From 72a62ad88f82fe1ffee50024db4dd0f3fa5806f7 Mon Sep 17 00:00:00 2001 From: Chris Johns Date: Thu, 3 Nov 2016 16:58:08 +1100 Subject: Rename all manuals with an _ to have a -. It helps released naming of files. --- cpu-supplement/altera_nios_ii.rst | 17 + cpu-supplement/arm.rst | 198 +++++++++ cpu-supplement/atmel_avr.rst | 136 ++++++ cpu-supplement/blackfin.rst | 147 ++++++ cpu-supplement/command.rst | 9 + cpu-supplement/conf.py | 11 + cpu-supplement/ephiphany.rst | 92 ++++ cpu-supplement/index.rst | 59 +++ cpu-supplement/intel_amd_x86.rst | 292 ++++++++++++ cpu-supplement/lattice_micro32.rst | 201 +++++++++ cpu-supplement/m68xxx_and_coldfire.rst | 356 +++++++++++++++ cpu-supplement/mips.rst | 125 ++++++ cpu-supplement/openrisc_1000.rst | 97 ++++ cpu-supplement/port.rst | 422 ++++++++++++++++++ cpu-supplement/powerpc.rst | 569 ++++++++++++++++++++++++ cpu-supplement/preface.rst | 46 ++ cpu-supplement/renesas_m32c.rst | 18 + cpu-supplement/sparc.rst | 788 +++++++++++++++++++++++++++++++++ cpu-supplement/sparc64.rst | 582 ++++++++++++++++++++++++ cpu-supplement/superh.rst | 140 ++++++ cpu-supplement/wscript | 6 + cpu-supplement/xilinx_microblaze.rst | 18 + 22 files changed, 4329 insertions(+) create mode 100644 cpu-supplement/altera_nios_ii.rst create mode 100644 cpu-supplement/arm.rst create mode 100644 cpu-supplement/atmel_avr.rst create mode 100644 cpu-supplement/blackfin.rst create mode 100644 cpu-supplement/command.rst create mode 100644 cpu-supplement/conf.py create mode 100644 cpu-supplement/ephiphany.rst create mode 100644 cpu-supplement/index.rst create mode 100644 cpu-supplement/intel_amd_x86.rst create mode 100644 cpu-supplement/lattice_micro32.rst create mode 100644 cpu-supplement/m68xxx_and_coldfire.rst create mode 100644 cpu-supplement/mips.rst create mode 100644 cpu-supplement/openrisc_1000.rst create mode 100644 cpu-supplement/port.rst create mode 100644 cpu-supplement/powerpc.rst create mode 100644 cpu-supplement/preface.rst create mode 100644 cpu-supplement/renesas_m32c.rst create mode 100644 cpu-supplement/sparc.rst create mode 100644 cpu-supplement/sparc64.rst create mode 100644 cpu-supplement/superh.rst create mode 100644 cpu-supplement/wscript create mode 100644 cpu-supplement/xilinx_microblaze.rst (limited to 'cpu-supplement') diff --git a/cpu-supplement/altera_nios_ii.rst b/cpu-supplement/altera_nios_ii.rst new file mode 100644 index 0000000..f0f994b --- /dev/null +++ b/cpu-supplement/altera_nios_ii.rst @@ -0,0 +1,17 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: COPYRIGHT (c) 2014 Hesham ALMatary +.. COMMENT: All rights reserved. + +Altera Nios II Specific Information +################################### + +Symmetric Multiprocessing +========================= + +SMP is not supported. + +Thread-Local Storage +==================== + +Thread-local storage is not implemented. diff --git a/cpu-supplement/arm.rst b/cpu-supplement/arm.rst new file mode 100644 index 0000000..64fc156 --- /dev/null +++ b/cpu-supplement/arm.rst @@ -0,0 +1,198 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: COPYRIGHT (c) 1988-2009. +.. COMMENT: On-Line Applications Research Corporation (OAR). +.. COMMENT: All rights reserved. + +ARM Specific Information +######################## + +This chapter discusses the *ARM architecture* +(http://en.wikipedia.org/wiki/ARM_architecture) dependencies in this port of +RTEMS. The ARMv4T (and compatible), ARMv7-A, ARMv7-R and ARMv7-M architecture +versions are supported by RTEMS. Processors with a MMU use a static +configuration which is set up during system start. SMP is supported. + +**Architecture Documents** + +For information on the ARM architecture refer to the *ARM Infocenter* +(http://infocenter.arm.com/). + +CPU Model Dependent Features +============================ + +This section presents the set of features which vary across ARM implementations +and are of importance to RTEMS. The set of CPU model feature macros are +defined in the file :file:`cpukit/score/cpu/arm/rtems/score/arm.h` based upon +the particular CPU model flags specified on the compilation command line. + +CPU Model Name +-------------- + +The macro ``CPU_MODEL_NAME`` is a string which designates the architectural +level of this CPU model. See in :file:`cpukit/score/cpu/arm/rtems/score/arm.h` +for the values. + +Count Leading Zeroes Instruction +-------------------------------- + +The ARMv5 and later has the count leading zeroes ``clz`` instruction which +could be used to speed up the find first bit operation. The use of this +instruction should significantly speed up the scheduling associated with a +thread blocking. This is currently not used. + +Floating Point Unit +------------------- + +The following floating point units are supported. + +- VFPv3-D32/NEON (for example available on Cortex-A processors) + +- VFPv3-D16 (for example available on Cortex-R processors) + +- FPv4-SP-D16 (for example available on Cortex-M processors) + +Multilibs +========= + +The following multilibs are available: + +#. ``.``: ARMv4T, ARM instruction set + +#. ``thumb``: ARMv4T, Thumb-1 instruction set + +#. ``thumb/armv6-m``: ARMv6M, subset of Thumb-2 instruction set + +#. ``thumb/armv7-a``: ARMv7-A, Thumb-2 instruction set + +#. ``thumb/armv7-a/neon/hard``: ARMv7-A, Thumb-2 instruction set with + hard-float ABI Neon and VFP-D32 support + +#. ``thumb/armv7-r``: ARMv7-R, Thumb-2 instruction set + +#. ``thumb/armv7-r/vfpv3-d16/hard``: ARMv7-R, Thumb-2 instruction set with + hard-float ABI VFP-D16 support + +#. ``thumb/armv7-m``: ARMv7-M, Thumb-2 instruction set with hardware + integer division (SDIV/UDIV) + +#. ``thumb/armv7-m/fpv4-sp-d16``: ARMv7-M, Thumb-2 instruction set with + hardware integer division (SDIV/UDIV) and hard-float ABI FPv4-SP support + +#. ``eb/thumb/armv7-r``: ARMv7-R, Big-endian Thumb-2 instruction set + +#. ``eb/thumb/armv7-r/vfpv3-d16/hard``: ARMv7-R, Big-endian Thumb-2 instruction + set with hard-float ABI VFP-D16 support + +Multilib 1. and 2. support the standard ARM7TDMI and ARM926EJ-S targets. + +Multilib 3. supports the Cortex-M0 and Cortex-M1 cores. + +Multilib 8. supports the Cortex-M3 and Cortex-M4 cores, which have a special +hardware integer division instruction (this is not present in the A and R +profiles). + +Multilib 9. supports the Cortex-M4 cores with a floating point unit. + +Multilib 4. and 5. support the Cortex-A processors. + +Multilib 6., 7., 10. and 11. support the Cortex-R processors. Here also +big-endian variants are available. + +Use for example the following GCC options: + +.. code-block:: shell + + -mthumb -march=armv7-a -mfpu=neon -mfloat-abi=hard -mtune=cortex-a9 + +to build an application or BSP for the ARMv7-A architecture and tune the code +for a Cortex-A9 processor. It is important to select the options used for the +multilibs. For example: + +.. code-block:: shell + + -mthumb -mcpu=cortex-a9 + +alone will not select the ARMv7-A multilib. + +Calling Conventions +=================== + +Please refer to the *Procedure Call Standard for the ARM Architecture* +(http://infocenter.arm.com/help/topic/com.arm.doc.ihi0042c/IHI0042C_aapcs.pdf). + +Memory Model +============ + +A flat 32-bit memory model is supported. The board support package must take +care about the MMU if necessary. + +Interrupt Processing +==================== + +The ARMv4T (and compatible) architecture has seven exception types: + +- Reset + +- Undefined + +- Software Interrupt (SWI) + +- Prefetch Abort + +- Data Abort + +- Interrupt (IRQ) + +- Fast Interrupt (FIQ) + +Of these types only the IRQ has explicit operating system support. It is +intentional that the FIQ is not supported by the operating system. Without +operating system support for the FIQ it is not necessary to disable them during +critical sections of the system. + +The ARMv7-M architecture has a completely different exception model. Here +interrupts are disabled with a write of 0x80 to the ``basepri_max`` register. +This means that all exceptions and interrupts with a priority value of greater +than or equal to 0x80 are disabled. Thus exceptions and interrupts with a +priority value of less than 0x80 are non-maskable with respect to the operating +system and therefore must not use operating system services. Several support +libraries of chip vendors implicitly shift the priority value somehow before +the value is written to the NVIC IPR register. This can easily lead to +confusion. + +Interrupt Levels +---------------- + +There are exactly two interrupt levels on ARM with respect to RTEMS. Level +zero corresponds to interrupts enabled. Level one corresponds to interrupts +disabled. + +Interrupt Stack +--------------- + +The board support package must initialize the interrupt stack. The memory for +the stacks is usually reserved in the linker script. + +Default Fatal Error Processing +============================== + +The default fatal error handler for this architecture performs the following +actions: + +- disables operating system supported interrupts (IRQ), + +- places the error code in ``r0``, and + +- executes an infinite loop to simulate a halt processor instruction. + +Symmetric Multiprocessing +========================= + +SMP is supported on ARMv7-A. Available platforms are the Altera Cyclone V and +the Xilinx Zynq. + +Thread-Local Storage +==================== + +Thread-local storage is supported. diff --git a/cpu-supplement/atmel_avr.rst b/cpu-supplement/atmel_avr.rst new file mode 100644 index 0000000..6a3ce02 --- /dev/null +++ b/cpu-supplement/atmel_avr.rst @@ -0,0 +1,136 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: COPYRIGHT (c) 1988-2006. +.. COMMENT: On-Line Applications Research Corporation (OAR). +.. COMMENT: All rights reserved. + +Atmel AVR Specific Information +############################## + +This chapter discusses the AVR architecture dependencies in this port of RTEMS. + +**Architecture Documents** + +For information on the AVR architecture, refer to the following documents +available from Atmel. + +TBD + +- See other CPUs for documentation reference formatting examples. + +CPU Model Dependent Features +============================ + +CPUs of the AVR 53X only differ in the peripherals and thus in the device +drivers. This port does not yet support the 56X dual core variants. + +Count Leading Zeroes Instruction +-------------------------------- + +The AVR CPU has the XXX instruction which could be used to speed up the find +first bit operation. The use of this instruction should significantly speed up +the scheduling associated with a thread blocking. + +Calling Conventions +=================== + +Processor Background +-------------------- + +The AVR architecture supports a simple call and return mechanism. A subroutine +is invoked via the call (``call``) instruction. This instruction saves the +return address in the ``RETS`` register and transfers the execution to the +given address. + +It is the called funcions responsability to use the link instruction to reserve +space on the stack for the local variables. Returning from a subroutine is +done by using the RTS (``RTS``) instruction which loads the PC with the adress +stored in RETS. + +It is is important to note that the ``call`` instruction 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. + +Register Usage +-------------- + +A called function may clobber all registers, except RETS, R4-R7, P3-P5, FP and +SP. It may also modify the first 12 bytes in the caller's stack frame which is +used as an argument area for the first three arguments (which are passed in +R0...R3 but may be placed on the stack by the called function). + +Parameter Passing +----------------- + +RTEMS assumes that the AVR GCC calling convention is followed. The first three +parameters are stored in registers R0, R1, and R2. All other parameters are +put pushed on the stack. The result is returned through register R0. + +Memory Model +============ + +The AVR family architecutre support a single unified 4 GB byte address space +using 32-bit addresses. It maps all resources like internal and external memory +and IO registers into separate sections of this common address space. + +The AVR architcture supports some form of memory protection via its Memory +Management Unit. Since the AVR port runs in supervisior mode this memory +protection mechanisms are not used. + +Interrupt Processing +==================== + +Discussed in this chapter are the AVR's interrupt response and control +mechanisms as they pertain to RTEMS. + +Vectoring of an Interrupt Handler +--------------------------------- + +TBD + +Disabling of Interrupts by RTEMS +-------------------------------- + +During interrupt disable critical sections, RTEMS disables interrupts to level +N (N) before the execution of this section and restores them to the previous +level upon completion of the section. RTEMS uses the instructions CLI and STI +to enable and disable Interrupts. Emulation, Reset, NMI and Exception +Interrupts are never disabled. + +Interrupt Stack +--------------- + +The AVR Architecture works with two different kind of stacks, User and +Supervisor Stack. Since RTEMS and its Application run in supervisor mode, all +interrupts will use the interrupted tasks stack for execution. + +Default Fatal Error Processing +============================== + +The default fatal error handler for the AVR performs the following +actions: + +- disables processor interrupts, + +- places the error code in *r0*, and + +- executes an infinite loop (``while(0);`` to + simulate a halt processor instruction. + +Symmetric Multiprocessing +========================= + +SMP is not supported. + +Thread-Local Storage +==================== + +Thread-local storage is not supported due to a broken tool chain. + +Board Support Packages +====================== + +System Reset +------------ + +TBD diff --git a/cpu-supplement/blackfin.rst b/cpu-supplement/blackfin.rst new file mode 100644 index 0000000..e26ceb8 --- /dev/null +++ b/cpu-supplement/blackfin.rst @@ -0,0 +1,147 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: Copyright (c) 2015 University of York. +.. COMMENT: Hesham ALMatary + +Blackfin Specific Information +############################# + +This chapter discusses the Blackfin architecture dependencies in this port of +RTEMS. + +**Architecture Documents** + +For information on the Blackfin architecture, refer to the following documents +available from Analog Devices. + +TBD + +- *"ADSP-BF533 Blackfin Processor Hardware Reference."* http://www.analog.com/UploadedFiles/Associated_Docs/892485982bf533_hwr.pdf + +CPU Model Dependent Features +============================ + +CPUs of the Blackfin 53X only differ in the peripherals and thus in the device +drivers. This port does not yet support the 56X dual core variants. + +Count Leading Zeroes Instruction +-------------------------------- + +The Blackfin CPU has the BITTST instruction which could be used to speed up the +find first bit operation. The use of this instruction should significantly +speed up the scheduling associated with a thread blocking. + +Calling Conventions +=================== + +This section is heavily based on content taken from the Blackfin uCLinux +documentation wiki which is edited by Analog Devices and Arcturus Networks. +http://docs.blackfin.uclinux.org/ + +Processor Background +-------------------- + +The Blackfin architecture supports a simple call and return mechanism. A +subroutine is invoked via the call (``call``) instruction. This instruction +saves the return address in the ``RETS`` register and transfers the execution +to the given address. + +It is the called funcions responsability to use the link instruction to reserve +space on the stack for the local variables. Returning from a subroutine is +done by using the RTS (``RTS``) instruction which loads the PC with the adress +stored in RETS. + +It is is important to note that the ``call`` instruction 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. + +Register Usage +-------------- + +A called function may clobber all registers, except RETS, R4-R7, P3-P5, FP and +SP. It may also modify the first 12 bytes in the caller's stack frame which is +used as an argument area for the first three arguments (which are passed in +R0...R3 but may be placed on the stack by the called function). + +Parameter Passing +----------------- + +RTEMS assumes that the Blackfin GCC calling convention is followed. The first +three parameters are stored in registers R0, R1, and R2. All other parameters +are put pushed on the stack. The result is returned through register R0. + +Memory Model +============ + +The Blackfin family architecutre support a single unified 4 GB byte address +space using 32-bit addresses. It maps all resources like internal and external +memory and IO registers into separate sections of this common address space. + +The Blackfin architcture supports some form of memory protection via its Memory +Management Unit. Since the Blackfin port runs in supervisior mode this memory +protection mechanisms are not used. + +Interrupt Processing +==================== + +Discussed in this chapter are the Blackfin's interrupt response and control +mechanisms as they pertain to RTEMS. The Blackfin architecture support 16 kinds +of interrupts broken down into Core and general-purpose interrupts. + +Vectoring of an Interrupt Handler +--------------------------------- + +RTEMS maps levels 0 -15 directly to Blackfins event vectors EVT0 - EVT15. Since +EVT0 - EVT6 are core events and it is suggested to use EVT15 and EVT15 for +Software interrupts, 7 Interrupts (EVT7-EVT13) are left for periferical use. + +When installing an RTEMS interrupt handler RTEMS installs a generic Interrupt +Handler which saves some context and enables nested interrupt servicing and +then vectors to the users interrupt handler. + +Disabling of Interrupts by RTEMS +-------------------------------- + +During interrupt disable critical sections, RTEMS disables interrupts to level +four (4) before the execution of this section and restores them to the previous +level upon completion of the section. RTEMS uses the instructions CLI and STI +to enable and disable Interrupts. Emulation, Reset, NMI and Exception +Interrupts are never disabled. + +Interrupt Stack +--------------- + +The Blackfin Architecture works with two different kind of stacks, User and +Supervisor Stack. Since RTEMS and its Application run in supervisor mode, all +interrupts will use the interrupted tasks stack for execution. + +Default Fatal Error Processing +============================== + +The default fatal error handler for the Blackfin performs the following +actions: + +- disables processor interrupts, + +- places the error code in *r0*, and + +- executes an infinite loop (``while(0);`` to + simulate a halt processor instruction. + +Symmetric Multiprocessing +========================= + +SMP is not supported. + +Thread-Local Storage +==================== + +Thread-local storage is not implemented. + +Board Support Packages +====================== + +System Reset +------------ + +TBD diff --git a/cpu-supplement/command.rst b/cpu-supplement/command.rst new file mode 100644 index 0000000..46bd174 --- /dev/null +++ b/cpu-supplement/command.rst @@ -0,0 +1,9 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +Command and Variable Index +########################## + +There are currently no Command and Variable Index entries. + +.. COMMENT: @printindex fn + diff --git a/cpu-supplement/conf.py b/cpu-supplement/conf.py new file mode 100644 index 0000000..e08bbf1 --- /dev/null +++ b/cpu-supplement/conf.py @@ -0,0 +1,11 @@ +import sys, os +sys.path.append(os.path.abspath('../common/')) + +from conf import * + +version = '1.0' +release = '5.0' + +latex_documents = [ + ('index', 'cpu-supplement.tex', u'RTEMS CPU Supplement Documentation', u'RTEMS Documentation Project', 'manual'), +] diff --git a/cpu-supplement/ephiphany.rst b/cpu-supplement/ephiphany.rst new file mode 100644 index 0000000..fa36119 --- /dev/null +++ b/cpu-supplement/ephiphany.rst @@ -0,0 +1,92 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: COPYRIGHT (c) 1988-2002. +.. COMMENT: On-Line Applications Research Corporation (OAR). +.. COMMENT: All rights reserved. + +Epiphany Specific Information +############################# + +This chapter discusses the`Epiphany Architecture +http://adapteva.com/docs/epiphany_sdk_ref.pdf dependencies in this port of +RTEMS. Epiphany is a chip that can come with 16 and 64 cores, each of which can +run RTEMS separately or they can work together to run a SMP RTEMS application. + +**Architecture Documents** + +For information on the Epiphany architecture refer to the *Epiphany +Architecture Reference* http://adapteva.com/docs/epiphany_arch_ref.pdf. + +Calling Conventions +=================== + +Please refer to the *Epiphany SDK* +http://adapteva.com/docs/epiphany_sdk_ref.pdf Appendix A: Application Binary +Interface + +Floating Point Unit +------------------- + +A floating point unit is currently not supported. + +Memory Model +============ + +A flat 32-bit memory model is supported, no caches. Each core has its own 32 +KiB strictly ordered local memory along with an access to a shared 32 MiB +external DRAM. + +Interrupt Processing +==================== + +Every Epiphany core has 10 exception types: + +- Reset + +- Software Exception + +- Data Page Fault + +- Timer 0 + +- Timer 1 + +- Message Interrupt + +- DMA0 Interrupt + +- DMA1 Interrupt + +- WANT Interrupt + +- User Interrupt + +Interrupt Levels +---------------- + +There are only two levels: interrupts enabled and interrupts disabled. + +Interrupt Stack +--------------- + +The Epiphany RTEMS port uses a dedicated software interrupt stack. The stack +for interrupts is allocated during interrupt driver initialization. When an +interrupt is entered, the _ISR_Handler routine is responsible for switching +from the interrupted task stack to RTEMS software interrupt stack. + +Default Fatal Error Processing +============================== + +The default fatal error handler for this architecture performs the following +actions: + +- disables operating system supported interrupts (IRQ), + +- places the error code in ``r0``, and + +- executes an infinite loop to simulate a halt processor instruction. + +Symmetric Multiprocessing +========================= + +SMP is not supported. diff --git a/cpu-supplement/index.rst b/cpu-supplement/index.rst new file mode 100644 index 0000000..4d5c2ac --- /dev/null +++ b/cpu-supplement/index.rst @@ -0,0 +1,59 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +================================= +RTEMS CPU Architecture Supplement +================================= + + | COPYRIGHT (c) 1988 - 2015. + | On-Line Applications Research Corporation (OAR). + +The authors have used their best efforts in preparing this material. These +efforts include the development, research, and testing of the theories and +programs to determine their effectiveness. No warranty of any kind, expressed +or implied, with regard to the software or the material contained in this +document is provided. No liability arising out of the application or use of +any product described in this document is assumed. The authors reserve the +right to revise this material and to make changes from time to time in the +content hereof without obligation to notify anyone of such revision or changes. + +The RTEMS Project is hosted at http://www.rtems.org/. Any inquiries concerning +RTEMS, its related support components, or its documentation should be directed +to the Community Project hosted at http://www.rtems.org/. + +.. topic:: RTEMS Online Resources + + ================ ============================= + Home https://www.rtems.org/ + Developers https://devel.rtems.org/ + Documentation https://docs.rtems.org/ + Bug Reporting https://devel.rtems.org/query + Mailing Lists https://lists.rtems.org/ + Git Repositories https://git.rtems.org/ + ================ ============================= + +.. toctree:: + :maxdepth: 3 + :numbered: + + preface + port + arm + atmel_avr + blackfin + ephiphany + intel_amd_x86 + lattice_micro32 + renesas_m32c + m68xxx_and_coldfire + xilinx_microblaze + mips + altera_nios_ii + openrisc_1000 + powerpc + superh + sparc + sparc64 + command + +* :ref:`genindex` +* :ref:`search` diff --git a/cpu-supplement/intel_amd_x86.rst b/cpu-supplement/intel_amd_x86.rst new file mode 100644 index 0000000..37ff569 --- /dev/null +++ b/cpu-supplement/intel_amd_x86.rst @@ -0,0 +1,292 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: COPYRIGHT (c) 1988-2002. +.. COMMENT: On-Line Applications Research Corporation (OAR). +.. COMMENT: All rights reserved. +.. COMMENT: Jukka Pietarinen , 2008, +.. COMMENT: Micro-Research Finland Oy + +Intel/AMD x86 Specific Information +################################## + +This chapter discusses the Intel x86 architecture dependencies in this port of +RTEMS. This family has multiple implementations from multiple vendors and +suffers more from having evolved rather than being designed for growth. + +For information on the i386 processor, refer to the following documents: + +- *386 Programmer's Reference Manual, Intel, Order No. 230985-002*. + +- *386 Microprocessor Hardware Reference Manual, Intel, + Order No. 231732-003*. + +- *80386 System Software Writer's Guide, Intel, Order No. 231499-001*. + +- *80387 Programmer's Reference Manual, Intel, Order No. 231917-001*. + +CPU Model Dependent Features +============================ + +This section presents the set of features which vary across i386 +implementations and are of importance to RTEMS. The set of CPU model feature +macros are defined in the :file:`cpukit/score/cpu/i386/i386.h` based upon the +particular CPU model specified on the compilation command line. + +bswap Instruction +----------------- + +The macro ``I386_HAS_BSWAP`` is set to 1 to indicate that this CPU model has +the ``bswap`` instruction which endian swaps a thirty-two bit quantity. This +instruction appears to be present in all CPU models i486's and above. + +Calling Conventions +=================== + +Processor Background +-------------------- + +The i386 architecture supports a simple yet effective call and return +mechanism. A subroutine is invoked via the call (``call``) instruction. This +instruction pushes the return address on the stack. The return from subroutine +(``ret``) instruction pops the return address off the current stack and +transfers control to that instruction. It is is important to note that the +i386 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. + +Calling Mechanism +----------------- + +All RTEMS directives are invoked using a call instruction and return to the +user application via the ret instruction. + +Register Usage +-------------- + +As discussed above, the call instruction does not automatically save any +registers. RTEMS uses the registers EAX, ECX, and EDX 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. + +Parameter Passing +----------------- + +RTEMS assumes that arguments are placed on the current stack before the +directive is invoked via the call 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: + +.. code-block:: c + + push third argument + push second argument + push first argument + invoke directive + remove arguments from the stack + +The arguments to RTEMS are typically pushed onto the stack using a push +instruction. 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 stack pointer. + +Memory Model +============ + +Flat Memory Model +----------------- + +RTEMS supports the i386 protected mode, flat memory model with paging disabled. +In this mode, the i386 automatically converts every address from a logical to a +physical address each time it is used. The i386 uses information provided in +the segment registers and the Global Descriptor Table to convert these +addresses. RTEMS assumes the existence of the following segments: + +- a single code segment at protection level (0) which contains all application + and executive code. + +- a single data segment at protection level zero (0) which contains all + application and executive data. + +The i386 segment registers and associated selectors must be initialized when +the initialize_executive directive is invoked. RTEMS treats the segment +registers as system registers and does not modify or context switch them. + +This i386 memory model 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, half-word (2-bytes), or word (4 bytes). + +Interrupt Processing +==================== + +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 the processor's response and control mechanisms as they pertain to RTEMS. + +Vectoring of Interrupt Handler +------------------------------ + +Although the i386 supports multiple privilege levels, RTEMS and all user +software executes at privilege level 0. This decision was made by the RTEMS +designers to enhance compatibility with processors which do not provide +sophisticated protection facilities like those of the i386. This decision +greatly simplifies the discussion of i386 processing, as one need only consider +interrupts without privilege transitions. + +Upon receipt of an interrupt the i386 automatically performs the following +actions: + +- pushes the EFLAGS register + +- pushes the far address of the interrupted instruction + +- vectors to the interrupt service routine (ISR). + +A nested interrupt is processed similarly by the i386. + +Interrupt Stack Frame +--------------------- + +The structure of the Interrupt Stack Frame for the i386 which is placed on the +interrupt stack by the processor in response to an interrupt is as follows: + ++----------------------+-------+ +| Old EFLAGS Register | ESP+8 | ++----------+-----------+-------+ +| UNUSED | Old CS | ESP+4 | ++----------+-----------+-------+ +| Old EIP | ESP | ++----------------------+-------+ + + +Interrupt Levels +---------------- + +Although RTEMS supports 256 interrupt levels, the i386 only supports two - +enabled and disabled. Interrupts are enabled when the interrupt-enable flag +(IF) in the extended flags (EFLAGS) is set. Conversely, interrupt processing +is inhibited when the IF is cleared. During a non-maskable interrupt, all +other interrupts, including other non-maskable ones, are inhibited. + +RTEMS interrupt levels 0 and 1 such that level zero +(0) indicates that interrupts are fully enabled and level one that interrupts +are disabled. All other RTEMS interrupt levels are undefined and their +behavior is unpredictable. + +Interrupt Stack +--------------- + +The i386 family does not support a dedicated hardware interrupt stack. On this +processor, RTEMS allocates and manages a dedicated interrupt stack. As part of +vectoring a non-nested interrupt service routine, RTEMS switches from the stack +of the interrupted task to a dedicated interrupt stack. When a non-nested +interrupt returns, RTEMS switches back to the stack of the interrupted stack. +The current stack pointer is not altered by RTEMS on nested interrupt. + +Default Fatal Error Processing +============================== + +The default fatal error handler for this architecture disables processor +interrupts, places the error code in EAX, and executes a HLT instruction to +halt the processor. + +Symmetric Multiprocessing +========================= + +SMP is not supported. + +Thread-Local Storage +==================== + +Thread-local storage is not implemented. + +Board Support Packages +====================== + +System Reset +------------ + +An RTEMS based application is initiated when the i386 processor is reset. When +the i386 is reset, + +- The EAX register is set to indicate the results of the processor's power-up + self test. If the self-test was not executed, the contents of this register + are undefined. Otherwise, a non-zero value indicates the processor is faulty + and a zero value indicates a successful self-test. + +- The DX register holds a component identifier and revision level. DH contains + 3 to indicate an i386 component and DL contains a unique revision level + indicator. + +- Control register zero (CR0) is set such that the processor is in real mode + with paging disabled. Other portions of CR0 are used to indicate the + presence of a numeric coprocessor. + +- All bits in the extended flags register (EFLAG) which are not permanently set + are cleared. This inhibits all maskable interrupts. + +- The Interrupt Descriptor Register (IDTR) is set to point at address zero. + +- All segment registers are set to zero. + +- The instruction pointer is set to 0x0000FFF0. The first instruction executed + after a reset is actually at 0xFFFFFFF0 because the i386 asserts the upper + twelve address until the first intersegment (FAR) JMP or CALL instruction. + When a JMP or CALL is executed, the upper twelve address lines are lowered + and the processor begins executing in the first megabyte of memory. + +Typically, an intersegment JMP to the application's initialization code is +placed at address 0xFFFFFFF0. + +Processor Initialization +------------------------ + +This initialization code is responsible for initializing all data structures +required by the i386 in protected mode and for actually entering protected +mode. The i386 must be placed in protected mode and the segment registers and +associated selectors must be initialized before the initialize_executive +directive is invoked. + +The initialization code is responsible for initializing the Global Descriptor +Table such that the i386 is in the thirty-two bit flat memory model with paging +disabled. In this mode, the i386 automatically converts every address from a +logical to a physical address each time it is used. For more information on +the memory model used by RTEMS, please refer to the Memory Model chapter in +this document. + +Since the processor is in real mode upon reset, the processor must be switched +to protected mode before RTEMS can execute. Before switching to protected +mode, at least one descriptor table and two descriptors must be created. +Descriptors are needed for a code segment and a data segment. ( This will give +you the flat memory model.) The stack can be placed in a normal read/write +data segment, so no descriptor for the stack is needed. Before the GDT can be +used, the base address and limit must be loaded into the GDTR register using an +LGDT instruction. + +If the hardware allows an NMI to be generated, you need to create the IDT and a +gate for the NMI interrupt handler. Before the IDT can be used, the base +address and limit for the idt must be loaded into the IDTR register using an +LIDT instruction. + +Protected mode is entered by setting thye PE bit in the CR0 register. Either a +LMSW or MOV CR0 instruction may be used to set this bit. Because the processor +overlaps the interpretation of several instructions, it is necessary to discard +the instructions from the read-ahead cache. A JMP instruction immediately after +the LMSW changes the flow and empties the processor if intructions which have +been pre-fetched and/or decoded. At this point, the processor is in protected +mode and begins to perform protected mode application initialization. + +If the application requires that the IDTR be some value besides zero, then it +should set it to the required value at this point. All tasks share the same +i386 IDTR value. Because interrupts are enabled automatically by RTEMS as part +of the initialize_executive directive, the IDTR MUST be set properly 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. The reset code which is executed before the +call to initialize_executive has the following requirements: + +For more information regarding the i386 data structures and their contents, +refer to Intel's 386 Programmer's Reference Manual. diff --git a/cpu-supplement/lattice_micro32.rst b/cpu-supplement/lattice_micro32.rst new file mode 100644 index 0000000..620cadf --- /dev/null +++ b/cpu-supplement/lattice_micro32.rst @@ -0,0 +1,201 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: Copyright (c) 2014 embedded brains GmbH. All rights reserved. + +Lattice Mico32 Specific Information +################################### + +This chaper discusses the Lattice Mico32 architecture dependencies in this port +of RTEMS. The Lattice Mico32 is a 32-bit Harvard, RISC architecture "soft" +microprocessor, available for free with an open IP core licensing +agreement. Although mainly targeted for Lattice FPGA devices the microprocessor +can be implemented on other vendors' FPGAs, too. + +**Architecture Documents** + +For information on the Lattice Mico32 architecture, refer to the following +documents available from Lattice Semiconductor http://www.latticesemi.com/. + +- *"LatticeMico32 Processor Reference Manual"* + http://www.latticesemi.com/dynamic/view_document.cfm?document_id=20890 + +CPU Model Dependent Features +============================ + +The Lattice Mico32 architecture allows for different configurations of the +processor. This port is based on the assumption that the following options are +implemented: + +- hardware multiplier + +- hardware divider + +- hardware barrel shifter + +- sign extension instructions + +- instruction cache + +- data cache + +- debug + +Register Architecture +===================== + +This section gives a brief introduction to the register architecture of the +Lattice Mico32 processor. + +The Lattice Mico32 is a RISC archictecture processor with a 32-register file of +32-bit registers. + +Register Name + +Function + +r0 + +holds value zero + +r1-r25 + +general purpose + +r26/gp + +general pupose / global pointer + +r27/fp + +general pupose / frame pointer + +r28/sp + +stack pointer + +r29/ra + +return address + +r30/ea + +exception address + +r31/ba + +breakpoint address + +Note that on processor startup all register values are undefined including r0, +thus r0 has to be initialized to zero. + +Calling Conventions +=================== + +Calling Mechanism +----------------- + +A call instruction places the return address to register r29 and a return from +subroutine (ret) is actually a branch to r29/ra. + +Register Usage +-------------- + +A subroutine may freely use registers r1 to r10 which are *not* preserved +across subroutine invocations. + +Parameter Passing +----------------- + +When calling a C function the first eight arguments are stored in registers r1 +to r8. Registers r1 and r2 hold the return value. + +Memory Model +============ + +The Lattice Mico32 processor supports a flat memory model with a 4 Gbyte +address space with 32-bit addresses. + +The following data types are supported: + +================== ==== ====================== +Type Bits C Compiler Type +================== ==== ====================== +unsigned byte 8 unsigned char +signed byte 8 char +unsigned half-word 16 unsigned short +signed half-word 16 short +unsigned word 32 unsigned int / unsigned long +signed word 32 int / long +================== ==== ====================== + +Data accesses need to be aligned, with unaligned accesses result are undefined. + +Interrupt Processing +==================== + +The Lattice Mico32 has 32 interrupt lines which are however served by only one +exception vector. When an interrupt occurs following happens: + +- address of next instruction placed in r30/ea + +- IE field of IE CSR saved to EIE field and IE field cleared preventing further + exceptions from occuring. + +- branch to interrupt exception address EBA CSR + 0xC0 + +The interrupt exception handler determines from the state of the interrupt +pending registers (IP CSR) and interrupt enable register (IE CSR) which +interrupt to serve and jumps to the interrupt routine pointed to by the +corresponding interrupt vector. + +For now there is no dedicated interrupt stack so every task in the system MUST +have enough stack space to accommodate the worst case stack usage of that +particular task and the interrupt service routines COMBINED. + +Nested interrupts are not supported. + +Default Fatal Error Processing +============================== + +Upon detection of a fatal error by either the application or RTEMS during +initialization the ``rtems_fatal_error_occurred`` directive supplied by 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 or all of them return without taking action to shutdown the +processor or reset, a default fatal error handler is invoked. + +Most of the action performed as part of processing the fatal error are +described in detail in the Fatal Error Manager chapter in the User's Guide. +However, the if no user provided extension or BSP specific fatal error handler +takes action, the final default action is to invoke a CPU architecture specific +function. Typically this function disables interrupts and halts the processor. + +In each of the architecture specific chapters, this describes the precise +operations of the default CPU specific fatal error handler. + +Symmetric Multiprocessing +========================= + +SMP is not supported. + +Thread-Local Storage +==================== + +Thread-local storage is not implemented. + +Board Support Packages +====================== + +An RTEMS Board Support Package (BSP) must be designed to support a particular +processor model and target board combination. + +In each of the architecture specific chapters, this section will present a +discussion of architecture specific BSP issues. For more information on +developing a BSP, refer to BSP and Device Driver Development Guide and the +chapter titled Board Support Packages in the RTEMS Applications User's Guide. + +System Reset +------------ + +An RTEMS based application is initiated or re-initiated when the processor is +reset. diff --git a/cpu-supplement/m68xxx_and_coldfire.rst b/cpu-supplement/m68xxx_and_coldfire.rst new file mode 100644 index 0000000..d448276 --- /dev/null +++ b/cpu-supplement/m68xxx_and_coldfire.rst @@ -0,0 +1,356 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: Copyright (c) 2014 embedded brains GmbH. All rights reserved. + +M68xxx and Coldfire Specific Information +######################################## + +This chapter discusses the Freescale (formerly Motorola) MC68xxx and Coldfire +architectural dependencies. The MC68xxx family has a wide variety of CPU +models within it based upon different CPU core implementations. Ignoring the +Coldfire parts, the part numbers for these models are generally divided into +MC680xx and MC683xx. The MC680xx models are more general purpose processors +with no integrated peripherals. The MC683xx models, on the other hand, are +more specialized and have a variety of peripherals on chip including +sophisticated timers and serial communications controllers. + +**Architecture Documents** + +For information on the MC68xxx and Coldfire architecture, refer to the +following documents available from Freescale website +(http//www.freescale.com/): + +- *M68000 Family Reference, Motorola, FR68K/D*. + +- *MC68020 User's Manual, Motorola, MC68020UM/AD*. + +- *MC68881/MC68882 Floating-Point Coprocessor User's Manual, + Motorola, MC68881UM/AD*. + +CPU Model Dependent Features +============================ + +This section presents the set of features which vary across m68k/Coldfire +implementations that are of importance to RTEMS. The set of CPU model feature +macros are defined in the file :file:`cpukit/score/cpu/m68k/m68k.h` based upon +the particular CPU model selected on the compilation command line. + +BFFFO Instruction +----------------- + +The macro ``M68K_HAS_BFFFO`` is set to 1 to indicate that this CPU model has +the bfffo instruction. + +Vector Base Register +-------------------- + +The macro ``M68K_HAS_VBR`` is set to 1 to indicate that this CPU model has a +vector base register (vbr). + +Separate Stacks +--------------- + +The macro ``M68K_HAS_SEPARATE_STACKS`` is set to 1 to indicate that this CPU +model has separate interrupt, user, and supervisor mode stacks. + +Pre-Indexing Address Mode +------------------------- + +The macro ``M68K_HAS_PREINDEXING`` is set to 1 to indicate that this CPU model +has the pre-indexing address mode. + +Extend Byte to Long Instruction +------------------------------- + +The macro ``M68K_HAS_EXTB_L`` is set to 1 to indicate that this CPU model has +the extb.l instruction. This instruction is supposed to be available in all +models based on the cpu32 core as well as mc68020 and up models. + +Calling Conventions +=================== + +The MC68xxx architecture supports a simple yet effective call and return +mechanism. A subroutine is invoked via the branch to subroutine (``bsr``) or +the jump to subroutine (``jsr``) instructions. These instructions push the +return address on the current stack. The return from subroutine (``rts``) +instruction pops the return address off the current stack and transfers control +to that instruction. It is is important to note that the MC68xxx 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. + +Calling Mechanism +----------------- + +All RTEMS directives are invoked using either a ``bsr`` or ``jsr`` instruction +and return to the user application via the rts instruction. + +Register Usage +-------------- + +As discussed above, the ``bsr`` and ``jsr`` instructions do not automatically +save any registers. RTEMS uses the registers D0, D1, A0, and 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. + +Parameter Passing +----------------- + +RTEMS assumes that arguments are placed on the current stack before the +directive is invoked via the bsr or jsr 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: + +.. code-block:: c + + push third argument + push second argument + push first argument + invoke directive + remove arguments from the stack + +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. + +Memory Model +============ + +The MC68xxx 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 MC68xxx family members such as the MC68020, MC68030, and MC68040 +support virtual memory and segmentation. The MC68020 requires external +hardware support such as the MC68851 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 MC68xxx +family members. + +Interrupt Processing +==================== + +Discussed in this section are the MC68xxx's interrupt response and control +mechanisms as they pertain to RTEMS. + +Vectoring of an Interrupt Handler +--------------------------------- + +Depending on whether or not the particular CPU supports a separate interrupt +stack, the MC68xxx family has two different interrupt handling models. + +Models Without Separate Interrupt Stacks +~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +Upon receipt of an interrupt the MC68xxx family members without separate +interrupt stacks automatically use software to switch stacks. + +Models With Separate Interrupt Stacks +~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +Upon receipt of an interrupt the MC68xxx family members with separate interrupt +stacks automatically perform the following actions: + +- saves the current status register (SR), + +- clears the master/interrupt (M) bit of the SR to indicate the switch from + master state to interrupt state, + +- sets the privilege mode to supervisor, + +- suppresses tracing, + +- sets the interrupt mask level equal to the level of the interrupt being + serviced, + +- 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, + +- 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. + +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 MC68xxx CPU models with +separate interrupt stacks: + ++----------------------+-----+ +| Status Register | 0x0 | ++----------------------+-----+ +| Program Counter High | 0x2 | ++----------------------+-----+ +| Program Counter Low | 0x4 | ++----------------------+-----+ +| Format/Vector Offset | 0x6 | ++----------------------+-----+ + + +CPU Models Without VBR and RAM at 0 +----------------------------------- + +This is from a post by Zoltan Kocsi and is a nice trick +in certain situations. In his words: + +I think somebody on this list asked about the interupt vector handling w/o VBR +and RAM at 0. The usual trick is to initialise the vector table (except the +first 2 two entries, of course) to point to the same location BUT you also add +the vector number times 0x1000000 to them. That is, bits 31-24 contain the +vector number and 23-0 the address of the common handler. Since the PC is 32 +bit wide but the actual address bus is only 24, the top byte will be in the PC +but will be ignored when jumping onto your routine. + +Then your common interrupt routine gets this info by loading the PC into some +register and based on that info, you can jump to a vector in a vector table +pointed by a virtual VBR: + +.. code-block:: c + + // + // Real vector table at 0 + // + .long initial_sp + .long initial_pc + .long myhandler+0x02000000 + .long myhandler+0x03000000 + .long myhandler+0x04000000 + ... + .long myhandler+0xff000000 + // + // This handler will jump to the interrupt routine of which + // the address is stored at VBR[ vector_no ] + // The registers and stackframe will be intact, the interrupt + // routine will see exactly what it would see if it was called + // directly from the HW vector table at 0. + // + .comm VBR,4,2 // This defines the 'virtual' VBR + // From C: extern void *VBR; + myhandler: // At entry, PC contains the full vector + move.l %d0,-(%sp) // Save d0 + move.l %a0,-(%sp) // Save a0 + lea 0(%pc),%a0 // Get the value of the PC + move.l %a0,%d0 // Copy it to a data reg, d0 is VV?????? + swap %d0 // Now d0 is ????VV?? + and.w #0xff00,%d0 // Now d0 is ????VV00 (1) + lsr.w #6,%d0 // Now d0.w contains the VBR table offset + move.l VBR,%a0 // Get the address from VBR to a0 + move.l (%a0,%d0.w),%a0 // Fetch the vector + move.l 4(%sp),%d0 // Restore d0 + move.l %a0,4(%sp) // Place target address to the stack + move.l (%sp)+,%a0 // Restore a0, target address is on TOS + ret // This will jump to the handler and + // restore the stack + +(1) If 'myhandler' is guaranteed to be in the first 64K, e.g. just + after the vector table then that insn is not needed. + +There are probably shorter ways to do this, but it I believe is enough to +illustrate the trick. Optimisation is left as an exercise to the reader :-) + +Interrupt Levels +---------------- + +Eight levels (0-7) of interrupt priorities are supported by MC68xxx 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 MC68xxx family only supports +eight. RTEMS interrupt levels 0 through 7 directly correspond to MC68xxx +interrupt levels. All other RTEMS interrupt levels are undefined and their +behavior is unpredictable. + +Default Fatal Error Processing +============================== + +The default fatal error handler for this architecture disables processor +interrupts to level 7, places the error code in D0, and executes a ``stop`` +instruction to simulate a halt processor instruction. + +Symmetric Multiprocessing +========================= + +SMP is not supported. + +Thread-Local Storage +==================== + +Thread-local storage is supported. + +Board Support Packages +====================== + +System Reset +------------ + +An RTEMS based application is initiated or re-initiated when the MC68020 +processor is reset. When the MC68020 is reset, the processor performs the +following actions: + +- The tracing bits of the status register are cleared to disable tracing. + +- The supervisor interrupt state is entered by setting the supervisor (S) bit + and clearing the master/interrupt (M) bit of the status register. + +- The interrupt mask of the status register is set to level 7 to effectively + disable all maskable interrupts. + +- The vector base register (VBR) is set to zero. + +- The cache control register (CACR) is set to zero to disable and freeze the + processor cache. + +- The interrupt stack pointer (ISP) is set to the value stored at vector 0 + (bytes 0-3) of the exception vector table (EVT). + +- The program counter (PC) is set to the value stored at vector 1 (bytes 4-7) + of the EVT. + +- The processor begins execution at the address stored in the PC. + +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 MC68020's VBR value. Because interrupts are enabled +automatically by RTEMS as part of the context switch to the first task, the VBR +MUST be set by either RTEMS of the BSP before this occurs ensure 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 MC68020 version has the following +specific requirements: + +- Must leave the S bit of the status register set so that the MC68020 remains + in the supervisor state. + +- Must set the M bit of the status register to remove the MC68020 from the + interrupt state. + +- 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. + +- Must initialize the MC68020's vector table. diff --git a/cpu-supplement/mips.rst b/cpu-supplement/mips.rst new file mode 100644 index 0000000..aca10ec --- /dev/null +++ b/cpu-supplement/mips.rst @@ -0,0 +1,125 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: Copyright (c) 2014 embedded brains GmbH. All rights reserved. + +MIPS Specific Information +######################### + +This chapter discusses the MIPS architecture dependencies in this port of +RTEMS. The MIPS family has a wide variety of implementations by a wide range +of vendors. Consequently, there are many, many CPU models within it. + +**Architecture Documents** + +IDT docs are online at http://www.idt.com/products/risc/Welcome.html + +CPU Model Dependent Features +============================ + +This section presents the set of features which vary across MIPS +implementations and are of importance to RTEMS. The set of CPU model feature +macros are defined in the file ``cpukit/score/cpu/mips/mips.h`` based upon the +particular CPU model specified on the compilation command line. + +Another Optional Feature +------------------------ + +The macro XXX + +Calling Conventions +=================== + +Processor Background +-------------------- + +TBD + +Calling Mechanism +----------------- + +TBD + +Register Usage +-------------- + +TBD + +Parameter Passing +----------------- + +TBD + +Memory Model +============ + +Flat Memory Model +----------------- + +The MIPS 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 MIPS family members such as the support virtual memory and +segmentation. RTEMS does not support virtual memory or segmentation on any of +these family members. + +Interrupt Processing +==================== + +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 MIPS's interrupt response and control mechanisms as they pertain to RTEMS. + +Vectoring of an Interrupt Handler +--------------------------------- + +Upon receipt of an interrupt the XXX family members with separate interrupt +stacks automatically perform the following actions: + +- TBD + +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. + +Interrupt Levels +---------------- + +TBD + +Default Fatal Error Processing +============================== + +The default fatal error handler for this target architecture disables processor +interrupts, places the error code in *XXX*, and executes a``XXX`` instruction +to simulate a halt processor instruction. + +Symmetric Multiprocessing +========================= + +SMP is not supported. + +Thread-Local Storage +==================== + +Thread-local storage is not implemented. + +Board Support Packages +====================== + +System Reset +------------ + +An RTEMS based application is initiated or re-initiated when the processor is +reset. When the processor is reset, it performs the following actions: + +- TBD + +Processor Initialization +------------------------ + +TBD diff --git a/cpu-supplement/openrisc_1000.rst b/cpu-supplement/openrisc_1000.rst new file mode 100644 index 0000000..c9d6127 --- /dev/null +++ b/cpu-supplement/openrisc_1000.rst @@ -0,0 +1,97 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: COPYRIGHT (c) 1989-2007. +.. COMMENT: On-Line Applications Research Corporation (OAR). +.. COMMENT: All rights reserved. + +OpenRISC 1000 Specific Information +################################## + +This chapter discusses the`OpenRISC 1000 architecture +http://opencores.org/or1k/Main_Page dependencies in this port of RTEMS. There +are many implementations for OpenRISC like or1200 and mor1kx. Currently RTEMS +supports basic features that all implementations should have. + +**Architecture Documents** + +For information on the OpenRISC 1000 architecture refer to the`OpenRISC 1000 +architecture manual http://openrisc.github.io/or1k.html. + +Calling Conventions +=================== + +Please refer to the`Function Calling Sequence +http://openrisc.github.io/or1k.html#__RefHeading__504887_595890882. + +Floating Point Unit +------------------- + +A floating point unit is currently not supported. + +Memory Model +============ + +A flat 32-bit memory model is supported. + +Interrupt Processing +==================== + +OpenRISC 1000 architecture has 13 exception types: + +- Reset + +- Bus Error + +- Data Page Fault + +- Instruction Page Fault + +- Tick Timer + +- Alignment + +- Illegal Instruction + +- External Interrupt + +- D-TLB Miss + +- I-TLB Miss + +- Range + +- System Call + +- Floating Point + +- Trap + +Interrupt Levels +---------------- + +There are only two levels: interrupts enabled and interrupts disabled. + +Interrupt Stack +--------------- + +The OpenRISC RTEMS port uses a dedicated software interrupt stack. The stack +for interrupts is allocated during interrupt driver initialization. When an +interrupt is entered, the _ISR_Handler routine is responsible for switching +from the interrupted task stack to RTEMS software interrupt stack. + +Default Fatal Error Processing +============================== + +The default fatal error handler for this architecture performs the following +actions: + +- disables operating system supported interrupts (IRQ), + +- places the error code in ``r0``, and + +- executes an infinite loop to simulate a halt processor instruction. + +Symmetric Multiprocessing +========================= + +SMP is not supported. diff --git a/cpu-supplement/port.rst b/cpu-supplement/port.rst new file mode 100644 index 0000000..9ccd2f4 --- /dev/null +++ b/cpu-supplement/port.rst @@ -0,0 +1,422 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: COPYRIGHT (c) 1988-2002. +.. COMMENT: On-Line Applications Research Corporation (OAR). +.. COMMENT: All rights reserved. + +Port Specific Information +######################### + +This chaper provides a general description of the type of architecture specific +information which is in each of the architecture specific chapters that follow. +The outline of this chapter is identical to that of the architecture specific +chapters. + +In each of the architecture specific chapters, this introductory section will +provide an overview of the architecture: + +**Architecture Documents** + +In each of the architecture specific chapters, this section will provide +pointers on where to obtain documentation. + +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 Motorola 68000 and the +Intel x86 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. + +The set of CPU model feature macros are defined in the +:file:`cpukit/score/cpu/CPU/rtems/score/cpu.h` based upon the GNU tools +multilib variant that is appropriate for the particular CPU model defined on +the compilation command line. + +In each of the architecture specific chapters, this section presents the set of +features which vary across various implementations of the architecture that may +be of importance to RTEMS application developers. + +The subsections will vary amongst the target architecture chapters as the +specific features may vary. However, each port will include a few common +features such as the CPU Model Name and presence of a hardware Floating Point +Unit. The common features are described here. + +CPU Model Name +-------------- + +The macro ``CPU_MODEL_NAME`` is a string which designates the name of this CPU +model. For example, for the MC68020 processor model from the m68k +architecture, this macro is set to the string "mc68020". + +Floating Point Unit +------------------- + +In most architectures, the presence of a floating point unit is an option. It +does not matter whether the hardware floating point support is incorporated +on-chip or is an external coprocessor as long as it appears an FPU per the ISA. +However, if a hardware FPU is not present, it is possible that the floating +point emulation library for this CPU is not reentrant and thus context switched +by RTEMS. + +RTEMS provides two feature macros to indicate the FPU configuration: + +- CPU_HARDWARE_FP + is set to TRUE to indicate that a hardware FPU is present. + +- CPU_SOFTWARE_FP + is set to TRUE to indicate that a hardware FPU is not present and that the FP + software emulation will be context switched. + +Multilibs +========= + +Newlib and GCC provide several target libraries like the :file:`libc.a`, +:file:`libm.a` and :file:`libgcc.a`. These libraries are artifacts of the GCC +build process. Newlib is built together with GCC. To provide optimal support +for various chip derivatives and instruction set revisions multiple variants of +these libraries are available for each architecture. For example one set may +use software floating point support and another set may use hardware floating +point instructions. These sets of libraries are called *multilibs*. Each +library set corresponds to an application binary interface (ABI) and +instruction set. + +A multilib variant can be usually detected via built-in compiler defines at +compile-time. This mechanism is used by RTEMS to select for example the +context switch support for a particular BSP. The built-in compiler defines +corresponding to multilibs are the only architecture specific defines allowed +in the ``cpukit`` area of the RTEMS sources. + +Invoking the GCC with the ``-print-multi-lib`` option lists the available +multilibs. Each line of the output describes one multilib variant. The +default variant is denoted by ``.`` which is selected when no or contradicting +GCC machine options are selected. The multilib selection for a target is +specified by target makefile fragments (see file :file:`t-rtems` in the GCC +sources and section *The Target Makefile Fragment* +(https://gcc.gnu.org/onlinedocs/gccint/Target-Fragment.html#Target-Fragment) +in the *GCC Internals Manual* (https://gcc.gnu.org/onlinedocs/gccint/). + +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: + +- register preservation and usage + +- parameter passing + +- call and return mechanism + +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. + +Calling Mechanism +----------------- + +In each of the architecture specific chapters, this subsection will describe +the instruction(s) used to perform a *normal* subroutine invocation. All RTEMS +directives are invoked as *normal* C language functions so it is important to +the user application to understand the call and return mechanism. + +Register Usage +-------------- + +In each of the architecture specific chapters, this subsection will detail the +set of registers which are *NOT* preserved across subroutine invocations. The +registers which are not preserved are assumed to be available for use as +scratch registers. Therefore, the contents of these registers should not be +assumed upon return from any RTEMS directive. + +In some architectures, there may be a set of registers made available +automatically as a side-effect of the subroutine invocation mechanism. + +Parameter Passing +----------------- + +In each of the architecture specific chapters, this subsection will describe +the mechanism by which the parameters or arguments are passed by the caller to +a subroutine. In some architectures, all parameters are passed on the stack +while in others some are passed in registers. + +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. + +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. + +Flat Memory Model +----------------- + +Most RTEMS target processors can be initialized to support a flat address +space. Although the size of addresses varies between architectures, on most +RTEMS targets, an address is 32-bits wide which defines 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 may be performed in little or big endian fashion. + +On smaller CPU architectures supported by RTEMS, the address space may only be +20 or 24 bits wide. + +If the CPU model has support for virtual memory or segmentation, it is the +responsibility of the Board Support Package (BSP) to initialize the MMU +hardware to perform address translations which correspond to flat memory model. + +In each of the architecture specific chapters, this subsection will describe +any architecture characteristics that differ from this general description. + +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. + +RTEMS supports a dedicated interrupt stack for all architectures. On +architectures with hardware support for a dedicated interrupt stack, it will be +initialized such that when an interrupt occurs, the processor automatically +switches to this dedicated stack. On architectures without hardware support +for a dedicated interrupt stack which is separate from those of the tasks, +RTEMS will support switching to a dedicated stack for interrupt processing. + +Without a dedicated interrupt stack, every task in the system MUST have enough +stack space to accommodate the worst case stack usage of that particular task +and the interrupt service routines COMBINED. By supporting a dedicated +interrupt stack, RTEMS significantly lowers the stack requirements for each +task. + +A nested interrupt is processed similarly with the exception that since the CPU +is already executing on the interrupt stack, there is no need to switch to the +interrupt stack. + +In some configurations, RTEMS allocates the interrupt stack from the Workspace +Area. The amount of memory allocated for the interrupt stack is user +configured and based upon the ``confdefs.h`` parameter +``CONFIGURE_INTERRUPT_STACK_SIZE``. This parameter is described in detail in +the Configuring a System chapter of the User's Guide. On configurations in +which RTEMS allocates the interrupt stack, during the initialization process, +RTEMS will also install its interrupt stack. In other configurations, the +interrupt stack is allocated and installed by the Board Support Package (BSP). + +In each of the architecture specific chapters, this section discesses the +interrupt response and control mechanisms of the architecture as they pertain +to RTEMS. + +Vectoring of an Interrupt Handler +--------------------------------- + +In each of the architecture specific chapters, this subsection will describe +the architecture specific details of the interrupt vectoring process. In +particular, it should include a description of the Interrupt Stack Frame (ISF). + +Interrupt Levels +---------------- + +In each of the architecture specific chapters, this subsection will describe +how the interrupt levels available on this particular architecture are mapped +onto the 255 reserved in the task mode. The interrupt level value of zero (0) +should always mean that interrupts are enabled. + +Any use of an interrupt level that is is not undefined on a particular +architecture may result in behavior that is unpredictable. + +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 all external +interrupts before the execution of this section and restores them to the +previous level upon completion of the section. RTEMS has been optimized to +ensure that interrupts are disabled for the shortest number of instructions +possible. Since the precise number of instructions and their execution time +varies based upon target CPU family, CPU model, board memory speed, compiler +version, and optimization level, it is not practical to provide the precise +number for all possible RTEMS configurations. + +Historically, the measurements were made by hand analyzing and counting the +execution time of instruction sequences during interrupt disable critical +sections. For reference purposes, on a 16 Mhz Motorola MC68020, the maximum +interrupt disable period was typically approximately ten (10) to thirteen (13) +microseconds. This architecture was memory bound and had a slow bit scan +instruction. In contrast, during the same period a 14 Mhz SPARC would have a +worst case disable time of approximately two (2) to three (3) microseconds +because it had a single cycle bit scan instruction and used fewer cycles for +memory accesses. + +If you are interested in knowing the worst case execution time for a particular +version of RTEMS, please contact OAR Corporation and we will be happy to +product the results as a consulting service. + +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. + +Default Fatal Error Processing +============================== + +Upon detection of a fatal error by either the application or RTEMS during +initialization the ``rtems_fatal_error_occurred`` directive supplied by 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 or all of them return without taking action to shutdown the +processor or reset, a default fatal error handler is invoked. + +Most of the action performed as part of processing the fatal error are +described in detail in the Fatal Error Manager chapter in the User's Guide. +However, the if no user provided extension or BSP specific fatal error handler +takes action, the final default action is to invoke a CPU architecture specific +function. Typically this function disables interrupts and halts the processor. + +In each of the architecture specific chapters, this describes the precise +operations of the default CPU specific fatal error handler. + +Symmetric Multiprocessing +========================= + +This section contains information about the Symmetric Multiprocessing (SMP) +status of a particular architecture. + +Thread-Local Storage +==================== + +In order to support thread-local storage (TLS) the CPU port must implement the +facilities mandated by the application binary interface (ABI) of the CPU +architecture. The CPU port must initialize the TLS area in the +``_CPU_Context_Initialize()`` function. There are support functions available +via ``#include `` which implement Variants I and II +according to Ulrich Drepper, *ELF Handling For Thread-Local Storage*. + +``_TLS_TCB_at_area_begin_initialize()`` + Uses Variant I, TLS offsets emitted by linker takes the TCB into account. + For a reference implementation see :file:`cpukit/score/cpu/arm/cpu.c`. + +``_TLS_TCB_before_TLS_block_initialize()`` + Uses Variant I, TLS offsets emitted by linker neglects the TCB. For a + reference implementation see + :file:`c/src/lib/libcpu/powerpc/new-exceptions/cpu.c`. + +``_TLS_TCB_after_TLS_block_initialize()`` + Uses Variant II. For a reference implementation see + :file:`cpukit/score/cpu/sparc/cpu.c`. + +The board support package (BSP) must provide the following sections and symbols +in its linker command file: + +.. code-block:: c + + .tdata : { + _TLS_Data_begin = .; + *(.tdata .tdata.* .gnu.linkonce.td.*) + _TLS_Data_end = .; + } + .tbss : { + _TLS_BSS_begin = .; + *(.tbss .tbss.* .gnu.linkonce.tb.*) *(.tcommon) + _TLS_BSS_end = .; + } + _TLS_Data_size = _TLS_Data_end - _TLS_Data_begin; + _TLS_Data_begin = _TLS_Data_size != 0 ? _TLS_Data_begin : _TLS_BSS_begin; + _TLS_Data_end = _TLS_Data_size != 0 ? _TLS_Data_end : _TLS_BSS_begin; + _TLS_BSS_size = _TLS_BSS_end - _TLS_BSS_begin; + _TLS_Size = _TLS_BSS_end - _TLS_Data_begin; + _TLS_Alignment = MAX (ALIGNOF (.tdata), ALIGNOF (.tbss)); + +CPU counter +=========== + +The CPU support must implement the CPU counter interface. A CPU counter is +some free-running counter. It ticks usually with a frequency close to the CPU +or system bus clock. On some architectures the actual implementation is board +support package dependent. The CPU counter is used for profiling of low-level +functions. It is also used to implement two busy wait functions +``rtems_counter_delay_ticks()`` and ``rtems_counter_delay_nanoseconds()`` which +may be used in device drivers. It may be also used as an entropy source for +random number generators. + +The CPU counter interface uses a CPU port specific unsigned integer type +``CPU_Counter_ticks`` to represent CPU counter values. The CPU port must +provide the following two functions + +- ``_CPU_Counter_read()`` to read the current CPU counter value, and + +- ``_CPU_Counter_difference()`` to get the difference between two CPU + counter values. + +Interrupt Profiling +=================== + +The RTEMS profiling needs support by the CPU port for the interrupt entry and +exit times. In case profiling is enabled via the RTEMS build configuration +option ``--enable-profiling`` (in this case the pre-processor symbol +``RTEMS_PROFILING`` is defined) the CPU port may provide data for the interrupt +entry and exit times of the outer-most interrupt. The CPU port can feed +interrupt entry and exit times with the +``_Profiling_Outer_most_interrupt_entry_and_exit()`` function (``#include +``). For an example please have a look at +:file:`cpukit/score/cpu/arm/arm_exc_interrupt.S`. + +Board Support Packages +====================== + +An RTEMS Board Support Package (BSP) must be designed to support a particular +processor model and target board combination. + +In each of the architecture specific chapters, this section will present a +discussion of architecture specific BSP issues. For more information on +developing a BSP, refer to BSP and Device Driver Development Guide and the +chapter titled Board Support Packages in the RTEMS Applications User's Guide. + +System Reset +------------ + +An RTEMS based application is initiated or re-initiated when the processor is +reset or transfer is passed to it from a boot monitor or ROM monitor. + +In each of the architecture specific chapters, this subsection describes the +actions that the BSP must tak assuming the application gets control when the +microprocessor is reset. diff --git a/cpu-supplement/powerpc.rst b/cpu-supplement/powerpc.rst new file mode 100644 index 0000000..8a7f92e --- /dev/null +++ b/cpu-supplement/powerpc.rst @@ -0,0 +1,569 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: COPYRIGHT (c) 1988-2002. +.. COMMENT: On-Line Applications Research Corporation (OAR). +.. COMMENT: All rights reserved. + +PowerPC Specific Information +############################ + +This chapter discusses the PowerPC architecture dependencies in this port of +RTEMS. The PowerPC family has a wide variety of implementations by a range of +vendors. Consequently, there are many, many CPU models within it. + +It is highly recommended that the PowerPC RTEMS application developer obtain +and become familiar with the documentation for the processor being used as well +as the specification for the revision of the PowerPC architecture which +corresponds to that processor. + +**PowerPC Architecture Documents** + +For information on the PowerPC architecture, refer to the following documents +available from Motorola and IBM: + +- *PowerPC Microprocessor Family: The Programming Environment* + (Motorola Document MPRPPCFPE-01). + +- *IBM PPC403GB Embedded Controller User's Manual*. + +- *PoweRisControl MPC500 Family RCPU RISC Central Processing + Unit Reference Manual* (Motorola Document RCPUURM/AD). + +- *PowerPC 601 RISC Microprocessor User's Manual* + (Motorola Document MPR601UM/AD). + +- *PowerPC 603 RISC Microprocessor User's Manual* + (Motorola Document MPR603UM/AD). + +- *PowerPC 603e RISC Microprocessor User's Manual* + (Motorola Document MPR603EUM/AD). + +- *PowerPC 604 RISC Microprocessor User's Manual* + (Motorola Document MPR604UM/AD). + +- *PowerPC MPC821 Portable Systems Microprocessor User's Manual* + (Motorola Document MPC821UM/AD). + +- *PowerQUICC MPC860 User's Manual* + (Motorola Document MPC860UM/AD). + +Motorola maintains an on-line electronic library for the PowerPC at the +following URL: + +- http://www.mot.com/powerpc/library/library.html + +This site has a a wealth of information and examples. Many of the manuals are +available from that site in electronic format. + +**PowerPC Processor Simulator Information** + +PSIM is a program which emulates the Instruction Set Architecture of the +PowerPC microprocessor family. It is reely available in source code form under +the terms of the GNU General Public License (version 2 or later). PSIM can be +integrated with the GNU Debugger (gdb) to execute and debug PowerPC executables +on non-PowerPC hosts. PSIM supports the addition of user provided device +models which can be used to allow one to develop and debug embedded +applications using the simulator. + +The latest version of PSIM is included in GDB and enabled on pre-built binaries +provided by the RTEMS Project. + +CPU Model Dependent Features +============================ + +This section presents the set of features which vary across PowerPC +implementations and are of importance to RTEMS. The set of CPU model feature +macros are defined in the file ``cpukit/score/cpu/powerpc/powerpc.h`` based +upon the particular CPU model specified on the compilation command line. + +Alignment +--------- + +The macro PPC_ALIGNMENT is set to the PowerPC model's worst case alignment +requirement for data types on a byte boundary. This value is used to derive +the alignment restrictions for memory allocated from regions and partitions. + +Cache Alignment +--------------- + +The macro PPC_CACHE_ALIGNMENT is set to the line size of the cache. It is used +to align the entry point of critical routines so that as much code as possible +can be retrieved with the initial read into cache. This is done for the +interrupt handler as well as the context switch routines. + +In addition, the "shortcut" data structure used by the PowerPC implementation +to ease access to data elements frequently accessed by RTEMS routines +implemented in assembly language is aligned using this value. + +Maximum Interrupts +------------------ + +The macro PPC_INTERRUPT_MAX is set to the number of exception sources supported +by this PowerPC model. + +Has Double Precision Floating Point +----------------------------------- + +The macro PPC_HAS_DOUBLE is set to 1 to indicate that the PowerPC model has +support for double precision floating point numbers. This is important because +the floating point registers need only be four bytes wide (not eight) if double +precision is not supported. + +Critical Interrupts +------------------- + +The macro PPC_HAS_RFCI is set to 1 to indicate that the PowerPC model has the +Critical Interrupt capability as defined by the IBM 403 models. + +Use Multiword Load/Store Instructions +------------------------------------- + +The macro PPC_USE_MULTIPLE is set to 1 to indicate that multiword load and +store instructions should be used to perform context switch operations. The +relative efficiency of multiword load and store instructions versus an +equivalent set of single word load and store instructions varies based upon the +PowerPC model. + +Instruction Cache Size +---------------------- + +The macro PPC_I_CACHE is set to the size in bytes of the instruction cache. + +Data Cache Size +--------------- + +The macro PPC_D_CACHE is set to the size in bytes of the data cache. + +Debug Model +----------- + +The macro PPC_DEBUG_MODEL is set to indicate the debug support features present +in this CPU model. The following debug support feature sets are currently +supported: + +*``PPC_DEBUG_MODEL_STANDARD``* + indicates that the single-step trace enable (SE) and branch trace enable + (BE) bits in the MSR are supported by this CPU model. + +*``PPC_DEBUG_MODEL_SINGLE_STEP_ONLY``* + indicates that only the single-step trace enable (SE) bit in the MSR is + supported by this CPU model. + +*``PPC_DEBUG_MODEL_IBM4xx``* + indicates that the debug exception enable (DE) bit in the MSR is supported + by this CPU model. At this time, this particular debug feature set has + only been seen in the IBM 4xx series. + +Low Power Model +~~~~~~~~~~~~~~~ + +The macro PPC_LOW_POWER_MODE is set to indicate the low power model supported +by this CPU model. The following low power modes are currently supported. + +*``PPC_LOW_POWER_MODE_NONE``* + indicates that this CPU model has no low power mode support. + +*``PPC_LOW_POWER_MODE_STANDARD``* + indicates that this CPU model follows the low power model defined for the + PPC603e. + +Multilibs +========= + +The following multilibs are available: + +#. ``.``: 32-bit PowerPC with FPU + +#. ``nof``: 32-bit PowerPC with software floating point support + +#. ``m403``: Instruction set for PPC403 with FPU + +#. ``m505``: Instruction set for MPC505 with FPU + +#. ``m603e``: Instruction set for MPC603e with FPU + +#. ``m603e/nof``: Instruction set for MPC603e with software floating + point support + +#. ``m604``: Instruction set for MPC604 with FPU + +#. ``m604/nof``: Instruction set for MPC604 with software floating point + support + +#. ``m860``: Instruction set for MPC860 with FPU + +#. ``m7400``: Instruction set for MPC7500 with FPU + +#. ``m7400/nof``: Instruction set for MPC7500 with software floating + point support + +#. ``m8540``: Instruction set for e200, e500 and e500v2 cores with + single-precision FPU and SPE + +#. ``m8540/gprsdouble``: Instruction set for e200, e500 and e500v2 cores + with double-precision FPU and SPE + +#. ``m8540/nof/nospe``: Instruction set for e200, e500 and e500v2 cores + with software floating point support and no SPE + +#. ``me6500/m32``: 32-bit instruction set for e6500 core with FPU and + AltiVec + +#. ``me6500/m32/nof/noaltivec``: 32-bit instruction set for e6500 core + with software floating point support and no AltiVec + +Calling Conventions +=================== + +RTEMS supports the Embedded Application Binary Interface (EABI) calling +convention. Documentation for EABI is available by sending a message with a +subject line of "EABI" to eabi@goth.sis.mot.com. + +Programming Model +----------------- + +This section discusses the programming model for the PowerPC architecture. + +Non-Floating Point Registers +~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +The PowerPC architecture defines thirty-two non-floating point registers +directly visible to the programmer. In thirty-two bit implementations, each +register is thirty-two bits wide. In sixty-four bit implementations, each +register is sixty-four bits wide. + +These registers are referred to as ``gpr0`` to ``gpr31``. + +Some of the registers serve defined roles in the EABI programming model. The +following table describes the role of each of these registers: + ++---------------+----------------+------------------------------+ +| Register Name | Alternate Name | Description | ++---------------+----------------+------------------------------+ +| r1 | sp | stack pointer | ++---------------+----------------+------------------------------+ +| | | global pointer to the Small | +| r2 | na | Constant Area (SDA2) | ++---------------+----------------+------------------------------+ +| r3 - r12 | na | parameter and result passing | ++---------------+----------------+------------------------------+ +| | | global pointer to the Small | +| r13 | na | Data Area (SDA) | ++---------------+----------------+------------------------------+ + +Floating Point Registers +~~~~~~~~~~~~~~~~~~~~~~~~ + +The PowerPC architecture includes thirty-two, sixty-four bit floating point +registers. All PowerPC floating point instructions interpret these registers +as 32 double precision floating point registers, regardless of whether the +processor has 64-bit or 32-bit implementation. + +The floating point status and control register (fpscr) records exceptions and +the type of result generated by floating-point operations. Additionally, it +controls the rounding mode of operations and allows the reporting of floating +exceptions to be enabled or disabled. + +Special Registers +~~~~~~~~~~~~~~~~~ + +The PowerPC architecture includes a number of special registers which are +critical to the programming model: + +*Machine State Register* + The MSR contains the processor mode, power management mode, endian mode, + exception information, privilege level, floating point available and + floating point excepiton mode, address translation information and the + exception prefix. + +*Link Register* + The LR contains the return address after a function call. This register + must be saved before a subsequent subroutine call can be made. The use of + this register is discussed further in the *Call and Return Mechanism* + section below. + +*Count Register* + The CTR contains the iteration variable for some loops. It may also be + used for indirect function calls and jumps. + +Call and Return Mechanism +------------------------- + +The PowerPC architecture supports a simple yet effective call and return +mechanism. A subroutine is invoked via the "branch and link" (``bl``) and +"brank and link absolute" (``bla``) instructions. This instructions place the +return address in the Link Register (LR). The callee returns to the caller by +executing a "branch unconditional to the link register" (``blr``) instruction. +Thus the callee returns to the caller via a jump to the return address which is +stored in the LR. + +The previous contents of the LR are not automatically saved by either the +``bl`` or ``bla``. It is the responsibility of the callee to save the contents +of the LR before invoking another subroutine. If the callee invokes another +subroutine, it must restore the LR before executing the ``blr`` instruction to +return to the caller. + +It is important to note that the PowerPC subroutine call and return mechanism +does not automatically save and restore any registers. + +The LR may be accessed as special purpose register 8 (``SPR8``) using the "move +from special register" (``mfspr``) and "move to special register" (``mtspr``) +instructions. + +Calling Mechanism +----------------- + +All RTEMS directives are invoked using the regular PowerPC EABI calling +convention via the ``bl`` or``bla`` instructions. + +Register Usage +-------------- + +As discussed above, the call instruction does not automatically save any +registers. It is the responsibility of the callee to save and restore any +registers which must be preserved across subroutine calls. The callee is +responsible for saving callee-preserved registers to the program stack and +restoring them before returning to the caller. + +Parameter Passing +----------------- + +RTEMS assumes that arguments are placed in the general purpose registers with +the first argument in register 3 (``r3``), the second argument in general +purpose register 4 (``r4``), and so forth until the seventh argument is in +general purpose register 10 (``r10``). If there are more than seven arguments, +then subsequent arguments are placed on the program stack. The following +pseudo-code illustrates the typical sequence used to call a RTEMS directive +with three (3) arguments: + +.. code-block:: c + + load third argument into r5 + load second argument into r4 + load first argument into r3 + invoke directive + +Memory Model +============ + +Flat Memory Model +----------------- + +The PowerPC architecture supports a variety of memory models. RTEMS supports +the PowerPC using a flat memory model with paging disabled. In this mode, the +PowerPC automatically converts every address from a logical to a physical +address each time it is used. The PowerPC uses information provided in the +Block Address Translation (BAT) to convert these addresses. + +Implementations of the PowerPC architecture may be thirty-two or sixty-four +bit. The PowerPC architecture supports a flat thirty-two or sixty-four bit +address space with addresses ranging from 0x00000000 to 0xFFFFFFFF (4 +gigabytes) in thirty-two bit implementations or to 0xFFFFFFFFFFFFFFFF in +sixty-four bit implementations. Each address is represented by either a +thirty-two bit or sixty-four bit value and is byte addressable. The address +may be used to reference a single byte, half-word (2-bytes), word (4 bytes), or +in sixty-four bit implementations a doubleword (8 bytes). Memory accesses +within the address space are performed in big or little endian fashion by the +PowerPC based upon the current setting of the Little-endian mode enable bit +(LE) in the Machine State Register (MSR). While the processor is in big endian +mode, memory accesses which are not properly aligned generate an "alignment +exception" (vector offset 0x00600). In little endian mode, the PowerPC +architecture does not require the processor to generate alignment exceptions. + +The following table lists the alignment requirements for a variety of data +accesses: + +============== ====================== +Data Type Alignment Requirement +============== ====================== +byte 1 +half-word 2 +word 4 +doubleword 8 +============== ====================== + +Doubleword load and store operations are only available in PowerPC CPU models +which are sixty-four bit implementations. + +RTEMS does not directly support any PowerPC Memory Management Units, therefore, +virtual memory or segmentation systems involving the PowerPC are not supported. + +Interrupt Processing +==================== + +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 PowerPC's interrupt response and control mechanisms as they pertain to +RTEMS. + +RTEMS and associated documentation uses the terms interrupt and vector. In the +PowerPC architecture, these terms correspond to exception and exception +handler, respectively. The terms will be used interchangeably in this manual. + +Synchronous Versus Asynchronous Exceptions +------------------------------------------ + +In the PowerPC architecture exceptions can be either precise or imprecise and +either synchronous or asynchronous. Asynchronous exceptions occur when an +external event interrupts the processor. Synchronous exceptions are caused by +the actions of an instruction. During an exception SRR0 is used to calculate +where instruction processing should resume. All instructions prior to the +resume instruction will have completed execution. SRR1 is used to store the +machine status. + +There are two asynchronous nonmaskable, highest-priority exceptions system +reset and machine check. There are two asynchrononous maskable low-priority +exceptions external interrupt and decrementer. Nonmaskable execptions are +never delayed, therefore if two nonmaskable, asynchronous exceptions occur in +immediate succession, the state information saved by the first exception may be +overwritten when the subsequent exception occurs. + +The PowerPC arcitecure defines one imprecise exception, the imprecise floating +point enabled exception. All other synchronous exceptions are precise. The +synchronization occuring during asynchronous precise exceptions conforms to the +requirements for context synchronization. + +Vectoring of Interrupt Handler +------------------------------ + +Upon determining that an exception can be taken the PowerPC automatically +performs the following actions: + +- an instruction address is loaded into SRR0 + +- bits 33-36 and 42-47 of SRR1 are loaded with information specific to the + exception. + +- bits 0-32, 37-41, and 48-63 of SRR1 are loaded with corresponding bits from + the MSR. + +- the MSR is set based upon the exception type. + +- instruction fetch and execution resumes, using the new MSR value, at a + location specific to the execption type. + +If the interrupt handler was installed as an RTEMS interrupt handler, then upon +receipt of the interrupt, the processor passes control to the RTEMS interrupt +handler which performs the following actions: + +- saves the state of the interrupted task on it's stack, + +- saves all registers which are not normally preserved by the calling sequence + so the user's interrupt service routine can be written in a high-level + language. + +- if this is the outermost (i.e. non-nested) interrupt, then the RTEMS + interrupt handler switches from the current stack to the interrupt stack, + +- enables exceptions, + +- invokes the vectors to a user interrupt service routine (ISR). + +Asynchronous interrupts are ignored while exceptions are disabled. Synchronous +interrupts which occur while are disabled result in the CPU being forced into +an error mode. + +A nested interrupt is processed similarly with the exception that the current +stack need not be switched to the interrupt stack. + +Interrupt Levels +---------------- + +The PowerPC architecture supports only a single external asynchronous interrupt +source. This interrupt source may be enabled and disabled via the External +Interrupt Enable (EE) bit in the Machine State Register (MSR). Thus only two +level (enabled and disabled) of external device interrupt priorities are +directly supported by the PowerPC architecture. + +Some PowerPC implementations include a Critical Interrupt capability which is +often used to receive interrupts from high priority external devices. + +The RTEMS interrupt level mapping scheme for the PowerPC is not a numeric level +as on most RTEMS ports. It is a bit mapping in which the least three +significiant bits of the interrupt level are mapped directly to the enabling of +specific interrupt sources as follows: + +*Critical Interrupt* + Setting bit 0 (the least significant bit) of the interrupt level enables + the Critical Interrupt source, if it is available on this CPU model. + +*Machine Check* + Setting bit 1 of the interrupt level enables Machine Check execptions. + +*External Interrupt* + Setting bit 2 of the interrupt level enables External Interrupt execptions. + +All other bits in the RTEMS task interrupt level are ignored. + +Default Fatal Error Processing +============================== + +The default fatal error handler for this architecture performs the following +actions: + +- places the error code in r3, and + +- executes a trap instruction which results in a Program Exception. + +If the Program Exception returns, then the following actions are performed: + +- disables all processor exceptions by loading a 0 into the MSR, and + +- goes into an infinite loop to simulate a halt processor instruction. + +Symmetric Multiprocessing +========================= + +SMP is supported. Available platforms are the Freescale QorIQ P series (e.g. +P1020) and T series (e.g. T2080, T4240). + +Thread-Local Storage +==================== + +Thread-local storage is supported. + +Board Support Packages +====================== + +System Reset +------------ + +An RTEMS based application is initiated or re-initiated when the PowerPC +processor is reset. The PowerPC architecture defines a Reset Exception, but +leaves the details of the CPU state as implementation specific. Please refer +to the User's Manual for the CPU model in question. + +In general, at power-up the PowerPC begin execution at address 0xFFF00100 in +supervisor mode with all exceptions disabled. For soft resets, the CPU will +vector to either 0xFFF00100 or 0x00000100 depending upon the setting of the +Exception Prefix bit in the MSR. If during a soft reset, a Machine Check +Exception occurs, then the CPU may execute a hard reset. + +Processor Initialization +------------------------ + +If this PowerPC implementation supports on-chip caching and this is to be +utilized, then it should be enabled during the reset application initialization +code. On-chip caching has been observed to prevent some emulators from working +properly, so it may be necessary to run with caching disabled to use these +emulators. + +In addition to the requirements described in the*Board Support Packages* +chapter of the RTEMS C Applications User's Manual for the reset code which is +executed before the call to ``rtems_initialize_executive``, the PowrePC version +has the following specific requirements: + +- Must leave the PR bit of the Machine State Register (MSR) set to 0 so the + PowerPC remains in the supervisor state. + +- Must set stack pointer (sp or r1) such that a minimum stack size of + MINIMUM_STACK_SIZE bytes is provided for the RTEMS initialization sequence. + +- Must disable all external interrupts (i.e. clear the EI (EE) bit of the + machine state register). + +- Must enable traps so window overflow and underflow conditions can be properly + handled. + +- Must initialize the PowerPC's initial Exception Table with default handlers. diff --git a/cpu-supplement/preface.rst b/cpu-supplement/preface.rst new file mode 100644 index 0000000..0fa6341 --- /dev/null +++ b/cpu-supplement/preface.rst @@ -0,0 +1,46 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: COPYRIGHT (c) 1988-2002. +.. COMMENT: On-Line Applications Research Corporation (OAR). +.. COMMENT: All rights reserved. + +======= +Preface +======= + +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. + +Each architecture represents a CPU family and usually there are a wide variety +of CPU models within it. These models share a common Instruction Set +Architecture (ISA) which often varies based upon some well-defined rules. +There are often multiple implementations of the ISA and these may be from one +or multiple vendors. + +On top of variations in the ISA, there may also be variations which occur when +a CPU core implementation is combined with a set of peripherals to form a +system on chip. For example, there are many ARM CPU models from numerous +semiconductor vendors and a wide variety of peripherals. But at the ISA level, +they share a common compatibility. + +RTEMS depends upon this core similarity across the CPU models and leverages +that to minimize the source code that is specific to any particular CPU core +implementation or CPU model. + +This manual is separate and distinct from the RTEMS Porting Guide. That manual +is a guide on porting RTEMS to a new architecture. This manual is focused on +the more mundane CPU architecture specific issues that may impact application +development. For example, if you need to write a subroutine in assembly +language, it is critical to understand the calling conventions for the target +architecture. + +The first chapter in this manual describes these issues in general terms. In a +sense, it is posing the questions one should be aware may need to be answered +and understood when porting an RTEMS application to a new architecture. Each +subsequent chapter gives the answers to those questions for a particular CPU +architecture. diff --git a/cpu-supplement/renesas_m32c.rst b/cpu-supplement/renesas_m32c.rst new file mode 100644 index 0000000..4884e15 --- /dev/null +++ b/cpu-supplement/renesas_m32c.rst @@ -0,0 +1,18 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: COPYRIGHT (c) 1988-2002. +.. COMMENT: On-Line Applications Research Corporation (OAR). +.. COMMENT: All rights reserved. + +Renesas M32C Specific Information +################################# + +Symmetric Multiprocessing +========================= + +SMP is not supported. + +Thread-Local Storage +==================== + +Thread-local storage is not implemented. diff --git a/cpu-supplement/sparc.rst b/cpu-supplement/sparc.rst new file mode 100644 index 0000000..f993cd8 --- /dev/null +++ b/cpu-supplement/sparc.rst @@ -0,0 +1,788 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: COPYRIGHT (c) 1988-2002. +.. COMMENT: On-Line Applications Research Corporation (OAR). +.. COMMENT: All rights reserved. + +SPARC 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 SPARC architecture dependencies in this port of +RTEMS. This architectural port is for SPARC Version 7 and +8. Implementations for SPARC V9 are in the sparc64 target. + +It is highly recommended that the SPARC RTEMS application developer obtain and +become familiar with the documentation for the processor being used as well as +the specification for the revision of the SPARC architecture which corresponds +to that processor. + +**SPARC Architecture Documents** + +For information on the SPARC architecture, refer to the following documents +available from SPARC International, Inc. (http://www.sparc.com): + +- SPARC Standard Version 7. + +- SPARC Standard Version 8. + +**ERC32 Specific Information** + +The European Space Agency's ERC32 is a three chip computing core implementing a +SPARC V7 processor and associated support circuitry for embedded space +applications. The integer and floating-point units (90C601E & 90C602E) are +based on the Cypress 7C601 and 7C602, with additional error-detection and +recovery functions. The memory controller (MEC) implements system support +functions such as address decoding, memory interface, DMA interface, UARTs, +timers, interrupt control, write-protection, memory reconfiguration and +error-detection. The core is designed to work at 25MHz, but using space +qualified memories limits the system frequency to around 15 MHz, resulting in a +performance of 10 MIPS and 2 MFLOPS. + +Information on the ERC32 and a number of development support tools, such as the +SPARC Instruction Simulator (SIS), are freely available on the Internet. The +following documents and SIS are available via anonymous ftp or pointing your +web browser at ftp://ftp.estec.esa.nl/pub/ws/wsd/erc32. + +- ERC32 System Design Document + +- MEC Device Specification + +Additionally, the SPARC RISC User's Guide from Matra MHS documents the +functionality of the integer and floating point units including the instruction +set information. To obtain this document as well as ERC32 components and VHDL +models contact: + + Matra MHS SA + 3 Avenue du Centre, BP 309, + 78054 St-Quentin-en-Yvelines, + Cedex, France + VOICE: +31-1-30607087 + FAX: +31-1-30640693 + +Amar Guennon (amar.guennon@matramhs.fr) is familiar with the ERC32. + +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. + +CPU Model Feature Flags +----------------------- + +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 section 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/sparc/sparc.h based upon the +particular CPU model defined on the compilation command line. + +CPU Model Name +~~~~~~~~~~~~~~ + +The macro CPU_MODEL_NAME is a string which designates the name of this CPU +model. For example, for the European Space Agency's ERC32 SPARC model, this +macro is set to the string "erc32". + +Floating Point Unit +~~~~~~~~~~~~~~~~~~~ + +The macro SPARC_HAS_FPU is set to 1 to indicate that this CPU model has a +hardware floating point unit and 0 otherwise. + +Bitscan Instruction +~~~~~~~~~~~~~~~~~~~ + +The macro SPARC_HAS_BITSCAN is set to 1 to indicate that this CPU model has the +bitscan instruction. For example, this instruction is supported by the Fujitsu +SPARClite family. + +Number of Register Windows +~~~~~~~~~~~~~~~~~~~~~~~~~~ + +The macro SPARC_NUMBER_OF_REGISTER_WINDOWS is set to indicate the number of +register window sets implemented by this CPU model. The SPARC architecture +allows a for a maximum of thirty-two register window sets although most +implementations only include eight. + +Low Power Mode +~~~~~~~~~~~~~~ + +The macro SPARC_HAS_LOW_POWER_MODE is set to one to indicate that this CPU +model has a low power mode. If low power is enabled, then there must be CPU +model specific implementation of the IDLE task in cpukit/score/cpu/sparc/cpu.c. +The low power mode IDLE task should be of the form: + +.. code-block:: c + + while ( TRUE ) { + enter low power mode + } + +The code required to enter low power mode is CPU model specific. + +CPU Model Implementation Notes +------------------------------ + +The ERC32 is a custom SPARC V7 implementation based on the Cypress 601/602 +chipset. This CPU has a number of on-board peripherals and was developed by +the European Space Agency to target space applications. RTEMS currently +provides support for the following peripherals: + +- UART Channels A and B + +- General Purpose Timer + +- Real Time Clock + +- Watchdog Timer (so it can be disabled) + +- Control Register (so powerdown mode can be enabled) + +- Memory Control Register + +- Interrupt Control + +The General Purpose Timer and Real Time Clock Timer provided with the ERC32 +share the Timer Control Register. Because the Timer Control Register is write +only, we must mirror it in software and insure that writes to one timer do not +alter the current settings and status of the other timer. Routines are +provided in erc32.h which promote the view that the two timers are completely +independent. By exclusively using these routines to access the Timer Control +Register, the application can view the system as having a General Purpose Timer +Control Register and a Real Time Clock Timer Control Register rather than the +single shared value. + +The RTEMS Idle thread take advantage of the low power mode provided by the +ERC32. Low power mode is entered during idle loops and is enabled at +initialization time. + +Calling Conventions +=================== + +Each high-level language compiler generates subroutine entry and exit code +based upon a set of rules known as the application binary interface (ABI) +calling convention. These rules address the following issues: + +- register preservation and usage + +- parameter passing + +- call and return mechanism + +An ABI calling convention is of importance when interfacing to subroutines +written in another language either assembly or high-level. It determines also +the set of registers to be saved or restored during a context switch and +interrupt processing. + +The ABI relevant for RTEMS on SPARC is defined by SYSTEM V APPLICATION BINARY +INTERFACE, SPARC Processor Supplement, Third Edition. + +Programming Model +----------------- + +This section discusses the programming model for the SPARC architecture. + +Non-Floating Point Registers +~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +The SPARC architecture defines thirty-two non-floating point registers directly +visible to the programmer. These are divided into four sets: + +- input registers + +- local registers + +- output registers + +- global registers + +Each register is referred to by either two or three names in the SPARC +reference manuals. First, the registers are referred to as r0 through r31 or +with the alternate notation r[0] through r[31]. Second, each register is a +member of one of the four sets listed above. Finally, some registers have an +architecturally defined role in the programming model which provides an +alternate name. The following table describes the mapping between the 32 +registers and the register sets: + +================ ================ =================== +Register Number Register Names Description +================ ================ =================== +0 - 7 g0 - g7 Global Registers +8 - 15 o0 - o7 Output Registers +16 - 23 l0 - l7 Local Registers +24 - 31 i0 - i7 Input Registers +================ ================ =================== + +As mentioned above, some of the registers serve defined roles in the +programming model. The following table describes the role of each of these +registers: + +============== ================ ================================== +Register Name Alternate Name Description +============== ================ ================================== +g0 na reads return 0, writes are ignored +o6 sp stack pointer +i6 fp frame pointer +i7 na return address +============== ================ ================================== + +The registers g2 through g4 are reserved for applications. GCC uses them as +volatile registers by default. So they are treated like volatile registers in +RTEMS as well. + +The register g6 is reserved for the operating system and contains the address +of the per-CPU control block of the current processor. This register is +initialized during system start and then remains unchanged. It is not +saved/restored by the context switch or interrupt processing code. + +The register g7 is reserved for the operating system and contains the thread +pointer used for thread-local storage (TLS) as mandated by the SPARC ABI. + +Floating Point Registers +~~~~~~~~~~~~~~~~~~~~~~~~ + +The SPARC V7 architecture includes thirty-two, thirty-two bit registers. These +registers may be viewed as follows: + +- 32 single precision floating point or integer registers (f0, f1, ... f31) + +- 16 double precision floating point registers (f0, f2, f4, ... f30) + +- 8 extended precision floating point registers (f0, f4, f8, ... f28) + +The floating point status register (FSR) specifies the behavior of the floating +point unit for rounding, contains its condition codes, version specification, +and trap information. + +According to the ABI all floating point registers and the floating point status +register (FSR) are volatile. Thus the floating point context of a thread is +the empty set. The rounding direction is a system global state and must not be +modified by threads. + +A queue of the floating point instructions which have started execution but not +yet completed is maintained. This queue is needed to support the multiple +cycle nature of floating point operations and to aid floating point exception +trap handlers. Once a floating point exception has been encountered, the queue +is frozen until it is emptied by the trap handler. The floating point queue is +loaded by launching instructions. It is emptied normally when the floating +point completes all outstanding instructions and by floating point exception +handlers with the store double floating point queue (stdfq) instruction. + +Special Registers +~~~~~~~~~~~~~~~~~ + +The SPARC architecture includes two special registers which are critical to the +programming model: the Processor State Register (psr) and the Window Invalid +Mask (wim). The psr contains the condition codes, processor interrupt level, +trap enable bit, supervisor mode and previous supervisor mode bits, version +information, floating point unit and coprocessor enable bits, and the current +window pointer (cwp). The cwp field of the psr and wim register are used to +manage the register windows in the SPARC architecture. The register windows +are discussed in more detail below. + +Register Windows +---------------- + +The SPARC architecture includes the concept of register windows. An overly +simplistic way to think of these windows is to imagine them as being an +infinite supply of "fresh" register sets available for each subroutine to use. +In reality, they are much more complicated. + +The save instruction is used to obtain a new register window. This instruction +decrements the current window pointer, thus providing a new set of registers +for use. This register set includes eight fresh local registers for use +exclusively by this subroutine. When done with a register set, the restore +instruction increments the current window pointer and the previous register set +is once again available. + +The two primary issues complicating the use of register windows are that (1) +the set of register windows is finite, and (2) some registers are shared +between adjacent registers windows. + +Because the set of register windows is finite, it is possible to execute enough +save instructions without corresponding restore's to consume all of the +register windows. This is easily accomplished in a high level language because +each subroutine typically performs a save instruction upon entry. Thus having +a subroutine call depth greater than the number of register windows will result +in a window overflow condition. The window overflow condition generates a trap +which must be handled in software. The window overflow trap handler is +responsible for saving the contents of the oldest register window on the +program stack. + +Similarly, the subroutines will eventually complete and begin to perform +restore's. If the restore results in the need for a register window which has +previously been written to memory as part of an overflow, then a window +underflow condition results. Just like the window overflow, the window +underflow condition must be handled in software by a trap handler. The window +underflow trap handler is responsible for reloading the contents of the +register window requested by the restore instruction from the program stack. + +The Window Invalid Mask (wim) and the Current Window Pointer (cwp) field in the +psr are used in conjunction to manage the finite set of register windows and +detect the window overflow and underflow conditions. The cwp contains the +index of the register window currently in use. The save instruction decrements +the cwp modulo the number of register windows. Similarly, the restore +instruction increments the cwp modulo the number of register windows. Each bit +in the wim represents represents whether a register window contains valid +information. The value of 0 indicates the register window is valid and 1 +indicates it is invalid. When a save instruction causes the cwp to point to a +register window which is marked as invalid, a window overflow condition +results. Conversely, the restore instruction may result in a window underflow +condition. + +Other than the assumption that a register window is always available for trap +(i.e. interrupt) handlers, the SPARC architecture places no limits on the +number of register windows simultaneously marked as invalid (i.e. number of +bits set in the wim). However, RTEMS assumes that only one register window is +marked invalid at a time (i.e. only one bit set in the wim). This makes the +maximum possible number of register windows available to the user while still +meeting the requirement that window overflow and underflow conditions can be +detected. + +The window overflow and window underflow trap handlers are a critical part of +the run-time environment for a SPARC application. The SPARC architectural +specification allows for the number of register windows to be any power of two +less than or equal to 32. The most common choice for SPARC implementations +appears to be 8 register windows. This results in the cwp ranging in value +from 0 to 7 on most implementations. + +The second complicating factor is the sharing of registers between adjacent +register windows. While each register window has its own set of local +registers, the input and output registers are shared between adjacent windows. +The output registers for register window N are the same as the input registers +for register window ((N - 1) modulo RW) where RW is the number of register +windows. An alternative way to think of this is to remember how parameters are +passed to a subroutine on the SPARC. The caller loads values into what are its +output registers. Then after the callee executes a save instruction, those +parameters are available in its input registers. This is a very efficient way +to pass parameters as no data is actually moved by the save or restore +instructions. + +Call and Return Mechanism +------------------------- + +The SPARC architecture supports a simple yet effective call and return +mechanism. A subroutine is invoked via the call (call) instruction. This +instruction places the return address in the caller's output register 7 (o7). +After the callee executes a save instruction, this value is available in input +register 7 (i7) until the corresponding restore instruction is executed. + +The callee returns to the caller via a jmp to the return address. There is a +delay slot following this instruction which is commonly used to execute a +restore instruction - if a register window was allocated by this subroutine. + +It is important to note that the SPARC subroutine call and return mechanism +does not automatically save and restore any registers. This is accomplished +via the save and restore instructions which manage the set of registers +windows. + +In case a floating-point unit is supported, then floating-point return values +appear in the floating-point registers. Single-precision values occupy %f0; +double-precision values occupy %f0 and %f1. Otherwise, these are scratch +registers. Due to this the hardware and software floating-point ABIs are +incompatible. + +Calling Mechanism +----------------- + +All RTEMS directives are invoked using the regular SPARC calling convention via +the call instruction. + +Register Usage +-------------- + +As discussed above, the call instruction does not automatically save any +registers. The save and restore instructions are used to allocate and +deallocate register windows. When a register window is allocated, the new set +of local registers are available for the exclusive use of the subroutine which +allocated this register set. + +Parameter Passing +----------------- + +RTEMS assumes that arguments are placed in the caller's output registers with +the first argument in output register 0 (o0), the second argument in output +register 1 (o1), and so forth. Until the callee executes a save instruction, +the parameters are still visible in the output registers. After the callee +executes a save instruction, the parameters are visible in the corresponding +input registers. The following pseudo-code illustrates the typical sequence +used to call a RTEMS directive with three (3) arguments: + +.. code-block:: c + + load third argument into o2 + load second argument into o1 + load first argument into o0 + invoke directive + +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. + +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. + +Flat Memory Model +----------------- + +The SPARC architecture 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, half-word (2-bytes), word (4 bytes), or doubleword +(8 bytes). Memory accesses within this address space are performed in big +endian fashion by the SPARC. Memory accesses which are not properly aligned +generate a "memory address not aligned" trap (type number 7). The following +table lists the alignment requirements for a variety of data accesses: + +============== ====================== +Data Type Alignment Requirement +============== ====================== +byte 1 +half-word 2 +word 4 +doubleword 8 +============== ====================== + +Doubleword load and store operations must use a pair of registers as their +source or destination. This pair of registers must be an adjacent pair of +registers with the first of the pair being even numbered. For example, a valid +destination for a doubleword load might be input registers 0 and 1 (i0 and i1). +The pair i1 and i2 would be invalid. \[NOTE: Some assemblers for the SPARC do +not generate an error if an odd numbered register is specified as the beginning +register of the pair. In this case, the assembler assumes that what the +programmer meant was to use the even-odd pair which ends at the specified +register. This may or may not have been a correct assumption.] + +RTEMS does not support any SPARC Memory Management Units, therefore, virtual +memory or segmentation systems involving the SPARC are not supported. + +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 SPARC's interrupt response and control mechanisms as +they pertain to RTEMS. + +RTEMS and associated documentation uses the terms interrupt and vector. In the +SPARC architecture, these terms correspond to traps and trap type, +respectively. The terms will be used interchangeably in this manual. + +Synchronous Versus Asynchronous Traps +------------------------------------- + +The SPARC architecture includes two classes of traps: synchronous and +asynchronous. Asynchronous traps occur when an external event interrupts the +processor. These traps are not associated with any instruction executed by the +processor and logically occur between instructions. The instruction currently +in the execute stage of the processor is allowed to complete although +subsequent instructions are annulled. The return address reported by the +processor for asynchronous traps is the pair of instructions following the +current instruction. + +Synchronous traps are caused by the actions of an instruction. The trap +stimulus in this case either occurs internally to the processor or is from an +external signal that was provoked by the instruction. These traps are taken +immediately and the instruction that caused the trap is aborted before any +state changes occur in the processor itself. The return address reported by +the processor for synchronous traps is the instruction which caused the trap +and the following instruction. + +Vectoring of Interrupt Handler +------------------------------ + +Upon receipt of an interrupt the SPARC automatically performs the following +actions: + +- disables traps (sets the ET bit of the psr to 0), + +- the S bit of the psr is copied into the Previous Supervisor Mode (PS) bit of + the psr, + +- the cwp is decremented by one (modulo the number of register windows) to + activate a trap window, + +- the PC and nPC are loaded into local register 1 and 2 (l0 and l1), + +- the trap type (tt) field of the Trap Base Register (TBR) is set to the + appropriate value, and + +- if the trap is not a reset, then the PC is written with the contents of the + TBR and the nPC is written with TBR + 4. If the trap is a reset, then the PC + is set to zero and the nPC is set to 4. + +Trap processing on the SPARC has two features which are noticeably different +than interrupt processing on other architectures. First, the value of psr +register in effect immediately before the trap occurred is not explicitly +saved. Instead only reversible alterations are made to it. Second, the +Processor Interrupt Level (pil) is not set to correspond to that of the +interrupt being processed. When a trap occurs, ALL subsequent traps are +disabled. In order to safely invoke a subroutine during trap handling, traps +must be enabled to allow for the possibility of register window overflow and +underflow traps. + +If the interrupt handler was installed as an RTEMS interrupt handler, then upon +receipt of the interrupt, the processor passes control to the RTEMS interrupt +handler which performs the following actions: + +- saves the state of the interrupted task on it's stack, + +- insures that a register window is available for subsequent traps, + +- if this is the outermost (i.e. non-nested) interrupt, then the RTEMS + interrupt handler switches from the current stack to the interrupt stack, + +- enables traps, + +- invokes the vectors to a user interrupt service routine (ISR). + +Asynchronous interrupts are ignored while traps are disabled. Synchronous +traps which occur while traps are disabled result in the CPU being forced into +an error mode. + +A nested interrupt is processed similarly with the exception that the current +stack need not be switched to the interrupt stack. + +Traps and Register Windows +-------------------------- + +One of the register windows must be reserved at all times for trap processing. +This is critical to the proper operation of the trap mechanism in the SPARC +architecture. It is the responsibility of the trap handler to insure that +there is a register window available for a subsequent trap before re-enabling +traps. It is likely that any high level language routines invoked by the trap +handler (such as a user-provided RTEMS interrupt handler) will allocate a new +register window. The save operation could result in a window overflow trap. +This trap cannot be correctly processed unless (1) traps are enabled and (2) a +register window is reserved for traps. Thus, the RTEMS interrupt handler +insures that a register window is available for subsequent traps before +enabling traps and invoking the user's interrupt handler. + +Interrupt Levels +---------------- + +Sixteen levels (0-15) of interrupt priorities are supported by the SPARC +architecture with level fifteen (15) 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. Level fifteen (15) is a non-maskable interrupt (NMI), which +makes it unsuitable for standard usage since it can affect the real-time +behaviour by interrupting critical sections and spinlocks. Disabling traps +stops also the NMI interrupt from happening. It can however be used for +power-down or other critical events. + +Although RTEMS supports 256 interrupt levels, the SPARC only supports sixteen. +RTEMS interrupt levels 0 through 15 directly correspond to SPARC processor +interrupt levels. All other RTEMS interrupt levels are undefined and their +behavior is unpredictable. + +Many LEON SPARC v7/v8 systems features an extended interrupt controller which +adds an extra step of interrupt decoding to allow handling of interrupt +16-31. When such an extended interrupt is generated the CPU traps into a +specific interrupt trap level 1-14 and software reads out from the interrupt +controller which extended interrupt source actually caused the interrupt. + +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 fifteen (15) before the execution of the section and restores them to the +previous level upon completion of the section. RTEMS has been optimized to +ensure that interrupts are disabled for less than RTEMS_MAXIMUM_DISABLE_PERIOD +microseconds on a RTEMS_MAXIMUM_DISABLE_PERIOD_MHZ Mhz ERC32 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.] + +[NOTE: It is thought that the length of time at which the processor interrupt +level is elevated to fifteen by RTEMS is not anywhere near as long as the +length of time ALL traps are disabled as part of the "flush all register +windows" operation.] + +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. + +Interrupts are disabled or enabled by performing a system call to the Operating +System reserved software traps 9 (SPARC_SWTRAP_IRQDIS) or 10 +(SPARC_SWTRAP_IRQDIS). The trap is generated by the software trap (Ticc) +instruction or indirectly by calling sparc_disable_interrupts() or +sparc_enable_interrupts() functions. Disabling interrupts return the previous +interrupt level (on trap entry) in register G1 and sets PSR.PIL to 15 to +disable all maskable interrupts. The interrupt level can be restored by +trapping into the enable interrupt handler with G1 containing the new interrupt +level. + +Interrupt Stack +--------------- + +The SPARC architecture does not provide for a dedicated interrupt stack. Thus +by default, trap handlers would execute on the stack of the RTEMS task which +they interrupted. This artificially inflates the stack requirements for each +task since EVERY task stack would have to include enough space to account for +the worst case interrupt stack requirements in addition to it's own worst case +usage. RTEMS addresses this problem on the SPARC by providing a dedicated +interrupt stack managed by software. + +During system initialization, 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. +As part of processing a non-nested interrupt, RTEMS will switch to the +interrupt stack before invoking the installed handler. + +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. + +Default Fatal Error Handler Operations +-------------------------------------- + +The default fatal error handler which is invoked by the fatal_error_occurred +directive when there is no user handler configured or the user handler returns +control to RTEMS. + +If the BSP has been configured with ``BSP_POWER_DOWN_AT_FATAL_HALT`` set to +true, the default handler will disable interrupts and enter power down mode. If +power down mode is not available, it goes into an infinite loop to simulate a +halt processor instruction. + +If ``BSP_POWER_DOWN_AT_FATAL_HALT`` is set to false, the default handler will +place the value ``1`` in register ``g1``, the error source in register ``g2``, +and the error code in register``g3``. It will then generate a system error +which will hand over control to the debugger, simulator, etc. + +Symmetric Multiprocessing +========================= + +SMP is supported. Available platforms are the Cobham Gaisler GR712RC and +GR740. + +Thread-Local Storage +==================== + +Thread-local storage is supported. + +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 +SPARC 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. + +System Reset +------------ + +An RTEMS based application is initiated or re-initiated when the SPARC +processor is reset. When the SPARC is reset, the processor performs the +following actions: + +- the enable trap (ET) of the psr is set to 0 to disable traps, + +- the supervisor bit (S) of the psr is set to 1 to enter supervisor mode, and + +- the PC is set 0 and the nPC is set to 4. + +The processor then begins to execute the code at location 0. It is important +to note that all fields in the psr are not explicitly set by the above steps +and all other registers retain their value from the previous execution mode. +This is true even of the Trap Base Register (TBR) whose contents reflect the +last trap which occurred before the reset. + +Processor Initialization +------------------------ + +It is the responsibility of the application's initialization code to initialize +the TBR and install trap handlers for at least the register window overflow and +register window underflow conditions. Traps should be enabled before invoking +any subroutines to allow for register window management. However, interrupts +should be disabled by setting the Processor Interrupt Level (pil) field of the +psr to 15. RTEMS installs it's own Trap Table as part of initialization which +is initialized with the contents of the Trap Table in place when the +``rtems_initialize_executive`` directive was invoked. Upon completion of +executive initialization, interrupts are enabled. + +If this SPARC implementation supports on-chip caching and this 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 C Applications Users Manual for the reset code which is executed before +the call to``rtems_initialize_executive``, the SPARC version has the following +specific requirements: + +- Must leave the S bit of the status register set so that the SPARC remains in + the supervisor state. + +- Must set stack pointer (sp) such that a minimum stack size of + MINIMUM_STACK_SIZE bytes is provided for the``rtems_initialize_executive`` + directive. + +- Must disable all external interrupts (i.e. set the pil to 15). + +- Must enable traps so window overflow and underflow conditions can be properly + handled. + +- Must initialize the SPARC's initial trap table with at least trap handlers + for register window overflow and register window underflow. diff --git a/cpu-supplement/sparc64.rst b/cpu-supplement/sparc64.rst new file mode 100644 index 0000000..f2785ff --- /dev/null +++ b/cpu-supplement/sparc64.rst @@ -0,0 +1,582 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: COPYRIGHT (c) 1988-2002. +.. COMMENT: On-Line Applications Research Corporation (OAR). +.. COMMENT: All rights reserved. + +SPARC-64 Specific Information +############################# + +This document discusses the SPARC Version 9 (aka SPARC-64, SPARC64 or SPARC V9) +architecture dependencies in this port of RTEMS. + +The SPARC V9 architecture leaves a lot of undefined implemenation dependencies +which are defined by the processor models. Consult the specific CPU model +section in this document for additional documents covering the implementation +dependent architectural features. + +**sun4u Specific Information** + +sun4u is the subset of the SPARC V9 implementations comprising the UltraSPARC I +through UltraSPARC IV processors. + +The following documents were used in developing the SPARC-64 sun4u port: + +- UltraSPARC User's Manual + (http://www.sun.com/microelectronics/manuals/ultrasparc/802-7220-02.pdf) + +- UltraSPARC IIIi Processor (http://datasheets.chipdb.org/Sun/UltraSparc-IIIi.pdf) + +**sun4v Specific Information** + +sun4v is the subset of the SPARC V9 implementations comprising the UltraSPARC +T1 or T2 processors. + +The following documents were used in developing the SPARC-64 sun4v port: + +- UltraSPARC Architecture 2005 Specification + (http://opensparc-t1.sunsource.net/specs/UA2005-current-draft-P-EXT.pdf) + +- UltraSPARC T1 supplement to UltraSPARC Architecture 2005 Specification + (http://opensparc-t1.sunsource.net/specs/UST1-UASuppl-current-draft-P-EXT.pdf) + +The defining feature that separates the sun4v architecture from its predecessor +is the existence of a super-privileged hypervisor that is responsible for +providing virtualized execution environments. The impact of the hypervisor on +the real-time guarantees available with sun4v has not yet been determined. + +CPU Model Dependent Features +============================ + +CPU Model Feature Flags +----------------------- + +This section presents the set of features which vary across SPARC-64 +implementations and are of importance to RTEMS. The set of CPU model feature +macros are defined in the file cpukit/score/cpu/sparc64/sparc64.h based upon +the particular CPU model defined on the compilation command line. + +CPU Model Name +~~~~~~~~~~~~~~ + +The macro CPU MODEL NAME is a string which designates the name of this CPU +model. For example, for the UltraSPARC T1 SPARC V9 model, this macro is set to +the string "sun4v". + +Floating Point Unit +~~~~~~~~~~~~~~~~~~~ + +The macro SPARC_HAS_FPU is set to 1 to indicate that this CPU model has a +hardware floating point unit and 0 otherwise. + +Number of Register Windows +~~~~~~~~~~~~~~~~~~~~~~~~~~ + +The macro SPARC_NUMBER_OF_REGISTER_WINDOWS is set to indicate the number of +register window sets implemented by this CPU model. The SPARC architecture +allows for a maximum of thirty-two register window sets although most +implementations only include eight. + +CPU Model Implementation Notes +------------------------------ + +This section describes the implemenation dependencies of the CPU Models sun4u +and sun4v of the SPARC V9 architecture. + +sun4u Notes +~~~~~~~~~~~ + +XXX + +sun4v Notes +----------- + +XXX + +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: + +- register preservation and usage + +- parameter passing + +- call and return mechanism + +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. + +The following document also provides some conventions on the global register +usage in SPARC V9: http://developers.sun.com/solaris/articles/sparcv9abi.html + +Programming Model +----------------- + +This section discusses the programming model for the SPARC architecture. + +Non-Floating Point Registers +~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +The SPARC architecture defines thirty-two non-floating point registers directly +visible to the programmer. These are divided into four sets: + +- input registers + +- local registers + +- output registers + +- global registers + +Each register is referred to by either two or three names in the SPARC +reference manuals. First, the registers are referred to as r0 through r31 or +with the alternate notation r[0] through r[31]. Second, each register is a +member of one of the four sets listed above. Finally, some registers have an +architecturally defined role in the programming model which provides an +alternate name. The following table describes the mapping between the 32 +registers and the register sets: + +================ ================ =================== +Register Number Register Names Description +================ ================ =================== +0 - 7 g0 - g7 Global Registers +8 - 15 o0 - o7 Output Registers +16 - 23 l0 - l7 Local Registers +24 - 31 i0 - i7 Input Registers +================ ================ =================== + +As mentioned above, some of the registers serve defined roles in the +programming model. The following table describes the role of each of these +registers: + +============== ================ ================================== +Register Name Alternate Name Description +============== ================ ================================== +g0 na reads return 0, writes are ignored +o6 sp stack pointer +i6 fp frame pointer +i7 na return address +============== ================ ================================== + +Floating Point Registers +~~~~~~~~~~~~~~~~~~~~~~~~ + +The SPARC V9 architecture includes sixty-four, thirty-two bit registers. These +registers may be viewed as follows: + +- 32 32-bit single precision floating point or integer registers (f0, f1, + ... f31) + +- 32 64-bit double precision floating point registers (f0, f2, f4, ... f62) + +- 16 128-bit extended precision floating point registers (f0, f4, f8, ... f60) + +The floating point state register (fsr) specifies the behavior of the floating +point unit for rounding, contains its condition codes, version specification, +and trap information. + +Special Registers +~~~~~~~~~~~~~~~~~ + +The SPARC architecture includes a number of special registers: + +*``Ancillary State Registers (ASRs)``* + The ancillary state registers (ASRs) are optional state registers that may + be privileged or nonprivileged. ASRs 16-31 are implementation- + dependent. The SPARC V9 ASRs include: y, ccr, asi, tick, pc, fprs. The + sun4u ASRs include: pcr, pic, dcr, gsr, softint set, softint clr, softint, + and tick cmpr. The sun4v ASRs include: pcr, pic, gsr, soft- int set, + softint clr, softint, tick cmpr, stick, and stick cmpr. + +*``Processor State Register (pstate)``* + The privileged pstate register contains control fields for the proces- + sor's current state. Its flag fields include the interrupt enable, privi- + leged mode, and enable FPU. + +*``Processor Interrupt Level (pil)``* + The PIL specifies the interrupt level above which interrupts will be + accepted. + +*``Trap Registers``* + The trap handling mechanism of the SPARC V9 includes a number of registers, + including: trap program counter (tpc), trap next pc (tnpc), trap state + (tstate), trap type (tt), trap base address (tba), and trap level (tl). + +*``Alternate Globals``* + The AG bit of the pstate register provides access to an alternate set of + global registers. On sun4v, the AG bit is replaced by the global level (gl) + register, providing access to at least two and at most eight alternate sets + of globals. + +*``Register Window registers``* + A number of registers assist in register window management. These include + the current window pointer (cwp), savable windows (cansave), restorable + windows (canrestore), clean windows (clean- win), other windows (otherwin), + and window state (wstate). + +Register Windows +---------------- + +The SPARC architecture includes the concept of register windows. An overly +simplistic way to think of these windows is to imagine them as being an +infinite supply of "fresh" register sets available for each subroutine to use. +In reality, they are much more complicated. + +The save instruction is used to obtain a new register window. This instruction +increments the current window pointer, thus providing a new set of registers +for use. This register set includes eight fresh local registers for use +exclusively by this subroutine. When done with a register set, the restore +instruction decrements the current window pointer and the previous register set +is once again available. + +The two primary issues complicating the use of register windows are that (1) +the set of register windows is finite, and (2) some registers are shared +between adjacent registers windows. + +Because the set of register windows is finite, it is possible to execute enough +save instructions without corresponding restore's to consume all of the +register windows. This is easily accomplished in a high level language because +each subroutine typically performs a save instruction upon entry. Thus having +a subroutine call depth greater than the number of register windows will result +in a window overflow condition. The window overflow condition generates a trap +which must be handled in software. The window overflow trap handler is +responsible for saving the contents of the oldest register window on the +program stack. + +Similarly, the subroutines will eventually complete and begin to perform +restore's. If the restore results in the need for a register window which has +previously been written to memory as part of an overflow, then a window +underflow condition results. Just like the window overflow, the window +underflow condition must be handled in software by a trap handler. The window +underflow trap handler is responsible for reloading the contents of the +register window requested by the restore instruction from the program stack. + +The cansave, canrestore, otherwin, and cwp are used in conjunction to manage +the finite set of register windows and detect the window overflow and underflow +conditions. The first three of these registers must satisfy the invariant +cansave + canrestore + otherwin = nwindow - 2, where nwindow is the number of +register windows. The cwp contains the index of the register window currently +in use. RTEMS does not use the cleanwin and otherwin registers. + +The save instruction increments the cwp modulo the number of register windows, +and if cansave is 0 then it also generates a window overflow. Similarly, the +restore instruction decrements the cwp modulo the number of register windows, +and if canrestore is 0 then it also generates a window underflow. + +Unlike with the SPARC model, the SPARC-64 port does not assume that a register +window is available for a trap. The window overflow and underflow conditions +are not detected without hardware generating the trap. (These conditions can be +detected by reading the register window registers and doing some simple +arithmetic.) + +The window overflow and window underflow trap handlers are a critical part of +the run-time environment for a SPARC application. The SPARC architectural +specification allows for the number of register windows to be any power of two +less than or equal to 32. The most common choice for SPARC implementations +appears to be 8 register windows. This results in the cwp ranging in value +from 0 to 7 on most implementations. + +The second complicating factor is the sharing of registers between adjacent +register windows. While each register window has its own set of local +registers, the input and output registers are shared between adjacent windows. +The output registers for register window N are the same as the input registers +for register window ((N + 1) modulo RW) where RW is the number of register +windows. An alternative way to think of this is to remember how parameters are +passed to a subroutine on the SPARC. The caller loads values into what are its +output registers. Then after the callee executes a save instruction, those +parameters are available in its input registers. This is a very efficient way +to pass parameters as no data is actually moved by the save or restore +instructions. + +Call and Return Mechanism +------------------------- + +The SPARC architecture supports a simple yet effective call and return +mechanism. A subroutine is invoked via the call (call) instruction. This +instruction places the return address in the caller's output register 7 (o7). +After the callee executes a save instruction, this value is available in input +register 7 (i7) until the corresponding restore instruction is executed. + +The callee returns to the caller via a jmp to the return address. There is a +delay slot following this instruction which is commonly used to execute a +restore instruction - if a register window was allocated by this subroutine. + +It is important to note that the SPARC subroutine call and return mechanism +does not automatically save and restore any registers. This is accomplished +via the save and restore instructions which manage the set of registers +windows. This allows for the compiler to generate leaf-optimized functions +that utilize the caller's output registers without using save and restore. + +Calling Mechanism +----------------- + +All RTEMS directives are invoked using the regular SPARC calling convention via +the call instruction. + +Register Usage +-------------- + +As discussed above, the call instruction does not automatically save any +registers. The save and restore instructions are used to allocate and +deallocate register windows. When a register window is allocated, the new set +of local registers are available for the exclusive use of the subroutine which +allocated this register set. + +Parameter Passing +----------------- + +RTEMS assumes that arguments are placed in the caller's output registers with +the first argument in output register 0 (o0), the second argument in output +register 1 (o1), and so forth. Until the callee executes a save instruction, +the parameters are still visible in the output registers. After the callee +executes a save instruction, the parameters are visible in the corresponding +input registers. The following pseudo-code illustrates the typical sequence +used to call a RTEMS directive with three (3) arguments: + +.. code-block:: c + + load third argument into o2 + load second argument into o1 + load first argument into o0 + invoke directive + +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. + +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. + +Flat Memory Model +----------------- + +The SPARC-64 architecture supports a flat 64-bit address space with addresses +ranging from 0x0000000000000000 to 0xFFFFFFFFFFFFFFFF. Each address is +represented by a 64-bit value (and an 8-bit address space identifider or ASI) +and is byte addressable. The address may be used to reference a single byte, +half-word (2-bytes), word (4 bytes), doubleword (8 bytes), or quad-word (16 +bytes). Memory accesses within this address space are performed in big endian +fashion by the SPARC. Memory accesses which are not properly aligned generate a +"memory address not aligned" trap (type number 0x34). The following table lists +the alignment requirements for a variety of data accesses: + +============== ====================== +Data Type Alignment Requirement +============== ====================== +byte 1 +half-word 2 +word 4 +doubleword 8 +quadword 16 +============== ====================== + +RTEMS currently does not support any SPARC Memory Management Units, therefore, +virtual memory or segmentation systems involving the SPARC are not supported. + +Interrupt Processing +==================== + +RTEMS and associated documentation uses the terms interrupt and vector. In the +SPARC architecture, these terms correspond to traps and trap type, +respectively. The terms will be used interchangeably in this manual. Note that +in the SPARC manuals, interrupts are a subset of the traps that are delivered +to software interrupt handlers. + +Synchronous Versus Asynchronous Traps +------------------------------------- + +The SPARC architecture includes two classes of traps: synchronous (precise) and +asynchronous (deferred). Asynchronous traps occur when an external event +interrupts the processor. These traps are not associated with any instruction +executed by the processor and logically occur between instructions. The +instruction currently in the execute stage of the processor is allowed to +complete although subsequent instructions are annulled. The return address +reported by the processor for asynchronous traps is the pair of instructions +following the current instruction. + +Synchronous traps are caused by the actions of an instruction. The trap +stimulus in this case either occurs internally to the processor or is from an +external signal that was provoked by the instruction. These traps are taken +immediately and the instruction that caused the trap is aborted before any +state changes occur in the processor itself. The return address reported by +the processor for synchronous traps is the instruction which caused the trap +and the following instruction. + +Vectoring of Interrupt Handler +------------------------------ + +Upon receipt of an interrupt the SPARC automatically performs the following +actions: + +- The trap level is set. This provides access to a fresh set of privileged + trap-state registers used to save the current state, in effect, pushing a + frame on the trap stack. TL <- TL + 1 + +- Existing state is preserved + - TSTATE[TL].CCR <- CCR + - TSTATE[TL].ASI <- ASI + - TSTATE[TL].PSTATE <- PSTATE + - TSTATE[TL].CWP <- CWP + - TPC[TL] <- PC + - TNPC[TL] <- nPC + +- The trap type is preserved. TT[TL] <- the trap type + +- The PSTATE register is updated to a predefined state + - PSTATE.MM is unchanged + - PSTATE.RED <- 0 + - PSTATE.PEF <- 1 if FPU is present, 0 otherwise + - PSTATE.AM <- 0 (address masking is turned off) + - PSTATE.PRIV <- 1 (the processor enters privileged mode) + - PSTATE.IE <- 0 (interrupts are disabled) + - PSTATE.AG <- 1 (global regs are replaced with alternate globals) + - PSTATE.CLE <- PSTATE.TLE (set endian mode for traps) + +- For a register-window trap only, CWP is set to point to the register + window that must be accessed by the trap-handler software, that is: + + - If TT[TL] = 0x24 (a clean window trap), then CWP <- CWP + 1. + - If (0x80 <= TT[TL] <= 0xBF) (window spill trap), then CWP <- CWP + + CANSAVE + 2. + - If (0xC0 <= TT[TL] <= 0xFF) (window fill trap), then CWP <- CWP1. + - For non-register-window traps, CWP is not changed. + +- Control is transferred into the trap table: + + - PC <- TBA<63:15> (TL>0) TT[TL] 0 0000 + - nPC <- TBA<63:15> (TL>0) TT[TL] 0 0100 + - where (TL>0) is 0 if TL = 0, and 1 if TL > 0. + +In order to safely invoke a subroutine during trap handling, traps must be +enabled to allow for the possibility of register window overflow and underflow +traps. + +If the interrupt handler was installed as an RTEMS interrupt handler, then upon +receipt of the interrupt, the processor passes control to the RTEMS interrupt +handler which performs the following actions: + +- saves the state of the interrupted task on it's stack, + +- switches the processor to trap level 0, + +- if this is the outermost (i.e. non-nested) interrupt, then the RTEMS + interrupt handler switches from the current stack to the interrupt stack, + +- enables traps, + +- invokes the vectors to a user interrupt service routine (ISR). + +Asynchronous interrupts are ignored while traps are disabled. Synchronous +traps which occur while traps are disabled may result in the CPU being forced +into an error mode. + +A nested interrupt is processed similarly with the exception that the current +stack need not be switched to the interrupt stack. + +Traps and Register Windows +-------------------------- + +XXX + +Interrupt Levels +---------------- + +Sixteen levels (0-15) of interrupt priorities are supported by the SPARC +architecture with level fifteen (15) 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 SPARC only supports sixteen. +RTEMS interrupt levels 0 through 15 directly correspond to SPARC processor +interrupt levels. All other RTEMS interrupt levels are undefined and their +behavior is unpredictable. + +Disabling of Interrupts by RTEMS +-------------------------------- + +XXX + +Interrupt Stack +--------------- + +The SPARC architecture does not provide for a dedicated interrupt stack. Thus +by default, trap handlers would execute on the stack of the RTEMS task which +they interrupted. This artificially inflates the stack requirements for each +task since EVERY task stack would have to include enough space to account for +the worst case interrupt stack requirements in addition to it's own worst case +usage. RTEMS addresses this problem on the SPARC by providing a dedicated +interrupt stack managed by software. + +During system initialization, 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. +As part of processing a non-nested interrupt, RTEMS will switch to the +interrupt stack before invoking the installed handler. + +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. + +Default Fatal Error Handler Operations +-------------------------------------- + +The default fatal error handler which is invoked by the 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 to level 15, places the error code in g1, and goes into an infinite +loop to simulate a halt processor instruction. + +Symmetric Multiprocessing +========================= + +SMP is not supported. + +Thread-Local Storage +==================== + +Thread-local storage is supported. + +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 +SPARC 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. + +HelenOS and Open Firmware +------------------------- + +The provided BSPs make use of some bootstrap and low-level hardware code of the +HelenOS operating system. These files can be found in the shared/helenos +directory of the sparc64 bsp directory. Consult the sources for more detailed +information. + +The shared BSP code also uses the Open Firmware interface to re-use firmware +code, primarily for console support and default trap handlers. diff --git a/cpu-supplement/superh.rst b/cpu-supplement/superh.rst new file mode 100644 index 0000000..fddf1b1 --- /dev/null +++ b/cpu-supplement/superh.rst @@ -0,0 +1,140 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: COPYRIGHT (c) 1988-2002. +.. COMMENT: On-Line Applications Research Corporation (OAR). +.. COMMENT: All rights reserved. + +SuperH Specific Information +########################### + +This chapter discusses the SuperH architecture dependencies in this port of +RTEMS. The SuperH family has a wide variety of implementations by a wide range +of vendors. Consequently, there are many, many CPU models within it. + +**Architecture Documents** + +For information on the SuperH architecture, refer to the following documents +available from VENDOR (http://www.XXX.com/): + +- *SuperH Family Reference, VENDOR, PART NUMBER*. + +CPU Model Dependent Features +============================ + +This chapter presents the set of features which vary across SuperH +implementations and are of importance to RTEMS. The set of CPU model feature +macros are defined in the file ``cpukit/score/cpu/sh/sh.h`` based upon the +particular CPU model specified on the compilation command line. + +Another Optional Feature +------------------------ + +The macro XXX + +Calling Conventions +=================== + +Calling Mechanism +----------------- + +All RTEMS directives are invoked using a ``XXX`` instruction and return to the +user application via the ``XXX`` instruction. + +Register Usage +-------------- + +The SH1 has 16 general registers (r0..r15). + +- r0..r3 used as general volatile registers + +- r4..r7 used to pass up to 4 arguments to functions, arguments above 4 are + passed via the stack) + +- r8..13 caller saved registers (i.e. push them to the stack if you need them + inside of a function) + +- r14 frame pointer + +- r15 stack pointer + +Parameter Passing +----------------- + +XXX + +Memory Model +============ + +Flat Memory Model +----------------- + +The SuperH 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 SuperH family members support virtual memory and segmentation. +RTEMS does not support virtual memory or segmentation on any of the SuperH +family members. It is the responsibility of the BSP to initialize the mapping +for a flat memory model. + +Interrupt Processing +==================== + +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 MIPS's interrupt response and control mechanisms as they pertain to RTEMS. + +Vectoring of an Interrupt Handler +--------------------------------- + +Upon receipt of an interrupt the XXX family members with separate interrupt +stacks automatically perform the following actions: + +- TBD + +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. + +Interrupt Levels +---------------- + +TBD + +Default Fatal Error Processing +============================== + +The default fatal error handler for this architecture disables processor +interrupts, places the error code in *XXX*, and executes a ``XXX`` instruction +to simulate a halt processor instruction. + +Symmetric Multiprocessing +========================= + +SMP is not supported. + +Thread-Local Storage +==================== + +Thread-local storage is not implemented. + +Board Support Packages +====================== + +System Reset +------------ + +An RTEMS based application is initiated or +re-initiated when the processor is reset. When the +processor is reset, it performs the following actions: + +- TBD + +Processor Initialization +------------------------ + +TBD diff --git a/cpu-supplement/wscript b/cpu-supplement/wscript new file mode 100644 index 0000000..4a5f474 --- /dev/null +++ b/cpu-supplement/wscript @@ -0,0 +1,6 @@ +from sys import path +from os.path import abspath +path.append(abspath('../common/')) + +from waf import cmd_configure as configure, cmd_build as build, spell, cmd_spell, cmd_options as options, linkcheck, cmd_linkcheck + diff --git a/cpu-supplement/xilinx_microblaze.rst b/cpu-supplement/xilinx_microblaze.rst new file mode 100644 index 0000000..4cc2863 --- /dev/null +++ b/cpu-supplement/xilinx_microblaze.rst @@ -0,0 +1,18 @@ +.. comment SPDX-License-Identifier: CC-BY-SA-4.0 + +.. COMMENT: COPYRIGHT (c) 1988-2002. +.. COMMENT: On-Line Applications Research Corporation (OAR). +.. COMMENT: All rights reserved. + +Xilinx MicroBlaze Specific Information +###################################### + +Symmetric Multiprocessing +========================= + +SMP is not supported. + +Thread-Local Storage +==================== + +Thread-local storage is not implemented. -- cgit v1.2.3