This repository has been archived on 2020-09-21. You can view files and clone it, but cannot push or open issues or pull requests.
FRC2016-old/Robot2016/wpilib/cpp/current/include/fpgainterfacecapi/NiFpga.h

2460 lines
101 KiB
C
Raw Permalink Normal View History

/*
* FPGA Interface C API 15.0 header file.
*
* Copyright (c) 2015,
* National Instruments Corporation.
* All rights reserved.
*/
#ifndef __NiFpga_h__
#define __NiFpga_h__
/*
* Determine platform details.
*/
#if defined(_M_IX86) \
|| defined(_M_X64) \
|| defined(_M_AMD64) \
|| defined(i386) \
|| defined(__i386) \
|| defined(__i386__) \
|| defined(__i486__) \
|| defined(__i586__) \
|| defined(__i686__) \
|| defined(__amd64__) \
|| defined(__amd64) \
|| defined(__x86_64__) \
|| defined(__x86_64) \
|| defined(__IA32__) \
|| defined(_X86_) \
|| defined(__THW_INTEL__) \
|| defined(__I86__) \
|| defined(__INTEL__) \
|| defined(__X86__) \
|| defined(__386__) \
|| defined(__I86__) \
|| defined(M_I386) \
|| defined(M_I86) \
|| defined(_M_I386) \
|| defined(_M_I86)
#if defined(_WIN32) \
|| defined(_WIN64) \
|| defined(__WIN32__) \
|| defined(__TOS_WIN__) \
|| defined(__WINDOWS__) \
|| defined(_WINDOWS) \
|| defined(__WINDOWS_386__) \
|| defined(__CYGWIN__)
/* Either Windows or Phar Lap ETS. */
#define NiFpga_Windows 1
#elif defined(__linux__) \
|| defined(__linux) \
|| defined(linux) \
|| defined(__gnu_linux__)
#define NiFpga_Linux 1
#elif defined(__APPLE__) && defined(__MACH__)
#define NiFpga_MacOsX 1
#else
#error Unsupported OS.
#endif
#elif defined(__powerpc) \
|| defined(__powerpc__) \
|| defined(__POWERPC__) \
|| defined(__ppc__) \
|| defined(__PPC) \
|| defined(_M_PPC) \
|| defined(_ARCH_PPC) \
|| defined(__PPC__) \
|| defined(__ppc)
#if defined(__vxworks)
#define NiFpga_VxWorks 1
#else
#error Unsupported OS.
#endif
#elif defined(__arm__) \
|| defined(__thumb__) \
|| defined(__TARGET_ARCH_ARM) \
|| defined(__TARGET_ARCH_THUMB) \
|| defined(_ARM) \
|| defined(_M_ARM) \
|| defined(_M_ARMT)
#if defined(__linux__) \
|| defined(__linux) \
|| defined(linux) \
|| defined(__gnu_linux__)
#define NiFpga_Linux 1
#else
#error Unsupported OS.
#endif
#else
#error Unsupported architecture.
#endif
/*
* Determine compiler.
*/
#if defined(_MSC_VER)
#define NiFpga_Msvc 1
#elif defined(__GNUC__)
#define NiFpga_Gcc 1
#elif defined(_CVI_) && !defined(_TPC_)
#define NiFpga_Cvi 1
/* Enables CVI Library Protection Errors. */
#pragma EnableLibraryRuntimeChecking
#else
/* Unknown compiler. */
#endif
/*
* Determine compliance with different C/C++ language standards.
*/
#if defined(__cplusplus)
#define NiFpga_Cpp 1
#if __cplusplus >= 199707L
#define NiFpga_Cpp98 1
#if __cplusplus >= 201103L
#define NiFpga_Cpp11 1
#endif
#endif
#endif
#if defined(__STDC__)
#define NiFpga_C89 1
#if defined(__STDC_VERSION__)
#define NiFpga_C90 1
#if __STDC_VERSION__ >= 199409L
#define NiFpga_C94 1
#if __STDC_VERSION__ >= 199901L
#define NiFpga_C99 1
#if __STDC_VERSION__ >= 201112L
#define NiFpga_C11 1
#endif
#endif
#endif
#endif
#endif
/*
* Determine ability to inline functions.
*/
#if NiFpga_Cpp || NiFpga_C99
/* The inline keyword exists in C++ and C99. */
#define NiFpga_Inline inline
#elif NiFpga_Msvc
/* Visual C++ (at least since 6.0) also supports an alternate keyword. */
#define NiFpga_Inline __inline
#elif NiFpga_Gcc
/* GCC (at least since 2.95.2) also supports an alternate keyword. */
#define NiFpga_Inline __inline__
#elif !defined(NiFpga_Inline)
/*
* Disable inlining if inline support is unknown. To manually enable
* inlining, #define the following macro before #including NiFpga.h:
*
* #define NiFpga_Inline inline
*/
#define NiFpga_Inline
#endif
/*
* Define exact-width integer types, if they have not already been defined.
*/
#if NiFpga_ExactWidthIntegerTypesDefined \
|| defined(_STDINT) \
|| defined(_STDINT_H) \
|| defined(_STDINT_H_) \
|| defined(_INTTYPES_H) \
|| defined(_INTTYPES_H_) \
|| defined(_SYS_STDINT_H) \
|| defined(_SYS_STDINT_H_) \
|| defined(_SYS_INTTYPES_H) \
|| defined(_SYS_INTTYPES_H_) \
|| defined(_STDINT_H_INCLUDED) \
|| defined(_MSC_STDINT_H_) \
|| defined(_PSTDINT_H_INCLUDED)
/* Assume that exact-width integer types have already been defined. */
#elif NiFpga_VxWorks
/* VxWorks (at least 6.3 and earlier) did not have stdint.h. */
#include <types/vxTypes.h>
#elif NiFpga_C99 \
|| NiFpga_Gcc /* GCC (at least since 3.0) has a stdint.h. */ \
|| defined(HAVE_STDINT_H)
/* Assume that stdint.h can be included. */
#include <stdint.h>
#elif NiFpga_Msvc \
|| NiFpga_Cvi
/* Manually define exact-width integer types. */
typedef signed char int8_t;
typedef unsigned char uint8_t;
typedef short int16_t;
typedef unsigned short uint16_t;
typedef int int32_t;
typedef unsigned int uint32_t;
typedef __int64 int64_t;
typedef unsigned __int64 uint64_t;
#else
/*
* Exact-width integer types must be defined by the user, and the following
* macro must be #defined, before #including NiFpga.h:
*
* #define NiFpga_ExactWidthIntegerTypesDefined 1
*/
#error Exact-width integer types must be defined by the user. See comment.
#endif
/* Included for definition of size_t. */
#include <stddef.h>
#if NiFpga_Cpp
extern "C"
{
#endif
/**
* A boolean value; either NiFpga_False or NiFpga_True.
*/
typedef uint8_t NiFpga_Bool;
/**
* Represents a false condition.
*/
static const NiFpga_Bool NiFpga_False = 0;
/**
* Represents a true condition.
*/
static const NiFpga_Bool NiFpga_True = 1;
/**
* Represents the resulting status of a function call through its return value.
* 0 is success, negative values are errors, and positive values are warnings.
*/
typedef int32_t NiFpga_Status;
/**
* No errors or warnings.
*/
static const NiFpga_Status NiFpga_Status_Success = 0;
/**
* The timeout expired before the FIFO operation could complete.
*/
static const NiFpga_Status NiFpga_Status_FifoTimeout = -50400;
/**
* No transfer is in progress because the transfer was aborted by the client.
* The operation could not be completed as specified.
*/
static const NiFpga_Status NiFpga_Status_TransferAborted = -50405;
/**
* A memory allocation failed. Try again after rebooting.
*/
static const NiFpga_Status NiFpga_Status_MemoryFull = -52000;
/**
* An unexpected software error occurred.
*/
static const NiFpga_Status NiFpga_Status_SoftwareFault = -52003;
/**
* A parameter to a function was not valid. This could be a NULL pointer, a bad
* value, etc.
*/
static const NiFpga_Status NiFpga_Status_InvalidParameter = -52005;
/**
* A required resource was not found. The NiFpga.* library, the RIO resource, or
* some other resource may be missing.
*/
static const NiFpga_Status NiFpga_Status_ResourceNotFound = -52006;
/**
* A required resource was not properly initialized. This could occur if
* NiFpga_Initialize was not called or a required NiFpga_IrqContext was not
* reserved.
*/
static const NiFpga_Status NiFpga_Status_ResourceNotInitialized = -52010;
/**
* A hardware failure has occurred. The operation could not be completed as
* specified.
*/
static const NiFpga_Status NiFpga_Status_HardwareFault = -52018;
/**
* The FPGA is already running.
*/
static const NiFpga_Status NiFpga_Status_FpgaAlreadyRunning = -61003;
/**
* An error occurred downloading the VI to the FPGA device. Verify that
* the target is connected and powered and that the resource of the target
* is properly configured.
*/
static const NiFpga_Status NiFpga_Status_DownloadError = -61018;
/**
* The bitfile was not compiled for the specified resource's device type.
*/
static const NiFpga_Status NiFpga_Status_DeviceTypeMismatch = -61024;
/**
* An error was detected in the communication between the host computer and the
* FPGA target.
*/
static const NiFpga_Status NiFpga_Status_CommunicationTimeout = -61046;
/**
* The timeout expired before any of the IRQs were asserted.
*/
static const NiFpga_Status NiFpga_Status_IrqTimeout = -61060;
/**
* The specified bitfile is invalid or corrupt.
*/
static const NiFpga_Status NiFpga_Status_CorruptBitfile = -61070;
/**
* The requested FIFO depth is invalid. It is either 0 or an amount not
* supported by the hardware.
*/
static const NiFpga_Status NiFpga_Status_BadDepth = -61072;
/**
* The number of FIFO elements is invalid. Either the number is greater than the
* depth of the host memory DMA FIFO, or more elements were requested for
* release than had been acquired.
*/
static const NiFpga_Status NiFpga_Status_BadReadWriteCount = -61073;
/**
* A hardware clocking error occurred. A derived clock lost lock with its base
* clock during the execution of the LabVIEW FPGA VI. If any base clocks with
* derived clocks are referencing an external source, make sure that the
* external source is connected and within the supported frequency, jitter,
* accuracy, duty cycle, and voltage specifications. Also verify that the
* characteristics of the base clock match the configuration specified in the
* FPGA Base Clock Properties. If all base clocks with derived clocks are
* generated from free-running, on-board sources, please contact National
* Instruments technical support at ni.com/support.
*/
static const NiFpga_Status NiFpga_Status_ClockLostLock = -61083;
/**
* The operation could not be performed because the FPGA is busy. Stop all
* activities on the FPGA before requesting this operation. If the target is in
* Scan Interface programming mode, put it in FPGA Interface programming mode.
*/
static const NiFpga_Status NiFpga_Status_FpgaBusy = -61141;
/**
* The operation could not be performed because the FPGA is busy operating in
* FPGA Interface C API mode. Stop all activities on the FPGA before requesting
* this operation.
*/
static const NiFpga_Status NiFpga_Status_FpgaBusyFpgaInterfaceCApi = -61200;
/**
* The chassis is in Scan Interface programming mode. In order to run FPGA VIs,
* you must go to the chassis properties page, select FPGA programming mode, and
* deploy settings.
*/
static const NiFpga_Status NiFpga_Status_FpgaBusyScanInterface = -61201;
/**
* The operation could not be performed because the FPGA is busy operating in
* FPGA Interface mode. Stop all activities on the FPGA before requesting this
* operation.
*/
static const NiFpga_Status NiFpga_Status_FpgaBusyFpgaInterface = -61202;
/**
* The operation could not be performed because the FPGA is busy operating in
* Interactive mode. Stop all activities on the FPGA before requesting this
* operation.
*/
static const NiFpga_Status NiFpga_Status_FpgaBusyInteractive = -61203;
/**
* The operation could not be performed because the FPGA is busy operating in
* Emulation mode. Stop all activities on the FPGA before requesting this
* operation.
*/
static const NiFpga_Status NiFpga_Status_FpgaBusyEmulation = -61204;
/**
* LabVIEW FPGA does not support the Reset method for bitfiles that allow
* removal of implicit enable signals in single-cycle Timed Loops.
*/
static const NiFpga_Status NiFpga_Status_ResetCalledWithImplicitEnableRemoval = -61211;
/**
* LabVIEW FPGA does not support the Abort method for bitfiles that allow
* removal of implicit enable signals in single-cycle Timed Loops.
*/
static const NiFpga_Status NiFpga_Status_AbortCalledWithImplicitEnableRemoval = -61212;
/**
* LabVIEW FPGA does not support Close and Reset if Last Reference for bitfiles
* that allow removal of implicit enable signals in single-cycle Timed Loops.
* Pass the NiFpga_CloseAttribute_NoResetIfLastSession attribute to NiFpga_Close
* instead of 0.
*/
static const NiFpga_Status NiFpga_Status_CloseAndResetCalledWithImplicitEnableRemoval = -61213;
/**
* For bitfiles that allow removal of implicit enable signals in single-cycle
* Timed Loops, LabVIEW FPGA does not support this method prior to running the
* bitfile.
*/
static const NiFpga_Status NiFpga_Status_ImplicitEnableRemovalButNotYetRun = -61214;
/**
* Bitfiles that allow removal of implicit enable signals in single-cycle Timed
* Loops can run only once. Download the bitfile again before re-running the VI.
*/
static const NiFpga_Status NiFpga_Status_RunAfterStoppedCalledWithImplicitEnableRemoval = -61215;
/**
* A gated clock has violated the handshaking protocol. If you are using
* external gated clocks, ensure that they follow the required clock gating
* protocol. If you are generating your clocks internally, please contact
* National Instruments Technical Support.
*/
static const NiFpga_Status NiFpga_Status_GatedClockHandshakingViolation = -61216;
/**
* The number of elements requested must be less than or equal to the number of
* unacquired elements left in the host memory DMA FIFO. There are currently
* fewer unacquired elements left in the FIFO than are being requested. Release
* some acquired elements before acquiring more elements.
*/
static const NiFpga_Status NiFpga_Status_ElementsNotPermissibleToBeAcquired = -61219;
/**
* The operation could not be performed because the FPGA is in configuration or
* discovery mode. Wait for configuration or discovery to complete and retry
* your operation.
*/
static const NiFpga_Status NiFpga_Status_FpgaBusyConfiguration = -61252;
/**
* An unexpected internal error occurred.
*/
static const NiFpga_Status NiFpga_Status_InternalError = -61499;
/**
* The NI-RIO driver was unable to allocate memory for a FIFO. This can happen
* when the combined depth of all DMA FIFOs exceeds the maximum depth for the
* controller, or when the controller runs out of system memory. You may be able
* to reconfigure the controller with a greater maximum FIFO depth. For more
* information, refer to the NI KnowledgeBase article 65OF2ERQ.
*/
static const NiFpga_Status NiFpga_Status_TotalDmaFifoDepthExceeded = -63003;
/**
* Access to the remote system was denied. Use MAX to check the Remote Device
* Access settings under Software>>NI-RIO>>NI-RIO Settings on the remote system.
*/
static const NiFpga_Status NiFpga_Status_AccessDenied = -63033;
/**
* The NI-RIO software on the host is not compatible with the software on the
* target. Upgrade the NI-RIO software on the host in order to connect to this
* target.
*/
static const NiFpga_Status NiFpga_Status_HostVersionMismatch = -63038;
/**
* A connection could not be established to the specified remote device. Ensure
* that the device is on and accessible over the network, that NI-RIO software
* is installed, and that the RIO server is running and properly configured.
*/
static const NiFpga_Status NiFpga_Status_RpcConnectionError = -63040;
/**
* The RPC session is invalid. The target may have reset or been rebooted. Check
* the network connection and retry the operation.
*/
static const NiFpga_Status NiFpga_Status_RpcSessionError = -63043;
/**
* The operation could not complete because another session is accessing the
* FIFO. Close the other session and retry.
*/
static const NiFpga_Status NiFpga_Status_FifoReserved = -63082;
/**
* A Configure FIFO, Stop FIFO, Read FIFO, or Write FIFO function was called
* while the host had acquired elements of the FIFO. Release all acquired
* elements before configuring, stopping, reading, or writing.
*/
static const NiFpga_Status NiFpga_Status_FifoElementsCurrentlyAcquired = -63083;
/**
* A function was called using a misaligned address. The address must be a
* multiple of the size of the datatype.
*/
static const NiFpga_Status NiFpga_Status_MisalignedAccess = -63084;
/**
* The FPGA Read/Write Control Function is accessing a control or indicator
* with data that exceeds the maximum size supported on the current target.
* Refer to the hardware documentation for the limitations on data types for
* this target.
*/
static const NiFpga_Status NiFpga_Status_ControlOrIndicatorTooLarge = -63085;
/**
* A valid .lvbitx bitfile is required. If you are using a valid .lvbitx
* bitfile, the bitfile may not be compatible with the software you are using.
* Determine which version of LabVIEW was used to make the bitfile, update your
* software to that version or later, and try again.
*/
static const NiFpga_Status NiFpga_Status_BitfileReadError = -63101;
/**
* The specified signature does not match the signature of the bitfile. If the
* bitfile has been recompiled, regenerate the C API and rebuild the
* application.
*/
static const NiFpga_Status NiFpga_Status_SignatureMismatch = -63106;
/**
* The bitfile you are trying to use is incompatible with the version
* of NI-RIO installed on the target and/or host. Update the version
* of NI-RIO on the target and/or host to the same version (or later)
* used to compile the bitfile. Alternatively, recompile the bitfile
* with the same version of NI-RIO that is currently installed on the
* target and/or host.
*/
static const NiFpga_Status NiFpga_Status_IncompatibleBitfile = -63107;
/**
* Either the supplied resource name is invalid as a RIO resource name, or the
* device was not found. Use MAX to find the proper resource name for the
* intended device.
*/
static const NiFpga_Status NiFpga_Status_InvalidResourceName = -63192;
/**
* The requested feature is not supported.
*/
static const NiFpga_Status NiFpga_Status_FeatureNotSupported = -63193;
/**
* The NI-RIO software on the target system is not compatible with this
* software. Upgrade the NI-RIO software on the target system.
*/
static const NiFpga_Status NiFpga_Status_VersionMismatch = -63194;
/**
* The session is invalid or has been closed.
*/
static const NiFpga_Status NiFpga_Status_InvalidSession = -63195;
/**
* The maximum number of open FPGA sessions has been reached. Close some open
* sessions.
*/
static const NiFpga_Status NiFpga_Status_OutOfHandles = -63198;
/**
* Tests whether a status is an error.
*
* @param status status to check for an error
* @return whether the status was an error
*/
static NiFpga_Inline NiFpga_Bool NiFpga_IsError(const NiFpga_Status status)
{
return status < NiFpga_Status_Success ? NiFpga_True : NiFpga_False;
}
/**
* Tests whether a status is not an error. Success and warnings are not errors.
*
* @param status status to check for an error
* @return whether the status was a success or warning
*/
static NiFpga_Inline NiFpga_Bool NiFpga_IsNotError(const NiFpga_Status status)
{
return status >= NiFpga_Status_Success ? NiFpga_True : NiFpga_False;
}
/**
* Conditionally sets the status to a new value. The previous status is
* preserved unless the new status is more of an error, which means that
* warnings and errors overwrite successes, and errors overwrite warnings. New
* errors do not overwrite older errors, and new warnings do not overwrite
* older warnings.
*
* @param status status to conditionally set
* @param newStatus new status value that may be set
* @return the resulting status
*/
static NiFpga_Inline NiFpga_Status NiFpga_MergeStatus(
NiFpga_Status* const status,
const NiFpga_Status newStatus)
{
if (!status)
return NiFpga_Status_InvalidParameter;
if (NiFpga_IsNotError(*status)
&& (*status == NiFpga_Status_Success || NiFpga_IsError(newStatus)))
*status = newStatus;
return *status;
}
/**
* This macro evaluates the expression only if the status is not an error. The
* expression must evaluate to an NiFpga_Status, such as a call to any NiFpga_*
* function, because the status will be set to the returned status if the
* expression is evaluated.
*
* You can use this macro to mimic status chaining in LabVIEW, where the status
* does not have to be explicitly checked after each call. Such code may look
* like the following example.
*
* NiFpga_Status status = NiFpga_Status_Success;
* NiFpga_IfIsNotError(status, NiFpga_WriteU32(...));
* NiFpga_IfIsNotError(status, NiFpga_WriteU32(...));
* NiFpga_IfIsNotError(status, NiFpga_WriteU32(...));
*
* @param status status to check for an error
* @param expression expression to call if the incoming status is not an error
*/
#define NiFpga_IfIsNotError(status, expression) \
if (NiFpga_IsNotError(status)) \
NiFpga_MergeStatus(&status, (expression)); \
/**
* You must call this function before all other function calls. This function
* loads the NiFpga library so that all the other functions will work. If this
* function succeeds, you must call NiFpga_Finalize after all other function
* calls.
*
* @warning This function is not thread safe.
*
* @return result of the call
*/
NiFpga_Status NiFpga_Initialize(void);
/**
* You must call this function after all other function calls if
* NiFpga_Initialize succeeds. This function unloads the NiFpga library.
*
* @warning This function is not thread safe.
*
* @return result of the call
*/
NiFpga_Status NiFpga_Finalize(void);
/**
* A handle to an FPGA session.
*/
typedef uint32_t NiFpga_Session;
/**
* Attributes that NiFpga_Open accepts.
*/
typedef enum
{
NiFpga_OpenAttribute_NoRun = 1
} NiFpga_OpenAttribute;
/**
* Opens a session to the FPGA. This call ensures that the contents of the
* bitfile are programmed to the FPGA. The FPGA runs unless the
* NiFpga_OpenAttribute_NoRun attribute is used.
*
* Because different operating systems have different default current working
* directories for applications, you must pass an absolute path for the bitfile
* parameter. If you pass only the filename instead of an absolute path, the
* operating system may not be able to locate the bitfile. For example, the
* default current working directories are C:\ni-rt\system\ for Phar Lap ETS and
* /c/ for VxWorks. Because the generated *_Bitfile constant is a #define to a
* string literal, you can use C/C++ string-literal concatenation to form an
* absolute path. For example, if the bitfile is in the root directory of a
* Phar Lap ETS system, pass the following for the bitfile parameter.
*
* "C:\\" NiFpga_MyApplication_Bitfile
*
* @param bitfile path to the bitfile
* @param signature signature of the bitfile
* @param resource RIO resource string to open ("RIO0" or "rio://mysystem/RIO")
* @param attribute bitwise OR of any NiFpga_OpenAttributes, or 0
* @param session outputs the session handle, which must be closed when no
* longer needed
* @return result of the call
*/
NiFpga_Status NiFpga_Open(const char* bitfile,
const char* signature,
const char* resource,
uint32_t attribute,
NiFpga_Session* session);
/**
* Attributes that NiFpga_Close accepts.
*/
typedef enum
{
NiFpga_CloseAttribute_NoResetIfLastSession = 1
} NiFpga_CloseAttribute;
/**
* Closes the session to the FPGA. The FPGA resets unless either another session
* is still open or you use the NiFpga_CloseAttribute_NoResetIfLastSession
* attribute.
*
* @param session handle to a currently open session
* @param attribute bitwise OR of any NiFpga_CloseAttributes, or 0
* @return result of the call
*/
NiFpga_Status NiFpga_Close(NiFpga_Session session,
uint32_t attribute);
/**
* Attributes that NiFpga_Run accepts.
*/
typedef enum
{
NiFpga_RunAttribute_WaitUntilDone = 1
} NiFpga_RunAttribute;
/**
* Runs the FPGA VI on the target. If you use NiFpga_RunAttribute_WaitUntilDone,
* NiFpga_Run blocks the thread until the FPGA finishes running.
*
* @param session handle to a currently open session
* @param attribute bitwise OR of any NiFpga_RunAttributes, or 0
* @return result of the call
*/
NiFpga_Status NiFpga_Run(NiFpga_Session session,
uint32_t attribute);
/**
* Aborts the FPGA VI.
*
* @param session handle to a currently open session
* @return result of the call
*/
NiFpga_Status NiFpga_Abort(NiFpga_Session session);
/**
* Resets the FPGA VI.
*
* @param session handle to a currently open session
* @return result of the call
*/
NiFpga_Status NiFpga_Reset(NiFpga_Session session);
/**
* Re-downloads the FPGA bitstream to the target.
*
* @param session handle to a currently open session
* @return result of the call
*/
NiFpga_Status NiFpga_Download(NiFpga_Session session);
/**
* Reads a boolean value from a given indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param value outputs the value that was read
* @return result of the call
*/
NiFpga_Status NiFpga_ReadBool(NiFpga_Session session,
uint32_t indicator,
NiFpga_Bool* value);
/**
* Reads a signed 8-bit integer value from a given indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param value outputs the value that was read
* @return result of the call
*/
NiFpga_Status NiFpga_ReadI8(NiFpga_Session session,
uint32_t indicator,
int8_t* value);
/**
* Reads an unsigned 8-bit integer value from a given indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param value outputs the value that was read
* @return result of the call
*/
NiFpga_Status NiFpga_ReadU8(NiFpga_Session session,
uint32_t indicator,
uint8_t* value);
/**
* Reads a signed 16-bit integer value from a given indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param value outputs the value that was read
* @return result of the call
*/
NiFpga_Status NiFpga_ReadI16(NiFpga_Session session,
uint32_t indicator,
int16_t* value);
/**
* Reads an unsigned 16-bit integer value from a given indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param value outputs the value that was read
* @return result of the call
*/
NiFpga_Status NiFpga_ReadU16(NiFpga_Session session,
uint32_t indicator,
uint16_t* value);
/**
* Reads a signed 32-bit integer value from a given indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param value outputs the value that was read
* @return result of the call
*/
NiFpga_Status NiFpga_ReadI32(NiFpga_Session session,
uint32_t indicator,
int32_t* value);
/**
* Reads an unsigned 32-bit integer value from a given indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param value outputs the value that was read
* @return result of the call
*/
NiFpga_Status NiFpga_ReadU32(NiFpga_Session session,
uint32_t indicator,
uint32_t* value);
/**
* Reads a signed 64-bit integer value from a given indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param value outputs the value that was read
* @return result of the call
*/
NiFpga_Status NiFpga_ReadI64(NiFpga_Session session,
uint32_t indicator,
int64_t* value);
/**
* Reads an unsigned 64-bit integer value from a given indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param value outputs the value that was read
* @return result of the call
*/
NiFpga_Status NiFpga_ReadU64(NiFpga_Session session,
uint32_t indicator,
uint64_t* value);
/**
* Writes a boolean value to a given control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param value value to write
* @return result of the call
*/
NiFpga_Status NiFpga_WriteBool(NiFpga_Session session,
uint32_t control,
NiFpga_Bool value);
/**
* Writes a signed 8-bit integer value to a given control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param value value to write
* @return result of the call
*/
NiFpga_Status NiFpga_WriteI8(NiFpga_Session session,
uint32_t control,
int8_t value);
/**
* Writes an unsigned 8-bit integer value to a given control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param value value to write
* @return result of the call
*/
NiFpga_Status NiFpga_WriteU8(NiFpga_Session session,
uint32_t control,
uint8_t value);
/**
* Writes a signed 16-bit integer value to a given control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param value value to write
* @return result of the call
*/
NiFpga_Status NiFpga_WriteI16(NiFpga_Session session,
uint32_t control,
int16_t value);
/**
* Writes an unsigned 16-bit integer value to a given control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param value value to write
* @return result of the call
*/
NiFpga_Status NiFpga_WriteU16(NiFpga_Session session,
uint32_t control,
uint16_t value);
/**
* Writes a signed 32-bit integer value to a given control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param value value to write
* @return result of the call
*/
NiFpga_Status NiFpga_WriteI32(NiFpga_Session session,
uint32_t control,
int32_t value);
/**
* Writes an unsigned 32-bit integer value to a given control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param value value to write
* @return result of the call
*/
NiFpga_Status NiFpga_WriteU32(NiFpga_Session session,
uint32_t control,
uint32_t value);
/**
* Writes a signed 64-bit integer value to a given control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param value value to write
* @return result of the call
*/
NiFpga_Status NiFpga_WriteI64(NiFpga_Session session,
uint32_t control,
int64_t value);
/**
* Writes an unsigned 64-bit integer value to a given control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param value value to write
* @return result of the call
*/
NiFpga_Status NiFpga_WriteU64(NiFpga_Session session,
uint32_t control,
uint64_t value);
/**
* Reads an entire array of boolean values from a given array indicator or
* control.
*
* @warning The size passed must be the exact number of elements in the
* indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param array outputs the entire array that was read
* @param size exact number of elements in the indicator or control
* @return result of the call
*/
NiFpga_Status NiFpga_ReadArrayBool(NiFpga_Session session,
uint32_t indicator,
NiFpga_Bool* array,
size_t size);
/**
* Reads an entire array of signed 8-bit integer values from a given array
* indicator or control.
*
* @warning The size passed must be the exact number of elements in the
* indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param array outputs the entire array that was read
* @param size exact number of elements in the indicator or control
* @return result of the call
*/
NiFpga_Status NiFpga_ReadArrayI8(NiFpga_Session session,
uint32_t indicator,
int8_t* array,
size_t size);
/**
* Reads an entire array of unsigned 8-bit integer values from a given array
* indicator or control.
*
* @warning The size passed must be the exact number of elements in the
* indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param array outputs the entire array that was read
* @param size exact number of elements in the indicator or control
* @return result of the call
*/
NiFpga_Status NiFpga_ReadArrayU8(NiFpga_Session session,
uint32_t indicator,
uint8_t* array,
size_t size);
/**
* Reads an entire array of signed 16-bit integer values from a given array
* indicator or control.
*
* @warning The size passed must be the exact number of elements in the
* indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param array outputs the entire array that was read
* @param size exact number of elements in the indicator or control
* @return result of the call
*/
NiFpga_Status NiFpga_ReadArrayI16(NiFpga_Session session,
uint32_t indicator,
int16_t* array,
size_t size);
/**
* Reads an entire array of unsigned 16-bit integer values from a given array
* indicator or control.
*
* @warning The size passed must be the exact number of elements in the
* indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param array outputs the entire array that was read
* @param size exact number of elements in the indicator or control
* @return result of the call
*/
NiFpga_Status NiFpga_ReadArrayU16(NiFpga_Session session,
uint32_t indicator,
uint16_t* array,
size_t size);
/**
* Reads an entire array of signed 32-bit integer values from a given array
* indicator or control.
*
* @warning The size passed must be the exact number of elements in the
* indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param array outputs the entire array that was read
* @param size exact number of elements in the indicator or control
* @return result of the call
*/
NiFpga_Status NiFpga_ReadArrayI32(NiFpga_Session session,
uint32_t indicator,
int32_t* array,
size_t size);
/**
* Reads an entire array of unsigned 32-bit integer values from a given array
* indicator or control.
*
* @warning The size passed must be the exact number of elements in the
* indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param array outputs the entire array that was read
* @param size exact number of elements in the indicator or control
* @return result of the call
*/
NiFpga_Status NiFpga_ReadArrayU32(NiFpga_Session session,
uint32_t indicator,
uint32_t* array,
size_t size);
/**
* Reads an entire array of signed 64-bit integer values from a given array
* indicator or control.
*
* @warning The size passed must be the exact number of elements in the
* indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param array outputs the entire array that was read
* @param size exact number of elements in the indicator or control
* @return result of the call
*/
NiFpga_Status NiFpga_ReadArrayI64(NiFpga_Session session,
uint32_t indicator,
int64_t* array,
size_t size);
/**
* Reads an entire array of unsigned 64-bit integer values from a given array
* indicator or control.
*
* @warning The size passed must be the exact number of elements in the
* indicator or control.
*
* @param session handle to a currently open session
* @param indicator indicator or control from which to read
* @param array outputs the entire array that was read
* @param size exact number of elements in the indicator or control
* @return result of the call
*/
NiFpga_Status NiFpga_ReadArrayU64(NiFpga_Session session,
uint32_t indicator,
uint64_t* array,
size_t size);
/**
* Writes an entire array of boolean values to a given array control or
* indicator.
*
* @warning The size passed must be the exact number of elements in the
* control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param array entire array to write
* @param size exact number of elements in the control or indicator
* @return result of the call
*/
NiFpga_Status NiFpga_WriteArrayBool(NiFpga_Session session,
uint32_t control,
const NiFpga_Bool* array,
size_t size);
/**
* Writes an entire array of signed 8-bit integer values to a given array
* control or indicator.
*
* @warning The size passed must be the exact number of elements in the
* control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param array entire array to write
* @param size exact number of elements in the control or indicator
* @return result of the call
*/
NiFpga_Status NiFpga_WriteArrayI8(NiFpga_Session session,
uint32_t control,
const int8_t* array,
size_t size);
/**
* Writes an entire array of unsigned 8-bit integer values to a given array
* control or indicator.
*
* @warning The size passed must be the exact number of elements in the
* control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param array entire array to write
* @param size exact number of elements in the control or indicator
* @return result of the call
*/
NiFpga_Status NiFpga_WriteArrayU8(NiFpga_Session session,
uint32_t control,
const uint8_t* array,
size_t size);
/**
* Writes an entire array of signed 16-bit integer values to a given array
* control or indicator.
*
* @warning The size passed must be the exact number of elements in the
* control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param array entire array to write
* @param size exact number of elements in the control or indicator
* @return result of the call
*/
NiFpga_Status NiFpga_WriteArrayI16(NiFpga_Session session,
uint32_t control,
const int16_t* array,
size_t size);
/**
* Writes an entire array of unsigned 16-bit integer values to a given array
* control or indicator.
*
* @warning The size passed must be the exact number of elements in the
* control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param array entire array to write
* @param size exact number of elements in the control or indicator
* @return result of the call
*/
NiFpga_Status NiFpga_WriteArrayU16(NiFpga_Session session,
uint32_t control,
const uint16_t* array,
size_t size);
/**
* Writes an entire array of signed 32-bit integer values to a given array
* control or indicator.
*
* @warning The size passed must be the exact number of elements in the
* control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param array entire array to write
* @param size exact number of elements in the control or indicator
* @return result of the call
*/
NiFpga_Status NiFpga_WriteArrayI32(NiFpga_Session session,
uint32_t control,
const int32_t* array,
size_t size);
/**
* Writes an entire array of unsigned 32-bit integer values to a given array
* control or indicator.
*
* @warning The size passed must be the exact number of elements in the
* control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param array entire array to write
* @param size exact number of elements in the control or indicator
* @return result of the call
*/
NiFpga_Status NiFpga_WriteArrayU32(NiFpga_Session session,
uint32_t control,
const uint32_t* array,
size_t size);
/**
* Writes an entire array of signed 64-bit integer values to a given array
* control or indicator.
*
* @warning The size passed must be the exact number of elements in the
* control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param array entire array to write
* @param size exact number of elements in the control or indicator
* @return result of the call
*/
NiFpga_Status NiFpga_WriteArrayI64(NiFpga_Session session,
uint32_t control,
const int64_t* array,
size_t size);
/**
* Writes an entire array of unsigned 64-bit integer values to a given array
* control or indicator.
*
* @warning The size passed must be the exact number of elements in the
* control or indicator.
*
* @param session handle to a currently open session
* @param control control or indicator to which to write
* @param array entire array to write
* @param size exact number of elements in the control or indicator
* @return result of the call
*/
NiFpga_Status NiFpga_WriteArrayU64(NiFpga_Session session,
uint32_t control,
const uint64_t* array,
size_t size);
/**
* Enumeration of all 32 possible IRQs. Multiple IRQs can be bitwise ORed
* together like this:
*
* NiFpga_Irq_3 | NiFpga_Irq_23
*/
typedef enum
{
NiFpga_Irq_0 = 1 << 0,
NiFpga_Irq_1 = 1 << 1,
NiFpga_Irq_2 = 1 << 2,
NiFpga_Irq_3 = 1 << 3,
NiFpga_Irq_4 = 1 << 4,
NiFpga_Irq_5 = 1 << 5,
NiFpga_Irq_6 = 1 << 6,
NiFpga_Irq_7 = 1 << 7,
NiFpga_Irq_8 = 1 << 8,
NiFpga_Irq_9 = 1 << 9,
NiFpga_Irq_10 = 1 << 10,
NiFpga_Irq_11 = 1 << 11,
NiFpga_Irq_12 = 1 << 12,
NiFpga_Irq_13 = 1 << 13,
NiFpga_Irq_14 = 1 << 14,
NiFpga_Irq_15 = 1 << 15,
NiFpga_Irq_16 = 1 << 16,
NiFpga_Irq_17 = 1 << 17,
NiFpga_Irq_18 = 1 << 18,
NiFpga_Irq_19 = 1 << 19,
NiFpga_Irq_20 = 1 << 20,
NiFpga_Irq_21 = 1 << 21,
NiFpga_Irq_22 = 1 << 22,
NiFpga_Irq_23 = 1 << 23,
NiFpga_Irq_24 = 1 << 24,
NiFpga_Irq_25 = 1 << 25,
NiFpga_Irq_26 = 1 << 26,
NiFpga_Irq_27 = 1 << 27,
NiFpga_Irq_28 = 1 << 28,
NiFpga_Irq_29 = 1 << 29,
NiFpga_Irq_30 = 1 << 30,
NiFpga_Irq_31 = 1U << 31
} NiFpga_Irq;
/**
* Represents an infinite timeout.
*/
static const uint32_t NiFpga_InfiniteTimeout = 0xFFFFFFFF;
/**
* See NiFpga_ReserveIrqContext for more information.
*/
typedef void* NiFpga_IrqContext;
/**
* IRQ contexts are single-threaded; only one thread can wait with a
* particular context at any given time. To minimize jitter when first
* waiting on IRQs, reserve as many contexts as the application
* requires.
*
* If a context is successfully reserved (the returned status is not an error),
* it must be unreserved later. Otherwise a memory leak will occur.
*
* @param session handle to a currently open session
* @param context outputs the IRQ context
* @return result of the call
*/
NiFpga_Status NiFpga_ReserveIrqContext(NiFpga_Session session,
NiFpga_IrqContext* context);
/**
* Unreserves an IRQ context obtained from NiFpga_ReserveIrqContext.
*
* @param session handle to a currently open session
* @param context IRQ context to unreserve
* @return result of the call
*/
NiFpga_Status NiFpga_UnreserveIrqContext(NiFpga_Session session,
NiFpga_IrqContext context);
/**
* This is a blocking function that stops the calling thread until the
* FPGA asserts any IRQ in the irqs parameter, or until the function
* call times out. Before calling this function, use
* NiFpga_ReserveIrqContext to reserve an IRQ context. No other
* threads can use the same context when this function is called.
*
* You can use the irqsAsserted parameter to determine which IRQs were asserted
* for each function call.
*
* @param session handle to a currently open session
* @param context IRQ context with which to wait
* @param irqs bitwise OR of NiFpga_Irqs
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param irqsAsserted if non-NULL, outputs bitwise OR of IRQs that were
* asserted
* @param timedOut if non-NULL, outputs whether the timeout expired
* @return result of the call
*/
NiFpga_Status NiFpga_WaitOnIrqs(NiFpga_Session session,
NiFpga_IrqContext context,
uint32_t irqs,
uint32_t timeout,
uint32_t* irqsAsserted,
NiFpga_Bool* timedOut);
/**
* Acknowledges an IRQ or set of IRQs.
*
* @param session handle to a currently open session
* @param irqs bitwise OR of NiFpga_Irqs
* @return result of the call
*/
NiFpga_Status NiFpga_AcknowledgeIrqs(NiFpga_Session session,
uint32_t irqs);
/**
* Specifies the depth of the host memory part of the DMA FIFO. This method is
* optional. In order to see the actual depth configured, use
* NiFpga_ConfigureFifo2.
*
* @param session handle to a currently open session
* @param fifo FIFO to configure
* @param depth requested number of elements in the host memory part of the
* DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_ConfigureFifo(NiFpga_Session session,
uint32_t fifo,
size_t depth);
/**
* Specifies the depth of the host memory part of the DMA FIFO. This method is
* optional.
*
* @param session handle to a currently open session
* @param fifo FIFO to configure
* @param requestedDepth requested number of elements in the host memory part
* of the DMA FIFO
* @param actualDepth if non-NULL, outputs the actual number of elements in the
* host memory part of the DMA FIFO, which may be more than
* the requested number
* @return result of the call
*/
NiFpga_Status NiFpga_ConfigureFifo2(NiFpga_Session session,
uint32_t fifo,
size_t requestedDepth,
size_t* actualDepth);
/**
* Starts a FIFO. This method is optional.
*
* @param session handle to a currently open session
* @param fifo FIFO to start
* @return result of the call
*/
NiFpga_Status NiFpga_StartFifo(NiFpga_Session session,
uint32_t fifo);
/**
* Stops a FIFO. This method is optional.
*
* @param session handle to a currently open session
* @param fifo FIFO to stop
* @return result of the call
*/
NiFpga_Status NiFpga_StopFifo(NiFpga_Session session,
uint32_t fifo);
/**
* Reads from a target-to-host FIFO of booleans.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param data outputs the data that was read
* @param numberOfElements number of elements to read
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_ReadFifoBool(NiFpga_Session session,
uint32_t fifo,
NiFpga_Bool* data,
size_t numberOfElements,
uint32_t timeout,
size_t* elementsRemaining);
/**
* Reads from a target-to-host FIFO of signed 8-bit integers.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param data outputs the data that was read
* @param numberOfElements number of elements to read
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_ReadFifoI8(NiFpga_Session session,
uint32_t fifo,
int8_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* elementsRemaining);
/**
* Reads from a target-to-host FIFO of unsigned 8-bit integers.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param data outputs the data that was read
* @param numberOfElements number of elements to read
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_ReadFifoU8(NiFpga_Session session,
uint32_t fifo,
uint8_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* elementsRemaining);
/**
* Reads from a target-to-host FIFO of signed 16-bit integers.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param data outputs the data that was read
* @param numberOfElements number of elements to read
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_ReadFifoI16(NiFpga_Session session,
uint32_t fifo,
int16_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* elementsRemaining);
/**
* Reads from a target-to-host FIFO of unsigned 16-bit integers.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param data outputs the data that was read
* @param numberOfElements number of elements to read
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_ReadFifoU16(NiFpga_Session session,
uint32_t fifo,
uint16_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* elementsRemaining);
/**
* Reads from a target-to-host FIFO of signed 32-bit integers.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param data outputs the data that was read
* @param numberOfElements number of elements to read
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_ReadFifoI32(NiFpga_Session session,
uint32_t fifo,
int32_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* elementsRemaining);
/**
* Reads from a target-to-host FIFO of unsigned 32-bit integers.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param data outputs the data that was read
* @param numberOfElements number of elements to read
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_ReadFifoU32(NiFpga_Session session,
uint32_t fifo,
uint32_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* elementsRemaining);
/**
* Reads from a target-to-host FIFO of signed 64-bit integers.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param data outputs the data that was read
* @param numberOfElements number of elements to read
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_ReadFifoI64(NiFpga_Session session,
uint32_t fifo,
int64_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* elementsRemaining);
/**
* Reads from a target-to-host FIFO of unsigned 64-bit integers.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param data outputs the data that was read
* @param numberOfElements number of elements to read
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_ReadFifoU64(NiFpga_Session session,
uint32_t fifo,
uint64_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* elementsRemaining);
/**
* Writes to a host-to-target FIFO of booleans.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param data data to write
* @param numberOfElements number of elements to write
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param emptyElementsRemaining if non-NULL, outputs the number of empty
* elements remaining in the host memory part of
* the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_WriteFifoBool(NiFpga_Session session,
uint32_t fifo,
const NiFpga_Bool* data,
size_t numberOfElements,
uint32_t timeout,
size_t* emptyElementsRemaining);
/**
* Writes to a host-to-target FIFO of signed 8-bit integers.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param data data to write
* @param numberOfElements number of elements to write
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param emptyElementsRemaining if non-NULL, outputs the number of empty
* elements remaining in the host memory part of
* the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_WriteFifoI8(NiFpga_Session session,
uint32_t fifo,
const int8_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* emptyElementsRemaining);
/**
* Writes to a host-to-target FIFO of unsigned 8-bit integers.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param data data to write
* @param numberOfElements number of elements to write
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param emptyElementsRemaining if non-NULL, outputs the number of empty
* elements remaining in the host memory part of
* the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_WriteFifoU8(NiFpga_Session session,
uint32_t fifo,
const uint8_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* emptyElementsRemaining);
/**
* Writes to a host-to-target FIFO of signed 16-bit integers.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param data data to write
* @param numberOfElements number of elements to write
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param emptyElementsRemaining if non-NULL, outputs the number of empty
* elements remaining in the host memory part of
* the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_WriteFifoI16(NiFpga_Session session,
uint32_t fifo,
const int16_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* emptyElementsRemaining);
/**
* Writes to a host-to-target FIFO of unsigned 16-bit integers.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param data data to write
* @param numberOfElements number of elements to write
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param emptyElementsRemaining if non-NULL, outputs the number of empty
* elements remaining in the host memory part of
* the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_WriteFifoU16(NiFpga_Session session,
uint32_t fifo,
const uint16_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* emptyElementsRemaining);
/**
* Writes to a host-to-target FIFO of signed 32-bit integers.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param data data to write
* @param numberOfElements number of elements to write
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param emptyElementsRemaining if non-NULL, outputs the number of empty
* elements remaining in the host memory part of
* the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_WriteFifoI32(NiFpga_Session session,
uint32_t fifo,
const int32_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* emptyElementsRemaining);
/**
* Writes to a host-to-target FIFO of unsigned 32-bit integers.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param data data to write
* @param numberOfElements number of elements to write
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param emptyElementsRemaining if non-NULL, outputs the number of empty
* elements remaining in the host memory part of
* the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_WriteFifoU32(NiFpga_Session session,
uint32_t fifo,
const uint32_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* emptyElementsRemaining);
/**
* Writes to a host-to-target FIFO of signed 64-bit integers.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param data data to write
* @param numberOfElements number of elements to write
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param emptyElementsRemaining if non-NULL, outputs the number of empty
* elements remaining in the host memory part of
* the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_WriteFifoI64(NiFpga_Session session,
uint32_t fifo,
const int64_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* emptyElementsRemaining);
/**
* Writes to a host-to-target FIFO of unsigned 64-bit integers.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param data data to write
* @param numberOfElements number of elements to write
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param emptyElementsRemaining if non-NULL, outputs the number of empty
* elements remaining in the host memory part of
* the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_WriteFifoU64(NiFpga_Session session,
uint32_t fifo,
const uint64_t* data,
size_t numberOfElements,
uint32_t timeout,
size_t* emptyElementsRemaining);
/**
* Acquires elements for reading from a target-to-host FIFO of booleans.
*
* Acquiring, reading, and releasing FIFO elements prevents the need to copy
* the contents of elements from the host memory buffer to a separate
* user-allocated buffer before reading. The FPGA target cannot write to
* elements acquired by the host. Therefore, the host must release elements
* after reading them. The number of elements acquired may differ from the
* number of elements requested if, for example, the number of elements
* requested reaches the end of the host memory buffer. Always release all
* acquired elements before closing the session. Do not attempt to access FIFO
* elements after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoReadElementsBool(
NiFpga_Session session,
uint32_t fifo,
NiFpga_Bool** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for reading from a target-to-host FIFO of signed 8-bit
* integers.
*
* Acquiring, reading, and releasing FIFO elements prevents the need to copy
* the contents of elements from the host memory buffer to a separate
* user-allocated buffer before reading. The FPGA target cannot write to
* elements acquired by the host. Therefore, the host must release elements
* after reading them. The number of elements acquired may differ from the
* number of elements requested if, for example, the number of elements
* requested reaches the end of the host memory buffer. Always release all
* acquired elements before closing the session. Do not attempt to access FIFO
* elements after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoReadElementsI8(
NiFpga_Session session,
uint32_t fifo,
int8_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for reading from a target-to-host FIFO of unsigned 8-bit
* integers.
*
* Acquiring, reading, and releasing FIFO elements prevents the need to copy
* the contents of elements from the host memory buffer to a separate
* user-allocated buffer before reading. The FPGA target cannot write to
* elements acquired by the host. Therefore, the host must release elements
* after reading them. The number of elements acquired may differ from the
* number of elements requested if, for example, the number of elements
* requested reaches the end of the host memory buffer. Always release all
* acquired elements before closing the session. Do not attempt to access FIFO
* elements after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoReadElementsU8(
NiFpga_Session session,
uint32_t fifo,
uint8_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for reading from a target-to-host FIFO of signed 16-bit
* integers.
*
* Acquiring, reading, and releasing FIFO elements prevents the need to copy
* the contents of elements from the host memory buffer to a separate
* user-allocated buffer before reading. The FPGA target cannot write to
* elements acquired by the host. Therefore, the host must release elements
* after reading them. The number of elements acquired may differ from the
* number of elements requested if, for example, the number of elements
* requested reaches the end of the host memory buffer. Always release all
* acquired elements before closing the session. Do not attempt to access FIFO
* elements after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoReadElementsI16(
NiFpga_Session session,
uint32_t fifo,
int16_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for reading from a target-to-host FIFO of unsigned 16-bit
* integers.
*
* Acquiring, reading, and releasing FIFO elements prevents the need to copy
* the contents of elements from the host memory buffer to a separate
* user-allocated buffer before reading. The FPGA target cannot write to
* elements acquired by the host. Therefore, the host must release elements
* after reading them. The number of elements acquired may differ from the
* number of elements requested if, for example, the number of elements
* requested reaches the end of the host memory buffer. Always release all
* acquired elements before closing the session. Do not attempt to access FIFO
* elements after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoReadElementsU16(
NiFpga_Session session,
uint32_t fifo,
uint16_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for reading from a target-to-host FIFO of signed 32-bit
* integers.
*
* Acquiring, reading, and releasing FIFO elements prevents the need to copy
* the contents of elements from the host memory buffer to a separate
* user-allocated buffer before reading. The FPGA target cannot write to
* elements acquired by the host. Therefore, the host must release elements
* after reading them. The number of elements acquired may differ from the
* number of elements requested if, for example, the number of elements
* requested reaches the end of the host memory buffer. Always release all
* acquired elements before closing the session. Do not attempt to access FIFO
* elements after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoReadElementsI32(
NiFpga_Session session,
uint32_t fifo,
int32_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for reading from a target-to-host FIFO of unsigned 32-bit
* integers.
*
* Acquiring, reading, and releasing FIFO elements prevents the need to copy
* the contents of elements from the host memory buffer to a separate
* user-allocated buffer before reading. The FPGA target cannot write to
* elements acquired by the host. Therefore, the host must release elements
* after reading them. The number of elements acquired may differ from the
* number of elements requested if, for example, the number of elements
* requested reaches the end of the host memory buffer. Always release all
* acquired elements before closing the session. Do not attempt to access FIFO
* elements after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoReadElementsU32(
NiFpga_Session session,
uint32_t fifo,
uint32_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for reading from a target-to-host FIFO of signed 64-bit
* integers.
*
* Acquiring, reading, and releasing FIFO elements prevents the need to copy
* the contents of elements from the host memory buffer to a separate
* user-allocated buffer before reading. The FPGA target cannot write to
* elements acquired by the host. Therefore, the host must release elements
* after reading them. The number of elements acquired may differ from the
* number of elements requested if, for example, the number of elements
* requested reaches the end of the host memory buffer. Always release all
* acquired elements before closing the session. Do not attempt to access FIFO
* elements after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoReadElementsI64(
NiFpga_Session session,
uint32_t fifo,
int64_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for reading from a target-to-host FIFO of unsigned 64-bit
* integers.
*
* Acquiring, reading, and releasing FIFO elements prevents the need to copy
* the contents of elements from the host memory buffer to a separate
* user-allocated buffer before reading. The FPGA target cannot write to
* elements acquired by the host. Therefore, the host must release elements
* after reading them. The number of elements acquired may differ from the
* number of elements requested if, for example, the number of elements
* requested reaches the end of the host memory buffer. Always release all
* acquired elements before closing the session. Do not attempt to access FIFO
* elements after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo target-to-host FIFO from which to read
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoReadElementsU64(
NiFpga_Session session,
uint32_t fifo,
uint64_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for writing to a host-to-target FIFO of booleans.
*
* Acquiring, writing, and releasing FIFO elements prevents the need to write
* first into a separate user-allocated buffer and then copy the contents of
* elements to the host memory buffer. The FPGA target cannot read elements
* acquired by the host. Therefore, the host must release elements after
* writing to them. The number of elements acquired may differ from the number
* of elements requested if, for example, the number of elements requested
* reaches the end of the host memory buffer. Always release all acquired
* elements before closing the session. Do not attempt to access FIFO elements
* after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoWriteElementsBool(
NiFpga_Session session,
uint32_t fifo,
NiFpga_Bool** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for writing to a host-to-target FIFO of signed 8-bit
* integers.
*
* Acquiring, writing, and releasing FIFO elements prevents the need to write
* first into a separate user-allocated buffer and then copy the contents of
* elements to the host memory buffer. The FPGA target cannot read elements
* acquired by the host. Therefore, the host must release elements after
* writing to them. The number of elements acquired may differ from the number
* of elements requested if, for example, the number of elements requested
* reaches the end of the host memory buffer. Always release all acquired
* elements before closing the session. Do not attempt to access FIFO elements
* after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoWriteElementsI8(
NiFpga_Session session,
uint32_t fifo,
int8_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for writing to a host-to-target FIFO of unsigned 8-bit
* integers.
*
* Acquiring, writing, and releasing FIFO elements prevents the need to write
* first into a separate user-allocated buffer and then copy the contents of
* elements to the host memory buffer. The FPGA target cannot read elements
* acquired by the host. Therefore, the host must release elements after
* writing to them. The number of elements acquired may differ from the number
* of elements requested if, for example, the number of elements requested
* reaches the end of the host memory buffer. Always release all acquired
* elements before closing the session. Do not attempt to access FIFO elements
* after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoWriteElementsU8(
NiFpga_Session session,
uint32_t fifo,
uint8_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for writing to a host-to-target FIFO of signed 16-bit
* integers.
*
* Acquiring, writing, and releasing FIFO elements prevents the need to write
* first into a separate user-allocated buffer and then copy the contents of
* elements to the host memory buffer. The FPGA target cannot read elements
* acquired by the host. Therefore, the host must release elements after
* writing to them. The number of elements acquired may differ from the number
* of elements requested if, for example, the number of elements requested
* reaches the end of the host memory buffer. Always release all acquired
* elements before closing the session. Do not attempt to access FIFO elements
* after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoWriteElementsI16(
NiFpga_Session session,
uint32_t fifo,
int16_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for writing to a host-to-target FIFO of unsigned 16-bit
* integers.
*
* Acquiring, writing, and releasing FIFO elements prevents the need to write
* first into a separate user-allocated buffer and then copy the contents of
* elements to the host memory buffer. The FPGA target cannot read elements
* acquired by the host. Therefore, the host must release elements after
* writing to them. The number of elements acquired may differ from the number
* of elements requested if, for example, the number of elements requested
* reaches the end of the host memory buffer. Always release all acquired
* elements before closing the session. Do not attempt to access FIFO elements
* after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoWriteElementsU16(
NiFpga_Session session,
uint32_t fifo,
uint16_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for writing to a host-to-target FIFO of signed 32-bit
* integers.
*
* Acquiring, writing, and releasing FIFO elements prevents the need to write
* first into a separate user-allocated buffer and then copy the contents of
* elements to the host memory buffer. The FPGA target cannot read elements
* acquired by the host. Therefore, the host must release elements after
* writing to them. The number of elements acquired may differ from the number
* of elements requested if, for example, the number of elements requested
* reaches the end of the host memory buffer. Always release all acquired
* elements before closing the session. Do not attempt to access FIFO elements
* after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoWriteElementsI32(
NiFpga_Session session,
uint32_t fifo,
int32_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for writing to a host-to-target FIFO of unsigned 32-bit
* integers.
*
* Acquiring, writing, and releasing FIFO elements prevents the need to write
* first into a separate user-allocated buffer and then copy the contents of
* elements to the host memory buffer. The FPGA target cannot read elements
* acquired by the host. Therefore, the host must release elements after
* writing to them. The number of elements acquired may differ from the number
* of elements requested if, for example, the number of elements requested
* reaches the end of the host memory buffer. Always release all acquired
* elements before closing the session. Do not attempt to access FIFO elements
* after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoWriteElementsU32(
NiFpga_Session session,
uint32_t fifo,
uint32_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for writing to a host-to-target FIFO of signed 64-bit
* integers.
*
* Acquiring, writing, and releasing FIFO elements prevents the need to write
* first into a separate user-allocated buffer and then copy the contents of
* elements to the host memory buffer. The FPGA target cannot read elements
* acquired by the host. Therefore, the host must release elements after
* writing to them. The number of elements acquired may differ from the number
* of elements requested if, for example, the number of elements requested
* reaches the end of the host memory buffer. Always release all acquired
* elements before closing the session. Do not attempt to access FIFO elements
* after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoWriteElementsI64(
NiFpga_Session session,
uint32_t fifo,
int64_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Acquires elements for writing to a host-to-target FIFO of unsigned 64-bit
* integers.
*
* Acquiring, writing, and releasing FIFO elements prevents the need to write
* first into a separate user-allocated buffer and then copy the contents of
* elements to the host memory buffer. The FPGA target cannot read elements
* acquired by the host. Therefore, the host must release elements after
* writing to them. The number of elements acquired may differ from the number
* of elements requested if, for example, the number of elements requested
* reaches the end of the host memory buffer. Always release all acquired
* elements before closing the session. Do not attempt to access FIFO elements
* after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo host-to-target FIFO to which to write
* @param elements outputs a pointer to the elements acquired
* @param elementsRequested requested number of elements
* @param timeout timeout in milliseconds, or NiFpga_InfiniteTimeout
* @param elementsAcquired actual number of elements acquired, which may be
* less than the requested number
* @param elementsRemaining if non-NULL, outputs the number of elements
* remaining in the host memory part of the DMA FIFO
* @return result of the call
*/
NiFpga_Status NiFpga_AcquireFifoWriteElementsU64(
NiFpga_Session session,
uint32_t fifo,
uint64_t** elements,
size_t elementsRequested,
uint32_t timeout,
size_t* elementsAcquired,
size_t* elementsRemaining);
/**
* Releases previously acquired FIFO elements.
*
* The FPGA target cannot read elements acquired by the host. Therefore, the
* host must release elements after acquiring them. Always release all acquired
* elements before closing the session. Do not attempt to access FIFO elements
* after the elements are released or the session is closed.
*
* @param session handle to a currently open session
* @param fifo FIFO from which to release elements
* @param elements number of elements to release
* @return result of the call
*/
NiFpga_Status NiFpga_ReleaseFifoElements(NiFpga_Session session,
uint32_t fifo,
size_t elements);
/**
* Gets an endpoint reference to a peer-to-peer FIFO.
*
* @param session handle to a currently open session
* @param fifo peer-to-peer FIFO
* @param endpoint outputs the endpoint reference
* @return result of the call
*/
NiFpga_Status NiFpga_GetPeerToPeerFifoEndpoint(NiFpga_Session session,
uint32_t fifo,
uint32_t* endpoint);
#if NiFpga_Cpp
}
#endif
#endif