Brainf*ck to 8085 Assembler compiler written in Red

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Note:

It's originally based on: https://gist.github.com/dockimbel/7713170

Examples:

5 * 10 in BF (Constant multiplication is optimised by the compiler)

bf/comment-start {+++++[->++++++++++<]} " ;"

yields

MVI D,10 ; Data starting at 0A00h
ADI 50 ; 5 * 10
STAX D ; Save to memory before exiting
HLT ; Exit

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5 - 3 in BF (Substraction is not yet optimised)

bf/comment-start {+++++>+++[-<->]} " ;"

yields

MVI D,10 ; Data starting at 0A00h
ADI 5 ; + 5
STAX D ; >
INX D
LDAX D
ADI 3 ; + 3
label1: NOP ; [
        DCR A ; - 1
        STAX D ; <
        DCX D
        LDAX D
        DCR A ; - 1
        STAX D ; >
        INX D
        LDAX D
        CPI 0
JNZ label1 ; ]
STAX D ; Save to memory before exiting
HLT ; Exit

Compatibility:

Many 8085 emulators / assemblers have different comment line starts, you can choose the one you need by using the /comment-start refinement or you disable all comments by using the /no-comments refinement. Default comment is a # without a preceeding space. To compile a snippet for GNUSim8085 for example, you have to use ; without a preceeding space as the comment, as follows:

bf/comment-start {... code goes here ...} ";"

On the other hand, the online interpreter sim8085 allows you to include a preceeding space, to enchant readability.

Furthermore, some emulators / assemblers interpret a number followed by a h as a label, so only decimal addresses and numbers are used here.

I / O:

Port 1, and currently only Port 1 is used as the Input / Output of the program (, and . in BF). The compiled program does not wait until input "is available". This behaiviour may improve in the future, but feel free to submit a PR if you want it earlier :P.

How it works:

The compiler matches the BF code against a set of rules, and generates the mnemonics (You didn't expect this, did you? :P). On program execution, changes are always first performed on registers and then written to RAM on pointer move (> and <).

• Register A contains the value of the current cell.
• Register D and E contain the 16 Bit address of the current cell. It's set to 0A00 Hex (1000 decimal) on program start.

Optimisations:

The BF program is compiled to assembly applying some basic, naive optimisations:

• A multiplication of two constants is replaced with an ADI instruction
• [-], used for zeroing a cell, is replaced with a XOR of the register with itself (XRA A)
• Pointer moves below 5 get compiled to single increments of the pointer, whetever pointer moves above and including 5 get compiled to an ADD to safe cycles. This is done because the pointer is stored as a 16 Bit address, and an 16 Bit addition is in our case as expensive as 5 increments. E.g.:

+++ ->
    ...
    INX D 
    INX D
    INX D
    ...
++++++ ->
    ...
    ADI D,6
    ...

• Similiar to that above, single increments of a cell get compiled to an INR, but starting from 2 increments an addition is performed (ADI)