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428 lines
17 KiB
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428 lines
17 KiB
TeX
\documentstyle{article}
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\title{{\huge{Syn68k}} \\ ARDI's dynamically compiling 68LC040 emulator}
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\author{Mat Hostetter {\verb+<mat@ardi.com>+}}
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\date{\today}
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\begin{document}
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\maketitle
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\section{Overview}
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This document is meant to give a concise technical summary of how
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syn68k works.
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``Syn68k,'' ARDI's 68LC040 emulator, is both highly portable and
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fast. The portable core of syn68k, which works by dynamically
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compiling 680x0 code into an efficient interpreted form, was designed
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to run on all major CPU's. On supported architectures, syn68k can
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also translate 680x0 code into native code that the host processor
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can run directly.
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\section{Syngen}
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ARDI's ``syngen'' system analyzes a lisp-like file describing the
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bit patterns and semantics of the 680x0 instruction set and produces
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lookup tables and C code for the runtime system to use. This
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process takes place only when syn68k is built, so we can afford
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extensive analysis here. The code and tables generated by syngen
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depend somewhat on the characteristics of the host processor; for
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example, on a little endian machine it is advantageous to byte swap
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some extracted 680x0 operands at compile time instead of at runtime.
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The 680x0 description file can describe multiple ways to emulate
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any particular 680x0 opcode. The runtime system looks at what CC
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bits are live after the instruction and chooses the fastest variant
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it can legally use. In the following example, we have two CC
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variants of lsrw; one computes no CC bits, and the other computes
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all of them:
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\begin{verbatim}
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(defopcode lsrw_ea
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(list 68000 amode_alterable_memory () (list "1110001011mmmmmm"))
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(list "-----" "-----" dont_expand
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(assign $1.muw (>> $1.muw 1)))
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(list "CN0XZ" "-----" dont_expand
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(list
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(assign ccx (assign ccc (& $1.muw 1)))
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(ASSIGN_NNZ_WORD (assign $1.muw (>> $1.muw 1))))))
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\end{verbatim}
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The 680x0 description file can also specify which 680x0 operands
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should be ``expanded'' to become implicitly known by the corresponding
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synthetic opcode. For example, fully expanding out ``addl dx,dy''
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would result in 64 synthetic opcodes, one for each combination of
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data register operands. This results in smaller and faster synthetic
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opcodes at the expense of increasing the total number of synthetic
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opcodes. To conserve space, we only expand out common 680x0 opcodes.
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On host architectures where we can compile to native code, we don't
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waste space by ``expanding out'' common synthetic opcodes.
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\section{Test suites}
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ARDI has a large set of test suites that try thousands upon thousands
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of variations of 680x0 opcodes and compare the results to those
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generated by a real 68040. These test suites have proven to be an
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invaluable debugging tool, both as new features are added and as
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we have ported syn68k to other architectures (notably 80x86, 680x0,
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i860 and Alpha). Our native code support is so recent that our
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test suites do not yet adequately test all of the situations that
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arise when generating native code, but we plan to extend them in
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the near future.
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\section{Interpreted code}
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Our interpreted code consists of contiguous sequences of ``synthetic
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opcodes'' and their operands. Syngen can generate ANSI C, but when
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compiled with gcc it uses C language extensions that make synthetic
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opcodes pointers to the C code responsible for interpreting that
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opcode. This ``threaded interpreting'' entirely eliminates switch
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dispatch and loop overhead.
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To illustrate the above points, here is the assembly language
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generated for the synthetic opcode that would handle a fully expanded
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``addl d0,d1'' when no CC bit values are required. This is what
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gcc's 80x86 output looks like (edited for readability) after we
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run our interpreter through ARDI's Pentium-specific instruction
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scheduling Perl script:
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\begin{verbatim}
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movl _d0,%eax ; fetch d0
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movl (%esi),%edi ; fetch next synthetic opcode
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addl %eax,_d1 ; do the add
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addl $4,%esi ; increment synthetic PC
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jmp *%edi ; jump to next synthetic opcode handler
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\end{verbatim}
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We must emphasize that the preceding example is not native code
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generated by our emulator, but merely a snippet of what gcc generates
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for our interpreter. This gives you some idea of the efficiency
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of the portable component of our emulator.
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\section{Native code}
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Syn68k supports optional architecture-specific native code extensions.
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On systems where they are present, the runtime system tries to
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generate native code whenever possible. In those rare cases when
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it cannot, it reverts to our interpreted code. Since syn68k supports
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both native and synthetic code, the runtime system automatically
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inserts gateways between the two whenever there is a transition.
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This approach allows us to gradually phase in native code handlers
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for most 680x0 instructions while leaving tricky and unimportant
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rare cases alone.
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Although our native code compilation engine is not architecture-specific,
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to date we have only implemented an 80x86 back end. The 80x86
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architecture has achieved such important status in the industry
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that it makes sense for us to describe how we generate native code
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for it, even though many of these techniques would not be necessary
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on RISC architectures.
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We are glad that we implemented the most difficult back end first.
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We believe that, were we to have started with a RISC back end, we
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would have quite possibly architected a system where retrofitting
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the exotic mechanisms necessary for efficient 80x86 support was
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difficult.
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Three major problems make translating 680x0 code to 80x86 code difficult:
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\begin{enumerate}
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\item The 80x86 has only 8 registers, while the 680x0 has 16.
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\item The 80x86 is little endian, while the 680x0 is big endian.
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\item The 80x86 does not have general-purpose postincrement and predecrement
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operators, which are used frequently in 680x0 code.
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\end{enumerate}
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On the other hand, several factors make the job easier:
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\begin{enumerate}
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\item The 80x86 has all of the CISC addressing modes commonly used in 680x0 code.
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\item The 80x86 has CC bits that map directly to their 680x0 counterparts
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(except for the 680x0's X bit).
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\item The 80x86 supports 8-, 16- and 32-bit operations, (although it can only
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support 8 bit operations on four of its registers).
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\item The 80x86 and 680x0 have analogous conditional branch instructions.
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\item The 80x86 allows unaligned memory accesses without substantial overhead.
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\end{enumerate}
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The toughest problem is the lack of registers. On 32-register RISC
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architectures it's easy to allocate one RISC register for each
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680x0 register, but on the 80x86 a different approach is needed.
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The obvious solution is to perform full-blown inter-block register
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allocation, but we fear that using traditional compiler techniques
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would be unacceptably slow.
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For now, we have adopted a simple constraint: between basic blocks,
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all registers and live CC bits must reside in their canonical home
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in memory. Within a block, anything goes. So what liberties does
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syn68k take within a block?
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The 80x86 register set is treated as a cache for recently used
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680x0 registers, and the 80x86 CC bits are used as a cache for the
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680x0 CC bits. At any particular point within a block, each 680x0
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register is either sitting in its memory home or is cached in an
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80x86 register, and each live 680x0 CC bit is either cached in its
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80x86 equivalent or stored in its memory home. Cached registers
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may be in canonical form, may be byte swapped, may have only their
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low two bytes swapped, or may be offset by a known constant from
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their actual value.
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Each 680x0 instruction can require that 680x0 registers be cached
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in particular ways; the compilation engine generates the minimal
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code needed to satisfy those constraints and then calls a sequence
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of routines to generate the native code. As each 680x0 instruction
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is processed, each 680x0 register's cache status is updated. Dirty
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registers are canonicalized and spilled back to memory at the end
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of each block (or when we run out of 80x86 registers and we need
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to make room).
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We allow 680x0 registers to be cached with varying byte orders and
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offsets so that we can perform the optimizations of lazy byte
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swapping and lazy constant offsetting. If the 680x0 program loads
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a register from memory and then ends up writing it out later, we
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avoid unnecessary byte swaps by not canonicalizing the value
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immediately. Lazy constant offsetting mitigates the overhead of
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postincrement and predecrement side effects. For example, this
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680x0 code:
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\begin{verbatim}
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pea 0x1
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pea 0x2
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pea 0x3
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pea 0x4
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...
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\end{verbatim}
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becomes this 80x86 code:
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\begin{verbatim}
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movl _a7,%edi
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movl $0x01000000,-4(%edi) ; "push" big-endian constant
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movl $0x02000000,-8(%edi)
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movl $0x03000000,-12(%edi)
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movl $0x04000000,-16(%edi)
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... <more uses of a7 may follow, and they'll use %edi>
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subl $16,%edi
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movl $edi,_a7
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...
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\end{verbatim}
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As mentioned above, we use the 80x86 condition code bits as a cache
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for the real 680x0 CC bits. Although live cached CC bits are
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occasionally spilled back to memory because some 80x86 instruction
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is about to clobber them, this trick almost always works. Using
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80x86 CC bits, we can frequently get away with extremely concise
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code sequences; for example, a 680x0 compare and conditional branch
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becomes an 80x86 compare and conditional branch.
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\section{Self-modifying code}
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Like most dynamically compiling emulators, syn68k doesn't detect
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self-modifying code; the overhead is too high. Fortunately,
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self-modifying programs don't work on the real 68040 either. We
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rely on the program making explicit system calls to flush the caches
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whenever 680x0 code may have been modified or created. Some programs
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(like HyperCard) flush the caches very often, which can cause real
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performance headaches if code is continuously recompiled. We have
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solved this problem by checksumming 680x0 blocks as they are compiled
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and only decompiling blocks which fail their checksums. This
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optimization alone sped up some HyperCard stacks by a factor of
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three or so.
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\section{Responsiveness}
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Responsiveness is a concern for any dynamic compiler. Fortunately,
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syn68k is largely driven by automatically generated lookup tables
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so compilation speed is good. Like other dynamic compilers, syn68k
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only bothers to compile 680x0 code when it encounters it for the
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first time.
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When syn68k encounters new code, it compiles other 680x0 code that
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it can reach from there but does not compile through jsr's. Only
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when a jsr is actually executed does syn68k compile the target
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routine. Once that target routine is compiled, syn68k modifies
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the jsr handler to point directly to the target routine so that
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the jsr will be extremely fast the second time it is executed.
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We've found that lazily compiling through jsr's does a good job of
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avoiding compilation lag that might annoy the user.
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Syn68k does not attempt to generate native code for a basic block
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until that block (or a nearby one) has been executed 50 times.
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This saves memory and some compilation time, although we haven't
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noticed any particular sluggishness when compiling to native code.
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\section{Other optimizations}
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Syn68k maintains an internal ``jsr stack'' to speed up the common
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case of jsr/rts. We realize that the rts address might have been
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fiddled with, so the rts handler verifies at runtime that the rts
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address matches the tag on top of the jsr stack. If it matches,
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syn68k does a fast jump. If it doesn't, syn68k looks up the code
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corresponding to the rts address in a hash table.
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\section{Neat hacks}
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The low-level code generation routines for the 80x86 back end are
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machine generated from assembly language templates. Thousands of
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operand permutations for 80x86 instructions of interest are run
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through the system's assembler and analyzed to derive the rules
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the assembler uses to create binaries. Those rules are encapsulated
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into C code and compiled into syn68k so we can generate binaries
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on the fly. Here is a sample template:
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\begin{verbatim}
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{ "i386_leal_indoff", "", "", "", "", "-",
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"leal %0(%1),%2",
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{ "offset", "base", "dst" },
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{ { SIZE_32, CONSTANT, IN }, { SIZE_32, REGISTER, IN },
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{ SIZE_32, REGISTER, OUT } } },
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\end{verbatim}
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This approach has saved us countless hours of debugging and allows
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our system to automatically perform the same optimizations as the
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host system's assembler.
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We've annotated our 80x86 descriptions with information about
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Pentium pairability so that future versions of syn68k can schedule
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the native code we generate (we already schedule our main interpreter
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when we build syn68k).
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\section{Future optimizations}
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We are working on a simple inter-block register allocation algorithm.
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By relocating most 680x0 register to 80x86 register moves to the
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beginning of each block, we can improve Pentium pairability and
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reduce 80486 and Pentium address generation pipeline stalls.
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Now that we compile to native code, A-line trap overhead is becoming
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significant. We may soon compile A-line traps to native code that
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directly calls the appropriate ROMlib routine with the appropriate
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arguments (checking at runtime to make sure that neither the trap
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nor the A-line vector has been patched out, of course).
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\section{Code examples}
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Here are two sample 680x0 code sequences from real applications,
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and the 80x86 code that syn68k generates for them. We chose these
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code sequences specifically to showcase several of the techniques
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we use, so you shouldn't use them as a substitute for benchmarks.
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Not all 680x0 code translates as well as these examples do, but
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these examples are far from exotic.
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\begin{itemize}
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\item Example 1 (Solarian):
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\begin{verbatim}
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680x0 code:
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addqb #1,a4@(1)
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movel #0,d0
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moveb a4@,d0
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swap d0
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clrw d0
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swap d0
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asll #2,d0
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lea a5@(-13462),a0
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addal d0,a0
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moveal a0@,a0
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movel #0,d0
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moveb a4@(1),d0
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cmpw a0@,d0
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bcs 0x3fffee2
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80x86 code:
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movl _a4,%edi ; addqb #1,a4@(1)
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addb $0x1,0x1(%edi)
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xorl %ebx,%ebx ; movel #0,d0
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movb (%edi),%bl ; moveb a4@,d0
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rorl $0x10,%ebx ; swap d0
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xorw %bx,%bx ; clrw d0
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rorl $0x10,%ebx ; swap d0
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shll $0x2,%ebx ; asll #2,d0
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movl _a5,%esi ; lea a5@(-13462),a0
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leal 0xffffcb6a(%esi),%edx
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addl %ebx,%edx ; addal d0,a0
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movl (%edx),%edx ; moveal a0@,a0
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xorl %ebx,%ebx ; movel #0,d0
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movb 0x1(%edi),%bl ; moveb a4@(1),d0
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bswap %edx ; cmpw a0@,d0
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movw (%edx),%cx
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rorw $0x8,%cx
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cmpw %cx,%bx
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movl %edx,_a0 ; <spill dirty 68k
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movl %ebx,_d0 ; registers back to memory>
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jb 0x6fae0c ; bcs 0x3fffee2
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jmp 0x6faf0c ; <go to "fall through" code>
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\end{verbatim}
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\item Example 2 (PageMaker):
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\begin{verbatim}
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680x0 code:
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movel #0,d2
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moveb d0,d2
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lslw #8,d0
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orw d0,d2
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movel d2,d0
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swap d2
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orl d2,d0
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movel a0,d2
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lsrb #1,d2
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bcc 0x3fffed4
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80x86 code:
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xorl %ebx,%ebx ; movel #0,d2
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movl _d0,%edx ; moveb d0,d2
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movb %dl,%bl
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shlw $0x8,%dx ; lslw #8,d0
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orw %dx,%bx ; orw d0,d2
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movl %ebx,%edx ; movel d2,d0
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rorl $0x10,%ebx ; swap d2
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orl %ebx,%edx ; orl d2,d0
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movl _a0,%ecx ; movel a0,d2
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movl %ecx,%ebx
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shrb %bl ; lsrb #1,d2
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movl %ebx,_d2 ; <spill dirty 68k
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movl %edx,_d0 ; registers back to memory>
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jae 0x3b734c ; bcc 0x3fffed4
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jmp 0x43d48c ; <go to "fall through" 68k code>
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\end{verbatim}
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\end{itemize}
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\section{Benchmarks}
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These performance numbers were computed with Speedometer 3.23.
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We've removed the floating point tests from the list since they do
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not measure syn68k's speed. Syn68k contains no special provisions
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for Speedometer's benchmarks and we believe that these numbers are
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indicative of syn68k's performance for many other CPU-intensive
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programs.
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\begin{center}
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\begin{tabular}{||l||c|c|c|c||} \hline \hline
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\em{\small{Test/CPU}} & \em{\small{Quadra 610}} & \em{\small{Pentium 90Mhz}}
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& \em{\small{486DX4 75Mhz}} & \em{\small{486DX/2 66Mhz}} \\ \hline \hline
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CPU & 16.018 & 28.833 & 15.727 & 13.840 \\ \hline
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Dhrystones & 19.586 & 21.886 & 12.084 & 9.424 \\ \hline
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Tower & 18.909 & 27.130 & 12.235 & 11.556 \\ \hline
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Quicksort & 17.759 & 27.105 & 15.606 & 13.919 \\ \hline
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Bubble sort & 18.409 & 31.154 & 19.286 & 16.875 \\ \hline
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Queens & 19.083 & 38.167 & 19.083 & 18.320 \\ \hline
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Puzzle & 22.083 & 44.167 & 23.661 & 21.032 \\ \hline
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Permutations & 21.019 & 28.564 & 11.604 & 12.242 \\ \hline
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Int. Matrix & 24.200 & 26.469 & 19.369 & 16.608 \\ \hline
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Sieve & 23.362 & 60.290 & 33.982 & 30.145 \\ \hline \hline
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Average & 20.490 & 33.881 & 18.582 & 16.680 \\ \hline
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\end{tabular}
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\end{center}
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Preliminary analysis suggests that we average a roughly 3:1
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instruction count increase when translating to 80x86 code. We have
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not yet taken rigorous measurements, but the 3:1 figure is lent
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some credence by the fact that our 75MHz 486DX4 gets nearly the
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same performance as our Quadra 610. We believe that inter-block
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register allocation will noticeably improve this ratio.
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\end{document}
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