469 lines
16 KiB
Plaintext
469 lines
16 KiB
Plaintext
.so init
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.hw data-structures
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.nr H1 3
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.NH
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SOLUTIONS
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.NH 2
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Maintaining SPARC speed
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.PP
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In chapter 3 we wrote:
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.sp 0.3
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.nf
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>If we want to generate efficient code, we should at least try to reduce the number of
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>memory references and use registers wherever we can.
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.fi
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.sp 0.3
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In this chapter we will device a strategy to swiftly generate acceptable
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code by using push-pop optimization.
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Note that this is not the push-pop
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optimization already available in the EM-kit, since that is only present
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in the assembler-to-binary part which we do not use
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.[ [
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The Code Expander Generator
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.]].
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Our push-pop optimization
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works more like the fake-stack described in
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.[ [
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The table driven code generator
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.]].
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.NH 3
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Ad-hoc optimization
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.PP
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Before getting involved in any optimization let's have a look at some
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code generated with a straightforward EM to SPARC conversion of the
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C statement: \*(Sif(a[i]);\*(So Note that \*(Si%SP\*(So is an alias
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for a general purpose
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register and acts as the EM stack pointer. It has nothing to do with
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\*(Si%sp\*(So \(em the SPARC stack pointer.
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Analogous \*(Si%LB\*(So is EMs local base pointer.
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.br
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.IP
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.HS
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.TS
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;
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l s l s l
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l1f6 lf6 l2f6 lf6 l.
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EM code SPARC code Comment
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lae _a set _a, %g1 ! load address of external _a
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dec 4, %SP
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st %g1, [%SP]
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lol -4 set -4, %g1 ! load local -4 (i)
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ld [%g1+%LB], %g2
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dec 4, %SP
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st %g2, [%SP]
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loc 2 set 2, %g1 ! load constant 2
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dec 4, %SP
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st %g1, [%SP]
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sli 4 ld [%SP], %g1 ! pop shift count
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ld [%SP+4], %g2 ! pop shiftee
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sll %g2, %g1, %g3
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inc 4, %SP
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st %g3, [%SP] ! push 4 * i
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ads 4 ld [%SP], %g1 ! add pointer and offset
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ld [%SP+4], %g2
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add %g1, %g2, %g3
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inc 4, %SP
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st %g3, [%SP] ! push address of _a + (4 * i)
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loi 4 ld [%SP], %g1 ! load indirect 4 bytes
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ld [%g1], %g2
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st %g2, [%SP] ! push a[i]
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cal _f
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...
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.TE
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.HS
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.LP
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Although the code is easy understand, it clearly is far from optimal.
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The above code uses approximately 60 clock-cycles\(dg
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.FS
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\(dg In general each instruction only takes one cycle,
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except for \*(Sild\*(So and
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\*(Sist\*(So which may both require additional clock cycles. The exact amount
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of extra cycles needed depends on the SPARC implementation and memory access
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time. Furthermore, the
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\*(Siset\*(So pseudo-instruction is a bit tricky. It takes one cycle when
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its argument lies between -4096 and 4095, and two cycles otherwise.
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.FE
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to push an array-element on the stack,
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something which a 68020 can do in a single instruction. The SPARC
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processor may be fast, but not fast enough to justify the above code.
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.PP
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The same statement can be translated much more efficiently:
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.DS
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.TS
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;
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l2f6 lf6 l.
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sll %i0, 2, %g2 ! multiply index by 4
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set _a, g3
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ld [%g2+%g3], %g1 ! get contents of a[i]
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dec 4, SP
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st %g2, [SP] ! push a[i] onto the stack
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.TE
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.DE
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which, instead of 60, uses only 5 clock cycles to retrieve the element
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from memory and 5 additional cycles when the result has to be pushed
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on the stack. Note that when the result is not a parameter it does not
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have to be pushed on the stack. By making efficient use of the SPARC
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registers we can fetch \*(Sia[i]\*(So in only 5 cycles!
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.NH 3
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Analyzing optimization
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.PP
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Instead of ad-hoc optimization we will need something more solid.
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When one tries to optimize the above code in an ad-hoc manner one will
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probably notice the large overhead due to stack access. Almost every EM
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instruction requires at least three SPARC instructions: one to carry out
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the EM instruction and two to pop and push the result from and onto the
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stack. This happens for every instruction, even though the data being pushed
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will probably be needed by the next instruction. To optimize this extensive
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pushing and popping of data we will use the appropriately named push-pop
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optimization.
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.PP
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The idea behind push-pop optimization is to delay the push operation until
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it is almost certain that the data actually has to be pushed.
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As is often the case, the data does not have to be pushed,
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but will be used as input to another EM instruction.
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If we can decide at compile time that this will indeed be
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the case we can save the time of first pushing the data and then popping it
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back again by temporarily storing the data (possibly only during compilation!)
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and using it no sooner than it is actually needed.
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.PP
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The \*(Sisli 4\*(So instruction, for instance, expects two inputs on top of the
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stack: on top a counter and right below that the shiftee (the number
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to be shifted). As a result \*(Sisli\*(So
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pushes 'shiftee << counter' back to the stack. Now consider the following
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sequence, which could be the result of the expression \*(Si4 * i\*(So
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.DS
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.TS
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;
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l1f6 lf6 l.
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lol -4
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loc 2
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sli 4
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.TE
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.DE
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In the non-optimized situation the \*(Silol\*(So would push
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a local variable (whose offset is -4) on the stack.
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Then the \*(Siloc\*(So pushes a 2 on the stack and finally \*(Sisli\*(So
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retrieves both these numbers to replace then with the result.
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On most machines it is not necessary to
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push the 2 on the stack, since it can be used in the shift instruction
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as an immediately operand. On a SPARC, for instance, one can write
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.DS
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.TS
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;
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l2f6 lf6 l.
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ld [%LB-4], %g1 ! load local variable into register g1
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sll %g1, 2, %g2 ! perform the shift-left-by-2
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.TE
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.DE
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where the output of the \*(Silol\*(So, as well as the immediate operand 2 are used
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in the shift instruction. As suggested before, all of this can be
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achieved with push-pop optimization.
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.NH 3
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A mechanism for push-pop optimization
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.PP
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To implement the above optimization we need some mechanism to
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temporarily store information during compilation.
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We need to be able to store, compare and retrieve information from the
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temporary storage (cache) without any
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loss of information. Before describing all the routines used
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to implement our cache we will first describe how the cache works.
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.PP
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Items in the cache are structures containing an external (\*(Sichar *\*(So),
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two registers (\*(Sireg_t\*(So) and a constant (\*(Siarith\*(So),
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any of which may be 0.
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The value of such a structure is the sum of (the values of)
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its elements. To put a register in the cache, one has to be allocated either
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by calling \*(Sialloc_reg\*(So which returns a free register, by
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\*(Siforced_alloc_reg\*(So which allocates a specific register or any
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of the other routines available to allocate a register. The keep things
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simple, we will not discuss all of the available primitives here.
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When the register
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is then put in the cache by the \*(Sipush_reg\*(So routine, the ownership will
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be transferred from the user to the cache. Ownership is important, because
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only the owner of a register may (and must!) deallocate it. Registers can be
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owned by either an (imaginary) register manager, the cache or the user.
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When the user retrieves a register from the stack with \*(Sipop_reg\*(So for
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instance, ownership is back to the user.
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The user should then call \*(Sifree_reg\*(So
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to transfer ownership to the register manager or call \*(Sipush_reg\*(So
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to give it back to the cache.
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Since the cache behaves itself as a stack we will use the term pop resp. push
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to get items from, resp. put items in the cache.
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.PP
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We shall now present the sets of routines that implement the cache.
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.IP \(bu
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The routines
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.DS
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\*(Si
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reg_t alloc_reg(void)
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reg_t alloc_reg_var(void)
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reg_t alloc_float(void)
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reg_t alloc_float_var(void)
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reg_t alloc_double(void)
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reg_t alloc_double_var(void)
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void forced_alloc_reg(reg_t)
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void soft_alloc_reg(reg_t)
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void free_reg(reg_t)
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void free_double_reg(reg_t)
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\*(So
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.DE
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allocate and deallocate registers. If there are no more register left,
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i.e. they are owned by the cache,
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one or more registers will be freed by flushing part of the cache
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onto the real stack.
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The \*(Sialloc_xxx_var\*(So primitives try to allocate a register that
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can be used to store local variables. (In the current implementation
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only the input and local registers.) If none can be found \*(SiNULL\*(So
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is returned. \*(Siforced_alloc_reg\*(So forces the allocation of a certain
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register. If it was already in use, its contents are moved to another
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register. Finally \*(Sisoft_alloc_reg\*(So provides the possibility to
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push a register onto the cache and still keep a copy for later use.
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(Used to implement the \*(Sidup 4\*(So for example.)
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.IP \(bu
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The routines
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.DS
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\*(Si
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void push_const(arith)
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arith pop_const(void)
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\*(So
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.DE
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push or pop a constant onto or from the stack. Distinction between
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constants and other types is made so as not to loose any information; constants
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may be used later on as immediate operators, which is not the case
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for other types. If \*(Sipop_const\*(So is called, but the element on top of
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the cache has either one of the external or register fields non-zero a
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fatal error will be reported.
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.IP \(bu
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The routines
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.DS
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\*(Si
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reg_t pop_reg(void)
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reg_t pop_float(void)
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reg_t pop_double(void)
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reg_t pop_reg_c13(char *n)
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void pop_reg_as(reg_t)
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void push_reg(reg_t)
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\*(So
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.DE
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push or pop a register. These will be used most often since results from one
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EM instruction, which are computed in a register, are often used in the next.
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When the element on top of the cache is more
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than just a register the cache manager
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will generate code to compute the sum of its fields and put the result in a
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register. This register will then be given to the user.
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If the user wants the result is a special register, he should use the
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\*(Sipop_reg_as\*(So routine.
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The \*(Sipop_reg_c13\*(So gives an optional number (as character string) whose
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value can be represented in 13 bits. The constant can then be used as an
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offset for the SPARC \*(Sild\*(So and \*(Sist\*(So instructions.
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.IP \(bu
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The routine
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.DS
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\*(Si
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void push_ext(char *)
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\*(So
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.DE
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pushes an external onto the stack. There is no pop-variant of this one since
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there is no use in popping an external.
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.IP \(bu
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The routines
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.DS
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\*(Si
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void inc_tos(arith n)
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void inc_tos_reg(reg_t r)
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\*(So
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.DE
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increment the element on top of the cache by either the constant \*(Sin\*(So
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or by a register. The latter is useful for pointer addition when referencing
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external memory.
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.KS
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.IP \(bu
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The routine
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.DS
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\*(Si
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int type_of_tos(void)
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\*(So
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.DE
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.KE
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returns the type of the element on top of the cache. This is a combination
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(binary OR) of \*(SiT_ext\*(So, \*(SiT_reg\*(So or \*(SiT_float\*(So,
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\*(SiT_reg2\*(So or \*(SiT_float2\*(So, and \*(SiT_cst\*(So,
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and tells the
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user which of the three fields are non-zero. When the register-fields
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represent \*(Si%g0\*(So, it is considered zero.
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.IP \(bu
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Miscellaneous routines:
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.DS
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\*(Si
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void init_cache(void)
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void cache_need(int)
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void change_reg(void)
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void flush_cache(void)
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\*(So
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.DE
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\*(Siinit_cache\*(So should be called before any
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other cache routines, to initialize some internal datastructures.
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\*(Sicache_need\*(So is used to tell the cache that a certain number
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of register are needed for the next operation. This way the cache can
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load them efficiently in one fell swoop. \*(Sichange_reg\*(So is to be
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called when the user changes a register of which the cache (possibly) has
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co-ownership. Because the contents of registers in the cache are
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not allowed to change the user should call \*(Sichange_reg\*(So to
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instruct the cache to copy the contents to some other register.
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\*(Siflush_cache\*(So writes the cache to the stack and invalidates
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the cache. It should be used before branches,
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before labels and on other places where the stack has to be valid (i.e. where
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every item on the EM-stack should be stored on the real stack, not in some
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virtual cache).
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.NH 3
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Implementing push-pop optimization in the EM_table
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.PP
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As indicated above, there is no regular way to represent the described
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optimization in the EM_table. The only possible escapes from the EM_table
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are function calls, but that is clearly not enough to implement a good
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push-pop optimizer. Therefore we will use a modified version of the EM_table
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format, where the description of, say, the \*(Silol\*(So instruction might look
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like this\(dg:
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.FS
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\(dg This is not the way the \*(Silol\*(So actually looks in the EM_table;
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it only shows how it \fImight\fR look using the forementioned push/pop
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primitives.
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.FE
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.DS
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\*(Si
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reg_t A, B;
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const_str_t n;
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alloc_reg(A);
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push_reg(LB);
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inc_tos($1);
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B = pop_reg_c13(n);
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"ld [$B+$n], $A";
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push_reg(A);
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free_reg(B);
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\*(So
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.DE
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For more details about the exact implementation consult
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appendix B which contains some characteristic excerpts from the EM_table.
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.NH 2
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Stack management
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.PP
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When converting EM code to some executable code there is the problem of
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maintaining multiple stacks. The usual way to do this is described in
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.[ [
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Description of a Machine Architecture
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.]]
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and is shown in figure \*(SN1.
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.KE
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.PS
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copy "pics/EM_stack.orig"
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.PE
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.ce 1
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\fIFigure \*(SN1: usual stack management.
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.KE
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.sp
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.LP
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This means that the EM stack and the hardware stack (used
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for subroutine calls, etc.) are interleaved in memory. On the SPARC, however,
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this brings up a large problem: in the former model it is assumed that the
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resolution of the stack pointer is a word, but this is not the case on the
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SPARC processor. On the SPARC processor the stack-pointer as well as the
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frame-pointer have to be aligned on 8-byte boundaries, so one can not simply
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push a word on the stack and then lower the stack-pointer by 4 bytes!
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.NH 3
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Possible solutions
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.PP
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A simple idea might be to use a swiss-cheese stack; we could
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push a 4-byte word onto the stack and then lower the stack by 8.
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Unfortunately, this is not a very solid solution, because
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pointer-arithmetic involving pointers to objects on the stack would cause
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hard-to-predict anomalies.
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.PP
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Another try would be not to use the hardware stack at all. As long as we
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do not generate subroutine-calls everything will be all right. This
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approach, however, also has some disadvantages: first we would not be able
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to use any of the existing debuggers such as \fIadb\fR, because they all
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assume a regular stack format. Secondly, we would not be able to make use
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of the SPARC's register windows to keep local variables. Finally, doing all the
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administrative work necessary for subroutine calls ourselves instead of
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letting the hardware handle it for us,
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causes unnecessary procedure-call overhead.
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.PP
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Yet another alternative would be to emulate the EM-part of the stack,
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and to let the hardware handle the subroutine call. Since we will
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emulate our own stack, there are no alignment restrictions and because
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we will use the hardware procedure call we can still make use of
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the register windows.
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.NH 3
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Our implementation
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.PP
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To implement the hybrid stack we need two extra registers: one for the
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the EM stack pointer (the forementioned \*(Si%SP\*(So) and one for the
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EM local base pointer (\*(Si%LB\*(So). The most elegant solution would be to
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put both stacks in different segments, so they would not influence
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each other. Unfortunately
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.UX
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lacks the ability to add segments and
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since we will implement our backend under
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.UX,
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we will have to put
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both stacks in the same segment. Exactly how this can be done is shown
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in figure \*(SN2.
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.DS
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.PS
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copy "pics/mem_config"
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.PE
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.ce 1
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\fIFigure \*(SN2: our stack management.\fR
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.DE
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.sp
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During normal procedure execution, the SPARC stack pointer has to point to
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a memory location where the operating system can dump the active part of
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the register window. The rest of the
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register window will be dumped in the therefor pre-allocated (stack) space
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by following the frame
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pointer. When a signal occurs things get even more complicated and
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result in figure \*(SN3.
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.DS
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.PS
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copy "pics/signal_stack"
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.PE
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.ce 1
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\fIFigure \*(SN3: our signal stack.\fR
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.DE
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.PP
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The exact implementation of the stack is shown in figure \*(SN4.
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.KF
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.PS
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copy "pics/EM_stack.ours"
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.PE
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.ce 1
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\fIFigure \*(SN4: stack overview.\fR
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.KE
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.NH 2
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Miscellaneous
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.PP
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As mentioned in the previous chapter, the generated \fI.o\fR-files are
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not compatible with Sun's own object format. The primary reason for
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this is that Sun usually passes the first six parameters of a procedure call
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through registers. If we were to do that too, we would always have
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to fetch the top six words from the stack into registers, even when
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the procedure would not have any parameters at all. Apart from this,
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structure-passing is another exception in Sun's object format which
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makes is impossible to generate object-compatible code.\(dg
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.FS
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\(dg Exactly how Sun passes structures as parameters is described in
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Appendix D of the SPARC Architecture Manual (Software Considerations)
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.FE
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.bp
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