/** * * @file ioctl.c * @author Guillermo Marcus * @date 2009-04-05 * @brief Contains the functions handling the different ioctl calls. * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "config.h" /* Configuration for the driver */ #include "compat.h" /* Compatibility functions/definitions */ #include "pciDriver.h" /* External interface for the driver */ #include "common.h" /* Internal definitions for all parts */ #include "kmem.h" /* Internal definitions for kernel memory */ #include "umem.h" /* Internal definitions for user space memory */ #include "ioctl.h" /* Internal definitions for the ioctl part */ /** Declares a variable of the given type with the given name and copies it from userspace */ #define READ_FROM_USER(type, name) \ type name; \ if ((ret = copy_from_user(&name, (type*)arg, sizeof(name))) != 0) \ return -EFAULT; /** Writes back the given variable with the given type to userspace */ #define WRITE_TO_USER(type, name) \ if ((ret = copy_to_user((type*)arg, &name, sizeof(name))) != 0) \ return -EFAULT; /** * * Sets the mmap mode for following mmap() calls. * * @param arg Not a pointer, but either PCIDRIVER_MMAP_PCI or PCIDRIVER_MMAP_KMEM * */ static int ioctl_mmap_mode(pcidriver_privdata_t *privdata, unsigned long arg) { if ((arg != PCIDRIVER_MMAP_PCI) && (arg != PCIDRIVER_MMAP_KMEM)) return -EINVAL; /* change the mode */ privdata->mmap_mode = arg; return 0; } /** * * Sets the mmap area (BAR) for following mmap() calls. * */ static int ioctl_mmap_area(pcidriver_privdata_t *privdata, unsigned long arg) { /* validate input */ if ((arg < PCIDRIVER_BAR0) || (arg > PCIDRIVER_BAR5)) return -EINVAL; /* change the PCI area to mmap */ privdata->mmap_area = arg; return 0; } /** * * Reads/writes a byte/word/dword of the device's PCI config. * * @see pcidriver_pci_read * @see pcidriver_pci_write * */ static int ioctl_pci_config_read_write(pcidriver_privdata_t *privdata, unsigned int cmd, unsigned long arg) { int ret; READ_FROM_USER(pci_cfg_cmd, pci_cmd); if (cmd == PCIDRIVER_IOC_PCI_CFG_RD) { switch (pci_cmd.size) { case PCIDRIVER_PCI_CFG_SZ_BYTE: ret = pci_read_config_byte( privdata->pdev, pci_cmd.addr, &(pci_cmd.val.byte) ); break; case PCIDRIVER_PCI_CFG_SZ_WORD: ret = pci_read_config_word( privdata->pdev, pci_cmd.addr, &(pci_cmd.val.word) ); break; case PCIDRIVER_PCI_CFG_SZ_DWORD: ret = pci_read_config_dword( privdata->pdev, pci_cmd.addr, &(pci_cmd.val.dword) ); break; default: return -EINVAL; /* Wrong size setting */ } } else { switch (pci_cmd.size) { case PCIDRIVER_PCI_CFG_SZ_BYTE: ret = pci_write_config_byte( privdata->pdev, pci_cmd.addr, pci_cmd.val.byte ); break; case PCIDRIVER_PCI_CFG_SZ_WORD: ret = pci_write_config_word( privdata->pdev, pci_cmd.addr, pci_cmd.val.word ); break; case PCIDRIVER_PCI_CFG_SZ_DWORD: ret = pci_write_config_dword( privdata->pdev, pci_cmd.addr, pci_cmd.val.dword ); break; default: return -EINVAL; /* Wrong size setting */ break; } } WRITE_TO_USER(pci_cfg_cmd, pci_cmd); return 0; } /** * * Gets the PCI information for the device. * * @see pcidriver_pci_info * */ static int ioctl_pci_info(pcidriver_privdata_t *privdata, unsigned long arg) { int ret; int bar; READ_FROM_USER(pcilib_board_info_t, pci_info); pci_info.vendor_id = privdata->pdev->vendor; pci_info.device_id = privdata->pdev->device; pci_info.bus = privdata->pdev->bus->number; pci_info.slot = PCI_SLOT(privdata->pdev->devfn); pci_info.devfn = privdata->pdev->devfn; pci_info.func = PCI_FUNC(privdata->pdev->devfn); if ((ret = pci_read_config_byte(privdata->pdev, PCI_INTERRUPT_PIN, &(pci_info.interrupt_pin))) != 0) return ret; if ((ret = pci_read_config_byte(privdata->pdev, PCI_INTERRUPT_LINE, &(pci_info.interrupt_line))) != 0) return ret; for (bar = 0; bar < 6; bar++) { pci_info.bar_start[bar] = pci_resource_start(privdata->pdev, bar); pci_info.bar_length[bar] = pci_resource_len(privdata->pdev, bar); pci_info.bar_flags[bar] = pci_resource_flags(privdata->pdev, bar); } WRITE_TO_USER(pcilib_board_info_t, pci_info); return 0; } /** * * Allocates kernel memory. * * @see pcidriver_kmem_alloc * */ static int ioctl_kmem_alloc(pcidriver_privdata_t *privdata, unsigned long arg) { int ret; READ_FROM_USER(kmem_handle_t, khandle); if ((ret = pcidriver_kmem_alloc(privdata, &khandle)) != 0) return ret; WRITE_TO_USER(kmem_handle_t, khandle); return 0; } /** * * Frees kernel memory. * * @see pcidriver_kmem_free * */ static int ioctl_kmem_free(pcidriver_privdata_t *privdata, unsigned long arg) { int ret; READ_FROM_USER(kmem_handle_t, khandle); if ((ret = pcidriver_kmem_free(privdata, &khandle)) != 0) return ret; return 0; } /** * * Syncs kernel memory. * * @see pcidriver_kmem_sync * */ static int ioctl_kmem_sync(pcidriver_privdata_t *privdata, unsigned long arg) { int ret; READ_FROM_USER(kmem_sync_t, ksync); if ((ret = pcidriver_kmem_sync(privdata, &ksync)) != 0) return ret; WRITE_TO_USER(kmem_sync_t, ksync); return 0; } /* * * Maps the given scatter/gather list from memory to PCI bus addresses. * * @see pcidriver_umem_sgmap * */ static int ioctl_umem_sgmap(pcidriver_privdata_t *privdata, unsigned long arg) { int ret; READ_FROM_USER(umem_handle_t, uhandle); if ((ret = pcidriver_umem_sgmap(privdata, &uhandle)) != 0) return ret; WRITE_TO_USER(umem_handle_t, uhandle); return 0; } /** * * Unmaps the given scatter/gather list. * * @see pcidriver_umem_sgunmap * */ static int ioctl_umem_sgunmap(pcidriver_privdata_t *privdata, unsigned long arg) { int ret; pcidriver_umem_entry_t *umem_entry; READ_FROM_USER(umem_handle_t, uhandle); /* Find the associated umem_entry for this buffer, * return -EINVAL if the specified handle id is invalid */ if ((umem_entry = pcidriver_umem_find_entry_id(privdata, uhandle.handle_id)) == NULL) return -EINVAL; if ((ret = pcidriver_umem_sgunmap(privdata, umem_entry)) != 0) return ret; return 0; } /** * * Copies the scatter/gather list from kernelspace to userspace. * * @see pcidriver_umem_sgget * */ static int ioctl_umem_sgget(pcidriver_privdata_t *privdata, unsigned long arg) { int ret; READ_FROM_USER(umem_sglist_t, usglist); /* The umem_sglist_t has a pointer to the scatter/gather list itself which * needs to be copied separately. The number of elements is stored in ->nents. * As the list can get very big, we need to use vmalloc. */ if ((usglist.sg = vmalloc(usglist.nents * sizeof(umem_sgentry_t))) == NULL) return -ENOMEM; /* copy array to kernel structure */ ret = copy_from_user(usglist.sg, ((umem_sglist_t *)arg)->sg, (usglist.nents)*sizeof(umem_sgentry_t)); if (ret) return -EFAULT; if ((ret = pcidriver_umem_sgget(privdata, &usglist)) != 0) return ret; /* write data to user space */ ret = copy_to_user(((umem_sglist_t *)arg)->sg, usglist.sg, (usglist.nents)*sizeof(umem_sgentry_t)); if (ret) return -EFAULT; /* free array memory */ vfree(usglist.sg); /* restore sg pointer to vma address in user space before copying */ usglist.sg = ((umem_sglist_t *)arg)->sg; WRITE_TO_USER(umem_sglist_t, usglist); return 0; } /** * * Syncs user memory. * * @see pcidriver_umem_sync * */ static int ioctl_umem_sync(pcidriver_privdata_t *privdata, unsigned long arg) { int ret; READ_FROM_USER(umem_handle_t, uhandle); return pcidriver_umem_sync( privdata, &uhandle ); } /** * * Waits for an interrupt * * @param arg Not a pointer, but the irq source to wait for (unsigned int) * */ static int ioctl_wait_interrupt(pcidriver_privdata_t *privdata, unsigned long arg) { #ifdef ENABLE_IRQ int ret; unsigned long timeout; unsigned int irq_source; unsigned long temp = 0; READ_FROM_USER(interrupt_wait_t, irq_handle); irq_source = irq_handle.source; if (irq_source >= PCIDRIVER_INT_MAXSOURCES) return -EFAULT; /* User tried to overrun the IRQ_SOURCES array */ timeout = jiffies + (irq_handle.timeout * HZ / 1000000); /* Thanks to Joern for the correction and tips! */ /* done this way to avoid wrong behaviour (endless loop) of the compiler in AMD platforms */ do { /* We wait here with an interruptible timeout. This will be interrupted * by int.c:check_acknowledge_channel() as soon as in interrupt for * the specified source arrives. */ wait_event_interruptible_timeout( (privdata->irq_queues[irq_source]), (atomic_read(&(privdata->irq_outstanding[irq_source])) > 0), (10*HZ/1000) ); if (atomic_add_negative( -1, &(privdata->irq_outstanding[irq_source])) ) atomic_inc( &(privdata->irq_outstanding[irq_source]) ); else temp = 1; } while ((!temp)&&(jiffies < timeout)); if ((temp)&&(irq_handle.count)) { while (!atomic_add_negative( -1, &(privdata->irq_outstanding[irq_source]))) temp++; atomic_inc( &(privdata->irq_outstanding[irq_source]) ); } irq_handle.count = temp; WRITE_TO_USER(interrupt_wait_t, irq_handle); return 0; #else mod_info("Asked to wait for interrupt but interrupts are not enabled in the driver\n"); return -EFAULT; #endif } /** * * Clears the interrupt wait queue. * * @param arg Not a pointer, but the irq source (unsigned int) * @returns -EFAULT if the user specified an irq source out of range * */ static int ioctl_clear_ioq(pcidriver_privdata_t *privdata, unsigned long arg) { #ifdef ENABLE_IRQ unsigned int irq_source; if (arg >= PCIDRIVER_INT_MAXSOURCES) return -EFAULT; irq_source = arg; atomic_set(&(privdata->irq_outstanding[irq_source]), 0); return 0; #else mod_info("Asked to wait for interrupt but interrupts are not enabled in the driver\n"); return -EFAULT; #endif } /** * * This function handles all ioctl file operations. * Generally, the data of the ioctl is copied from userspace to kernelspace, a separate * function is called to handle the ioctl itself, then the data is copied back to userspace. * * @returns -EFAULT when an invalid memory pointer is passed * */ #if LINUX_VERSION_CODE < KERNEL_VERSION(2,6,11) int pcidriver_ioctl(struct inode *inode, struct file *filp, unsigned int cmd, unsigned long arg) #else long pcidriver_ioctl(struct file *filp, unsigned int cmd, unsigned long arg) #endif { pcidriver_privdata_t *privdata = filp->private_data; /* Select the appropiate command */ switch (cmd) { case PCIDRIVER_IOC_MMAP_MODE: return ioctl_mmap_mode(privdata, arg); case PCIDRIVER_IOC_MMAP_AREA: return ioctl_mmap_area(privdata, arg); case PCIDRIVER_IOC_PCI_CFG_RD: case PCIDRIVER_IOC_PCI_CFG_WR: return ioctl_pci_config_read_write(privdata, cmd, arg); case PCIDRIVER_IOC_PCI_INFO: return ioctl_pci_info(privdata, arg); case PCIDRIVER_IOC_KMEM_ALLOC: return ioctl_kmem_alloc(privdata, arg); case PCIDRIVER_IOC_KMEM_FREE: return ioctl_kmem_free(privdata, arg); case PCIDRIVER_IOC_KMEM_SYNC: return ioctl_kmem_sync(privdata, arg); case PCIDRIVER_IOC_UMEM_SGMAP: return ioctl_umem_sgmap(privdata, arg); case PCIDRIVER_IOC_UMEM_SGUNMAP: return ioctl_umem_sgunmap(privdata, arg); case PCIDRIVER_IOC_UMEM_SGGET: return ioctl_umem_sgget(privdata, arg); case PCIDRIVER_IOC_UMEM_SYNC: return ioctl_umem_sync(privdata, arg); case PCIDRIVER_IOC_WAITI: return ioctl_wait_interrupt(privdata, arg); case PCIDRIVER_IOC_CLEAR_IOQ: return ioctl_clear_ioq(privdata, arg); default: return -EINVAL; } }