/** * tpci200.c * * driver for the TEWS TPCI-200 device * Copyright (c) 2009 Nicolas Serafini, EIC2 SA * Copyright (c) 2010,2011 Samuel Iglesias Gonsalvez , CERN * Copyright (c) 2012 Samuel Iglesias Gonsalvez , Igalia * * This program is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the Free * Software Foundation; version 2 of the License. */ #define pr_fmt(fmt) KBUILD_MODNAME ": " fmt #include #include "tpci200.h" static struct ipack_bus_ops tpci200_bus_ops; /* TPCI200 controls registers */ static int control_reg[] = { TPCI200_CONTROL_A_REG, TPCI200_CONTROL_B_REG, TPCI200_CONTROL_C_REG, TPCI200_CONTROL_D_REG }; /* Linked list to save the registered devices */ static LIST_HEAD(tpci200_list); static int tpci200_slot_unregister(struct ipack_device *dev); static struct tpci200_board *check_slot(struct ipack_device *dev) { struct tpci200_board *tpci200; int found = 0; if (dev == NULL) { pr_info("Slot doesn't exist.\n"); return NULL; } list_for_each_entry(tpci200, &tpci200_list, list) { if (tpci200->number == dev->bus_nr) { found = 1; break; } } if (!found) { pr_err("Carrier not found\n"); return NULL; } if (dev->slot >= TPCI200_NB_SLOT) { pr_info("Slot [%d:%d] doesn't exist! Last tpci200 slot is %d.\n", dev->bus_nr, dev->slot, TPCI200_NB_SLOT-1); return NULL; } BUG_ON(tpci200->slots == NULL); if (tpci200->slots[dev->slot].dev == NULL) { pr_info("Slot [%d:%d] is not registered !\n", dev->bus_nr, dev->slot); return NULL; } return tpci200; } static inline unsigned char __tpci200_read8(void __iomem *address, unsigned long offset) { return ioread8(address + (offset^1)); } static inline unsigned short __tpci200_read16(void __iomem *address, unsigned long offset) { return ioread16(address + offset); } static inline unsigned int __tpci200_read32(void __iomem *address, unsigned long offset) { return swahw32(ioread32(address + offset)); } static inline void __tpci200_write8(unsigned char value, void __iomem *address, unsigned long offset) { iowrite8(value, address+(offset^1)); } static inline void __tpci200_write16(unsigned short value, void __iomem *address, unsigned long offset) { iowrite16(value, address+offset); } static inline void __tpci200_write32(unsigned int value, void __iomem *address, unsigned long offset) { iowrite32(swahw32(value), address+offset); } static struct ipack_addr_space *get_slot_address_space(struct ipack_device *dev, int space) { struct ipack_addr_space *addr; switch (space) { case IPACK_IO_SPACE: addr = &dev->io_space; break; case IPACK_ID_SPACE: addr = &dev->id_space; break; case IPACK_MEM_SPACE: addr = &dev->mem_space; break; default: pr_err("Slot [%d:%d] space number %d doesn't exist !\n", dev->bus_nr, dev->slot, space); return NULL; break; } if ((addr->size == 0) || (addr->address == NULL)) { pr_err("Error, slot space not mapped !\n"); return NULL; } return addr; } static int tpci200_read8(struct ipack_device *dev, int space, unsigned long offset, unsigned char *value) { struct ipack_addr_space *addr; struct tpci200_board *tpci200; tpci200 = check_slot(dev); if (tpci200 == NULL) return -EINVAL; addr = get_slot_address_space(dev, space); if (addr == NULL) return -EINVAL; if (offset >= addr->size) { pr_err("Error, slot space offset error !\n"); return -EFAULT; } *value = __tpci200_read8(addr->address, offset); return 0; } static int tpci200_read16(struct ipack_device *dev, int space, unsigned long offset, unsigned short *value) { struct ipack_addr_space *addr; struct tpci200_board *tpci200; tpci200 = check_slot(dev); if (tpci200 == NULL) return -EINVAL; addr = get_slot_address_space(dev, space); if (addr == NULL) return -EINVAL; if ((offset+2) >= addr->size) { pr_err("Error, slot space offset error !\n"); return -EFAULT; } *value = __tpci200_read16(addr->address, offset); return 0; } static int tpci200_read32(struct ipack_device *dev, int space, unsigned long offset, unsigned int *value) { struct ipack_addr_space *addr; struct tpci200_board *tpci200; tpci200 = check_slot(dev); if (tpci200 == NULL) return -EINVAL; addr = get_slot_address_space(dev, space); if (addr == NULL) return -EINVAL; if ((offset+4) >= addr->size) { pr_err("Error, slot space offset error !\n"); return -EFAULT; } *value = __tpci200_read32(addr->address, offset); return 0; } static int tpci200_write8(struct ipack_device *dev, int space, unsigned long offset, unsigned char value) { struct ipack_addr_space *addr; struct tpci200_board *tpci200; tpci200 = check_slot(dev); if (tpci200 == NULL) return -EINVAL; addr = get_slot_address_space(dev, space); if (addr == NULL) return -EINVAL; if (offset >= addr->size) { pr_err("Error, slot space offset error !\n"); return -EFAULT; } __tpci200_write8(value, addr->address, offset); return 0; } static int tpci200_write16(struct ipack_device *dev, int space, unsigned long offset, unsigned short value) { struct ipack_addr_space *addr; struct tpci200_board *tpci200; tpci200 = check_slot(dev); if (tpci200 == NULL) return -EINVAL; addr = get_slot_address_space(dev, space); if (addr == NULL) return -EINVAL; if ((offset+2) >= addr->size) { pr_err("Error, slot space offset error !\n"); return -EFAULT; } __tpci200_write16(value, addr->address, offset); return 0; } static int tpci200_write32(struct ipack_device *dev, int space, unsigned long offset, unsigned int value) { struct ipack_addr_space *addr; struct tpci200_board *tpci200; tpci200 = check_slot(dev); if (tpci200 == NULL) return -EINVAL; addr = get_slot_address_space(dev, space); if (addr == NULL) return -EINVAL; if ((offset+4) >= addr->size) { pr_err("Error, slot space offset error !\n"); return -EFAULT; } __tpci200_write32(value, addr->address, offset); return 0; } static void tpci200_unregister(struct tpci200_board *tpci200) { int i; free_irq(tpci200->info->pdev->irq, (void *) tpci200); pci_iounmap(tpci200->info->pdev, tpci200->info->interface_regs); pci_iounmap(tpci200->info->pdev, tpci200->info->ioidint_space); pci_iounmap(tpci200->info->pdev, tpci200->info->mem8_space); pci_release_region(tpci200->info->pdev, TPCI200_IP_INTERFACE_BAR); pci_release_region(tpci200->info->pdev, TPCI200_IO_ID_INT_SPACES_BAR); pci_release_region(tpci200->info->pdev, TPCI200_MEM8_SPACE_BAR); pci_disable_device(tpci200->info->pdev); pci_dev_put(tpci200->info->pdev); kfree(tpci200->info); for (i = 0; i < TPCI200_NB_SLOT; i++) { tpci200->slots[i].io_phys.address = NULL; tpci200->slots[i].io_phys.size = 0; tpci200->slots[i].id_phys.address = NULL; tpci200->slots[i].id_phys.size = 0; tpci200->slots[i].mem_phys.address = NULL; tpci200->slots[i].mem_phys.size = 0; } } static irqreturn_t tpci200_interrupt(int irq, void *dev_id) { struct tpci200_board *tpci200 = (struct tpci200_board *) dev_id; int i; unsigned long flags; unsigned short status_reg, reg_value; unsigned short unhandled_ints = 0; irqreturn_t ret = IRQ_NONE; spin_lock_irqsave(&tpci200->info->access_lock, flags); /* Read status register */ status_reg = readw(tpci200->info->interface_regs + TPCI200_STATUS_REG); if (status_reg & TPCI200_SLOT_INT_MASK) { unhandled_ints = status_reg & TPCI200_SLOT_INT_MASK; /* callback to the IRQ handler for the corresponding slot */ for (i = 0; i < TPCI200_NB_SLOT; i++) { if ((tpci200->slots[i].irq != NULL) && (status_reg & ((TPCI200_A_INT0 | TPCI200_A_INT1) << (2*i)))) { ret = tpci200->slots[i].irq->handler(tpci200->slots[i].irq->arg); /* Dummy reads */ readw(tpci200->slots[i].dev->io_space.address + 0xC0); readw(tpci200->slots[i].dev->io_space.address + 0xC2); unhandled_ints &= ~(((TPCI200_A_INT0 | TPCI200_A_INT1) << (2*i))); } } } /* Interrupt not handled are disabled */ if (unhandled_ints) { for (i = 0; i < TPCI200_NB_SLOT; i++) { if (unhandled_ints & ((TPCI200_INT0_EN | TPCI200_INT1_EN) << (2*i))) { pr_info("No registered ISR for slot [%d:%d]!. IRQ will be disabled.\n", tpci200->number, i); reg_value = readw( tpci200->info->interface_regs + control_reg[i]); reg_value &= ~(TPCI200_INT0_EN | TPCI200_INT1_EN); writew(reg_value, (tpci200->info->interface_regs + control_reg[i])); } } } spin_unlock_irqrestore(&tpci200->info->access_lock, flags); return ret; } #ifdef CONFIG_SYSFS static struct ipack_device *tpci200_slot_register(unsigned int tpci200_number, unsigned int slot_position) { int found = 0; struct ipack_device *dev; struct tpci200_board *tpci200; list_for_each_entry(tpci200, &tpci200_list, list) { if (tpci200->number == tpci200_number) { found = 1; break; } } if (!found) { pr_err("carrier board not found for the device\n"); return NULL; } if (slot_position >= TPCI200_NB_SLOT) { pr_info("Slot [%d:%d] doesn't exist!\n", tpci200_number, slot_position); return NULL; } if (mutex_lock_interruptible(&tpci200->mutex)) return NULL; if (tpci200->slots[slot_position].dev != NULL) { pr_err("Slot [%d:%d] already installed !\n", tpci200_number, slot_position); goto err_unlock; } /* * Give the same IRQ number as the slot number. * The TPCI200 has assigned his own two IRQ by PCI bus driver */ dev = ipack_device_register(tpci200->info->ipack_bus, slot_position, slot_position); if (dev == NULL) { pr_info("Slot [%d:%d] Unable to register an ipack device\n", tpci200_number, slot_position); goto err_unlock; } tpci200->slots[slot_position].dev = dev; mutex_unlock(&tpci200->mutex); return dev; err_unlock: mutex_unlock(&tpci200->mutex); return NULL; } static ssize_t tpci200_store_board(struct device *pdev, const char *buf, size_t count, int slot) { struct tpci200_board *card = dev_get_drvdata(pdev); struct ipack_device *dev = card->slots[slot].dev; if (dev != NULL) return -EBUSY; dev = tpci200_slot_register(card->number, slot); if (dev == NULL) return -ENODEV; return count; } static ssize_t tpci200_show_board(struct device *pdev, char *buf, int slot) { struct tpci200_board *card = dev_get_drvdata(pdev); struct ipack_device *dev = card->slots[slot].dev; if (dev != NULL) return snprintf(buf, PAGE_SIZE, "%s\n", dev_name(&dev->dev)); else return snprintf(buf, PAGE_SIZE, "none\n"); } static ssize_t tpci200_show_description(struct device *pdev, struct device_attribute *attr, char *buf) { return snprintf(buf, PAGE_SIZE, "TEWS tpci200 carrier PCI for Industry-pack mezzanines.\n"); } static ssize_t tpci200_show_board_slot0(struct device *pdev, struct device_attribute *attr, char *buf) { return tpci200_show_board(pdev, buf, 0); } static ssize_t tpci200_store_board_slot0(struct device *pdev, struct device_attribute *attr, const char *buf, size_t count) { return tpci200_store_board(pdev, buf, count, 0); } static ssize_t tpci200_show_board_slot1(struct device *pdev, struct device_attribute *attr, char *buf) { return tpci200_show_board(pdev, buf, 1); } static ssize_t tpci200_store_board_slot1(struct device *pdev, struct device_attribute *attr, const char *buf, size_t count) { return tpci200_store_board(pdev, buf, count, 1); } static ssize_t tpci200_show_board_slot2(struct device *pdev, struct device_attribute *attr, char *buf) { return tpci200_show_board(pdev, buf, 2); } static ssize_t tpci200_store_board_slot2(struct device *pdev, struct device_attribute *attr, const char *buf, size_t count) { return tpci200_store_board(pdev, buf, count, 2); } static ssize_t tpci200_show_board_slot3(struct device *pdev, struct device_attribute *attr, char *buf) { return tpci200_show_board(pdev, buf, 3); } static ssize_t tpci200_store_board_slot3(struct device *pdev, struct device_attribute *attr, const char *buf, size_t count) { return tpci200_store_board(pdev, buf, count, 3); } /* Declaration of the device attributes for the TPCI200 */ static DEVICE_ATTR(description, S_IRUGO, tpci200_show_description, NULL); static DEVICE_ATTR(board_slot0, S_IRUGO | S_IWUSR, tpci200_show_board_slot0, tpci200_store_board_slot0); static DEVICE_ATTR(board_slot1, S_IRUGO | S_IWUSR, tpci200_show_board_slot1, tpci200_store_board_slot1); static DEVICE_ATTR(board_slot2, S_IRUGO | S_IWUSR, tpci200_show_board_slot2, tpci200_store_board_slot2); static DEVICE_ATTR(board_slot3, S_IRUGO | S_IWUSR, tpci200_show_board_slot3, tpci200_store_board_slot3); static struct attribute *tpci200_attrs[] = { &dev_attr_description.attr, &dev_attr_board_slot0.attr, &dev_attr_board_slot1.attr, &dev_attr_board_slot2.attr, &dev_attr_board_slot3.attr, NULL, }; static struct attribute_group tpci200_attr_group = { .attrs = tpci200_attrs, }; static int tpci200_create_sysfs_files(struct tpci200_board *card) { return sysfs_create_group(&card->info->pdev->dev.kobj, &tpci200_attr_group); } static void tpci200_remove_sysfs_files(struct tpci200_board *card) { sysfs_remove_group(&card->info->pdev->dev.kobj, &tpci200_attr_group); } #else static int tpci200_create_sysfs_files(struct tpci200_board *card) { return 0; } static void tpci200_remove_sysfs_files(struct tpci200_board *card) { } #endif /* CONFIG_SYSFS */ static int tpci200_register(struct tpci200_board *tpci200) { int i; int res; unsigned long ioidint_base; unsigned long mem_base; unsigned short slot_ctrl; if (pci_enable_device(tpci200->info->pdev) < 0) return -ENODEV; if (tpci200_create_sysfs_files(tpci200) < 0) { pr_err("failed creating sysfs files\n"); res = -EFAULT; goto out_disable_pci; } /* Request IP interface register (Bar 2) */ res = pci_request_region(tpci200->info->pdev, TPCI200_IP_INTERFACE_BAR, "Carrier IP interface registers"); if (res) { pr_err("(bn 0x%X, sn 0x%X) failed to allocate PCI resource for BAR 2 !", tpci200->info->pdev->bus->number, tpci200->info->pdev->devfn); goto out_remove_sysfs; } /* Request IO ID INT space (Bar 3) */ res = pci_request_region(tpci200->info->pdev, TPCI200_IO_ID_INT_SPACES_BAR, "Carrier IO ID INT space"); if (res) { pr_err("(bn 0x%X, sn 0x%X) failed to allocate PCI resource for BAR 3 !", tpci200->info->pdev->bus->number, tpci200->info->pdev->devfn); goto out_release_ip_space; } /* Request MEM space (Bar 4) */ res = pci_request_region(tpci200->info->pdev, TPCI200_MEM8_SPACE_BAR, "Carrier MEM space"); if (res) { pr_err("(bn 0x%X, sn 0x%X) failed to allocate PCI resource for BAR 4!", tpci200->info->pdev->bus->number, tpci200->info->pdev->devfn); goto out_release_ioid_int_space; } /* Map internal tpci200 driver user space */ tpci200->info->interface_regs = ioremap(pci_resource_start(tpci200->info->pdev, TPCI200_IP_INTERFACE_BAR), TPCI200_IFACE_SIZE); tpci200->info->ioidint_space = ioremap(pci_resource_start(tpci200->info->pdev, TPCI200_IO_ID_INT_SPACES_BAR), TPCI200_IOIDINT_SIZE); tpci200->info->mem8_space = ioremap(pci_resource_start(tpci200->info->pdev, TPCI200_MEM8_SPACE_BAR), TPCI200_MEM8_SIZE); spin_lock_init(&tpci200->info->access_lock); ioidint_base = pci_resource_start(tpci200->info->pdev, TPCI200_IO_ID_INT_SPACES_BAR); mem_base = pci_resource_start(tpci200->info->pdev, TPCI200_MEM8_SPACE_BAR); /* Set the default parameters of the slot * INT0 disabled, level sensitive * INT1 disabled, level sensitive * error interrupt disabled * timeout interrupt disabled * recover time disabled * clock rate 8 MHz */ slot_ctrl = 0; /* Set all slot physical address space */ for (i = 0; i < TPCI200_NB_SLOT; i++) { tpci200->slots[i].io_phys.address = (void __iomem *)ioidint_base + TPCI200_IO_SPACE_OFF + TPCI200_IO_SPACE_GAP*i; tpci200->slots[i].io_phys.size = TPCI200_IO_SPACE_SIZE; tpci200->slots[i].id_phys.address = (void __iomem *)ioidint_base + TPCI200_ID_SPACE_OFF + TPCI200_ID_SPACE_GAP*i; tpci200->slots[i].id_phys.size = TPCI200_ID_SPACE_SIZE; tpci200->slots[i].mem_phys.address = (void __iomem *)mem_base + TPCI200_MEM8_GAP*i; tpci200->slots[i].mem_phys.size = TPCI200_MEM8_SIZE; writew(slot_ctrl, (tpci200->info->interface_regs + control_reg[i])); } res = request_irq(tpci200->info->pdev->irq, tpci200_interrupt, IRQF_SHARED, KBUILD_MODNAME, (void *) tpci200); if (res) { pr_err("(bn 0x%X, sn 0x%X) unable to register IRQ !", tpci200->info->pdev->bus->number, tpci200->info->pdev->devfn); tpci200_unregister(tpci200); goto out_err; } return 0; out_release_ioid_int_space: pci_release_region(tpci200->info->pdev, TPCI200_IO_ID_INT_SPACES_BAR); out_release_ip_space: pci_release_region(tpci200->info->pdev, TPCI200_IP_INTERFACE_BAR); out_remove_sysfs: tpci200_remove_sysfs_files(tpci200); out_disable_pci: pci_disable_device(tpci200->info->pdev); out_err: return res; } static int __tpci200_request_irq(struct tpci200_board *tpci200, struct ipack_device *dev) { unsigned short slot_ctrl; /* Set the default parameters of the slot * INT0 enabled, level sensitive * INT1 enabled, level sensitive * error interrupt disabled * timeout interrupt disabled * recover time disabled * clock rate 8 MHz */ slot_ctrl = TPCI200_INT0_EN | TPCI200_INT1_EN; writew(slot_ctrl, (tpci200->info->interface_regs + control_reg[dev->slot])); return 0; } static void __tpci200_free_irq(struct tpci200_board *tpci200, struct ipack_device *dev) { unsigned short slot_ctrl; /* Set the default parameters of the slot * INT0 disabled, level sensitive * INT1 disabled, level sensitive * error interrupt disabled * timeout interrupt disabled * recover time disabled * clock rate 8 MHz */ slot_ctrl = 0; writew(slot_ctrl, (tpci200->info->interface_regs + control_reg[dev->slot])); } static int tpci200_free_irq(struct ipack_device *dev) { int res; struct slot_irq *slot_irq; struct tpci200_board *tpci200; tpci200 = check_slot(dev); if (tpci200 == NULL) { res = -EINVAL; goto out; } if (mutex_lock_interruptible(&tpci200->mutex)) { res = -ERESTARTSYS; goto out; } if (tpci200->slots[dev->slot].irq == NULL) { res = -EINVAL; goto out_unlock; } __tpci200_free_irq(tpci200, dev); slot_irq = tpci200->slots[dev->slot].irq; tpci200->slots[dev->slot].irq = NULL; kfree(slot_irq); out_unlock: mutex_unlock(&tpci200->mutex); out: return res; } static int tpci200_slot_unmap_space(struct ipack_device *dev, int space) { int res; struct ipack_addr_space *virt_addr_space; struct tpci200_board *tpci200; tpci200 = check_slot(dev); if (tpci200 == NULL) { res = -EINVAL; goto out; } if (mutex_lock_interruptible(&tpci200->mutex)) { res = -ERESTARTSYS; goto out; } switch (space) { case IPACK_IO_SPACE: if (dev->io_space.address == NULL) { pr_info("Slot [%d:%d] IO space not mapped !\n", dev->bus_nr, dev->slot); goto out_unlock; } virt_addr_space = &dev->io_space; break; case IPACK_ID_SPACE: if (dev->id_space.address == NULL) { pr_info("Slot [%d:%d] ID space not mapped !\n", dev->bus_nr, dev->slot); goto out_unlock; } virt_addr_space = &dev->id_space; break; case IPACK_MEM_SPACE: if (dev->mem_space.address == NULL) { pr_info("Slot [%d:%d] MEM space not mapped !\n", dev->bus_nr, dev->slot); goto out_unlock; } virt_addr_space = &dev->mem_space; break; default: pr_err("Slot [%d:%d] space number %d doesn't exist !\n", dev->bus_nr, dev->slot, space); res = -EINVAL; goto out_unlock; break; } iounmap(virt_addr_space->address); virt_addr_space->address = NULL; virt_addr_space->size = 0; out_unlock: mutex_unlock(&tpci200->mutex); out: return res; } static int tpci200_slot_unregister(struct ipack_device *dev) { struct tpci200_board *tpci200; if (dev == NULL) return -ENODEV; tpci200 = check_slot(dev); if (tpci200 == NULL) return -EINVAL; tpci200_free_irq(dev); if (mutex_lock_interruptible(&tpci200->mutex)) return -ERESTARTSYS; ipack_device_unregister(dev); tpci200->slots[dev->slot].dev = NULL; mutex_unlock(&tpci200->mutex); return 0; } static int tpci200_slot_map_space(struct ipack_device *dev, unsigned int memory_size, int space) { int res; unsigned int size_to_map; void __iomem *phys_address; struct ipack_addr_space *virt_addr_space; struct tpci200_board *tpci200; tpci200 = check_slot(dev); if (tpci200 == NULL) { res = -EINVAL; goto out; } if (mutex_lock_interruptible(&tpci200->mutex)) { res = -ERESTARTSYS; goto out; } switch (space) { case IPACK_IO_SPACE: if (dev->io_space.address != NULL) { pr_err("Slot [%d:%d] IO space already mapped !\n", tpci200->number, dev->slot); res = -EINVAL; goto out_unlock; } virt_addr_space = &dev->io_space; phys_address = tpci200->slots[dev->slot].io_phys.address; size_to_map = tpci200->slots[dev->slot].io_phys.size; break; case IPACK_ID_SPACE: if (dev->id_space.address != NULL) { pr_err("Slot [%d:%d] ID space already mapped !\n", tpci200->number, dev->slot); res = -EINVAL; goto out_unlock; } virt_addr_space = &dev->id_space; phys_address = tpci200->slots[dev->slot].id_phys.address; size_to_map = tpci200->slots[dev->slot].id_phys.size; break; case IPACK_MEM_SPACE: if (dev->mem_space.address != NULL) { pr_err("Slot [%d:%d] MEM space already mapped !\n", tpci200->number, dev->slot); res = -EINVAL; goto out_unlock; } virt_addr_space = &dev->mem_space; if (memory_size > tpci200->slots[dev->slot].mem_phys.size) { pr_err("Slot [%d:%d] request is 0x%X memory, only 0x%X available !\n", dev->bus_nr, dev->slot, memory_size, tpci200->slots[dev->slot].mem_phys.size); res = -EINVAL; goto out_unlock; } phys_address = tpci200->slots[dev->slot].mem_phys.address; size_to_map = memory_size; break; default: pr_err("Slot [%d:%d] space %d doesn't exist !\n", tpci200->number, dev->slot, space); res = -EINVAL; goto out_unlock; break; } virt_addr_space->size = size_to_map; virt_addr_space->address = ioremap((unsigned long)phys_address, size_to_map); out_unlock: mutex_unlock(&tpci200->mutex); out: return res; } static int tpci200_request_irq(struct ipack_device *dev, int vector, int (*handler)(void *), void *arg) { int res; struct slot_irq *slot_irq; struct tpci200_board *tpci200; tpci200 = check_slot(dev); if (tpci200 == NULL) { res = -EINVAL; goto out; } if (mutex_lock_interruptible(&tpci200->mutex)) { res = -ERESTARTSYS; goto out; } if (tpci200->slots[dev->slot].irq != NULL) { pr_err("Slot [%d:%d] IRQ already registered !\n", dev->bus_nr, dev->slot); res = -EINVAL; goto out_unlock; } slot_irq = kzalloc(sizeof(struct slot_irq), GFP_KERNEL); if (slot_irq == NULL) { pr_err("Slot [%d:%d] unable to allocate memory for IRQ !\n", dev->bus_nr, dev->slot); res = -ENOMEM; goto out_unlock; } /* * WARNING: Setup Interrupt Vector in the IndustryPack device * before an IRQ request. * Read the User Manual of your IndustryPack device to know * where to write the vector in memory. */ slot_irq->vector = vector; slot_irq->handler = handler; slot_irq->arg = arg; slot_irq->name = dev_name(&dev->dev); tpci200->slots[dev->slot].irq = slot_irq; res = __tpci200_request_irq(tpci200, dev); out_unlock: mutex_unlock(&tpci200->mutex); out: return res; } static void tpci200_slot_remove(struct tpci200_slot *slot) { if ((slot->dev == NULL) || (slot->dev->driver->ops->remove == NULL)) return; slot->dev->driver->ops->remove(slot->dev); } static void tpci200_uninstall(struct tpci200_board *tpci200) { int i; for (i = 0; i < TPCI200_NB_SLOT; i++) tpci200_slot_remove(&tpci200->slots[i]); tpci200_unregister(tpci200); kfree(tpci200->slots); } static struct ipack_bus_ops tpci200_bus_ops = { .map_space = tpci200_slot_map_space, .unmap_space = tpci200_slot_unmap_space, .request_irq = tpci200_request_irq, .free_irq = tpci200_free_irq, .read8 = tpci200_read8, .read16 = tpci200_read16, .read32 = tpci200_read32, .write8 = tpci200_write8, .write16 = tpci200_write16, .write32 = tpci200_write32, .remove_device = tpci200_slot_unregister, }; static int tpci200_install(struct tpci200_board *tpci200) { int res; tpci200->slots = kzalloc( TPCI200_NB_SLOT * sizeof(struct tpci200_slot), GFP_KERNEL); if (tpci200->slots == NULL) { res = -ENOMEM; goto out_err; } res = tpci200_register(tpci200); if (res) goto out_free; mutex_init(&tpci200->mutex); return 0; out_free: kfree(tpci200->slots); tpci200->slots = NULL; out_err: return res; } static int tpci200_pciprobe(struct pci_dev *pdev, const struct pci_device_id *id) { int ret; struct tpci200_board *tpci200; tpci200 = kzalloc(sizeof(struct tpci200_board), GFP_KERNEL); if (!tpci200) return -ENOMEM; tpci200->info = kzalloc(sizeof(struct tpci200_infos), GFP_KERNEL); if (!tpci200->info) { kfree(tpci200); return -ENOMEM; } /* Save struct pci_dev pointer */ tpci200->info->pdev = pdev; tpci200->info->id_table = (struct pci_device_id *)id; /* register the device and initialize it */ ret = tpci200_install(tpci200); if (ret) { pr_err("Error during tpci200 install !\n"); kfree(tpci200->info); kfree(tpci200); return -ENODEV; } /* Register the carrier in the industry pack bus driver */ tpci200->info->ipack_bus = ipack_bus_register(&pdev->dev, TPCI200_NB_SLOT, &tpci200_bus_ops); if (!tpci200->info->ipack_bus) { pr_err("error registering the carrier on ipack driver\n"); tpci200_uninstall(tpci200); kfree(tpci200->info); kfree(tpci200); return -EFAULT; } /* save the bus number given by ipack to logging purpose */ tpci200->number = tpci200->info->ipack_bus->bus_nr; dev_set_drvdata(&pdev->dev, tpci200); /* add the registered device in an internal linked list */ list_add_tail(&tpci200->list, &tpci200_list); return ret; } static void __tpci200_pci_remove(struct tpci200_board *tpci200) { tpci200_uninstall(tpci200); tpci200_remove_sysfs_files(tpci200); list_del(&tpci200->list); ipack_bus_unregister(tpci200->info->ipack_bus); kfree(tpci200->info); kfree(tpci200); } static void __devexit tpci200_pci_remove(struct pci_dev *dev) { struct tpci200_board *tpci200, *next; /* Search the registered device to uninstall it */ list_for_each_entry_safe(tpci200, next, &tpci200_list, list) { if (tpci200->info->pdev == dev) { __tpci200_pci_remove(tpci200); break; } } } static struct pci_device_id tpci200_idtable[2] = { { TPCI200_VENDOR_ID, TPCI200_DEVICE_ID, TPCI200_SUBVENDOR_ID, TPCI200_SUBDEVICE_ID }, { 0, }, }; static struct pci_driver tpci200_pci_drv = { .name = "tpci200", .id_table = tpci200_idtable, .probe = tpci200_pciprobe, .remove = __devexit_p(tpci200_pci_remove), }; static int __init tpci200_drvr_init_module(void) { return pci_register_driver(&tpci200_pci_drv); } static void __exit tpci200_drvr_exit_module(void) { struct tpci200_board *tpci200, *next; list_for_each_entry_safe(tpci200, next, &tpci200_list, list) __tpci200_pci_remove(tpci200); pci_unregister_driver(&tpci200_pci_drv); } MODULE_DESCRIPTION("TEWS TPCI-200 device driver"); MODULE_LICENSE("GPL"); module_init(tpci200_drvr_init_module); module_exit(tpci200_drvr_exit_module);