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><H1

CLASS="SECTION"

><A

NAME="HAL-ARCHITECTURE-CHARACTERIZATION">Architecture Characterization</H1

><P

>These are definition that are related to the basic architecture of the

CPU. These include the CPU context save format, context switching, bit

twiddling, breakpoints, stack sizes and address translation.</P

><P

>Most of these definition are found in

<TT

CLASS="FILENAME"

>cyg/hal/hal_arch.h</TT

>.  This file is supplied by the

architecture HAL. If there are variant or platform specific

definitions then these will be found in

<TT

CLASS="FILENAME"

>cyg/hal/var_arch.h</TT

> or

<TT

CLASS="FILENAME"

>cyg/hal/plf_arch.h</TT

>. These files are include

automatically by this header, so need not be included explicitly.</P

><DIV

CLASS="SECTION"

><H2

CLASS="SECTION"

><A

NAME="AEN7787">Register Save Format</H2

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>typedef struct HAL_SavedRegisters

{

    /* architecture-dependent list of registers to be saved */

} HAL_SavedRegisters;</PRE

></TD

></TR

></TABLE

><P

>This structure describes the layout of a saved machine state on the

stack. Such states are saved during thread context switches,

interrupts and exceptions. Different quantities of state may be saved

during each of these, but usually a thread context state is a subset

of the interrupt state which is itself a subset of an exception state.

For debugging purposes, the same structure is used for all three

purposes, but where these states are significantly different, this

structure may contain a union of the three states.</P

></DIV

><DIV

CLASS="SECTION"

><H2

CLASS="SECTION"

><A

NAME="AEN7791">Thread Context Initialization</H2

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>HAL_THREAD_INIT_CONTEXT( sp, arg, entry, id )</PRE

></TD

></TR

></TABLE

><P

>This macro initializes a thread's context so that

it may be switched to by <TT

CLASS="FUNCTION"

>HAL_THREAD_SWITCH_CONTEXT()</TT

>.

The arguments are:</P

><P

></P

><DIV

CLASS="VARIABLELIST"

><DL

><DT

>sp</DT

><DD

><P

>      A location containing the current value of the thread's stack

      pointer. This should be a variable or a structure field. The SP

      value will be read out of here and an adjusted value written

      back.

      </P

></DD

><DT

>arg</DT

><DD

><P

>      A value that is passed as the first argument to the entry

      point function.

      </P

></DD

><DT

>entry</DT

><DD

><P

>      The address of an entry point function. This will be called

      according the C calling conventions, and the value of

      <TT

CLASS="PARAMETER"

><I

>arg</I

></TT

> will be passed as the first

      argument. This function should have the following type signature

      <TT

CLASS="FUNCTION"

>void entry(CYG_ADDRWORD arg)</TT

>.

      </P

></DD

><DT

>id</DT

><DD

><P

>      A thread id value. This is only used for debugging purposes,

      it is ORed into the initialization pattern for unused registers

      and may be used to help identify the thread from its register dump.

      The least significant 16 bits of this value should be zero to allow

      space for a register identifier.

      </P

></DD

></DL

></DIV

></DIV

><DIV

CLASS="SECTION"

><H2

CLASS="SECTION"

><A

NAME="HAL-CONTEXT-SWITCH">Thread Context Switching</H2

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>HAL_THREAD_LOAD_CONTEXT( to )

HAL_THREAD_SWITCH_CONTEXT( from, to )</PRE

></TD

></TR

></TABLE

><P

>These macros implement the thread switch code. The arguments are:</P

><P

></P

><DIV

CLASS="VARIABLELIST"

><DL

><DT

>from</DT

><DD

><P

>      A pointer to a location where the stack pointer of the current

      thread will be stored.

      </P

></DD

><DT

>to</DT

><DD

><P

>      A pointer to a location from where the stack pointer of the next

      thread will be read.

      </P

></DD

></DL

></DIV

><P

>For <TT

CLASS="FUNCTION"

>HAL_THREAD_LOAD_CONTEXT()</TT

> the current CPU

state is discarded and the state of the destination thread is

loaded. This is only used once, to load the first thread when the

scheduler is started.</P

><P

>For <TT

CLASS="FUNCTION"

>HAL_THREAD_SWITCH_CONTEXT()</TT

> the state of the

current thread is saved onto its stack, using the current value of the

stack pointer, and the address of the saved state placed in

<TT

CLASS="PARAMETER"

><I

>*from</I

></TT

>.  The value in

<TT

CLASS="PARAMETER"

><I

>*to</I

></TT

> is then read and the state of the new

thread is loaded from it.</P

><P

>While these two operations may be implemented with inline assembler,

they are normally implemented as calls to assembly code functions in

the HAL. There are two advantages to doing it this way. First, the

return link of the call provides a convenient PC value to be used in

the saved context. Second, the calling conventions mean that the

compiler will have already saved the caller-saved registers before the

call, so the HAL need only save the callee-saved registers.</P

><P

>The implementation of <TT

CLASS="FUNCTION"

>HAL_THREAD_SWITCH_CONTEXT()</TT

>

saves the current CPU state on the stack, including the current

interrupt state (or at least the register that contains it). For

debugging purposes it is useful to save the entire register set, but

for performance only the ABI-defined callee-saved registers need be

saved. If it is implemented, the option

<TT

CLASS="LITERAL"

>CYGDBG_HAL_COMMON_CONTEXT_SAVE_MINIMUM</TT

> controls

how many registers are saved.</P

><P

>The implementation of <TT

CLASS="FUNCTION"

>HAL_THREAD_LOAD_CONTEXT()</TT

>

loads a thread context, destroying the current context. With a little

care this can be implemented by sharing code with

<TT

CLASS="FUNCTION"

>HAL_THREAD_SWITCH_CONTEXT()</TT

>. To load a thread

context simply requires the saved registers to be restored from the

stack and a jump or return made back to the saved PC.</P

><P

>Note that interrupts are not disabled during this process, any

interrupts that occur will be delivered onto the stack to which the

current CPU stack pointer points. Hence the stack pointer

should never be invalid, or loaded with a value that might cause the

saved state to become corrupted by an interrupt. However, the current

interrupt state is saved and restored as part of the thread

context. If a thread disables interrupts and does something to cause a

context switch, interrupts may be re-enabled on switching to another

thread. Interrupts will be disabled again when the original thread

regains control.</P

></DIV

><DIV

CLASS="SECTION"

><H2

CLASS="SECTION"

><A

NAME="AEN7842">Bit indexing</H2

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>HAL_LSBIT_INDEX( index, mask )

HAL_MSBIT_INDEX( index, mask )</PRE

></TD

></TR

></TABLE

><P

>These macros place in <TT

CLASS="PARAMETER"

><I

>index</I

></TT

> the bit index of

the least significant bit in <TT

CLASS="PARAMETER"

><I

>mask</I

></TT

>. Some

architectures have instruction level support for one or other of these

operations. If no architectural support is available, then these

macros may call C functions to do the job.</P

></DIV

><DIV

CLASS="SECTION"

><H2

CLASS="SECTION"

><A

NAME="AEN7848">Idle thread activity</H2

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>HAL_IDLE_THREAD_ACTION( count )</PRE

></TD

></TR

></TABLE

><P

>It may be necessary under some circumstances for the HAL to execute

code in the kernel idle thread's loop. An example might be to execute

a processor halt instruction. This macro provides a portable way of

doing this. The argument is a copy of the idle thread's loop counter,

and may be used to trigger actions at longer intervals than every

loop.</P

></DIV

><DIV

CLASS="SECTION"

><H2

CLASS="SECTION"

><A

NAME="AEN7852">Reorder barrier</H2

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>HAL_REORDER_BARRIER()</PRE

></TD

></TR

></TABLE

><P

>When optimizing the compiler can reorder code. In some parts of

multi-threaded systems, where the order of actions is vital, this can

sometimes cause problems. This macro may be inserted into places where

reordering should not happen and prevents code being migrated across

it by the compiler optimizer. It should be placed between statements

that must be executed in the order written in the code.</P

></DIV

><DIV

CLASS="SECTION"

><H2

CLASS="SECTION"

><A

NAME="AEN7856">Breakpoint support</H2

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>HAL_BREAKPOINT( label )

HAL_BREAKINST

HAL_BREAKINST_SIZE</PRE

></TD

></TR

></TABLE

><P

>These macros provide support for breakpoints.</P

><P

><TT

CLASS="FUNCTION"

>HAL_BREAKPOINT()</TT

> executes a breakpoint

instruction. The label is defined at the breakpoint instruction so

that exception code can detect which breakpoint was executed.</P

><P

><TT

CLASS="LITERAL"

>HAL_BREAKINST</TT

> contains the breakpoint instruction

code as an integer value. <TT

CLASS="LITERAL"

>HAL_BREAKINST_SIZE</TT

> is

the size of that breakpoint instruction in bytes. Together these

may be used to place a breakpoint in any code.</P

></DIV

><DIV

CLASS="SECTION"

><H2

CLASS="SECTION"

><A

NAME="AEN7865">GDB support</H2

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>HAL_THREAD_GET_SAVED_REGISTERS( sp, regs )

HAL_GET_GDB_REGISTERS( regval, regs )

HAL_SET_GDB_REGISTERS( regs, regval )</PRE

></TD

></TR

></TABLE

><P

>These macros provide support for interfacing GDB to the HAL.</P

><P

><TT

CLASS="FUNCTION"

>HAL_THREAD_GET_SAVED_REGISTERS()</TT

> extracts a

pointer to a <SPAN

CLASS="STRUCTNAME"

>HAL_SavedRegisters</SPAN

> structure

from a stack pointer value. The stack pointer passed in should be the

value saved by the thread context macros. The macro will assign a

pointer to the <SPAN

CLASS="STRUCTNAME"

>HAL_SavedRegisters</SPAN

> structure

to the variable passed as the second argument.</P

><P

><TT

CLASS="FUNCTION"

>HAL_GET_GDB_REGISTERS()</TT

> translates a register

state as saved by the HAL and into a register dump in the format

expected by GDB. It takes a pointer to a

<SPAN

CLASS="STRUCTNAME"

>HAL_SavedRegisters</SPAN

> structure in the

<TT

CLASS="PARAMETER"

><I

>regs</I

></TT

> argument and a pointer to the memory to

contain the GDB register dump in the <TT

CLASS="PARAMETER"

><I

>regval</I

></TT

>

argument.</P

><P

><TT

CLASS="FUNCTION"

>HAL_SET_GDB_REGISTERS()</TT

> translates a GDB format

register dump into a the format expected by the HAL.  It takes a

pointer to the memory containing the GDB register dump in the

<TT

CLASS="PARAMETER"

><I

>regval</I

></TT

> argument and a pointer to a

<SPAN

CLASS="STRUCTNAME"

>HAL_SavedRegisters</SPAN

> structure

in the <TT

CLASS="PARAMETER"

><I

>regs</I

></TT

> argument.</P

></DIV

><DIV

CLASS="SECTION"

><H2

CLASS="SECTION"

><A

NAME="AEN7883">Setjmp and longjmp support</H2

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>CYGARC_JMP_BUF_SIZE

hal_jmp_buf[CYGARC_JMP_BUF_SIZE]

hal_setjmp( hal_jmp_buf env )

hal_longjmp( hal_jmp_buf env, int val )</PRE

></TD

></TR

></TABLE

><P

>These functions provide support for the C

<TT

CLASS="FUNCTION"

>setjmp()</TT

> and <TT

CLASS="FUNCTION"

>longjmp()</TT

>

functions.  Refer to the C library for further information.</P

></DIV

><DIV

CLASS="SECTION"

><H2

CLASS="SECTION"

><A

NAME="AEN7889">Stack Sizes</H2

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>CYGNUM_HAL_STACK_SIZE_MINIMUM

CYGNUM_HAL_STACK_SIZE_TYPICAL</PRE

></TD

></TR

></TABLE

><P

>The values of these macros define the minimum and typical sizes of

thread stacks.</P

><P

><TT

CLASS="LITERAL"

>CYGNUM_HAL_STACK_SIZE_MINIMUM</TT

> defines the minimum

size of a thread stack. This is enough for the thread to function

correctly within eCos and allows it to take interrupts and context

switches. There should also be enough space for a simple thread entry

function to execute and call basic kernel operations on objects like

mutexes and semaphores. However there will not be enough room for much

more than this. When creating stacks for their own threads,

applications should determine the stack usage needed for application

purposes and then add

<TT

CLASS="LITERAL"

>CYGNUM_HAL_STACK_SIZE_MINIMUM</TT

>.</P

><P

><TT

CLASS="LITERAL"

>CYGNUM_HAL_STACK_SIZE_TYPICAL</TT

> is a reasonable increment over

<TT

CLASS="LITERAL"

>CYGNUM_HAL_STACK_SIZE_MINIMUM</TT

>, usually about 1kB. This should be

adequate for most modest thread needs. Only threads that need to

define significant amounts of local data, or have very deep call trees

should need to use a larger stack size.</P

></DIV

><DIV

CLASS="SECTION"

><H2

CLASS="SECTION"

><A

NAME="AEN7899">Address Translation</H2

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>CYGARC_CACHED_ADDRESS(addr)

CYGARC_UNCACHED_ADDRESS(addr)

CYGARC_PHYSICAL_ADDRESS(addr)</PRE

></TD

></TR

></TABLE

><P

>These macros provide address translation between different views of

memory. In many architectures a given memory location may be visible

at different addresses in both cached and uncached forms. It is also

possible that the MMU or some other address translation unit in the

CPU presents memory to the program at a different virtual address to

its physical address on the bus.</P

><P

><TT

CLASS="FUNCTION"

>CYGARC_CACHED_ADDRESS()</TT

> translates the given

address to its location in cached memory. This is typically where the

application will access the memory.</P

><P

><TT

CLASS="FUNCTION"

>CYGARC_UNCACHED_ADDRESS()</TT

> translates the given

address to its location in uncached memory. This is typically where

device drivers will access the memory to avoid cache problems. It may

additionally be necessary for the cache to be flushed before the

contents of this location is fully valid.</P

><P

><TT

CLASS="FUNCTION"

>CYGARC_PHYSICAL_ADDRESS()</TT

> translates the given

address to its location in the physical address space. This is

typically the address that needs to be passed to device hardware such

as a DMA engine, ethernet device or PCI bus bridge. The physical

address may not be directly accessible to the program, it may be

re-mapped by address translation.</P

></DIV

><DIV

CLASS="SECTION"

><H2

CLASS="SECTION"

><A

NAME="AEN7909">Global Pointer</H2

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>CYGARC_HAL_SAVE_GP()

CYGARC_HAL_RESTORE_GP()</PRE

></TD

></TR

></TABLE

><P

>These macros insert code to save and restore any global data pointer

that the ABI uses. These are necessary when switching context between

two eCos instances - for example between an eCos application and

RedBoot.</P

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