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a1ce39288e
Convert #include "..." to #include <path/...> in kernel system headers. Signed-off-by: David Howells <dhowells@redhat.com> Acked-by: Arnd Bergmann <arnd@arndb.de> Acked-by: Thomas Gleixner <tglx@linutronix.de> Acked-by: Paul E. McKenney <paulmck@linux.vnet.ibm.com> Acked-by: Dave Jones <davej@redhat.com>
715 lines
25 KiB
C
715 lines
25 KiB
C
/*
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* Copyright 2012 Tilera Corporation. All Rights Reserved.
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation, version 2.
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*
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* This program is distributed in the hope that it will be useful, but
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* WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE, GOOD TITLE or
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* NON INFRINGEMENT. See the GNU General Public License for
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* more details.
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*/
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#ifndef _HV_IORPC_H_
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#define _HV_IORPC_H_
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/**
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*
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* Error codes and struct definitions for the IO RPC library.
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*
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* The hypervisor's IO RPC component provides a convenient way for
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* driver authors to proxy system calls between user space, linux, and
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* the hypervisor driver. The core of the system is a set of Python
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* files that take ".idl" files as input and generates the following
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* source code:
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*
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* - _rpc_call() routines for use in userspace IO libraries. These
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* routines take an argument list specified in the .idl file, pack the
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* arguments in to a buffer, and read or write that buffer via the
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* Linux iorpc driver.
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*
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* - dispatch_read() and dispatch_write() routines that hypervisor
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* drivers can use to implement most of their dev_pread() and
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* dev_pwrite() methods. These routines decode the incoming parameter
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* blob, permission check and translate parameters where appropriate,
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* and then invoke a callback routine for whichever RPC call has
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* arrived. The driver simply implements the set of callback
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* routines.
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*
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* The IO RPC system also includes the Linux 'iorpc' driver, which
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* proxies calls between the userspace library and the hypervisor
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* driver. The Linux driver is almost entirely device agnostic; it
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* watches for special flags indicating cases where a memory buffer
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* address might need to be translated, etc. As a result, driver
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* writers can avoid many of the problem cases related to registering
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* hardware resources like memory pages or interrupts. However, the
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* drivers must be careful to obey the conventions documented below in
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* order to work properly with the generic Linux iorpc driver.
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*
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* @section iorpc_domains Service Domains
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*
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* All iorpc-based drivers must support a notion of service domains.
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* A service domain is basically an application context - state
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* indicating resources that are allocated to that particular app
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* which it may access and (perhaps) other applications may not
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* access. Drivers can support any number of service domains they
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* choose. In some cases the design is limited by a number of service
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* domains supported by the IO hardware; in other cases the service
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* domains are a purely software concept and the driver chooses a
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* maximum number of domains based on how much state memory it is
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* willing to preallocate.
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*
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* For example, the mPIPE driver only supports as many service domains
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* as are supported by the mPIPE hardware. This limitation is
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* required because the hardware implements its own MMIO protection
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* scheme to allow large MMIO mappings while still protecting small
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* register ranges within the page that should only be accessed by the
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* hypervisor.
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*
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* In contrast, drivers with no hardware service domain limitations
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* (for instance the TRIO shim) can implement an arbitrary number of
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* service domains. In these cases, each service domain is limited to
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* a carefully restricted set of legal MMIO addresses if necessary to
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* keep one application from corrupting another application's state.
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*
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* @section iorpc_conventions System Call Conventions
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*
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* The driver's open routine is responsible for allocating a new
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* service domain for each hv_dev_open() call. By convention, the
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* return value from open() should be the service domain number on
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* success, or GXIO_ERR_NO_SVC_DOM if no more service domains are
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* available.
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*
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* The implementations of hv_dev_pread() and hv_dev_pwrite() are
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* responsible for validating the devhdl value passed up by the
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* client. Since the device handle returned by hv_dev_open() should
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* embed the positive service domain number, drivers should make sure
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* that DRV_HDL2BITS(devhdl) is a legal service domain. If the client
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* passes an illegal service domain number, the routine should return
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* GXIO_ERR_INVAL_SVC_DOM. Once the service domain number has been
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* validated, the driver can copy to/from the client buffer and call
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* the dispatch_read() or dispatch_write() methods created by the RPC
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* generator.
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*
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* The hv_dev_close() implementation should reset all service domain
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* state and put the service domain back on a free list for
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* reallocation by a future application. In most cases, this will
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* require executing a hardware reset or drain flow and denying any
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* MMIO regions that were created for the service domain.
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*
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* @section iorpc_data Special Data Types
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*
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* The .idl file syntax allows the creation of syscalls with special
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* parameters that require permission checks or translations as part
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* of the system call path. Because of limitations in the code
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* generator, APIs are generally limited to just one of these special
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* parameters per system call, and they are sometimes required to be
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* the first or last parameter to the call. Special parameters
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* include:
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*
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* @subsection iorpc_mem_buffer MEM_BUFFER
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*
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* The MEM_BUFFER() datatype allows user space to "register" memory
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* buffers with a device. Registering memory accomplishes two tasks:
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* Linux keeps track of all buffers that might be modified by a
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* hardware device, and the hardware device drivers bind registered
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* buffers to particular hardware resources like ingress NotifRings.
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* The MEM_BUFFER() idl syntax can take extra flags like ALIGN_64KB,
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* ALIGN_SELF_SIZE, and FLAGS indicating that memory buffers must have
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* certain alignment or that the user should be able to pass a "memory
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* flags" word specifying attributes like nt_hint or IO cache pinning.
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* The parser will accept multiple MEM_BUFFER() flags.
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*
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* Implementations must obey the following conventions when
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* registering memory buffers via the iorpc flow. These rules are a
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* result of the Linux driver implementation, which needs to keep
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* track of how many times a particular page has been registered with
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* the hardware so that it can release the page when all those
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* registrations are cleared.
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*
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* - Memory registrations that refer to a resource which has already
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* been bound must return GXIO_ERR_ALREADY_INIT. Thus, it is an
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* error to register memory twice without resetting (i.e. closing) the
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* resource in between. This convention keeps the Linux driver from
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* having to track which particular devices a page is bound to.
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*
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* - At present, a memory registration is only cleared when the
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* service domain is reset. In this case, the Linux driver simply
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* closes the HV device file handle and then decrements the reference
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* counts of all pages that were previously registered with the
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* device.
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*
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* - In the future, we may add a mechanism for unregistering memory.
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* One possible implementation would require that the user specify
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* which buffer is currently registered. The HV would then verify
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* that that page was actually the one currently mapped and return
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* success or failure to Linux, which would then only decrement the
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* page reference count if the addresses were mapped. Another scheme
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* might allow Linux to pass a token to the HV to be returned when the
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* resource is unmapped.
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*
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* @subsection iorpc_interrupt INTERRUPT
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*
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* The INTERRUPT .idl datatype allows the client to bind hardware
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* interrupts to a particular combination of IPI parameters - CPU, IPI
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* PL, and event bit number. This data is passed via a special
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* datatype so that the Linux driver can validate the CPU and PL and
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* the HV generic iorpc code can translate client CPUs to real CPUs.
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*
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* @subsection iorpc_pollfd_setup POLLFD_SETUP
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*
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* The POLLFD_SETUP .idl datatype allows the client to set up hardware
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* interrupt bindings which are received by Linux but which are made
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* visible to user processes as state transitions on a file descriptor;
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* this allows user processes to use Linux primitives, such as poll(), to
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* await particular hardware events. This data is passed via a special
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* datatype so that the Linux driver may recognize the pollable file
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* descriptor and translate it to a set of interrupt target information,
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* and so that the HV generic iorpc code can translate client CPUs to real
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* CPUs.
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*
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* @subsection iorpc_pollfd POLLFD
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*
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* The POLLFD .idl datatype allows manipulation of hardware interrupt
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* bindings set up via the POLLFD_SETUP datatype; common operations are
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* resetting the state of the requested interrupt events, and unbinding any
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* bound interrupts. This data is passed via a special datatype so that
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* the Linux driver may recognize the pollable file descriptor and
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* translate it to an interrupt identifier previously supplied by the
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* hypervisor as the result of an earlier pollfd_setup operation.
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*
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* @subsection iorpc_blob BLOB
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*
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* The BLOB .idl datatype allows the client to write an arbitrary
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* length string of bytes up to the hypervisor driver. This can be
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* useful for passing up large, arbitrarily structured data like
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* classifier programs. The iorpc stack takes care of validating the
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* buffer VA and CPA as the data passes up to the hypervisor. Unlike
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* MEM_BUFFER(), the buffer is not registered - Linux does not bump
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* page refcounts and the HV driver should not reuse the buffer once
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* the system call is complete.
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*
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* @section iorpc_translation Translating User Space Calls
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*
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* The ::iorpc_offset structure describes the formatting of the offset
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* that is passed to pread() or pwrite() as part of the generated RPC code.
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* When the user calls up to Linux, the rpc code fills in all the fields of
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* the offset, including a 16-bit opcode, a 16 bit format indicator, and 32
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* bits of user-specified "sub-offset". The opcode indicates which syscall
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* is being requested. The format indicates whether there is a "prefix
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* struct" at the start of the memory buffer passed to pwrite(), and if so
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* what data is in that prefix struct. These prefix structs are used to
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* implement special datatypes like MEM_BUFFER() and INTERRUPT - we arrange
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* to put data that needs translation and permission checks at the start of
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* the buffer so that the Linux driver and generic portions of the HV iorpc
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* code can easily access the data. The 32 bits of user-specified
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* "sub-offset" are most useful for pread() calls where the user needs to
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* also pass in a few bits indicating which register to read, etc.
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*
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* The Linux iorpc driver watches for system calls that contain prefix
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* structs so that it can translate parameters and bump reference
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* counts as appropriate. It does not (currently) have any knowledge
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* of the per-device opcodes - it doesn't care what operation you're
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* doing to mPIPE, so long as it can do all the generic book-keeping.
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* The hv/iorpc.h header file defines all of the generic encoding bits
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* needed to translate iorpc calls without knowing which particular
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* opcode is being issued.
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*
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* @section iorpc_globals Global iorpc Calls
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*
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* Implementing mmap() required adding some special iorpc syscalls
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* that are only called by the Linux driver, never by userspace.
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* These include get_mmio_base() and check_mmio_offset(). These
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* routines are described in globals.idl and must be included in every
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* iorpc driver. By providing these routines in every driver, Linux's
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* mmap implementation can easily get the PTE bits it needs and
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* validate the PA offset without needing to know the per-device
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* opcodes to perform those tasks.
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*
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* @section iorpc_kernel Supporting gxio APIs in the Kernel
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*
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* The iorpc code generator also supports generation of kernel code
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* implementing the gxio APIs. This capability is currently used by
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* the mPIPE network driver, and will likely be used by the TRIO root
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* complex and endpoint drivers and perhaps an in-kernel crypto
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* driver. Each driver that wants to instantiate iorpc calls in the
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* kernel needs to generate a kernel version of the generate rpc code
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* and (probably) copy any related gxio source files into the kernel.
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* The mPIPE driver provides a good example of this pattern.
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*/
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#ifdef __KERNEL__
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#include <linux/stddef.h>
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#else
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#include <stddef.h>
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#endif
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#if defined(__HV__)
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#include <hv/hypervisor.h>
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#elif defined(__KERNEL__)
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#include <hv/hypervisor.h>
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#include <linux/types.h>
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#else
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#include <stdint.h>
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#endif
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/** Code indicating translation services required within the RPC path.
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* These indicate whether there is a translatable struct at the start
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* of the RPC buffer and what information that struct contains.
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*/
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enum iorpc_format_e
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{
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/** No translation required, no prefix struct. */
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IORPC_FORMAT_NONE,
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/** No translation required, no prefix struct, no access to this
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* operation from user space. */
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IORPC_FORMAT_NONE_NOUSER,
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/** Prefix struct contains user VA and size. */
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IORPC_FORMAT_USER_MEM,
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/** Prefix struct contains CPA, size, and homing bits. */
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IORPC_FORMAT_KERNEL_MEM,
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/** Prefix struct contains interrupt. */
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IORPC_FORMAT_KERNEL_INTERRUPT,
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/** Prefix struct contains user-level interrupt. */
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IORPC_FORMAT_USER_INTERRUPT,
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/** Prefix struct contains pollfd_setup (interrupt information). */
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IORPC_FORMAT_KERNEL_POLLFD_SETUP,
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/** Prefix struct contains user-level pollfd_setup (file descriptor). */
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IORPC_FORMAT_USER_POLLFD_SETUP,
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/** Prefix struct contains pollfd (interrupt cookie). */
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IORPC_FORMAT_KERNEL_POLLFD,
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/** Prefix struct contains user-level pollfd (file descriptor). */
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IORPC_FORMAT_USER_POLLFD,
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};
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/** Generate an opcode given format and code. */
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#define IORPC_OPCODE(FORMAT, CODE) (((FORMAT) << 16) | (CODE))
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/** The offset passed through the read() and write() system calls
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combines an opcode with 32 bits of user-specified offset. */
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union iorpc_offset
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{
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#ifndef __BIG_ENDIAN__
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uint64_t offset; /**< All bits. */
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struct
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{
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uint16_t code; /**< RPC code. */
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uint16_t format; /**< iorpc_format_e */
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uint32_t sub_offset; /**< caller-specified offset. */
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};
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uint32_t opcode; /**< Opcode combines code & format. */
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#else
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uint64_t offset; /**< All bits. */
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struct
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{
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uint32_t sub_offset; /**< caller-specified offset. */
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uint16_t format; /**< iorpc_format_e */
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uint16_t code; /**< RPC code. */
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};
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struct
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{
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uint32_t padding;
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uint32_t opcode; /**< Opcode combines code & format. */
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};
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#endif
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};
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/** Homing and cache hinting bits that can be used by IO devices. */
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struct iorpc_mem_attr
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{
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unsigned int lotar_x:4; /**< lotar X bits (or Gx page_mask). */
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unsigned int lotar_y:4; /**< lotar Y bits (or Gx page_offset). */
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unsigned int hfh:1; /**< Uses hash-for-home. */
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unsigned int nt_hint:1; /**< Non-temporal hint. */
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unsigned int io_pin:1; /**< Only fill 'IO' cache ways. */
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};
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/** Set the nt_hint bit. */
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#define IORPC_MEM_BUFFER_FLAG_NT_HINT (1 << 0)
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/** Set the IO pin bit. */
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#define IORPC_MEM_BUFFER_FLAG_IO_PIN (1 << 1)
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/** A structure used to describe memory registration. Different
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protection levels describe memory differently, so this union
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contains all the different possible descriptions. As a request
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moves up the call chain, each layer translates from one
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description format to the next. In particular, the Linux iorpc
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driver translates user VAs into CPAs and homing parameters. */
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union iorpc_mem_buffer
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{
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struct
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{
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uint64_t va; /**< User virtual address. */
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uint64_t size; /**< Buffer size. */
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unsigned int flags; /**< nt_hint, IO pin. */
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}
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user; /**< Buffer as described by user apps. */
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struct
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{
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unsigned long long cpa; /**< Client physical address. */
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#if defined(__KERNEL__) || defined(__HV__)
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size_t size; /**< Buffer size. */
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HV_PTE pte; /**< PTE describing memory homing. */
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#else
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uint64_t size;
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uint64_t pte;
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#endif
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unsigned int flags; /**< nt_hint, IO pin. */
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}
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kernel; /**< Buffer as described by kernel. */
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struct
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{
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unsigned long long pa; /**< Physical address. */
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size_t size; /**< Buffer size. */
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struct iorpc_mem_attr attr; /**< Homing and locality hint bits. */
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}
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hv; /**< Buffer parameters for HV driver. */
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};
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/** A structure used to describe interrupts. The format differs slightly
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* for user and kernel interrupts. As with the mem_buffer_t, translation
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* between the formats is done at each level. */
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union iorpc_interrupt
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{
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struct
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{
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int cpu; /**< CPU. */
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int event; /**< evt_num */
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}
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user; /**< Interrupt as described by user applications. */
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struct
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{
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int x; /**< X coord. */
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int y; /**< Y coord. */
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int ipi; /**< int_num */
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int event; /**< evt_num */
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}
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kernel; /**< Interrupt as described by the kernel. */
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};
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/** A structure used to describe interrupts used with poll(). The format
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* differs significantly for requests from user to kernel, and kernel to
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* hypervisor. As with the mem_buffer_t, translation between the formats
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* is done at each level. */
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union iorpc_pollfd_setup
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{
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struct
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{
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int fd; /**< Pollable file descriptor. */
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}
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user; /**< pollfd_setup as described by user applications. */
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struct
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{
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int x; /**< X coord. */
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int y; /**< Y coord. */
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int ipi; /**< int_num */
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int event; /**< evt_num */
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}
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kernel; /**< pollfd_setup as described by the kernel. */
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};
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/** A structure used to describe previously set up interrupts used with
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* poll(). The format differs significantly for requests from user to
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* kernel, and kernel to hypervisor. As with the mem_buffer_t, translation
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* between the formats is done at each level. */
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union iorpc_pollfd
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{
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struct
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{
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int fd; /**< Pollable file descriptor. */
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}
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user; /**< pollfd as described by user applications. */
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struct
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{
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int cookie; /**< hv cookie returned by the pollfd_setup operation. */
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}
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kernel; /**< pollfd as described by the kernel. */
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};
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/** The various iorpc devices use error codes from -1100 to -1299.
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*
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* This range is distinct from netio (-700 to -799), the hypervisor
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* (-800 to -899), tilepci (-900 to -999), ilib (-1000 to -1099),
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* gxcr (-1300 to -1399) and gxpci (-1400 to -1499).
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*/
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enum gxio_err_e {
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/** Largest iorpc error number. */
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GXIO_ERR_MAX = -1101,
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/********************************************************/
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/* Generic Error Codes */
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/********************************************************/
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/** Bad RPC opcode - possible version incompatibility. */
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GXIO_ERR_OPCODE = -1101,
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/** Invalid parameter. */
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GXIO_ERR_INVAL = -1102,
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/** Memory buffer did not meet alignment requirements. */
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GXIO_ERR_ALIGNMENT = -1103,
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/** Memory buffers must be coherent and cacheable. */
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GXIO_ERR_COHERENCE = -1104,
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/** Resource already initialized. */
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GXIO_ERR_ALREADY_INIT = -1105,
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/** No service domains available. */
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GXIO_ERR_NO_SVC_DOM = -1106,
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/** Illegal service domain number. */
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GXIO_ERR_INVAL_SVC_DOM = -1107,
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/** Illegal MMIO address. */
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GXIO_ERR_MMIO_ADDRESS = -1108,
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/** Illegal interrupt binding. */
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GXIO_ERR_INTERRUPT = -1109,
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/** Unreasonable client memory. */
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GXIO_ERR_CLIENT_MEMORY = -1110,
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/** No more IOTLB entries. */
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GXIO_ERR_IOTLB_ENTRY = -1111,
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/** Invalid memory size. */
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GXIO_ERR_INVAL_MEMORY_SIZE = -1112,
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/** Unsupported operation. */
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GXIO_ERR_UNSUPPORTED_OP = -1113,
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/** Insufficient DMA credits. */
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GXIO_ERR_DMA_CREDITS = -1114,
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/** Operation timed out. */
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GXIO_ERR_TIMEOUT = -1115,
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/** No such device or object. */
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GXIO_ERR_NO_DEVICE = -1116,
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/** Device or resource busy. */
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GXIO_ERR_BUSY = -1117,
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/** I/O error. */
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GXIO_ERR_IO = -1118,
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/** Permissions error. */
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GXIO_ERR_PERM = -1119,
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/********************************************************/
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/* Test Device Error Codes */
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/********************************************************/
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/** Illegal register number. */
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GXIO_TEST_ERR_REG_NUMBER = -1120,
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/** Illegal buffer slot. */
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GXIO_TEST_ERR_BUFFER_SLOT = -1121,
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/********************************************************/
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/* MPIPE Error Codes */
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/********************************************************/
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/** Invalid buffer size. */
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GXIO_MPIPE_ERR_INVAL_BUFFER_SIZE = -1131,
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/** Cannot allocate buffer stack. */
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GXIO_MPIPE_ERR_NO_BUFFER_STACK = -1140,
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/** Invalid buffer stack number. */
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GXIO_MPIPE_ERR_BAD_BUFFER_STACK = -1141,
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/** Cannot allocate NotifRing. */
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GXIO_MPIPE_ERR_NO_NOTIF_RING = -1142,
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/** Invalid NotifRing number. */
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GXIO_MPIPE_ERR_BAD_NOTIF_RING = -1143,
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/** Cannot allocate NotifGroup. */
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GXIO_MPIPE_ERR_NO_NOTIF_GROUP = -1144,
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/** Invalid NotifGroup number. */
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GXIO_MPIPE_ERR_BAD_NOTIF_GROUP = -1145,
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/** Cannot allocate bucket. */
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GXIO_MPIPE_ERR_NO_BUCKET = -1146,
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/** Invalid bucket number. */
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GXIO_MPIPE_ERR_BAD_BUCKET = -1147,
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/** Cannot allocate eDMA ring. */
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GXIO_MPIPE_ERR_NO_EDMA_RING = -1148,
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/** Invalid eDMA ring number. */
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GXIO_MPIPE_ERR_BAD_EDMA_RING = -1149,
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/** Invalid channel number. */
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GXIO_MPIPE_ERR_BAD_CHANNEL = -1150,
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/** Bad configuration. */
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GXIO_MPIPE_ERR_BAD_CONFIG = -1151,
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/** Empty iqueue. */
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GXIO_MPIPE_ERR_IQUEUE_EMPTY = -1152,
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/** Empty rules. */
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GXIO_MPIPE_ERR_RULES_EMPTY = -1160,
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/** Full rules. */
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GXIO_MPIPE_ERR_RULES_FULL = -1161,
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/** Corrupt rules. */
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GXIO_MPIPE_ERR_RULES_CORRUPT = -1162,
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/** Invalid rules. */
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GXIO_MPIPE_ERR_RULES_INVALID = -1163,
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/** Classifier is too big. */
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GXIO_MPIPE_ERR_CLASSIFIER_TOO_BIG = -1170,
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/** Classifier is too complex. */
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GXIO_MPIPE_ERR_CLASSIFIER_TOO_COMPLEX = -1171,
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/** Classifier has bad header. */
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GXIO_MPIPE_ERR_CLASSIFIER_BAD_HEADER = -1172,
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/** Classifier has bad contents. */
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GXIO_MPIPE_ERR_CLASSIFIER_BAD_CONTENTS = -1173,
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/** Classifier encountered invalid symbol. */
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GXIO_MPIPE_ERR_CLASSIFIER_INVAL_SYMBOL = -1174,
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/** Classifier encountered invalid bounds. */
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GXIO_MPIPE_ERR_CLASSIFIER_INVAL_BOUNDS = -1175,
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/** Classifier encountered invalid relocation. */
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GXIO_MPIPE_ERR_CLASSIFIER_INVAL_RELOCATION = -1176,
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/** Classifier encountered undefined symbol. */
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GXIO_MPIPE_ERR_CLASSIFIER_UNDEF_SYMBOL = -1177,
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/********************************************************/
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/* TRIO Error Codes */
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/********************************************************/
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/** Cannot allocate memory map region. */
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GXIO_TRIO_ERR_NO_MEMORY_MAP = -1180,
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/** Invalid memory map region number. */
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GXIO_TRIO_ERR_BAD_MEMORY_MAP = -1181,
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/** Cannot allocate scatter queue. */
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GXIO_TRIO_ERR_NO_SCATTER_QUEUE = -1182,
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/** Invalid scatter queue number. */
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GXIO_TRIO_ERR_BAD_SCATTER_QUEUE = -1183,
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/** Cannot allocate push DMA ring. */
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GXIO_TRIO_ERR_NO_PUSH_DMA_RING = -1184,
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/** Invalid push DMA ring index. */
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GXIO_TRIO_ERR_BAD_PUSH_DMA_RING = -1185,
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/** Cannot allocate pull DMA ring. */
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GXIO_TRIO_ERR_NO_PULL_DMA_RING = -1186,
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/** Invalid pull DMA ring index. */
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GXIO_TRIO_ERR_BAD_PULL_DMA_RING = -1187,
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/** Cannot allocate PIO region. */
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GXIO_TRIO_ERR_NO_PIO = -1188,
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/** Invalid PIO region index. */
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GXIO_TRIO_ERR_BAD_PIO = -1189,
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/** Cannot allocate ASID. */
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GXIO_TRIO_ERR_NO_ASID = -1190,
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/** Invalid ASID. */
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GXIO_TRIO_ERR_BAD_ASID = -1191,
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/********************************************************/
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/* MICA Error Codes */
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/********************************************************/
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/** No such accelerator type. */
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GXIO_MICA_ERR_BAD_ACCEL_TYPE = -1220,
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/** Cannot allocate context. */
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GXIO_MICA_ERR_NO_CONTEXT = -1221,
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/** PKA command queue is full, can't add another command. */
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GXIO_MICA_ERR_PKA_CMD_QUEUE_FULL = -1222,
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/** PKA result queue is empty, can't get a result from the queue. */
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|
GXIO_MICA_ERR_PKA_RESULT_QUEUE_EMPTY = -1223,
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/********************************************************/
|
|
/* GPIO Error Codes */
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|
/********************************************************/
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/** Pin not available. Either the physical pin does not exist, or
|
|
* it is reserved by the hypervisor for system usage. */
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|
GXIO_GPIO_ERR_PIN_UNAVAILABLE = -1240,
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/** Pin busy. The pin exists, and is available for use via GXIO, but
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|
* it has been attached by some other process or driver. */
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|
GXIO_GPIO_ERR_PIN_BUSY = -1241,
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|
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/** Cannot access unattached pin. One or more of the pins being
|
|
* manipulated by this call are not attached to the requesting
|
|
* context. */
|
|
GXIO_GPIO_ERR_PIN_UNATTACHED = -1242,
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|
|
|
/** Invalid I/O mode for pin. The wiring of the pin in the system
|
|
* is such that the I/O mode or electrical control parameters
|
|
* requested could cause damage. */
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|
GXIO_GPIO_ERR_PIN_INVALID_MODE = -1243,
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|
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/** Smallest iorpc error number. */
|
|
GXIO_ERR_MIN = -1299
|
|
};
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#endif /* !_HV_IORPC_H_ */
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