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Agilent IO Libraries Suite
E2094S
Agilent VISA
User’s Guide for IO
Libraries Suite 15.5
Agilent Technologies
#
Notices
© Agilent Technologies, Inc. 71995-1996,
1998, 2000-2009
No part of this manual may be reproduced in any form or by any means (including electronic storage and retrieval or translation into a foreign language) without prior agreement and written consent from Agilent Technologies, Inc. as governed by
United States and international copyright laws.
Manual Part Number
E2094-90013
Edition
First edition, October 2009
Agilent Technologies, Inc.
815 14th Street SW
Loveland, CO 80537 USA
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This guide is valid for Revisions 15.xx of the Agilent IO Libraries Suite software, where xx refers to minor revisions of the software that do not affect the technical accuracy of this guide.
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Agilent VISA User’s Guide
Agilent VISA User’s Guide
1 Introduction
What’s in This Guide?
VISA Overview
Using VISA, VISA COM, and SICL
VISA Support
VISA Documentation
Contacting Agilent
2 Building a VISA Application in Windows
Building a VISA Program (C/C++)
Compiling and Linking VISA Programs (C/C++)
Sample VISA Program (C/C++)
Building a VISA Program (Visual Basic)
Visual Basic Programming Considerations
Sample VISA Program (Visual Basic)
Logging Error Messages
Using the Event Viewer
Using the Debug Window
3 Programming with VISA
VISA Resources and Attributes
28
VISA Resources
VISA Attributes
Using Sessions
30
Including the VISA Declarations File (C/C++)
30
Adding the visa32.bas File (Visual Basic)
Opening a Session
31
Addressing a Session
Agilent VISA User’s Guide 3
4
Closing a Session
Searching for Resources
Sending I/O Commands
Types of I/O
Using Non-Formatted I/O
Using Events and Handlers
Events and Attributes
Using the Callback Method
Using the Queuing Method
62
Trapping Errors
68
Trapping Errors
Exception Events
Using Locks
Lock Functions
viLock/viUnlock Functions
VISA Lock Types
75
4 Programming via GPIB and VXI
GPIB and VXI Interfaces Overview
80
General Interface Information
80
GPIB Interfaces Overview
VXI Interfaces Overview
84
GPIB-VXI Interfaces Overview
Using High-Level Memory Functions
Programming the Registers
High-Level Memory Functions: Sample Programs
90
Using Low-Level Memory Functions
Programming the Registers
Low-Level Memory Functions: Code Samples
Using Low/High-Level Memory I/O Methods
100
Agilent VISA User’s Guide
Using Low-Level
100
Using High-Level
viIn/viOut 101
Using High-Level
viMoveIn/viMoveOut 101
Using the Memory Access Resource
Memory I/O Services
MEMACC Attribute Descriptions
109
Using VXI-Specific Attributes
Using the Map Address as a Pointer
Setting the VXI Trigger Line
114
5 Programming via LAN
LAN and Remote Interfaces Overview
Direct LAN Connection versus Remote IO Server/Client
Connection
Remote IO Server/Client Architecture
118
Addressing LAN-Connected Devices
Using the TCPIP Interface Type for LAN Access
Using a Remote Interface for LAN Access
6 Programming via USB
USB Interfaces Overview
Communicating with a USB Instrument Using VISA
Glossary
Agilent VISA User’s Guide 5
6 Agilent VISA User’s Guide
Agilent IO Libraries Suite
Agilent VISA User’s Guide
N O T E
1
Introduction
This Agilent VISA User’s Guide describes the Agilent Virtual Instrument
Software Architecture (VISA) library and shows how to use it to develop I/O applications and instrument drivers on Windows PCs.
Before you can use VISA, you must install and configure VISA on your computer. See the Agilent IO Libraries Suite Connectivity Guide with
Getting Started for installation on Windows systems.
Note that using VISA functions and SICL functions in the same I/O application is not supported.
This chapter includes:
• What’s In This Guide?
• VISA Overview
• Contacting Agilent
Agilent Technologies
7
8
1
Introduction
What’s in This Guide?
This guide shows VISA programming techniques using C/C++ and
Visual Basic. This chapter provides an overview of VISA and shows how to contact Agilent Technologies. Subsequent chapters in this guide address the following topics:
• Chapter 2 - Building a VISA Application in Windows describes how to build a VISA application in a Windows environment. A sample program is provided to help you get started programming with VISA.
• Chapter 3 - Programming with VISA describes the basics of VISA and lists some sample programs. The chapter also includes information on creating sessions, using formatted I/O, events, etc.
• Chapter 4 - Programming via GPIB and VXI provides guidelines for using VISA to communicate over the GPIB, GPIB-VXI, and VXI interfaces to instruments.
• Chapter 5 - Programming via LAN provides guidelines for using
VISA to communicate over a LAN (Local Area Network) to instruments.
• Chapter 6 - Programming via USB provides guidelines for using
VISA to communicate over a USB (Universal Serial Bus) to instruments.
• Glossary includes a glossary of terms and their definitions.
See “VISA Documentation" on page 10 for other sources of information
on VISA programming.
Agilent VISA User’s Guide
Introduction
1
VISA Overview
VISA is an application programming interface (API) for instrument control. It allows you to programmatically send commands and receive data from instruments and other test and measurement devices (such as sources and switches).
VISA is a part of the Agilent IO Libraries Suite product. The Agilent IO
Libraries Suite includes three libraries: Agilent Virtual Instrument
Software Architecture (VISA), VISA for the Common Object Model
(VISA COM), and Agilent Standard Instrument Control Library (SICL).
This guide describes Agilent VISA for supported Windows environments.
For information on VISA COM, see the online Help on VISA COM, available by clicking the blue IO Control icon on your screen (if you have installed Agilent IO Libraries Suite). For information on using
SICL in Windows, see the Agilent SICL User’s Guide for Windows. For information on Agilent IO Libraries Suite, see the Agilent IO Libraries
Suite Connectivity Guide with Getting Started and the Agilent IO
Libraries Suite Online Help.
Using VISA, VISA COM, and SICL
Agilent Virtual Instrument Software Architecture (VISA) is an I/O library designed according to the VXIplug&play System Alliance that allows software developed from different vendors to run on the same system.
If you are using new instruments or are developing new I/O applications or instrument drivers, and you have chosen to use direct I/O rather than instrument drivers, we recommend you use Agilent VISA or VISA
COM. See the Agilent IO Libraries Suite Online Help for an in-depth discussion of your programming options.
Agilent Standard Instrument Control Library (SICL) is an I/O library developed by Agilent that is portable across many I/O interfaces and systems. You can use Agilent SICL if you have been using SICL and want to remain compatible with software currently implemented in
SICL.
Agilent VISA User’s Guide 9
1
Introduction
VISA Support
This 32-bit version of VISA is supported on Microsoft Windows 2000,
Windows XP and Windows Vista. (For information on support of older operating systems, see the Agilent IO Libraries Suite Online Help.) C,
C++, and Visual Basic are supported on these Windows versions. C# and Visual Basic .NET are also supported via the visa32.cs and visa32.vb
header files that are included with the Agilent VISA library.
VISA is supported on the GPIB, VXI, GPIB-VXI, Serial (RS-232),
LAN, and USB interfaces. LAN support from within VISA occurs via an address translation such that a GPIB interface can be accessed remotely over a computer network.
Agilent VISA provides support for version 3.0 of the VISA specification.
VISA Documentation
This table shows associated documentation you can use when programming with Agilent VISA.
Table 1 Agilent VISA Documentation
Document
Agilent IO Libraries Suite
Connectivity Guide with Getting
Started
VISA Online Help
VISA Sample Programs
Description
Shows how to install, configure, and maintain Agilent IO Libraries Suite.
A function reference and other programming information is provided in the form of Windows Help.
Sample programs are provided online to help you develop VISA applications.
Specifications for VISA.
VXIplug&play System Alliance
VISA Library Specification 4.3
IEEE Standard Codes, Formats,
Protocols, and Common
Commands
ANSI/IEEE Standard 488.2-1992.
10 Agilent VISA User’s Guide
Introduction
1
Table 1 Agilent VISA Documentation
VXIbus Consortium specifications (when using VISA over LAN)
TCP/IP Instrument Protocol
Specification - VXI-11, Rev. 1.0
TCP/IP-VXIbus Interface Specification -
VXI-11.1, Rev. 1.0
TCP/IP-IEEE 488.1 Interface
Specification - VXI-11.2, Rev. 1.0
TCP/IP-IEEE 488.2 Instrument Interface
Specification - VXI-11.3, Rev. 1.0
Agilent VISA User’s Guide 11
1
Introduction
Contacting Agilent
• In the USA, you can reach Agilent Technologies by telephone at:
USA: 1-800-829-4444
• Outside the USA, contact your country’s Agilent support organization. A list of contact information for other countries is available on the Agilent Web site: http://www.agilent.com/find/assist
• The Agilent Developer Network (ADN), http://www.agilent.com/find/adn is a one-stop web resource that supports your connectivity needs with software downloads, sample code, technical notes and white papers.
12 Agilent VISA User’s Guide
Agilent IO Libraries Suite
Agilent VISA User’s Guide
2
Building a VISA Application in
Windows
This chapter provides guidelines for building a VISA application in a
Windows environment.
The chapter contains the following sections:
• Building a VISA Program (C/C++)
• Building a VISA Program (Visual Basic)
• Logging Error Messages
For information on building a VISA application in Visual Studio .NET, see the VISA Online Help.
Agilent Technologies
13
2
Building a VISA Application in Windows
Building a VISA Program (C/C++)
This section provides guidelines for building VISA programs using the
C/C++ language, including:
• Compiling and Linking VISA Programs (C/C++)
• Sample VISA Program (C/C++)
Compiling and Linking VISA Programs (C/C++)
This section provides a summary of important compiler-specific considerations when developing Win32 applications.
Linking to VISA Libraries
Your application must link to the VISA import library as follows, assuming default installation directories and Microsoft compilers:
C:\VXIPNP\WinNT\lib\msc\visa32.lib
The following steps will help you do this. This information is specific to your development environment.
Microsoft Visual C++ Version 6.0 Development Environment
1 Use the File menu to create a new project or open an existing project.
2 Select Project > Settings from the menu and click the C/C++ tab.
3 Select Code Generation from the Category list box and select
Multi-Threaded using DLL from the Use Run-Time Libraries list box. (VISA requires these definitions for Win32.) Click OK to close the dialog box.
4 Select Project > Settings from the menu. Click the Link tab and add visa32.lib
to the Object/Library Modules list box. Optionally, you may add the library directly to your project file. Click OK to close the dialog box.
5 You may want to add the include files and library files search paths.
They are set as follows:
• Select Tools > Options from the menu.
• Click the Directories tab to set the include file path.
• Select Include Files from the Show Directories For list box.
14 Agilent VISA User’s Guide
Building a VISA Application in Windows
2
• Click at the bottom of the list box and type:
C:\Program Files\IVIfoundation\IVI\VISA\ winnt\include
(This assumes that you used the default installation location for
VISA. If VISA had been installed previously, it may be in a different location.)
• Select Library Files from the Show Directories For list box.
• Click at the bottom of the list box and type:
C:\VXIPNP\WinNT\lib\msc
(This assumes that you used the default installation location for
VISA.)
6 Add or create your C or C++ source files. For example, to build the sample described below, select Project > Add to Project > Files... and type or browse to C:\Program Files\Agilent\
IO Libraries Suite\ ProgrammingSamples\C\VISA\ idn.c.
7 Click Build > Rebuild All to build the VISA program.
Microsoft Visual Studio .NET
For information on building a VISA application in Visual Studio .NET, see the VISA Online Help.
Sample VISA Program (C/C++)
This section lists a sample program called idn that queries a GPIB instrument for its identification string. This sample assumes a Win32 console application using Microsoft Visual Studio® on Windows.
The idn sample files are in the ProgrammingSamples directory under the Agilent IO Libraries Suite installation directory. By default, the sample files are in
C:\Program Files\Agilent\IO Libraries Suite\
ProgrammingSamples\C\VISA.
Sample C/C++ Program Source Code
The source file idn.c follows. An explanation of the various function calls in the sample is provided directly after the program listing. If the program runs correctly and your PC is connected to a 54622A oscilloscope, the following is an example of the program output.
Agilent VISA User’s Guide 15
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Building a VISA Application in Windows
AGILENT TECHNOLOGIES,54622A,987654312,A.01.50
If the program does not run, see the Event Viewer for a list of run-time errors.
/*idn.c
This example program queries a GPIB device for an identification string and prints the results. Note that you must change the address.
*/
#include <visa.h>
#include <stdio.h> void main () {
ViSession defaultRM, vi; char buf [256] = {0};
/* Open session to GPIB device at address 22 */ viOpenDefaultRM(&defaultRM); viOpen(defaultRM,
"GPIB0::22::INSTR",VI_NULL,VI_NULL,
&vi);
/* Initialize device */ viPrintf(vi, "*RST\n");
/* Send an *IDN? string to the device */ viPrintf(vi, "*IDN?\n");
/* Read results */ viScanf(vi, "%t", buf);
/* Print results */ printf("Instrument identification string:
%s\n", buf);
/* Close session */ viClose(vi); viClose(defaultRM);}
16 Agilent VISA User’s Guide
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Building a VISA Application in Windows
2
C/C++ Sample Program Contents
A summary of the VISA function calls used in the preceding sample
C/C++ program follows. For a more detailed explanation of VISA
functionality, see Chapter 3 , “Programming with VISA.” See the VISA
Online Help for more detailed information on these VISA function calls.
Table 2 Summary of VISA Function Calls Used in the C/C++ Sample
Function(s) visa.h
ViSession
Description
This file is included at the beginning of the program to provide the function prototypes and constants defined by
VISA.
The ViSession is a VISA data type. Each object that will establish a communication channel must be defined as
ViSession .
viOpenDefaultR
M
You must first open a session with the default resource manager with the viOpenDefaultRM function. This function will initialize the default resource manager and return a pointer to that resource manager session.
viOpen viPrintf viScanf viClose
and
This function establishes a communication channel with the device specified. A session identifier that can be used with other VISA functions is returned. This call must be made for each device you will be using.
These are the VISA formatted I/O functions that are patterned after those used in the C programming language. The viPrintf call sends the IEEE 488.2 *RST command to the instrument and puts it in a known state.
The viPrintf call is used again to query for the device identification ( *IDN?
). The viScanf call is then used to read the results.
This function must be used to close each session. When you close a device session, all data structures that had been allocated for the session will be deallocated. When you close the default manager session, all sessions opened using that default manager session will be closed.
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Building a VISA Application in Windows
Building a VISA Program (Visual Basic)
This section provides guidelines for building a VISA program in the
Microsoft Visual Basic (VB) language, including:
• Visual Basic Programming Considerations
• Sample VISA Program (Visual Basic)
Visual Basic Programming Considerations
Some considerations for programming in Visual Basic follow. This information applies to Microsoft Visual Basic version 6.0; for information on building a VISA application in Microsoft Visual Studio
.NET, see the VISA Online Help.
Required Module for a Visual Basic VISA Program
Before you can use VISA specific functions, your application must add the visa32.bas VISA Visual Basic module found in C:\VXIPNP\
WinNT\include\ (assuming default installation directories).
Adding the visa32.bas File to Your Project
To install visa32.bas:
1 Select Project > Add Module from the Visual Basic 6.0 menu.
2 Select the Existing tab.
3 Browse and select the visa32.bas file from the applicable directory (by default, C:\VXIPNP\WinNT\include\).
4 Click the Open button.
VISA Limitations in Visual Basic
VISA functions return a status code that indicates success or failure of the function. The only indication of an error is the value of a returned status code. The VB Error variable is not set by any VISA function.
Thus, you cannot use the ON ERROR construct in VB or the value of the VB Error variable to catch VISA function errors.
18 Agilent VISA User’s Guide
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2
VISA cannot call back to a VB function. Thus, you can only use the
VI_QUEUE mechanism in viEnableEvent. There is no way to install a VISA event handler in VB.
VISA functions that take a variable number of parameters (viPrintf, viScanf , viQueryf) are not callable from VB. Use the corresponding viVPrintf, viVScanf and viVQueryf functions instead.
You cannot pass variables of type Variant to VISA functions. If you attempt this, the Visual Basic program will probably crash with a
'General Protection Fault' or an 'Access Violation.'
Format Conversion Commands
The functions viVPrintf, viVscanf and viVqueryf can be called from VB, but there are restrictions on the format conversions that can be used. Only one format conversion command can be specified in a format string (a format conversion command begins with the % character).
For example, the following is invalid: status = viVPrintf(vi, "%lf%d" + Chr$(10),
...)
Instead, you must make one call for each format conversion command, as shown in the following example: status = viVPrintf(vi, "%lf" + Chr$(10), dbl_value) status = viVPrintf(vi, "%d" + Chr$(10), int_value)
Numeric Arrays
When reading from or writing to a numeric array, you must specify the first element of a numeric array as the params parameter. This passes the address of the first array element to the function. For example, the following code declares an array of 50 floating point numbers and then calls viVPrintf to write from the array.
Dim flt_array(50) As Double status = viVPrintf(id, "%,50f", dbl_array(0))
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Building a VISA Application in Windows
20
Strings
When reading in a string value with viVScanf or viVQueryf, you must pass a fixed length string as the params parameter. To declare a fixed length string, instead of using the normal variable length declaration:
Dim strVal as String use the following declaration, where 40 is the fixed length.
Dim strVal as String * 40
Sample VISA Program (Visual Basic)
This section lists a sample program called idn that queries a GPIB instrument for its identification string. This sample builds a standard
.exe application for WIN32 programs using the Visual Basic 6.0 programming language.
Assuming default installation directories, the idn sample files are in C:\
Program Files\Agilent\IO Libraries Suite\
ProgrammingSamples\VB6\VISA\IDN
N O T E
Steps to Running the Program
The steps to building and running the idn sample program follow.
1 Connect an instrument to a GPIB interface that is compatible with
IEEE 488.2.
2 Start the Visual Basic 6.0 application.
This example assumes you are building a new project (no .vbp file exists for the project). If you do not want to build the project from scratch, from the menu select File > Open Project... and select and open the idn.vbp file. Then skip to Step 7.
3 Start a new Visual Basic Standard .exe project. VB 6.0 will open a new project, Project1, with a blank Form, Form1.
4 From the menu, select Project > Add Module, select the Existing tab, and browse to the idn directory. If you used default installation paths, this directory is C:\Program Files\Agilent\IO
Agilent VISA User’s Guide
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2
Libraries Suite\ProgrammingSamples\VB6\VISA\ idn .
5 Select the file idn.bas and click Open. Since the Main() subroutine is executed when the program is run without requiring user interaction with a Form, you may delete Form1 if desired. To do this, right-click Form1 in the Project Explorer window and select
Remove Form1.
6 VISA applications in Visual Basic require the VISA Visual Basic
(VB) declaration file visa32.bas in your VB project. This file contains the VISA function definitions and constant declarations needed to make VISA calls from Visual Basic. To add this module to your project in VB 6.0, from the menu select Project > Add
Module, select the Existing tab, browse to the directory containing the VB declaration file (by default, this is C:\VXIPNP\WinNT\ include\ ), select visa32.bas, and click Open.
7 At this point, you can run and debug the Visual Basic project. You may need to change the VISA interface name and address in the code to match your device’s configuration.
8 If you want to compile to an executable file, from the menu select
File > Make idn.exe... and click OK. This will create idn.exe in the idn directory.
Sample Program Source Code
An explanation of the various function calls in the sample is provided after this program listing. If the program runs correctly, the following is an example of the output that appears in a message box if your PC is connected to a 54601A oscilloscope.
HEWLETT-PACKARD,54601A,0,1.7
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Building a VISA Application in Windows
If the program does not run, see the Event Viewer for a list of run-time errors. The source file idn.bas follows.
Option Explicit
''''''''''''''''''''''''''''''''''''''''''''''''
'''''''''''''''''''
' idn.bas
' This example program queries a GPIB device for
' an identification string and prints the
' results. Note that you may have to change the
' VISA Interface Name and address for your
' device from "GPIB0" and "22",respectively.
''''''''''''''''''''''''''''''''''''''''''''''''
'''''''''''''''''''
Sub Main()
Dim defrm As Long 'Session to Default
Resource Manager
Dim vi As Long 'Session to instrument
Dim strRes As String * 200 'Fixed length
string to hold results
' Open the default resource manager session
Call viOpenDefaultRM(defrm)
' Open the session to the resource
' The "GPIB0" parameter is the VISA Interface
' name to a
' GPIB instrument as defined in
' Connection Expert.
' Change this name to what you have defined
' for your VISA Interface.
' "GPIB0::22::INSTR" is the address string
' for the device.
' this address will be the same as seen in:
' Connection Expert)
22 Agilent VISA User’s Guide
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Call viOpen(defrm, "GPIB0::22::INSTR", 0, 0,
vi)
' Initialize device
Call viVPrintf(vi, "*RST" + Chr$(10), 0)
' Ask for the device's *IDN string.
Call viVPrintf(vi, "*IDN?" + Chr$(10), 0)
' Read the results as a string.
Call viVScanf(vi, "%t", strRes)
' Display the results
MsgBox "Result is: " + strRes, vbOKOnly,
"*IDN? Result"
' Close the vi session and the resource
manager session
Call viClose(vi)
Call viClose(defrm)
End Sub
Sample Program Contents
A summary of the VISA function calls used in the preceding sample
Visual Basic program follows. For a more detailed explanation of VISA
functionality, see Chapter 3 , “Programming with VISA.” See the VISA
Online Help for more detailed information on these VISA function calls.
Table 3 Summary of VISA Function Calls in Visual Basic Sample
Function(s) viOpenDefaultRM
Description
You must first open a session with the default resource manager with the viOpenDefaultRM function. This function will initialize the default resource manager and return a pointer (defrm) to that resource manager session.
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Building a VISA Application in Windows
Table 3 Summary of VISA Function Calls in Visual Basic Sample viOpen viVPrintf and viVScanf viClose
This function establishes a communication channel with the device specified. A session identifier (vi) that can be used with other VISA functions is returned.
This call must be made for each device you will be using.
These are the VISA formatted I/O functions. The
viVPrintf call sends the IEEE 488.2 *RST command to the instrument (plus a linefeed character) and puts it in a known state. The viVPrintf call is used again to query for the device identification (*IDN?). The
viVScanf call is then used to read the results (strRes) that are displayed in a Message Box.
This function must be used to close each session.
When you close a device session, all data structures that had been allocated for the session will be deallocated. When you close the default manager session, all sessions opened using that default manager session will be closed.
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Logging Error Messages
When developing or debugging your VISA application, you may want to view internal VISA messages while your application is running. You can do this by using the Event Viewer utility or the Debug Window.
There are three choices for VISA logging:
• Off (default) for best performance
• Event Viewer
• Debug Window
Using the Event Viewer
The Event Viewer utility provides a way to view internal VISA error messages during application execution. Some of these internal messages do not represent programming errors; they indicate events which are being handled internally by VISA. The process for using the Event
Viewer is:
• Enable VISA logging from the Agilent IO Control by clicking the blue IO icon on the taskbar and then clicking Agilent VISA Options
> VISA Logging > Event Viewer.
• Run your VISA program.
• View VISA error messages by running the Event Viewer. From the
Agilent IO Control, click Event Viewer. VISA error messages will appear in the application log of the Event Viewer utility.
Using the Debug Window
When VISA logging is directed to the Debug Window, VISA writes logging messages using the Win32 API call OutputDebugString(). The most common use for this feature is when debugging your VISA
Agilent VISA User’s Guide 25
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Building a VISA Application in Windows program using an application such as Microsoft Visual Studio. In this case, VISA messages will appear in the Visual Studio output window.
The process for using the Debug Window is:
1 Enable VISA logging from the Agilent IO Control by clicking the blue IO icon on the taskbar and then clicking Agilent VISA Options
> VISA Logging > Debug Window.
2 Run your VISA program from Microsoft Visual Studio (or equivalent application).
3 View error messages in the Visual Studio (or equivalent) output window.
26 Agilent VISA User’s Guide
Agilent IO Libraries Suite
Agilent VISA User’s Guide
3
Programming with VISA
This chapter describes how to program with VISA. The basics of VISA are described, including formatted I/O, events and handlers, attributes, and locking. Example programs are also provided and can be found in the ProgrammingSamples subdirectory
(C:\Program Files\Agilent\IO Libraries Suite\
ProgrammingSamples in a default installation).
Click the IO Control and select Installation Information to see the specific installation directories used on your PC. For specific details on
VISA functions, see the VISA Online Help.
This chapter contains the following sections:
• VISA Resources and Attributes
• Using Sessions
• Sending I/O Commands
• Using Events and Handlers
• Trapping Errors
• Using Locks
Agilent Technologies
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Programming with VISA
VISA Resources and Attributes
This section introduces VISA resources and attributes, including:
• VISA Resources
• VISA Attributes
VISA Resources
In VISA, a resource is defined as any device (such as a voltmeter) with which VISA can provide communication. VISA defines six resource
classes that a complete VISA system, fully compliant with the
VXIplug&play Systems Alliance specification, can implement. Each resource class includes:
• Attributes to determine the state of a resource or session or to set a resource or session to a specified state.
• Events for communication with applications.
• Operations (functions) that can be used for the resource class.
Table 4describes each resource class supported by Agilent VISA. See
VISA Resource Classes in the VISA Online Help for a description of the attributes, events, and operations for each resource class.
N O T E
Although the Servant Device-Side (SERVANT) resource is defined by the VISA specification, the SERVANT resource is not supported by
Agilent VISA. The SERVANT Resource is intended for advanced users who need to write code that causes a computer to function as an instrument rather than as a controller.
Table 4 Resource Classes Supported by Agilent VISA
Resource Class
Instrument
Control (INSTR)
Interface Types
Generic, GPIB,
GPIB-VXI, Serial,
TCPIP, USB, VXI
GPIB Bus
Interface
(INTFC)
Generic, GPIB
Resource Class Description
Device operations (reading, writing, triggering, etc.).
Raw GPIB interface operations (reading, writing, triggering, etc.).
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Table 4 Resource Classes Supported by Agilent VISA (continued)
Memory Access
(MEMACC)
Generic, GPIB-VXI,
VXI
VXI Mainframe
Backplane
(BACKPLANE)
TCPIP Socket
(SOCKET)
Generic, GPIB-VXI,
VXI (GPIB-VXI
BACKPLANE not supported)
Generic, TCPIP
Address space of a memory-mapped bus such as the VXIbus.
VXI-defined operations and properties of each backplane in a VXIbus system.
Operations and properties of a raw network socket connection using TCPIP.
VISA Attributes
Attributes are associated with resources or sessions. You can use attributes to determine the state of a resource or session, or to set a resource or session to a specified state.
For example, you can use the viGetAttribute function to read the state of an attribute for a specified session, event context, or find list. There are read only (RO) and read/write (RW) attributes. Use the
viSetAttribute function to modify the state of a read/write attribute for a specified session, event context, or find list.
The pointer passed to viGetAttribute must point to the exact type required for that attribute (ViUInt16, ViInt32, etc.). For example, when reading an attribute state that returns a ViUInt16, declare a variable of that type and use it for the returned data. If ViString is returned, allocate an array and pass a pointer to that array for returned data.
Example: Reading a VISA Attribute
This example reads the state of the VI_ATTR_TERMCHAR_EN attribute and changes it if it is false.
ViBoolean state, newstate; newstate=VI_TRUE; viGetAttribute(vi, VI_ATTR_TERMCHAR_EN, &state); if (state err !=VI_TRUE) viSetAttribute(vi,
VI_ATTR_TERMCHAR_EN, newstate);
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Using Sessions
This section shows how to use VISA sessions, including:
• Including the VISA Declarations File (C/C++)
• Adding the visa32.bas File (Visual Basic)
• Opening a Session to a Resource
• Addressing a Session
• Closing a Session
• Searching for Resources
Including the VISA Declarations File (C/C++)
For C and C++ programs, you must include the visa.h header file at the beginning of every file that contains VISA function calls:
#include "visa.h"
This header file contains the VISA function prototypes and the definitions for all VISA constants and error codes. The visa.h header file also includes the visatype.h header file.
The visatype.h header file defines most of the VISA types. The
VISA types are used throughout VISA to specify data types used in the functions. For example, the viOpenDefaultRM function requires a pointer to a parameter of type ViSession. If you find ViSession in the visatype.h
header file, you will find that ViSession is eventually typed as an unsigned long. VISA types are also listed in VISA System
Information in the VISA Online Help.
Adding the visa32.bas File (Visual Basic)
You must add the visa32.bas Basic module file to your Visual Basic project. The visa32.bas file contains the VISA function prototypes and definitions for all VISA constants and error codes.
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Opening a Session
A session is a channel of communication. Sessions must first be opened on the default resource manager, and then for each resource you will be using.
• A resource manager session is used to initialize the VISA system. It is a parent session that knows about all the opened sessions. A resource manager session must be opened before any other session can be opened.
• A resource session is used to communicate with a resource on an interface. A session must be opened for each resource you will be using. When you use a session you can communicate without worrying about the type of interface to which it is connected. This insulation makes applications more robust and portable across interfaces.
Resource Manager Sessions
There are two parts to opening a communications session with a specific resource. First, you must open a session to the default resource manager with the viOpenDefaultRM function. The first call to this function initializes the default resource manager and returns a session to that resource manager session. You only need to open the default manager session once. However, subsequent calls to viOpenDefaultRM return a unique session to the same default resource manager resource.
Resource Sessions
Next, open a session with a specific resource using the viOpen function.
This function uses the session returned from viOpenDefaultRM and returns its own session to identify the resource session. The following shows the function syntax.
viOpenDefaultRM(sesn); viOpen(sesn, rsrcName, accessMode, timeout,
vi);
The session returned from viOpenDefaultRM must be used in the sesn parameter of the viOpen function. The viOpen function then uses that session and the resource address specified in the rsrcName parameter to open a resource session. The vi parameter in viOpen returns a session identifier that can be used with other VISA functions.
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Your program may have several sessions open at the same time after creating multiple session identifiers by calling the viOpen function multiple times. The following table summarizes the parameters in the previous function calls.
Table 5 Parameters Used in Function Calls
Parameter sesn
Description
A session returned from the viOpenDefaultRM function that identifies the resource manager session.
A unique symbolic name of the resource (resource address).
rsrcName accessMode Specifies the modes by which the resource is to be accessed.
The value VI_EXCLUSIVE_LOCK is used to acquire an exclusive lock immediately upon opening a session. If a lock cannot be acquired, the session is closed and an error is returned. The VI_LOAD_CONFIG value is used to configure attributes specified by some external configuration utility. If this value is not used, the session uses the default values provided by this specification.
timeout vi
Multiple access modes can be used simultaneously by specifying a “bit-wise OR” of the values.
If the accessMode parameter requires a lock, this parameter specifies the absolute time period (in milliseconds) that the resource waits to get unlocked before this operation returns an error. Otherwise, this parameter is ignored.
This is a pointer to the session identifier for this particular resource session. This pointer will be used to identify this resource session when using other VISA functions.
Example: Opening a Resource Session
This code sample shows one way of opening resource sessions with a GPIB multimeter and a
GPIB-VXI scanner. The sample first opens a session with the default resource manager. The example then uses the session returned from the resource manager, and a VISA address, to open a session with the GPIB device at address 22. You can now identify that session as dmm when you call other VISA functions.
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The example again uses the session returned from the resource manager, with another VISA address, to open a session with the GPIB-VXI device at primary address 9 and VXI logical address (secondary address) 24. You will now identify this session as scanner when calling
other VISA functions. See the following section, “Addressing a
Session”, for information on addressing particular devices.
ViSession defaultRM, dmm, scanner;
.
viOpenDefaultRM(&defaultRM); viOpen(defaultRM, "GPIB0::22::INSTR",VI_NULL,
VI_NULL,&dmm); viOpen(defaultRM, "GPIB-VXI0::24::INSTR",
VI_NULL, VI_NULL,&scanner);
.
viClose(scanner); viClose(dmm); viClose(defaultRM);
Addressing a Session
As shown in the previous section, the rsrcName parameter in the
viOpen function is used to identify a specific resource. This parameter consists of the VISA interface ID and the resource address. The interface ID is determined when you run the Agilent Connection Expert utility. The interface ID is usually the VISA interface type followed by a number.
The following table illustrates the format of the rsrcName for different
VISA interface types. INSTR is an optional parameter that indicates that you are communicating with a resource that is of type INSTR, meaning instrument. The keywords are:
• ASRL - used for asynchronous serial devices.
• GPIB - used for GPIB devices and interfaces.
• GPIB-VXI - used for GPIB-VXI controllers.
• TCPIP - used for LAN instruments.
• VXI - used for VXI instruments.
• USB - used for USB instruments.
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Table 6 The Format of the rsrcName (VISA Address) for Different
Interface Types
Interface
ASRL
GPIB
GPIB
Typical Syntax
ASRL[board][::INSTR]
GPIB[board]::primary address[::secondary address][::INSTR]
GPIB[board]::INTFC
GPIB-VXI GPIB-VXI[board]::VXI logical address[::INSTR]
GPIB-VXI GPIB-VXI[board]::MEMACC
GPIB-VXI GPIB-VXI[board][::VXI logical address]::BACKPLANE
TCPIP TCPIP[board]::host address[::LAN device name]::INSTR
TCPIP
USB
TCPIP[board]::host address::port::SOCKET
USB[board]::manufacturer ID::model code::serial
number[::USB interface number][::INSTR]
VXI
VXI
VXI
VXI[board]::VXI logical address[::INSTR]
VXI[board]::MEMACC
VXI[board][::VXI logical address]::BACKPLANE
The following table describes the parameters used above.
Table 7 Description of Parameters
Parameter board host address
LAN device name
Description
This optional parameter is used if you have more than one interface of the same type. The default value for board is 0.
The IP address (in dotted decimal notation) or the name of the host computer/gateway.
The assigned name for a LAN device. Device
Name depends on LAN Host Device (see documentaiton that came with your LAN Host device such as E5810A). The default is inst().
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Table 7 Description of Parameters (continued) manufacturer ID model code port primary address secondary address serial number
USB interface number
VXI logical address
Manufacturer’s ID for a USB Test & Measurement class device
Model code of a USB device.
The port number to use for a TCP/IP Socket connection.
The primary address of the GPIB device.
This optional parameter is the secondary address of the GPIB device. If no secondary address is specified, none is assumed.
Serial number of a USB device.
Interface number of a USB device.
Logical address of a VXI instrument within a mainframe.
Some examples of valid VISA addresses follow.
Table 8 Examples of Valid VISA Addresses
Address String
VXI0::1::INSTR
GPIB-VXI::9::INSTR
GPIB::1::0::INSTR
ASRL1::INSTR
VXI::MEMACC
GPIB-VXI1::MEMACC
Description
A VXI device at logical address 1 in VXI interface VXI0.
A VXI device at logical address 9 in a
GPIB-VXI controlled VXI system.
A GPIB device at primary address 1 and secondary address 0 in GPIB interface 0.
A serial device located on port 1.
Board-level register access to the VXI interface.
Board-level register access to GPIB-VXI interface number 1.
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Table 8 Examples of Valid VISA Addresses (continued)
GPIB2::INTFC
VXI::1::BACKPLANE
GPIB-VXI2:: BACKPLANE Mainframe resource for default chassis on
GPIB-VXI interface 2.
GPIB1::SERVANT Servant/device-side resource for GPIB interface 1.
VXI0::SERVANT
TCPIP0::1.2.3.4::999::SOCK
ET
Servant/device-side resource for VXI interface 0.
Raw TCPIP access to port 999 at the specified address.
TCPIP::devicename@compa ny.
com::INSTR
USB::0x1234::125::A22-5::I
NSTR
Interface or raw resource for GPIB interface 2.
Mainframe resource for chassis 1 on the default VXI system, which is interface 0.
TCPIP device using VXI-11 located at the specified address. This uses the default
LAN Device Name of inst0.
USB Test & Measurement class device with manufacturer ID 0x1234, model code
125, and serial number A22-5. This uses the device's first available USBTMC interface, which is usually numbered 0.
Example: Opening a Session
This sample shows one way to open a
VISA session with the GPIB device at primary address 23.
ViSession defaultRM, vi;
.
.
viOpenDefaultRM(&defaultRM); viOpen(defaultRM, "GPIB0::23::INSTR", VI_NULL,
VI_NULL,&vi);
.
.
viClose(vi); viClose(defaultRM);
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Closing a Session
You must use the viClose function to close each session. Closing the specific resource session frees all data structures that had been allocated for the session. If you close the default resource manager session, all sessions opened using that resource manager session will close.
Since system resources are also used when searching for resources
(viFindRsrc), the viClose function needs to be called to free up find
lists. See the following section, “Searching for Resources”, for more
information on closing find lists.
Searching for Resources
When you open the default resource manager, you are opening a parent session that knows about all the other resources in the system. Since the resource manager session knows about all resources, it has the ability to search for specific resources and open sessions to these resources. You can, for example, search an interface for devices and open a session with one of the devices found.
Use the viFindRsrc function to search an interface for device resources.
This function finds matches and returns the number of matches found and a handle to the resources found. If there are more matches, use the
viFindNext function with the handle returned from viFindRsrc to get the next match: viFindRsrc(sesn, expr, findList, retcnt,
instrDesc);
.
.
viFindNext(findList, instrDesc);
.
.
viClose (findList);
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N O T E
The parameters are defined as follows.
Table 9 Definitions of Parameters
Parameter sesn expr findList retcnt instrDesc
Description
The resource manager session.
The expression that identifies what to search (Table 10).
A handle that identifies this search. This handle will then be used as an input to the viFindNext function when finding the next match.
A pointer to the number of matches found.
A pointer to a string identifying the location of the match.
Note that you must allocate storage for this string.
The handle returned from viFindRsrc should be closed to free up all the system resources associated with the search. To close the find object, pass the findList to the viClose function.
Use the expr parameter of viFindRsrc to specify the interface to search.
You can search for devices on the specified interface. Use the following table to determine what to use for your expr parameter.
Because VISA interprets strings as regular expressions, the string
GPIB?*INSTR applies to both GPIB and GPIB-VXI devices.
38
Table 10 Determining What to Use for the expr Parameter
Interface
GPIB
VXI
GPIB-VXI
GPIB and GPIB-VXI
All VXI
ASRL
All
expr Parameter
GPIB[0-9]*::?*INSTR
VXI?*INSTR
GPIB-VXI?*INSTR
GPIB?*INSTR
?*VXI[0-9]*::?*INSTR
ASRL[0-9]*::?*INSTR
?*INSTR
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Example: Searching the VXI Interface for Resources
This code sample searches the VXI interface for resources. The number of matches found is returned in nmatches, and matches points to the string that contains the matches found. The first call returns the first match found, the second call returns the second match found, etc.
VI_FIND_BUFLEN is defined in the visa.h declarations file.
ViChar buffer [VI_FIND_BUFLEN];
ViRsrc matches=buffer;
ViUInt32 nmatches;
ViFindList list;
.
.
viFindRsrc(defaultRM, "VXI?*INSTR", &list,
&nmatches, matches);
..
.
viFindNext(list, matches);
.
.
viClose(list);
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Sending I/O Commands
This section provides guidelines for sending I/O commands, including:
• Types of I/O
• Using Formatted I/O
• Using Non-Formatted I/O
Types of I/O
Once you have established a communications session with a device, you can start communicating with that device using VISA's I/O routines.
VISA provides both formatted and non-formatted I/O routines.
• Formatted I/O converts mixed types of data under the control of a format string. The data is buffered, thus optimizing interface traffic.
• Non-formatted I/O sends or receives raw data to or from a device.
With non-formatted I/O, no format or conversion of the data is performed. Thus, if formatted data is required, it must be done by the user.
You can choose between VISA's formatted and non-formatted I/O routines. However, you should not mix formatted I/O and non-formatted
I/O in the same session. See the following sections for descriptions and code examples using formatted I/O and non-formatted I/O in VISA.
The VISA formatted I/O mechanism is similar to the C stdio mechanism. The VISA formatted I/O functions are viPrintf, viQueryf, and viScanf. Two non-buffered and non-formatted I/O functions,
viRead and viWrite, synchronously transfer data. Two additional functions, viReadAsync and viWriteAsync were intended for asynchronous data transfer but are imlemented synchronously in
Agilent VISA.
These are raw I/O functions and do not intermix with the formatted I/O
functions. See “Using Non-Formatted I/O” in this chapter for details.
Refer to the VISA Online Help for more information on how data is converted under the control of the format string.
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Using Formatted I/O
As noted, the VISA formatted I/O functions are viPrintf, viQueryf, and
viScanf.
• viPrintf formats data according to the format string (writeFmt) and sends the data to a device. viPrintf sends separate arg parameters, while the viVPrintf function sends a list of parameters in params: viPrintf(vi, writeFmt[, arg1][, arg2][, ...]); viVPrintf(vi, writeFmt, params);
• viScanf receives and converts data from a device according to the format string (readFmt). The viScanf function receives separate arg parameters, while the viVScanf function receives a list of parameters in params: viScanf(vi, readFmt[, arg1][, arg2][, ...]); viVScanf(vi, readFmt, params);
• viQueryf formats and sends data to a device and then immediately receives and converts the response data. Hence, viQueryf is a combination of both viPrintf and viScanf functions. Similarly,
viVQueryf is a combination of viVPrintf and viVScanf. viQueryf sends and receives separate arg parameters, while the viVQueryf function sends and receives a list of parameters in params: viQueryf(vi, writeFmt, readFmt[, arg1]
[, arg2][, ...]); viVQueryf(vi, writeFmt, readFmt, params);
Formatted I/O Conversion
Formatted I/O functions convert data under the control of the format specifier. The format specifier consists of a % (percent) symbol, optional modifier, and a format code. Both readFmt and writeFmt have the form:
%[modifier]formatCode
Example: Receiving Data From a Session
The following example uses viScanf to receive data from the session specified by the vi parameter and converts the data to a string.
char data[180]; viScanf(vi, "%t", data);
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Formatted I/O Buffers
The VISA software maintains both a read and write buffer for formatted
I/O operations. Occasionally, you may want to control the actions of these buffers. You can modify the size of the buffer using the viSetBuf function. See the VISA Online Help for more information on this function.
The write buffer is maintained by the viPrintf or viQueryf (writeFmt) functions. The buffer queues characters to send to the device so that they are sent in large blocks, thus increasing performance. The write buffer automatically flushes when it sends a newline character from the format string. It may occasionally be flushed at other non-deterministic times, such as when the buffer fills.
When the write buffer flushes, it sends its contents to the device. If you set the VI_ATTR_WR_BUF_OPER_MODE attribute to
VI_FLUSH_ON_ACCESS, the write buffer will also be flushed every
time a viPrintf or viQueryf operation completes. See “VISA
Attributes” in this chapter for information
on setting VISA attributes.
The read buffer is maintained by the viScanf and viQueryf (readFmt) functions. It queues the data received from a device until it is needed by the format string. Flushing the read buffer destroys the data in the buffer and guarantees that the next call to viScanf or viQueryf reads data directly from the device rather than data that was previously queued.
If you set the VI_ATTR_RD_BUF_OPER_MODE attribute to
VI_FLUSH_ON_ACCESS, the read buffer will be flushed every time a
viScanf or viQueryf operation completes. See “VISA Attributes” in this
chapter for information on setting VISA attributes.
You can manually flush the read and write buffers using the viFlush function. Flushing the read buffer also includes reading all pending response data from a device. If the device is still sending data, the flush process will continue to read data from the device until it receives an
END indicator from the device.
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Example: Sending and Receiving Formatted I/O
The following
C sample program demonstrates sending and receiving formatted I/O.
The program opens a session with a GPIB device and sends a comma operator to send a comma-separated list. This program shows specific
VISA functionality and does not include error trapping.
This example program is installed on your system in the
ProgrammingSamples subdirectory.
/*formatio.c
This example program makes a dmm measurement with a comma-separated list passed with formatted I/O and prints the results. You may need to change the device address. */
#include <visa.h>
#include <stdio.h> void main () {
ViSession defaultRM, vi;
double res;
double list [2] = {1,0.001};
/* Open session to GPIB device at address 22*/
viOpenDefaultRM(&efaultRM);
viOpen(defaultRM, "GPIB0::22::INSTR",
VI_NULL,VI_NULL, &vi);
/* Initialize device */
viPrintf(vi, "*RST\n");
/* Set-up device,send comma-separated list */
viPrintf(vi, "CALC:DBM:REF 50\n");
viPrintf(vi, "MEAS:VOLT:AC? %,2f\n", list);
/* Read results */
viScanf(vi, "%lf", &res);
/* Print results */
printf("Measurement Results: %lf\n", res);
/* Close session */
viClose(vi);
viClose(defaultRM);
}
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Using Non-Formatted I/O
There are two non-buffered, non-formatted I/O functions that synchronously transfer data called viRead and viWrite. Also, there are two non-formatted I/O functions that asynchronously transfer data called viReadAsync and viWriteAsync. These are raw I/O functions and do not intermix with the formatted I/O functions.
Non-Formatted I/O Functions
The non-formatted I/O functions follow. For more information, see the
viRead, viWrite, viReadAsync, viWriteAsync, and viTerminate functions in the VISA Online Help.
viRead .
The viRead function synchronously reads raw data from the session specified by the vi parameter and stores the results in the location where buf is pointing. Only one synchronous read operation can occur at any one time.
viRead(vi, buf, count, retCount); viWrite .
The viWrite function synchronously sends the data pointed to by buf to the device specified by vi. Only one synchronous write operation can occur at any one time.
viWrite(vi, buf, count, retCount);
Refer to the Agilent VISA help file for specific infomraiton on these and other VISA functions such as viReadAsync and viWriteAsync .
Example: Using Non-Formatted I/O Functions
This sample program illustrates using non-formatted I/O functions to communicate with a GPIB device. This example program is intended to show specific
VISA functionality and does not include error trapping. Error trapping, however, is good programming practice and is recommended in your
VISA applications. See “Trapping Errors” in this chapter for more
information.
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/*nonfmtio.c
This example program measures the AC voltage on a multimeter and prints the results. You may need to change the device address. */
#include <visa.h>
#include <stdio.h> void main () {
ViSession defaultRM, vi;
char strres [20];
unsigned long actual;
/* Open session to GPIB device at address 22 */
viOpenDefaultRM(&defaultRM);
viOpen(defaultRM, "GPIB0::22::INSTR",
VI_NULL,VI_NULL, &vi);
/* Initialize device */
viWrite(vi, (ViBuf)"*RST\n", 5, &actual);
/* Set up device and take measurement */
viWrite(vi, (ViBuf)"CALC:DBM:REF 50\n", 16,
&actual);
viWrite(vi, (ViBuf)"MEAS:VOLT:AC? 1, 0.001\n",
23, &actual);
/* Read results */
viRead(vi, (ViBuf)strres, 20, &actual);
/* NULL terminate the string */
strres[actual]=0;
/* Print results */
printf("Measurement Results: %s\n", strres);
/* Close session */
viClose(vi);
viClose(defaultRM);
}
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Using Events and Handlers
This section provides guidelines to using events and handlers, including:
• Events and Attributes
• Using the Callback Method
• Using the Queuing Method
Events and Attributes
Events are special occurrences that require attention from your application. Event types include Service Requests (SRQs), interrupts, and hardware triggers. Events will not be delivered unless the appropriate events are enabled.
N O T E
VISA cannot call back to a Visual Basic function. Thus, you can only use the queuing mechanism in viEnableEvent. There is no way to install a VISA event handler in Visual Basic.
N O T E
Event Notification
There are two ways you can receive notification that an event has occurred:
• Install an event handler with viInstallHandler, and enable one or several events with viEnableEvent. If the event was enabled with a handler, the specified event handler will be called when the specified event occurs. This is called a callback.
VISA cannot call back to a Visual Basic function. This means that you can only use the VI_QUEUE mechanism in viEnableEvent. There is no way to install a VISA event handler in Visual Basic.
• Enable one or several events with viEnableEvent and call the
viWaitOnEvent function. The viWaitOnEvent function will suspend the program execution until the specified event occurs or the specified timeout period is reached. This is called queuing.
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The queuing and callback mechanisms are suitable for different programming styles. The queuing mechanism is generally useful for non-critical events that do not need immediate servicing. The callback mechanism is useful when immediate responses are needed. These mechanisms work independently of each other, so both can be enabled at the same time. By default, a session is not enabled to receive any events by either mechanism.
The viEnableEvent operation can be used to enable a session to respond to a specified event type using either the queuing mechanism, the callback mechanism, or both. Similarly, the viDisableEvent operation can be used to disable one or both mechanisms. Because the two methods work independently of each other, one can be enabled or disabled regardless of the current state of the other.
Events that can be Enabled
The following table shows the events that are implemented for Agilent
VISA for each resource class, where AP = Access Privilege, RO - Read
Only, and RW = Read/Write. Note that some resource classes/events, such as the SERVANT class, are not implemented by Agilent VISA and are not listed in the following tables.
Once the application has received an event, information about that event can be obtained by using the viGetAttribute function on that particular event context. Use the VISA viReadSTB function to read the status byte of the service request.
.
Table 11 Instrument Control (INSTR) Resource Events
VI_EVENT_SERVICE_REQUEST
Notification that a service request was received from the device.
Event Attribute Description
VI_ATTR_EVENT_TYPE Unique logical identifier of the event.
A
P
R
O
Data Type Range
ViEventTy pe
VI_EVENT_SERVICE_RE
Q
VI_EVENT_VXI_SIGP
Notification that a VXIbus signal or VXIbus interrupt was received from the device.
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Table 11 Instrument Control (INSTR) Resource Events (continued)
Event Attribute
VI_ATTR_EVENT_TYPE
VI_ATTR_SIGP_STATUS
_ID
Description
Unique logical identifier of the event.
The 16-bit Status/ID value retrieved during the IACK cycle or from the Signal register.
A
P
R
O
R
O
Data Type Range
ViEventTy pe
ViUInt16
VI_EVENT_VXI_STOP
0 to FFFF h
VI_EVENT_TRIG
Notification that a trigger interrupt was received from the device. For VISA, the only triggers that can be sensed are VXI hardware triggers on the assertion edge (SYNC and ON trigger protocols only).
Event Attribute Description
VI_ATTR_EVENT_TYPE
VI_ATTR_RECV_TRIG_I
D
Unique logical identifier of the event.
The identifier of the triggering mechanism on which the specified trigger event was received.
A
P
R
O
R
O
Data Type Range
ViEventTy pe
ViInt16
VI_EVENT_TRIG
VI_TRIG_TTL0 to
VI_TRIG_TTL7;
VI_TRIG_ECL0 to
VI_TRIG_ECL1*
* Agilent VISA can also return VI_TRIG_PANEL_IN (exception to the VISA Specification)
VI_EVENT_IO_COMPLETION
Notification that an asynchronous operation has completed.
Event Attribute Description
VI_ATTR_EVENT_TYPE
VI_ATTR_STATUS
Unique logical identifier of the event.
Return code of the asynchronous
I/O operation that has completed.
A
P
R
O
R
O
Data Type Range
ViEventTy pe
ViStatus
VI_EVENT_IO_COMPLE
TION
N/A
VI_ATTR_JOB_ID ViJobId N/A
VI_ATTR_BUFFER
Job ID of the asynchronous operation that has completed.
Address of a buffer that was used in an asynchronous operation.
R
O
R
O
ViBuf N/A
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Table 11 Instrument Control (INSTR) Resource Events (continued)
VI_ATTR_RET_COUNT
VI_ATTR_OPER_NAME
Actual number of elements that were asynchronously transferred.
Name of the operation generating the event.
R
O
ViUInt32
ViString
0 to FFFFFFFF h
N/A
VI_EVENT_USB_INTR
Notification that a vendor-specific USB interrupt was received from the device.
Event Attribute Description A
P
Data Type Range
VI_ATTR_EVENT_TYPE Unique logical identifier of the event.
R
O
ViEventTy pe
VI_EVENT_USB_INTR
VI_ATTR_USB_RECV_IN
TR_
SIZE
VI_ATTR_USB_RECV_IN
TR
_DATA
VI_ATTR_STATUS
Specifies the size of the data that was received from the USB interrupt-IN pipe. This value will never be larger than the sessions value of VI_ATTR_USB_MAX_
INTR_SIZE.
Specifies the actual data that was received from the USB interrupt-IN pipe. Querying this attribute copies the contents of the data to the users buffer. The users buffer must be sufficiently large enough to hold all of the data.
Specifies the status of the read operation from the USB interrupt-IN pipe. If the device sent more data than the user specified in
VI_ATTR_USB_MAX_INTR_S
IZE, then this attribute value will contain an error code.
R
O
ViUInt16
R
O
R
O
ViBuf
ViStatus
0 to FFFFh
N/A
N/A
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Table 12 Memory Access (MEMACC) Resource Event
VI_EVENT_IO_COMPLETION
Notification that an asynchronous operation has completed
Event Attribute Description
VI_ATTR_EVENT_TYPE
VI_ATTR_STATUS
Unique logical identifier of the event.
Return code of the asynchronous
I/O operation that has completed.
A
P
R
O
R
O
Data Type Range
ViEventTy pe
ViStatus
VI_EVENT_IO_COMPLE
TION
N/A
VI_ATTR_JOB_ID ViJobId N/A
VI_ATTR_BUFFER
Job ID of the asynchronous operation that has completed.
Address of a buffer that was used in an asynchronous operation.
R
O
R
O
ViBuf N/A
VI_ATTR_RET_COUNT
VI_ATTR_OPER_NAME
Actual number of elements that were asynchronously transferred.
Name of the operation generating the event.
R
O
R
O
ViUInt32
ViString
0 to FFFFFFFF h
N/A
Table 13 GPIB Bus Interface (INTFC) Resource Events
VI_EVENT_GPIB_CIC
Notification that the GPIB controller has gained or lost CIC (controller in charge) status
Event Attribute Description A
P
Data Type Range
VI_ATTR_EVENT_TYPE
VI_ATTR_GPIB_RECV_CIC_
STATE
Unique logical identifier of the event.
Controller has become controller-in-charge.
R
O
R
O
ViEventTy pe
VI_EVENT_GPIB_CIC
ViBoolean VI_TRUE
VI_FALSE
VI_EVENT_GPIB_TALK
Notification that the GPIB controller has been addressed to talk
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Table 13 GPIB Bus Interface (INTFC) Resource Events (continued)
Event Attribute
VI_ATTR_EVENT_TYPE
Description
Unique logical identifier of the event.
A
P
R
O
Data Type Range
ViEventTy pe
VI_EVENT_GPIB_TAL
K
VI_EVENT_GPIB_LISTEN
Notification that the GPIB controller has been addressed to listen.
Event Attribute Description
VI_ATTR_EVENT_TYPE Unique logical identifier of the event.
A
P
R
O
Data Type Range
ViEventTy pe
VI_EVENT_GPIB_LIST
EN
VI_EVENT_CLEAR
Notification that the GPIB controller has been sent a device clear message.
Event Attribute Description
VI_ATTR_EVENT_TYPE Unique logical identifier of the event.
VI_EVENT_TRIGGER
Notification that a trigger interrupt was received from the interface.
Event Attribute Description
A
P
R
O
Data Type Range
ViEventTy pe
VI_EVENT_CLEAR
Data Type Range
VI_ATTR_EVENT_TYPE
VI_ATTR_RECV_TRIG_ID
Unique logical identifier of the event.
The identifier of the triggering mechanism on which the specified trigger event was received.
A
P
R
O
R
O
ViEventTy pe
ViInt16
VI_EVENT_TRIG
VI_TRIG_SW
VI_EVENT_IO_COMPLETION
Notification that an asynchronous operation has completed.
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Table 13 GPIB Bus Interface (INTFC) Resource Events (continued)
Event Attribute
VI_ATTR_EVENT_TYPE
VI_ATTR_STATUS
VI_ATTR_JOB_ID
VI_ATTR_BUFFER
VI_ATTR_RET_COUNT
VI_ATTR_OPER_NAME
Description
Unique logical identifier of the event.
Return code of the asynchronous I/O operation that has completed.
A
P
R
O
R
O
Data Type Range
ViEventTy pe
ViStatus
VI_EVENT_IO_
COMPLETION
N/A
ViJobId N/A Job ID of the asynchronous operation that has completed.
Address of buffer used in an asynchronous operation.
Actual number of elements that were asynchronously transferred.
The name of the operation generating the event.
R
O
R
O
R
O
R
O
ViBuf
ViUInt32
ViString
N/A
0 to FFFFFFFF
N/A h
Table 14 VXI Mainframe Backplane (BACKPLANE) Resource Events
VI_EVENT_TRIG
Notification that a trigger interrupt was received from the backplane. For VISA, the only triggers that can be sensed are VXI hardware triggers on the assertion edge (SYNC and ON trigger protocols only).
Event Attribute Description A
P
Data Type Range
VI_ATTR_EVENT_TYPE VI_EVENT_TRIG
VI_ATTR_RECV_TRIG_I
D
Unique logical identifier of the event.
The identifier of the triggering mechanism on which the specified trigger event was received.
R
O
R
O
ViEventTy pe
ViInt16 VI_TRIG_TTL0 to
VI_TRIG_TTL7;
VI_TRIG_ECL0 to
VI_TRIG_ECL1
VI_EVENT_VXI_VME_SYSFAIL
Notification that the VXI/VME SYSFAIL* line has been asserted.
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Table 14 VXI Mainframe Backplane (BACKPLANE) Resource Events (continued)
VI_ATTR_EVENT_TYPE Unique logical identifier of the event.
R
O
ViEventTy pe
VI_EVENT_VXI_VME_
SYSFAIL
VI_EVENT_VXI_VME_SYSRESET
Notification that the VXI/VME SYSRESET* line has been reset
Event Attributes Description
VI_ATTR_EVENT_TYPE Unique logical identifier of the event.
A
P
R
O
Data Type Range
ViEventTy pe
VI_EVENT_VXI_VME_
SYSRESET
Table 15 TCPIP Socket (SOCKET) Resource Event
VI_EVENT_IO_COMPLETION
Notification that an asynchronous operation has completed
Event Attribute Description
VI_ATTR_EVENT_TYPE
VI_ATTR_STATUS
Unique logical identifier of the event.
Return code of the asynchronous
I/O operation that has completed.
A
P
R
O
R
O
Data Type Range
ViEventTy pe
ViStatus
VI_EVENT_IO_COMPLE
TION
N/A
VI_ATTR_JOB_ID ViJobId N/A
VI_ATTR_BUFFER
Job ID of the asynchronous operation that has completed.
Address of a buffer that was used in an asynchronous operation.
R
O
R
O
ViBuf N/A
VI_ATTR_RET_COUNT
VI_ATTR_OPER_NAME
Actual number of elements that were asynchronously transferred.
Name of the operation generating the event.
R
O
R
O
ViUInt32
ViString
0 to FFFFFFFF h
N/A
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Example: Reading Event Attributes
Once you have decided which attribute to check, you can read the attribute using the
viGetAttribute function. The following example shows one way you could check which trigger line fired when the VI_EVENT_TRIG event was delivered.
Note that the context parameter is either the event context passed to your event handler, or the outcontext specified when doing a wait on event.
See “VISA Attributes” in this chapter for more information on reading
attribute states.
ViInt16 state;
.
.
viGetAttribute(context, VI_ATTR_RECV_TRIG_ID,
&state)
Using the Callback Method
The callback method of event notification is used when an immediate response to an event is required. To use the callback method for receiving notification that an event has occurred, you must do the following.
• Install an event handler with the viInstallHandler function
• Enable one or several events with the viEnableEvent function
When the enabled event occurs, the installed event handler is called.
Example: Using the Callback Method
This example shows one way you can use the callback method.
ViStatus _VI_FUNCH my_handler (ViSession vi,
ViEventType eventType, ViEvent context, ViAddr
usrHandle) {
/* your event handling code here */ return VI_SUCCESS;
} main(){
ViSession vi;
ViAddr addr=0;
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.
.
viInstallHandler(vi, VI_EVENT_SERVICE_REQ,
my_handler, addr); viEnableEvent(vi, VI_EVENT_SERVICE_REQ,
VI_HNDLR, VI_NULL);
.
/* your code here */
.
viDisableEvent(vi, VI_EVENT_SERVICE_REQ,
VI_HNDLR); viUninstallHandler(vi, VI_EVENT_SERVICE_REQ,
my_handler, addr);
.
}
Installing Handlers
VISA allows applications to install multiple handlers for an event type on the same session. Multiple handlers can be installed through multiple invocations of the viInstallHandler operation, where each invocation adds to the previous list of handlers.
If more than one handler is installed for an event type, each of the handlers is invoked on every occurrence of the specified event(s). VISA specifies that the handlers are invoked in Last In First Out (LIFO) order.
Use the following function when installing an event handler: viInstallHandler(vi, eventType, handler,
userHandle);
These parameters are defined as follows.
Table 16 Parameters Used to Install a Handler
Parameter vi eventType handler userHandle
Description
The session on which the handler will be installed.
The event type that will activate the handler.
The name of the handler to be called.
A user value that uniquely identifies the handler for the specified event type.
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The userHandle parameter allows you to assign a value to be used with the handler on the specified session. Thus, you can install the same handler for the same event type on several sessions with different
userHandle values. The same handler is called for the specified event type.
However, the value passed to userHandle is different. Therefore the handlers are uniquely identified by the combination of the handler and the userHandle. This may be useful when you need a different handling method depending on the userHandle.
Example: Installing an Event Handler
This example shows how to install an event handler to call my_handler when a Service Request occurs. Note that VI_EVENT_SERVICE_REQ must also be an enabled event with the viEnableEvent function for the service request event to be delivered. viInstallHandler(vi, VI_EVENT_SERVICE_REQ,
my_handler, addr);
Use the viUninstallHandler function to uninstall a specific handler, or you can use wildcards (VI_ANY_HNDLR in the handler parameter) to uninstall groups of handlers. See viUninstallHandler in the VISA
Online Help for more details on this function.
Writing the Handler
The handler installed needs to be written by the programmer. The event handler typically reads an associated attribute and performs some sort of action. See the event handler in the example program later in this section.
Enabling Events
Before an event can be delivered, it must be enabled using the
viEnableEvent function. This function causes the application to be notified when the enabled event has occurred, where the parameters are: viEnableEvent(vi, eventType, mechanism,
context);
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Using VI_QUEUE in the mechanism parameter specifies a queuing method for the events to be handled. If you use both VI_QUEUE and one of the mechanisms listed above, notification of events will be sent to both locations. See the next subsection for information on the queuing method.
Table 17 Description of Parameters Used to Install a Handler
Parameter vi eventType mechanism context
Description
The session on which the handler will be installed.
The type of event to enable.
The mechanism by which the event will be enabled. It can be enabled in several different ways. You can use
VI_HNDLR in this parameter to specify that the installed handler will be called when the event occurs. Use
VI_SUSPEND_HNDLR in this parameter, which puts the events in a queue and waits to call the installed handlers until viEnableEvent is called with VI_HNDLR specified in the mechanism parameter. When viEnableEvent is called with VI_HNDLR specified, the handler for each queued event will be called.
Not used in VISA 1.0. Use VI_NULL.
Example: Enabling a Hardware Trigger Event
This example illustrates enabling a hardware trigger event.
viInstallHandler(vi, VI_EVENT_TRIG,
my_handler,&addr); viEnableEvent(vi, VI_EVENT_TRIG, VI_HNDLR,
VI_NULL);
The VI_HNDLR mechanism specifies that the handler installed for
VI_EVENT_TRIG will be called when a hardware trigger occurs.
If you specify VI_ALL_ENABLE_EVENTS in the eventType parameter, all events that have previously been enabled on the specified session will be enabled for the mechanism specified in this function call.
Use the viDisableEvent function to stop servicing the event specified.
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Example: Trigger Callback
This sample program installs an event handler and enables the trigger event. When the event occurs, the installed event handler is called. This program is intended to show specific VISA functionality and does not include error trapping. Error trapping, however, is good programming practice and is recommended
in your VISA applications. See “Trapping Errors” in this chapter for
more information.
This sample program is installed on your system in the
ProgrammingSamples subdirectory. See the IO Libraries Suite
Online Help for locations of example programs.
/* evnthdlr.c
This example program illustrates installing an event handler to be called when a trigger interrupt occurs. Note that you may need to change the address. */
#include <visa.h>
#include <stdio.h>
/* trigger event handler */
ViStatus _VI_FUNCH myHdlr(ViSession vi,
ViEventType eventType, ViEvent ctx, ViAddr
userHdlr){
ViInt16 trigId;
/* make sure it is a trigger event */ if(eventType!=VI_EVENT_TRIG){
/* Stray event, so ignore */
return VI_SUCCESS;
}
/* print the event information */ printf("Trigger Event Occurred!\n"); printf("...Original Device Session = %ld\n",
vi);
/* get the trigger that fired */ viGetAttribute(ctx, VI_ATTR_RECV_TRIG_ID,
&trigId); printf("Trigger that fired: "); switch(trigId){
case VI_TRIG_TTL0:
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printf("TTL0");
break;
default:
printf("<other 0x%x>", trigId);
break;
} printf("\n"); return VI_SUCCESS;
} void main(){
ViSession defaultRM,vi;
/* open session to VXI device */ viOpenDefaultRM(&defaultRM); viOpen(defaultRM, "VXI0::24::INSTR", VI_NULL,
VI_NULL, &vi);
/* select trigger line TTL0 */ viSetAttribute(vi, VI_ATTR_TRIG_ID,
VI_TRIG_TTL0);
/* install the handler and enable it */ viInstallHandler(vi, VI_EVENT_TRIG, myHdlr,
(ViAddr)10); viEnableEvent(vi, VI_EVENT_TRIG, VI_HNDLR,
VI_NULL);
/* fire trigger line, twice */ viAssertTrigger(vi, VI_TRIG_PROT_SYNC); viAssertTrigger(vi, VI_TRIG_PROT_SYNC);
/* unenable and uninstall the handler */ viDisableEvent(vi, VI_EVENT_TRIG, VI_HNDLR); viUninstallHandler(vi, VI_EVENT_TRIG, myHdlr,
(ViAddr)10);
/* close the sessions */ viClose(vi); viClose(defaultRM);
}
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Example: SRQ Callback
This program installs an event handler and enables an SRQ event. When the event occurs, the installed event handler is called. This sample program is intended to show specific
VISA functionality and does not include error trapping. Error trapping, however, is good programming practice and is recommended in your
VISA applications. See “Trapping Errors” in this chapter for more
information.
This program is installed on your system in the
ProgrammingSamples subdirectory. See the IO Libraries Suite
Online Help for locations of example programs.
/* srqhdlr.c
This example program illustrates installing an event handler to be called when an SRQ interrupt occurs. Note that you may need to change the address. */
#include <visa.h>
#include <stdio.h>
#if defined (_WIN32)
#include <windows.h> /* for Sleep() */
#define YIELD Sleep( 10 )
#elif defined (_WINDOWS)
#include <io.h> /* for _wyield */
#define YIELD _wyield()
#else
#include <unistd.h>
#define YIELD sleep (1)
#endif int srqOccurred;
/* trigger event handler */
ViStatus _VI_FUNCH mySrqHdlr(ViSession vi,
ViEventType eventType, ViEvent ctx, ViAddr userHdlr){
ViUInt16 statusByte;
/* make sure it is an SRQ event */
if(eventType!=VI_EVENT_SERVICE_REQ){
/* Stray event, so ignore */
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printf( "\nStray event of type 0x%lx\n",
eventType );
return VI_SUCCESS;
}
/* print the event information */
printf("\nSRQ Event Occurred!\n");
printf("...Original Device Session = %ld\n",
vi);
/* get the status byte */
viReadSTB(vi, &statusByte);
printf("...Status byte is 0x%x\n",
statusByte);
srqOccurred = 1;
return VI_SUCCESS;
} void main(){
ViSession defaultRM,vi;
long count;
/* open session to message based VXI device */
viOpenDefaultRM(&defaultRM);
viOpen(defaultRM, "GPIB-VXI0::24::INSTR",
VI_NULL, VI_NULL, &vi);
/* Enable command error events */
viPrintf( vi, "*ESE 32\n" );
/* Enable event register interrupts */
viPrintf( vi, "*SRE 32\n" );
/* install the handler and enable it */
viInstallHandler(vi, VI_EVENT_SERVICE_REQ,
mySrqHdlr,
(ViAddr)10);
viEnableEvent(vi, VI_EVENT_SERVICE_REQ,
VI_HNDLR, VI_NULL);
srqOccurred = 0;
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/* Send a bogus command to the message-based
device to cause an SRQ. Note: 'IDN' causes the
error -- 'IDN?' is the correct syntax */
viPrintf( vi, "IDN\n" );
/* Wait a while for the SRQ to be generated and
for the handler to be called. Print something
while we wait */
printf("Waiting for an SRQ to be generated.");
for (count = 0 ; (count < 10) &&
(srqOccurred == 0);count++) {
long count2 = 0;
printf( "." );
while ( (count2++ < 100) && (srqOccurred ==0)
){YIELD;
}
}
printf( "\n" );
/* disable and uninstall the handler */
viDisableEvent(vi, VI_EVENT_SERVICE_REQ,
VI_HNDLR);
viUninstallHandler(vi, VI_EVENT_SERVICE_REQ,
mySrqHdlr, (ViAddr)10);
/* Clean up - do not leave device in error
state */
viPrintf( vi, "*CLS\n" );
/* close the sessions */
viClose(vi);
viClose(defaultRM);
printf( "End of program\n" );}
Using the Queuing Method
The queuing method is generally used when an immediate response from your application is not needed. To use the queuing method for receiving notification that an event has occurred, you must do the following:
• Enable one or several events with the viEnableEvent function.
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• When ready to query, use the viWaitOnEvent function to check for queued events.
If the specified event has occurred, the event information is retrieved and the program returns immediately. If the specified event has not occurred, the program suspends execution until a specified event occurs or until the specified timeout period is reached.
Example: Using the Queuing Method
This example program shows one way you can use the queuing method.
main();
ViSession vi;
ViEventType eventType;
ViEvent event;
.
.
viEnableEvent(vi, VI_EVENT_SERVICE_REQ,
VI_QUEUE, VI_NULL);
.
.
viWaitOnEvent(vi, VI_EVENT_SERVICE_REQ,
VI_TMO_INFINITE, &eventType, &event);
.
.
viClose(event); viDisableEvent(vi, VI_EVENT_SERVICE_REQ,
VI_QUEUE);
}
Enabling Events
Before an event can be delivered, it must be enabled using the
viEnableEvent function: viEnableEvent(vi, eventType, mechanism,
context);
These parameters are defined as follows:
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Table 18 Descriptions of Parameters Used to Enable Events
Parameter vi eventType mechanism context
Description
The session the handler will be installed on.
The type of event to enable.
The mechanism by which the event will be enabled. Specify
VI_QUEUE to use the queuing method.
Not used in VISA 1.0. Use VI_NULL.
When you use VI_QUEUE in the mechanism parameter, you are specifying that the events will be put into a queue. Then, when a
viWaitOnEvent function is invoked, the program execution will suspend until the enabled event occurs or the timeout period specified is reached. If the event has already occurred, the viWaitOnEvent function will return immediately.
Example: Enabling a Hardware Trigger Event
This example illustrates enabling a hardware trigger event.
viEnableEvent(vi, VI_EVENT_TRIG, VI_QUEUE,
VI_NULL);
The VI_QUEUE mechanism specifies that when an event occurs, it will go into a queue. If you specify VI_ALL_ENABLE_EVENTS in the
eventType parameter, all events that have previously been enabled on the specified session will be enabled for the mechanism specified in this function call. Use the viDisableEvent function to stop servicing the event specified.
Wait on the Event
When using the viWaitOnEvent function, specify the session, the event type to wait for, and the timeout period to wait: viWaitOnEvent(vi, inEventType, timeout,
outEventType, outContext);
The event must have previously been enabled with VI_QUEUE specified as the mechanism parameter.
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Example: Wait on Event for SRQ
This example shows how to install a wait on event for service requests.
viEnableEvent(vi, VI_EVENT_SERVICE_REQ,
VI_QUEUE, VI_NULL); viWaitOnEvent(vi, VI_EVENT_SERVICE_REQ,
VI_TMO_INFINITE, &eventType, &event);
.
.
viDisableEvent(vi, VI_EVENT_SERVICE_REQ,
VI_QUEUE);
Every time a wait on event is invoked, an event context object is created. Specifying VI_TMO_INFINITE in the timeout parameter indicates that the program execution will suspend indefinitely until the event occurs. To clear the event queue for a specified event type, use the
viDiscardEvents function.
Example: Trigger Event Queuing
This program enables the trigger event in a queuing mode. When the viWaitOnEvent function is called, the program will suspend operation until the trigger line is fired or the timeout period is reached. Since the trigger lines were already fired and the events were put into a queue, the function will return and print the trigger line that fired.
This program is intended to show specific VISA functionality and does not include error trapping. Error trapping, however, is good programming practice and is recommended in your VISA applications.
See “Trapping Errors” in this chapter for more information.
This example program is installed on your system in the
ProgrammingSamples subdirectory. See the IO Libraries Suite
Online Help for locations of example programs.
/* evntqueu.c
This sample program illustrates enabling an event queue using viWaitOnEvent. Note that you must change the device address. */
#include <visa.h>
#include <stdio.h>
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66 void main(){
ViSession defaultRM,vi;
ViEventType eventType;
ViEvent eventVi;
ViStatus err;
ViInt16 trigId;
/* open session to VXI device */
viOpenDefaultRM(&defaultRM);
viOpen(defaultRM, "VXI0::24::INSTR", VI_NULL,
VI_NULL, &vi);
/* select trigger line TTL0 */
viSetAttribute(vi, VI_ATTR_TRIG_ID,
VI_TRIG_TTL0);
/* enable the event */
viEnableEvent(vi, VI_EVENT_TRIG, VI_QUEUE,
VI_NULL);
/* fire trigger line, twice */
viAssertTrigger(vi, VI_TRIG_PROT_SYNC);
viAssertTrigger(vi, VI_TRIG_PROT_SYNC);
/* Wait for the event to occur */
err=viWaitOnEvent(vi, VI_EVENT_TRIG, 10000,
&eventType, &eventVi);
if(err==VI_ERROR_TMO){
printf("Timeout Occurred! Event not
received.\n");
return;
}
/* print the event information */
printf("Trigger Event Occurred!\n");
printf("...Original Device Session = %ld\n",
vi);
/* get trigger that fired */
viGetAttribute(eventVi, VI_ATTR_RECV_TRIG_ID,
&trigId);
printf("Trigger that fired: ");
switch(trigId){
case VI_TRIG_TTL0:
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printf("TTL0");
break;
default:
printf("<other 0x%x>",trigId);
break;
}
printf("\n");
/* close the context before continuing */
viClose(eventVi);
/* get second event */
err=viWaitOnEvent(vi, VI_EVENT_TRIG, 10000,
&eventType, &eventVi);
if(err==VI_ERROR_TMO){
printf("Timeout Occurred! Event not
received.\n");
return;
}
printf("Got second event\n");
/* close the context before continuing */
viClose(eventVi);
/* disable event */
viDisableEvent(vi, VI_EVENT_TRIG, VI_QUEUE);
/* close the sessions */
viClose(vi);
viClose(defaultRM);
}
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Trapping Errors
This section provides guidelines for trapping errors, including:
• Trapping Errors
• Exception Events
Trapping Errors
The example programs in this guide show specific VISA functionality and do not include error trapping. Error trapping, however, is good programming practice and is recommended in all your VISA application programs. To trap VISA errors you must check for VI_SUCCESS after each VISA function call.
If you want to ignore WARNINGS, you can test to see if err is less than
(<) VI_SUCCESS. Since WARNINGS are greater than VI_SUCCESS and ERRORS are less than VI_SUCCESS, err_handler would only be called when the function returns an ERROR. For example: if(err < VI_SUCCESS) err_handler (vi, err);
Example: Checking for
VI_SUCCESS This example illustrates checking for VI_SUCCESS. If VI_SUCCESS is not returned, an error handler (written by the programmer) is called. This must be done with each VISA function call.
ViStatus err;
.
.
err=viPrintf(vi, "*RST\n"); if (err < VI_SUCCESS) err_handler(vi, err);
.
.
Example: Printing Error Code
The following error handler prints a user-readable string describing the error code passed to the function: void err_handler(ViSession vi, ViStatus err){
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char err_msg[1024]={0};
viStatusDesc (vi, err, err_msg);
printf ("ERROR = %s\n", err_msg);
return;
}
Example: Checking Instrument Errors
When programming instruments, it is good practice to check the instrument to ensure there are no instrument errors after each instrument function. This example uses a SCPI command to check a specific instrument for errors.
void system_err(){
ViStatus err;
char buf[1024]={0};
int err_no;
err=viPrintf(vi, "SYSTEM:ERR?\n");
if (err < VI_SUCCESS) err_handler (vi, err);
err=viScanf (vi, "%d%t", &err_no, &buf);
if (err < VI_SUCCESS) err_handler (vi, err);
while (err_no >0){
printf ("Error Found: %d,%s\n", err_no,
buf);
err=viScanf (vi, "%d%t", &err_no, &buf);
}
err=viFlush(vi, VI_READ_BUF);
if (err < VI_SUCCESS) err_handler (vi, err);
err=viFlush(vi, VI_WRITE_BUF);
if (err < VI_SUCCESS) err_handler (vi, err);
}
Exception Events
An alternative to trapping VISA errors by checking the return status after each VISA call is to use the VISA exception event. On sessions where an exception event handler is installed and
VI_EVENT_EXCEPTION is enabled, the exception event handler is called whenever an error occurs while executing an operation.
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Exception Handling Model
The exception-handling model follows the event-handling model for callbacks, and it uses the same operations as those used for general event handling. For example, an application calls viInstallHandler and
viEnableEvent to enable exception events. The exception event is like any other event in VISA, except that the queueing and suspended handler mechanisms are not allowed.
When an error occurs for a session operation, the exception handler is executed synchronously. That is, the operation that caused the exception blocks until the exception handler completes its execution. The exception handler is executed in the context of the same thread that caused the exception event.
When invoked, the exception handler can check the error condition and instruct the exception operation to take a specific action. It can instruct the exception operation to continue normally (by returning
VI_SUCCESS) or to not invoke any additional handlers in the case of handler nesting (by returning VI_SUCCESS_NCHAIN).
As noted, an exception operation blocks until the exception handler execution is completed. However, an exception handler sometimes may prefer to terminate the program prematurely without returning the control to the operation generating the exception. VISA does not preclude an application from using a platform-specific or language-specific exception handling mechanism from within the VISA exception handler.
For example, the C++ try/catch block can be used in an application in conjunction with the C++ throw mechanism from within the VISA exception handler. When using the C++ try/catch/throw or other exception-handling mechanisms, the control will not return to the VISA system. This has several important repercussions:
1 If multiple handlers were installed on the exception event, the handlers that were not invoked prior to the current handler will not be invoked for the current exception.
2 The exception context will not be deleted by the VISA system when a C++ exception is used. In this case, the application should delete the exception context as soon as the application has no more use for the context, before terminating the session. An application should use the viClose operation to delete the exception context.
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3 Code in any operation (after calling an exception handler) may not be called if the handler does not return. For example, local allocations must be freed before invoking the exception handler, rather than after it.
One situation in which an exception event will not be generated is in the case of asynchronous operations. If the error is detected after the operation is posted (i.e., once the asynchronous portion has begun), the status is returned normally via the I/O completion event.
However, if an error occurs before the asynchronous portion begins (i.e., the error is returned from the asynchronous operation itself), then the exception event will still be raised. This deviation is due to the fact that asynchronous operations already raise an event when they complete, and this I/O completion event may occur in the context of a separate thread previously unknown to the application. In summary, a single application event handler can easily handle error conditions arising from both exception events and failed asynchronous operations.
Using the VI_EVENT_EXCEPTION Event
You can use the VI_EVENT_EXCEPTION event as notification that an error condition has occurred during an operation invocation. The following table describes the VI_EVENT_EXCEPTION event attributes.
Table 19 VI_EVENT_EXCEPTION Event Attributes.
Attribute Name
VI_ATTR_EVENT_TYPE
Access Privilege
RO Global
Data Type
ViEventType
VI_ATTR_STATUS
VI_ATTR_OPER_NAME
RO Global
RO Global
ViStatus
ViString
Range
VI_EVENT_EXCEPTIO
N
Default
N/A
N/A
N/A
N/A
N/A
Example: Exception Events
/* This is an example of how to use exception events to trap VISA errors. An exception event
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Programming with VISA handler must be installed and exception events enabled on all sessions where the exception handler is used.*/
#include <stdio.h>
#include <visa.h>
ViStatus __stdcall myExceptionHandler (
ViSession vi,
ViEventType eventType,
ViEvent context,
ViAddr usrHandle
) {
ViStatus exceptionErrNbr;
char nameBuffer[256];
ViString functionName = nameBuffer;
char errStrBuffer[256];
/* Get the error value from the exception
context */
viGetAttribute( context, VI_ATTR_STATUS,
&exceptionErrNbr );
/* Get the function name from the exception
context */
viGetAttribute( context, VI_ATTR_OPER_NAME,
functionName ); errStrBuffer[0] = 0;
viStatusDesc( vi, exceptionErrNbr,
errStrBuffer );
printf("ERROR: Exception Handler reports\n"
"(%s)\n","VISA function '%s' failed with
error 0x%lx\n", "functionName,
exceptionErrNbr, errStrBuffer );
return VI_SUCCESS;
} void main(){
ViStatus status;
ViSession drm;
ViSession vi;
ViAddr myUserHandle = 0;
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status = viOpenDefaultRM( &drm );
if ( status < VI_SUCCESS ) {
printf( "ERROR: viOpenDefaultRM failed with
error = 0x%lx\n", status );
return;
}
/* Install the exception handler and enable
events for it */
status = viInstallHandler(drm,
VI_EVENT_EXCEPTION, myExceptionHandler,
myUserHandle);
if ( status < VI_SUCCESS )
{
printf( "ERROR: viInstallHandler failed
with error 0x%lx\n", status );
} status = viEnableEvent(drm, VI_EVENT_EXCEPTION,
VI_HNDLR, VI_NULL); if ( status < VI_SUCCESS ) {
printf( "ERROR: viEnableEvent failed with
error 0x%lx\n", status );
}
/* Generate an error to demonstrate that the
handler will be called */
status = viOpen( drm, "badVisaName", NULL,
NULL, &vi );
if ( status < VI_SUCCESS ) {
printf("ERROR: viOpen failed with error
0x%lx\n"
"Exception Handler should have been
called\n"
"before this message was printed.\n",status
);
}
}
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Using Locks
In VISA, applications can open multiple sessions to a VISA resource simultaneously. Applications can, therefore, access a VISA resource concurrently through different sessions. However, in certain cases, applications accessing a VISA resource may want to restrict other applications from accessing that resource.
Lock Functions
For example, when an application needs to perform successive write operations on a resource, the application may require that, during the sequence of writes, no other operation can be invoked through any other session to that resource. For such circumstances, VISA defines a locking mechanism that restricts access to resources.
The VISA locking mechanism enforces arbitration of accesses to VISA resources on a per-session basis. If a session locks a resource, operations invoked on the resource through other sessions either are serviced or are returned with an error, depending on the operation and the type of lock.
If a VISA resource is not locked by any of its sessions, all sessions have full privilege to invoke any operation and update any global attributes.
Sessions are not required to have locks to invoke operations or update global attributes. However, if some other session has already locked the resource, attempts to update global attributes or invoke certain operations will fail.
viLock/viUnlock Functions
The VISA viLock function is used to acquire a lock on a resource.
viLock(vi, lockType, timeout, requestedKey,
accessKey);
The VI_ATTR_RSRC_LOCK_STATE attribute specifies the current locking state of the resource on the given session, which can be either
VI_NO_LOCK, VI_EXCLUSIVE_LOCK, or VI_SHARED_LOCK.
The VISA viUnlock function is then used to release the lock on a resource. If a resource is locked and the current session does not have the lock, the error VI_ERROR_RSRC_LOCKED is returned.
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VISA Lock Types
VISA defines two different types of locks: Exclusive Lock and Shared
Lock.
Exclusive Lock - A session can lock a VISA resource using the lock type VI_EXCLUSIVE_LOCK to get exclusive access privileges to the resource. This exclusive lock type excludes access to the resource from all other sessions.
If a session has an exclusive lock, other sessions cannot modify global attributes or invoke operations on the resource. However, the other sessions can still get attributes.
Shared Lock - A session can share a lock on a VISA resource with other sessions by using the lock type VI_SHARED_LOCK. Shared locks in VISA are similar to exclusive locks in terms of access privileges, but can still be shared between multiple sessions.
If a session has a shared lock, other sessions that share the lock can also modify global attributes and invoke operations on the resource
(of course, unless some other session has a previous exclusive lock on that resource). A session that does not share the lock will lack these capabilities.
Locking a resource restricts access from other sessions, and in the case where an exclusive lock is acquired, ensures that operations do not fail because other sessions have acquired a lock on that resource. Thus, locking a resource prevents other, subsequent sessions from acquiring an exclusive lock on that resource. Yet, when multiple sessions have acquired a shared lock, VISA allows one of the sessions to acquire an exclusive lock along with the shared lock it is holding.
Also, VISA supports nested locking. That is, a session can lock the same VISA resource multiple times (for the same lock type) via multiple invocations of the viLock function. In such a case, unlocking the resource requires an equal number of invocations of the viUnlock function. Nested locking is explained in detail later in this section.
Some VISA operations may be permitted even when there is an exclusive lock on a resource, or some global attributes may not be read when there is any kind of lock on the resource. These exceptions, when applicable, are mentioned in the descriptions of the individual VISA functions and attributes.
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See the VISA Online Help for function descriptions to determine which are applicable for locking and which are not restricted by locking.
Example: Exclusive Lock
This example shows a session gaining an exclusive lock to perform the viPrintf and viScanf VISA operations on a GPIB device. It then releases the lock via the viUnlock function.
/* lockexcl.c
This example program queries a GPIB device for an identification string and prints the results.
Note that you may need to change the address. */
#include <visa.h>
#include <stdio.h> void main () {
ViSession defaultRM, vi;
char buf [256] = {0};
/* Open session to GPIB device at address 22 */
viOpenDefaultRM (&defaultRM);
viOpen (defaultRM, "GPIB0::22::INSTR",
VI_NULL,VI_NULL, &vi);
/* Initialize device */
viPrintf (vi, "*RST\n");
/* Make sure no other process or thread does
anything to this resource between viPrintf and
viScanf calls */
viLock (vi, VI_EXCLUSIVE_LOCK, 2000, VI_NULL,
VI_NULL);
/* Send an *IDN? string to the device */
viPrintf (vi, "*IDN?\n");
/* Read results */
viScanf (vi, "%t", &buf);
/* Unlock this session so other processes and
threads can use it */
viUnlock (vi);
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/* Print results */
printf ("Instrument identification string:
%s\n", buf);
/* Close session */
viClose (vi);
viClose (defaultRM);}
Example: Shared Lock
This example shows a session gaining a shared lock with the accessKey called lockkey. Other sessions can now use this accessKey in the requestedKey parameter of the viLock function to share access on the locked resource. This example then shows the original session acquiring an exclusive lock while maintaining its shared lock.
When the session holding the exclusive lock unlocks the resource via the viUnlock function, all the sessions sharing the lock again have all the access privileges associated with the shared lock.
/* lockshr.c
This example program queries a GPIB device for an identification string and prints the results.
Note that you must change the address. */
#include <visa.h>
#include <stdio.h> void main () {
ViSession defaultRM, vi;
char buf [256] = {0};
char lockkey [256] = {0};
/* Open session to GPIB device at address 22 */
viOpenDefaultRM (&defaultRM);
viOpen (defaultRM, "GPIB0::22::INSTR",
VI_NULL,VI_NULL,&vi);
/* acquire a shared lock so only this process
and processes that we know about can access
this resource */
viLock (vi, VI_SHARED_LOCK, 2000, VI_NULL,
lockkey);
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/* at this time, we can make 'lockkey'
available to other processes that we know
about. This can be done with shared memory or
other inter-process communication methods.
These other processes can then call
"viLock(vi,VI_SHARED_LOCK, 2000, lockkey,
lockkey)" and they will also have access to
this resource. */
/* Initialize device */
viPrintf (vi, "*RST\n");
/* Make sure no other process or thread does
anything to this resource between the
viPrintf() and the viScanf()calls Note: this
also locks out the processes with which we
shared our 'shared lock' key. */
viLock (vi, VI_EXCLUSIVE_LOCK, 2000,
VI_NULL,VI_NULL);
/* Send an *IDN? string to the device */
viPrintf (vi, "*IDN?\n");
/* Read results */
viScanf (vi, "%t", &buf);
/* unlock this session so other processes and
threads can use it */
viUnlock (vi);
/* Print results */
printf ("Instrument identification string:
%s\n", buf);
/* release the shared lock also*/
viUnlock (vi);
/* Close session */
viClose (vi);
viClose (defaultRM);
}
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Programming via GPIB and VXI
VISA supports three interfaces you can use to access GPIB (General
Purpose Interface Bus) and VXI (VME eXtension for Instrumentation) instruments: GPIB, VXI, and GPIB-VXI.
This chapter provides information to program GPIB and VXI devices via the GPIB, VXI or GPIB-VXI interfaces, including:
• GPIB and VXI Interfaces Overview
• Using High-Level Memory Functions
• Using Low-Level Memory Functions
• Using High/Low-Level Memory I/O Methods
• Using the Memory Access Resource
• Using VXI-Specific Attributes
See Chapter 3, “Programming with VISA”, for general information on
VISA programming for the GPIB, VXI, and GPIB-VXI interfaces. See the VISA Online Help for information on the specific VISA functions.
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GPIB and VXI Interfaces Overview
This section provides an overview of the GPIB, GPIB-VXI, and VXI interfaces, including:
• General Interface Information
• GPIB Interfaces Overview
• VXI Interfaces Overview
General Interface Information
VISA supports three interfaces you can use to access instruments or devices: GPIB, VXI, and GPIB-VXI. The GPIB interface can be used to access VXI instruments via a Command Module. In addition, the VXI backplane can be directly accessed with the VXI or GPIB-VXI interfaces.
What is an I/O Interface?
An I/O interface can be defined as both a hardware interface and as a software interface. Connection Expert is used to associate a unique interface name with a hardware interface. Agilent IO Libraries Suite uses a VISA interface name to identify an interface. This information is passed in the parameter string of the viOpen function call in a VISA program.
Connection Expert assigns a VISA interface name to the interface hardware, and other necessary configuration values for an interface when the interface is configured. See the Agilent IO Libraries Suite
Online Help for details.
VXI Device Types
When using GPIB-VXI or VXI interfaces to directly access the VXI backplane (in the VXI mainframe), you must know whether you are programming a message-based or a register-based VXI device
(instrument).
A message-based VXI device has its own processor that allows it to interpret high-level commands such as Standard Commands for
Programmable Instruments (SCPI). When using VISA, you can place the SCPI command within your VISA output function call. Then, the
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4 message-based device interprets the SCPI command. In this case you can use the VISA formatted I/O or non-formatted I/O functions and program the message-based device as you would a GPIB device.
However, if the message-based device has shared memory, you can access the device's shared memory by doing register peeks and pokes.
VISA provides two different methods you can use to program directly to the registers: high-level memory functions or low-level memory functions.
A register-based VXI device typically does not have a processor to interpret high-level commands. Therefore, the device must be programmed with register peeks and pokes directly to the device's registers. VISA provides two different methods you can use to program register-based devices: high-level memory functions or low-level memory functions.
GPIB Interfaces Overview
As shown in the following figure, a typical GPIB interface consists of a
Windows PC with one or more GPIB cards (PCI and/or ISA) cards installed in the PC, and one or more GPIB instruments connected to the
GPIB cards via GPIB cable. I/O communication between the PC and the instruments is via the GPIB cards and the GPIB cable. The following figure shows GPIB instruments at addresses 3 and 5.
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GPIB Interface (82350 PCI GPIB Cards)
Windows PC GPIB Cable GPIB Instruments
82350 GPIB Card #1
82350 GPIB Card #2
5
3
3
Example: GPIB (82350) Interface
The GPIB interface system in the following figure consists of a
Windows PC with two 82350 GPIB cards connected to three GPIB instruments via GPIB cables. For this system, Agilent Connection
Expert has been used to assign GPIB card #1 a VISA name of GPIB0 and to assign GPIB card #2 a VISA name of GPIB1. VISA addressing is as shown in the figure.
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Interface VISA Names
GPIB Interface (82350 PCI GPIB Cards)
Windows PC GPIB Cable
VISA Name
"GPIB0"
"GPIB1"
82350 GPIB Card #1
82350 GPIB Card #2
GPIB Instruments
5
3
3
VISA Addressing viOpen (... "GPIB0::5::INSTR"...) viOpen (... "GPIB0::3::INSTR"...) viOpen (... "GPIB1::3::INSTR"...)
Open IO path to GPIB instrument at address 5 using 82350 Card #1
Open IO path to GPIB instrument at address 3 using 82350 Card #1
Open IO path to GPIB instrument at address 3 using 82350 Card #2
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VXI Interfaces Overview
As shown in the following figure, a typical VXI (E8491) interface consists of an E8491 PC Card in a Windows PC that is connected to an
E8491B IEEE-1394 Module in a VXI mainframe via an IEEE-1394 to
VXI cable. The VXI mainframe also includes one or more VXI instruments.
Windows PC
VXI (E8491) Interfaces
IEEE-1394 to VXI
VXI Mainframe
E8491 PC Card
9
1
B
E
8
4
I n s r t
V
X
I
V
X
I n s t r
. .
I n s r t
V
X
I
Example: VXI (E8491B) Interfaces
The VXI interface system in the following figure consists of a Windows
PC with an E8491 PC card that connects to an E8491B IEEE-1394 to
VXI Module in a VXI Mainframe. For this system, the three VXI instruments shown have logical addresses 8, 16, and 24. The
Connection Expert utility has been used to assign the E8491 PC card a
VISA name of VXI0. VISA addressing is as shown in the figure.
For information on the E8491B module, see the Agilent E8491B User’s
Guide. For information on VXI instruments, see the applicable VXI instrument User’s Guide.
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VXI Interface (E8491B IEEE-1394 to VXI Module)
Interface VISA Name
VISA Name
"VXI0"
Windows PC IEEE-1394 to VXI
E8491 PC Card
VXI Mainframe
1
B
4
9
E
8
V
X
I
V
X
I
V
X
I r t s
I n
I t s r
LA 8 LA 24
. .
LA 16 s t r
I n
VISA Addressing viOpen (... "VXI0::24::INSTR"...) Open IO path to VXI instrument at logical address 24 using
E8491 PC Card and E8491 IEEE-1394 to VXI Module
GPIB-VXI Interfaces Overview
As shown in the following figure, a typical GPIB-VXI interface consists of a GPIB card (82350 or equivalent) in a Windows PC that is connected via a GPIB cable to an E1406A Command Module. The
E1406A sends commands to the VXI instruments in a VXI mainframe.
There is no direct access to the VXI backplane from the PC.
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N O T E
For a GPIB-VXI interface, VISA uses a DLL supplied by the Command
Module vendor to translate the VISA VXI calls to Command Module commands that are vendor-specific. The DLL required for Agilent
Command Modules is installed by the Agilent IO Libraries Suite installer. This DLL is installed by default when Agilent VISA is installed.
Windows PC
GPIB-VXI (E1406A) Interfaces
GPIB VXI Mainframe
GPIB Card
0
6
A
E
1
4 s t r
I n
V
X
I
V
X
I r t n s
. .
I r t n s
V
X
I
Example: GPIB-VXI (E1406A) Interface
The GPIB-VXI interface system in the following figure consists of a
Windows PC with an Agilent 82350 GPIB card that connects to an
E1406A command module in a VXI mainframe. The VXI mainframe includes one or more VXI instruments.
When Agilent IO Libraries Suite was installed, a GPIB-VXI driver with
GPIB address 9 was also installed, and the E1406A was configured for primary address 9 and logical address (LA) 0. The three VXI instruments shown have logical addresses 8, 16, and 24.
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The Connection Expert utility has been used to assign the GPIB-VXI driver a VISA name of GPIB-VXI0 and to assign the 82350 GPIB card a VISA name of GPIB0. VISA addressing is as shown in the figure.
For information on the E1406A Command Module, see the Agilent
E1406A Command Module User’s Guide. For information on VXI instruments, see the applicable instrument’s User’s Guide.
Interface VISA Name
VISA Name
"GPIB-VXI0"
"GPIB0"
GPIB-VXI Interface (E1406A Command Module)
Windows PC VXI Mainframe
GPIB-VXI Driver
GPIB Address 9
82350 GPIB Card
Primary
Address 9
GPIB
V
X
I
V
X
I
0
6
A
E
1
4
I n s t r
I s t r
LA 0 LA 8 LA 24
V
X
I
. .
s t
I n r
LA 16
VISA Addressing viOpen (... "GPIB-VXI0::24::INSTR"...) Open IO path to VXI instrument at logical address 24 using
82350 GPIB Card and E1406A VXI Command Module at
GPIB primary address 9
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Using High-Level Memory Functions
High-level memory functions allow you to access memory on the interface through simple function calls. There is no need to map memory to a window. Instead, when high-level memory functions are used, memory mapping and direct register access are automatically done.
The trade-off, however, is speed. High-level memory functions are easier to use. However, since these functions encompass mapping of memory space and direct register access, the associated overhead slows program execution time. If speed is required, use the low-level memory
functions discussed in “Using Low-Level Memory Functions” on page 94.
Programming the Registers
High-level memory functions include the viIn and viOut functions for transferring 8-, 16-, or 32-bit values, as well as the viMoveIn and
viMoveOut functions for transferring 8-, 16-, or 32-bit blocks of data into or out of local memory. You can therefore program using 8-, 16-, or
32-bit transfers.
High-Level Memory Functions
This table summarizes the high-level memory functions.
Table 20 Summary of High-Level Memory Functions
Function viIn8 ( vi, space, offset, val8) ;
Description
Reads 8 bits of data from the specified offset.
viIn16 ( vi, space, offset, val16) ; Reads 16 bits of data from the specified offset.
viIn32 ( vi, space, offset, val32) ; Reads 32 bits of data from the specified offset.
viOut8 ( vi, space, offset, val8) ; Writes 8 bits of data to the specified offset.
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Table 20 Summary of High-Level Memory Functions viOut16
val16)
val32)
; viOut32
;
( vi, space, offset,
( vi, space, offset,
viMoveIn8(vi, space, offset,
length, buf8) ; viMoveIn16 ( vi, space, offset,
length, buf16) ;
viMoveIn32(vi, space, offset,
length, buf32) ;
viMoveOut8(vi, space, offset,
length, buf8) ; viMoveOut16 ( vi, space, offset,
length, buf16) ; viMoveOut32 ( vi, space, offset,
length, buf32) ;
Writes 16 bits of data to the specified offset.
Writes 32 bits of data to the specified offset.
Moves an 8-bit block of data from the specified offset to local memory.
Moves a 16-bit block of data from the specified offset to local memory.
Moves a 32-bit block of data from the specified offset to local memory.
Moves an 8-bit block of data from local memory to the specified offset.
Moves a 16-bit block of data from local memory to the specified offset.
Moves a 32-bit block of data from local memory to the specified offset.
Using viIn and viOut
When using the viIn and viOut high-level memory functions to program to the device registers, all you need to specify is the session identifier, address space, and the offset of the register. Memory mapping is done for you. For example, in this function: viIn32(vi, space, offset, val32);
vi is the session identifier and offset is used to indicate the offset of the memory to be mapped. offset is relative to the location of this device's memory in the given address space. The space parameter determines which memory location to map the space. Valid space values are:
• VI_A16_SPACE - Maps in VXI/MXI A16 address space
• VI_A24_SPACE - Maps in VXI/MXI A24 address space
• VI_A32_SPACE - Maps in VXI/MXI A32 address space
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The val32 parameter is a pointer to where the data read will be stored. If instead you write to the registers via the viOut32 function, the val32 parameter is a pointer to the data to write to the specified registers. If the device specified by vi does not have memory in the specified address space, an error is returned. The following code sample uses viIn16.
ViSession defaultRM, vi;
ViUInt16 value;
.
viOpenDefaultRM(&&defaultRM); viOpen(defaultRM, "VXI::24", VI_NULL, VI_NULL,
&vi); viIn16(vi, VI_A16_SPACE, 0x100, &value);
Using
viMoveIn
and
viMoveOut
You can also use the viMoveIn and viMoveOut high-level memory functions to move blocks of data to or from local memory. Specifically, the viMoveIn function moves an 8-, 16-, or 32-bit block of data from the specified offset to local memory, and the viMoveOut functions moves an 8-, 16-, or 32-bit block of data from local memory to the specified offset. Again, the memory mapping is done for you.
For example, in this function: viMoveIn32(vi, space, offset, length, buf32);
vi is the session identifier and offset is used to indicate the offset of the memory to be mapped. offset is relative to the location of this device's memory in the given address space. The space parameter determines which memory location to map the space and the length parameter specifies the number of elements to transfer (8-, 16-, or 32-bits).
The buf32 parameter is a pointer to where the data read will be stored. If instead you write to the registers via the viMoveOut32 function, the
buf32 parameter is a pointer to the data to write to the specified registers.
High-Level Memory Functions: Sample Programs
Two sample programs follow that use the high-level memory functions to read the ID and Device Type registers of a device at the VXI logical address 24. The contents of the registers are then printed out.
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The first program uses the VXI interface; the second program accesses the backplane with the GPIB-VXI interface. These two programs are identical except for the string passed to viOpen.
Sample: Using VXI Interface (High-Level) Memory
Functions
This program uses high-level memory functions and the VXI interface to read the ID and Device Type registers of a device at VXI0::24.
/* vxihl.c
This example program uses the high-level memory functions to read the id and device type registers of the device at VXI0::24. Change this address if necessary. The register contents are then displayed.*/
#include <visa.h>
#include <stdlib.h>
#include <stdio.h> void main () {
ViSession defaultRM, dmm;
unsigned short id_reg, devtype_reg;
/* Open session to VXI device at address 24 */
viOpenDefaultRM(&defaultRM);
viOpen(defaultRM, "VXI0::24::INSTR", VI_NULL,
VI_NULL, &dmm);
/* Read instrument id register contents */
viIn16(dmm, VI_A16_SPACE, 0x00, &id_reg);
/* Read device type register contents */
viIn16(dmm, VI_A16_SPACE, 0x02,
&devtype_reg);
/* Print results */
printf ("ID Register = 0x%4X\n", id_reg);
printf ("Device Type Register = 0x%4X\n",
devtype_reg);
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/* Close sessions */
viClose(dmm);
viClose(defaultRM);
}
Sample: Using GPIB-VXI Interface (High-Level) Memory
Functions
This program uses high-level memory functions and the GPIB-VXI interface to read the ID and Device Type registers of a device at
GPIB-VXI0::24.
/*gpibvxih.c
This example program uses the high-level memory functions to read the id and device type registers of the device at GPIB-VXI0::24. Change this address if necessary. The register contents are then displayed.*/
#include <visa.h>
#include <stdlib.h>
#include <stdio.h> void main ()
{
ViSession defaultRM, dmm;
unsigned short id_reg, devtype_reg;
/* Open session to VXI device at address 24 */
viOpenDefaultRM(&defaultRM);
viOpen(defaultRM, "GPIB-VXI0::24::INSTR",
VI_NULL,VI_NULL, &dmm);
/* Read instrument id register contents */
viIn16(dmm, VI_A16_SPACE, 0x00, &id_reg);
/* Read device type register contents */
viIn16(dmm, VI_A16_SPACE, 0x02,
&devtype_reg);
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/* Print results */
printf ("ID Register = 0x%4X\n", id_reg);
printf ("Device Type Register = 0x%4X\n",
devtype_reg);
/* Close sessions */
viClose(dmm);
viClose(defaultRM);
}
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Using Low-Level Memory Functions
Low-level memory functions allow direct access to memory on the interface just as do high-level memory functions. However, with low-level memory function calls, you must map a range of addresses and directly access the registers with low-level memory functions, such as viPeek32 and viPoke32.
There is more programming effort required when using low-level memory functions. However, the program execution speed can increase.
Additionally, to increase program execution speed, the low-level memory functions do not return error codes.
Programming the Registers
When using the low-level memory functions for direct register access, you must first map a range of addresses using the viMapAddress function. Next, you can send a series of peeks and pokes using the
viPeek and viPoke low-level memory functions. Then, you must free the address window using the viUnmapAddress function. A process you could use is:
1 Map memory space using viMapAddress.
2 Read and write to the register's contents using viPeek32 and
viPoke32.
3 Unmap the memory space using viUnmapAddress.
Low-Level Memory Functions
You can program the registers using low-level functions for 8-, 16-, or
32-bit transfers. This table summarizes the low-level memory functions.
Table 21 Summary of Low-Level Memory Functions
Function
viMapAddress(vi, mapSpace, mapBase, mapSize, access, suggested,
address);
viPeek8(vi, addr, val8);
Description
Maps the specified memory space.
Reads 8 bits of data from address specified.
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Table 21 Summary of Low-Level Memory Functions (continued)
viPeek16(vi, addr, val16);
viPeek32(vi, addr, val32);
viPoke8(vi, addr, val8);
viPoke16(vi, addr, val16);
viPoke32(vi, addr, val32);
viUnmapAddress(vi);
Reads 16 bits of data from address specified.
Reads 32 bits of data from address specified.
Writes 8 bits of data to address specified.
Writes 16 bits of data to address specified.
Writes 32 bits of data to address specified.
Unmaps memory space previously mapped.
Mapping Memory Space
When using VISA to access the device's registers, you must map memory space into your process space. For a given session, you can have only one map at a time. To map space into your process, use the
VISA viMapAddress function: viMapAddress(vi, mapSpace, mapBase, mapSize,
access, suggested, address);
This function maps space for the device specified by the vi session. mapBase , mapSize , and suggested are used to indicate the offset of the memory to be mapped, amount of memory to map, and a suggested starting location, respectively. mapSpace determines which memory location to map the space. The following are valid mapSpace choices:
VI_A16_SPACE - Maps in VXI/MXI A16 address space
VI_A24_SPACE - Maps in VXI/MXI A24 address space
VI_A32_SPACE - Maps in VXI/MXI A32 address space
A pointer to the address space where the memory was mapped is returned in the address parameter. If the device specified by vi does not have memory in the specified address space, an error is returned. Some sample viMapAddress function calls follow.
/* Maps to A32 address space */ viMapAddress(vi, VI_A32_SPACE, 0x000, 0x100,
VI_FALSE,
VI_NULL,&address);
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/* Maps to A24 address space */ viMapAddress(vi, VI_A24_SPACE, 0x00, 0x80,
VI_FALSE,
VI_NULL,&address);
Reading and Writing to Device Registers
When you have mapped the memory space, use the VISA low-level memory functions to access the device's registers. First, determine which device register you need to access. Then, you need to know the register's offset. See the applicable instrument’s user manual for a description of the registers and register locations. You can then use this information and the VISA low-level functions to access the device registers.
Sample: Using
viPeek16
A code sample using viPeek16 follows.
ViSession defaultRM, vi;
ViUInt16 value;
ViAddr address;
ViUInt16 value;
.
.
viOpenDefaultRM(&&defaultRM); viOpen(defaultRM, "VXI::24::INSTR", VI_NULL,
VI_NULL,
&vi); viMapAddress(vi, VI_A16_SPACE, 0x00, 0x04,
VI_FALSE,
VI_NULL, &address); viPeek16(vi, addr, &value)
Unmapping Memory Space
Make sure you use the viUnmapAddress function to unmap the memory space when it is no longer needed. Unmapping memory space makes the window available for the system to reallocate.
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Low-Level Memory Functions: Code Samples
Two sample programs follow that use the low-level memory functions to read the ID and Device Type registers of the device at VXI logical address 24. The contents of the registers are then printed out. The first program uses the VXI interface and the second program uses the
GPIB-VXI interface to access the VXI backplane. These two programs are identical except for the string passed to viOpen.
Sample: Using the VXI Interface (Low-Level) Memory
Functions
This program uses low-level memory functions and the VXI interface to read the ID and Device Type registers of a device at VXI0::24.
/*vxill.c
This example program uses the low-level memory functions to read the id and device type registers of the device at VXI0::24. Change this address if necessary. The register contents are then displayed.*/
#include <visa.h>
#include <stdlib.h>
#include <stdio.h> void main () {
ViSession defaultRM, dmm;
ViAddr address;
unsigned short id_reg, devtype_reg;
/* Open session to VXI device at address 24 */
viOpenDefaultRM(&defaultRM);
viOpen(defaultRM, "VXI0::24::INSTR", VI_NULL,
VI_NULL, &dmm);
/* Map into memory space */
viMapAddress(dmm, VI_A16_SPACE, 0x00, 0x10,
VI_FALSE,VI_NULL, &address);
/* Read instrument id register contents */
viPeek16(dmm, address, &id_reg);
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/* Read device type register contents */
/* ViAddr is defined as a void so we must cast
/* it to something else to do pointer
arithmetic */
viPeek16(dmm, (ViAddr)((ViUInt16 *)address +
0x01),
&devtype_reg);
/* Unmap memory space */
viUnmapAddress(dmm);
/* Print results */
printf ("ID Register = 0x%4X\n", id_reg);
printf ("Device Type Register = 0x%4X\n",
devtype_reg);
/* Close sessions */
viClose(dmm);
viClose(defaultRM);
}
Sample: Using the GPIB-VXI Interface (Low-Level) Memory
Functions
This program uses low-level memory functions and the GPIB-VXI interface to read the ID and Device Type registers of a device at
GPIB-VXI0::24.
/*gpibvxil.c
This example program uses the low-level memory functions to read the id and device type registers of the device at GPIB-VXI0::24. Change this address if necessary. Register contents are then displayed.*/
#include <visa.h>
#include <stdlib.h>
#include <stdio.h> void main () {
ViSession defaultRM, dmm;
ViAddr address;
unsigned short id_reg, devtype_reg;
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/* Open session to VXI device at address 24 */
viOpenDefaultRM(&defaultRM);
viOpen(defaultRM, "GPIB-VXI0::24::INSTR",
VI_NULL,
VI_NULL,&dmm);
/* Map into memory space */
viMapAddress(dmm, VI_A16_SPACE, 0x00, 0x10,
VI_FALSE,
VI_NULL, &address);
/* Read instrument id register contents */
viPeek16(dmm, address, &id_reg);
/* Read device type register contents */
/* ViAddr is defined as a void so we must
cast it to something else to do pointer
arithmetic */
viPeek16(dmm, (ViAddr)((ViUInt16 *)address +
0x01),
&devtype_reg);
/* Unmap memory space */
viUnmapAddress(dmm);
/* Print results */
printf ("ID Register = 0x%4X\n", id_reg);
printf ("Device Type Register = 0x%4X\n",
devtype_reg);
/* Close sessions */
viClose(dmm);
viClose(defaultRM);
}
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Using Low/High-Level Memory I/O Methods
VISA supports three different memory I/O methods for accessing memory on the VXI backplane, as shown. All three of these access methods can be used to read and write VXI memory in the A16, A24, and A32 address spaces. The best method to use depends on the VISA program characteristics.
• Low-level viPeek/viPoke
• viMapAddress
• viUnmapAddress
• viPeek8, viPeek16, viPeek32
• viPoke8, viPoke16, viPoke32
• High-level viIn/viOut
• viIn8, viIn16, viIn32
• viOut8, viOut16, viOut32
• High-level viMoveIn/viMoveOut
• viMoveIn8, viMoveIn16, viMoveIn32
• viMoveOut8, viMoveOut16, viMoveOut32
Using Low-Level viPeek/viPoke
Low-level viPeek/viPoke is the most efficient in programs that require repeated access to different addresses in the same memory space.
The advantages of low-level viPeek/viPoke are:
• Individual viPeek/viPoke calls are faster than viIn/viOut or
viMoveIn/viMoveOut calls.
• Memory pointers may be directly de-referenced in some cases for the lowest possible overhead.
The disadvantages of low-level viPeek/viPoke are:
• A viMapAddress call is required to set up mapping before
viPeek/viPoke can be used.
• viPeek/viPoke calls do not return status codes.
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• Only one active viMapAddress is allowed per vi session.
• There may be a limit to the number of simultaneous active
viMapAddress calls per process or system.
Using High-Level viIn/viOut
High-level viIn/viOut calls are best in situations where a few widely scattered memory accesses are required and speed is not a major consideration.
The advantages of high-level viIn/viOut are:
• It is the simplest method to implement.
• There is no limit on the number of active maps.
• A16, A24, and A32 memory access can be mixed in a single vi session.
The disadvantage of high-level viIn/viOut calls is that they are slower than viPeek/viPoke.
Using High-Level viMoveIn/viMoveOut
High-level viMoveIn/viMoveOut calls provide the highest possible performance for transferring blocks of data to or from the VXI backplane. Although these calls have higher initial overhead than the
viPeek/viPoke calls, they are optimized on each platform to provide the fastest possible transfer rate for large blocks of data.
For small blocks, the overhead associated with viMoveIn/viMoveOut may actually make these calls longer than an equivalent loop of
viIn/viOut calls. The block size at which viMoveIn/viMoveOut becomes faster depends on the particular platform and processor speed.
The advantages of high-level viMoveIn/viMoveOut are:
• They are simple to use.
• There is no limit on number of active maps.
• A16, A24, and A32 memory access can be mixed in a single vi session.
• They provide the best performance when transferring large blocks of data.
• They support both block and FIFO mode.
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The disadvantage of viMoveIn/viMoveOut calls is that they have higher initial overhead than viPeek/viPoke.
Sample: Using VXI Memory I/O
This program demonstrates using various types of VXI memory I/O.
/* memio.c
This example program demonstrates the use of various memory I/O methods in VISA. */
#include <visa.h>
#include <stdlib.h>
#include <stdio.h>
#define VXI_INST "VXI0::24::INSTR" void main () {
ViSession defaultRM, vi;
ViAddr address;
ViUInt16 accessMode;
unsigned short *memPtr16;
unsigned short id_reg;
unsigned short devtype_reg;
unsigned short memArray[2];
/*Open default resource manager and session
to instr*/
viOpenDefaultRM (&defaultRM);
viOpen defaultRM, VXI_INST, VI_NULL,VI_NULL,
&vi);
/*
================================================
==
Low level memory I/O = viPeek16 = direct
memory dereference (when allowed)
================================================
*/
/* Map into memory space */
viMapAddress (vi, VI_A16_SPACE, 0x00, 0x10,
VI_FALSE,VI_NULL, &address);
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/*
================================================
=
Using viPeek
================================================
*/
Read instrument id register contents */
viPeek16 (vi, address, &id_reg);
/* Read device type register contents
ViAddr is defined as a (void *) so we must
cast it to something else in order to do
pointer arithmetic. */
viPeek16 (vi, (ViAddr)((ViUInt16 *)address +
0x01),&devtype_reg);
/* Print results */
printf (" viPeek16: ID Register = 0x%4X\n",
id_reg);
printf (" viPeek16: Device Type Register =
0x%4X\n",devtype_reg);
/* Use direct memory dereferencing if
supported */
viGetAttribute( vi, VI_ATTR_WIN_ACCESS,
&accessMode );
if ( accessMode == VI_DEREF_ADDR ) {
/* assign pointer to variable of correct
type */
memPtr16 = (unsigned short *)address;
/* do the actual memory reads */
id_reg = *memPtr16;
devtype_reg = *(memPtr16+1);
/* Print results */
printf ("dereference: ID Register =
0x%4X\n",id_reg);
printf ("dereference: Device Type Register
=0x%4X\n", devtype_reg);
}
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/* Unmap memory space */
viUnmapAddress (vi);
/*==============================================
High Level memory I/O = viIn16
==============================================*/
/* Read instrument id register contents */
viIn16 (vi, VI_A16_SPACE, 0x00, &&id_reg);
/* Read device type register contents */
viIn16 (vi, VI_A16_SPACE, 0x02,&devtype_reg);
/* Print results */
printf (" viIn16: ID Register = 0x%4X\n",
id_reg);
printf (" viIn16: Device Type Register =
0x%4X\n", devtype_reg);
/*==============================================
======
High Level block memory I/O = viMoveIn16
The viMoveIn/viMoveOut commands do both block read/write and FIFO read write. These commands offer the best performance for reading and writing large data blocks on the VXI backplane.
For this example we are only moving 2 words at a time. Normally, these functions would be used to move much larger blocks of data.
If the value of VI_ATTR_SRC_INCREMENT is 1 (the default),viMoveIn does a block read. If the value of VI_ATTR_SRC_INCREMENT is 0, viMoveIn does a FIFO read.
If the value of VI_ATTR_DEST_INCREMENT is 1 (the default),viMoveOut does a block write. If the value of VI_ATTR_DEST_INCREMENT is 0, viMoveOut does a FIFO write.
*/
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/* Demonstrate block read.
Read instrument id register and device type
register into an array.*/
viMoveIn16 (vi, VI_A16_SPACE, 0x00, 2,
memArray);
/* Print results */
printf (" viMoveIn16: ID Register = 0x%4X\n",
memArray[0]);
printf (" viMoveIn16: Device Type Register =
0x%4X\n", memArray[1]);
/* Demonstrate FIFO read.
First set the source increment to 0 so we will
repetitively read from the same memory
location.*/
viSetAttribute( vi, VI_ATTR_SRC_INCREMENT, 0
);
/* Do a FIFO read of the Id Register */
viMoveIn16 (vi, VI_A16_SPACE, 0x00, 2,
memArray);
/* Print results */
printf (" viMoveIn16: 1 ID Register =
0x%4X\n",
memArray[0]);
printf (" viMoveIn16: 2 ID Register =
0x%4X\n",
memArray[1]);
/* Close sessions */
viClose (vi);
viClose (defaultRM); }
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Using the Memory Access Resource
For VISA 1.1 and later, the Memory Access (MEMACC) resource type has been added to VXI and GPIB-VXI. VXI::MEMACC and
GPIB-VXI::MEMACC allow access to all of the A16, A24, and A32 memory by providing the controller with access to arbitrary registers or memory addresses on memory-mapped buses.
The MEMACC resource, like any other resource, starts with the basic operations and attributes of other VISA resources. For example, modifying the state of an attribute is done via the operation
viSetAttribute (see VISA Resource Classes in the VISA Online Help for details).
Memory I/O Services
Memory I/O services include high-level memory I/O services and low-level memory I/O services.
High-Level Memory I/O Services
High-level memory I/O services allow register-level access to the interfaces that support direct memory access, such as the VXIbus,
VMEbus, MXIbus, or even VME or VXI memory through a system controlled by a GPIB-VXI controller. A resource exists for each interface to which the controller has access.
You can access memory on the interface bus through operations such as
viIn16 and viOut16. These operations encapsulate the map/unmap and peek/poke operations found in the low-level service. There is no need to explicitly map the memory to a window.
Low-Level Memory I/O Services
Low-level memory I/O services also allow register-level access to the interfaces that support direct memory access. Before an application can use the low-level service on the interface bus, it must map a range of addresses using the operation viMapAddress.
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Although the resource handles the allocation and operation of the window, the programmer must free the window via viUnMapAddress when finished. This makes the window available for the system to reallocate.
Sample: MEMACC Resource Program
This program demonstrates one way to use the MEMACC resource to open the entire VXI A16 memory and then calculate an offset to address a specific device.
/* peek16.c */
#include <stdio.h>
#include <stdlib.h>
#include <visa.h>
#define EXIT1
#define NO_EXIT 0
/* This function simplifies checking for VISA errors. */ void checkError( ViSession vi, ViStatus status, char
*errStr,int doexit){
char buf[256];
if (status >= VI_SUCCESS)
return;
buf[0] = 0;
viStatusDesc( vi, status, buf );
printf( "ERROR 0x%lx (%s)\n ’%s’\n", status, errStr,
buf );
if ( doexit == EXIT )
exit ( 1 );
} void main() {
ViSession drm;
ViSession vi;
ViUInt16inData16 = 0;
ViUInt16peekData16 = 0;
ViUInt8*addr;
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ViUInt16*addr16;
ViStatusstatus;
ViUInt16offset;
status = viOpenDefaultRM ( &drm );
checkError( 0, status, "viOpenDefaultRM",
EXIT );
/* Open a session to the VXI MEMACC Resource*/
status = viOpen( drm, "vxi0::memacc",
VI_NULL, VI_NULL,
&vi );
checkError (0, status, "viOpen", EXIT );
/* Calculate the A16 offset of the VXI
REgisters for
the device at VXI logical address 8. */
offset = 0xc000 + 64 * 8;
/* Open a map to all of A16 memory space. */
status = viMapAddress(vi,VI_A16_SPACE,0,0x10000,
VI_FALSE,0,(ViPAddr)(&addr));
checkError( vi, status, "viMapAddress", EXIT
);
/* Offset the address pointer returned from
viMapAddress for use with viPeek16. */
addr16 = (ViUInt16 *) (addr + offset);
/* Peek the contents of the card’s ID register
(offset
0 from card’s base address. Note that viPeek does
not return a status code. */
viPeek16( vi, addr16, &peekData16 );
/* Now use viIn16 and read the contents of the same
register */
status = viIn16(vi, VI_A16_SPACE,
ViBusAddress)offset, &inData16 );
checkError(vi, status, "viIn16", NO_EXIT );
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/* Print the results. */
printf( "inData16 : 0x%04hx\n", inData16 );
printf( "peekData16: ox%04hx\n", peekData16
);
viClose( vi );
viClose (drm );
}
MEMACC Attribute Descriptions
Generic MEMACC Attributes
The following read-only attributes (VI_ATTR_TMO_VALUE is read/write) provide general interface information.
Table 22 Attributes That Provide General Interface Information
Attribute
VI_ATTR_INTF_TYPE
VI_ATTR_INTF_NUM
VI_ATTR_TMO_VALUE
VI_ATTR_INTF_INST_NA
ME
VI_ATTR_DMA_ALLOW_
EN
Description
Interface type of the given session.
Board number for the given interface.
Minimum timeout value to use, in milliseconds. A timeout value of
VI_TMO_IMMEDIATE means operation should never wait for the device to respond.
A timeout value of VI_TMO_INFINITE disables the timeout mechanism.
Human-readable text describing the given interface.
Specifies whether I/O accesses should use
DMA (VI_TRUE) or Programmed I/O
(VI_FALSE).
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VXI and GPIB-VXI Specific MEMACC Attributes
The following attributes, most of which are read/write, provide memory window control information.
Table 23 Attributes That Provide Memory Window Control
Information
Attribute
VI_ATTR_VXI_LA
Description
Logical address of the local controller.
VI_ATTR_SRC_INCREMENT Used in viMoveInxx operation to specify how much the source offset is to be incremented after every transfer. The default value is 1 and the viMoveInxx operation moves from consecutive elements.
If this attribute is set to 0, the viMoveInxx operation will always read from the same element, essentially treating the source as a
FIFO register.
VI_ATTR_DEST_INCREMEN
T
Used in viMoveOutxx operation to specify how much the destination offset is to be incremented after every transfer. The default value is 1 and the viMoveOutxx operation moves into consecutive elements.
VI_ATTR_WIN_ACCESS
VI_ATTR_WIN_BASE_ADD
R
VI_ATTR_WIN_SIZE
If this attribute is set to 0, the
viMoveOutxx operation will always write to the same element, essentially treating the destination as a FIFO register.
Specifies modes in which the current window may be addressed: not currently mapped, through the viPeekxx or viPokexx operations only, or through operations and/or by directly de-referencing the address parameter as a pointer.
Base address of the interface bus to which this window is mapped.
Size of the region mapped to this window.
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Table 23 Attributes That Provide Memory Window Control
Information
VI_ATTR_SRC_BYTE_ORDE
R
Specifies the byte order used in high-level access operations, such as viInxx and
viMoveInxx, when reading from the source.
VI_ATTR_DEST_BYTE_ORD
ER
Specifies the byte order used in high level access operations, such as viOutxx and
viMoveOutxx, when writing to the destination.
VI_ATTR_WIN_BYTE_ORD
ER
Specifies the byte order used in low-level access operations, such as viMapAddress,
viPeekxx, and viPokexx, when accessing the mapped window.
VI_ATTR_SRC_ACCESS_PRI
V
Specifies the address modifier used in high-level access operations, such as
viInxx and viMoveInxx, when reading from the source.
VI_ATTR_DEST_ACCESS_P
RIV
VI_ATTR_WIN_ACCESS_PR
IV
Specifies the address modifier used in high-level access operations such as
viOutxx and viMoveOutxx, when writing to destination.
Specifies the address modifier used in low-level access operations, such as
viMapAddress, viPeekxx, and viPokexx, when accessing the mapped window.
GPIB-VXI Specific MEMACC Attributes
The following read-only attributes provide specific address information about GPIB hardware.
Table 24 Attributes that Provide Specific Address Information
Attribute
VI_ATTR_INTF_PARENT_NUM
Description
Board number of the GPIB board to which the GPIB-VXI is attached.
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Table 24 Attributes that Provide Specific Address Information
VI_ATTR_GPIB_PRIMARY_ADD
R
VI_ATTR_GPIB_SECONDARY_A
DDR
Primary address of the GPIB-VXI controller used by the session.
Secondary address of the GPIB-VXI controller used by the session.
MEMACC Resource Event Attribute
The following read-only events provide notification that an asynchronous operation has completed.
Table 25 Events Providing Notification About Asynchronous
Operations
Attribute
VI_ATTR_EVENT_T
YPE
VI_ATTR_STATUS
Description
Unique logical identifier of the event.
VI_ATTR_JOB_ID
VI_ATTR_BUFFER
VI_ATTR_RET_COU
NT
Return code of the asynchronous I/O operation that has completed.
Job ID of the asynchronous I/O operation that has completed.
Address of a buffer used in an asynchronous operation.
Actual number of elements that were asynchronously transferred.
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Using VXI-Specific Attributes
VXI-specific attributes can be useful to determine the state of your VXI system. Attributes are read-only and read/write. Read-only attributes specify things such as the logical address of the VXI device and information about where your VXI device is mapped. This section shows how you might use some of the VXI-specific attributes. See VISA
Resource Classes in the VISA Online Help for information on VISA attributes.
Using the Map Address as a Pointer
The VI_ATTR_WIN_ACCESS read-only attribute specifies how a window can be accessed. You can access a mapped window with the
VISA low-level memory functions or with a C pointer if the address is de-referenced. To determine how to access the window, read the
VI_ATTR_WIN_ACCESS attribute.
VI_ATTR_WIN_ACCESS Settings
The VI_ATTR_WIN_ACCESS read-only attribute can be set to one of the following:
Table 26 Settings for the VI_ATTR_WIN_ACCESS Attribute
Setting Description
VI_NMAPPED Specifies that the window is not mapped.
VI_USE_OPERS Specifies that the window is mapped and you can only use the low-level memory functions to access the data.
VI_DEREF_AD
DR
Specifies that the window is mapped and has a de-referenced address. In this case you can use the low-level memory functions to access the data, or you can use a C pointer. Using a de-referenced C pointer will allow faster access to data.
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Sample: Determining Window Mapping
ViAddr address;
Vi UInt16 access;
ViUInt16 value;
.
.
.
viMapAddress(vi, VI_A16_SPACE, 0x00, 0x04,
VI_FALSE,
VI_NULL, &address); viGetAttribute(vi, VI_ATTR_WIN_ACCESS, &access);
.
.
If(access==VI_USE_OPERS) {
viPeek16(vi, (ViAddr)(((ViUInt16 *)address) +
4/sizeof(ViUInt16)), &value)
}else if (access==VI_DEREF_ADDR){
value=*((ViUInt16
*)address+4/sizeof(ViUInt16));
}else if (access==VI_NMAPPED){
return error;
}
.
.
Setting the VXI Trigger Line
The VI_ATTR_TRIG_ID attribute is used to set the VXI trigger line.
This attribute is listed under generic attributes and defaults to
VI_TRIG_SW (software trigger). To set one of the VXI trigger lines, set the VI_ATTR_TRIG_ID attribute as follows: viSetAttribute(vi, VI_ATTR_TRIG_ID,
VI_TRIG_TTL0);
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The above function sets the VXI trigger line to TTL trigger line 0
(VI_TRIG_TTL0). The following are valid VXI trigger lines. (Panel In is an Agilent extension of the VISA specification.)
Table 27 VXI Trigger Lines and Values
VXI Trigger
Line
VI_ATTR_TRIG_ID Value
TTL 0
TTL 1
VI_TRIG_TTL0
VI_TRIG_TTL1
TTL 2
TTL 3
TTL 4
TTL 5
VI_TRIG_TTL2
VI_TRIG_TTL3
VI_TRIG_TTL4
VI_TRIG_TTL5
TTL 6
TTL 7
ECL 0
ECL 1
Panel In
VI_TRIG_TTL6
VI_TRIG_TTL7
VI_TRIG_ECL0
VI_TRIG_ECL1
VI_TRIG_PANEL_IN
Once you set a VXI trigger line, you can set up an event handler to be
VI_EVENT_TRIG event is enabled, the VI_ATTR_TRIG_ID becomes a read only attribute and cannot be changed. You must set this attribute prior to enabling event triggers.
The VI_ATTR_TRIG_ID attribute can also be used by viAssertTrigger function to assert software or hardware triggers. If VI_ATTR_TRIG_ID is VI_TRIG_SW, the device is sent a Word Serial Trigger command. If the attribute is any other value, a hardware trigger is sent on the line corresponding to the value of that attribute.
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N O T E
5
Programming via LAN
This chapter provides guidelines for programming via a LAN (Local
Area Network). A LAN allows you to extend the control of instrumentation beyond the limits of typical instrument interfaces.
The chapter contents are:
• LAN Interfaces Overview
• Communicating with LAN-Connected Devices
This chapter describes programming using the VISA TCPIP interface type to communicate directly with a LAN-connected device, as well as using a remote interface (also known as a LAN client) to emulate a
GPIB, serial (ASRL), or USB interface on the local machine to communicate with a LAN-connected device.
See the Agilent IO Libraries Suite Online Help for information on how to start and stop the Remote IO Server software, and on how to create and configure LAN interfaces and remote GPIB/USB/serial interfaces.
See the Connectivity Guide for detailed information on connecting instruments to a LAN, and for a discussion of network protocols.
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LAN and Remote Interfaces Overview
This section provides an overview of LAN (Local Area Network) interfaces. A LAN is a way to extend the control of instrumentation beyond the limits of typical instrument interfaces. To communicate with instruments over the LAN, you must first configure a LAN interface or a remote GPIB, USB, or serial interface, using the Agilent Connection
Expert.
Direct LAN Connection versus Remote IO Server/Client
Connection
Some instruments support direct connection to the LAN. These instruments include an RJ-45 or other standard LAN connector and software support for operating as an independent device on the network.
Some of these instruments are Web-enabled, meaning that they host a
Web page which you can access over the LAN.
With the Agilent IO Libraries Suite, you can connect to instruments across the LAN even if they do not have direct LAN capability, if they are connected to gateways (such as the Agilent E5810A) or to another
PC running the Remote IO Server software.
Refer to the IO Libraries Suite and the Connectivity Guide for information on connecting and configuring different types of LAN instrument connections.
Remote IO Server/Client Architecture
The Remote IO Server and Client software provided with Agilent IO
Libraries Suite allows instrumentation to be controlled over a LAN.
Using standard LAN connections, instruments can be controlled from computers that do not have special interfaces for instrument control.
Client/Server Model
The IO Libraries Suite software uses the client/server model of computing. Client/server computing refers to a model in which an application (the client) does not perform all necessary tasks of the application itself. Instead, the client makes requests of another computing device (the remote I/O server) for certain services.
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As shown in the following figure, a remote I/O client (a Windows PC) makes VISA requests over the network to a remote I/O server (such as a
Windows PC, an E5810 LAN/GPIB Gateway, or a Series 700 HP-UX workstation).
Gateway Operation
The remote I/O server is connected to the instrumentation or devices to be controlled. Once the remote I/O server has completed the requested operation on the instrument or device, the remote I/O server sends a reply to the client. This reply contains the requested data and status information that indicates whether or not the operation was successful.
The remote I/O server acts as a gateway between the LAN software that the client system supports and the instrument-specific interface that the device supports.
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Client
Windows PCs
LAN
Remote
I/O
Server
Series 700 workstation or
Windows PC
GPIB bus
(or other)
E5810
LAN/GPIB
Gateway
GPIB
Instrument
LAN Instruments
(VXI-11.2 GPIB Emulation
or
VXI-11.3 LAN Instruments)
GPIB
Instruments
GPIB bus
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Addressing LAN-Connected Devices
VISA can communicate with LAN-connected devices in one of two ways:
• TCPIP interface type
• Remote interface type (available only with Agilent IO Libraries
Suite)
Using the TCPIP Interface Type for LAN Access
VISA provides the TCPIP interface type to communicate with
LAN-connected devices. These can be devices connected directly to the
LAN, or they can be connected to the LAN through a LAN gateway such as the Agilent E5810 LAN/GPIB gateway or through Remote IO
Server software running on a remote computer with instruments connected to it.
The format of a TCPIP VISA resource string is:
TCPIP[<board>]::<hostname>[::<LAN device name>][::INSTR] where:
• <board> = board number (default is 0)
• <hostname> = the hostname or IP address of the LAN device or server
• <LAN device name> = the remote device name (case sensitive with default name of inst0)
Using Connection Expert, you can configure a LAN interface to use either the VXI-11 protocol or the SICL-LAN protocol. The protocol(s) you will use depends upon the devices you are using and the protocol(s) that they support.
The VXI-11 protocol constrains the LAN device name to be of the form
inst0, inst1, … for VXI-11.3 devices and gpib0,n, gpib1,n, … for
VXI-11.2 (GPIB Emulation) devices.
The SICL-LAN protocol allows any valid SICL name for the LAN device name. A valid SICL name must be a unique string of alphanumeric characters, starting with a letter.
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Some examples of TCPIP resource strings follow.
Table 28 Example TCPIP Resource Strings
String
TCPIP0::[email protected]::gpib0,2::INST
R
TCPIP0::123.456.0.21::gpib0,2::INSTR
TCPIP0::myMachine::inst0::INSTR
TCPIP::myMachine
TCPIP0::testMachine1::COM1,488::INSTR
TCPIP0::myMachine::gpib0,2::INSTR
TCPIP0::myMachine::UsbDevice1::INSTR
Description
A VXI-11.2 GPIB device at hostname
A VXI-11.2 GPIB device at a machine whose IP address is
123.456.0.21.
A VXI-11.3 LAN instrument at hostname myMachine.
A VXI-11.3 LAN instrument at hostname myMachine. Note that default values for board = 0, LAN device name = inst0, and the
::INSTR resource class are used.
An RS-232 device connected to a LAN server or gateway at hostname testMachine1. This device must use SICL-LAN protocol since RS-232 devices are not supported by the VXI-11 protocol.
A GPIB device at hostname myMachine. This device must use
SICL-LAN protocol since gpib0,2 is not a valid remote name with the VXI-11 protocol.
A USB device with a SICL alias of UsbDevice1 connected to a
LAN server at hostname myMachine. Note that the SICL alias is defined on the remote machine, not on the local machine.
Although the SICL and VISA alias names are normally the same, if they are not, you must be sure to use the SICL alias and not the
VISA alias.
This device must use the SICL-LAN protocol since USB devices are not supported by the VXI-11 protocol.
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Table 28 Example TCPIP Resource Strings
String
TCPIP0::myMachine::usb0[2391::1031::SN_00123
::0]::INSTR
Description
A USB device with:
Manufacture ID = 2391
Model Code = 1031
Serial Number = 'SN_00123'
USBTMC Intfc # = 0 connected to a LAN server at hostname myMachine.
This device must use SICL-LAN protocol since USB devices are not supported by the VXI-11 protocol.
N O T E
Agilent VISA User’s Guide
A LAN session to a remote interface provides the same VISA function support as if the interface were local, except that VXI-specific functions are not supported over LAN.
Addressing a Session Using the TCPIP Interface Type
This sample shows one way to open a device session with a GPIB device at primary address 23 on a remote PC that is running a LAN
server. The hostname of the remote PC is myMachine. See Chapter 3,
“Programming with VISA”, for more information on addressing device
sessions.
ViSession defaultRM, vi;.
.
viOpenDefaultRM(&defaultRM); viOpen(defaultRM,
"TCPIP0::myMachine::gpib0,23::INSTR", VI_NULL,
VI_NULL, &vi);
.
.
viClose(vi);
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124 viClose(defaultRM);
Using a Remote Interface for LAN Access
Agilent VISA provides three types of VISA LAN Client interfaces, implemented in Agilent IO Libraries Suite as remote interfaces:
• Remote serial interface (ASRL VISA LAN Client)
• Remote GPIB interface (GPIB VISA LAN Client)
• Remote USB interface (USB VISA LAN Client)
Remote interfaces are configured using Connection Expert; they provide virtual GPIB, serial, or USB interfaces. They make it possible to remotely access a LAN-connected device as if it were connected to a local interface. If, for example, the GPIB2 interface is configured as a remote GPIB interface, a program controlling the devices
GPIB2::5::INSTR and GPIB2::7::INSTR would not be aware of the fact that these devices are actually connected via LAN and not to a
GPIB interface connected to the local machine.
See the Agilent IO Libraries Suite Online Help for specific information on configuring remote interfaces.
Remote Serial Interface (ASRL VISA LAN Client)
A remote serial interface can use only the SICL-LAN protocol. A remote serial interface can be configured to use the serial port on the
Agilent E5810 LAN/GPIB gateway or the serial ports on a PC running the Remote IO Server software.
Remote GPIB Interface (GPIB VISA LAN Client)
A remote GPIB interface can use both the VXI-11 and SICL-LAN protocols. Typical uses for remote GPIB interfaces are with LAN/GPIB gateways (e.g. Agilent E5810), PCs with GPIB interfaces that are running a LAN server, and VXI-11.2 LAN-based instruments.
A remote GPIB interface can only be used to communicate with
VXI-11.2 (GPIB Emulation) devices. This is because the VISA GPIB interface type requires a primary and (optionally) a secondary address when communicating with a device. VXI-11.3 devices do not support the concept of a primary address, so they cannot be accessed with a remote GPIB interface.
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Remote USB Interface (USB VISA LAN Client)
A remote USB interface can use only the SICL-LAN protocol. It can communicate with USB devices attached to a remote PC running the
Remote IO Server software.
Note that if you have defined a VISA alias for a USB device on the remote I/O server, you must either define the same (or another) alias for the remote USB device on the client PC, or use the full USB resource string. Alias definitions are not shared between the remote I/O server and the client.
Addressing a Session Using a Remote Interface
In general, the rules to address a remote session are the same as to address a local session. The only difference for a remote session is that you use the VISA interface ID (provided during I/O configuration via
Connection Expert) that relates to the remote interface.
The following sample shows one way to open a device session with a
GPIB device at primary address 23 on a remote PC that is running
Remote IO Server software. A remote GPIB interface has been
configured at GPIB2 to communicate with that machine. See Chapter 3,
“Programming with VISA”, for more information on addressing device
sessions.
ViSession defaultRM, vi;.
.
viOpenDefaultRM(&defaultRM); viOpen(defaultRM, "GPIB2::23::INSTR", VI_NULL,
VI_NULL, &vi);
.
.
viClose(vi); viClose(defaultRM);
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Programming via USB
This chapter provides guidelines for VISA programming of USB instruments that conform to USBTMC (Universal Serial Bus Test and
Measurement Class) and/or USBTMC-USB488 (Universal Serial Bus
Test and Measurement Class, Subclass USB488 Specification).
The chapter contents are:
• USB Interfaces Overview
• Communicating with a USB Instrument Using VISA
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USB Interfaces Overview
USBTMC/USBTMC-USB488 instruments are detected and automatically configured by Agilent VISA when they are plugged into the computer. The Agilent IO Libraries Suite Online Help describes the
USB instrument configuration process in more detail.
N O T E
Do not confuse the Agilent 82357 USB/GPIB Interface with a
USBTMC device. The 82357 is automatically configured as a GPIB interface, not as a USBTMC device, when it is plugged into the computer. Only USBTMC/USBTMC-USB488 devices are configured as USB devices by Agilent VISA.
Due to the complexity of the VISA USB resource string, a VISA alias
(simple name) is assigned to each USB instrument when it is plugged into the computer. You can use either the alias or the full VISA resource string when opening a VISA resource, but using the alias is recommended because it is simpler and because it allows substitution of
USB instruments without the need to change the VISA program.
You can also create VISA aliases for other (non-USB) instruments, using the Agilent Connection Expert.
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Communicating with a USB Instrument Using VISA
To establish communications with a USB device using VISA, you can either use the full VISA resource string for the device or use the alias provided by VISA. Using the alias is recommended, for reasons described below.
Using the full VISA resource string, a viOpen call would look something like this: viOpen( . . .,
"USB0::2391::1031::0000000123::0::INSTR", . . .
);
Following is a summary of the components of this call.
Table 29 Summary of Full-String viOpen Call
Value
2391
1031
0000000123
0
Description
Manufacturer ID
Model Code
Serial Number
USBTMC Interface
Number
Data Type
16-bit unsigned integer
16-bit unsigned integer string value
8-bit unsigned integer
This string uniquely identifies the USB device. The values needed for the resource string are displayed in a dialog box when the device is plugged into the computer.
To simplify the way a USB device is identified, Agilent VISA also provides an alias which can be used in place of this resource string. The first USB device that is plugged in is assigned a default alias of
UsbDevice1. Additional devices are assigned aliases of UsbDevice2,
UsbDevice3, etc. You can modify the default alias name at the time a device is plugged in, or by running Agilent Connection Expert and changing the properties of the VISA alias.
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Although the case of a VISA alias is preserved, case is ignored when the alias is used in place of the full resource string in a viOpen call. For example, UsbDevice1, usbdevice1 and USBDEVICE1 all refer to the same device.
Using the alias, a viOpen call would look something like this: viOpen( . . ., "UsbDevice1", . . . );
As you can see, this is much simpler than having to use the full resource string for a USB device.
Using the alias in a program also makes it more portable. For example, two identical USB function generators have different resource strings because they have different serial numbers. If these function generators are used in two different test systems and you use the full resource string to access the function generator in the test program, you cannot use that same program for both test systems, since the function generators’ full resource strings are different. By using the alias in the program, however, you can use the same program in both test systems. All you need to do is make sure the same alias is used for the function generator in both systems.
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Glossary
access board
The GPIB interface to which a particular device is connected.
Active Controller
See "Controller in Charge".
address
A string (or other language construct) that uniquely locates and identifies a resource. VISA defines an ASCII-based grammar that associates address strings with particular physical devices or interfaces and VISA resources.
Agilent 488
An I/O library provided in Agilent IO Libraries Suite for compatibility with existing test & measurement programs that were developed using National Instruments’ NI-488 or other similar libraries. Agilent 488 supports communication with GPIB devices and interfaces, but does not support USB, LAN, RS-232, or VXI communications.
alias
See VISA alias.
API
Application Programming Interface. The interface that a programmer sees when creating an application. For example, the VISA API consists of the sum of all of the operations, attributes, and events of each of the VISA ResourceClasses.
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Glossary
attribute
In VISA and SICL, a value that indicates the operational state of a resource. Some attributes can be changed; others are read-only.
board
A GPIB interface. It may be a physical board, an adapter (such as the
82357 USB/GPIB adapter), or a remote GPIB interface.
board descriptor
A handle, returned from ibfind, that uniquely identifies a GPIB interface (board) in Agilent 488 original API calls. Also called an interface descriptor or board unit descriptor.
board-level
Refers to Agilent 488 functions that operate on an interface (board), rather than on a device.
bus error
An error that signals failure to access an address. Bus errors occur in conjunction with low-level accesses to memory, and usually involve hardware with bus mapping capabilities. Bus errors may be caused by non-existent memory, a non-existent register, an incorrect device access, etc.
bus error handler
Software that runs when a bus error occurs.
CIC
Controller in Charge.
command bytes
GPIB commands encoded as individual bytes. Also called GPIB
commands or interface messages.
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Glossary
commander
In test-system architectures, a device that has the ability to control another device. In a specialized case, a commander may also be the device that has sole control over another device (as with the VXI
Commander/Servant hierarchy).
commander session
A session that communicates to the interface’s commander.
Commander sessions are used when an interface is in a non-Controller role.
communication channel
A communication path between a software element and a resource.
In VISA, “communication channel” is synonymous with “session.”
Every communication channel in VISA is unique.
Connection Expert
An Agilent software utility that helps you quickly establish connections between your instruments and your PC. It also helps you troubleshoot connectivity problems. Connection Expert is part of the
Agilent IO Libraries Suite product.
Controller
A device (typically a computer) used to communicate with another device or devices (typically instruments). The Controller is in charge of communications and device operation; it controls the flow of communication and performs addressing and other bus management functions.
Controller in Charge
The device currently in control of the GPIB.
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Glossary
device
A unit that receives commands from a Controller. A device is typically an instrument, but can also be a computer acting in a non-Controller role or another peripheral such as a printer or plotter.
In VISA, a device is logically represented by the association of several VISA resources.
device descriptor
A handle, returned from ibdev or ibfind, that uniquely identifies a device in Agilent 488 original API calls. Also called a device unit
descriptor.
device driver
Software code that communicates with a device: for example, a printer driver that communicates with a printer from a PC. A device driver may either communicate directly with a device by reading to and writing from registers, or it may communicate through an interface driver.
device session
A session that communicates as a Controller with a single, specific device such as an instrument.
device-level
Refers to Agilent 488 functions that operate on a device (instrument), rather than on an interface.
direct I/O
Programmatic communication with instruments not involving an instrument driver. Direct I/O may be accomplished by using an IO
Library (VISA, VISA COM, SICL, or Agilent 488) or by using direct I/O tools such as those provided by Agilent VEE.
driver
See instrument driver and device driver.
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Glossary
explorer view
The tree view within the Connection Expert window that shows all devices connected to a test system.
handler
A software routine that responds to an asynchronous event such as an
SRQ or an interrupt.
instrument
A device that accepts commands and performs a test and measurement function.
instrument driver
Software that runs on a computer to allow an application to control a particular instrument.
Interactive IO
An Agilent application that allows you to interactively send commands to instruments and read the results. Interactive IO is part of the Agilent IO Libraries Suite product.
interface
A connection and medium of communication between devices and controllers. Interfaces include mechanical, electrical, and protocol connections.
interface descriptor
A handle, returned from ibfind, that uniquely identifies a GPIB interface (board) in Agilent 488 original API calls. Also called a
board descriptor or board unit descriptor.
interface driver
Software that communicates with an interface. The interface driver also handles commands used to perform communications on an interface.
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Glossary
interface messages
GPIB commands encoded as individual bytes. Also called GPIB
commands or command bytes.
interface session
A session that communicates and controls parameters affecting an entire interface.
interrupt
An asynchronous event that requires attention and actions that are out of the normal flow of control of a program.
IO Control
The icon in the Windows notification area (usually the lower right corner of your screen). The IO Control gives you access to Agilent
I/O utilities such as Connection Expert, Agilent I/O documentation, and VISA options.
IO Libraries
Application programming interfaces (APIs) for direct I/O communication between applications and devices. There are four
Agilent IO Libraries in the Agilent IO Libraries Suite: VISA, VISA
COM, SICL, and Agilent 488.
Listener
A device that can receive data from the bus when instructed
(addressed to listen) by the System Controller.
lock
A state that prohibits other users from accessing a resource such as a device or interface.
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Glossary
logical unit
A number associated with an interface. A logical unit, in SICL and
Agilent VEE, uniquely identifies an interface. Each interface on the controller must have a unique logical unit.
mapping
An operation that returns a reference to a specified section of an address space and makes the specified range of addresses accessible to the requester. This function is independent of memory allocation.
non-Controller role
A computer is in a non-Controller role when it acts as a device communicating with a computer that is in a Controller role.
notification area
The area on the Windows taskbar where notifications are posted, typically in the lower right corner of the screen. Also called taskbar
notification area or Windows notification area.
operation
A defined action that can be performed on a resource.
primary VISA
The VISA installation that controls the visa32.dll file. The primary
VISA will be used by default in VISA applications. See also
secondary VISA.
process
An operating system component that shares a system's resources. A single-process computer system allows only a single program to execute at any given time. A multi-process computer system allows multiple programs to execute simultaneously, each in a separate process environment.
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Glossary
programming alias
See VISA alias.
refresh
In Connection Expert, the action that invokes the discovery mechanism for detecting interfaces and instruments connected to your computer. The explorer view is then refreshed to show the current, discovered state of your test system.
register
An address location that contains a value that represents the state of hardware, or that can be written into to cause hardware to perform a specified action or to enter a specified state.
resource (or resource instance)
In VISA, an implementation of a resource class (in object-oriented terms, an instance of a resource class). For example, an instrument is represented by a resource instance.
resource class
The definition of a particular resource type (a class in object-oriented terms). For example, the VISA Instrument Control resource classes define how to create a resource to control a particular capability of a device.
resource descriptor
A string, such as a VISA resource descriptor, that specifies the I/O address of a device.
SCPI
Standard Commands for Programmable Instrumentation: a standard set of commands, defined by the SCPI Consortium, to control programmable test and measurement devices in instrumentation systems.
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Glossary
secondary VISA
A VISA installation that does not install visa32.dll in the standard
VISA location. The secondary VISA installation names its VISA
DLL with a different name (agvisa32.dll) so that it can be accessed programmatically. The primary VISA will be used by default in
VISA applications. See also primary VISA.
session
VISA term for a communication channel. An instance of a communications path between a software element and a resource.
Every communication channel in VISA is unique.
SICL
Standard Instrument Control Library. SICL is an Agilent-defined
API for instrument I/O. Agilent SICL is one of the IO Libraries installed with Agilent IO Libraries Suite.
side-by-side
A side-by-side installation allows two vendors' implementations of
VISA to be used on the same computer. See also primary VISA and
secondary VISA.
SRQ
An IEEE-488 Service Request. This is an asynchronous request (an interrupt) from a remote device that requires service. In GPIB, an
SRQ is implemented by asserting the SRQ line on the GPIB. In VXI, an SRQ is implemented by sending the Request for Service True event (REQT).
Standby Controller
A device or interface that has Controller capability, but is not currently the Active Controller.
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Glossary
status byte
A byte of information returned from a remote device that shows the current state and status of the device. If the device follows IEEE-488
(GPIB) conventions, bit 6 of the status byte indicates whether the device is currently requesting service.
symbolic name
A name corresponding to a single interface. This name uniquely identifies the interface on this Controller or gateway. When there is more than one interface on the Controller or gateway, each interface must have a unique symbolic name.
System Controller
One Controller on a GPIB is the System Controller. This is a master
Controller; it has the ability to demand control and to assert the IFC
(Interface Clear) and REN (remote enable) lines.
system tray
See notification area.
Talker
A device that transmits data onto the bus when instructed (addressed to talk).
task guide
The information and logic represented in the left pane of the
Connection Expert window. The task guide provides links to actions and information that help guide you through the most common I/O configuration tasks.
taskbar notification area
See notification area.
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Glossary
test system
An entire test setup including a controller (often a PC), instruments, interfaces, software, and any remote controllers, instruments, and interfaces that are configured to be used as part of the system.
thread
An operating system object that consists of a flow of control within a process. A single process may have multiple threads, each having access to the same data space within the process. Each thread has its own stack, and all threads may execute concurrently (either on multiple processors, or by time-sharing a single processor).
ViFind32
A console application that uses the viFindRsrc and viFindNext VISA functions to enumerate all resources visible to VISA. This application is useful for verifying that all expected interfaces have been configured by Connection Expert, and that the expected devices have been attached. ViFind32 is part of the Agilent IO Libraries
Suite.
virtual instrument
A name given to the grouping of software modules (such as VISA resources with any associated or required hardware) to give them the functionality of a traditional stand-alone instrument. Within VISA, a virtual instrument is the logical grouping of any of the VISA resources. The VISA Instrument Control Resources Organizer serves as a means to group any number of any type of VISA Instrument
Control Resources within a VISA system.
VISA
Virtual Instrument Software Architecture. VISA is a standard I/O library that allows software from different vendors to run together on the same platform. Agilent VISA is part of the Agilent IO Libraries
Suite.
VISA address
A resource descriptor that can be used to open a VISA session.
141
142
Glossary
VISA alias
A string that can be used instead of a resource descriptor in VISA programs. Using VISA aliases rather than hard-coded resource descriptors makes your programs more portable. You can define
VISA aliases for your instruments in Connection Expert.
VISA COM
The VXIplug&play specification for a COM-compliant VISA I/O library and its implementation. Agilent VISA COM is part of the
Agilent IO Libraries Suite.
VISA Instrument Control Resources
The VISA definition of device-specific resource classes. VISA
Instrument Control Resources include all VISA-defined device and interface capabilities for direct, low-level instrument control.
VISA name
The prefix of a VISA address, also called the VISA interface ID.
The VISA name specifies the interface.
VISA resource manager
The part of VISA that manages resources. This management includes support for opening, closing, and finding resources, setting attributes, retrieving attributes, and generating events on resources.
VISA resource template
The part of VISA that defines the basic constraints and interface definition for the creation and use of a VISA resource. Each VISA resource must derive its interface from the VISA resource template.
VXI Resource Manager
A software utility that initializes and prepares a VXI system for use.
The VXI Resource Manager is part of the Agilent IO Libraries Suite.
Agilent VISA User’s Guide
Windows notification area
See notification area.
Glossary
Agilent VISA User’s Guide 143
Glossary
144 Agilent VISA User’s Guide
Index
A addressing addressing device sessions,
devices,
Agilent 488,
Agilent web site,
attributes setting VXI trigger lines,
VXI,
B buffers formatted I/O,
C callbacks and events,
closing device sessions,
conversion, formatted I/O,
D declarations file,
default resource manager,
device sessions addressing,
closing,
opening,
E enable events for callback,
enable events for queuing,
event handler,
events callback,
enable for callback,
enable for queuing,
handlers,
hardware triggers,
interrupts,
queuing,
SRQs,
wait on event,
examples
Checking Instrument Errors,
Determining Window
Mapping,
Enabling a Hardware Trigger
Event,
,
Example C/C++ Source Code,
Exception Events,
Exclusive Lock,
GPIB-VXI (E1406A)
Interface,
Installing an Event Handler,
MEMACC Resource
Program,
Opening a Device Session,
Opening a Resource Session,
Opening a Session,
Printing Error Code,
Reading a VISA Attribute,
Receiving Data From a
Session,
Searching VXI Interface for
Resources,
SRQ Callback,
Trigger Callback,
Trigger Event Queuing,
Using Non-Formatted I/O
Functions,
Using the Callback Method,
Using the GPIB-VXI Interface
(Low-Level) Memory
Functions,
Using the Queuing Method,
Using the VXI Interface
(High-Level) Memory
Functions,
Using the VXI Interface
(Low-Level) Memory
Functions,
Using viPeek16,
VXI (E8491B) Interfaces,
F finding resources,
formatted I/O buffers,
conversion,
G
GPIB interfaces, introduction,
GPIB-VXI attributes,
high-level memory functions,
low-level memory functions,
register programming,
,
setting trigger lines,
GPIB-VXI interfaces overview,
H handlers,
event,
installing,
prototype,
hardware triggers and events,
header file, visa.h,
high-level memory functions,
high-level memory functions for
VXI,
I installing handlers,
interrupts and events,
Agilent VISA User’s Guide 145
Index
L
LAN hardware architecture,
interfaces overview,
locking,
locks using,
low-level memory functions,
low-level memory functions for
VXI,
M
MEMACC attribute descriptions,
memory functions, high-level,
memory functions, low-level,
N
NI-488,
non-formatted I/O mixing with formatted I/O,
O opening sessions,
overview, guide,
Q queuing and events,
R raw I/O,
register programming high-level memory functions,
low-level memory functions,
resource manager,
resource manager session,
resources finding,
locking,
S sample code
searching for resources,
sessions device,
opening,
resource manager,
SRQs,
starting the resource manager,
T timeout,
trigger lines,
triggers and events,
U
USB communicating with instruments using VISA,
interfaces overview,
V
VISA description,
visa.h header file,
VXI attributes,
high-level memory functions,
low-level memory functions,
register programming,
,
setting trigger lines,
W wait on event,
web site, Agilent,
146 Agilent VISA User’s Guide
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Table of contents
- 3 Agilent VISA User’s Guide
- 7 Introduction
- 8 What’s in This Guide?
- 9 VISA Overview
- 9 Using VISA, VISA COM, and SICL
- 10 VISA Support
- 10 VISA Documentation
- 12 Contacting Agilent
- 13 Building a VISA Application in Windows
- 14 Building a VISA Program (C/C++)
- 14 Compiling and Linking VISA Programs (C/C++)
- 14 Linking to VISA Libraries
- 14 Microsoft Visual C++ Version 6.0 Development Environment
- 15 Microsoft Visual Studio .NET
- 15 Sample VISA Program (C/C++)
- 15 Sample C/C++ Program Source Code
- 17 C/C++ Sample Program Contents
- 18 Building a VISA Program (Visual Basic)
- 18 Visual Basic Programming Considerations
- 18 Required Module for a Visual Basic VISA Program
- 18 Adding the visa32.bas File to Your Project
- 18 VISA Limitations in Visual Basic
- 19 Format Conversion Commands
- 19 Numeric Arrays
- 20 Strings
- 20 Sample VISA Program (Visual Basic)
- 20 Steps to Running the Program
- 21 Sample Program Source Code
- 23 Sample Program Contents
- 25 Logging Error Messages
- 25 Using the Event Viewer
- 25 Using the Debug Window
- 27 Programming with VISA
- 28 VISA Resources and Attributes
- 28 VISA Resources
- 29 VISA Attributes
- 29 Example: Reading a VISA Attribute
- 30 Using Sessions
- 30 Including the VISA Declarations File (C/C++)
- 30 Adding the visa32.bas File (Visual Basic)
- 31 Opening a Session
- 31 Resource Manager Sessions
- 31 Resource Sessions
- 32 Example: Opening a Resource Session
- 33 Addressing a Session
- 36 Example: Opening a Session
- 37 Closing a Session
- 37 Searching for Resources
- 39 Example: Searching the VXI Interface for Resources
- 40 Sending I/O Commands
- 40 Types of I/O
- 41 Formatted I/O Conversion
- 41 Example: Receiving Data From a Session
- 42 Formatted I/O Buffers
- 43 Example: Sending and Receiving Formatted I/O
- 44 Using Non-Formatted I/O
- 44 Non-Formatted I/O Functions
- 44 Example: Using Non-Formatted I/O Functions
- 46 Using Events and Handlers
- 46 Events and Attributes
- 46 Event Notification
- 47 Events that can be Enabled
- 54 Example: Reading Event Attributes
- 54 Using the Callback Method
- 54 Example: Using the Callback Method
- 55 Installing Handlers
- 56 Example: Installing an Event Handler
- 56 Writing the Handler
- 56 Enabling Events
- 57 Example: Enabling a Hardware Trigger Event
- 58 Example: Trigger Callback
- 60 Example: SRQ Callback
- 62 Using the Queuing Method
- 63 Example: Using the Queuing Method
- 63 Enabling Events
- 64 Example: Enabling a Hardware Trigger Event
- 64 Wait on the Event
- 65 Example: Wait on Event for SRQ
- 65 Example: Trigger Event Queuing
- 68 Trapping Errors
- 68 Trapping Errors
- 68 Example: Checking for VI_SUCCESS
- 68 Example: Printing Error Code
- 69 Example: Checking Instrument Errors
- 69 Exception Events
- 70 Exception Handling Model
- 71 Using the VI_EVENT_EXCEPTION Event
- 71 Example: Exception Events
- 74 Using Locks
- 74 Lock Functions
- 74 viLock/viUnlock Functions
- 75 VISA Lock Types
- 76 Example: Exclusive Lock
- 77 Example: Shared Lock
- 79 Programming via GPIB and VXI
- 80 GPIB and VXI Interfaces Overview
- 80 General Interface Information
- 80 What is an I/O Interface?
- 80 VXI Device Types
- 81 GPIB Interfaces Overview
- 82 Example: GPIB (82350) Interface
- 84 VXI Interfaces Overview
- 84 Example: VXI (E8491B) Interfaces
- 85 GPIB-VXI Interfaces Overview
- 86 Example: GPIB-VXI (E1406A) Interface
- 88 Using High-Level Memory Functions
- 88 Programming the Registers
- 88 High-Level Memory Functions
- 89 Using viIn and viOut
- 90 Using viMoveIn and viMoveOut
- 90 High-Level Memory Functions: Sample Programs
- 91 Sample: Using VXI Interface (High-Level) Memory Functions
- 92 Sample: Using GPIB-VXI Interface (High-Level) Memory Functions
- 94 Using Low-Level Memory Functions
- 94 Programming the Registers
- 94 Low-Level Memory Functions
- 95 Mapping Memory Space
- 96 Reading and Writing to Device Registers
- 96 Sample: Using viPeek16
- 96 Unmapping Memory Space
- 97 Low-Level Memory Functions: Code Samples
- 97 Sample: Using the VXI Interface (Low-Level) Memory Functions
- 98 Sample: Using the GPIB-VXI Interface (Low-Level) Memory Functions
- 100 Using Low/High-Level Memory I/O Methods
- 100 Using Low-Level viPeek/viPoke
- 101 Using High-Level viIn/viOut
- 101 Using High-Level viMoveIn/viMoveOut
- 102 Sample: Using VXI Memory I/O
- 106 Using the Memory Access Resource
- 106 Memory I/O Services
- 106 High-Level Memory I/O Services
- 106 Low-Level Memory I/O Services
- 107 Sample: MEMACC Resource Program
- 109 MEMACC Attribute Descriptions
- 109 Generic MEMACC Attributes
- 110 VXI and GPIB-VXI Specific MEMACC Attributes
- 111 GPIB-VXI Specific MEMACC Attributes
- 112 MEMACC Resource Event Attribute
- 113 Using VXI-Specific Attributes
- 113 Using the Map Address as a Pointer
- 113 VI_ATTR_WIN_ACCESS Settings
- 114 Sample: Determining Window Mapping
- 114 Setting the VXI Trigger Line
- 117 Programming via LAN
- 118 LAN and Remote Interfaces Overview
- 118 Direct LAN Connection versus Remote IO Server/Client Connection
- 118 Remote IO Server/Client Architecture
- 118 Client/Server Model
- 119 Gateway Operation
- 121 Addressing LAN-Connected Devices
- 121 Using the TCPIP Interface Type for LAN Access
- 123 Addressing a Session Using the TCPIP Interface Type
- 124 Using a Remote Interface for LAN Access
- 124 Remote Serial Interface (ASRL VISA LAN Client)
- 124 Remote GPIB Interface (GPIB VISA LAN Client)
- 125 Remote USB Interface (USB VISA LAN Client)
- 125 Addressing a Session Using a Remote Interface
- 127 Programming via USB
- 128 USB Interfaces Overview
- 129 Communicating with a USB Instrument Using VISA
- 131 Glossary
- 131 access board
- 131 Active Controller
- 131 address
- 131 Agilent 488
- 131 alias
- 131 API
- 132 attribute
- 132 board
- 132 board descriptor
- 132 board-level
- 132 bus error
- 132 bus error handler
- 132 CIC
- 132 command bytes
- 133 commander
- 133 commander session
- 133 communication channel
- 133 Connection Expert
- 133 Controller
- 133 Controller in Charge
- 134 device
- 134 device descriptor
- 134 device driver
- 134 device session
- 134 device-level
- 134 direct I/O
- 134 driver
- 135 explorer view
- 135 handler
- 135 instrument
- 135 instrument driver
- 135 Interactive IO
- 135 interface
- 135 interface descriptor
- 135 interface driver
- 136 interface messages
- 136 interface session
- 136 interrupt
- 136 IO Control
- 136 IO Libraries
- 136 Listener
- 136 lock
- 137 logical unit
- 137 mapping
- 137 non-Controller role
- 137 notification area
- 137 operation
- 137 primary VISA
- 137 process
- 138 programming alias
- 138 refresh
- 138 register
- 138 resource (or resource instance)
- 138 resource class
- 138 resource descriptor
- 138 SCPI
- 139 secondary VISA
- 139 session
- 139 SICL
- 139 side-by-side
- 139 SRQ
- 139 Standby Controller
- 140 status byte
- 140 symbolic name
- 140 System Controller
- 140 system tray
- 140 Talker
- 140 task guide
- 140 taskbar notification area
- 141 test system
- 141 thread
- 141 ViFind32
- 141 virtual instrument
- 141 VISA
- 141 VISA address
- 142 VISA alias
- 142 VISA COM
- 142 VISA Instrument Control Resources
- 142 VISA name
- 142 VISA resource manager
- 142 VISA resource template
- 142 VXI Resource Manager
- 143 Windows notification area
- 145 Index