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/intel_amd_x86.rst | 292 +++++++++++++++++++++++++++++++++++++++ 1 file changed, 292 insertions(+) create mode 100644 cpu-supplement/intel_amd_x86.rst (limited to 'cpu-supplement/intel_amd_x86.rst') 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. -- cgit v1.2.3