/* * hsi_driver_dma.c * * Implements HSI low level interface driver functionality with DMA support. * * Copyright (C) 2007-2008 Nokia Corporation. All rights reserved. * Copyright (C) 2009 Texas Instruments, Inc. * * Author: Carlos Chinea * Author: Sebastien JAN * * This package is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 as * published by the Free Software Foundation. * * THIS PACKAGE IS PROVIDED ``AS IS'' AND WITHOUT ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED * WARRANTIES OF MERCHANTIBILITY AND FITNESS FOR A PARTICULAR PURPOSE. */ #include #include "hsi_driver.h" #define HSI_SYNC_WRITE 0 #define HSI_SYNC_READ 1 #define HSI_L3_TPUT 13428 /* 13428 KiB/s => ~110 Mbit/s */ static unsigned char hsi_sync_table[2][2][8] = { { {0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08}, {0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x00} }, { {0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17}, {0x18, 0x19, 0x1a, 0x1b, 0x1c, 0x1d, 0x1e, 0x1f} } }; /** * hsi_is_dma_read_int_pending - Indicates if a DMA read interrupt is pending * @hsi_ctrl - HSI controller of the GDD. * * Needs to be called holding the hsi_controller lock * * Returns true if DMA read interrupt is pending, else false */ bool hsi_is_dma_read_int_pending(struct hsi_dev *hsi_ctrl) { void __iomem *base = hsi_ctrl->base; unsigned int gdd_lch = 0; u32 status_reg = 0; int i, j; status_reg = hsi_inl(base, HSI_SYS_GDD_MPU_IRQ_STATUS_REG); status_reg &= hsi_inl(base, HSI_SYS_GDD_MPU_IRQ_ENABLE_REG); if (!status_reg) return false; /* Scan all enabled DMA channels */ for (gdd_lch = 0; gdd_lch < hsi_ctrl->gdd_chan_count; gdd_lch++) { if (!(status_reg & HSI_GDD_LCH(gdd_lch))) continue; for (i = 0; i < hsi_ctrl->max_p; i++) for (j = 0; j < hsi_ctrl->hsi_port[i].max_ch; j++) if (hsi_ctrl->hsi_port[i]. hsi_channel[j].read_data.lch == gdd_lch) return true; } return false; } /** * hsi_get_free_lch - Get a free GDD(DMA) logical channel * @hsi_ctrl - HSI controller of the GDD. * * Needs to be called holding the hsi_controller lock * * Returns the logical channel number, or -EBUSY if none available */ static int hsi_get_free_lch(struct hsi_dev *hsi_ctrl) { unsigned int enable_reg; int i, lch; enable_reg = hsi_inl(hsi_ctrl->base, HSI_SYS_GDD_MPU_IRQ_ENABLE_REG); lch = hsi_ctrl->last_gdd_lch; for (i = 0; i < hsi_ctrl->gdd_chan_count; i++) { if (++lch >= hsi_ctrl->gdd_chan_count) lch = 0; if ((enable_reg & HSI_GDD_LCH(lch)) == 0) { hsi_ctrl->last_gdd_lch = lch; return lch; } } return -EBUSY; } /** * hsi_driver_write_dma - Program GDD [DMA] to write data from memory to * the hsi channel buffer. * @hsi_channel - pointer to the hsi_channel to write data to. * @data - 32-bit word pointer to the data. * @size - Number of 32bit words to be transfered. * * hsi_controller lock must be held before calling this function. * * Return 0 on success and < 0 on error. */ int hsi_driver_write_dma(struct hsi_channel *hsi_channel, u32 * data, unsigned int size) { struct hsi_dev *hsi_ctrl = hsi_channel->hsi_port->hsi_controller; void __iomem *base = hsi_ctrl->base; unsigned int port = hsi_channel->hsi_port->port_number; unsigned int channel = hsi_channel->channel_number; unsigned int sync; int lch; dma_addr_t src_addr; dma_addr_t dest_addr; u16 tmp; int fifo; if ((size < 1) || (data == NULL)) return -EINVAL; lch = hsi_get_free_lch(hsi_ctrl); if (lch < 0) { dev_err(hsi_ctrl->dev, "No free DMA channels.\n"); return -EBUSY; /* No free GDD logical channels. */ } else { dev_dbg(hsi_ctrl->dev, "Allocated DMA channel %d for write on" " HSI channel %d.\n", lch, hsi_channel->channel_number); } /* NOTE: Getting a free gdd logical channel and * reserve it must be done atomicaly. */ hsi_channel->write_data.lch = lch; /* Sync is required for SSI but not for HSI */ sync = hsi_sync_table[HSI_SYNC_WRITE][port - 1][channel]; src_addr = dma_map_single(hsi_ctrl->dev, data, size * 4, DMA_TO_DEVICE); if (unlikely(dma_mapping_error(hsi_ctrl->dev, src_addr))) { dev_err(hsi_ctrl->dev, "Failed to create DMA write mapping.\n"); return -ENOMEM; } tmp = HSI_SRC_BURST_4x32_BIT| HSI_SRC_MEMORY_PORT | HSI_DST_BURST_4x32_BIT | HSI_DST_PERIPHERAL_PORT | HSI_DATA_TYPE_S32; hsi_outw(tmp, base, HSI_GDD_CSDP_REG(lch)); tmp = HSI_SRC_AMODE_POSTINC | HSI_DST_AMODE_CONST | sync; hsi_outw(tmp, base, HSI_GDD_CCR_REG(lch)); hsi_outw((HSI_BLOCK_IE | HSI_TOUT_IE), base, HSI_GDD_CCIR_REG(lch)); if (hsi_driver_device_is_hsi(to_platform_device(hsi_ctrl->dev))) { fifo = hsi_fifo_get_id(hsi_ctrl, channel, port); if (unlikely(fifo < 0)) { dev_err(hsi_ctrl->dev, "No valid FIFO id for DMA " "transfer to FIFO.\n"); return -EFAULT; } /* HSI CDSA register takes a FIFO ID when copying to FIFO */ hsi_outl(fifo, base, HSI_GDD_CDSA_REG(lch)); } else { dest_addr = hsi_ctrl->phy_base + HSI_HST_BUFFER_CH_REG(port, channel); /* SSI CDSA register always takes a 32-bit address */ hsi_outl(dest_addr, base, HSI_GDD_CDSA_REG(lch)); } /* HSI CSSA register takes a 32-bit address when copying from memory */ /* SSI CSSA register always takes a 32-bit address */ hsi_outl(src_addr, base, HSI_GDD_CSSA_REG(lch)); hsi_outw(size, base, HSI_GDD_CEN_REG(lch)); /* TODO : Need to clean interrupt status here to avoid spurious int */ hsi_outl_or(HSI_GDD_LCH(lch), base, HSI_SYS_GDD_MPU_IRQ_ENABLE_REG); hsi_outw_or(HSI_CCR_ENABLE, base, HSI_GDD_CCR_REG(lch)); return 0; } /** * hsi_driver_read_dma - Program GDD [DMA] to write data to memory from * the hsi channel buffer. * @hsi_channel - pointer to the hsi_channel to read data from. * @data - 32-bit word pointer where to store the incoming data. * @size - Number of 32bit words to be transfered to the buffer. * * hsi_controller lock must be held before calling this function. * * Return 0 on success and < 0 on error. */ int hsi_driver_read_dma(struct hsi_channel *hsi_channel, u32 * data, unsigned int count) { struct hsi_dev *hsi_ctrl = hsi_channel->hsi_port->hsi_controller; void __iomem *base = hsi_ctrl->base; unsigned int port = hsi_channel->hsi_port->port_number; unsigned int channel = hsi_channel->channel_number; unsigned int sync; int lch; dma_addr_t src_addr; dma_addr_t dest_addr; u16 tmp; int fifo; lch = hsi_get_free_lch(hsi_ctrl); if (lch < 0) { dev_err(hsi_ctrl->dev, "No free DMA channels.\n"); return -EBUSY; /* No free GDD logical channels. */ } else { dev_dbg(hsi_ctrl->dev, "Allocated DMA channel %d for read on" " HSI channel %d.\n", lch, hsi_channel->channel_number); } /* When DMA is used for Rx, disable the Rx Interrupt. * (else DATAAVAILLABLE event would get triggered on first * received data word) * (Rx interrupt might be active for polling feature) */ hsi_driver_disable_read_interrupt(hsi_channel); /* * NOTE: Gettting a free gdd logical channel and * reserve it must be done atomicaly. */ hsi_channel->read_data.lch = lch; /* Sync is required for SSI but not for HSI */ sync = hsi_sync_table[HSI_SYNC_READ][port - 1][channel]; dest_addr = dma_map_single(hsi_ctrl->dev, data, count * 4, DMA_FROM_DEVICE); if (unlikely(dma_mapping_error(hsi_ctrl->dev, dest_addr))) { dev_err(hsi_ctrl->dev, "Failed to create DMA read mapping.\n"); return -ENOMEM; } tmp = HSI_DST_BURST_4x32_BIT | HSI_DST_MEMORY_PORT | HSI_SRC_BURST_4x32_BIT | HSI_SRC_PERIPHERAL_PORT | HSI_DATA_TYPE_S32; hsi_outw(tmp, base, HSI_GDD_CSDP_REG(lch)); tmp = HSI_DST_AMODE_POSTINC | HSI_SRC_AMODE_CONST | sync; hsi_outw(tmp, base, HSI_GDD_CCR_REG(lch)); hsi_outw((HSI_BLOCK_IE | HSI_TOUT_IE), base, HSI_GDD_CCIR_REG(lch)); if (hsi_driver_device_is_hsi(to_platform_device(hsi_ctrl->dev))) { fifo = hsi_fifo_get_id(hsi_ctrl, channel, port); if (unlikely(fifo < 0)) { dev_err(hsi_ctrl->dev, "No valid FIFO id for DMA " "transfer from FIFO.\n"); return -EFAULT; } /* HSI CSSA register takes a FIFO ID when copying from FIFO */ hsi_outl(fifo, base, HSI_GDD_CSSA_REG(lch)); } else{ src_addr = hsi_ctrl->phy_base + HSI_HSR_BUFFER_CH_REG(port, channel); /* SSI CSSA register always takes a 32-bit address */ hsi_outl(src_addr, base, HSI_GDD_CSSA_REG(lch)); } /* HSI CDSA register takes a 32-bit address when copying to memory */ /* SSI CDSA register always takes a 32-bit address */ hsi_outl(dest_addr, base, HSI_GDD_CDSA_REG(lch)); hsi_outw(count, base, HSI_GDD_CEN_REG(lch)); /* TODO : Need to clean interrupt status here to avoid spurious int */ hsi_outl_or(HSI_GDD_LCH(lch), base, HSI_SYS_GDD_MPU_IRQ_ENABLE_REG); hsi_outw_or(HSI_CCR_ENABLE, base, HSI_GDD_CCR_REG(lch)); return 0; } /** * hsi_driver_cancel_write_dma - Cancel an ongoing GDD [DMA] write for the * specified hsi channel. * @hsi_ch - pointer to the hsi_channel to cancel DMA write. * * hsi_controller lock must be held before calling this function. * * Return: -ENXIO : No DMA channel found for specified HSI channel * -ECANCELED : DMA cancel success, data not transfered to TX FIFO * 0 : DMA transfer is already over, data already transfered to TX FIFO * * Note: whatever returned value, write callback will not be called after * write cancel. */ int hsi_driver_cancel_write_dma(struct hsi_channel *hsi_ch) { int lch = hsi_ch->write_data.lch; unsigned int port = hsi_ch->hsi_port->port_number; unsigned int channel = hsi_ch->channel_number; struct hsi_dev *hsi_ctrl = hsi_ch->hsi_port->hsi_controller; u16 ccr, gdd_csr; long buff_offset; u32 status_reg; dma_addr_t dma_h; size_t size; if (lch < 0) { dev_err(&hsi_ch->dev->device, "No DMA channel found for HSI " "channel %d\n", hsi_ch->channel_number); return -ENXIO; } ccr = hsi_inw(hsi_ctrl->base, HSI_GDD_CCR_REG(lch)); if (!(ccr & HSI_CCR_ENABLE)) { dev_dbg(&hsi_ch->dev->device, "Write cancel on not " "enabled logical channel %d CCR REG 0x%04X\n", lch, ccr); } status_reg = hsi_inl(hsi_ctrl->base, HSI_SYS_GDD_MPU_IRQ_STATUS_REG); status_reg &= hsi_inl(hsi_ctrl->base, HSI_SYS_GDD_MPU_IRQ_ENABLE_REG); hsi_outw_and(~HSI_CCR_ENABLE, hsi_ctrl->base, HSI_GDD_CCR_REG(lch)); /* Clear CSR register by reading it, as it is cleared automaticaly */ /* by HW after SW read. */ gdd_csr = hsi_inw(hsi_ctrl->base, HSI_GDD_CSR_REG(lch)); hsi_outl_and(~HSI_GDD_LCH(lch), hsi_ctrl->base, HSI_SYS_GDD_MPU_IRQ_ENABLE_REG); hsi_outl(HSI_GDD_LCH(lch), hsi_ctrl->base, HSI_SYS_GDD_MPU_IRQ_STATUS_REG); /* Unmap DMA region */ dma_h = hsi_inl(hsi_ctrl->base, HSI_GDD_CSSA_REG(lch)); size = hsi_inw(hsi_ctrl->base, HSI_GDD_CEN_REG(lch)) * 4; dma_unmap_single(hsi_ctrl->dev, dma_h, size, DMA_TO_DEVICE); buff_offset = hsi_hst_bufstate_f_reg(hsi_ctrl, port, channel); if (buff_offset >= 0) hsi_outl_and(~HSI_BUFSTATE_CHANNEL(channel), hsi_ctrl->base, buff_offset); hsi_reset_ch_write(hsi_ch); return status_reg & HSI_GDD_LCH(lch) ? 0 : -ECANCELED; } /** * hsi_driver_cancel_read_dma - Cancel an ongoing GDD [DMA] read for the * specified hsi channel. * @hsi_ch - pointer to the hsi_channel to cancel DMA read. * * hsi_controller lock must be held before calling this function. * * Return: -ENXIO : No DMA channel found for specified HSI channel * -ECANCELED : DMA cancel success, data not available at expected * address. * 0 : DMA transfer is already over, data already available at * expected address. * * Note: whatever returned value, read callback will not be called after cancel. */ int hsi_driver_cancel_read_dma(struct hsi_channel *hsi_ch) { int lch = hsi_ch->read_data.lch; struct hsi_dev *hsi_ctrl = hsi_ch->hsi_port->hsi_controller; u16 ccr, gdd_csr; u32 status_reg; dma_addr_t dma_h; size_t size; /* Re-enable interrupts for polling if needed */ if (hsi_ch->flags & HSI_CH_RX_POLL) hsi_driver_enable_read_interrupt(hsi_ch, NULL); if (lch < 0) { dev_err(&hsi_ch->dev->device, "No DMA channel found for HSI " "channel %d\n", hsi_ch->channel_number); return -ENXIO; } ccr = hsi_inw(hsi_ctrl->base, HSI_GDD_CCR_REG(lch)); if (!(ccr & HSI_CCR_ENABLE)) { dev_dbg(&hsi_ch->dev->device, "Read cancel on not " "enabled logical channel %d CCR REG 0x%04X\n", lch, ccr); } status_reg = hsi_inl(hsi_ctrl->base, HSI_SYS_GDD_MPU_IRQ_STATUS_REG); status_reg &= hsi_inl(hsi_ctrl->base, HSI_SYS_GDD_MPU_IRQ_ENABLE_REG); hsi_outw_and(~HSI_CCR_ENABLE, hsi_ctrl->base, HSI_GDD_CCR_REG(lch)); /* Clear CSR register by reading it, as it is cleared automaticaly */ /* by HW after SW read */ gdd_csr = hsi_inw(hsi_ctrl->base, HSI_GDD_CSR_REG(lch)); hsi_outl_and(~HSI_GDD_LCH(lch), hsi_ctrl->base, HSI_SYS_GDD_MPU_IRQ_ENABLE_REG); hsi_outl(HSI_GDD_LCH(lch), hsi_ctrl->base, HSI_SYS_GDD_MPU_IRQ_STATUS_REG); /* Unmap DMA region - Access to the buffer is now safe */ dma_h = hsi_inl(hsi_ctrl->base, HSI_GDD_CDSA_REG(lch)); size = hsi_inw(hsi_ctrl->base, HSI_GDD_CEN_REG(lch)) * 4; dma_unmap_single(hsi_ctrl->dev, dma_h, size, DMA_FROM_DEVICE); hsi_reset_ch_read(hsi_ch); return status_reg & HSI_GDD_LCH(lch) ? 0 : -ECANCELED; } /** * hsi_get_info_from_gdd_lch - Retrieve channels information from DMA channel * @hsi_ctrl - HSI device control structure * @lch - DMA logical channel * @port - HSI port * @channel - HSI channel * @is_read_path - channel is used for reading * * Updates the port, channel and is_read_path parameters depending on the * lch DMA channel status. * * Return 0 on success and < 0 on error. */ int hsi_get_info_from_gdd_lch(struct hsi_dev *hsi_ctrl, unsigned int lch, unsigned int *port, unsigned int *channel, unsigned int *is_read_path) { int i, j; int err = -1; for (i = 0; i < hsi_ctrl->max_p; i++) for (j = 0; j < hsi_ctrl->hsi_port[i].max_ch; j++) if (hsi_ctrl->hsi_port[i]. hsi_channel[j].read_data.lch == lch) { *is_read_path = 1; *port = i + 1; *channel = j; err = 0; goto get_info_bk; } else if (hsi_ctrl->hsi_port[i]. hsi_channel[j].write_data.lch == lch) { *is_read_path = 0; *port = i + 1; *channel = j; err = 0; goto get_info_bk; } get_info_bk: return err; } static void do_hsi_gdd_lch(struct hsi_dev *hsi_ctrl, unsigned int gdd_lch) { void __iomem *base = hsi_ctrl->base; struct platform_device *pdev = to_platform_device(hsi_ctrl->dev); struct hsi_channel *ch; unsigned int port; unsigned int channel; unsigned int is_read_path; u32 gdd_csr; dma_addr_t dma_h; size_t size; int fifo, fifo_words_avail; if (hsi_get_info_from_gdd_lch(hsi_ctrl, gdd_lch, &port, &channel, &is_read_path) < 0) { dev_err(hsi_ctrl->dev, "Unable to match the DMA channel %d with" " an HSI channel\n", gdd_lch); return; } else { dev_dbg(hsi_ctrl->dev, "DMA event on gdd_lch=%d => port=%d, " "channel=%d, read=%d\n", gdd_lch, port, channel, is_read_path); } hsi_outl_and(~HSI_GDD_LCH(gdd_lch), base, HSI_SYS_GDD_MPU_IRQ_ENABLE_REG); /* Warning : CSR register is cleared automaticaly by HW after SW read */ gdd_csr = hsi_inw(base, HSI_GDD_CSR_REG(gdd_lch)); if (!(gdd_csr & HSI_CSR_TOUT)) { if (is_read_path) { /* Read path */ dma_h = hsi_inl(base, HSI_GDD_CDSA_REG(gdd_lch)); size = hsi_inw(base, HSI_GDD_CEN_REG(gdd_lch)) * 4; dma_sync_single_for_cpu(hsi_ctrl->dev, dma_h, size, DMA_FROM_DEVICE); dma_unmap_single(hsi_ctrl->dev, dma_h, size, DMA_FROM_DEVICE); ch = hsi_ctrl_get_ch(hsi_ctrl, port, channel); hsi_reset_ch_read(ch); dev_dbg(hsi_ctrl->dev, "Calling ch %d read callback " "(size %d).\n", channel, size/4); spin_unlock(&hsi_ctrl->lock); ch->read_done(ch->dev, size / 4); spin_lock(&hsi_ctrl->lock); /* Check if FIFO is correctly emptied */ if (hsi_driver_device_is_hsi(pdev)) { fifo = hsi_fifo_get_id(hsi_ctrl, channel, port); if (unlikely(fifo < 0)) { dev_err(hsi_ctrl->dev, "No valid FIFO " "id found for channel %d.\n", channel); return; } fifo_words_avail = hsi_get_rx_fifo_occupancy(hsi_ctrl, fifo); if (fifo_words_avail) dev_dbg(hsi_ctrl->dev, "FIFO %d not empty " "after DMA copy, remaining " "%d/%d frames\n", fifo, fifo_words_avail, HSI_HSR_FIFO_SIZE); } /* Re-enable interrupts for polling if needed */ if (ch->flags & HSI_CH_RX_POLL) hsi_driver_enable_read_interrupt(ch, NULL); } else { /* Write path */ dma_h = hsi_inl(base, HSI_GDD_CSSA_REG(gdd_lch)); size = hsi_inw(base, HSI_GDD_CEN_REG(gdd_lch)) * 4; dma_unmap_single(hsi_ctrl->dev, dma_h, size, DMA_TO_DEVICE); ch = hsi_ctrl_get_ch(hsi_ctrl, port, channel); hsi_reset_ch_write(ch); dev_dbg(hsi_ctrl->dev, "Calling ch %d write callback " "(size %d).\n", channel, size/4); spin_unlock(&hsi_ctrl->lock); ch->write_done(ch->dev, size / 4); spin_lock(&hsi_ctrl->lock); } } else { dev_err(hsi_ctrl->dev, "Time-out overflow Error on GDD transfer" " on gdd channel %d\n", gdd_lch); spin_unlock(&hsi_ctrl->lock); /* TODO : need to perform a DMA soft reset */ hsi_port_event_handler(&hsi_ctrl->hsi_port[port - 1], HSI_EVENT_ERROR, NULL); spin_lock(&hsi_ctrl->lock); } } static u32 hsi_process_dma_event(struct hsi_dev *hsi_ctrl) { void __iomem *base = hsi_ctrl->base; unsigned int gdd_lch = 0; u32 status_reg = 0; u32 lch_served = 0; unsigned int gdd_max_count = hsi_ctrl->gdd_chan_count; status_reg = hsi_inl(base, HSI_SYS_GDD_MPU_IRQ_STATUS_REG); status_reg &= hsi_inl(base, HSI_SYS_GDD_MPU_IRQ_ENABLE_REG); if (!status_reg) { dev_dbg(hsi_ctrl->dev, "DMA : no event, exit.\n"); return 0; } for (gdd_lch = 0; gdd_lch < gdd_max_count; gdd_lch++) { if (status_reg & HSI_GDD_LCH(gdd_lch)) { do_hsi_gdd_lch(hsi_ctrl, gdd_lch); lch_served |= HSI_GDD_LCH(gdd_lch); } } /* Acknowledge interrupt for DMA channel */ hsi_outl(lch_served, base, HSI_SYS_GDD_MPU_IRQ_STATUS_REG); return status_reg; } static void do_hsi_gdd_tasklet(unsigned long device) { struct hsi_dev *hsi_ctrl = (struct hsi_dev *)device; dev_dbg(hsi_ctrl->dev, "DMA Tasklet : clock_enabled=%d\n", hsi_ctrl->clock_enabled); spin_lock(&hsi_ctrl->lock); hsi_clocks_enable(hsi_ctrl->dev, __func__); hsi_ctrl->in_dma_tasklet = true; hsi_process_dma_event(hsi_ctrl); hsi_ctrl->in_dma_tasklet = false; hsi_clocks_disable(hsi_ctrl->dev, __func__); spin_unlock(&hsi_ctrl->lock); enable_irq(hsi_ctrl->gdd_irq); } static irqreturn_t hsi_gdd_mpu_handler(int irq, void *p) { struct hsi_dev *hsi_ctrl = p; tasklet_hi_schedule(&hsi_ctrl->hsi_gdd_tasklet); /* Disable interrupt until Bottom Half has cleared the IRQ status */ /* register */ disable_irq_nosync(hsi_ctrl->gdd_irq); return IRQ_HANDLED; } int __init hsi_gdd_init(struct hsi_dev *hsi_ctrl, const char *irq_name) { tasklet_init(&hsi_ctrl->hsi_gdd_tasklet, do_hsi_gdd_tasklet, (unsigned long)hsi_ctrl); dev_info(hsi_ctrl->dev, "Registering IRQ %s (%d)\n", irq_name, hsi_ctrl->gdd_irq); if (request_irq(hsi_ctrl->gdd_irq, hsi_gdd_mpu_handler, IRQF_NO_SUSPEND | IRQF_TRIGGER_HIGH, irq_name, hsi_ctrl) < 0) { dev_err(hsi_ctrl->dev, "FAILED to request GDD IRQ %d\n", hsi_ctrl->gdd_irq); return -EBUSY; } return 0; } void hsi_gdd_exit(struct hsi_dev *hsi_ctrl) { tasklet_kill(&hsi_ctrl->hsi_gdd_tasklet); free_irq(hsi_ctrl->gdd_irq, hsi_ctrl); }