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<!-- Copyright (C) 2003 Red Hat, Inc. --> <!-- This material may be distributed only subject to the terms --> <!-- and conditions set forth in the Open Publication License, v1.0 --> <!-- or later (the latest version is presently available at --> <!-- http://www.opencontent.org/openpub/). --> <!-- Distribution of the work or derivative of the work in any --> <!-- standard (paper) book form is prohibited unless prior --> <!-- permission is obtained from the copyright holder. --> <HTML ><HEAD ><TITLE >Interrupt Handling</TITLE ><meta name="MSSmartTagsPreventParsing" content="TRUE"> <META NAME="GENERATOR" CONTENT="Modular DocBook HTML Stylesheet Version 1.76b+ "><LINK REL="HOME" TITLE="eCos Reference Manual" HREF="ecos-ref.html"><LINK REL="UP" TITLE="The eCos Kernel" HREF="kernel.html"><LINK REL="PREVIOUS" TITLE="Scheduler Control" HREF="kernel-schedcontrol.html"><LINK REL="NEXT" TITLE="Kernel Real-time Characterization" HREF="kernel-characterization.html"></HEAD ><BODY CLASS="REFENTRY" BGCOLOR="#FFFFFF" TEXT="#000000" LINK="#0000FF" VLINK="#840084" ALINK="#0000FF" ><DIV CLASS="NAVHEADER" ><TABLE SUMMARY="Header navigation table" WIDTH="100%" BORDER="0" CELLPADDING="0" CELLSPACING="0" ><TR ><TH COLSPAN="3" ALIGN="center" >eCos Reference Manual</TH ></TR ><TR ><TD WIDTH="10%" ALIGN="left" VALIGN="bottom" ><A HREF="kernel-schedcontrol.html" ACCESSKEY="P" >Prev</A ></TD ><TD WIDTH="80%" ALIGN="center" VALIGN="bottom" ></TD ><TD WIDTH="10%" ALIGN="right" VALIGN="bottom" ><A HREF="kernel-characterization.html" ACCESSKEY="N" >Next</A ></TD ></TR ></TABLE ><HR ALIGN="LEFT" WIDTH="100%"></DIV ><H1 ><A NAME="KERNEL-INTERRUPTS">Interrupt Handling</H1 ><DIV CLASS="REFNAMEDIV" ><A NAME="AEN1834" ></A ><H2 >Name</H2 >cyg_interrupt_create, cyg_interrupt_delete, cyg_interrupt_attach, cyg_interrupt_detach, cyg_interrupt_configure, cyg_interrupt_acknowledge, cyg_interrupt_enable, cyg_interrupt_disable, cyg_interrupt_mask, cyg_interrupt_mask_intunsafe, cyg_interrupt_unmask, cyg_interrupt_unmask_intunsafe, cyg_interrupt_set_cpu, cyg_interrupt_get_cpu, cyg_interrupt_get_vsr, cyg_interrupt_set_vsr -- Manage interrupt handlers</DIV ><DIV CLASS="REFSYNOPSISDIV" ><A NAME="AEN1852"><H2 >Synopsis</H2 ><DIV CLASS="FUNCSYNOPSIS" ><A NAME="AEN1853"><P ></P ><TABLE BORDER="5" BGCOLOR="#E0E0F0" WIDTH="70%" ><TR ><TD ><PRE CLASS="FUNCSYNOPSISINFO" >#include <cyg/kernel/kapi.h> </PRE ></TD ></TR ></TABLE ><P ><CODE ><CODE CLASS="FUNCDEF" >void cyg_interrupt_create</CODE >(cyg_vector_t vector, cyg_priority_t priority, cyg_addrword_t data, cyg_ISR_t* isr, cyg_DSR_t* dsr, cyg_handle_t* handle, cyg_interrupt* intr);</CODE ></P ><P ><CODE ><CODE CLASS="FUNCDEF" >void cyg_interrupt_delete</CODE >(cyg_handle_t interrupt);</CODE ></P ><P ><CODE ><CODE CLASS="FUNCDEF" >void cyg_interrupt_attach</CODE >(cyg_handle_t interrupt);</CODE ></P ><P ><CODE ><CODE CLASS="FUNCDEF" >void cyg_interrupt_detach</CODE >(cyg_handle_t interrupt);</CODE ></P ><P ><CODE ><CODE CLASS="FUNCDEF" >void cyg_interrupt_configure</CODE >(cyg_vector_t vector, cyg_bool_t level, cyg_bool_t up);</CODE ></P ><P ><CODE ><CODE CLASS="FUNCDEF" >void cyg_interrupt_acknowledge</CODE >(cyg_vector_t vector);</CODE ></P ><P ><CODE ><CODE CLASS="FUNCDEF" >void cyg_interrupt_disable</CODE >(void);</CODE ></P ><P ><CODE ><CODE CLASS="FUNCDEF" >void cyg_interrupt_enable</CODE >(void);</CODE ></P ><P ><CODE ><CODE CLASS="FUNCDEF" >void cyg_interrupt_mask</CODE >(cyg_vector_t vector);</CODE ></P ><P ><CODE ><CODE CLASS="FUNCDEF" >void cyg_interrupt_mask_intunsafe</CODE >(cyg_vector_t vector);</CODE ></P ><P ><CODE ><CODE CLASS="FUNCDEF" >void cyg_interrupt_unmask</CODE >(cyg_vector_t vector);</CODE ></P ><P ><CODE ><CODE CLASS="FUNCDEF" >void cyg_interrupt_unmask_intunsafe</CODE >(cyg_vector_t vector);</CODE ></P ><P ><CODE ><CODE CLASS="FUNCDEF" >void cyg_interrupt_set_cpu</CODE >(cyg_vector_t vector, cyg_cpu_t cpu);</CODE ></P ><P ><CODE ><CODE CLASS="FUNCDEF" >cyg_cpu_t cyg_interrupt_get_cpu</CODE >(cyg_vector_t vector);</CODE ></P ><P ><CODE ><CODE CLASS="FUNCDEF" >void cyg_interrupt_get_vsr</CODE >(cyg_vector_t vector, cyg_VSR_t** vsr);</CODE ></P ><P ><CODE ><CODE CLASS="FUNCDEF" >void cyg_interrupt_set_vsr</CODE >(cyg_vector_t vector, cyg_VSR_t* vsr);</CODE ></P ><P ></P ></DIV ></DIV ><DIV CLASS="REFSECT1" ><A NAME="KERNEL-INTERRUPTS-DESCRIPTION" ></A ><H2 >Description</H2 ><P >The kernel provides an interface for installing interrupt handlers and controlling when interrupts occur. This functionality is used primarily by eCos device drivers and by any application code that interacts directly with hardware. However in most cases it is better to avoid using this kernel functionality directly, and instead the device driver API provided by the common HAL package should be used. Use of the kernel package is optional, and some applications such as RedBoot work with no need for multiple threads or synchronization primitives. Any code which calls the kernel directly rather than the device driver API will not function in such a configuration. When the kernel package is present the device driver API is implemented as <TT CLASS="LITERAL" >#define</TT >'s to the equivalent kernel calls, otherwise it is implemented inside the common HAL package. The latter implementation can be simpler than the kernel one because there is no need to consider thread preemption and similar issues. </P ><P >The exact details of interrupt handling vary widely between architectures. The functionality provided by the kernel abstracts away from many of the details of the underlying hardware, thus simplifying application development. However this is not always successful. For example, if some hardware does not provide any support at all for masking specific interrupts then calling <TT CLASS="FUNCTION" >cyg_interrupt_mask</TT > may not behave as intended: instead of masking just the one interrupt source it might disable all interrupts, because that is as close to the desired behaviour as is possible given the hardware restrictions. Another possibility is that masking a given interrupt source also affects all lower-priority interrupts, but still allows higher-priority ones. The documentation for the appropriate HAL packages should be consulted for more information about exactly how interrupts are handled on any given hardware. The HAL header files will also contain useful information. </P ></DIV ><DIV CLASS="REFSECT1" ><A NAME="KERNEL-INTERRUPTS-HANDLERS" ></A ><H2 >Interrupt Handlers</H2 ><P >Interrupt handlers are created by a call to <TT CLASS="FUNCTION" >cyg_interrupt_create</TT >. This takes the following arguments: </P ><P ></P ><DIV CLASS="VARIABLELIST" ><DL ><DT >cyg_vector_t <TT CLASS="PARAMETER" ><I >vector</I ></TT ></DT ><DD ><P >The interrupt vector, a small integer, identifies the specific interrupt source. The appropriate hardware documentation or HAL header files should be consulted for details of which vector corresponds to which device. </P ></DD ><DT >cyg_priority_t <TT CLASS="PARAMETER" ><I >priority</I ></TT ></DT ><DD ><P >Some hardware may support interrupt priorities, where a low priority interrupt handler can in turn be interrupted by a higher priority one. Again hardware-specific documentation should be consulted for details about what the valid interrupt priority levels are. </P ></DD ><DT >cyg_addrword_t <TT CLASS="PARAMETER" ><I >data</I ></TT ></DT ><DD ><P >When an interrupt occurs eCos will first call the associated interrupt service routine or ISR, then optionally a deferred service routine or DSR. The <TT CLASS="PARAMETER" ><I >data</I ></TT > argument to <TT CLASS="FUNCTION" >cyg_interrupt_create</TT > will be passed to both these functions. Typically it will be a pointer to some data structure. </P ></DD ><DT >cyg_ISR_t <TT CLASS="PARAMETER" ><I >isr</I ></TT ></DT ><DD ><P >When an interrupt occurs the hardware will transfer control to the appropriate vector service routine or VSR, which is usually provided by eCos. This performs any appropriate processing, for example to work out exactly which interrupt occurred, and then as quickly as possible transfers control the installed ISR. An ISR is a C function which takes the following form: </P ><TABLE BORDER="5" BGCOLOR="#E0E0F0" WIDTH="70%" ><TR ><TD ><PRE CLASS="PROGRAMLISTING" >cyg_uint32 isr_function(cyg_vector_t vector, cyg_addrword_t data) { cyg_bool_t dsr_required = 0; … return dsr_required ? CYG_ISR_CALL_DSR : CYG_ISR_HANDLED; } </PRE ></TD ></TR ></TABLE ><P >The first argument identifies the particular interrupt source, especially useful if there multiple instances of a given device and a single ISR can be used for several different interrupt vectors. The second argument is the <TT CLASS="PARAMETER" ><I >data</I ></TT > field passed to <TT CLASS="FUNCTION" >cyg_interrupt_create</TT >, usually a pointer to some data structure. The exact conditions under which an ISR runs will depend partly on the hardware and partly on configuration options. Interrupts may currently be disabled globally, especially if the hardware does not support interrupt priorities. Alternatively interrupts may be enabled such that higher priority interrupts are allowed through. The ISR may be running on a separate interrupt stack, or on the stack of whichever thread was running at the time the interrupt happened. </P ><P >A typical ISR will do as little work as possible, just enough to meet the needs of the hardware and then acknowledge the interrupt by calling <TT CLASS="FUNCTION" >cyg_interrupt_acknowledge</TT >. This ensures that interrupts will be quickly reenabled, so higher priority devices can be serviced. For some applications there may be one device which is especially important and whose ISR can take much longer than normal. However eCos device drivers usually will not assume that they are especially important, so their ISRs will be as short as possible. </P ><P >The return value of an ISR is normally one of <TT CLASS="LITERAL" >CYG_ISR_CALL_DSR</TT > or <TT CLASS="LITERAL" >CYG_ISR_HANDLED</TT >. The former indicates that further processing is required at DSR level, and the interrupt handler's DSR will be run as soon as possible. The latter indicates that the interrupt has been fully handled and no further effort is required. </P ><P >An ISR is allowed to make very few kernel calls. It can manipulate the interrupt mask, and on SMP systems it can use spinlocks. However an ISR must not make higher-level kernel calls such as posting to a semaphore, instead any such calls must be made from the DSR. This avoids having to disable interrupts throughout the kernel and thus improves interrupt latency. </P ></DD ><DT >cyg_DSR_t <TT CLASS="PARAMETER" ><I >dsr</I ></TT ></DT ><DD ><P >If an interrupt has occurred and the ISR has returned a value <TT CLASS="LITERAL" >CYG_ISR_CALL_DSR</TT >, the system will call the deferred service routine or DSR associated with this interrupt handler. If the scheduler is not currently locked then the DSR will run immediately. However if the interrupted thread was in the middle of a kernel call and had locked the scheduler, then the DSR will be deferred until the scheduler is again unlocked. This allows the DSR to make certain kernel calls safely, for example posting to a semaphore or signalling a condition variable. A DSR is a C function which takes the following form: </P ><TABLE BORDER="5" BGCOLOR="#E0E0F0" WIDTH="70%" ><TR ><TD ><PRE CLASS="PROGRAMLISTING" >void dsr_function(cyg_vector_t vector, cyg_ucount32 count, cyg_addrword_t data) { } </PRE ></TD ></TR ></TABLE ><P >The first argument identifies the specific interrupt that has caused the DSR to run. The second argument indicates the number of these interrupts that have occurred and for which the ISR requested a DSR. Usually this will be <TT CLASS="LITERAL" >1</TT >, unless the system is suffering from a very heavy load. The third argument is the <TT CLASS="PARAMETER" ><I >data</I ></TT > field passed to <TT CLASS="FUNCTION" >cyg_interrupt_create</TT >. </P ></DD ><DT >cyg_handle_t* <TT CLASS="PARAMETER" ><I >handle</I ></TT ></DT ><DD ><P >The kernel will return a handle to the newly created interrupt handler via this argument. Subsequent operations on the interrupt handler such as attaching it to the interrupt source will use this handle. </P ></DD ><DT >cyg_interrupt* <TT CLASS="PARAMETER" ><I >intr</I ></TT ></DT ><DD ><P >This provides the kernel with an area of memory for holding this interrupt handler and associated data. </P ></DD ></DL ></DIV ><P >The call to <TT CLASS="FUNCTION" >cyg_interrupt_create</TT > simply fills in a kernel data structure. A typical next step is to call <TT CLASS="FUNCTION" >cyg_interrupt_attach</TT > using the handle returned by the create operation. This makes it possible to have several different interrupt handlers for a given vector, attaching whichever one is currently appropriate. Replacing an interrupt handler requires a call to <TT CLASS="FUNCTION" >cyg_interrupt_detach</TT >, followed by another call to <TT CLASS="FUNCTION" >cyg_interrupt_attach</TT > for the replacement handler. <TT CLASS="FUNCTION" >cyg_interrupt_delete</TT > can be used if an interrupt handler is no longer required. </P ><P >Some hardware may allow for further control over specific interrupts, for example whether an interrupt is level or edge triggered. Any such hardware functionality can be accessed using <TT CLASS="FUNCTION" >cyg_interrupt_configure</TT >: the <TT CLASS="PARAMETER" ><I >level</I ></TT > argument selects between level versus edge triggered; the <TT CLASS="PARAMETER" ><I >up</I ></TT > argument selects between high and low level, or between rising and falling edges. </P ><P >Usually interrupt handlers are created, attached and configured during system initialization, while global interrupts are still disabled. On most hardware it will also be necessary to call <TT CLASS="FUNCTION" >cyg_interrupt_unmask</TT >, since the sensible default for interrupt masking is to ignore any interrupts for which no handler is installed. </P ></DIV ><DIV CLASS="REFSECT1" ><A NAME="KERNEL-INTERRUPTS-ENABLE" ></A ><H2 >Controlling Interrupts</H2 ><P >eCos provides two ways of controlling whether or not interrupts happen. It is possible to disable and reenable all interrupts globally, using <TT CLASS="FUNCTION" >cyg_interrupt_disable</TT > and <TT CLASS="FUNCTION" >cyg_interrupt_enable</TT >. Typically this works by manipulating state inside the cpu itself, for example setting a flag in a status register or executing special instructions. Alternatively it may be possible to mask a specific interrupt source by writing to one or to several interrupt mask registers. Hardware-specific documentation should be consulted for the exact details of how interrupt masking works, because a full implementation is not possible on all hardware. </P ><P >The primary use for these functions is to allow data to be shared between ISRs and other code such as DSRs or threads. If both a thread and an ISR need to manipulate either a data structure or the hardware itself, there is a possible conflict if an interrupt happens just when the thread is doing such manipulation. Problems can be avoided by the thread either disabling or masking interrupts during the critical region. If this critical region requires only a few instructions then usually it is more efficient to disable interrupts. For larger critical regions it may be more appropriate to use interrupt masking, allowing other interrupts to occur. There are other uses for interrupt masking. For example if a device is not currently being used by the application then it may be desirable to mask all interrupts generated by that device. </P ><P >There are two functions for masking a specific interrupt source, <TT CLASS="FUNCTION" >cyg_interrupt_mask</TT > and <TT CLASS="FUNCTION" >cyg_interrupt_mask_intunsafe</TT >. On typical hardware masking an interrupt is not an atomic operation, so if two threads were to perform interrupt masking operations at the same time there could be problems. <TT CLASS="FUNCTION" >cyg_interrupt_mask</TT > disables all interrupts while it manipulates the interrupt mask. In situations where interrupts are already know to be disabled, <TT CLASS="FUNCTION" >cyg_interrupt_mask_intunsafe</TT > can be used instead. There are matching functions <TT CLASS="FUNCTION" >cyg_interrupt_unmask</TT > and <TT CLASS="FUNCTION" >cyg_interrupt_unmask_intsafe</TT >. </P ></DIV ><DIV CLASS="REFSECT1" ><A NAME="KERNEL-INTERRUPTS-SMP" ></A ><H2 >SMP Support</H2 ><P >On SMP systems the kernel provides an additional two functions related to interrupt handling. <TT CLASS="FUNCTION" >cyg_interrupt_set_cpu</TT > specifies that a particular hardware interrupt should always be handled on one specific processor in the system. In other words when the interrupt triggers it is only that processor which detects it, and it is only on that processor that the VSR and ISR will run. If a DSR is requested then it will also run on the same CPU. The function <TT CLASS="FUNCTION" >cyg_interrupt_get_cpu</TT > can be used to find out which interrupts are handled on which processor. </P ></DIV ><DIV CLASS="REFSECT1" ><A NAME="KERNEL-INTERRUPTS-VSR" ></A ><H2 >VSR Support</H2 ><P >When an interrupt occurs the hardware will transfer control to a piece of code known as the VSR, or Vector Service Routine. By default this code is provided by eCos. Usually it is written in assembler, but on some architectures it may be possible to implement VSRs in C by specifying an interrupt attribute. Compiler documentation should be consulted for more information on this. The default eCos VSR will work out which ISR function should process the interrupt, and set up a C environment suitable for this ISR. </P ><P >For some applications it may be desirable to replace the default eCos VSR and handle some interrupts directly. This minimizes interrupt latency, but it requires application developers to program at a lower level. Usually the best way to write a custom VSR is to copy the existing one supplied by eCos and then make appropriate modifications. The function <TT CLASS="FUNCTION" >cyg_interrupt_get_vsr</TT > can be used to get hold of the current VSR for a given interrupt vector, allowing it to be restored if the custom VSR is no longer required. <TT CLASS="FUNCTION" >cyg_interrupt_set_vsr</TT > can be used to install a replacement VSR. Usually the <TT CLASS="PARAMETER" ><I >vsr</I ></TT > argument will correspond to an exported label in an assembler source file. </P ></DIV ><DIV CLASS="REFSECT1" ><A NAME="KERNEL-INTERRUPTS-CONTEXT" ></A ><H2 >Valid contexts</H2 ><P >In a typical configuration interrupt handlers are created and attached during system initialization, and never detached or deleted. However it is possible to perform these operations at thread level, if desired. Similarly <TT CLASS="FUNCTION" >cyg_interrupt_configure</TT >, <TT CLASS="FUNCTION" >cyg_interrupt_set_vsr</TT >, and <TT CLASS="FUNCTION" >cyg_interrupt_set_cpu</TT > are usually called only during system initialization, but on typical hardware may be called at any time. <TT CLASS="FUNCTION" >cyg_interrupt_get_vsr</TT > and <TT CLASS="FUNCTION" >cyg_interrupt_get_cpu</TT > may be called at any time. </P ><P >The functions for enabling, disabling, masking and unmasking interrupts can be called in any context, when appropriate. It is the responsibility of application developers to determine when the use of these functions is appropriate. </P ></DIV ><DIV CLASS="NAVFOOTER" ><HR ALIGN="LEFT" WIDTH="100%"><TABLE SUMMARY="Footer navigation table" WIDTH="100%" BORDER="0" CELLPADDING="0" CELLSPACING="0" ><TR ><TD WIDTH="33%" ALIGN="left" VALIGN="top" ><A HREF="kernel-schedcontrol.html" ACCESSKEY="P" >Prev</A ></TD ><TD WIDTH="34%" ALIGN="center" VALIGN="top" ><A HREF="ecos-ref.html" ACCESSKEY="H" >Home</A ></TD ><TD WIDTH="33%" ALIGN="right" VALIGN="top" ><A HREF="kernel-characterization.html" ACCESSKEY="N" >Next</A ></TD ></TR ><TR ><TD WIDTH="33%" ALIGN="left" VALIGN="top" >Scheduler Control</TD ><TD WIDTH="34%" ALIGN="center" VALIGN="top" ><A HREF="kernel.html" ACCESSKEY="U" >Up</A ></TD ><TD WIDTH="33%" ALIGN="right" VALIGN="top" >Kernel Real-time Characterization</TD ></TR ></TABLE ></DIV ></BODY ></HTML >
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