Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Kishon Vijay Abraham I | 2673 | 88.28% | 17 | 48.57% |
Cyrille Pitchen | 128 | 4.23% | 1 | 2.86% |
Gustavo Pimentel | 105 | 3.47% | 3 | 8.57% |
Niklas Cassel | 75 | 2.48% | 7 | 20.00% |
Yoshihiro Shimoda | 27 | 0.89% | 1 | 2.86% |
Alan Mikhak | 9 | 0.30% | 1 | 2.86% |
Vidya Sagar | 7 | 0.23% | 1 | 2.86% |
Krzysztof Wilczynski | 2 | 0.07% | 2 | 5.71% |
Krzysztof Kozlowski | 1 | 0.03% | 1 | 2.86% |
Björn Helgaas | 1 | 0.03% | 1 | 2.86% |
Total | 3028 | 35 |
// SPDX-License-Identifier: GPL-2.0 /* * PCI Endpoint *Controller* (EPC) library * * Copyright (C) 2017 Texas Instruments * Author: Kishon Vijay Abraham I <kishon@ti.com> */ #include <linux/device.h> #include <linux/slab.h> #include <linux/module.h> #include <linux/of_device.h> #include <linux/pci-epc.h> #include <linux/pci-epf.h> #include <linux/pci-ep-cfs.h> static struct class *pci_epc_class; static void devm_pci_epc_release(struct device *dev, void *res) { struct pci_epc *epc = *(struct pci_epc **)res; pci_epc_destroy(epc); } static int devm_pci_epc_match(struct device *dev, void *res, void *match_data) { struct pci_epc **epc = res; return *epc == match_data; } /** * pci_epc_put() - release the PCI endpoint controller * @epc: epc returned by pci_epc_get() * * release the refcount the caller obtained by invoking pci_epc_get() */ void pci_epc_put(struct pci_epc *epc) { if (!epc || IS_ERR(epc)) return; module_put(epc->ops->owner); put_device(&epc->dev); } EXPORT_SYMBOL_GPL(pci_epc_put); /** * pci_epc_get() - get the PCI endpoint controller * @epc_name: device name of the endpoint controller * * Invoke to get struct pci_epc * corresponding to the device name of the * endpoint controller */ struct pci_epc *pci_epc_get(const char *epc_name) { int ret = -EINVAL; struct pci_epc *epc; struct device *dev; struct class_dev_iter iter; class_dev_iter_init(&iter, pci_epc_class, NULL, NULL); while ((dev = class_dev_iter_next(&iter))) { if (strcmp(epc_name, dev_name(dev))) continue; epc = to_pci_epc(dev); if (!try_module_get(epc->ops->owner)) { ret = -EINVAL; goto err; } class_dev_iter_exit(&iter); get_device(&epc->dev); return epc; } err: class_dev_iter_exit(&iter); return ERR_PTR(ret); } EXPORT_SYMBOL_GPL(pci_epc_get); /** * pci_epc_get_first_free_bar() - helper to get first unreserved BAR * @epc_features: pci_epc_features structure that holds the reserved bar bitmap * * Invoke to get the first unreserved BAR that can be used by the endpoint * function. For any incorrect value in reserved_bar return '0'. */ enum pci_barno pci_epc_get_first_free_bar(const struct pci_epc_features *epc_features) { return pci_epc_get_next_free_bar(epc_features, BAR_0); } EXPORT_SYMBOL_GPL(pci_epc_get_first_free_bar); /** * pci_epc_get_next_free_bar() - helper to get unreserved BAR starting from @bar * @epc_features: pci_epc_features structure that holds the reserved bar bitmap * @bar: the starting BAR number from where unreserved BAR should be searched * * Invoke to get the next unreserved BAR starting from @bar that can be used * for endpoint function. For any incorrect value in reserved_bar return '0'. */ enum pci_barno pci_epc_get_next_free_bar(const struct pci_epc_features *epc_features, enum pci_barno bar) { unsigned long free_bar; if (!epc_features) return BAR_0; /* If 'bar - 1' is a 64-bit BAR, move to the next BAR */ if ((epc_features->bar_fixed_64bit << 1) & 1 << bar) bar++; /* Find if the reserved BAR is also a 64-bit BAR */ free_bar = epc_features->reserved_bar & epc_features->bar_fixed_64bit; /* Set the adjacent bit if the reserved BAR is also a 64-bit BAR */ free_bar <<= 1; free_bar |= epc_features->reserved_bar; free_bar = find_next_zero_bit(&free_bar, 6, bar); if (free_bar > 5) return NO_BAR; return free_bar; } EXPORT_SYMBOL_GPL(pci_epc_get_next_free_bar); /** * pci_epc_get_features() - get the features supported by EPC * @epc: the features supported by *this* EPC device will be returned * @func_no: the features supported by the EPC device specific to the * endpoint function with func_no will be returned * @vfunc_no: the features supported by the EPC device specific to the * virtual endpoint function with vfunc_no will be returned * * Invoke to get the features provided by the EPC which may be * specific to an endpoint function. Returns pci_epc_features on success * and NULL for any failures. */ const struct pci_epc_features *pci_epc_get_features(struct pci_epc *epc, u8 func_no, u8 vfunc_no) { const struct pci_epc_features *epc_features; if (IS_ERR_OR_NULL(epc) || func_no >= epc->max_functions) return NULL; if (vfunc_no > 0 && (!epc->max_vfs || vfunc_no > epc->max_vfs[func_no])) return NULL; if (!epc->ops->get_features) return NULL; mutex_lock(&epc->lock); epc_features = epc->ops->get_features(epc, func_no, vfunc_no); mutex_unlock(&epc->lock); return epc_features; } EXPORT_SYMBOL_GPL(pci_epc_get_features); /** * pci_epc_stop() - stop the PCI link * @epc: the link of the EPC device that has to be stopped * * Invoke to stop the PCI link */ void pci_epc_stop(struct pci_epc *epc) { if (IS_ERR(epc) || !epc->ops->stop) return; mutex_lock(&epc->lock); epc->ops->stop(epc); mutex_unlock(&epc->lock); } EXPORT_SYMBOL_GPL(pci_epc_stop); /** * pci_epc_start() - start the PCI link * @epc: the link of *this* EPC device has to be started * * Invoke to start the PCI link */ int pci_epc_start(struct pci_epc *epc) { int ret; if (IS_ERR(epc)) return -EINVAL; if (!epc->ops->start) return 0; mutex_lock(&epc->lock); ret = epc->ops->start(epc); mutex_unlock(&epc->lock); return ret; } EXPORT_SYMBOL_GPL(pci_epc_start); /** * pci_epc_raise_irq() - interrupt the host system * @epc: the EPC device which has to interrupt the host * @func_no: the physical endpoint function number in the EPC device * @vfunc_no: the virtual endpoint function number in the physical function * @type: specify the type of interrupt; legacy, MSI or MSI-X * @interrupt_num: the MSI or MSI-X interrupt number * * Invoke to raise an legacy, MSI or MSI-X interrupt */ int pci_epc_raise_irq(struct pci_epc *epc, u8 func_no, u8 vfunc_no, enum pci_epc_irq_type type, u16 interrupt_num) { int ret; if (IS_ERR_OR_NULL(epc) || func_no >= epc->max_functions) return -EINVAL; if (vfunc_no > 0 && (!epc->max_vfs || vfunc_no > epc->max_vfs[func_no])) return -EINVAL; if (!epc->ops->raise_irq) return 0; mutex_lock(&epc->lock); ret = epc->ops->raise_irq(epc, func_no, vfunc_no, type, interrupt_num); mutex_unlock(&epc->lock); return ret; } EXPORT_SYMBOL_GPL(pci_epc_raise_irq); /** * pci_epc_map_msi_irq() - Map physical address to MSI address and return * MSI data * @epc: the EPC device which has the MSI capability * @func_no: the physical endpoint function number in the EPC device * @vfunc_no: the virtual endpoint function number in the physical function * @phys_addr: the physical address of the outbound region * @interrupt_num: the MSI interrupt number * @entry_size: Size of Outbound address region for each interrupt * @msi_data: the data that should be written in order to raise MSI interrupt * with interrupt number as 'interrupt num' * @msi_addr_offset: Offset of MSI address from the aligned outbound address * to which the MSI address is mapped * * Invoke to map physical address to MSI address and return MSI data. The * physical address should be an address in the outbound region. This is * required to implement doorbell functionality of NTB wherein EPC on either * side of the interface (primary and secondary) can directly write to the * physical address (in outbound region) of the other interface to ring * doorbell. */ int pci_epc_map_msi_irq(struct pci_epc *epc, u8 func_no, u8 vfunc_no, phys_addr_t phys_addr, u8 interrupt_num, u32 entry_size, u32 *msi_data, u32 *msi_addr_offset) { int ret; if (IS_ERR_OR_NULL(epc)) return -EINVAL; if (vfunc_no > 0 && (!epc->max_vfs || vfunc_no > epc->max_vfs[func_no])) return -EINVAL; if (!epc->ops->map_msi_irq) return -EINVAL; mutex_lock(&epc->lock); ret = epc->ops->map_msi_irq(epc, func_no, vfunc_no, phys_addr, interrupt_num, entry_size, msi_data, msi_addr_offset); mutex_unlock(&epc->lock); return ret; } EXPORT_SYMBOL_GPL(pci_epc_map_msi_irq); /** * pci_epc_get_msi() - get the number of MSI interrupt numbers allocated * @epc: the EPC device to which MSI interrupts was requested * @func_no: the physical endpoint function number in the EPC device * @vfunc_no: the virtual endpoint function number in the physical function * * Invoke to get the number of MSI interrupts allocated by the RC */ int pci_epc_get_msi(struct pci_epc *epc, u8 func_no, u8 vfunc_no) { int interrupt; if (IS_ERR_OR_NULL(epc) || func_no >= epc->max_functions) return 0; if (vfunc_no > 0 && (!epc->max_vfs || vfunc_no > epc->max_vfs[func_no])) return 0; if (!epc->ops->get_msi) return 0; mutex_lock(&epc->lock); interrupt = epc->ops->get_msi(epc, func_no, vfunc_no); mutex_unlock(&epc->lock); if (interrupt < 0) return 0; interrupt = 1 << interrupt; return interrupt; } EXPORT_SYMBOL_GPL(pci_epc_get_msi); /** * pci_epc_set_msi() - set the number of MSI interrupt numbers required * @epc: the EPC device on which MSI has to be configured * @func_no: the physical endpoint function number in the EPC device * @vfunc_no: the virtual endpoint function number in the physical function * @interrupts: number of MSI interrupts required by the EPF * * Invoke to set the required number of MSI interrupts. */ int pci_epc_set_msi(struct pci_epc *epc, u8 func_no, u8 vfunc_no, u8 interrupts) { int ret; u8 encode_int; if (IS_ERR_OR_NULL(epc) || func_no >= epc->max_functions || interrupts < 1 || interrupts > 32) return -EINVAL; if (vfunc_no > 0 && (!epc->max_vfs || vfunc_no > epc->max_vfs[func_no])) return -EINVAL; if (!epc->ops->set_msi) return 0; encode_int = order_base_2(interrupts); mutex_lock(&epc->lock); ret = epc->ops->set_msi(epc, func_no, vfunc_no, encode_int); mutex_unlock(&epc->lock); return ret; } EXPORT_SYMBOL_GPL(pci_epc_set_msi); /** * pci_epc_get_msix() - get the number of MSI-X interrupt numbers allocated * @epc: the EPC device to which MSI-X interrupts was requested * @func_no: the physical endpoint function number in the EPC device * @vfunc_no: the virtual endpoint function number in the physical function * * Invoke to get the number of MSI-X interrupts allocated by the RC */ int pci_epc_get_msix(struct pci_epc *epc, u8 func_no, u8 vfunc_no) { int interrupt; if (IS_ERR_OR_NULL(epc) || func_no >= epc->max_functions) return 0; if (vfunc_no > 0 && (!epc->max_vfs || vfunc_no > epc->max_vfs[func_no])) return 0; if (!epc->ops->get_msix) return 0; mutex_lock(&epc->lock); interrupt = epc->ops->get_msix(epc, func_no, vfunc_no); mutex_unlock(&epc->lock); if (interrupt < 0) return 0; return interrupt + 1; } EXPORT_SYMBOL_GPL(pci_epc_get_msix); /** * pci_epc_set_msix() - set the number of MSI-X interrupt numbers required * @epc: the EPC device on which MSI-X has to be configured * @func_no: the physical endpoint function number in the EPC device * @vfunc_no: the virtual endpoint function number in the physical function * @interrupts: number of MSI-X interrupts required by the EPF * @bir: BAR where the MSI-X table resides * @offset: Offset pointing to the start of MSI-X table * * Invoke to set the required number of MSI-X interrupts. */ int pci_epc_set_msix(struct pci_epc *epc, u8 func_no, u8 vfunc_no, u16 interrupts, enum pci_barno bir, u32 offset) { int ret; if (IS_ERR_OR_NULL(epc) || func_no >= epc->max_functions || interrupts < 1 || interrupts > 2048) return -EINVAL; if (vfunc_no > 0 && (!epc->max_vfs || vfunc_no > epc->max_vfs[func_no])) return -EINVAL; if (!epc->ops->set_msix) return 0; mutex_lock(&epc->lock); ret = epc->ops->set_msix(epc, func_no, vfunc_no, interrupts - 1, bir, offset); mutex_unlock(&epc->lock); return ret; } EXPORT_SYMBOL_GPL(pci_epc_set_msix); /** * pci_epc_unmap_addr() - unmap CPU address from PCI address * @epc: the EPC device on which address is allocated * @func_no: the physical endpoint function number in the EPC device * @vfunc_no: the virtual endpoint function number in the physical function * @phys_addr: physical address of the local system * * Invoke to unmap the CPU address from PCI address. */ void pci_epc_unmap_addr(struct pci_epc *epc, u8 func_no, u8 vfunc_no, phys_addr_t phys_addr) { if (IS_ERR_OR_NULL(epc) || func_no >= epc->max_functions) return; if (vfunc_no > 0 && (!epc->max_vfs || vfunc_no > epc->max_vfs[func_no])) return; if (!epc->ops->unmap_addr) return; mutex_lock(&epc->lock); epc->ops->unmap_addr(epc, func_no, vfunc_no, phys_addr); mutex_unlock(&epc->lock); } EXPORT_SYMBOL_GPL(pci_epc_unmap_addr); /** * pci_epc_map_addr() - map CPU address to PCI address * @epc: the EPC device on which address is allocated * @func_no: the physical endpoint function number in the EPC device * @vfunc_no: the virtual endpoint function number in the physical function * @phys_addr: physical address of the local system * @pci_addr: PCI address to which the physical address should be mapped * @size: the size of the allocation * * Invoke to map CPU address with PCI address. */ int pci_epc_map_addr(struct pci_epc *epc, u8 func_no, u8 vfunc_no, phys_addr_t phys_addr, u64 pci_addr, size_t size) { int ret; if (IS_ERR_OR_NULL(epc) || func_no >= epc->max_functions) return -EINVAL; if (vfunc_no > 0 && (!epc->max_vfs || vfunc_no > epc->max_vfs[func_no])) return -EINVAL; if (!epc->ops->map_addr) return 0; mutex_lock(&epc->lock); ret = epc->ops->map_addr(epc, func_no, vfunc_no, phys_addr, pci_addr, size); mutex_unlock(&epc->lock); return ret; } EXPORT_SYMBOL_GPL(pci_epc_map_addr); /** * pci_epc_clear_bar() - reset the BAR * @epc: the EPC device for which the BAR has to be cleared * @func_no: the physical endpoint function number in the EPC device * @vfunc_no: the virtual endpoint function number in the physical function * @epf_bar: the struct epf_bar that contains the BAR information * * Invoke to reset the BAR of the endpoint device. */ void pci_epc_clear_bar(struct pci_epc *epc, u8 func_no, u8 vfunc_no, struct pci_epf_bar *epf_bar) { if (IS_ERR_OR_NULL(epc) || func_no >= epc->max_functions || (epf_bar->barno == BAR_5 && epf_bar->flags & PCI_BASE_ADDRESS_MEM_TYPE_64)) return; if (vfunc_no > 0 && (!epc->max_vfs || vfunc_no > epc->max_vfs[func_no])) return; if (!epc->ops->clear_bar) return; mutex_lock(&epc->lock); epc->ops->clear_bar(epc, func_no, vfunc_no, epf_bar); mutex_unlock(&epc->lock); } EXPORT_SYMBOL_GPL(pci_epc_clear_bar); /** * pci_epc_set_bar() - configure BAR in order for host to assign PCI addr space * @epc: the EPC device on which BAR has to be configured * @func_no: the physical endpoint function number in the EPC device * @vfunc_no: the virtual endpoint function number in the physical function * @epf_bar: the struct epf_bar that contains the BAR information * * Invoke to configure the BAR of the endpoint device. */ int pci_epc_set_bar(struct pci_epc *epc, u8 func_no, u8 vfunc_no, struct pci_epf_bar *epf_bar) { int ret; int flags = epf_bar->flags; if (IS_ERR_OR_NULL(epc) || func_no >= epc->max_functions || (epf_bar->barno == BAR_5 && flags & PCI_BASE_ADDRESS_MEM_TYPE_64) || (flags & PCI_BASE_ADDRESS_SPACE_IO && flags & PCI_BASE_ADDRESS_IO_MASK) || (upper_32_bits(epf_bar->size) && !(flags & PCI_BASE_ADDRESS_MEM_TYPE_64))) return -EINVAL; if (vfunc_no > 0 && (!epc->max_vfs || vfunc_no > epc->max_vfs[func_no])) return -EINVAL; if (!epc->ops->set_bar) return 0; mutex_lock(&epc->lock); ret = epc->ops->set_bar(epc, func_no, vfunc_no, epf_bar); mutex_unlock(&epc->lock); return ret; } EXPORT_SYMBOL_GPL(pci_epc_set_bar); /** * pci_epc_write_header() - write standard configuration header * @epc: the EPC device to which the configuration header should be written * @func_no: the physical endpoint function number in the EPC device * @vfunc_no: the virtual endpoint function number in the physical function * @header: standard configuration header fields * * Invoke to write the configuration header to the endpoint controller. Every * endpoint controller will have a dedicated location to which the standard * configuration header would be written. The callback function should write * the header fields to this dedicated location. */ int pci_epc_write_header(struct pci_epc *epc, u8 func_no, u8 vfunc_no, struct pci_epf_header *header) { int ret; if (IS_ERR_OR_NULL(epc) || func_no >= epc->max_functions) return -EINVAL; if (vfunc_no > 0 && (!epc->max_vfs || vfunc_no > epc->max_vfs[func_no])) return -EINVAL; /* Only Virtual Function #1 has deviceID */ if (vfunc_no > 1) return -EINVAL; if (!epc->ops->write_header) return 0; mutex_lock(&epc->lock); ret = epc->ops->write_header(epc, func_no, vfunc_no, header); mutex_unlock(&epc->lock); return ret; } EXPORT_SYMBOL_GPL(pci_epc_write_header); /** * pci_epc_add_epf() - bind PCI endpoint function to an endpoint controller * @epc: the EPC device to which the endpoint function should be added * @epf: the endpoint function to be added * @type: Identifies if the EPC is connected to the primary or secondary * interface of EPF * * A PCI endpoint device can have one or more functions. In the case of PCIe, * the specification allows up to 8 PCIe endpoint functions. Invoke * pci_epc_add_epf() to add a PCI endpoint function to an endpoint controller. */ int pci_epc_add_epf(struct pci_epc *epc, struct pci_epf *epf, enum pci_epc_interface_type type) { struct list_head *list; u32 func_no; int ret = 0; if (IS_ERR_OR_NULL(epc) || epf->is_vf) return -EINVAL; if (type == PRIMARY_INTERFACE && epf->epc) return -EBUSY; if (type == SECONDARY_INTERFACE && epf->sec_epc) return -EBUSY; mutex_lock(&epc->lock); func_no = find_first_zero_bit(&epc->function_num_map, BITS_PER_LONG); if (func_no >= BITS_PER_LONG) { ret = -EINVAL; goto ret; } if (func_no > epc->max_functions - 1) { dev_err(&epc->dev, "Exceeding max supported Function Number\n"); ret = -EINVAL; goto ret; } set_bit(func_no, &epc->function_num_map); if (type == PRIMARY_INTERFACE) { epf->func_no = func_no; epf->epc = epc; list = &epf->list; } else { epf->sec_epc_func_no = func_no; epf->sec_epc = epc; list = &epf->sec_epc_list; } list_add_tail(list, &epc->pci_epf); ret: mutex_unlock(&epc->lock); return ret; } EXPORT_SYMBOL_GPL(pci_epc_add_epf); /** * pci_epc_remove_epf() - remove PCI endpoint function from endpoint controller * @epc: the EPC device from which the endpoint function should be removed * @epf: the endpoint function to be removed * @type: identifies if the EPC is connected to the primary or secondary * interface of EPF * * Invoke to remove PCI endpoint function from the endpoint controller. */ void pci_epc_remove_epf(struct pci_epc *epc, struct pci_epf *epf, enum pci_epc_interface_type type) { struct list_head *list; u32 func_no = 0; if (!epc || IS_ERR(epc) || !epf) return; if (type == PRIMARY_INTERFACE) { func_no = epf->func_no; list = &epf->list; } else { func_no = epf->sec_epc_func_no; list = &epf->sec_epc_list; } mutex_lock(&epc->lock); clear_bit(func_no, &epc->function_num_map); list_del(list); epf->epc = NULL; mutex_unlock(&epc->lock); } EXPORT_SYMBOL_GPL(pci_epc_remove_epf); /** * pci_epc_linkup() - Notify the EPF device that EPC device has established a * connection with the Root Complex. * @epc: the EPC device which has established link with the host * * Invoke to Notify the EPF device that the EPC device has established a * connection with the Root Complex. */ void pci_epc_linkup(struct pci_epc *epc) { if (!epc || IS_ERR(epc)) return; atomic_notifier_call_chain(&epc->notifier, LINK_UP, NULL); } EXPORT_SYMBOL_GPL(pci_epc_linkup); /** * pci_epc_init_notify() - Notify the EPF device that EPC device's core * initialization is completed. * @epc: the EPC device whose core initialization is completed * * Invoke to Notify the EPF device that the EPC device's initialization * is completed. */ void pci_epc_init_notify(struct pci_epc *epc) { if (!epc || IS_ERR(epc)) return; atomic_notifier_call_chain(&epc->notifier, CORE_INIT, NULL); } EXPORT_SYMBOL_GPL(pci_epc_init_notify); /** * pci_epc_destroy() - destroy the EPC device * @epc: the EPC device that has to be destroyed * * Invoke to destroy the PCI EPC device */ void pci_epc_destroy(struct pci_epc *epc) { pci_ep_cfs_remove_epc_group(epc->group); device_unregister(&epc->dev); } EXPORT_SYMBOL_GPL(pci_epc_destroy); /** * devm_pci_epc_destroy() - destroy the EPC device * @dev: device that wants to destroy the EPC * @epc: the EPC device that has to be destroyed * * Invoke to destroy the devres associated with this * pci_epc and destroy the EPC device. */ void devm_pci_epc_destroy(struct device *dev, struct pci_epc *epc) { int r; r = devres_destroy(dev, devm_pci_epc_release, devm_pci_epc_match, epc); dev_WARN_ONCE(dev, r, "couldn't find PCI EPC resource\n"); } EXPORT_SYMBOL_GPL(devm_pci_epc_destroy); static void pci_epc_release(struct device *dev) { kfree(to_pci_epc(dev)); } /** * __pci_epc_create() - create a new endpoint controller (EPC) device * @dev: device that is creating the new EPC * @ops: function pointers for performing EPC operations * @owner: the owner of the module that creates the EPC device * * Invoke to create a new EPC device and add it to pci_epc class. */ struct pci_epc * __pci_epc_create(struct device *dev, const struct pci_epc_ops *ops, struct module *owner) { int ret; struct pci_epc *epc; if (WARN_ON(!dev)) { ret = -EINVAL; goto err_ret; } epc = kzalloc(sizeof(*epc), GFP_KERNEL); if (!epc) { ret = -ENOMEM; goto err_ret; } mutex_init(&epc->lock); INIT_LIST_HEAD(&epc->pci_epf); ATOMIC_INIT_NOTIFIER_HEAD(&epc->notifier); device_initialize(&epc->dev); epc->dev.class = pci_epc_class; epc->dev.parent = dev; epc->dev.release = pci_epc_release; epc->ops = ops; ret = dev_set_name(&epc->dev, "%s", dev_name(dev)); if (ret) goto put_dev; ret = device_add(&epc->dev); if (ret) goto put_dev; epc->group = pci_ep_cfs_add_epc_group(dev_name(dev)); return epc; put_dev: put_device(&epc->dev); kfree(epc); err_ret: return ERR_PTR(ret); } EXPORT_SYMBOL_GPL(__pci_epc_create); /** * __devm_pci_epc_create() - create a new endpoint controller (EPC) device * @dev: device that is creating the new EPC * @ops: function pointers for performing EPC operations * @owner: the owner of the module that creates the EPC device * * Invoke to create a new EPC device and add it to pci_epc class. * While at that, it also associates the device with the pci_epc using devres. * On driver detach, release function is invoked on the devres data, * then, devres data is freed. */ struct pci_epc * __devm_pci_epc_create(struct device *dev, const struct pci_epc_ops *ops, struct module *owner) { struct pci_epc **ptr, *epc; ptr = devres_alloc(devm_pci_epc_release, sizeof(*ptr), GFP_KERNEL); if (!ptr) return ERR_PTR(-ENOMEM); epc = __pci_epc_create(dev, ops, owner); if (!IS_ERR(epc)) { *ptr = epc; devres_add(dev, ptr); } else { devres_free(ptr); } return epc; } EXPORT_SYMBOL_GPL(__devm_pci_epc_create); static int __init pci_epc_init(void) { pci_epc_class = class_create(THIS_MODULE, "pci_epc"); if (IS_ERR(pci_epc_class)) { pr_err("failed to create pci epc class --> %ld\n", PTR_ERR(pci_epc_class)); return PTR_ERR(pci_epc_class); } return 0; } module_init(pci_epc_init); static void __exit pci_epc_exit(void) { class_destroy(pci_epc_class); } module_exit(pci_epc_exit); MODULE_DESCRIPTION("PCI EPC Library"); MODULE_AUTHOR("Kishon Vijay Abraham I <kishon@ti.com>"); MODULE_LICENSE("GPL v2");
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