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><H1

><A

NAME="KERNEL-THREAD-CREATE">Thread creation</H1

><DIV

CLASS="REFNAMEDIV"

><A

NAME="AEN256"

></A

><H2

>Name</H2

>cyg_thread_create&nbsp;--&nbsp;Create a new thread</DIV

><DIV

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><A

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>Synopsis</H2

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><A

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><TD

><PRE

CLASS="FUNCSYNOPSISINFO"

>#include <cyg/kernel/kapi.h>

        </PRE

></TD

></TR

></TABLE

><P

><CODE

><CODE

CLASS="FUNCDEF"

>void cyg_thread_create</CODE

>(cyg_addrword_t sched_info, cyg_thread_entry_t* entry, cyg_addrword_t entry_data, char* name, void* stack_base, cyg_ucount32 stack_size, cyg_handle_t* handle, cyg_thread* thread);</CODE

></P

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><DIV

CLASS="REFSECT1"

><A

NAME="KERNEL-THREAD-CREATE-DESCRIPTION"

></A

><H2

>Description</H2

><P

>The <TT

CLASS="FUNCTION"

>cyg_thread_create</TT

> function allows application

code and eCos packages to create new threads. In many applications

this only happens during system initialization and all required data

is allocated statically.  However additional threads can be created at

any time, if necessary. A newly created thread is always in suspended

state and will not start running until it has been resumed via a call

to <TT

CLASS="FUNCTION"

>cyg_thread_resume</TT

>. Also, if threads are

created during system initialization then they will not start running

until the eCos scheduler has been started.

      </P

><P

>The <TT

CLASS="PARAMETER"

><I

>name</I

></TT

> argument is used

primarily for debugging purposes, making it easier to keep track of

which <SPAN

CLASS="STRUCTNAME"

>cyg_thread</SPAN

> structure is associated with

which application-level thread. The kernel configuration option

<TT

CLASS="VARNAME"

>CYGVAR_KERNEL_THREADS_NAME</TT

> controls whether or not

this name is actually used.

      </P

><P

>On creation each thread is assigned a unique handle, and this will be

stored in the location pointed at by the <TT

CLASS="PARAMETER"

><I

>handle</I

></TT

> argument. Subsequent operations on

this thread including the required

<TT

CLASS="FUNCTION"

>cyg_thread_resume</TT

> should use this handle to

identify the thread.

      </P

><P

>The kernel requires a small amount of space for each thread, in the

form of a <SPAN

CLASS="STRUCTNAME"

>cyg_thread</SPAN

> data structure, to hold

information such as the current state of that thread. To avoid any

need for dynamic memory allocation within the kernel this space has to

be provided by higher-level code, typically in the form of a static

variable. The <TT

CLASS="PARAMETER"

><I

>thread</I

></TT

> argument

provides this space.

      </P

></DIV

><DIV

CLASS="REFSECT1"

><A

NAME="KERNEL-THREAD-CREATE-ENTRY"

></A

><H2

>Thread Entry Point</H2

><P

>The entry point for a thread takes the form:

      </P

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>void

thread_entry_function(cyg_addrword_t data)

{

    …

}

      </PRE

></TD

></TR

></TABLE

><P

>The second argument to <TT

CLASS="FUNCTION"

>cyg_thread_create</TT

> is a

pointer to such a function. The third argument <TT

CLASS="PARAMETER"

><I

>entry_data</I

></TT

> is used to pass additional

data to the function. Typically this takes the form of a pointer to

some static data, or a small integer, or <TT

CLASS="LITERAL"

>0</TT

> if the

thread does not require any additional data.

      </P

><P

>If the thread entry function ever returns then this is equivalent to

the thread calling <TT

CLASS="FUNCTION"

>cyg_thread_exit</TT

>. Even though

the thread will no longer run again, it remains registered with the

scheduler. If the application needs to re-use the

<SPAN

CLASS="STRUCTNAME"

>cyg_thread</SPAN

> data structure then a call to

<TT

CLASS="FUNCTION"

>cyg_thread_delete</TT

> is required first.

      </P

></DIV

><DIV

CLASS="REFSECT1"

><A

NAME="KERNEL-THREAD-CREATE-PRIORITIES"

></A

><H2

>Thread Priorities</H2

><P

>The <TT

CLASS="PARAMETER"

><I

>sched_info</I

></TT

> argument

provides additional information to the scheduler. The exact details

depend on the scheduler being used. For the bitmap and mlqueue

schedulers it is a small integer, typically in the range 0 to 31, with

only by the system's idle thread. The exact number of priorities is

controlled by the kernel configuration option

<TT

CLASS="VARNAME"

>CYGNUM_KERNEL_SCHED_PRIORITIES</TT

>.

      </P

><P

>It is the responsibility of the application developer to be aware of

the various threads in the system, including those created by eCos

packages, and to ensure that all threads run at suitable priorities.

For threads created by other packages the documentation provided by

those packages should indicate any requirements.

      </P

><P

>The functions <TT

CLASS="FUNCTION"

>cyg_thread_set_priority</TT

>,

<TT

CLASS="FUNCTION"

>cyg_thread_get_priority</TT

>, and

<TT

CLASS="FUNCTION"

>cyg_thread_get_current_priority</TT

> can be used to

manipulate a thread's priority.

      </P

></DIV

><DIV

CLASS="REFSECT1"

><A

NAME="KERNEL-THREAD-CREATE-STACK"

></A

><H2

>Stacks and Stack Sizes</H2

><P

>Each thread needs its own stack for local variables and to keep track

of function calls and returns. Again it is expected that this stack is

provided by the calling code, usually in the form of static data, so

that the kernel does not need any dynamic memory allocation

facilities. <TT

CLASS="FUNCTION"

>cyg_thread_create</TT

> takes two arguments

related to the stack, a pointer to the base of the stack and the total

size of this stack. On many processors stacks actually descend from the

top down, so the kernel will add the stack size to the base address to

determine the starting location.

      </P

><P

>The exact stack size requirements for any given thread depend on a

number of factors. The most important is of course the code that will

be executed in the context of this code: if this involves significant

nesting of function calls, recursion, or large local arrays, then the

stack size needs to be set to a suitably high value. There are some

architectural issues, for example the number of cpu registers and the

calling conventions will have some effect on stack usage. Also,

depending on the configuration, it is possible that some other code

such as interrupt handlers will occasionally run on the current

thread's stack. This depends in part on configuration options such as

<TT

CLASS="VARNAME"

>CYGIMP_HAL_COMMON_INTERRUPTS_USE_INTERRUPT_STACK</TT

>

and <TT

CLASS="VARNAME"

>CYGSEM_HAL_COMMON_INTERRUPTS_ALLOW_NESTING</TT

>.

      </P

><P

>Determining an application's actual stack size requirements is the

responsibility of the application developer, since the kernel cannot

know in advance what code a given thread will run. However, the system

does provide some hints about reasonable stack sizes in the form of

two constants: <TT

CLASS="VARNAME"

>CYGNUM_HAL_STACK_SIZE_MINIMUM</TT

> and

<TT

CLASS="VARNAME"

>CYGNUM_HAL_STACK_SIZE_TYPICAL</TT

>. These are defined by

the appropriate HAL package. The <TT

CLASS="VARNAME"

>MINIMUM</TT

> value is

appropriate for a thread that just runs a single function and makes

very simple system calls. Trying to create a thread with a smaller

stack than this is illegal. The <TT

CLASS="VARNAME"

>TYPICAL</TT

> value is

appropriate for applications where application calls are nested no

more than half a dozen or so levels, and there are no large arrays on

the stack.

      </P

><P

>If the stack sizes are not estimated correctly and a stack overflow

occurs, the probably result is some form of memory corruption. This

can be very hard to track down. The kernel does contain some code to

help detect stack overflows, controlled by the configuration option

<TT

CLASS="VARNAME"

>CYGFUN_KERNEL_THREADS_STACK_CHECKING</TT

>: a small

amount of space is reserved at the stack limit and filled with a

special signature: every time a thread context switch occurs this

signature is checked, and if invalid that is a good indication (but

not absolute proof) that a stack overflow has occurred. This form of

stack checking is enabled by default when the system is built with

debugging enabled. A related configuration option is

<TT

CLASS="VARNAME"

>CYGFUN_KERNEL_THREADS_STACK_MEASUREMENT</TT

>: enabling

this option means that a thread can call the function

<TT

CLASS="FUNCTION"

>cyg_thread_measure_stack_usage</TT

> to find out the

maximum stack usage to date. Note that this is not necessarily the

true maximum because, for example, it is possible that in the current

run no interrupt occurred at the worst possible moment.

      </P

></DIV

><DIV

CLASS="REFSECT1"

><A

NAME="KERNEL-THREAD-CREATE-CONTEXT"

></A

><H2

>Valid contexts</H2

><P

><TT

CLASS="FUNCTION"

>cyg_thread_create</TT

> may be called during

initialization and from within thread context. It may not be called

from inside a DSR.

      </P

></DIV

><DIV

CLASS="REFSECT1"

><A

NAME="KERNEL-THREAD-CREATE-EXAMPLE"

></A

><H2

>Example</H2

><P

>A simple example of thread creation is shown below. This involves

creating five threads, one producer and four consumers or workers. The

threads are created in the system's

<TT

CLASS="FUNCTION"

>cyg_user_start</TT

>: depending on the configuration it

might be more appropriate to do this elsewhere, for example inside

<TT

CLASS="FUNCTION"

>main</TT

>.

      </P

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>#include <cyg/hal/hal_arch.h>

#include <cyg/kernel/kapi.h>

// These numbers depend entirely on your application

#define NUMBER_OF_WORKERS    4

#define PRODUCER_PRIORITY   10

#define WORKER_PRIORITY     11

#define PRODUCER_STACKSIZE  CYGNUM_HAL_STACK_SIZE_TYPICAL

#define WORKER_STACKSIZE    (CYGNUM_HAL_STACK_SIZE_MINIMUM + 1024)

static unsigned char producer_stack[PRODUCER_STACKSIZE];

static unsigned char worker_stacks[NUMBER_OF_WORKERS][WORKER_STACKSIZE];

static cyg_handle_t producer_handle, worker_handles[NUMBER_OF_WORKERS];

static cyg_thread_t producer_thread, worker_threads[NUMBER_OF_WORKERS];

static void

producer(cyg_addrword_t data)

{

    …

}

static void

worker(cyg_addrword_t data)

{

    …

}

void

cyg_user_start(void)

{

    int i;

    cyg_thread_create(PRODUCER_PRIORITY, &producer, 0, "producer",

                      producer_stack, PRODUCER_STACKSIZE,

                      &producer_handle, &producer_thread);

    cyg_thread_resume(producer_handle);

    for (i = 0; i < NUMBER_OF_WORKERS; i++) {

        cyg_thread_create(WORKER_PRIORITY, &worker, i, "worker",

                          worker_stacks[i], WORKER_STACKSIZE,

                          &(worker_handles[i]), &(worker_threads[i]));

        cyg_thread_resume(worker_handles[i]);

    }

}

      </PRE

></TD

></TR

></TABLE

></DIV

><DIV

CLASS="REFSECT1"

><A

NAME="KERNEL-THREAD-CREATE-CXX"

></A

><H2

>Thread Entry Points and C++</H2

><P

>For code written in C++ the thread entry function must be either a

static member function of a class or an ordinary function outside any

class. It cannot be a normal member function of a class because such

member functions take an implicit additional argument

<TT

CLASS="VARNAME"

>this</TT

>, and the kernel has no way of knowing what

value to use for this argument. One way around this problem is to make

use of a special static member function, for example:

      </P

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>class fred {

  public:

    void thread_function();

    static void static_thread_aux(cyg_addrword_t);

};

void

fred::static_thread_aux(cyg_addrword_t objptr)

{

    fred* object = static_cast<fred*>(objptr);

    object->thread_function();

}

static fred instance;

extern "C" void

cyg_start( void )

{

    …

    cyg_thread_create( …,

                      &fred::static_thread_aux,

                      static_cast<cyg_addrword_t>(&instance),

                      …);

    …

}

      </PRE

></TD

></TR

></TABLE

><P

>Effectively this uses the <TT

CLASS="PARAMETER"

><I

>entry_data</I

></TT

> argument to

<TT

CLASS="FUNCTION"

>cyg_thread_create</TT

> to hold the

<TT

CLASS="VARNAME"

>this</TT

> pointer. Unfortunately this approach does

require the use of some C++ casts, so some of the type safety that can

be achieved when programming in C++ is lost.

      </P

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