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1300 lines
52 KiB
Plaintext
1300 lines
52 KiB
Plaintext
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###### ## ## ###### ###### ##### #### ##### ### ##
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#### #### ### ## ###### ##### ##### ##### ### ##
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[ Turbo68K Readme ]
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Copyright 2000-2002 Bart Trzynadlowski
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This is the documentation for Turbo68K Version 0.6, please read it. Terms of
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use are explained a little further below, it is required that you read and
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abide by them in order to use this software.
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Turbo68K is a Motorola 680X0 emulator. It currently emulates the 68000 and
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68010 microprocessors. It was written for Intel X86-based (Pentium or better)
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systems. Originally designed for Genital it is now available for public use.
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Contact Bart Trzynadlowski:
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Email: trzy@mailandnews.com
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WWW: http://trzy.overclocked.org
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http://trzy.overclocked.org/turbo68k
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-------------------
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0. Terms of Use
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-------------------
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Turbo68K is Copyright 2000, 2001, 2002 Bart Trzynadlowski.
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"Turbo68K" refers to: MAKE68K.C, TURBO68K.H, README.TXT, any binaries compiled
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from those files, any source code emitted from MAKE68K.C, and any object file
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created from such code.
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To use Turbo68K, you must agree to the following:
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- Turbo68K shall be distributed freely, unmodified, and intact.
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- Charging money, goods, or services for Turbo68K is forbidden.
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- Claiming ownership or authorship of Turbo68K is forbidden.
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- Turbo68K may not be distributed in any medium for which money, goods, or
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services are solicited.
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- The author, Bart Trzynadlowski, will not be held liable for damages.
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- Credit must be given to the author either in the program itself (where
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the user can see it) or in its documentation.
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You are encouraged to contact Bart Trzynadlowski if you wish to use Turbo68K
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in a commercial product (to negotiate licensing.)
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Bart Trzynadlowski reserves the right to use Turbo68K in any way he sees fit.
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If you do not agree with all of these terms, please remove Turbo68K from your
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possession.
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------------------------
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1. Table of Contents
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------------------------
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0. Terms of Use
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1. Table of Contents
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2. Making Turbo68K
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3. Command Line Options
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4. Using Turbo68K
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4.1 Basic Data Types
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4.2 Definitions
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4.3 Context
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4.4 Instruction Fetching
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4.5 Data Access
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4.6 PC-Relative Reads
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4.7 Interrupts
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4.8 Byte Swapped Memory
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4.9 The RESET and BKPT Instructions
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4.10 Initializing and Resetting Turbo68K
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4.11 Running the Emulator
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5. Function Reference
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6. Hints and Tips
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6.1 Alternative Identifiers
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6.2 Multiple Processors
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6.3 Maximizing Speed and Minimizing Size
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6.4 Sega Genesis TAS Bug
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7. Additional Notes
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7.1 Change History
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7.2 Un-emulated Features
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7.3 Errata
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7.4 Bibliography
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8. Special Thanks
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----------------------
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2. Making Turbo68K
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----------------------
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The Turbo68K 680X0 emulator is usually distributed in a compressed archive,
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simply extract it and you should have MAKE68K.C, TURBO68K.H, and this
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README.TXT file.
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The first step is to get the source code emitter, Make68K, up and running. It
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should compile with any 32-bit C compiler (compilers other than gcc will often
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produce warnings, these can be ignored.) The following have been confirmed:
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- DJGPP (gcc v2.8.1) [ MS-DOS ]
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- gcc v2.7.2.1 [ FreeBSD ]
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- Microsoft VisualC++ 6.0 Professional Edition [ Windows 95 ]
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- WATCOM C/C++32 Version 10.6 [ MS-DOS ]
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If you get link errors concerning pow(), make sure to include the appropriate
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math library. Try "-lm" if you are using GNU tools.
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Once Make68K has been built, run it with the name of the file you wish to emit
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on the command line. For example:
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make68k turbo68k.asm
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Make68K can take a number of options. Try "make68k -h" to see a list. Section
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3 of this text describes them in more detail.
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Assemble the emitted file with NASM. Version 0.97 or better should work, 0.98
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is known to work.
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Turbo68K contains identifiers with leading and trailing underscores as
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well as without any, so all the object formats supported by NASM should work.
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Remember to include TURBO68K.H to use Turbo68K.
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---------------------------
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3. Command Line Options
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---------------------------
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Turbo68K can be tailored in a variety of ways to suit your needs through the
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use of the following command line options:
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-mpu <type> Processor type. Valid types are 68000 and 68010.
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[Default=68000]
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-addr <bits> Address bus width. This simulates the specified number of
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address lines by cutting off any unsupported address bits
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when accessing memory or updating the PC. The 68000 and
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68010 have a 24-bit address bus. [Default=24]
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-illegal Emulates illegal instruction traps. Line 1010 and Line
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1111 emulator exceptions are processed as is the normal
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illegal instruction exception. [Default]
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-noillegal Does not emulate illegal instruction traps but instead
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returns an error from Turbo68KRun(). The ILLEGAL opcode
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still generates an illegal instruction trap regardless of
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whether -illegal or -noillegal has been specified.
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-dummyread Emulates dummy reads for the CLR, Scc, and unprivileged
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"MOVE from SR" instructions. These instructions perform a
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read (and do not make use of the data) before writing.
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Some systems may require this for accurate emulation (for
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example: some systems will lock up when write-only
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locations are read.) This is only available if the
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processor type is 68000. [Default]
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-nodummyread Does not emulate dummy reads and instead performs a write
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immediately.
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-skip Skips over idle DBRA loops by setting the counter register
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to 0xFFFF, adjusting the timer appropriately, and moving
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to the next instruction.
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-noskip Does not skip over idle loops. This eliminates problems
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with compatibility and is recommended. [Default]
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-brafetch Uses the fetch memory map array to update the PC on Bcc,
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BRA, BSR, and DBcc instructions.
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-nobrafetch Bcc, BRA, BSR, and DBcc branches are handled by adding the
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displacement to the internal normalized PC. This is less
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safe, in theory, but you should not normally have any
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problems. It is also faster and generates less code than
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-brafetch. [Default]
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-pcfetch PC-relative reads are handled through a special fetch map.
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Please read section 4.6 for more information.
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-nopcfetch PC-relative reads are treated as normal data reads.
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[Default]
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-multiaddr Separate address spaces for supervisor and user. This has
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not been extensively tested, so let me know how it works.
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[Default]
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-singleaddr Single address space for supervisor and user.
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-defmap Definable memory map arrays are used to handle reading and
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writing to the address space. [Default]
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-handler Uses handlers for reading/writing bytes, words, and long-
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words. The fetch memory map array must still be set up.
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-stackcall Use stack-based calling conventions. [Default]
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-regcall Use register-based calling conventions. EAX contains the
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first argument, the second is in EDX.
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-id <string> Adds the specified string to the beginning of all
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identifiers. Up to 16 characters are allowed. See section
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6.1 for more information on this.
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Please read further to learn more about the details of some of these options.
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---------------------
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4. Using Turbo68K
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---------------------
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A general overview of Turbo68K is provided here. More information on certain
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topics is provided throughout the document.
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4.1 Basic Data Types
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The following data types are provided by Turbo68K:
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TURBO68K_UINT32 Unsigned 32-bit
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TURBO68K_INT32 Signed 32-bit
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TURBO68K_UINT16 Unsigned 16-bit
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TURBO68K_INT16 Signed 16-bit
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TURBO68K_UINT8 Unsigned 8-bit
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TURBO68K_INT8 Signed 8-bit
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4.2 Definitions
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Turbo68K functions return and accept defined arguments. Use these instead of
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hard-coded values. Different functions return and accept different values, so
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make sure to check with the function reference first.
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TURBO68K_NULL 0
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TURBO68K_OKAY Success
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TURBO68K_SUPERVISOR Supervisor address space
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TURBO68K_USER User address space
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TURBO68K_ERROR_FETCH Fetch error (PC out of bounds)
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TURBO68K_ERROR_INVINST Invalid instruction
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TURBO68K_ERROR_INTLEVEL Invalid interrupt level was specified
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TURBO68K_ERROR_INTVECTOR Invalid interrupt vector was specified
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TURBO68K_ERROR_INTPENDING Specified interrupt level already pending
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TURBO68K_UNINITIALIZED Uninitialized interrupt vector
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TURBO68K_SPURIOUS Spurious interrupt vector
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TURBO68K_AUTOVECTOR Autovectored interrupt
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4.3 Context
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Processor contexts are special structures which contain all the data necessary
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to manage the emulated 680X0. The procedure for emulating a 680X0 processor
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with Turbo68K involves setting up a context, mapping it in, emulating some
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code, and perhaps mapping the context out.
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Context Definitions:
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--------------------
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struct TURBO68K_CONTEXT_68000
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{
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void *fetch;
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void *read_byte, *read_word, *read_long;
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void *write_byte, *write_word, *write_long;
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void *super_fetch;
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void *super_read_byte, *super_read_word, *super_read_long;
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void *super_write_byte, *super_write_word,
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*super_write_long;
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void *user_fetch;
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void *user_read_byte, *user_read_word, *user_read_long;
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void *user_write_byte, *user_write_word, *user_write_long;
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TURBO68K_UINT32 intr[8], cycles, remaining;
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TURBO68K_UINT32 d[8], a[8], sp, sr, pc, status;
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void *InterruptAcknowledge;
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void *Reset;
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};
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struct TURBO68K_CONTEXT_68010
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{
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void *fetch, *pcfetch;
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void *read_byte, *read_word, *read_long;
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void *write_byte, *write_word, *write_long;
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void *super_fetch, *super_pcfetch;
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void *super_read_byte, *super_read_word, *super_read_long;
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void *super_write_byte, *super_write_word,
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*super_write_long;
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void *user_fetch, *user_pcfetch;
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void *user_read_byte, *user_read_word, *user_read_long;
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void *user_write_byte, *user_write_word, *user_write_long;
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TURBO68K_UINT32 intr[8], cycles, remaining;
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TURBO68K_UINT32 d[8], a[8], sp, sr, pc, fc, vbr, status;
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void *InterruptAcknowledge;
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void *Reset, *Bkpt;
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};
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If you are emulating different address spaces for supervisor and user modes,
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the super_ and user_ pointers must be set to point at the respective memory
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maps. The other memory map pointers (fetch, read_byte, write_byte, etc.) will
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be managed internally by Turbo68K.
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If you are only emulating a single address space for both privilege modes,
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you do not have to set up the super_ and user_ pointers but must set up the
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others.
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The "intr" array holds pending interrupt information. Entries 0-6 are for
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interrupt levels 1-7, they contain the vector of the pending interrupt, or 0
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if no interrupt at the given level is pending. Entry 7 contains the number of
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pending interrupts. You should not modify this yourself, use the interrupt
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functions.
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The "cycles" and "remaining" members are used to control execution time.
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The total amount of request cycles is held in "cycles" and the number left is
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held in "remaining."
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Data and address registers are kept in the "d" and "a" array, the PC is kept
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in "pc", and the SR is kept in "sr" (the low word is used, the upper word
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should be kept 0.)
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Whichever stack pointer is not in A7 is stored in "sp." Thus, if the processor
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is in Supervisor mode, A7 is the SSP and "sp" contains the USP. Turbo68K will
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only swap these when it has to switch privilege modes internally, such as with
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a MOVE SR instruction, exception processing, etc.
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NOTE: If you absolutely must modify the SR outside of Turbo68K (for example,
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if you are writing a debugger), you have to swap A7 and "sp" manually if the
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privilege mode changed.
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For the 68010, "fc" is both SFC (first 3 bits of byte 0) and DFC (first 3 bits
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of byte 1.) The 68010's VBR is kept in "vbr."
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Additional information on the processor status is reflected in the "status"
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member. Its format is:
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Bit 0: R (Running) flag -- 0 = not running, 1 = running
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Bit 1: S (Stopped) flag -- 0 = not stopped, 1 = stopped via the STOP
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instruction
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Bit 2: I (Interrupt) flag -- 0 = not processing interrupts, 1 = process-
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ing interrupts (Turbo68KProcessInterrupts())
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The "InterruptAcknowledge" pointer points to an interrupt acknowledge handler
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which is called when interrupts are being processed. If the pointer is set to
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TURBO68K_NULL, it will not be called. See section 4.7.
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Finally, the "Reset" pointer points to a Reset handler. If the RESET
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instruction is executed, this handler will be called. If the pointer is set to
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TURBO68K_NULL, it will not be called. The "Bkpt" pointer is for the 68010's
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BKPT instruction.
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Contexts can be mapped in and out of Turbo68K's internal data space by using
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Turbo68KSetContext() and Turbo68KGetContext(). Once they are mapped in, no
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changes will be reflected in your context structures until you map them out.
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NOTE: You CANNOT access context members while the context is mapped in unless
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there are functions provided for that purpose (such as Turbo68KSetFetch(),
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Turbo68KFreeTimeSlice(), Turbo68KReadPC(), etc.)
|
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If there is no function for the operation you want to perform on the context,
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you simply cannot do it until the context is mapped out. You may NOT map
|
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contexts in and out from memory handlers while Turbo68K is running. Please
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consult the function reference for more information.
|
||
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Turbo68K provides an internal context called "turbo68kcontext_68000" if
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emulating a 68000, or "turbo68kcontext_68010" if emulating a 68010. These are
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where you copy your context when you use Turbo68KSetContext(). They should
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only be used if you are emulating one processor.
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When setting up memory maps, you can modify context pointers only if the
|
||
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context was defined by you. If you wish to use the internal context, you will
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||
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have to use special functions to perform the same tasks. This is because
|
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Turbo68K expects pointers in the internal context to be mangled (for
|
||
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performance reasons.) Turbo68KSetContext()/Turbo68KGetContext() handle
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||
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this task automatically.
|
||
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Here is an example of defining a context and mapping it in and out:
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||
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||
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struct TURBO68K_CONTEXT_68000 mycontext;
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|
||
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/* ... Set up everything ... */
|
||
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|
||
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Turbo68KSetContext(&mycontext);
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||
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/* ... Run some code ... */
|
||
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Turbo68KGetContext(&mycontext);
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||
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|
||
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|
||
|
4.4 Instruction Fetching
|
||
|
|
||
|
Turbo68K needs to know how to fetch instruction from 680X0 memory space. An
|
||
|
array of fetch regions must be set up describing where valid program areas are
|
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located.
|
||
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|
||
|
Fetch Region Definition:
|
||
|
------------------------
|
||
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|
||
|
struct TURBO68K_FETCHREGION
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||
|
{
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||
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TURBO68K_UINT32 base;
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||
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TURBO68K_UINT32 limit;
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||
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TURBO68K_UINT32 ptr;
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||
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};
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||
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|
||
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The "base" is the start address of the fetch region. The "limit" is the end
|
||
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address. The "ptr" must be set to a host machine pointer value with the base
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||
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subtracted from it.
|
||
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|
||
|
NOTE: Memory must be byte swapped. See section 4.8 for more information.
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||
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|
||
|
Here is an example of how a hypothetical system's fetch map might look:
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||
|
|
||
|
struct TURBO68K_FETCHREGION my_fetch[] =
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||
|
{
|
||
|
{ 0x000000, 0x3fffff, rom - 0x000000 },
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||
|
{ 0xff0000, 0xffffff, ram - 0xff0000 },
|
||
|
{ -1, -1, TURBO68K_NULL }
|
||
|
}
|
||
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|
||
|
The last element is required to let Turbo68K know where the array ends.
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||
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|
||
|
To hook the fetch map up to your context, you would code:
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||
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|
||
|
mycontext.super_fetch = my_fetch;
|
||
|
mycontext.user_fetch = my_fetch;
|
||
|
|
||
|
If you are only using one unified address space for both supervisor and user
|
||
|
modes, all you have to do is:
|
||
|
|
||
|
mycontext.fetch = my_fetch;
|
||
|
|
||
|
For the internal context, you must use the appropriate functions:
|
||
|
|
||
|
Turbo68KSetFetch(my_fetch, TURBO68K_SUPERVISOR);
|
||
|
Turbo68KSetFetch(my_fetch, TURBO68K_USER);
|
||
|
|
||
|
Or, if one address space is being used:
|
||
|
|
||
|
Turbo68KSetFetch(my_fetch, TURBO68K_NULL); /* second arg. ignored */
|
||
|
|
||
|
|
||
|
4.5 Data Access
|
||
|
|
||
|
Data accessing (byte, word, and long word read/writes) can be handled in a
|
||
|
number of ways. The first method is handled through definable memory map
|
||
|
arrays, somewhat similar to instruction fetching. This is the default method
|
||
|
(-defmap.)
|
||
|
|
||
|
Data Region Definition:
|
||
|
-----------------------
|
||
|
|
||
|
struct TURBO68K_DATAREGION
|
||
|
{
|
||
|
TURBO68K_UINT32 base;
|
||
|
TURBO68K_UINT32 limit;
|
||
|
TURBO68K_UINT32 ptr;
|
||
|
void *handler;
|
||
|
};
|
||
|
|
||
|
You may either set up a pointer, exactly the same as with instruction fetch
|
||
|
regions. But, if the pointer is not set up (TURBO68K_NULL), Turbo68K will
|
||
|
assume you want to use a handler. Simply set "handler" to the address of the
|
||
|
function you want to use, nothing has to be mangled.
|
||
|
|
||
|
Handler functions vary for different sizes of data:
|
||
|
|
||
|
/*
|
||
|
* Read byte
|
||
|
*/
|
||
|
|
||
|
TURBO68K_UINT8 ReadByte(TURBO68K_UINT32 addr)
|
||
|
{
|
||
|
/* ... */
|
||
|
}
|
||
|
|
||
|
/*
|
||
|
* Read word
|
||
|
*/
|
||
|
|
||
|
TURBO68K_UINT16 ReadWord(TURBO68K_UINT32 addr)
|
||
|
{
|
||
|
/* ... */
|
||
|
}
|
||
|
|
||
|
/*
|
||
|
* Read long word
|
||
|
*/
|
||
|
|
||
|
TURBO68K_UINT32 ReadLong(TURBO68K_UINT32 addr)
|
||
|
{
|
||
|
/* ... */
|
||
|
}
|
||
|
|
||
|
/*
|
||
|
* Write byte
|
||
|
*/
|
||
|
|
||
|
void WriteByte(TURBO68K_UINT32 addr, TURBO68K_UINT8 data)
|
||
|
{
|
||
|
/* ... */
|
||
|
}
|
||
|
|
||
|
/*
|
||
|
* Write word
|
||
|
*/
|
||
|
|
||
|
void WriteWord(TURBO68K_UINT32 addr, TURBO68K_UINT16 data)
|
||
|
{
|
||
|
/* ... */
|
||
|
}
|
||
|
|
||
|
/*
|
||
|
* Write long word
|
||
|
*/
|
||
|
|
||
|
void WriteLong(TURBO68K_UINT32 addr, TURBO68K_UINT32 data)
|
||
|
{
|
||
|
/* ... */
|
||
|
}
|
||
|
|
||
|
All handlers are passed addresses that are clipped to whichever value you
|
||
|
chose when emitting the emulator. By default, the address space is 24-bit.
|
||
|
|
||
|
NOTE: It is not a good idea to try to read the CCR from within a handler. Some
|
||
|
flag calculations are not completed until after data has been read/written.
|
||
|
In fact, do not read any registers besides PC (with the Turbo68KReadPC()
|
||
|
function.)
|
||
|
|
||
|
The 68000 and 68010 break down long word accesses into 2 consecutive word
|
||
|
word accesses, yet Turbo68K still uses long word handlers to provide
|
||
|
opportunities for optimization.
|
||
|
|
||
|
NOTE: Memory must be byte swapped. See section 4.8 for more information.
|
||
|
|
||
|
To hook up the memory maps, you would code:
|
||
|
|
||
|
mycontext.super_read_byte = my_read_byte;
|
||
|
mycontext.super_read_word = my_read_word;
|
||
|
mycontext.super_read_long = my_read_long;
|
||
|
mycontext.super_write_byte = my_write_byte;
|
||
|
mycontext.super_write_word = my_write_word;
|
||
|
mycontext.super_write_long = my_write_long;
|
||
|
|
||
|
mycontext.user_read_byte = my_read_byte;
|
||
|
mycontext.user_read_word = my_read_word;
|
||
|
mycontext.user_read_long = my_read_long;
|
||
|
mycontext.user_write_byte = my_write_byte;
|
||
|
mycontext.user_write_word = my_write_word;
|
||
|
mycontext.user_write_long = my_write_long;
|
||
|
|
||
|
If only one address space is being emulated, try:
|
||
|
|
||
|
mycontext.read_byte = my_read_byte;
|
||
|
mycontext.read_word = my_read_word;
|
||
|
/* ... */
|
||
|
|
||
|
When using an internal context, use the appropriate functions:
|
||
|
|
||
|
Turbo68KSetReadByte(my_read_byte, TURBO68K_SUPERVISOR);
|
||
|
Turbo68KSetReadWord(my_read_word, TURBO68K_SUPERVISOR);
|
||
|
/* ... */
|
||
|
|
||
|
|
||
|
The second method of handling data is to use functions exclusively. Use the
|
||
|
-handler option when emitting Turbo68K. Six functions (as shown above) must
|
||
|
be provided and directly hooked up to the context just as with memory maps.
|
||
|
Now, whenever the address space is read or written, your function will be
|
||
|
called and it is up to you to handle everything.
|
||
|
|
||
|
|
||
|
4.6 PC-Relative Reads
|
||
|
|
||
|
In some rare situations, PC-relative address reading cannot function properly
|
||
|
through the normal data access regions/handlers. An example of when this can
|
||
|
occur is when the emulated system uses partially encrypted ROMs (CPS-2.)
|
||
|
|
||
|
Turbo68K must be emitted with the -pcfetch option and a special fetch region
|
||
|
for PC-relative reads must be set up. Writes are still handled using the data
|
||
|
regions/handlers. The region is a TURBO68K_FETCHREGION and thus no handlers
|
||
|
can be used. Memory pointers must be provided in the exact same way as you
|
||
|
would for a normal fetch region.
|
||
|
|
||
|
The array of fetch regions must be attached to the "pcfetch" pointers of
|
||
|
the context:
|
||
|
|
||
|
mycontext.pcfetch = pcfetch;
|
||
|
mycontext.super_pcfetch = pcfetch;
|
||
|
mycontext.user_pcfetch = pcfetch;
|
||
|
|
||
|
When using an internal context, use Turbo68KSetPCFetch() and
|
||
|
Turbo68KGetPCFetch().
|
||
|
|
||
|
This is a pretty poor hack, but it should do the job in most cases. This
|
||
|
should not be needed for most systems.
|
||
|
|
||
|
|
||
|
4.7 Interrupts
|
||
|
|
||
|
Interrupts may be triggered with the Turbo68KInterrupt() function and when
|
||
|
they are being processed, an option call-back function may be called.
|
||
|
|
||
|
Turbo68KInterrupt() takes 2 arguments, the first is the level number, and the
|
||
|
second is the vector. For the vector, you may use TURBO68K_AUTOVECTOR for an
|
||
|
auto-vectored interrupt, TURBO68K_SPURIOUS for a spurious interrupt, and
|
||
|
TURBO68K_UNINITIALIZED for an uninitialized interrupt.
|
||
|
|
||
|
Interrupts will be checked for and processed at the start of Turbo68KRun() or
|
||
|
when Turbo68KProcessInterrupts() is called.
|
||
|
|
||
|
If the "InterruptAcknowledge" member of the context is null, the function it
|
||
|
points to will not be called, otherwise, the call-back can be used to make
|
||
|
certain that interrupts have been processed, if the hardware being emulated
|
||
|
requires this (for example, on the Sega Genesis, the call-back can be used to
|
||
|
update IRQ-related bit settings in the VDP status register.)
|
||
|
|
||
|
The call-back takes a single argument: The interrupt vector number passed to
|
||
|
Turbo68KInterrupt() (a TURBO68K_UINT32), and returns nothing. If
|
||
|
TURBO68K_AUTOVECTOR was passed to Turbo68KInterrupt(), the call-back will get
|
||
|
the proper vector for the level being processed. If non-autovectored
|
||
|
interrupts are triggered, there is no way to determine which level is being
|
||
|
processed at the time the call-back is invoked.
|
||
|
|
||
|
The InterruptAcknowledge pointer can be directly accessed regardless of
|
||
|
whether you use your own context, or Turbo68K's internal context:
|
||
|
|
||
|
turbo68kcontext_68000.InterruptAcknowledge = &MyIRQAckHandler;
|
||
|
|
||
|
Make sure to set it to TURBO68K_NULL if you do not wish to make use of the
|
||
|
call-back feature. It is possible to access this member at any time.
|
||
|
|
||
|
|
||
|
4.8 Byte Swapped Memory
|
||
|
|
||
|
Host memory which Turbo68K can access directly must be byte swapped! The
|
||
|
MSB (most significant byte) and LSB (least significant byte) of each 16-bit
|
||
|
aligned word must be reversed.
|
||
|
|
||
|
Sample Byte Swapping Function:
|
||
|
------------------------------
|
||
|
|
||
|
/*
|
||
|
* void SwapMemory(TURBO68K_UINT8 *mem, TURBO68K_INT32 size);
|
||
|
*
|
||
|
* Byte swaps a given region of memory to work with Turbo68K's native
|
||
|
* access capabilities.
|
||
|
*/
|
||
|
|
||
|
void SwapMemory(TURBO68K_UINT8 *mem, TURBO68K_INT32 size)
|
||
|
{
|
||
|
TURBO68K_UINT32 i, j;
|
||
|
|
||
|
/*
|
||
|
* Swap bytes in each word
|
||
|
*/
|
||
|
|
||
|
for (i = 0; i < length; i += 2)
|
||
|
{
|
||
|
j = buffer[i];
|
||
|
buffer[i] = buffer[i + 1];
|
||
|
buffer[i + 1] = j;
|
||
|
}
|
||
|
}
|
||
|
|
||
|
Byte swapping is an optimization which greatly benefits Turbo68K in terms of
|
||
|
speed. It relies on the fact that the 68000 and 68010 use a 16-bit data bus.
|
||
|
To access individual bytes in byte swapped memory, XOR the address with 1.
|
||
|
Words can be read or written normally. Long words are best accessed as 2
|
||
|
consecutive words.
|
||
|
|
||
|
|
||
|
4.9 The RESET and BKPT Instructions
|
||
|
|
||
|
When the RESET or BKPT instruction is executed, the respective handler is
|
||
|
called. If the handler is found to be TURBO68K_NULL, no action is taken.
|
||
|
This is useful for emulating the functionality of the RESET (some systems need
|
||
|
to reset hardware when it is executed) and BKPT (some systems might need to
|
||
|
react to the Breakpoint Acknowledge Cycle) instructions. The BKPT handler is
|
||
|
called before the 68010 processes the breakpoint exception.
|
||
|
|
||
|
You can also perform high level emulation (HLE) by strategically inserting
|
||
|
RESET (or BKPT, if dealing with a 68010) instructions into the emulated code.
|
||
|
Use Turbo68KReadPC() to make sure you know which RESET/BKPT was executed.
|
||
|
Turbo68KReadPC() will point to the next instruction.
|
||
|
|
||
|
When setting up the handlers, no special functions are needed, even if the
|
||
|
internal context is being manipulated.
|
||
|
|
||
|
mycontext.Reset = &MyRESETHandler;
|
||
|
|
||
|
turbo68kcontext_68000.Reset = &MyRESETHandler;
|
||
|
|
||
|
The RESET handler takes no arguments and returns nothing. The BKPT handler is
|
||
|
passed the breakpoint vector number (0-7.)
|
||
|
|
||
|
/*
|
||
|
* Sample RESET handler
|
||
|
*/
|
||
|
|
||
|
void MyRESETHandler()
|
||
|
{
|
||
|
/* ... Reset some hardware ... */
|
||
|
}
|
||
|
|
||
|
/*
|
||
|
* Sample BKPT handler
|
||
|
*/
|
||
|
|
||
|
void MyBKPTHandler(TURBO68K_INT32 num)
|
||
|
{
|
||
|
/* ... */
|
||
|
}
|
||
|
|
||
|
|
||
|
4.10 Initializing and Resetting Turbo68K
|
||
|
|
||
|
Prior to doing anything, call Turbo68KInit() to initialize Turbo68K. This
|
||
|
only needs to be done once per program session.
|
||
|
|
||
|
Next, set up your memory maps. Then, reset the 680X0 processor by calling the
|
||
|
Turbo68KReset() function. Turbo68K fetches the initial PC and SP from the
|
||
|
supervisor fetch memory map, not through the long word read map. Turbo68K
|
||
|
will return an error if it could not reset. This means you have set up your
|
||
|
memory map incorrectly.
|
||
|
|
||
|
/*
|
||
|
* Initialize Turbo68K (VERY important)
|
||
|
*/
|
||
|
|
||
|
Turbo68KInit();
|
||
|
|
||
|
/* ... set up memory maps and interrupt call-back (optional) ... */
|
||
|
|
||
|
/*
|
||
|
* Reset the processor
|
||
|
*/
|
||
|
|
||
|
if (Turbo68KReset() != TURBO68K_OKAY)
|
||
|
Error();
|
||
|
|
||
|
/* ... begin emulating ... */
|
||
|
|
||
|
|
||
|
4.11 Running the Emulator
|
||
|
|
||
|
To execute code, use Turbo68KRun(). Pass it the number of cycles you wish
|
||
|
to run for. Turbo68K will execute at least as many cycles as you wanted, but
|
||
|
often executes a bit more. You can use Turbo68KGetElapsedCycles() to find
|
||
|
out exactly how many were emulated. See the function reference for more
|
||
|
information.
|
||
|
|
||
|
Turbo68KInterrupt() can be used to trigger an interrupt. Please see section
|
||
|
4.7 for more information on interrupts.
|
||
|
|
||
|
/*
|
||
|
* Run Turbo68K for 1000 cycles
|
||
|
*/
|
||
|
|
||
|
Turbo68KRun(1000);
|
||
|
|
||
|
/*
|
||
|
* Level 6 auto-vectored interrupt
|
||
|
*/
|
||
|
|
||
|
Turbo68KInterrupt(6, TURBO68K_AUTOVECTOR);
|
||
|
|
||
|
Both Turbo68KRun() and Turbo68KInterrupt() can return error information.
|
||
|
See the function reference for more information.
|
||
|
|
||
|
|
||
|
-------------------------
|
||
|
5. Function Reference
|
||
|
-------------------------
|
||
|
|
||
|
All of Turbo68K's functions are described here. Functions which are said not
|
||
|
to work under given circumstances will have undefined results if used under
|
||
|
those conditions. Usually, this means the context will be trashed, so be very
|
||
|
careful!
|
||
|
|
||
|
When Turbo68K is running, any handlers you may have set up are considered
|
||
|
part of Turbo68K. Thus, when it is said a function cannot be called while
|
||
|
Turbo68K is running, this means it cannot be called from a handler.
|
||
|
|
||
|
TURBO68K_INT32 Turbo68KInit();
|
||
|
Initializes the emulator. This must be called before anything else.
|
||
|
Input:
|
||
|
Nothing.
|
||
|
Returns:
|
||
|
TURBO68K_OKAY
|
||
|
Restrictions:
|
||
|
For future compatibility, call this only once per program session.
|
||
|
|
||
|
TURBO68K_INT32 Turbo68KReset();
|
||
|
Resets the 680X0. It uses the supervisor instruction fetch region to
|
||
|
obtain the start-up vectors. Make sure everything is set up. A fetch
|
||
|
error indicates either that the reset vectors could not be fetched or
|
||
|
the PC reset vector points to an unhandled region of memory.
|
||
|
Input:
|
||
|
Nothing.
|
||
|
Returns:
|
||
|
TURBO68K_OKAY
|
||
|
TURBO68K_ERROR_FETCH (PC is out of bounds)
|
||
|
Restrictions:
|
||
|
Do not use while Turbo68K is running.
|
||
|
|
||
|
TURBO68K_INT32 Turbo68KRun(TURBO68K_INT32 cycles);
|
||
|
Executes at least the specified number of cycles. To get the actual
|
||
|
number of cycles that were emulated, use Turbo68KGetElapsedCycles().
|
||
|
Input:
|
||
|
Number of cycles.
|
||
|
Returns:
|
||
|
TURBO68K_OKAY
|
||
|
TURBO68K_ERROR_FETCH (PC is out of bounds)
|
||
|
TURBO68K_ERROR_INVINST (invalid instruction, if -noillegal was
|
||
|
specified)
|
||
|
TURBO68K_ERROR_STACKFRAME (68010 only, unsupported/invalid stack
|
||
|
frame, see section 7.2)
|
||
|
Restrictions:
|
||
|
Do not use while Turbo68K is running.
|
||
|
|
||
|
TURBO68K_INT32 Turbo68KProcessInterrupts();
|
||
|
Processes any pending interrupts (unless the priority level does not
|
||
|
agree with the SR priority bits.)
|
||
|
Input:
|
||
|
Nothing.
|
||
|
Returns:
|
||
|
TURBO68K_OKAY
|
||
|
TURBO68K_ERROR_FETCH
|
||
|
Restrictions:
|
||
|
None. (If called while Turbo68K is running, it has no effect.)
|
||
|
|
||
|
|
||
|
TURBO68K_INT32 Turbo68KInterrupt(TURBO68K_INT32 level,
|
||
|
TURBO68K_UINT32 vector);
|
||
|
Generates an interrupt with the specified level and vector. The level
|
||
|
must be 1-7 and the vector cannot be less than 2. For the vector, you
|
||
|
may specify the vector itself, TURBO68K_AUTOVECTOR for an autovectored
|
||
|
interrupt, TURBO68K_SPURIOUS for a spurious interrupt, or
|
||
|
TURBO68K_UNINITIALIZED for an uninitialized interrupt. If the
|
||
|
"InterruptAcknowledge" member of the context is not null, the function
|
||
|
it points to will be called as each interrupt is being taken.
|
||
|
Input:
|
||
|
Level.
|
||
|
Vector.
|
||
|
Returns:
|
||
|
TURBO68K_OKAY
|
||
|
TURBO68K_INTLEVEL (invalid level)
|
||
|
TURBO68K_INTVECTOR (invalid vector)
|
||
|
TURBO68K_INTPENDING (interrupt already pending at this level; this
|
||
|
is not an error and will frequently occur, it is best not to check
|
||
|
for this)
|
||
|
Restrictions:
|
||
|
None.
|
||
|
|
||
|
TURBO68K_INT32 Turbo68KCancelInterrupt(TURBO68K_INT32 level);
|
||
|
Cancels the pending interrupt at the specified level.
|
||
|
Input:
|
||
|
Level.
|
||
|
Returns:
|
||
|
TURBO68K_OKAY
|
||
|
TURBO68K_INTLEVEL (invalid level)
|
||
|
Restrictions:
|
||
|
None.
|
||
|
|
||
|
TURBO68K_UINT32 Turbo68KReadPC();
|
||
|
Returns the current PC. If this is called from within a handler, the
|
||
|
PC may point at the next instruction or to one of the operand words.
|
||
|
Input:
|
||
|
Nothing.
|
||
|
Returns:
|
||
|
PC
|
||
|
Restrictions:
|
||
|
None.
|
||
|
|
||
|
void Turbo68KSetFetch(void *fetch, TURBO68K_INT32 type);
|
||
|
void Turbo68KSetPCFetch(void *pcfetch, TURBO68K_INT32 type);
|
||
|
void Turbo68KSetReadByte(void *read_byte, TURBO68K_INT32 type);
|
||
|
void Turbo68KSetReadWord(void *read_word, TURBO68K_INT32 type);
|
||
|
void Turbo68KSetReadLong(void *read_long, TURBO68K_INT32 type);
|
||
|
void Turbo68KSetWriteByte(void *write_byte, TURBO68K_INT32 type);
|
||
|
void Turbo68KSetWriteWord(void *write_word, TURBO68K_INT32 type);
|
||
|
void Turbo68KSetWriteLong(void *write_long, TURBO68K_INT32 type);
|
||
|
These functions will attach memory maps to the internal context. If
|
||
|
you want to attach memory maps to a context you have created (which is
|
||
|
not mapped in), you must assign them manually.
|
||
|
Input:
|
||
|
Memory map array or function pointer (depending on whether
|
||
|
Turbo68K was configured for memory map arrays or handlers)
|
||
|
Type: TURBO68K_SUPERVISOR or TURBO68K_USER. If you are not
|
||
|
emulating the distinction, this argument can be set to anything
|
||
|
and will be ignored.
|
||
|
Returns:
|
||
|
Nothing.
|
||
|
Restrictions:
|
||
|
If different address spaces for supervisor and user modes are
|
||
|
being emulated and the "type" argument is unrecognized, the
|
||
|
behavior is undefined.
|
||
|
|
||
|
void *Turbo68KGetFetch(TURBO68K_INT32 type);
|
||
|
void *Turbo68KGetPCFetch(TURBO68K_INT32 type);
|
||
|
void *Turbo68KGetReadByte(TURBO68K_INT32 type);
|
||
|
void *Turbo68KGetReadWord(TURBO68K_INT32 type);
|
||
|
void *Turbo68KGetReadLong(TURBO68K_INT32 type);
|
||
|
void *Turbo68KGetWriteByte(TURBO68K_INT32 type);
|
||
|
void *Turbo68KGetWriteWord(TURBO68K_INT32 type);
|
||
|
void *Turbo68KGetWriteLong(TURBO68K_INT32 type);
|
||
|
Will return the memory map or function pointers that are associated
|
||
|
with each type of access.
|
||
|
Input:
|
||
|
Type: TURBO68K_SUPERVISOR or TURBO68K_USER. If you are not
|
||
|
emulating the distinction, this argument can be set to anything
|
||
|
and will be ignored.
|
||
|
Returns:
|
||
|
Memory map array or function pointer.
|
||
|
Restrictions:
|
||
|
If different address spaces for supervisor and user modes are
|
||
|
being emulated and the "type" argument is unrecognized, the
|
||
|
behavior is undefined.
|
||
|
|
||
|
TURBO68K_UINT8 *Turbo68KFetchPtr(TURBO68K_UINT32 addr);
|
||
|
Return a host pointer to the specified address in the current address
|
||
|
space. Turbo68K scans the fetch region and if the address is not
|
||
|
found, it will return 0. This is useful for disassemblers.
|
||
|
Input:
|
||
|
Address.
|
||
|
Returns:
|
||
|
Host address.
|
||
|
Restrictions:
|
||
|
Only the address space currently being used will be scanned. In
|
||
|
order to select the supervisor or user address space, you will
|
||
|
have to modify the privilege mode bit in SR and restore it to its
|
||
|
original value when finished.
|
||
|
|
||
|
TURBO68K_UINT8 Turbo68KReadByte(TURBO68K_UINT32 addr);
|
||
|
TURBO68K_UINT16 Turbo68KReadWord(TURBO68K_UINT32 addr);
|
||
|
TURBO68K_UINT32 Turbo68KReadLong(TURBO68K_UINT32 addr);
|
||
|
void Turbo68KWriteByte(TURBO68K_UINT32 addr, TURBO68K_UINT8 data);
|
||
|
void Turbo68KWriteWord(TURBO68K_UINT32 addr, TURBO68K_UINT16 data);
|
||
|
void Turbo68KWriteLong(TURBO68K_UINT32 addr, TURBO68K_UINT32 data);
|
||
|
These functions read/write data from the current Turbo68K address
|
||
|
space. Thus, they can call handlers you have set up. These are
|
||
|
particularly useful for debuggers. Be careful, the PC (and possibly
|
||
|
other context data) will be invalid.
|
||
|
Input:
|
||
|
Address (and data if writing.)
|
||
|
Returns:
|
||
|
Data (or nothing if writing.)
|
||
|
Restrictions:
|
||
|
Do not use while Turbo68K is running.
|
||
|
|
||
|
void Turbo68KSetContext(struct TURBO68K_CONTEXT *context);
|
||
|
void Turbo68KGetContext(struct TURBO68K_CONTEXT *context);
|
||
|
Map contexts in and out of the internal context using this pair of
|
||
|
functions. Turbo68K operates only on its internal context, so it is
|
||
|
necessary to copy externally-defined contexts into turbo68kcontext_*
|
||
|
when you want to emulate the processor they define. These functions
|
||
|
also make adjustments to the addresses contained in fetch, read_byte,
|
||
|
etc. in order to speed things up -- therefore you cannot access these
|
||
|
members, or any other context member, while it is mapped in.
|
||
|
Input:
|
||
|
Address of context to map in/out.
|
||
|
Returns:
|
||
|
Nothing.
|
||
|
Restrictions:
|
||
|
Do not use while Turbo68K is running.
|
||
|
|
||
|
TURBO68K_UINT32 Turbo68KGetContextSize();
|
||
|
Returns the size, in bytes, of a Turbo68K context. This is useful for
|
||
|
asserting that your compiler is packing the contexts correctly.
|
||
|
Input:
|
||
|
Nothing.
|
||
|
Returns:
|
||
|
Size of context in bytes.
|
||
|
Restrictions:
|
||
|
None.
|
||
|
|
||
|
void Turbo68KClearCycles();
|
||
|
Clears both "cycles" and "remaining" causing Turbo68K to exit early.
|
||
|
Be careful: a call to Turbo68KGetElapsedCycles() after this will
|
||
|
return 0 or a small number which does not reflect the total amount of
|
||
|
cycles used since Turbo68K was last called to run.
|
||
|
Input:
|
||
|
Nothing.
|
||
|
Returns:
|
||
|
Nothing.
|
||
|
Restrictions:
|
||
|
None.
|
||
|
|
||
|
void Turbo68KFreeTimeSlice();
|
||
|
Causes Turbo68K to stop running early by working some magic on both
|
||
|
"cycles" and "remaining." Unlike Turbo68KClearCycles(), you can get
|
||
|
the number of cycles executed with Turbo68KGetElapsedCycles().
|
||
|
Input:
|
||
|
Nothing.
|
||
|
Returns:
|
||
|
Nothing.
|
||
|
Restrictions:
|
||
|
If called from a handler, Turbo68K does not actually stop running
|
||
|
until the current instruction finishes.
|
||
|
|
||
|
TURBO68K_INT32 Turbo68KGetElapsedCycles();
|
||
|
Returns the amount of cycles run.
|
||
|
Input:
|
||
|
Nothing.
|
||
|
Returns:
|
||
|
Cycles run.
|
||
|
Restrictions:
|
||
|
None.
|
||
|
|
||
|
|
||
|
---------------------
|
||
|
6. Hints and Tips
|
||
|
---------------------
|
||
|
|
||
|
For those of you who want to get the most out of Turbo68K, this section aims
|
||
|
to provide you with some neat little tricks to try.
|
||
|
|
||
|
|
||
|
6.1 Alternative Identifiers
|
||
|
|
||
|
The default identifier names have nothing preceding them (Turbo68KInit(),
|
||
|
turbo68kcontext_68000, Turbo68KReset(), etc.) However, if the need arises, you
|
||
|
can change the identifier names by adding a string (up to 16 characters) to
|
||
|
the beginning of them.
|
||
|
|
||
|
Use the -id option to emit Turbo68K with different identifier names. The data
|
||
|
types and macros will not be changed, TURBO68K_CONTEXT_68000 will remain as it
|
||
|
is, so will TURBO68K_OKAY, etc.
|
||
|
|
||
|
You must also use the TURBO68K_ID() macro defined in TURBO68K.H to set the new
|
||
|
identifier names immediately after the header file has been included. For
|
||
|
example, if you want identifiers that start with "foo" you would write:
|
||
|
|
||
|
#include "turbo68k.h"
|
||
|
TURBO68K_ID(foo);
|
||
|
|
||
|
You can do this multiple times. If you have linked in 2 copies of Turbo68K,
|
||
|
one with identifiers that start with "foo", and another with identifiers
|
||
|
starting with "bar", you would write:
|
||
|
|
||
|
#include "turbo68k.h"
|
||
|
TURBO68K_ID(foo);
|
||
|
TURBO68K_ID(bar);
|
||
|
|
||
|
With the above example, you would have functions like: fooTurbo68KInit(),
|
||
|
barTurbo68KInit(), and (if you linked in another copy of Turbo68K without
|
||
|
modified identifiers) Turbo68KInit().
|
||
|
|
||
|
|
||
|
6.2 Multiple Processors
|
||
|
|
||
|
Emulating multiple processors is fairly simple (unless extremely accurate
|
||
|
timing is required.) You have to set up a context for each processor. You may
|
||
|
not use the internal context as one of them, since it will be overwritten if
|
||
|
you map in the other processor.
|
||
|
|
||
|
Simplistic Example of Running 2 68000s:
|
||
|
---------------------------------------
|
||
|
|
||
|
struct TURBO68K_CONTEXT_68000 context[2];
|
||
|
|
||
|
/* ... */
|
||
|
|
||
|
for (int i = 0; i < 2; i++)
|
||
|
{
|
||
|
Turbo68KSetContext(&context[i]);
|
||
|
Turbo68KRun(500);
|
||
|
Turbo68KGetContext(&context[i]);
|
||
|
}
|
||
|
|
||
|
Since Turbo68K is non-reentrant, you cannot multi-thread 2 processors unless
|
||
|
you link in 2 separate builds of Turbo68K (with different identifier names,
|
||
|
you can use the -id option for this.)
|
||
|
|
||
|
|
||
|
6.3 Maximizing Speed and Minimizing Size
|
||
|
|
||
|
What better reasons to write a CPU emulator in assembly language than for
|
||
|
speed and size? To get the most speed and least size (the 2 don't always co-
|
||
|
exist) out of Turbo68K, here are a few things you can try:
|
||
|
|
||
|
1. If you are using memory map arrays, set them up wisely. If you have
|
||
|
memory regions bordering each other, try turning them into a single
|
||
|
large region. This not only cuts down the time it takes to scan through
|
||
|
the map, but lets code flow between the regions. Put the most commonly
|
||
|
accessed regions at the beginning of the array, and the least commonly
|
||
|
accessed at the end.
|
||
|
2. Consider using handlers and not memory map arrays (-handler option.) If
|
||
|
you can write a fast and clean set of handlers, you can speed things up
|
||
|
by taking a load of work off of Turbo68K's back. Optimize your long-
|
||
|
word handlers as well. It is perfectly okay to have a long-word handler
|
||
|
call your word handlers twice and return the combined data, but it is
|
||
|
faster to write the handlers specifically for long-word accesses.
|
||
|
3. Execute code in large time slices. The overhead of Turbo68KRun() is
|
||
|
significant but it can be compensated by spending more time emulating.
|
||
|
Throw Turbo68KSetContext()/Turbo68KGetContext() in the mix and the
|
||
|
gains are even greater.
|
||
|
4. Try using -nodummyread if you can get away with it. For most systems,
|
||
|
it is unnecessary to emulate this tiny detail.
|
||
|
5. If possible, use -nobrafetch (the default) instead of -brafetch. The
|
||
|
branch instructions are used a lot. If -skip does not impact compatib-
|
||
|
ility, consider using it, too.
|
||
|
6. If you can get away with sneaking in a 32-bit address bus, do it. The
|
||
|
68000 and 68010 actuall use a 24-bit address bus, which means that
|
||
|
Turbo68K has to mask off the unused bits when fetching data. The
|
||
|
overhead of doing this is negligible, but if you can get away with
|
||
|
using the full 32-bits, go for it.
|
||
|
7. Don't allow separate address spaces for supervisor and user if you can
|
||
|
get away with it (with most systems, it isn't needed.) This reduces
|
||
|
some overhead in some of the instruction handlers and functions.
|
||
|
8. Link the Turbo68K object file close to the object files which call it
|
||
|
most frequently. The theory behind this is that the processor will be
|
||
|
able to easily cache in code areas that use each other often. It might
|
||
|
not always yield any speed increase, but I have observed slightly
|
||
|
quicker performance when optimizing the link order in Genital.
|
||
|
9. Strip the program you compile, this will reduce the executable tremend-
|
||
|
ously. Turbo68K leaves behind a lot of symbols and junk.
|
||
|
|
||
|
There is a lot to do on my part. Turbo68K features some really poor code, but
|
||
|
usually in uncommon instructions. When/if I have time, I will optimize what I
|
||
|
can, but not all at once.
|
||
|
|
||
|
|
||
|
6.4 Sega Genesis TAS Bug
|
||
|
|
||
|
The TAS instruction is usually used in multi-processor systems to synchronize
|
||
|
execution between multiple 68Ks because it takes the bus. But on the Sega
|
||
|
Genesis, the VDP will not release the bus and TAS instructions consequently
|
||
|
do not write to memory.
|
||
|
|
||
|
In order to emulate this, comment out the call to WriteByte() in the TAS()
|
||
|
function in make68k.c. This will fix Gargoyles and possible some other games
|
||
|
which use the TAS instruction. The Genesis 3 apparently fixes this little bug
|
||
|
and games like Gargoyles no longer work.
|
||
|
|
||
|
|
||
|
-----------------------
|
||
|
7. Additional Notes
|
||
|
-----------------------
|
||
|
|
||
|
This is a collection of miscellaneous notes, points of interest, and errata.
|
||
|
|
||
|
|
||
|
7.1 Change History
|
||
|
|
||
|
January 19, 2002: Version 0.6
|
||
|
- CMPI and CMP no longer write back to memory
|
||
|
- Turbo68KCancelInterrut() fixed (uses EAX*4 as an index into the
|
||
|
interrupt array, so it now actually cancels interrupts)
|
||
|
- Optmized Turbo68KCancelInterrupt() slightly
|
||
|
- Added the "InterruptAcknowledge" call-back to facilitate more accurate
|
||
|
interrupt handling on some systems (such as the Sega Genesis)
|
||
|
- API functions now use the stack to save registers. Turbo68KInterrupt()
|
||
|
can now be called from within a memory handler
|
||
|
- Turbo68KGetXXX() functions now properly retrieve arguments passed to
|
||
|
them
|
||
|
- Some instruction handlers now use the stack to save registers
|
||
|
|
||
|
( Thanks to Charles MacDonald for submitting most of these fixes and
|
||
|
additions! )
|
||
|
|
||
|
June 29, 2001: Version 0.5
|
||
|
- Changed the name to "Turbo68K"
|
||
|
- Undocumented flags emulated (verified against real 68000 processors)
|
||
|
- N flag calculation for ABCD, SBCD, and NBCD instructions is now truly
|
||
|
accurate
|
||
|
- Dummy read emulation added for CLR, Scc, and the unprivileged version of
|
||
|
"MOVE from SR." It is on by default and works only when the processor
|
||
|
type is 68000
|
||
|
- CHK comparisons are now signed as they should be
|
||
|
- Fixed internal calls to API functions to work with register calling
|
||
|
conventions
|
||
|
|
||
|
June 15, 2001: Version 0.4
|
||
|
- Now uses proper identifier names when internally calling
|
||
|
Genital68KUpdateFetchPtr()
|
||
|
- N flag is now calculated for SBCD (thanks to ElSemi for this!)
|
||
|
- Optimized C flag calculation for SBCD -(Ax),-(Ay) and ABCD -(Ax),-(Ay)
|
||
|
- N flag for ABCD is calculated the same way as for SBCD (not sure if this
|
||
|
is correct, I'll verify it once my Saturn 68K debugger is complete)
|
||
|
|
||
|
May 7, 2001: Version 0.35
|
||
|
- Output file is now properly closed on exit
|
||
|
- RTD is no longer emitted as a 68000 instruction (68010 only)
|
||
|
- Initial PC and SP are now read from the instruction fetch memory maps
|
||
|
- Instructions are emitted in a more optimal order, cache performance
|
||
|
might be better
|
||
|
|
||
|
April 29, 2001: Version 0.3
|
||
|
- Fixed a MOVEM bug (example: MOVEM.L (A7)+,A7)
|
||
|
- Added rudimentary 68010 support
|
||
|
- "MOVE from SR" is no longer privileged for 68000 processors
|
||
|
- Rewrote documentation
|
||
|
- Possibly other minor changes I forgot to list
|
||
|
|
||
|
February 11, 2001: Version 0.22
|
||
|
- Added a PC-relative read mode (useful in very special circumstances)
|
||
|
- Removed some unused data
|
||
|
- Removed sign-extended byte read functions (they were not being used)
|
||
|
|
||
|
January 13, 2001: Version 0.21
|
||
|
- Fixed Genital68KReadXXX() and Genital68KWriteXXX() functions, they no
|
||
|
longer trash the PC
|
||
|
|
||
|
January 7, 2001: Version 0.2
|
||
|
- Slightly modified Genital68KReadXXX() and Genital68KWriteXXX() functions
|
||
|
- Registers are now saved when Genital68K functions are called
|
||
|
- Minor optimizations here and there
|
||
|
|
||
|
December 8, 2000: Version 0.12
|
||
|
- Fixed a bug with register calling conventions and read/write handlers
|
||
|
|
||
|
December 4, 2000: Version 0.11
|
||
|
- Fixed a bug in Genital68KGetContext() and Genital68KSetContext() which
|
||
|
corrupted user and supervisor address spaces
|
||
|
- Corrected a misleading comment in MAKE68K.C and updated the macro refer-
|
||
|
ence in this document
|
||
|
|
||
|
December 3, 2000: Version 0.1
|
||
|
- Added user/supervisor address space distinction (optional)
|
||
|
- Changed address space functions
|
||
|
- Added a GENITAL68K_NULL macro
|
||
|
- Fixed some mistakes in this document
|
||
|
|
||
|
November 23, 2000: Version 0.0
|
||
|
- Initial release
|
||
|
|
||
|
|
||
|
7.2 Un-emulated Features
|
||
|
|
||
|
The following are not emulated:
|
||
|
|
||
|
Tracing Turbo68K does not emulate trace exceptions.
|
||
|
Address Errors Turbo68K does not emulate address error exceptions. The
|
||
|
X86 allows for misaligned accesses (unless alignment
|
||
|
checking is on), and consequently, so does Turbo68K.
|
||
|
Bus Errors Bus errors are not emulated.
|
||
|
Undefined Bits Undefined bits in the SR are usually kept 0.
|
||
|
FC Output Lines The real 68000 and 68010 classify address space accesses
|
||
|
as either "User Data", "User Program", "Supervisor Data",
|
||
|
"Supervisor Program", or "CPU Space." Turbo68K
|
||
|
simplifies this by supporting a user address space and a
|
||
|
supervisor address space. There is also an option to
|
||
|
disable this distinction and use one address space.
|
||
|
MOVES The effects of the alternate function code registers (SFC
|
||
|
and DFC) are not emulated. This includes the 68010 MOVES
|
||
|
instruction.
|
||
|
Loop Mode Loop mode (68010) is not emulated. Perhaps if someone
|
||
|
supplies me with very detailed information on how it
|
||
|
works, I might consider adding it.
|
||
|
Stack Frames Only stack frame 0 is supported. Stack frame 8 (associated
|
||
|
with group 0 exceptions: bus and address errors) is never
|
||
|
used and if encountered, Turbo68KRun() returns a stack
|
||
|
frame error. When such an error occurs, the processor
|
||
|
state will look as if the problematic RTE instruction had
|
||
|
never been executed.
|
||
|
68010 Timing For instructions common to both the 68000 and 68010 (most
|
||
|
of them), 68000 timing is used.
|
||
|
|
||
|
|
||
|
7.3 Errata
|
||
|
|
||
|
Although I have attempted to fix every bug I came across, there is bound to be
|
||
|
something obscure, or possibly major, left undiscovered. There are a few
|
||
|
unimportant inaccuracies I do know about, but have not bothered to fix yet:
|
||
|
|
||
|
DIVS, DIVU Timing is off by up to 10% in worst-case scenarios.
|
||
|
MULS, MULU Timing is off by an unknown amount. The multiplication
|
||
|
algorithm used by the 68000 and 68010 affects timing in
|
||
|
pretty odd ways.
|
||
|
Timing Some of the instructions have slightly inacurrate timing,
|
||
|
usually because of human error. Timing for exceptions and
|
||
|
interrupts is often wrong (but not TOO far off.)
|
||
|
Exceptions Priority between interrupts and other exceptions (such as
|
||
|
privilege violation, division by 0, TRAP, TRAPV, etc.) is
|
||
|
not fully emulated. Priority among interrupts themselves
|
||
|
seems to be properly handled, and that is most important.
|
||
|
I have not seen any situations where interrupts and other
|
||
|
exceptions affect each other.
|
||
|
|
||
|
More information on the priority of spurious and uninitialized interrupts as
|
||
|
well as level 7 would be appreciated. I am going off what little the Motorola
|
||
|
manuals say.
|
||
|
|
||
|
|
||
|
7.4 Bibliography
|
||
|
|
||
|
Most of what I know about 680X0 processors comes from the 2 free manuals I
|
||
|
ordered from Motorola. The rest comes from individuals who kindly helped me
|
||
|
and are mentioned in section 8.
|
||
|
|
||
|
Documents Used:
|
||
|
---------------
|
||
|
|
||
|
- "Programmer's Reference Manual" by Motorola (M68000PM/AD REV 1)
|
||
|
- "M68000 8-/16-/32-Bit Microprocessor User's Manual Ninth Edition" by
|
||
|
Motorola (M68000UM/AD REV 8)
|
||
|
|
||
|
|
||
|
---------------------
|
||
|
8. Special Thanks
|
||
|
---------------------
|
||
|
|
||
|
Many thanks go out to those who helped me out with Turbo68K and contributed
|
||
|
to the project in any form.
|
||
|
|
||
|
- Neil Bradley
|
||
|
- Victor Moya
|
||
|
- Dynarec Mailing List: M.I.K.e, Neil Griffiths, Gwenole, etc.
|
||
|
- Quintesson
|
||
|
- Steve Snake
|
||
|
- Tim Meekins
|
||
|
- Kuwanger
|
||
|
- Charles MacDonald
|
||
|
- Stephane Dallongeville
|
||
|
- Eli Dayan
|
||
|
- Neill Corlett
|
||
|
- Pete Dabbs
|
||
|
- ElSemi
|
||
|
|
||
|
And, of course, thank YOU! Remember, comments, suggestions, and contributions
|
||
|
are more than welcome, so get in touch with me. See you next time!
|