@c @c COPYRIGHT (c) 1988-2002. @c On-Line Applications Research Corporation (OAR). @c All rights reserved. @c @c $Id$ @c @ifinfo @end ifinfo @chapter MIPS Specific Information The Real Time Executive for Multiprocessor Systems (RTEMS) is designed to be portable across multiple processor architectures. However, the nature of real-time systems makes it essential that the application designer understand certain processor dependent implementation details. These processor dependencies include calling convention, board support package issues, interrupt processing, exact RTEMS memory requirements, performance data, header files, and the assembly language interface to the executive. This document discusses the VENDOR XXX architecture dependencies in this port of RTEMS. The XXX family has a wide variety of CPU models within it. The part numbers ... XXX fill in some things here It is highly recommended that the XXX RTEMS application developer obtain and become familiar with the documentation for the processor being used as well as the documentation for the family as a whole. @subheading Architecture Documents IDT docs are online at http://www.idt.com/products/risc/Welcome.html For information on the XXX architecture, refer to the following documents available from VENDOR (@file{http//www.XXX.com/}): @itemize @bullet @item @cite{XXX Family Reference, VENDOR, PART NUMBER}. @end itemize @subheading MODEL SPECIFIC DOCUMENTS For information on specific processor models and their associated coprocessors, refer to the following documents: @itemize @bullet @item @cite{XXX MODEL Manual, VENDOR, PART NUMBER}. @item @cite{XXX MODEL Manual, VENDOR, PART NUMBER}. @end itemize @c @c COPYRIGHT (c) 1988-2002. @c On-Line Applications Research Corporation (OAR). @c All rights reserved. @c @c $Id$ @c @section CPU Model Dependent Features Microprocessors are generally classified into families with a variety of CPU models or implementations within that family. Within a processor family, there is a high level of binary compatibility. This family may be based on either an architectural specification or on maintaining compatibility with a popular processor. Recent microprocessor families such as the SPARC or PowerPC are based on an architectural specification which is independent or any particular CPU model or implementation. Older families such as the M68xxx and the iX86 evolved as the manufacturer strived to produce higher performance processor models which maintained binary compatibility with older models. RTEMS takes advantage of the similarity of the various models within a CPU family. Although the models do vary in significant ways, the high level of compatibility makes it possible to share the bulk of the CPU dependent executive code across the entire family. Each processor family supported by RTEMS has a list of features which vary between CPU models within a family. For example, the most common model dependent feature regardless of CPU family is the presence or absence of a floating point unit or coprocessor. When defining the list of features present on a particular CPU model, one simply notes that floating point hardware is or is not present and defines a single constant appropriately. Conditional compilation is utilized to include the appropriate source code for this CPU model's feature set. It is important to note that this means that RTEMS is thus compiled using the appropriate feature set and compilation flags optimal for this CPU model used. The alternative would be to generate a binary which would execute on all family members using only the features which were always present. This chapter presents the set of features which vary across SPARC implementations and are of importance to RTEMS. The set of CPU model feature macros are defined in the file cpukit/score/cpu/XXX/XXX.h based upon the particular CPU model defined on the compilation command line. @subsection CPU Model Name The macro CPU_MODEL_NAME is a string which designates the name of this CPU model. For example, for the MODEL processor, this macro is set to the string "XXX". @subsection Floating Point Unit The macro XXX_HAS_FPU is set to 1 to indicate that this CPU model has a hardware floating point unit and 0 otherwise. It does not matter whether the hardware floating point support is incorporated on-chip or is an external coprocessor. @subsection Another Optional Feature The macro XXX @c @c COPYRIGHT (c) 1988-2002. @c On-Line Applications Research Corporation (OAR). @c All rights reserved. @c @c $Id$ @c @section Calling Conventions Each high-level language compiler generates subroutine entry and exit code based upon a set of rules known as the compiler's calling convention. These rules address the following issues: @itemize @bullet @item register preservation and usage @item parameter passing @item call and return mechanism @end itemize A compiler's calling convention is of importance when interfacing to subroutines written in another language either assembly or high-level. Even when the high-level language and target processor are the same, different compilers may use different calling conventions. As a result, calling conventions are both processor and compiler dependent. @subsection Processor Background The MC68xxx architecture supports a simple yet effective call and return mechanism. A subroutine is invoked via the branch to subroutine (@code{XXX}) or the jump to subroutine (@code{XXX}) instructions. These instructions push the return address on the current stack. The return from subroutine (@code{XXX}) instruction pops the return address off the current stack and transfers control to that instruction. It is is important to note that the XXX call and return mechanism does not automatically save or restore any registers. It is the responsibility of the high-level language compiler to define the register preservation and usage convention. @subsection Calling Mechanism All RTEMS directives are invoked using either a @code{XXX} or @code{XXX} instruction and return to the user application via the @code{XXX} instruction. @subsection Register Usage As discussed above, the @code{XXX} and @code{XXX} instructions do not automatically save any registers. RTEMS uses the registers @b{D0}, @b{D1}, @b{A0}, and @b{A1} as scratch registers. These registers are not preserved by RTEMS directives therefore, the contents of these registers should not be assumed upon return from any RTEMS directive. @subsection Parameter Passing RTEMS assumes that arguments are placed on the current stack before the directive is invoked via the @code{XXX} or @code{XXX} instruction. The first argument is assumed to be closest to the return address on the stack. This means that the first argument of the C calling sequence is pushed last. The following pseudo-code illustrates the typical sequence used to call a RTEMS directive with three (3) arguments: @example @group push third argument push second argument push first argument invoke directive remove arguments from the stack @end group @end example The arguments to RTEMS are typically pushed onto the stack using a move instruction with a pre-decremented stack pointer as the destination. These arguments must be removed from the stack after control is returned to the caller. This removal is typically accomplished by adding the size of the argument list in bytes to the current stack pointer. @subsection User-Provided Routines All user-provided routines invoked by RTEMS, such as user extensions, device drivers, and MPCI routines, must also adhere to these calling conventions. @c @c COPYRIGHT (c) 1988-2002. @c On-Line Applications Research Corporation (OAR). @c All rights reserved. @c @c $Id$ @c @section Memory Model A processor may support any combination of memory models ranging from pure physical addressing to complex demand paged virtual memory systems. RTEMS supports a flat memory model which ranges contiguously over the processor's allowable address space. RTEMS does not support segmentation or virtual memory of any kind. The appropriate memory model for RTEMS provided by the targeted processor and related characteristics of that model are described in this chapter. @subsection Flat Memory Model The XXX family supports a flat 32-bit address space with addresses ranging from 0x00000000 to 0xFFFFFFFF (4 gigabytes). Each address is represented by a 32-bit value and is byte addressable. The address may be used to reference a single byte, word (2-bytes), or long word (4 bytes). Memory accesses within this address space are performed in big endian fashion by the processors in this family. Some of the XXX family members such as the XXX, XXX, and XXX support virtual memory and segmentation. The XXX requires external hardware support such as the XXX Paged Memory Management Unit coprocessor which is typically used to perform address translations for these systems. RTEMS does not support virtual memory or segmentation on any of the XXX family members. @c @c Interrupt Stack Frame Picture @c @c COPYRIGHT (c) 1988-2002. @c On-Line Applications Research Corporation (OAR). @c All rights reserved. @c @c $Id$ @c @section Interrupt Processing Different types of processors respond to the occurrence of an interrupt in its own unique fashion. In addition, each processor type provides a control mechanism to allow for the proper handling of an interrupt. The processor dependent response to the interrupt modifies the current execution state and results in a change in the execution stream. Most processors require that an interrupt handler utilize some special control mechanisms to return to the normal processing stream. Although RTEMS hides many of the processor dependent details of interrupt processing, it is important to understand how the RTEMS interrupt manager is mapped onto the processor's unique architecture. Discussed in this chapter are the XXX's interrupt response and control mechanisms as they pertain to RTEMS. @subsection Vectoring of an Interrupt Handler Depending on whether or not the particular CPU supports a separate interrupt stack, the XXX family has two different interrupt handling models. @subsubsection Models Without Separate Interrupt Stacks Upon receipt of an interrupt the XXX family members without separate interrupt stacks automatically perform the following actions: @itemize @bullet @item To Be Written @end itemize @subsubsection Models With Separate Interrupt Stacks Upon receipt of an interrupt the XXX family members with separate interrupt stacks automatically perform the following actions: @itemize @bullet @item saves the current status register (SR), @item clears the master/interrupt (M) bit of the SR to indicate the switch from master state to interrupt state, @item sets the privilege mode to supervisor, @item suppresses tracing, @item sets the interrupt mask level equal to the level of the interrupt being serviced, @item pushes an interrupt stack frame (ISF), which includes the program counter (PC), the status register (SR), and the format/exception vector offset (FVO) word, onto the supervisor and interrupt stacks, @item switches the current stack to the interrupt stack and vectors to an interrupt service routine (ISR). If the ISR was installed with the interrupt_catch directive, then the RTEMS interrupt handler will begin execution. The RTEMS interrupt handler saves all registers which are not preserved according to the calling conventions and invokes the application's ISR. @end itemize A nested interrupt is processed similarly by these CPU models with the exception that only a single ISF is placed on the interrupt stack and the current stack need not be switched. The FVO word in the Interrupt Stack Frame is examined by RTEMS to determine when an outer most interrupt is being exited. Since the FVO is used by RTEMS for this purpose, the user application code MUST NOT modify this field. The following shows the Interrupt Stack Frame for XXX CPU models with separate interrupt stacks: @ifset use-ascii @example @group +----------------------+ | Status Register | 0x0 +----------------------+ | Program Counter High | 0x2 +----------------------+ | Program Counter Low | 0x4 +----------------------+ | Format/Vector Offset | 0x6 +----------------------+ @end group @end example @end ifset @ifset use-tex @sp 1 @tex \centerline{\vbox{\offinterlineskip\halign{ \strut\vrule#& \hbox to 2.00in{\enskip\hfil#\hfil}& \vrule#& \hbox to 0.50in{\enskip\hfil#\hfil} \cr \multispan{3}\hrulefill\cr & Status Register && 0x0\cr \multispan{3}\hrulefill\cr & Program Counter High && 0x2\cr \multispan{3}\hrulefill\cr & Program Counter Low && 0x4\cr \multispan{3}\hrulefill\cr & Format/Vector Offset && 0x6\cr \multispan{3}\hrulefill\cr }}\hfil} @end tex @end ifset @ifset use-html @html
Status Register 0x0
Program Counter High 0x2
Program Counter Low 0x4
Format/Vector Offset 0x6
@end html @end ifset @subsection Interrupt Levels Eight levels (0-7) of interrupt priorities are supported by XXX family members with level seven (7) being the highest priority. Level zero (0) indicates that interrupts are fully enabled. Interrupt requests for interrupts with priorities less than or equal to the current interrupt mask level are ignored. Although RTEMS supports 256 interrupt levels, the XXX family only supports eight. RTEMS interrupt levels 0 through 7 directly correspond to XXX interrupt levels. All other RTEMS interrupt levels are undefined and their behavior is unpredictable. @subsection Disabling of Interrupts by RTEMS During the execution of directive calls, critical sections of code may be executed. When these sections are encountered, RTEMS disables interrupts to level seven (7) before the execution of this section and restores them to the previous level upon completion of the section. RTEMS has been optimized to insure that interrupts are disabled for less than RTEMS_MAXIMUM_DISABLE_PERIOD microseconds on a RTEMS_MAXIMUM_DISABLE_PERIOD_MHZ Mhz processor with zero wait states. These numbers will vary based the number of wait states and processor speed present on the target board. [NOTE: The maximum period with interrupts disabled is hand calculated. This calculation was last performed for Release RTEMS_RELEASE_FOR_MAXIMUM_DISABLE_PERIOD.] Non-maskable interrupts (NMI) cannot be disabled, and ISRs which execute at this level MUST NEVER issue RTEMS system calls. If a directive is invoked, unpredictable results may occur due to the inability of RTEMS to protect its critical sections. However, ISRs that make no system calls may safely execute as non-maskable interrupts. @subsection Interrupt Stack RTEMS allocates the interrupt stack from the Workspace Area. The amount of memory allocated for the interrupt stack is determined by the interrupt_stack_size field in the CPU Configuration Table. During the initialization process, RTEMS will install its interrupt stack. The mips port of RTEMS supports a software managed dedicated interrupt stack on those CPU models which do not support a separate interrupt stack in hardware. @c @c COPYRIGHT (c) 1988-2002. @c On-Line Applications Research Corporation (OAR). @c All rights reserved. @c @c $Id$ @c @section Default Fatal Error Processing Upon detection of a fatal error by either the application or RTEMS the fatal error manager is invoked. The fatal error manager will invoke the user-supplied fatal error handlers. If no user-supplied handlers are configured, the RTEMS provided default fatal error handler is invoked. If the user-supplied fatal error handlers return to the executive the default fatal error handler is then invoked. This chapter describes the precise operations of the default fatal error handler. @subsection Default Fatal Error Handler Operations The default fatal error handler which is invoked by the @code{rtems_fatal_error_occurred} directive when there is no user handler configured or the user handler returns control to RTEMS. The default fatal error handler disables processor interrupts, places the error code in @b{XXX}, and executes a @code{XXX} instruction to simulate a halt processor instruction. @c @c COPYRIGHT (c) 1988-2002. @c On-Line Applications Research Corporation (OAR). @c All rights reserved. @c @c $Id$ @c @section Board Support Packages An RTEMS Board Support Package (BSP) must be designed to support a particular processor and target board combination. This chapter presents a discussion of XXX specific BSP issues. For more information on developing a BSP, refer to the chapter titled Board Support Packages in the RTEMS Applications User's Guide. @subsection System Reset An RTEMS based application is initiated or re-initiated when the XXX processor is reset. When the XXX is reset, the processor performs the following actions: @itemize @bullet @item The tracing bits of the status register are cleared to disable tracing. @item The supervisor interrupt state is entered by setting the supervisor (S) bit and clearing the master/interrupt (M) bit of the status register. @item The interrupt mask of the status register is set to level 7 to effectively disable all maskable interrupts. @item The vector base register (VBR) is set to zero. @item The cache control register (CACR) is set to zero to disable and freeze the processor cache. @item The interrupt stack pointer (ISP) is set to the value stored at vector 0 (bytes 0-3) of the exception vector table (EVT). @item The program counter (PC) is set to the value stored at vector 1 (bytes 4-7) of the EVT. @item The processor begins execution at the address stored in the PC. @end itemize @subsection Processor Initialization The address of the application's initialization code should be stored in the first vector of the EVT which will allow the immediate vectoring to the application code. If the application requires that the VBR be some value besides zero, then it should be set to the required value at this point. All tasks share the same XXX's VBR value. Because interrupts are enabled automatically by RTEMS as part of the initialize executive directive, the VBR MUST be set before this directive is invoked to insure correct interrupt vectoring. If processor caching is to be utilized, then it should be enabled during the reset application initialization code. In addition to the requirements described in the Board Support Packages chapter of the Applications User's Manual for the reset code which is executed before the call to initialize executive, the XXX version has the following specific requirements: @itemize @bullet @item Must leave the S bit of the status register set so that the XXX remains in the supervisor state. @item Must set the M bit of the status register to remove the XXX from the interrupt state. @item Must set the master stack pointer (MSP) such that a minimum stack size of MINIMUM_STACK_SIZE bytes is provided for the initialize executive directive. @item Must initialize the XXX's vector table. @end itemize Note that the BSP is not responsible for allocating or installing the interrupt stack. RTEMS does this automatically as part of initialization. If the BSP does not install an interrupt stack and -- for whatever reason -- an interrupt occurs before initialize_executive is invoked, then the results are unpredictable. @c @c COPYRIGHT (c) 1988-2002. @c On-Line Applications Research Corporation (OAR). @c All rights reserved. @c @c $Id$ @c @section Processor Dependent Information Table Any highly processor dependent information required to describe a processor to RTEMS is provided in the CPU Dependent Information Table. This table is not required for all processors supported by RTEMS. This chapter describes the contents, if any, for a particular processor type. @subsection CPU Dependent Information Table The XXX version of the RTEMS CPU Dependent Information Table contains the information required to interface a Board Support Package and RTEMS on the XXX. This information is provided to allow RTEMS to interoperate effectively with the BSP. The C structure definition is given here: @example @group typedef struct @{ void (*pretasking_hook)( void ); void (*predriver_hook)( void ); void (*postdriver_hook)( void ); void (*idle_task)( void ); boolean do_zero_of_workspace; unsigned32 idle_task_stack_size; unsigned32 interrupt_stack_size; unsigned32 extra_mpci_receive_server_stack; void * (*stack_allocate_hook)( unsigned32 ); void (*stack_free_hook)( void* ); /* end of fields required on all CPUs */ /* XXX CPU family dependent stuff */ @} rtems_cpu_table; @end group @end example @table @code @item pretasking_hook is the address of the user provided routine which is invoked once RTEMS APIs are initialized. This routine will be invoked before any system tasks are created. Interrupts are disabled. This field may be NULL to indicate that the hook is not utilized. @item predriver_hook is the address of the user provided routine that is invoked immediately before the the device drivers and MPCI are initialized. RTEMS initialization is complete but interrupts and tasking are disabled. This field may be NULL to indicate that the hook is not utilized. @item postdriver_hook is the address of the user provided routine that is invoked immediately after the the device drivers and MPCI are initialized. RTEMS initialization is complete but interrupts and tasking are disabled. This field may be NULL to indicate that the hook is not utilized. @item idle_task is the address of the optional user provided routine which is used as the system's IDLE task. If this field is not NULL, then the RTEMS default IDLE task is not used. This field may be NULL to indicate that the default IDLE is to be used. @item do_zero_of_workspace indicates whether RTEMS should zero the Workspace as part of its initialization. If set to TRUE, the Workspace is zeroed. Otherwise, it is not. @item idle_task_stack_size is the size of the RTEMS idle task stack in bytes. If this number is less than MINIMUM_STACK_SIZE, then the idle task's stack will be MINIMUM_STACK_SIZE in byte. @item interrupt_stack_size is the size of the RTEMS allocated interrupt stack in bytes. This value must be at least as large as MINIMUM_STACK_SIZE. @item extra_mpci_receive_server_stack is the extra stack space allocated for the RTEMS MPCI receive server task in bytes. The MPCI receive server may invoke nearly all directives and may require extra stack space on some targets. @item stack_allocate_hook is the address of the optional user provided routine which allocates memory for task stacks. If this hook is not NULL, then a stack_free_hook must be provided as well. @item stack_free_hook is the address of the optional user provided routine which frees memory for task stacks. If this hook is not NULL, then a stack_allocate_hook must be provided as well. @item XXX is where the CPU family dependent stuff goes. @end table