Jump table: Difference between revisions

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m (→‎Stack-based dispatch: we don't need to prescribe which is preferred, that's a personal preference, just describe the difference)
(→‎Indirect jumping: "the stack must be used" is too strong, you're not forced to share the variable between threads)
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To call a routine via a selector, load the selector into A, then JSR do_action. This will then JMP to the appropriate routine, which will eventually RTS back to the routine that did JSR do_action. Essentially, you have JSR do_action, which then does JMP routine, which then does RTS; the JMP in the middle has no effect on the call stack. Note that the above code cannot be used without a JSR to it, since without that it's just a glorified JMP. That is, do_action must never be inlined in the code that uses it; it must always be called with JSR like a normal routine.
To call a routine via a selector, load the selector into A, then JSR do_action. This will then JMP to the appropriate routine, which will eventually RTS back to the routine that did JSR do_action. Essentially, you have JSR do_action, which then does JMP routine, which then does RTS; the JMP in the middle has no effect on the call stack. Note that the above code cannot be used without a JSR to it, since without that it's just a glorified JMP. That is, do_action must never be inlined in the code that uses it; it must always be called with JSR like a normal routine.


This routine has a significant limitation: if it's used by the game code and from an interrupt, perhaps the music driver, it can fail. The use of temp, a global variable, prevents the routine from being [[Wikipedia:Reentrant (subroutine) | reentrant]]. If the game code were in the middle of a call to do_action, and had already written temp, but then an interrupt occurs and its code then calls do_action, it will overwrite the value in temp. Then, after the interrupt handler returns and resumes the interrupted code, temp won't have the value expected by the original call to do_action. To overcome this, the stack must be used.
Like most temporary variables, the temp variable in this routine should not be used by both main thread code and an interrupt/NMI. If this routine is interrupted in the middle and the interrupt code modifies temp, the wrong address will be jumped to when it resumes after the interrupt. If a [[Wikipedia:Reentrant (subroutine) | reentrant]] jump table subroutine is needed, the stack can be used instead (see below).


== Stack-based dispatch ==
== Stack-based dispatch ==

Revision as of 05:27, 22 March 2014

A jump table is a table of code addresses, meant to be indexed by a selector value. For example, a game script might specify an action to be performed via an index, which is then used to select a routine from a jump table of available scripting actions. The alternative to a jump table is a long string of comparisons with each possible selector value. This approach is tedious to set up and maintain, and slow:

<source lang="6502">

Jumps to routine selected by A

do_action:

      cmp #0
      bne not0
      jmp action0

not0: cmp #1

      bne not1
      jmp action1

not1: cmp #2

      bne not2
      jmp action2

not2: ... </source>

Indirect jumping

The NES doesn't have a JMP (addr,X) instruction, as other members of the 65xx family do. If it had one, a jump table would be trivial to implement, as in the following 65C02/Hu6280/65C816 code:

<source lang="6502">

Jumps to routine selected by A, from 0 to 127. High bit of A is ignored.

do_action:

      asl a           ; A = A * 2
      tax
      jmp (table,x)

table:

      .word action0, action1, action2 ; ...

</source>

The NES does support a JMP (addr) instruction, so a jump table can be implemented by copying the address to a temporary variable, then jumping through it:

<source lang="6502">

Jumps to routine selected by A, from 0 to 127. High bit of A is ignored.

do_action:

      asl a
      tax
      lda table,x
      sta temp
      lda table+1,x
      sta temp+1
      jmp (temp)

</source>

To call a routine via a selector, load the selector into A, then JSR do_action. This will then JMP to the appropriate routine, which will eventually RTS back to the routine that did JSR do_action. Essentially, you have JSR do_action, which then does JMP routine, which then does RTS; the JMP in the middle has no effect on the call stack. Note that the above code cannot be used without a JSR to it, since without that it's just a glorified JMP. That is, do_action must never be inlined in the code that uses it; it must always be called with JSR like a normal routine.

Like most temporary variables, the temp variable in this routine should not be used by both main thread code and an interrupt/NMI. If this routine is interrupted in the middle and the interrupt code modifies temp, the wrong address will be jumped to when it resumes after the interrupt. If a reentrant jump table subroutine is needed, the stack can be used instead (see below).

Stack-based dispatch

Main article: RTS Trick

RTI and RTS allow use of the stack for holding the temporary address. These are normally used to return to some calling/interrupted code, but at their core they pull an address from the stack then jump to it. This is the behavior we need. We push the address on the stack, then execute RTI or RTS to jump to it. It's roundabout, but it solves the interrupt problem.

Even though RTI is meant for returning from an interrupt, it happens to be simpler to use for this technique, since it doesn't adjust the address it pulls from the stack:

<source lang="6502"> do_action:

      asl a
      tax
      lda table+1,x ; high byte first
      pha
      lda table,x
      pha
      php
      rti

</source>

RTS is more tricky, because it adds one to the address it pulls from the stack. This requires that every entry in the jump table have one subtracted from it. This could be done by the code, but it's tedious because the low byte must be decremented first, while the high byte needs to be pushed first. Thus, it's preferable to simply subtract one from each entry in the assembly source text:

<source lang="6502"> do_action:

      asl a
      tax
      lda table+1,x
      pha
      lda table,x
      pha
      rts

table:

      .word action0-1, action1-1, action2-1 ; ...

</source>

The benefit of the RTS version is that it's three clock cycles faster than the RTI version, due to not having to push the flags. The disadvantage is that you must adjust every table entry by -1.