++] = data_value & fifo_data_mask; if (data_value & FIFO_DATA_EOI_FLAG) *end = 1; } return retval; } static int fmh_gpib_fifo_read(struct gpib_board *board, u8 *buffer, size_t length, int *end, size_t *bytes_read) { struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; size_t remain = length; size_t transfer_size; int retval = 0; size_t nbytes; unsigned long flags; clear_bit(DEV_CLEAR_BN, &nec_priv->state); // XXX FIXME *end = 0; *bytes_read = 0; /* * Do a little prep with data in interrupt so that following wait_for_read() * will wake up if a data byte is received. */ nec7210_set_reg_bits(nec_priv, IMR1, HR_DIIE, HR_DIIE); fmh_gpib_interrupt(0, board); retval = wait_for_read(board); if (retval < 0) return retval; fmh_gpib_release_rfd_holdoff(board, e_priv); while (remain > 0) { if (fifo_xfer_counter_mask < remain) { // round transfer size to a multiple of half fifo size transfer_size = (fifo_xfer_counter_mask / fmh_gpib_half_fifo_size(e_priv)) * fmh_gpib_half_fifo_size(e_priv); } else { transfer_size = remain; } retval = fmh_gpib_fifo_read_countable(board, buffer, transfer_size, end, &nbytes); remain -= nbytes; buffer += nbytes; *bytes_read += nbytes; if (*end) break; if (retval < 0) break; if (need_resched()) schedule(); } if (*end == 0) { spin_lock_irqsave(&board->spinlock, flags); write_byte(nec_priv, AUX_RFD_HOLDOFF_ASAP, AUXMR); set_bit(RFD_HOLDOFF_BN, &nec_priv->state); spin_unlock_irqrestore(&board->spinlock, flags); } return retval; } static struct gpib_interface fmh_gpib_unaccel_interface = { .name = "fmh_gpib_unaccel", .attach = fmh_gpib_attach_holdoff_all, .detach = fmh_gpib_detach, .read = fmh_gpib_read, .write = fmh_gpib_write, .command = fmh_gpib_command, .take_control = fmh_gpib_take_control, .go_to_standby = fmh_gpib_go_to_standby, .request_system_control = fmh_gpib_request_system_control, .interface_clear = fmh_gpib_interface_clear, .remote_enable = fmh_gpib_remote_enable, .enable_eos = fmh_gpib_enable_eos, .disable_eos = fmh_gpib_disable_eos, .parallel_poll = fmh_gpib_parallel_poll, .parallel_poll_configure = fmh_gpib_parallel_poll_configure, .parallel_poll_response = fmh_gpib_parallel_poll_response, .local_parallel_poll_mode = fmh_gpib_local_parallel_poll_mode, .line_status = fmh_gpib_line_status, .update_status = fmh_gpib_update_status, .primary_address = fmh_gpib_primary_address, .secondary_address = fmh_gpib_secondary_address, .serial_poll_response2 = fmh_gpib_serial_poll_response2, .serial_poll_status = fmh_gpib_serial_poll_status, .t1_delay = fmh_gpib_t1_delay, .return_to_local = fmh_gpib_return_to_local, }; static struct gpib_interface fmh_gpib_interface = { .name = "fmh_gpib", .attach = fmh_gpib_attach_holdoff_end, .detach = fmh_gpib_detach, .read = fmh_gpib_accel_read, .write = fmh_gpib_accel_write, .command = fmh_gpib_command, .take_control = fmh_gpib_take_control, .go_to_standby = fmh_gpib_go_to_standby, .request_system_control = fmh_gpib_request_system_control, .interface_clear = fmh_gpib_interface_clear, .remote_enable = fmh_gpib_remote_enable, .enable_eos = fmh_gpib_enable_eos, .disable_eos = fmh_gpib_disable_eos, .parallel_poll = fmh_gpib_parallel_poll, .parallel_poll_configure = fmh_gpib_parallel_poll_configure, .parallel_poll_response = fmh_gpib_parallel_poll_response, .local_parallel_poll_mode = fmh_gpib_local_parallel_poll_mode, .line_status = fmh_gpib_line_status, .update_status = fmh_gpib_update_status, .primary_address = fmh_gpib_primary_address, .secondary_address = fmh_gpib_secondary_address, .serial_poll_response2 = fmh_gpib_serial_poll_response2, .serial_poll_status = fmh_gpib_serial_poll_status, .t1_delay = fmh_gpib_t1_delay, .return_to_local = fmh_gpib_return_to_local, }; static struct gpib_interface fmh_gpib_pci_interface = { .name = "fmh_gpib_pci", .attach = fmh_gpib_pci_attach_holdoff_end, .detach = fmh_gpib_pci_detach, .read = fmh_gpib_fifo_read, .write = fmh_gpib_fifo_write, .command = fmh_gpib_command, .take_control = fmh_gpib_take_control, .go_to_standby = fmh_gpib_go_to_standby, .request_system_control = fmh_gpib_request_system_control, .interface_clear = fmh_gpib_interface_clear, .remote_enable = fmh_gpib_remote_enable, .enable_eos = fmh_gpib_enable_eos, .disable_eos = fmh_gpib_disable_eos, .parallel_poll = fmh_gpib_parallel_poll, .parallel_poll_configure = fmh_gpib_parallel_poll_configure, .parallel_poll_response = fmh_gpib_parallel_poll_response, .local_parallel_poll_mode = fmh_gpib_local_parallel_poll_mode, .line_status = fmh_gpib_line_status, .update_status = fmh_gpib_update_status, .primary_address = fmh_gpib_primary_address, .secondary_address = fmh_gpib_secondary_address, .serial_poll_response2 = fmh_gpib_serial_poll_response2, .serial_poll_status = fmh_gpib_serial_poll_status, .t1_delay = fmh_gpib_t1_delay, .return_to_local = fmh_gpib_return_to_local, }; static struct gpib_interface fmh_gpib_pci_unaccel_interface = { .name = "fmh_gpib_pci_unaccel", .attach = fmh_gpib_pci_attach_holdoff_all, .detach = fmh_gpib_pci_detach, .read = fmh_gpib_read, .write = fmh_gpib_write, .command = fmh_gpib_command, .take_control = fmh_gpib_take_control, .go_to_standby = fmh_gpib_go_to_standby, .request_system_control = fmh_gpib_request_system_control, .interface_clear = fmh_gpib_interface_clear, .remote_enable = fmh_gpib_remote_enable, .enable_eos = fmh_gpib_enable_eos, .disable_eos = fmh_gpib_disable_eos, .parallel_poll = fmh_gpib_parallel_poll, .parallel_poll_configure = fmh_gpib_parallel_poll_configure, .parallel_poll_response = fmh_gpib_parallel_poll_response, .local_parallel_poll_mode = fmh_gpib_local_parallel_poll_mode, .line_status = fmh_gpib_line_status, .update_status = fmh_gpib_update_status, .primary_address = fmh_gpib_primary_address, .secondary_address = fmh_gpib_secondary_address, .serial_poll_response2 = fmh_gpib_serial_poll_response2, .serial_poll_status = fmh_gpib_serial_poll_status, .t1_delay = fmh_gpib_t1_delay, .return_to_local = fmh_gpib_return_to_local, }; irqreturn_t fmh_gpib_internal_interrupt(struct gpib_board *board) { unsigned int status0, status1, status2, ext_status_1, fifo_status; struct fmh_priv *priv = board->private_data; struct nec7210_priv *nec_priv = &priv->nec7210_priv; int retval = IRQ_NONE; status0 = read_byte(nec_priv, ISR0_IMR0_REG); status1 = read_byte(nec_priv, ISR1); status2 = read_byte(nec_priv, ISR2); fifo_status = fifos_read(priv, FIFO_CONTROL_STATUS_REG); if (status0 & IFC_INTERRUPT_BIT) { push_gpib_event(board, EVENT_IFC); retval = IRQ_HANDLED; } if (nec7210_interrupt_have_status(board, nec_priv, status1, status2) == IRQ_HANDLED) retval = IRQ_HANDLED; ext_status_1 = read_byte(nec_priv, EXT_STATUS_1_REG); if (ext_status_1 & DATA_IN_STATUS_BIT) set_bit(READ_READY_BN, &nec_priv->state); else clear_bit(READ_READY_BN, &nec_priv->state); if (ext_status_1 & DATA_OUT_STATUS_BIT) set_bit(WRITE_READY_BN, &nec_priv->state); else clear_bit(WRITE_READY_BN, &nec_priv->state); if (ext_status_1 & COMMAND_OUT_STATUS_BIT) set_bit(COMMAND_READY_BN, &nec_priv->state); else clear_bit(COMMAND_READY_BN, &nec_priv->state); if (ext_status_1 & RFD_HOLDOFF_STATUS_BIT) set_bit(RFD_HOLDOFF_BN, &nec_priv->state); else clear_bit(RFD_HOLDOFF_BN, &nec_priv->state); if (ext_status_1 & END_STATUS_BIT) { /* * only set RECEIVED_END while there is still a data * byte sitting in the chip, to avoid spuriously * setting it multiple times after it has been cleared * during a read. */ if (ext_status_1 & DATA_IN_STATUS_BIT) set_bit(RECEIVED_END_BN, &nec_priv->state); } else { clear_bit(RECEIVED_END_BN, &nec_priv->state); } if ((fifo_status & TX_FIFO_HALF_EMPTY_INTERRUPT_IS_ENABLED) && (fifo_status & TX_FIFO_HALF_EMPTY)) { /* * We really only want to clear the * TX_FIFO_HALF_EMPTY_INTERRUPT_ENABLE bit in the * FIFO_CONTROL_STATUS_REG. Since we are not being * careful, this also has a side effect of disabling * DMA requests and the RX fifo interrupt. That is * fine though, since they should never be in use at * the same time as the TX fifo interrupt. */ fifos_write(priv, 0x0, FIFO_CONTROL_STATUS_REG); retval = IRQ_HANDLED; } if ((fifo_status & RX_FIFO_HALF_FULL_INTERRUPT_IS_ENABLED) && (fifo_status & RX_FIFO_HALF_FULL)) { /* * We really only want to clear the * RX_FIFO_HALF_FULL_INTERRUPT_ENABLE bit in the * FIFO_CONTROL_STATUS_REG. Since we are not being * careful, this also has a side effect of disabling * DMA requests and the TX fifo interrupt. That is * fine though, since they should never be in use at * the same time as the RX fifo interrupt. */ fifos_write(priv, 0x0, FIFO_CONTROL_STATUS_REG); retval = IRQ_HANDLED; } if (retval == IRQ_HANDLED) wake_up_interruptible(&board->wait); return retval; } irqreturn_t fmh_gpib_interrupt(int irq, void *arg) { struct gpib_board *board = arg; unsigned long flags; irqreturn_t retval; spin_lock_irqsave(&board->spinlock, flags); retval = fmh_gpib_internal_interrupt(board); spin_unlock_irqrestore(&board->spinlock, flags); return retval; } static int fmh_gpib_allocate_private(struct gpib_board *board) { struct fmh_priv *priv; board->private_data = kmalloc(sizeof(struct fmh_priv), GFP_KERNEL); if (!board->private_data) return -ENOMEM; priv = board->private_data; memset(priv, 0, sizeof(struct fmh_priv)); init_nec7210_private(&priv->nec7210_priv); priv->dma_buffer_size = 0x800; priv->dma_buffer = kmalloc(priv->dma_buffer_size, GFP_KERNEL); if (!priv->dma_buffer) return -ENOMEM; return 0; } static void fmh_gpib_generic_detach(struct gpib_board *board) { if (board->private_data) { struct fmh_priv *e_priv = board->private_data; kfree(e_priv->dma_buffer); kfree(board->private_data); board->private_data = NULL; } if (board->dev) dev_set_drvdata(board->dev, NULL); } // generic part of attach functions static int fmh_gpib_generic_attach(struct gpib_board *board) { struct fmh_priv *e_priv; struct nec7210_priv *nec_priv; int retval; board->status = 0; retval = fmh_gpib_allocate_private(board); if (retval < 0) return retval; e_priv = board->private_data; nec_priv = &e_priv->nec7210_priv; nec_priv->read_byte = gpib_cs_read_byte; nec_priv->write_byte = gpib_cs_write_byte; nec_priv->offset = 1; nec_priv->type = CB7210; return 0; } static int fmh_gpib_config_dma(struct gpib_board *board, int output) { struct fmh_priv *e_priv = board->private_data; struct dma_slave_config config; config.device_fc = true; if (e_priv->dma_burst_length < 1) { config.src_maxburst = 1; config.dst_maxburst = 1; } else { config.src_maxburst = e_priv->dma_burst_length; config.dst_maxburst = e_priv->dma_burst_length; } config.src_addr_width = 1; config.dst_addr_width = 1; if (output) { config.direction = DMA_MEM_TO_DEV; config.src_addr = 0; config.dst_addr = e_priv->dma_port_res->start + FIFO_DATA_REG * fifo_reg_offset; } else { config.direction = DMA_DEV_TO_MEM; config.src_addr = e_priv->dma_port_res->start + FIFO_DATA_REG * fifo_reg_offset; config.dst_addr = 0; } return dmaengine_slave_config(e_priv->dma_channel, &config); } static int fmh_gpib_init(struct fmh_priv *e_priv, struct gpib_board *board, int handshake_mode) { struct nec7210_priv *nec_priv = &e_priv->nec7210_priv; unsigned long flags; unsigned int fifo_status_bits; fifos_write(e_priv, RX_FIFO_CLEAR | TX_FIFO_CLEAR, FIFO_CONTROL_STATUS_REG); nec7210_board_reset(nec_priv, board); write_byte(nec_priv, AUX_LO_SPEED, AUXMR); nec7210_set_handshake_mode(board, nec_priv, handshake_mode); /* Hueristically check if hardware supports fifo half full/empty interrupts */ fifo_status_bits = fifos_read(e_priv, FIFO_CONTROL_STATUS_REG); e_priv->supports_fifo_interrupts = (fifo_status_bits & TX_FIFO_EMPTY) && (fifo_status_bits & TX_FIFO_HALF_EMPTY); nec7210_board_online(nec_priv, board); write_byte(nec_priv, IFC_INTERRUPT_ENABLE_BIT | ATN_INTERRUPT_ENABLE_BIT, ISR0_IMR0_REG); spin_lock_irqsave(&board->spinlock, flags); write_byte(nec_priv, AUX_RFD_HOLDOFF_ASAP, AUXMR); set_bit(RFD_HOLDOFF_BN, &nec_priv->state); spin_unlock_irqrestore(&board->spinlock, flags); return 0; } /* Match callback for driver_find_device */ static int fmh_gpib_device_match(struct device *dev, const void *data) { const struct gpib_board_config *config = data; if (dev_get_drvdata(dev)) return 0; if (gpib_match_device_path(dev, config->device_path) == 0) return 0; // driver doesn't support selection by serial number if (config->serial_number) return 0; dev_dbg(dev, "matched: %s\n", of_node_full_name(dev_of_node((dev)))); return 1; } static int fmh_gpib_attach_impl(struct gpib_board *board, const struct gpib_board_config *config, unsigned int handshake_mode, int acquire_dma) { struct fmh_priv *e_priv; struct nec7210_priv *nec_priv; int retval; int irq; struct resource *res; struct platform_device *pdev; board->dev = driver_find_device(&fmh_gpib_platform_driver.driver, NULL, (const void *)config, &fmh_gpib_device_match); if (!board->dev) { dev_err(board->gpib_dev, "No matching fmh_gpib_core device was found, attach failed."); return -ENODEV; } // currently only used to mark the device as already attached dev_set_drvdata(board->dev, board); pdev = to_platform_device(board->dev); retval = fmh_gpib_generic_attach(board); if (retval) return retval; e_priv = board->private_data; nec_priv = &e_priv->nec7210_priv; res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "gpib_control_status"); if (!res) { dev_err(board->dev, "Unable to locate mmio resource\n"); return -ENODEV; } if (request_mem_region(res->start, resource_size(res), pdev->name) == NULL) { dev_err(board->dev, "cannot claim registers\n"); return -ENXIO; } e_priv->gpib_iomem_res = res; nec_priv->mmiobase = ioremap(e_priv->gpib_iomem_res->start, resource_size(e_priv->gpib_iomem_res)); if (!nec_priv->mmiobase) { dev_err(board->dev, "Could not map I/O memory\n"); return -ENOMEM; } dev_dbg(board->dev, "iobase %pr remapped to %p\n", e_priv->gpib_iomem_res, nec_priv->mmiobase); res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "dma_fifos"); if (!res) { dev_err(board->dev, "Unable to locate mmio resource for gpib dma port\n"); return -ENODEV; } if (request_mem_region(res->start, resource_size(res), pdev->name) == NULL) { dev_err(board->dev, "cannot claim registers\n"); return -ENXIO; } e_priv->dma_port_res = res; e_priv->fifo_base = ioremap(e_priv->dma_port_res->start, resource_size(e_priv->dma_port_res)); if (!e_priv->fifo_base) { dev_err(board->dev, "Could not map I/O memory for fifos\n"); return -ENOMEM; } dev_dbg(board->dev, "dma fifos 0x%lx remapped to %p, length=%ld\n", (unsigned long)e_priv->dma_port_res->start, e_priv->fifo_base, (unsigned long)resource_size(e_priv->dma_port_res)); irq = platform_get_irq(pdev, 0); if (irq < 0) return -EBUSY; retval = request_irq(irq, fmh_gpib_interrupt, IRQF_SHARED, pdev->name, board); if (retval) { dev_err(board->dev, "cannot register interrupt handler err=%d\n", retval); return retval; } e_priv->irq = irq; if (acquire_dma) { e_priv->dma_channel = dma_request_slave_channel(board->dev, "rxtx"); if (!e_priv->dma_channel) { dev_err(board->dev, "failed to acquire dma channel \"rxtx\".\n"); return -EIO; } } /* * in the future we might want to know the half-fifo size * (dma_burst_length) even when not using dma, so go ahead an * initialize it unconditionally. */ e_priv->dma_burst_length = fifos_read(e_priv, FIFO_MAX_BURST_LENGTH_REG) & fifo_max_burst_length_mask; return fmh_gpib_init(e_priv, board, handshake_mode); } int fmh_gpib_attach_holdoff_all(struct gpib_board *board, const struct gpib_board_config *config) { return fmh_gpib_attach_impl(board, config, HR_HLDA, 0); } int fmh_gpib_attach_holdoff_end(struct gpib_board *board, const struct gpib_board_config *config) { return fmh_gpib_attach_impl(board, config, HR_HLDE, 1); } void fmh_gpib_detach(struct gpib_board *board) { struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv; if (e_priv) { if (e_priv->dma_channel) dma_release_channel(e_priv->dma_channel); nec_priv = &e_priv->nec7210_priv; if (e_priv->irq) free_irq(e_priv->irq, board); if (e_priv->fifo_base) fifos_write(e_priv, 0, FIFO_CONTROL_STATUS_REG); if (nec_priv->mmiobase) { write_byte(nec_priv, 0, ISR0_IMR0_REG); nec7210_board_reset(nec_priv, board); } if (e_priv->fifo_base) iounmap(e_priv->fifo_base); if (nec_priv->mmiobase) iounmap(nec_priv->mmiobase); if (e_priv->dma_port_res) { release_mem_region(e_priv->dma_port_res->start, resource_size(e_priv->dma_port_res)); } if (e_priv->gpib_iomem_res) release_mem_region(e_priv->gpib_iomem_res->start, resource_size(e_priv->gpib_iomem_res)); } fmh_gpib_generic_detach(board); if (board->dev) { put_device(board->dev); board->dev = NULL; } } static int fmh_gpib_pci_attach_impl(struct gpib_board *board, const struct gpib_board_config *config, unsigned int handshake_mode) { struct fmh_priv *e_priv; struct nec7210_priv *nec_priv; int retval; struct pci_dev *pci_device; retval = fmh_gpib_generic_attach(board); if (retval) return retval; e_priv = board->private_data; nec_priv = &e_priv->nec7210_priv; // find board pci_device = gpib_pci_get_device(config, BOGUS_PCI_VENDOR_ID_FLUKE, BOGUS_PCI_DEVICE_ID_FLUKE_BLADERUNNER, NULL); if (!pci_device) { dev_err(board->gpib_dev, "No matching fmh_gpib_core pci device was found, attach failed."); return -ENODEV; } board->dev = &pci_device->dev; // bladerunner prototype has offset of 4 between gpib control/status registers nec_priv->offset = 4; if (pci_enable_device(pci_device)) { dev_err(board->dev, "error enabling pci device\n"); return -EIO; } if (pci_request_regions(pci_device, KBUILD_MODNAME)) { dev_err(board->dev, "pci_request_regions failed\n"); return -EIO; } e_priv->gpib_iomem_res = &pci_device->resource[gpib_control_status_pci_resource_index]; e_priv->dma_port_res = &pci_device->resource[gpib_fifo_pci_resource_index]; nec_priv->mmiobase = ioremap(pci_resource_start(pci_device, gpib_control_status_pci_resource_index), pci_resource_len(pci_device, gpib_control_status_pci_resource_index)); dev_dbg(board->dev, "base address for gpib control/status registers remapped to 0x%p\n", nec_priv->mmiobase); if (e_priv->dma_port_res->flags & IORESOURCE_MEM) { e_priv->fifo_base = ioremap(pci_resource_start(pci_device, gpib_fifo_pci_resource_index), pci_resource_len(pci_device, gpib_fifo_pci_resource_index)); dev_dbg(board->dev, "base address for gpib fifo registers remapped to 0x%p\n", e_priv->fifo_base); } else { e_priv->fifo_base = NULL; dev_dbg(board->dev, "hardware has no gpib fifo registers.\n"); } if (pci_device->irq) { retval = request_irq(pci_device->irq, fmh_gpib_interrupt, IRQF_SHARED, KBUILD_MODNAME, board); if (retval) { dev_err(board->dev, "cannot register interrupt handler err=%d\n", retval); return retval; } } e_priv->irq = pci_device->irq; e_priv->dma_burst_length = fifos_read(e_priv, FIFO_MAX_BURST_LENGTH_REG) & fifo_max_burst_length_mask; return fmh_gpib_init(e_priv, board, handshake_mode); } int fmh_gpib_pci_attach_holdoff_all(struct gpib_board *board, const struct gpib_board_config *config) { return fmh_gpib_pci_attach_impl(board, config, HR_HLDA); } int fmh_gpib_pci_attach_holdoff_end(struct gpib_board *board, const struct gpib_board_config *config) { int retval; struct fmh_priv *e_priv; retval = fmh_gpib_pci_attach_impl(board, config, HR_HLDE); e_priv = board->private_data; if (retval == 0 && e_priv && e_priv->supports_fifo_interrupts == 0) { dev_err(board->gpib_dev, "your fmh_gpib_core does not appear to support fifo interrupts. Try the fmh_gpib_pci_unaccel board type instead."); return -EIO; } return retval; } void fmh_gpib_pci_detach(struct gpib_board *board) { struct fmh_priv *e_priv = board->private_data; struct nec7210_priv *nec_priv; if (e_priv) { nec_priv = &e_priv->nec7210_priv; if (e_priv->irq) free_irq(e_priv->irq, board); if (e_priv->fifo_base) fifos_write(e_priv, 0, FIFO_CONTROL_STATUS_REG); if (nec_priv->mmiobase) { write_byte(nec_priv, 0, ISR0_IMR0_REG); nec7210_board_reset(nec_priv, board); } if (e_priv->fifo_base) iounmap(e_priv->fifo_base); if (nec_priv->mmiobase) iounmap(nec_priv->mmiobase); if (e_priv->dma_port_res || e_priv->gpib_iomem_res) pci_release_regions(to_pci_dev(board->dev)); if (board->dev) pci_dev_put(to_pci_dev(board->dev)); } fmh_gpib_generic_detach(board); } static int fmh_gpib_platform_probe(struct platform_device *pdev) { return 0; } static const struct of_device_id fmh_gpib_of_match[] = { { .compatible = "fmhess,fmh_gpib_core"}, { {0} } }; MODULE_DEVICE_TABLE(of, fmh_gpib_of_match); static struct platform_driver fmh_gpib_platform_driver = { .driver = { .name = DRV_NAME, .of_match_table = fmh_gpib_of_match, }, .probe = &fmh_gpib_platform_probe }; static int fmh_gpib_pci_probe(struct pci_dev *dev, const struct pci_device_id *id) { return 0; } static const struct pci_device_id fmh_gpib_pci_match[] = { { BOGUS_PCI_VENDOR_ID_FLUKE, BOGUS_PCI_DEVICE_ID_FLUKE_BLADERUNNER, 0, 0, 0 }, { 0 } }; MODULE_DEVICE_TABLE(pci, fmh_gpib_pci_match); static struct pci_driver fmh_gpib_pci_driver = { .name = DRV_NAME, .id_table = fmh_gpib_pci_match, .probe = &fmh_gpib_pci_probe }; static int __init fmh_gpib_init_module(void) { int result; result = platform_driver_register(&fmh_gpib_platform_driver); if (result) { pr_err("platform_driver_register failed: error = %d\n", result); return result; } result = pci_register_driver(&fmh_gpib_pci_driver); if (result) { pr_err("pci_register_driver failed: error = %d\n", result); goto err_pci_driver; } result = gpib_register_driver(&fmh_gpib_unaccel_interface, THIS_MODULE); if (result) { pr_err("gpib_register_driver failed: error = %d\n", result); goto err_unaccel; } result = gpib_register_driver(&fmh_gpib_interface, THIS_MODULE); if (result) { pr_err("gpib_register_driver failed: error = %d\n", result); goto err_interface; } result = gpib_register_driver(&fmh_gpib_pci_unaccel_interface, THIS_MODULE); if (result) { pr_err("gpib_register_driver failed: error = %d\n", result); goto err_pci_unaccel; } result = gpib_register_driver(&fmh_gpib_pci_interface, THIS_MODULE); if (result) { pr_err("gpib_register_driver failed: error = %d\n", result); goto err_pci; } return 0; err_pci: gpib_unregister_driver(&fmh_gpib_pci_unaccel_interface); err_pci_unaccel: gpib_unregister_driver(&fmh_gpib_interface); err_interface: gpib_unregister_driver(&fmh_gpib_unaccel_interface); err_unaccel: pci_unregister_driver(&fmh_gpib_pci_driver); err_pci_driver: platform_driver_unregister(&fmh_gpib_platform_driver); return result; } static void __exit fmh_gpib_exit_module(void) { gpib_unregister_driver(&fmh_gpib_pci_interface); gpib_unregister_driver(&fmh_gpib_pci_unaccel_interface); gpib_unregister_driver(&fmh_gpib_unaccel_interface); gpib_unregister_driver(&fmh_gpib_interface); pci_unregister_driver(&fmh_gpib_pci_driver); platform_driver_unregister(&fmh_gpib_platform_driver); } module_init(fmh_gpib_init_module); module_exit(fmh_gpib_exit_module);
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