Server : Apache/2.4.41 (Ubuntu) System : Linux journalup 5.4.0-198-generic #218-Ubuntu SMP Fri Sep 27 20:18:53 UTC 2024 x86_64 User : www-data ( 33) PHP Version : 7.4.33 Disable Function : pcntl_alarm,pcntl_fork,pcntl_waitpid,pcntl_wait,pcntl_wifexited,pcntl_wifstopped,pcntl_wifsignaled,pcntl_wifcontinued,pcntl_wexitstatus,pcntl_wtermsig,pcntl_wstopsig,pcntl_signal,pcntl_signal_get_handler,pcntl_signal_dispatch,pcntl_get_last_error,pcntl_strerror,pcntl_sigprocmask,pcntl_sigwaitinfo,pcntl_sigtimedwait,pcntl_exec,pcntl_getpriority,pcntl_setpriority,pcntl_async_signals,pcntl_unshare, Directory : /usr/src/linux-headers-5.4.0-200/include/misc/ |
// SPDX-License-Identifier: GPL-2.0+ // Copyright 2017 IBM Corp. #ifndef _MISC_OCXL_H_ #define _MISC_OCXL_H_ #include <linux/pci.h> /* * Opencapi drivers all need some common facilities, like parsing the * device configuration space, adding a Process Element to the Shared * Process Area, etc... * * The ocxl module provides a kernel API, to allow other drivers to * reuse common code. A bit like a in-kernel library. */ #define OCXL_AFU_NAME_SZ (24+1) /* add 1 for NULL termination */ struct ocxl_afu_config { u8 idx; int dvsec_afu_control_pos; /* offset of AFU control DVSEC */ char name[OCXL_AFU_NAME_SZ]; u8 version_major; u8 version_minor; u8 afuc_type; u8 afum_type; u8 profile; u8 global_mmio_bar; /* global MMIO area */ u64 global_mmio_offset; u32 global_mmio_size; u8 pp_mmio_bar; /* per-process MMIO area */ u64 pp_mmio_offset; u32 pp_mmio_stride; u64 lpc_mem_offset; u64 lpc_mem_size; u64 special_purpose_mem_offset; u64 special_purpose_mem_size; u8 pasid_supported_log; u16 actag_supported; }; struct ocxl_fn_config { int dvsec_tl_pos; /* offset of the Transaction Layer DVSEC */ int dvsec_function_pos; /* offset of the Function DVSEC */ int dvsec_afu_info_pos; /* offset of the AFU information DVSEC */ s8 max_pasid_log; s8 max_afu_index; }; enum ocxl_endian { OCXL_BIG_ENDIAN = 0, /**< AFU data is big-endian */ OCXL_LITTLE_ENDIAN = 1, /**< AFU data is little-endian */ OCXL_HOST_ENDIAN = 2, /**< AFU data is the same endianness as the host */ }; // These are opaque outside the ocxl driver struct ocxl_afu; struct ocxl_fn; struct ocxl_context; // Device detection & initialisation /** * Open an OpenCAPI function on an OpenCAPI device * * @dev: The PCI device that contains the function * * Returns an opaque pointer to the function, or an error pointer (check with IS_ERR) */ struct ocxl_fn *ocxl_function_open(struct pci_dev *dev); /** * Get the list of AFUs associated with a PCI function device * * Returns a list of struct ocxl_afu * * * @fn: The OpenCAPI function containing the AFUs */ struct list_head *ocxl_function_afu_list(struct ocxl_fn *fn); /** * Fetch an AFU instance from an OpenCAPI function * * @fn: The OpenCAPI function to get the AFU from * @afu_idx: The index of the AFU to get * * If successful, the AFU should be released with ocxl_afu_put() * * Returns a pointer to the AFU, or NULL on error */ struct ocxl_afu *ocxl_function_fetch_afu(struct ocxl_fn *fn, u8 afu_idx); /** * Take a reference to an AFU * * @afu: The AFU to increment the reference count on */ void ocxl_afu_get(struct ocxl_afu *afu); /** * Release a reference to an AFU * * @afu: The AFU to decrement the reference count on */ void ocxl_afu_put(struct ocxl_afu *afu); /** * Get the configuration information for an OpenCAPI function * * @fn: The OpenCAPI function to get the config for * * Returns the function config, or NULL on error */ const struct ocxl_fn_config *ocxl_function_config(struct ocxl_fn *fn); /** * Close an OpenCAPI function * * This will free any AFUs previously retrieved from the function, and * detach and associated contexts. The contexts must by freed by the caller. * * @fn: The OpenCAPI function to close * */ void ocxl_function_close(struct ocxl_fn *fn); // Context allocation /** * Allocate an OpenCAPI context * * @context: The OpenCAPI context to allocate, must be freed with ocxl_context_free * @afu: The AFU the context belongs to * @mapping: The mapping to unmap when the context is closed (may be NULL) */ int ocxl_context_alloc(struct ocxl_context **context, struct ocxl_afu *afu, struct address_space *mapping); /** * Free an OpenCAPI context * * @ctx: The OpenCAPI context to free */ void ocxl_context_free(struct ocxl_context *ctx); /** * Grant access to an MM to an OpenCAPI context * @ctx: The OpenCAPI context to attach * @amr: The value of the AMR register to restrict access * @mm: The mm to attach to the context * * Returns 0 on success, negative on failure */ int ocxl_context_attach(struct ocxl_context *ctx, u64 amr, struct mm_struct *mm); /** * Detach an MM from an OpenCAPI context * @ctx: The OpenCAPI context to attach * * Returns 0 on success, negative on failure */ int ocxl_context_detach(struct ocxl_context *ctx); // AFU IRQs /** * Allocate an IRQ associated with an AFU context * @ctx: the AFU context * @irq_id: out, the IRQ ID * * Returns 0 on success, negative on failure */ extern int ocxl_afu_irq_alloc(struct ocxl_context *ctx, int *irq_id); /** * Frees an IRQ associated with an AFU context * @ctx: the AFU context * @irq_id: the IRQ ID * * Returns 0 on success, negative on failure */ extern int ocxl_afu_irq_free(struct ocxl_context *ctx, int irq_id); /** * Gets the address of the trigger page for an IRQ * This can then be provided to an AFU which will write to that * page to trigger the IRQ. * @ctx: The AFU context that the IRQ is associated with * @irq_id: The IRQ ID * * returns the trigger page address, or 0 if the IRQ is not valid */ extern u64 ocxl_afu_irq_get_addr(struct ocxl_context *ctx, int irq_id); /** * Provide a callback to be called when an IRQ is triggered * @ctx: The AFU context that the IRQ is associated with * @irq_id: The IRQ ID * @handler: the callback to be called when the IRQ is triggered * @free_private: the callback to be called when the IRQ is freed (may be NULL) * @private: Private data to be passed to the callbacks * * Returns 0 on success, negative on failure */ int ocxl_irq_set_handler(struct ocxl_context *ctx, int irq_id, irqreturn_t (*handler)(void *private), void (*free_private)(void *private), void *private); // AFU Metadata /** * Get a pointer to the config for an AFU * * @afu: a pointer to the AFU to get the config for * * Returns a pointer to the AFU config */ struct ocxl_afu_config *ocxl_afu_config(struct ocxl_afu *afu); /** * Assign opaque hardware specific information to an OpenCAPI AFU. * * @dev: The PCI device associated with the OpenCAPI device * @private: the opaque hardware specific information to assign to the driver */ void ocxl_afu_set_private(struct ocxl_afu *afu, void *private); /** * Fetch the hardware specific information associated with an external OpenCAPI * AFU. This may be consumed by an external OpenCAPI driver. * * @afu: The AFU * * Returns the opaque pointer associated with the device, or NULL if not set */ void *ocxl_afu_get_private(struct ocxl_afu *dev); // Global MMIO /** * Read a 32 bit value from global MMIO * * @afu: The AFU * @offset: The Offset from the start of MMIO * @endian: the endianness that the MMIO data is in * @val: returns the value * * Returns 0 for success, negative on error */ int ocxl_global_mmio_read32(struct ocxl_afu *afu, size_t offset, enum ocxl_endian endian, u32 *val); /** * Read a 64 bit value from global MMIO * * @afu: The AFU * @offset: The Offset from the start of MMIO * @endian: the endianness that the MMIO data is in * @val: returns the value * * Returns 0 for success, negative on error */ int ocxl_global_mmio_read64(struct ocxl_afu *afu, size_t offset, enum ocxl_endian endian, u64 *val); /** * Write a 32 bit value to global MMIO * * @afu: The AFU * @offset: The Offset from the start of MMIO * @endian: the endianness that the MMIO data is in * @val: The value to write * * Returns 0 for success, negative on error */ int ocxl_global_mmio_write32(struct ocxl_afu *afu, size_t offset, enum ocxl_endian endian, u32 val); /** * Write a 64 bit value to global MMIO * * @afu: The AFU * @offset: The Offset from the start of MMIO * @endian: the endianness that the MMIO data is in * @val: The value to write * * Returns 0 for success, negative on error */ int ocxl_global_mmio_write64(struct ocxl_afu *afu, size_t offset, enum ocxl_endian endian, u64 val); /** * Set bits in a 32 bit global MMIO register * * @afu: The AFU * @offset: The Offset from the start of MMIO * @endian: the endianness that the MMIO data is in * @mask: a mask of the bits to set * * Returns 0 for success, negative on error */ int ocxl_global_mmio_set32(struct ocxl_afu *afu, size_t offset, enum ocxl_endian endian, u32 mask); /** * Set bits in a 64 bit global MMIO register * * @afu: The AFU * @offset: The Offset from the start of MMIO * @endian: the endianness that the MMIO data is in * @mask: a mask of the bits to set * * Returns 0 for success, negative on error */ int ocxl_global_mmio_set64(struct ocxl_afu *afu, size_t offset, enum ocxl_endian endian, u64 mask); /** * Set bits in a 32 bit global MMIO register * * @afu: The AFU * @offset: The Offset from the start of MMIO * @endian: the endianness that the MMIO data is in * @mask: a mask of the bits to set * * Returns 0 for success, negative on error */ int ocxl_global_mmio_clear32(struct ocxl_afu *afu, size_t offset, enum ocxl_endian endian, u32 mask); /** * Set bits in a 64 bit global MMIO register * * @afu: The AFU * @offset: The Offset from the start of MMIO * @endian: the endianness that the MMIO data is in * @mask: a mask of the bits to set * * Returns 0 for success, negative on error */ int ocxl_global_mmio_clear64(struct ocxl_afu *afu, size_t offset, enum ocxl_endian endian, u64 mask); // Functions left here are for compatibility with the cxlflash driver /* * Read the configuration space of a function for the AFU specified by * the index 'afu_idx'. Fills in a ocxl_afu_config structure */ int ocxl_config_read_afu(struct pci_dev *dev, struct ocxl_fn_config *fn, struct ocxl_afu_config *afu, u8 afu_idx); /* * Tell an AFU, by writing in the configuration space, the PASIDs that * it can use. Range starts at 'pasid_base' and its size is a multiple * of 2 * * 'afu_control_offset' is the offset of the AFU control DVSEC which * can be found in the function configuration */ void ocxl_config_set_afu_pasid(struct pci_dev *dev, int afu_control_offset, int pasid_base, u32 pasid_count_log); /* * Get the actag configuration for the function: * 'base' is the first actag value that can be used. * 'enabled' it the number of actags available, starting from base. * 'supported' is the total number of actags desired by all the AFUs * of the function. */ int ocxl_config_get_actag_info(struct pci_dev *dev, u16 *base, u16 *enabled, u16 *supported); /* * Tell a function, by writing in the configuration space, the actags * it can use. * * 'func_offset' is the offset of the Function DVSEC that can found in * the function configuration */ void ocxl_config_set_actag(struct pci_dev *dev, int func_offset, u32 actag_base, u32 actag_count); /* * Tell an AFU, by writing in the configuration space, the actags it * can use. * * 'afu_control_offset' is the offset of the AFU control DVSEC for the * desired AFU. It can be found in the AFU configuration */ void ocxl_config_set_afu_actag(struct pci_dev *dev, int afu_control_offset, int actag_base, int actag_count); /* * Enable/disable an AFU, by writing in the configuration space. * * 'afu_control_offset' is the offset of the AFU control DVSEC for the * desired AFU. It can be found in the AFU configuration */ void ocxl_config_set_afu_state(struct pci_dev *dev, int afu_control_offset, int enable); /* * Set the Transaction Layer configuration in the configuration space. * Only needed for function 0. * * It queries the host TL capabilities, find some common ground * between the host and device, and set the Transaction Layer on both * accordingly. */ int ocxl_config_set_TL(struct pci_dev *dev, int tl_dvsec); /* * Request an AFU to terminate a PASID. * Will return once the AFU has acked the request, or an error in case * of timeout. * * The hardware can only terminate one PASID at a time, so caller must * guarantee some kind of serialization. * * 'afu_control_offset' is the offset of the AFU control DVSEC for the * desired AFU. It can be found in the AFU configuration */ int ocxl_config_terminate_pasid(struct pci_dev *dev, int afu_control_offset, int pasid); /* * Read the configuration space of a function and fill in a * ocxl_fn_config structure with all the function details */ int ocxl_config_read_function(struct pci_dev *dev, struct ocxl_fn_config *fn); /* * Set up the opencapi link for the function. * * When called for the first time for a link, it sets up the Shared * Process Area for the link and the interrupt handler to process * translation faults. * * Returns a 'link handle' that should be used for further calls for * the link */ int ocxl_link_setup(struct pci_dev *dev, int PE_mask, void **link_handle); /* * Remove the association between the function and its link. */ void ocxl_link_release(struct pci_dev *dev, void *link_handle); /* * Add a Process Element to the Shared Process Area for a link. * The process is defined by its PASID, pid, tid and its mm_struct. * * 'xsl_err_cb' is an optional callback if the driver wants to be * notified when the translation fault interrupt handler detects an * address error. * 'xsl_err_data' is an argument passed to the above callback, if * defined */ int ocxl_link_add_pe(void *link_handle, int pasid, u32 pidr, u32 tidr, u64 amr, struct mm_struct *mm, void (*xsl_err_cb)(void *data, u64 addr, u64 dsisr), void *xsl_err_data); /* * Remove a Process Element from the Shared Process Area for a link */ int ocxl_link_remove_pe(void *link_handle, int pasid); /* * Allocate an AFU interrupt associated to the link. * * 'hw_irq' is the hardware interrupt number * 'obj_handle' is the 64-bit object handle to be passed to the AFU to * trigger the interrupt. * On P9, 'obj_handle' is an address, which, if written, triggers the * interrupt. It is an MMIO address which needs to be remapped (one * page). */ int ocxl_link_irq_alloc(void *link_handle, int *hw_irq, u64 *obj_handle); /* * Free a previously allocated AFU interrupt */ void ocxl_link_free_irq(void *link_handle, int hw_irq); #endif /* _MISC_OCXL_H_ */