mu/mu_instructions

## Mu's instructions and their table-driven translation

See http://akkartik.name/akkartik-convivial-20200315.pdf for the complete
story. In brief: Mu is a statement-oriented language. Blocks consist of flat
lists of instructions. Instructions can have inputs after the operation, and
outputs to the left of a '<-'. Inputs and outputs must be variables. They can't
include nested expressions. Variables can be literals ('n'), or live in a
register ('var/reg') or in memory ('var') at some 'stack-offset' from the 'ebp'
register. Outputs must be registers. To modify a variable in memory, pass it in
by reference as an input. (Inputs are more precisely called 'inouts'.)
Conversely, registers that are just read from must not be passed as inputs.

The following chart shows all the instruction forms supported by Mu, along with
the SubX instruction they're translated to.

var/eax <- increment              => "40/increment-eax"
var/ecx <- increment              => "41/increment-ecx"
var/edx <- increment              => "42/increment-edx"
var/ebx <- increment              => "43/increment-ebx"
var/esi <- increment              => "46/increment-esi"
var/edi <- increment              => "47/increment-edi"
increment var                     => "ff 0/subop/increment *(ebp+" var.stack-offset ")"
increment *var/reg                => "ff 0/subop/increment *" reg

var/eax <- decrement              => "48/decrement-eax"
var/ecx <- decrement              => "49/decrement-ecx"
var/edx <- decrement              => "4a/decrement-edx"
var/ebx <- decrement              => "4b/decrement-ebx"
var/esi <- decrement              => "4e/decrement-esi"
var/edi <- decrement              => "4f/decrement-edi"
decrement var                     => "ff 1/subop/decrement *(ebp+" var.stack-offset ")"
decrement *var/reg                => "ff 1/subop/decrement *" reg

var/reg <- add var2/reg2          => "01/add-to %" reg " " reg2 "/r32"
var/reg <- add var2               => "03/add *(ebp+" var2.stack-offset ") " reg "/r32"
var/reg <- add *var2/reg2         => "03/add *" reg2 " " reg "/r32"
add-to var1, var2/reg             => "01/add-to *(ebp+" var1.stack-offset ") " reg "/r32"
var/eax <- add n                  => "05/add-to-eax " n "/imm32"
var/reg <- add n                  => "81 0/subop/add %" reg " " n "/imm32"
add-to var, n                     => "81 0/subop/add *(ebp+" var.stack-offset ") " n "/imm32"
add-to *var/reg, n                => "81 0/subop/add *" reg " " n "/imm32"

var/reg <- subtract var2/reg2     => "29/subtract-from %" reg " " reg2 "/r32"
var/reg <- subtract var2          => "2b/subtract *(ebp+" var2.stack-offset ") " reg "/r32"
var/reg <- subtract *var2/reg2    => "2b/subtract *" reg2 " " reg1 "/r32"
subtract-from var1, var2/reg2     => "29/subtract-from *(ebp+" var1.stack-offset ") " reg2 "/r32"
var/eax <- subtract n             => "2d/subtract-from-eax " n "/imm32"
var/reg <- subtract n             => "81 5/subop/subtract %" reg " " n "/imm32"
subtract-from var, n              => "81 5/subop/subtract *(ebp+" var.stack-offset ") " n "/imm32"
subtract-from *var/reg, n         => "81 5/subop/subtract *" reg " " n "/imm32"

var/reg <- and var2/reg2          => "21/and-with %" reg " " reg2 "/r32"
var/reg <- and var2               => "23/and *(ebp+" var2.stack-offset " " reg "/r32"
var/reg <- and *var2/reg2         => "23/and *" reg2 " " reg "/r32"
and-with var1, var2/reg           => "21/and-with *(ebp+" var1.stack-offset ") " reg "/r32"
var/eax <- and n                  => "25/and-with-eax " n "/imm32"
var/reg <- and n                  => "81 4/subop/and %" reg " " n "/imm32"
and-with var, n                   => "81 4/subop/and *(ebp+" var.stack-offset ") " n "/imm32"
and-with *var/reg, n              => "81 4/subop/and *" reg " " n "/imm32"

var/reg <- or var2/reg2           => "09/or-with %" reg " " reg2 "/r32"
var/reg <- or var2                => "0b/or *(ebp+" var2.stack-offset ") " reg "/r32"
var/reg <- or *var2/reg2          => "0b/or *" reg2 " " reg "/r32"
or-with var1, var2/reg2           => "09/or-with *(ebp+" var1.stack-offset " " reg2 "/r32"
var/eax <- or n                   => "0d/or-with-eax " n "/imm32"
var/reg <- or n                   => "81 1/subop/or %" reg " " n "/imm32"
or-with var, n                    => "81 1/subop/or *(ebp+" var.stack-offset ") " n "/imm32"
or-with *var/reg, n               => "81 1/subop/or *" reg " " n "/imm32"

var/reg <- xor var2/reg2          => "31/xor-with %" reg " " reg2 "/r32"
var/reg <- xor var2               => "33/xor *(ebp+" var2.stack-offset ") " reg "/r32"
var/reg <- xor *var2/reg2         => "33/xor *" reg2 " " reg "/r32"
xor-with var1, var2/reg           => "31/xor-with *(ebp+" var1.stack-offset ") " reg "/r32"
var/eax <- xor n                  => "35/xor-with-eax " n "/imm32"
var/reg <- xor n                  => "81 6/subop/xor %" reg " " n "/imm32"
xor-with var, n                   => "81 6/subop/xor *(ebp+" var.stack-offset ") " n "/imm32"
xor-with *var/reg, n              => "81 6/subop/xor *" reg " " n "/imm32"

var/eax <- copy n                 => "b8/copy-to-eax " n "/imm32"
var/ecx <- copy n                 => "b9/copy-to-ecx " n "/imm32"
var/edx <- copy n                 => "ba/copy-to-edx " n "/imm32"
var/ebx <- copy n                 => "bb/copy-to-ebx " n "/imm32"
var/esi <- copy n                 => "be/copy-to-esi " n "/imm32"
var/edi <- copy n                 => "bf/copy-to-edi " n "/imm32"
var/reg <- copy var2/reg2         => "89/<- %" reg " " reg2 "/r32"
copy-to var1, var2/reg            => "89/<- *(ebp+" var1.stack-offset ") " reg "/r32"
var/reg <- copy var2              => "8b/-> *(ebp+" var2.stack-offset ") " reg "/r32"
var/reg <- copy *var2/reg2        => "8b/-> *" reg2 " " reg "/r32"
var/reg <- copy n                 => "c7 0/subop/copy %" reg " " n "/imm32"
copy-to var, n                    => "c7 0/subop/copy *(ebp+" var.stack-offset ") " n "/imm32"
copy-to *var/reg, n               => "c7 0/subop/copy *" reg " " n "/imm32"

compare var1, var2/reg2           => "39/compare *(ebp+" var1.stack-offset ") " reg2 "/r32"
compare *var1/reg1, var2/reg2     => "39/compare *" reg1 " " reg2 "/r32"
compare var1/reg1, var2           => "3b/compare<- *(ebp+" var2.stack-offset ") " reg1 "/r32"
compare var/reg, *var2/reg2       => "3b/compare<- *" reg " " n "/imm32"
compare var/eax, n                => "3d/compare-eax-with " n "/imm32"
compare var, n                    => "81 7/subop/compare *(ebp+" var.stack-offset ") " n "/imm32"
compare *var/reg, n               => "81 7/subop/compare *" reg " " n "/imm32"

var/reg <- multiply var2          => "0f af/multiply *(ebp+" var2.stack-offset ") " reg "/r32"
var/reg <- multiply *var2/reg2    => "0f af/multiply *" reg2 " " reg "/r32"

break                             => "e9/jump break/disp32"
break label                       => "e9/jump " label ":break/disp32"
loop                              => "e9/jump loop/disp32"
loop label                        => "e9/jump " label ":loop/disp32"

break-if-=                        => "0f 84/jump-if-= break/disp32"
break-if-= label                  => "0f 84/jump-if-= " label ":break/disp32"
loop-if-=                         => "0f 84/jump-if-= loop/disp32"
loop-if-= label                   => "0f 84/jump-if-= " label ":loop/disp32"

break-if-!=                       => "0f 85/jump-if-!= break/disp32"
break-if-!= label                 => "0f 85/jump-if-!= " label ":break/disp32"
loop-if-!=                        => "0f 85/jump-if-!= loop/disp32"
loop-if-!= label                  => "0f 85/jump-if-!= " label ":loop/disp32"

break-if-<                        => "0f 8c/jump-if-< break/disp32"
break-if-< label                  => "0f 8c/jump-if-< " label ":break/disp32"
loop-if-<                         => "0f 8c/jump-if-< loop/disp32"
loop-if-< label                   => "0f 8c/jump-if-< " label ":loop/disp32"

break-if->                        => "0f 8f/jump-if-> break/disp32"
break-if-> label                  => "0f 8f/jump-if-> " label ":break/disp32"
loop-if->                         => "0f 8f/jump-if-> loop/disp32"
loop-if-> label                   => "0f 8f/jump-if-> " label ":loop/disp32"

break-if-<=                       => "0f 8e/jump-if-<= break/disp32"
break-if-<= label                 => "0f 8e/jump-if-<= " label ":break/disp32"
loop-if-<=                        => "0f 8e/jump-if-<= loop/disp32"
loop-if-<= label                  => "0f 8e/jump-if-<= " label ":loop/disp32"

break-if->=                       => "0f 8d/jump-if->= break/disp32"
break-if->= label                 => "0f 8d/jump-if->= " label ":break/disp32"
loop-if->=                        => "0f 8d/jump-if->= loop/disp32"
loop-if->= label                  => "0f 8d/jump-if->= " label ":loop/disp32"

break-if-addr<                    => "0f 82/jump-if-addr< break/disp32"
break-if-addr< label              => "0f 82/jump-if-addr< " label ":break/disp32"
loop-if-addr<                     => "0f 82/jump-if-addr< loop/disp32"
loop-if-addr< label               => "0f 82/jump-if-addr< " label ":loop/disp32"

break-if-addr>                    => "0f 87/jump-if-addr> break/disp32"
break-if-addr> label              => "0f 87/jump-if-addr> " label ":break/disp32"
loop-if-addr>                     => "0f 87/jump-if-addr> loop/disp32"
loop-if-addr> label               => "0f 87/jump-if-addr> " label ":loop/disp32"

break-if-addr<=                   => "0f 86/jump-if-addr<= break/disp32"
break-if-addr<= label             => "0f 86/jump-if-addr<= " label ":break/disp32"
loop-if-addr<=                    => "0f 86/jump-if-addr<= loop/disp32"
loop-if-addr<= label              => "0f 86/jump-if-addr<= " label ":loop/disp32"

break-if-addr>=                   => "0f 83/jump-if-addr>= break/disp32"
break-if-addr>= label             => "0f 83/jump-if-addr>= " label ":break/disp32"
loop-if-addr>=                    => "0f 83/jump-if-addr>= loop/disp32"
loop-if-addr>= label              => "0f 83/jump-if-addr>= " label ":loop/disp32"

In the following instructions types are provided for clarity even if they must
be provided in an earlier 'var' declaration.

# Address operations

var/reg: (addr T) <- address var2: T
  => "8d/copy-address *(ebp+" var2.stack-offset ") " reg "/r32"

Array operations (TODO: bounds-checking)

var/reg <- index arr/rega: (addr array T), idx/regi: int
  | if size-of(T) is 4 or 8
      => "8d/copy-address *(" rega "+" regi "<<" log2(size-of(T)) "+4) " reg "/r32"
var/reg <- index arr: (array T sz), idx/regi: int
  => "8d/copy-address *(ebp+" regi "<<" log2(size-of(T)) "+" (arr.stack-offset + 4) ") " reg "/r32"
var/reg <- index arr/rega: (addr array T), n
  => "8d/copy-address *(" rega "+" (n*size-of(T)+4) ") " reg "/r32"
var/reg <- index arr: (array T sz), n
  => "8d/copy-address *(ebp+" (arr.stack-offset+4+n*size-of(T)) ") " reg "/r32"

var/reg: (offset T) <- compute-offset arr: (addr array T), idx/regi: int  # arr can be in reg or mem
  => "69/multiply %" regi " " size-of(T) "/imm32 " reg "/r32"
var/reg: (offset T) <- compute-offset arr: (addr array T), idx: int       # arr can be in reg or mem
  => "69/multiply *(ebp+" idx.stack-offset ") " size-of(T) "/imm32 " reg "/r32"
var/reg <- index arr/rega: (addr array T), o/rego: offset
  => "8d/copy-address *(" rega "+" rego "+4) " reg "/r32"

Computing the length of an array is complex.

var/reg <- length arr/reg2: (addr array T)
  | if T is byte (TODO)
      => "8b/-> *" reg2 " " reg "/r32"
  | if size-of(T) is 4 or 8 or 16 or 32 or 64 or 128
      => "8b/-> *" reg2 " " reg "/r32"
         "c1/shift 5/subop/logic-right %" reg " " log2(size-of(T)) "/imm8"
  | otherwise (TODO)
      x86 has no instruction to divide by a literal, so
      we need up to 3 extra registers! eax/edx for division and say ecx
      => if reg is not eax
          "50/push-eax"
         if reg is not ecx
          "51/push-ecx"
         if reg is not edx
          "52/push-edx"
         "8b/-> *" reg2 " eax/r32"
         "31/xor %edx 2/r32/edx"  # sign-extend, but array size can't be negative
         "b9/copy-to-ecx " size-of(T) "/imm32"
         "f7 7/subop/idiv-eax-edx-by %ecx"
         if reg is not eax
           "89/<- %" reg " 0/r32/eax"
         if reg is not edx
          "5a/pop-to-edx"
         if reg is not ecx
          "59/pop-to-ecx"
         if reg is not eax
          "58/pop-to-eax"

# User-defined types

If a record (product) type T was defined to have elements a, b, c, ... of
types T_a, T_b, T_c, ..., then accessing one of those elements f of type T_f:

var/reg: (addr T_f) <- get var2/reg2: (addr F), f
  => "8d/copy-address *(" reg2 "+" offset(f) ") " reg "/r32"
var/reg: (addr T_f) <- get var2: (addr F), f
  => "8d/copy-address *(ebp+" var2.stack-offset "+" offset(f) ") " reg "/r32"

# Handles for safe access to the heap

copy-handle-to dest: (handle T), src: (handle T)
  => "50/push-eax"
     "8b/-> *(ebp+" src.stack-offset ") 0/r32/eax"
     "89/<- *(ebp+" dest.stack-offset ") 0/r32/eax"
     "8b/-> *(ebp+" src.stack-offset+4 ") 0/r32/eax"
     "89/<- *(ebp+" dest.stack-offset+4 ") 0/r32/eax"
     "58/pop-to-eax"

copy-handle-to *dest/reg: (addr handle T), src: (handle T)
  => "50/push-eax"
     "8b/-> *(ebp+" src.stack-offset ") 0/r32/eax"
     "89/<- *" reg " 0/r32/eax"
     "8b/-> *(ebp+" src.stack-offset+4 ") 0/r32/eax"
     "89/<- *(" reg "+4) 0/r32/eax"
     "58/pop-to-eax"

out/reg: (addr T) <- lookup in: (handle T)
  => # payload_allocid = in->address->allocid
     "8b/-> *(epb+" (in.stack-offset+4) ") " reg "/r32"
     "8b/-> *" reg " " reg "/r32"
     # if (payload_allocid != handle->allocid) abort
     "39/compare *(ebp+" in.stack-offset ") " reg "/r32"
     "0f 85/jump-if-!= $lookup:abort/disp32"
     # return payload
     "8b/-> *(epb+" (in.stack-offset+4) ") " reg "/r32"
     "81 0/subop/add %" reg " 4/imm32"  # skip payload->allocid

vim:ft=mu:nowrap:textwidth=0
5966 - document all supported Mu instructions 2020-02-01 02:39:27 +00:00			`## Mu's instructions and their table-driven translation`

6173 2020-03-27 09:08:02 +00:00			`See http://akkartik.name/akkartik-convivial-20200315.pdf for the complete`
			`story. In brief: Mu is a statement-oriented language. Blocks consist of flat`
			`lists of instructions. Instructions can have inputs after the operation, and`
			`outputs to the left of a '<-'. Inputs and outputs must be variables. They can't`
			`include nested expressions. Variables can be literals ('n'), or live in a`
			`register ('var/reg') or in memory ('var') at some 'stack-offset' from the 'ebp'`
			`register. Outputs must be registers. To modify a variable in memory, pass it in`
			`by reference as an input. (Inputs are more precisely called 'inouts'.)`
			`Conversely, registers that are just read from must not be passed as inputs.`

			`The following chart shows all the instruction forms supported by Mu, along with`
			`the SubX instruction they're translated to.`
6159 2020-03-22 00:25:52 +00:00
			`var/eax <- increment => "40/increment-eax"`
			`var/ecx <- increment => "41/increment-ecx"`
			`var/edx <- increment => "42/increment-edx"`
			`var/ebx <- increment => "43/increment-ebx"`
			`var/esi <- increment => "46/increment-esi"`
			`var/edi <- increment => "47/increment-edi"`
			`increment var => "ff 0/subop/increment *(ebp+" var.stack-offset ")"`
			`increment var/reg => "ff 0/subop/increment " reg`

			`var/eax <- decrement => "48/decrement-eax"`
			`var/ecx <- decrement => "49/decrement-ecx"`
			`var/edx <- decrement => "4a/decrement-edx"`
			`var/ebx <- decrement => "4b/decrement-ebx"`
			`var/esi <- decrement => "4e/decrement-esi"`
			`var/edi <- decrement => "4f/decrement-edi"`
			`decrement var => "ff 1/subop/decrement *(ebp+" var.stack-offset ")"`
			`decrement var/reg => "ff 1/subop/decrement " reg`

			`var/reg <- add var2/reg2 => "01/add-to %" reg " " reg2 "/r32"`
			`var/reg <- add var2 => "03/add *(ebp+" var2.stack-offset ") " reg "/r32"`
			`var/reg <- add var2/reg2 => "03/add " reg2 " " reg "/r32"`
			`add-to var1, var2/reg => "01/add-to *(ebp+" var1.stack-offset ") " reg "/r32"`
			`var/eax <- add n => "05/add-to-eax " n "/imm32"`
			`var/reg <- add n => "81 0/subop/add %" reg " " n "/imm32"`
			`add-to var, n => "81 0/subop/add *(ebp+" var.stack-offset ") " n "/imm32"`
			`add-to var/reg, n => "81 0/subop/add " reg " " n "/imm32"`

			`var/reg <- subtract var2/reg2 => "29/subtract-from %" reg " " reg2 "/r32"`
			`var/reg <- subtract var2 => "2b/subtract *(ebp+" var2.stack-offset ") " reg "/r32"`
			`var/reg <- subtract var2/reg2 => "2b/subtract " reg2 " " reg1 "/r32"`
			`subtract-from var1, var2/reg2 => "29/subtract-from *(ebp+" var1.stack-offset ") " reg2 "/r32"`
			`var/eax <- subtract n => "2d/subtract-from-eax " n "/imm32"`
			`var/reg <- subtract n => "81 5/subop/subtract %" reg " " n "/imm32"`
			`subtract-from var, n => "81 5/subop/subtract *(ebp+" var.stack-offset ") " n "/imm32"`
			`subtract-from var/reg, n => "81 5/subop/subtract " reg " " n "/imm32"`

			`var/reg <- and var2/reg2 => "21/and-with %" reg " " reg2 "/r32"`
			`var/reg <- and var2 => "23/and *(ebp+" var2.stack-offset " " reg "/r32"`
			`var/reg <- and var2/reg2 => "23/and " reg2 " " reg "/r32"`
			`and-with var1, var2/reg => "21/and-with *(ebp+" var1.stack-offset ") " reg "/r32"`
			`var/eax <- and n => "25/and-with-eax " n "/imm32"`
			`var/reg <- and n => "81 4/subop/and %" reg " " n "/imm32"`
			`and-with var, n => "81 4/subop/and *(ebp+" var.stack-offset ") " n "/imm32"`
			`and-with var/reg, n => "81 4/subop/and " reg " " n "/imm32"`

			`var/reg <- or var2/reg2 => "09/or-with %" reg " " reg2 "/r32"`
			`var/reg <- or var2 => "0b/or *(ebp+" var2.stack-offset ") " reg "/r32"`
			`var/reg <- or var2/reg2 => "0b/or " reg2 " " reg "/r32"`
			`or-with var1, var2/reg2 => "09/or-with *(ebp+" var1.stack-offset " " reg2 "/r32"`
			`var/eax <- or n => "0d/or-with-eax " n "/imm32"`
			`var/reg <- or n => "81 1/subop/or %" reg " " n "/imm32"`
			`or-with var, n => "81 1/subop/or *(ebp+" var.stack-offset ") " n "/imm32"`
			`or-with var/reg, n => "81 1/subop/or " reg " " n "/imm32"`

			`var/reg <- xor var2/reg2 => "31/xor-with %" reg " " reg2 "/r32"`
			`var/reg <- xor var2 => "33/xor *(ebp+" var2.stack-offset ") " reg "/r32"`
			`var/reg <- xor var2/reg2 => "33/xor " reg2 " " reg "/r32"`
			`xor-with var1, var2/reg => "31/xor-with *(ebp+" var1.stack-offset ") " reg "/r32"`
			`var/eax <- xor n => "35/xor-with-eax " n "/imm32"`
			`var/reg <- xor n => "81 6/subop/xor %" reg " " n "/imm32"`
			`xor-with var, n => "81 6/subop/xor *(ebp+" var.stack-offset ") " n "/imm32"`
			`xor-with var/reg, n => "81 6/subop/xor " reg " " n "/imm32"`

			`var/eax <- copy n => "b8/copy-to-eax " n "/imm32"`
			`var/ecx <- copy n => "b9/copy-to-ecx " n "/imm32"`
			`var/edx <- copy n => "ba/copy-to-edx " n "/imm32"`
			`var/ebx <- copy n => "bb/copy-to-ebx " n "/imm32"`
			`var/esi <- copy n => "be/copy-to-esi " n "/imm32"`
			`var/edi <- copy n => "bf/copy-to-edi " n "/imm32"`
			`var/reg <- copy var2/reg2 => "89/<- %" reg " " reg2 "/r32"`
			`copy-to var1, var2/reg => "89/<- *(ebp+" var1.stack-offset ") " reg "/r32"`
			`var/reg <- copy var2 => "8b/-> *(ebp+" var2.stack-offset ") " reg "/r32"`
			`var/reg <- copy var2/reg2 => "8b/-> " reg2 " " reg "/r32"`
			`var/reg <- copy n => "c7 0/subop/copy %" reg " " n "/imm32"`
			`copy-to var, n => "c7 0/subop/copy *(ebp+" var.stack-offset ") " n "/imm32"`
			`copy-to var/reg, n => "c7 0/subop/copy " reg " " n "/imm32"`

			`compare var1, var2/reg2 => "39/compare *(ebp+" var1.stack-offset ") " reg2 "/r32"`
			`compare var1/reg1, var2/reg2 => "39/compare " reg1 " " reg2 "/r32"`
			`compare var1/reg1, var2 => "3b/compare<- *(ebp+" var2.stack-offset ") " reg1 "/r32"`
			`compare var/reg, var2/reg2 => "3b/compare<- " reg " " n "/imm32"`
			`compare var/eax, n => "3d/compare-eax-with " n "/imm32"`
			`compare var, n => "81 7/subop/compare *(ebp+" var.stack-offset ") " n "/imm32"`
			`compare var/reg, n => "81 7/subop/compare " reg " " n "/imm32"`

			`var/reg <- multiply var2 => "0f af/multiply *(ebp+" var2.stack-offset ") " reg "/r32"`
			`var/reg <- multiply var2/reg2 => "0f af/multiply " reg2 " " reg "/r32"`

			`break => "e9/jump break/disp32"`
			`break label => "e9/jump " label ":break/disp32"`
			`loop => "e9/jump loop/disp32"`
			`loop label => "e9/jump " label ":loop/disp32"`

			`break-if-= => "0f 84/jump-if-= break/disp32"`
			`break-if-= label => "0f 84/jump-if-= " label ":break/disp32"`
			`loop-if-= => "0f 84/jump-if-= loop/disp32"`
			`loop-if-= label => "0f 84/jump-if-= " label ":loop/disp32"`

			`break-if-!= => "0f 85/jump-if-!= break/disp32"`
			`break-if-!= label => "0f 85/jump-if-!= " label ":break/disp32"`
			`loop-if-!= => "0f 85/jump-if-!= loop/disp32"`
			`loop-if-!= label => "0f 85/jump-if-!= " label ":loop/disp32"`

			`break-if-< => "0f 8c/jump-if-< break/disp32"`
			`break-if-< label => "0f 8c/jump-if-< " label ":break/disp32"`
			`loop-if-< => "0f 8c/jump-if-< loop/disp32"`
			`loop-if-< label => "0f 8c/jump-if-< " label ":loop/disp32"`

			`break-if-> => "0f 8f/jump-if-> break/disp32"`
			`break-if-> label => "0f 8f/jump-if-> " label ":break/disp32"`
			`loop-if-> => "0f 8f/jump-if-> loop/disp32"`
			`loop-if-> label => "0f 8f/jump-if-> " label ":loop/disp32"`

			`break-if-<= => "0f 8e/jump-if-<= break/disp32"`
			`break-if-<= label => "0f 8e/jump-if-<= " label ":break/disp32"`
			`loop-if-<= => "0f 8e/jump-if-<= loop/disp32"`
			`loop-if-<= label => "0f 8e/jump-if-<= " label ":loop/disp32"`

			`break-if->= => "0f 8d/jump-if->= break/disp32"`
			`break-if->= label => "0f 8d/jump-if->= " label ":break/disp32"`
			`loop-if->= => "0f 8d/jump-if->= loop/disp32"`
			`loop-if->= label => "0f 8d/jump-if->= " label ":loop/disp32"`

			`break-if-addr< => "0f 82/jump-if-addr< break/disp32"`
			`break-if-addr< label => "0f 82/jump-if-addr< " label ":break/disp32"`
			`loop-if-addr< => "0f 82/jump-if-addr< loop/disp32"`
			`loop-if-addr< label => "0f 82/jump-if-addr< " label ":loop/disp32"`

			`break-if-addr> => "0f 87/jump-if-addr> break/disp32"`
			`break-if-addr> label => "0f 87/jump-if-addr> " label ":break/disp32"`
			`loop-if-addr> => "0f 87/jump-if-addr> loop/disp32"`
			`loop-if-addr> label => "0f 87/jump-if-addr> " label ":loop/disp32"`

			`break-if-addr<= => "0f 86/jump-if-addr<= break/disp32"`
			`break-if-addr<= label => "0f 86/jump-if-addr<= " label ":break/disp32"`
			`loop-if-addr<= => "0f 86/jump-if-addr<= loop/disp32"`
			`loop-if-addr<= label => "0f 86/jump-if-addr<= " label ":loop/disp32"`

			`break-if-addr>= => "0f 83/jump-if-addr>= break/disp32"`
			`break-if-addr>= label => "0f 83/jump-if-addr>= " label ":break/disp32"`
			`loop-if-addr>= => "0f 83/jump-if-addr>= loop/disp32"`
			`loop-if-addr>= label => "0f 83/jump-if-addr>= " label ":loop/disp32"`

			`In the following instructions types are provided for clarity even if they must`
			`be provided in an earlier 'var' declaration.`
5968 2020-02-01 20:14:12 +00:00
6170 2020-03-25 16:54:53 +00:00			`# Address operations`
6145 - 'address' operator This could be a can of worms, but I think I have a set of checks that will keep use of addresses type-safe. 2020-03-14 21:46:45 +00:00
6164 2020-03-24 10:49:37 +00:00			`var/reg: (addr T) <- address var2: T`
			`=> "8d/copy-address *(ebp+" var2.stack-offset ") " reg "/r32"`
6145 - 'address' operator This could be a can of worms, but I think I have a set of checks that will keep use of addresses type-safe. 2020-03-14 21:46:45 +00:00
6160 - plan for safe heap access Based on apps/handle.subx (commit 4894), but we're able to simplify it further now that we know more about the situation we find ourselves in. 6 instructions, zero pushes or pops. Before I can start building this, I need to reorganize my use of handles. They're going to be fat pointers so we can't store them in registers anymore. 2020-03-22 04:22:20 +00:00			`Array operations (TODO: bounds-checking)`
6041 - array indexing starting to work And we're using it now in factorial.mu! In the process I had to fix a couple of bugs in pointer dereferencing. There are still some limitations: a) Indexing by a literal doesn't work yet. b) Only arrays of ints supported so far. Looking ahead, I'm not sure how I can support indexing arrays by non-literals (variables in registers) unless the element size is a power of 2. 2020-02-21 18:05:04 +00:00
6389 2020-05-24 15:02:11 +00:00			`var/reg <- index arr/rega: (addr array T), idx/regi: int`
			`\| if size-of(T) is 4 or 8`
			`=> "8d/copy-address *(" rega "+" regi "<<" log2(size-of(T)) "+4) " reg "/r32"`
6131 - operating on arrays on the stack 2020-03-12 07:17:35 +00:00			`var/reg <- index arr: (array T sz), idx/regi: int`
6389 2020-05-24 15:02:11 +00:00			`=> "8d/copy-address *(ebp+" regi "<<" log2(size-of(T)) "+" (arr.stack-offset + 4) ") " reg "/r32"`
6041 - array indexing starting to work And we're using it now in factorial.mu! In the process I had to fix a couple of bugs in pointer dereferencing. There are still some limitations: a) Indexing by a literal doesn't work yet. b) Only arrays of ints supported so far. Looking ahead, I'm not sure how I can support indexing arrays by non-literals (variables in registers) unless the element size is a power of 2. 2020-02-21 18:05:04 +00:00			`var/reg <- index arr/rega: (addr array T), n`
6389 2020-05-24 15:02:11 +00:00			`=> "8d/copy-address (" rega "+" (nsize-of(T)+4) ") " reg "/r32"`
6131 - operating on arrays on the stack 2020-03-12 07:17:35 +00:00			`var/reg <- index arr: (array T sz), n`
6389 2020-05-24 15:02:11 +00:00			`=> "8d/copy-address (ebp+" (arr.stack-offset+4+nsize-of(T)) ") " reg "/r32"`
6094 - new 'compute-offset' instruction If indexing into a type with power-of-2-sized elements we can access them in one instruction: x/reg1: (addr int) <- index A/reg2: (addr array int), idx/reg3: int This translates to a single instruction because x86 instructions support an addressing mode with left-shifts. For non-powers-of-2, however, we need a multiply. To keep things type-safe, it is performed like this: x/reg1: (offset T) <- compute-offset A: (addr array T), idx: int y/reg2: (addr T) <- index A, x An offset is just an int that is guaranteed to be a multiple of size-of(T). Offsets can only be used in index instructions, and the types will eventually be required to line up. In the process, I have to expand Input-size because mu.subx is growing big. 2020-03-08 01:32:39 +00:00
			`var/reg: (offset T) <- compute-offset arr: (addr array T), idx/regi: int # arr can be in reg or mem`
6389 2020-05-24 15:02:11 +00:00			`=> "69/multiply %" regi " " size-of(T) "/imm32 " reg "/r32"`
6094 - new 'compute-offset' instruction If indexing into a type with power-of-2-sized elements we can access them in one instruction: x/reg1: (addr int) <- index A/reg2: (addr array int), idx/reg3: int This translates to a single instruction because x86 instructions support an addressing mode with left-shifts. For non-powers-of-2, however, we need a multiply. To keep things type-safe, it is performed like this: x/reg1: (offset T) <- compute-offset A: (addr array T), idx: int y/reg2: (addr T) <- index A, x An offset is just an int that is guaranteed to be a multiple of size-of(T). Offsets can only be used in index instructions, and the types will eventually be required to line up. In the process, I have to expand Input-size because mu.subx is growing big. 2020-03-08 01:32:39 +00:00			`var/reg: (offset T) <- compute-offset arr: (addr array T), idx: int # arr can be in reg or mem`
6389 2020-05-24 15:02:11 +00:00			`=> "69/multiply *(ebp+" idx.stack-offset ") " size-of(T) "/imm32 " reg "/r32"`
6094 - new 'compute-offset' instruction If indexing into a type with power-of-2-sized elements we can access them in one instruction: x/reg1: (addr int) <- index A/reg2: (addr array int), idx/reg3: int This translates to a single instruction because x86 instructions support an addressing mode with left-shifts. For non-powers-of-2, however, we need a multiply. To keep things type-safe, it is performed like this: x/reg1: (offset T) <- compute-offset A: (addr array T), idx: int y/reg2: (addr T) <- index A, x An offset is just an int that is guaranteed to be a multiple of size-of(T). Offsets can only be used in index instructions, and the types will eventually be required to line up. In the process, I have to expand Input-size because mu.subx is growing big. 2020-03-08 01:32:39 +00:00			`var/reg <- index arr/rega: (addr array T), o/rego: offset`
6159 2020-03-22 00:25:52 +00:00			`=> "8d/copy-address *(" rega "+" rego "+4) " reg "/r32"`
6041 - array indexing starting to work And we're using it now in factorial.mu! In the process I had to fix a couple of bugs in pointer dereferencing. There are still some limitations: a) Indexing by a literal doesn't work yet. b) Only arrays of ints supported so far. Looking ahead, I'm not sure how I can support indexing arrays by non-literals (variables in registers) unless the element size is a power of 2. 2020-02-21 18:05:04 +00:00
6390 - return `length` in elements 2020-05-24 20:27:08 +00:00			`Computing the length of an array is complex.`
6389 2020-05-24 15:02:11 +00:00
			`var/reg <- length arr/reg2: (addr array T)`
			`\| if T is byte (TODO)`
			`=> "8b/-> *" reg2 " " reg "/r32"`
6390 - return `length` in elements 2020-05-24 20:27:08 +00:00			`\| if size-of(T) is 4 or 8 or 16 or 32 or 64 or 128`
			`=> "8b/-> *" reg2 " " reg "/r32"`
			`"c1/shift 5/subop/logic-right %" reg " " log2(size-of(T)) "/imm8"`
			`\| otherwise (TODO)`
			`x86 has no instruction to divide by a literal, so`
			`we need up to 3 extra registers! eax/edx for division and say ecx`
			`=> if reg is not eax`
			`"50/push-eax"`
			`if reg is not ecx`
			`"51/push-ecx"`
			`if reg is not edx`
			`"52/push-edx"`
			`"8b/-> *" reg2 " eax/r32"`
			`"31/xor %edx 2/r32/edx" # sign-extend, but array size can't be negative`
			`"b9/copy-to-ecx " size-of(T) "/imm32"`
			`"f7 7/subop/idiv-eax-edx-by %ecx"`
			`if reg is not eax`
			`"89/<- %" reg " 0/r32/eax"`
			`if reg is not edx`
			`"5a/pop-to-edx"`
			`if reg is not ecx`
			`"59/pop-to-ecx"`
			`if reg is not eax`
			`"58/pop-to-eax"`
6389 2020-05-24 15:02:11 +00:00
6170 2020-03-25 16:54:53 +00:00			`# User-defined types`
6059 2020-02-28 00:58:16 +00:00
			`If a record (product) type T was defined to have elements a, b, c, ... of`
			`types T_a, T_b, T_c, ..., then accessing one of those elements f of type T_f:`

6159 2020-03-22 00:25:52 +00:00			`var/reg: (addr T_f) <- get var2/reg2: (addr F), f`
			`=> "8d/copy-address *(" reg2 "+" offset(f) ") " reg "/r32"`
			`var/reg: (addr T_f) <- get var2: (addr F), f`
			`=> "8d/copy-address *(ebp+" var2.stack-offset "+" offset(f) ") " reg "/r32"`
6059 2020-02-28 00:58:16 +00:00
6170 2020-03-25 16:54:53 +00:00			`# Handles for safe access to the heap`
6160 - plan for safe heap access Based on apps/handle.subx (commit 4894), but we're able to simplify it further now that we know more about the situation we find ourselves in. 6 instructions, zero pushes or pops. Before I can start building this, I need to reorganize my use of handles. They're going to be fat pointers so we can't store them in registers anymore. 2020-03-22 04:22:20 +00:00
			`copy-handle-to dest: (handle T), src: (handle T)`
			`=> "50/push-eax"`
			`"8b/-> *(ebp+" src.stack-offset ") 0/r32/eax"`
			`"89/<- *(ebp+" dest.stack-offset ") 0/r32/eax"`
			`"8b/-> *(ebp+" src.stack-offset+4 ") 0/r32/eax"`
			`"89/<- *(ebp+" dest.stack-offset+4 ") 0/r32/eax"`
			`"58/pop-to-eax"`

			`copy-handle-to *dest/reg: (addr handle T), src: (handle T)`
			`=> "50/push-eax"`
			`"8b/-> *(ebp+" src.stack-offset ") 0/r32/eax"`
			`"89/<- *" reg " 0/r32/eax"`
			`"8b/-> *(ebp+" src.stack-offset+4 ") 0/r32/eax"`
			`"89/<- *(" reg "+4) 0/r32/eax"`
			`"58/pop-to-eax"`

			`out/reg: (addr T) <- lookup in: (handle T)`
			`=> # payload_allocid = in->address->allocid`
			`"8b/-> *(epb+" (in.stack-offset+4) ") " reg "/r32"`
			`"8b/-> *" reg " " reg "/r32"`
			`# if (payload_allocid != handle->allocid) abort`
			`"39/compare *(ebp+" in.stack-offset ") " reg "/r32"`
			`"0f 85/jump-if-!= $lookup:abort/disp32"`
			`# return payload`
			`"8b/-> *(epb+" (in.stack-offset+4) ") " reg "/r32"`
			`"81 0/subop/add %" reg " 4/imm32" # skip payload->allocid`

			`vim:ft=mu:nowrap:textwidth=0`