retroforth/doc/book/techniques/assembly

# Working With Assembly Language

RETRO runs on a virtual machine called Nga. It provides a
standard assembler for this called *Muri*.

Muri is a simple, multipass model that's not fancy, but
suffices for RETRO's needs.

## Assembling A Standalone File

A small example (*test.muri*)

    ~~~
    i liju....
    r main
    : c:put
    i liiire..
    i 0
    : main
    i lilica..
    d 97
    i liju....
    r main
    ~~~

Assembling it:

    retro-muri test.muri

So breaking down: Muri extracts the assembly code blocks to
assemble, then proceeds to do the assembly. Each source line
starts with a directive, followed by a space, and then ending
with a value.

The directives are:

    :    value is a label
    i    value is an instruction bundle
    d    value is a numeric value
    r    value is a reference
    s    value is a string to inline

Instructions for Nga are provided as bundles. Each memory
location can store up to four instructions. And each instruction
gets a two character identifier.

From the list of instructions:

    0 nop   5 push  10 ret   15 fetch 20 div   25 zret
    1 lit   6 pop   11 eq    16 store 21 and   26 halt
    2 dup   7 jump  12 neq   17 add   22 or    27 ienum
    3 drop  8 call  13 lt    18 sub   23 xor   28 iquery
    4 swap  9 ccall 14 gt    19 mul   24 shift 29 iinvoke

This reduces to:

    0 ..    5 pu    10 re    15 fe    20 di    25 zr
    1 li    6 po    11 eq    16 st    21 an    26 ha
    2 du    7 ju    12 ne    17 ad    22 or    27 ie
    3 dr    8 ca    13 lt    18 su    23 xo    28 iq
    4 sw    9 cc    14 gt    19 mu    24 sh    29 ii

Most are just the first two letters of the instruction name. I
use `..` instead of `no` for `NOP`, and the first letter of
each I/O instruction name. So a bundle may look like:

    dumure..

(This would correspond to `dup multiply return nop`).

## Runtime Assembler

RETRO also has a runtime variation of Muri that can be used
when you need to generate more optimal code. So one can write:

    :n:square dup * ;

Or:

    :n:square \dumure.. ;

The second one will be faster, as the entire definition is one
bundle, which reduces memory reads and decoding by 2/3.

Doing this is less readable, so I only recommend doing so after
you have finalized working RETRO level code and determined the
best places to optimize.

The runtime assembler has the following directives:

    i    value is an instruction bundle
    d    value is a numeric value
    r    value is a reference

Additionally, in the runtime assembler, these are reversed:

    'dudumu.. i

Instead of:

    i dudumu..

The runtime assembler also provides three sigils for use in
inlining machine code into a definition. These are:

     \    Treat token as an assembly sequence
     `    Treat token as a numeric value
     ^    Treat token as a reference

E.g., instead of doing something like:

    :n:square as{ 'dumu.... i }as ;
    :test as{ 'lilica.... i #22 d 'n:square r }as ;

Just write:

    :n:square \dumu.... ;
    :test     \lilica.. `22 ^n:square ;
book: add assembler section FossilOrigin-Name: 036ee24ada0881db8a0022d0c664e8fd0cf36a62a64e96cecf34c3bd97557527 2019-03-18 17:52:03 +01:00			`# Working With Assembly Language`

			`RETRO runs on a virtual machine called Nga. It provides a`
			`standard assembler for this called Muri.`

			`Muri is a simple, multipass model that's not fancy, but`
			`suffices for RETRO's needs.`

			`## Assembling A Standalone File`

			`A small example (test.muri)`

			`~~~`
			`i liju....`
			`r main`
			`: c:put`
			`i liiire..`
			`i 0`
			`: main`
			`i lilica..`
			`d 97`
			`i liju....`
			`r main`
			`~~~`

			`Assembling it:`

			`retro-muri test.muri`

			`So breaking down: Muri extracts the assembly code blocks to`
			`assemble, then proceeds to do the assembly. Each source line`
			`starts with a directive, followed by a space, and then ending`
			`with a value.`

			`The directives are:`

			`: value is a label`
			`i value is an instruction bundle`
			`d value is a numeric value`
			`r value is a reference`
			`s value is a string to inline`

			`Instructions for Nga are provided as bundles. Each memory`
			`location can store up to four instructions. And each instruction`
			`gets a two character identifier.`

			`From the list of instructions:`

			`0 nop 5 push 10 ret 15 fetch 20 div 25 zret`
END -> HALT in Nga instruction naming FossilOrigin-Name: e3a4cbb9ac94f83d9e256cdaca70addde60626771ccb68b9f784ca4b355ee2ea 2019-12-10 19:51:56 +01:00			`1 lit 6 pop 11 eq 16 store 21 and 26 halt`
book: add assembler section FossilOrigin-Name: 036ee24ada0881db8a0022d0c664e8fd0cf36a62a64e96cecf34c3bd97557527 2019-03-18 17:52:03 +01:00			`2 dup 7 jump 12 neq 17 add 22 or 27 ienum`
			`3 drop 8 call 13 lt 18 sub 23 xor 28 iquery`
			`4 swap 9 ccall 14 gt 19 mul 24 shift 29 iinvoke`

			`This reduces to:`

			`0 .. 5 pu 10 re 15 fe 20 di 25 zr`
END -> HALT in Nga instruction naming FossilOrigin-Name: e3a4cbb9ac94f83d9e256cdaca70addde60626771ccb68b9f784ca4b355ee2ea 2019-12-10 19:51:56 +01:00			`1 li 6 po 11 eq 16 st 21 an 26 ha`
book: add assembler section FossilOrigin-Name: 036ee24ada0881db8a0022d0c664e8fd0cf36a62a64e96cecf34c3bd97557527 2019-03-18 17:52:03 +01:00			`2 du 7 ju 12 ne 17 ad 22 or 27 ie`
			`3 dr 8 ca 13 lt 18 su 23 xo 28 iq`
			`4 sw 9 cc 14 gt 19 mu 24 sh 29 ii`

			`Most are just the first two letters of the instruction name. I`
			use `..` instead of `no` for `NOP`, and the first letter of
			`each I/O instruction name. So a bundle may look like:`

			`dumure..`

			(This would correspond to `dup multiply return nop`).

			`## Runtime Assembler`

			`RETRO also has a runtime variation of Muri that can be used`
			`when you need to generate more optimal code. So one can write:`

			`:n:square dup * ;`

			`Or:`

update documentation FossilOrigin-Name: 61bec5c3ab74da3be2fa090a346b667bfa03cea534d8b378b9ac3245412bdc72 2020-01-07 15:09:08 +01:00			`:n:square \dumure.. ;`
book: add assembler section FossilOrigin-Name: 036ee24ada0881db8a0022d0c664e8fd0cf36a62a64e96cecf34c3bd97557527 2019-03-18 17:52:03 +01:00
			`The second one will be faster, as the entire definition is one`
			`bundle, which reduces memory reads and decoding by 2/3.`

			`Doing this is less readable, so I only recommend doing so after`
			`you have finalized working RETRO level code and determined the`
			`best places to optimize.`

			`The runtime assembler has the following directives:`

			`i value is an instruction bundle`
			`d value is a numeric value`
			`r value is a reference`

			`Additionally, in the runtime assembler, these are reversed:`

			`'dudumu.. i`

			`Instead of:`

			`i dudumu..`
docs: more details on assembly, numbers FossilOrigin-Name: 94245d967728aac960b4ce6a834a4e51d84238490d0be4c9e849751a385f6fb6 2020-01-08 14:39:12 +01:00
prefix: namespace is now sigil:, rename words, update examples, update docs FossilOrigin-Name: 25cf19660ab7728d7bfee2722ea826a8a438faf92b2504b28d922d2958906aed 2021-03-30 13:58:25 +02:00			`The runtime assembler also provides three sigils for use in`
docs: more details on assembly, numbers FossilOrigin-Name: 94245d967728aac960b4ce6a834a4e51d84238490d0be4c9e849751a385f6fb6 2020-01-08 14:39:12 +01:00			`inlining machine code into a definition. These are:`

			`\ Treat token as an assembly sequence`
			` Treat token as a numeric value
			`^ Treat token as a reference`

			`E.g., instead of doing something like:`

			`:n:square as{ 'dumu.... i }as ;`
			`:test as{ 'lilica.... i #22 d 'n:square r }as ;`

			`Just write:`

			`:n:square \dumu.... ;`
			:test \lilica.. `22 ^n:square ;