nxu/math32.tal

( math32.tal )
( )
( 32-bit integers are represented by two 16-bit integers )
( x** means xhi* xlo* )

%DEBUG { #ff #0e DEO }
%RTN  { JMP2r }
%EMIT { #18 DEO }
%DIGIT { #00 SWP ;digits ADD2 LDA EMIT }
%SPACE { #20 EMIT }
%NEWLINE { #0a EMIT }

%TOR2 { ROT2 ROT2 }
%POP4 { POP2 POP2 }

%X { #0000 #0001 }
%Y { #1234 #ffff }
%Z { #fedc #ba98 }

|0100
    #ffff #ffff ;mul16 JSR2 ;emit-long JSR2 NEWLINE
    #ffff #ffff #ffff #ffff ;mul32 JSR2 ;emit-long JSR2 NEWLINE

    X Y #2b ;add32 ;emit-long ;test JSR2
    Z Y #2b ;add32 ;emit-long ;test JSR2
    #fedc #0000 #1234 #0000 #2b ;add32 ;emit-long ;test JSR2
    #fedc #0000 #0000 #0000 #2b ;add32 ;emit-long ;test JSR2
    #0000 #0000 #0000 #0000 #2b ;add32 ;emit-long ;test JSR2
    X Y #26 ;and32 ;emit-long ;test JSR2
    X Y #7c ;or32 ;emit-long ;test JSR2
    X Y #5e ;xor32 ;emit-long ;test JSR2
    X Y #3d ;eq32 ;emit-byte ;test JSR2
    Y Y #3d ;eq32 ;emit-byte ;test JSR2
    X Y #7e ;ne32 ;emit-byte ;test JSR2
    X X #7e ;ne32 ;emit-byte ;test JSR2
BRK

@test ( x** y** symbol^ test-addr* emit-addr* -> )
    ,&emitaddr STR2
    ,&testaddr STR2
    ,&testsym STR
    ,&ylo STR2 ,&yhi STR2
    ,&xlo STR2 ,&xhi STR2
    ,&xhi LDR2 ,&xlo LDR2 ;emit-long JSR2
    SPACE ,&testsym LDR EMIT SPACE
    ,&yhi LDR2 ,&ylo LDR2 ;emit-long JSR2
    SPACE #3d EMIT SPACE
    ,&xhi LDR2 ,&xlo LDR2
    ,&yhi LDR2 ,&ylo LDR2
    ,&testaddr LDR2 JSR2
    ,&emitaddr LDR2 JSR2 NEWLINE
RTN
&testsym $1
&testaddr $2
&emitaddr $2
&xhi $2 &xlo $2
&yhi $2 &ylo $2


@eq32 ( xhi* xlo* yhi* ylo* -> bool^ )
    ROT2 EQU2 ,&maybe JCN
    POP4 #00 RTN
    &maybe EQU2
RTN

@ne32 ( xhi* xlo* yhi* ylo* -> bool^ )
    ROT2 EQU2 ,&maybe JCN
    POP4 #01 RTN
    &maybe NEQ2
RTN

@and32 ( xhi* xlo* yhi* ylo* -> xhi|yhi* xlo|ylo* )
    ROT2 AND2 TOR2 AND2 SWP2
RTN

@or32 ( xhi* xlo* yhi* ylo* -> xhi|yhi* xlo|ylo* )
    ROT2 ORA2 TOR2 ORA2 SWP2
RTN

@xor32 ( xhi* xlo* yhi* ylo* -> xhi|yhi* xlo|ylo* )
    ROT2 EOR2 TOR2 EOR2 SWP2
RTN

@left-by-8 ( x** -> x<<8** )
    SWP2 ( x2 x3 x0 x1 )
    SWP POP ( x2 x3 x1 )
    ROT ROT #00 ( x1 x2 x3 00 )
RTN

@left-by-16 ( x** -> x<<16** )
    SWP2 ( x2 x3 x0 x1 )
    POP2 #0000 ( x2 x3 0000 )
RTN

@left-by-24 ( x** -> x<<24** )
    SWP2 POP2 ( x2 x3 )
    SWP POP #00 #0000 ( x3 00 0000 )
RTN

@add32 ( xhi* xlo* yhi* ylo* -> zhi* zlo* )
    ,&y2 STR2 ,&y0 STR2 ( save ylo, yhi )
    ,&x2 STR2 ,&x0 STR2 ( save xlo, xhi )
    #0000 #0000 ,&z0 STR2 ,&z2 STR2 ( reset zhi, zlo )

    ( x3 + y3 => z2z3 )
    #00 ,&x3 LDR #00 ,&y3 LDR ADD2 ,&z2 STR2

    ( x2 + y2 + z2 => z1z2 )
    #00 ,&x2 LDR ,&z1 LDR2 ADD2 ,&z1 STR2
    #00 ,&y2 LDR ,&z1 LDR2 ADD2 ,&z1 STR2

    ( x1 + y1 + z1 => z0z1 )
    #00 ,&x1 LDR ,&z0 LDR2 ADD2 ,&z0 STR2
    #00 ,&y1 LDR ,&z0 LDR2 ADD2 ,&z0 STR2

    ( x0 + y0 + z0 => z0 )
    ,&x0 LDR ,&z0 LDR ADD ,&z0 STR
    ,&y0 LDR ,&z0 LDR ADD ,&z0 STR

    ( load zhi,zlo )
    ,&z0 LDR2 ,&z2 LDR2
RTN

( registers for add32 )
[ &x0 $1 &x1 $1 &x2 $1 &x3 $1 ]
[ &y0 $1 &y1 $1 &y2 $1 &y3 $1 ]
[ &z0 $1 &z1 $1 &z2 $2 ]

@mul16 ( x* y* -> z** )
    ,&y1 STR ,&y0 STR ( save ylo, yhi )
    ,&x1 STR ,&x0 STR ( save xlo, xhi )
    #0000 #00 ,&z0 STR2 ,&z2 STR ( reset z0,z1,z2 )
    #0000 #00 ,&a0 STR2 ,&a2 STR ( reset a0,a1,a2 )

    ( x1 * y1 => z1z2 )
    #00 ,&x1 LDR #00 ,&y1 LDR MUL2 ,&z1 STR2

    ( x0 * y1 => z0z1 )
    #00 ,&x0 LDR #00 ,&y1 LDR MUL2 ,&z0 LDR2 ADD2 ,&z0 STR2

    ( x1 * y0 => a1a2 )
    #00 ,&x1 LDR #00 ,&y0 LDR MUL2 ,&a1 STR2

    ( x0 * y0 => a0a1 )
    #00 ,&x0 LDR #00 ,&y0 LDR MUL2 ,&a0 LDR2 ADD2 ,&a0 STR2

    ( load z and a )
    #00 ,&z0 LDR2 ,&z2 LDR
    ,&a0 LDR2 ,&z2 LDR #00
    ;add32 JSR2
RTN
[ &x0 $1 &x1 $1 ]
[ &y0 $1 &y1 $1 ]
[ &z0 $1 &z1 $1 &z2 $2 ]
[ &a0 $1 &a1 $1 &a2 $2 ]

@mul32 ( x** y** -> z** )
    ,&y1 STR2 ,&y0 STR2 ( save ylo, yhi )
    ,&x1 STR2 ,&x0 STR2 ( save xlo, xhi )
    ,&y1 LDR2 ,&x1 LDR2 ;mul16 JSR2 ( sum = [x1*y1] )
    ,&y1 LDR2 ,&x0 LDR2 ;mul16 JSR2 ;left-by-16 JSR2 ;add32 JSR2 ( sum += [x0*y1]<<16 )
    ,&y0 LDR2 ,&x1 LDR2 ;mul16 JSR2 ;left-by-16 JSR2 ;add32 JSR2 ( sum += [x1*y0]<<16 )
    ( [x0*y0]<<32 will completely overflow )
RTN
[ &x0 $2 &x1 $2 ]
[ &y0 $2 &y1 $2 ]

@emit-long ( hi* lo* -> )
    SWP2
    ;emit-short JSR2
    ;emit-short JSR2
RTN

@emit-short ( x* -> )
    SWP ( lo^ hi^ )
    DUP #04 SFT DIGIT ( emit hi>>4 )
    #0f AND DIGIT ( emit hi&f )
    DUP #04 SFT DIGIT ( emit lo>>4 )
    #0f AND DIGIT ( emit lo&f )
RTN

@emit-byte ( x^ -> )
    DUP #04 SFT DIGIT ( emit hi>>4 )
    #0f AND DIGIT ( emit hi&f )
RTN

@digits
    30 31 32 33 34 35 36 37
    38 39 61 62 63 64 65 66
start on 32-bit math 2021-12-23 00:43:10 -05:00			`( math32.tal )`
			`( )`
			`( 32-bit integers are represented by two 16-bit integers )`
			`( x** means xhi* xlo* )`

			`%DEBUG { #ff #0e DEO }`
			`%RTN { JMP2r }`
			`%EMIT { #18 DEO }`
			`%DIGIT { #00 SWP ;digits ADD2 LDA EMIT }`
			`%SPACE { #20 EMIT }`
			`%NEWLINE { #0a EMIT }`

			`%TOR2 { ROT2 ROT2 }`
			`%POP4 { POP2 POP2 }`

			`%X { #0000 #0001 }`
			`%Y { #1234 #ffff }`
			`%Z { #fedc #ba98 }`

			`\|0100`
			`#ffff #ffff ;mul16 JSR2 ;emit-long JSR2 NEWLINE`
			`#ffff #ffff #ffff #ffff ;mul32 JSR2 ;emit-long JSR2 NEWLINE`

			`X Y #2b ;add32 ;emit-long ;test JSR2`
			`Z Y #2b ;add32 ;emit-long ;test JSR2`
			`#fedc #0000 #1234 #0000 #2b ;add32 ;emit-long ;test JSR2`
			`#fedc #0000 #0000 #0000 #2b ;add32 ;emit-long ;test JSR2`
			`#0000 #0000 #0000 #0000 #2b ;add32 ;emit-long ;test JSR2`
			`X Y #26 ;and32 ;emit-long ;test JSR2`
			`X Y #7c ;or32 ;emit-long ;test JSR2`
			`X Y #5e ;xor32 ;emit-long ;test JSR2`
			`X Y #3d ;eq32 ;emit-byte ;test JSR2`
			`Y Y #3d ;eq32 ;emit-byte ;test JSR2`
			`X Y #7e ;ne32 ;emit-byte ;test JSR2`
			`X X #7e ;ne32 ;emit-byte ;test JSR2`
			`BRK`

			`@test ( x y symbol^ test-addr* emit-addr* -> )`
			`,&emitaddr STR2`
			`,&testaddr STR2`
			`,&testsym STR`
			`,&ylo STR2 ,&yhi STR2`
			`,&xlo STR2 ,&xhi STR2`
			`,&xhi LDR2 ,&xlo LDR2 ;emit-long JSR2`
			`SPACE ,&testsym LDR EMIT SPACE`
			`,&yhi LDR2 ,&ylo LDR2 ;emit-long JSR2`
			`SPACE #3d EMIT SPACE`
			`,&xhi LDR2 ,&xlo LDR2`
			`,&yhi LDR2 ,&ylo LDR2`
			`,&testaddr LDR2 JSR2`
			`,&emitaddr LDR2 JSR2 NEWLINE`
			`RTN`
			`&testsym $1`
			`&testaddr $2`
			`&emitaddr $2`
			`&xhi $2 &xlo $2`
			`&yhi $2 &ylo $2`


			`@eq32 ( xhi* xlo* yhi* ylo* -> bool^ )`
			`ROT2 EQU2 ,&maybe JCN`
			`POP4 #00 RTN`
			`&maybe EQU2`
			`RTN`

			`@ne32 ( xhi* xlo* yhi* ylo* -> bool^ )`
			`ROT2 EQU2 ,&maybe JCN`
			`POP4 #01 RTN`
			`&maybe NEQ2`
			`RTN`

			`@and32 ( xhi* xlo* yhi* ylo* -> xhi\|yhi* xlo\|ylo* )`
			`ROT2 AND2 TOR2 AND2 SWP2`
			`RTN`

			`@or32 ( xhi* xlo* yhi* ylo* -> xhi\|yhi* xlo\|ylo* )`
			`ROT2 ORA2 TOR2 ORA2 SWP2`
			`RTN`

			`@xor32 ( xhi* xlo* yhi* ylo* -> xhi\|yhi* xlo\|ylo* )`
			`ROT2 EOR2 TOR2 EOR2 SWP2`
			`RTN`

			`@left-by-8 ( x -> x<<8 )`
			`SWP2 ( x2 x3 x0 x1 )`
			`SWP POP ( x2 x3 x1 )`
			`ROT ROT #00 ( x1 x2 x3 00 )`
			`RTN`

			`@left-by-16 ( x -> x<<16 )`
			`SWP2 ( x2 x3 x0 x1 )`
			`POP2 #0000 ( x2 x3 0000 )`
			`RTN`

			`@left-by-24 ( x -> x<<24 )`
			`SWP2 POP2 ( x2 x3 )`
			`SWP POP #00 #0000 ( x3 00 0000 )`
			`RTN`

			`@add32 ( xhi* xlo* yhi* ylo* -> zhi* zlo* )`
			`,&y2 STR2 ,&y0 STR2 ( save ylo, yhi )`
			`,&x2 STR2 ,&x0 STR2 ( save xlo, xhi )`
			`#0000 #0000 ,&z0 STR2 ,&z2 STR2 ( reset zhi, zlo )`

			`( x3 + y3 => z2z3 )`
			`#00 ,&x3 LDR #00 ,&y3 LDR ADD2 ,&z2 STR2`

			`( x2 + y2 + z2 => z1z2 )`
			`#00 ,&x2 LDR ,&z1 LDR2 ADD2 ,&z1 STR2`
			`#00 ,&y2 LDR ,&z1 LDR2 ADD2 ,&z1 STR2`

			`( x1 + y1 + z1 => z0z1 )`
			`#00 ,&x1 LDR ,&z0 LDR2 ADD2 ,&z0 STR2`
			`#00 ,&y1 LDR ,&z0 LDR2 ADD2 ,&z0 STR2`

			`( x0 + y0 + z0 => z0 )`
			`,&x0 LDR ,&z0 LDR ADD ,&z0 STR`
			`,&y0 LDR ,&z0 LDR ADD ,&z0 STR`

			`( load zhi,zlo )`
			`,&z0 LDR2 ,&z2 LDR2`
			`RTN`

			`( registers for add32 )`
			`[ &x0 $1 &x1 $1 &x2 $1 &x3 $1 ]`
			`[ &y0 $1 &y1 $1 &y2 $1 &y3 $1 ]`
			`[ &z0 $1 &z1 $1 &z2 $2 ]`

			`@mul16 ( x* y* -> z** )`
			`,&y1 STR ,&y0 STR ( save ylo, yhi )`
			`,&x1 STR ,&x0 STR ( save xlo, xhi )`
			`#0000 #00 ,&z0 STR2 ,&z2 STR ( reset z0,z1,z2 )`
			`#0000 #00 ,&a0 STR2 ,&a2 STR ( reset a0,a1,a2 )`

			`( x1 * y1 => z1z2 )`
			`#00 ,&x1 LDR #00 ,&y1 LDR MUL2 ,&z1 STR2`

			`( x0 * y1 => z0z1 )`
			`#00 ,&x0 LDR #00 ,&y1 LDR MUL2 ,&z0 LDR2 ADD2 ,&z0 STR2`

			`( x1 * y0 => a1a2 )`
			`#00 ,&x1 LDR #00 ,&y0 LDR MUL2 ,&a1 STR2`

			`( x0 * y0 => a0a1 )`
			`#00 ,&x0 LDR #00 ,&y0 LDR MUL2 ,&a0 LDR2 ADD2 ,&a0 STR2`

			`( load z and a )`
			`#00 ,&z0 LDR2 ,&z2 LDR`
			`,&a0 LDR2 ,&z2 LDR #00`
			`;add32 JSR2`
			`RTN`
			`[ &x0 $1 &x1 $1 ]`
			`[ &y0 $1 &y1 $1 ]`
			`[ &z0 $1 &z1 $1 &z2 $2 ]`
			`[ &a0 $1 &a1 $1 &a2 $2 ]`

			`@mul32 ( x y -> z** )`
			`,&y1 STR2 ,&y0 STR2 ( save ylo, yhi )`
			`,&x1 STR2 ,&x0 STR2 ( save xlo, xhi )`
			`,&y1 LDR2 ,&x1 LDR2 ;mul16 JSR2 ( sum = [x1*y1] )`
			`,&y1 LDR2 ,&x0 LDR2 ;mul16 JSR2 ;left-by-16 JSR2 ;add32 JSR2 ( sum += [x0*y1]<<16 )`
			`,&y0 LDR2 ,&x1 LDR2 ;mul16 JSR2 ;left-by-16 JSR2 ;add32 JSR2 ( sum += [x1*y0]<<16 )`
			`( [x0*y0]<<32 will completely overflow )`
			`RTN`
			`[ &x0 $2 &x1 $2 ]`
			`[ &y0 $2 &y1 $2 ]`

			`@emit-long ( hi* lo* -> )`
			`SWP2`
			`;emit-short JSR2`
			`;emit-short JSR2`
			`RTN`

			`@emit-short ( x* -> )`
			`SWP ( lo^ hi^ )`
			`DUP #04 SFT DIGIT ( emit hi>>4 )`
			`#0f AND DIGIT ( emit hi&f )`
			`DUP #04 SFT DIGIT ( emit lo>>4 )`
			`#0f AND DIGIT ( emit lo&f )`
			`RTN`

			`@emit-byte ( x^ -> )`
			`DUP #04 SFT DIGIT ( emit hi>>4 )`
			`#0f AND DIGIT ( emit hi&f )`
			`RTN`

			`@digits`
			`30 31 32 33 34 35 36 37`
			`38 39 61 62 63 64 65 66`