/* If the argument of N is a zero page location that ends with "+1", we
- * must also check for word accesses to the location without +1.
- */
+ ** must also check for word accesses to the location without +1.
+ */
if (N->AM == AM65_ZP && NLen > 2 && strcmp (N->Arg + NLen - 2, "+1") == 0) {
What |= Base;
}
/* If the argument is zero page indirect, we must also check for accesses
- * to "arg+1"
- */
+ ** to "arg+1"
+ */
if (N->AM == AM65_ZP_INDY || N->AM == AM65_ZPX_IND || N->AM == AM65_ZP_IND) {
What |= Word;
}
CodeEntry* E = CS_GetEntry (S, From);
/* Check if there is an argument and if this argument equals Arg in
- * some variants.
- */
+ ** some variants.
+ */
if (E->Arg[0] != '\0') {
unsigned ELen;
static int GetBranchDist (CodeSeg* S, unsigned From, CodeEntry* To)
/* Get the branch distance between the two entries and return it. The distance
- * will be negative for backward jumps and positive for forward jumps.
- */
+** will be negative for backward jumps and positive for forward jumps.
+*/
{
/* Get the index of the branch target */
unsigned TI = CS_GetEntryIndex (S, To);
/* Get the jump target and the next entry. There's always a next
- * entry, because we don't cover the last entry in the loop.
- */
+ ** entry, because we don't cover the last entry in the loop.
+ */
CodeEntry* X = 0;
CodeEntry* T = E->JumpTo->Owner;
CodeEntry* N = CS_GetNextEntry (S, I);
if (T->OPC == OP65_RTS) {
/* It's a jump to RTS. Create a conditional branch around an
- * RTS insn.
- */
+ ** RTS insn.
+ */
X = NewCodeEntry (OP65_RTS, AM65_IMP, 0, 0, T->LI);
} else if (T->OPC == OP65_JMP && T->JumpTo == 0) {
/* It's a jump to a label outside the function. Create a
- * conditional branch around a jump to the external label.
- */
+ ** conditional branch around a jump to the external label.
+ */
X = NewCodeEntry (OP65_JMP, AM65_ABS, T->Arg, T->JumpTo, T->LI);
}
CS_InsertEntry (S, X, I+1);
/* Create a conditional branch with the inverse condition
- * around the replacement insn
- */
+ ** around the replacement insn
+ */
/* Get the new branch opcode */
NewBranch = MakeShortBranch (GetInverseBranch (E->OPC));
CodeEntry* E = CS_GetEntry (S, I);
/* Check if it's a branch, if it has a local target, and if the target
- * is the next instruction.
- */
+ ** is the next instruction.
+ */
if (E->AM == AM65_BRA &&
E->JumpTo &&
E->JumpTo->Owner == CS_GetNextEntry (S, I)) {
unsigned OptDeadCode (CodeSeg* S)
/* Remove dead code (code that follows an unconditional jump or an rts/rti
- * and has no label)
- */
+** and has no label)
+*/
{
unsigned Changes = 0;
CodeEntry* E = CS_GetEntry (S, I);
/* Check if it's an unconditional branch, and if the next entry has
- * no labels attached, or if the label is just used so that the insn
- * can jump to itself.
- */
+ ** no labels attached, or if the label is just used so that the insn
+ ** can jump to itself.
+ */
if ((E->Info & OF_DEAD) != 0 && /* Dead code follows */
(N = CS_GetNextEntry (S, I)) != 0 && /* Has next entry */
(!CE_HasLabel (N) || /* Don't has a label */
unsigned OptJumpCascades (CodeSeg* S)
/* Optimize jump cascades (jumps to jumps). In such a case, the jump is
- * replaced by a jump to the final location. This will in some cases produce
- * worse code, because some jump targets are no longer reachable by short
- * branches, but this is quite rare, so there are more advantages than
- * disadvantages.
- */
+** replaced by a jump to the final location. This will in some cases produce
+** worse code, because some jump targets are no longer reachable by short
+** branches, but this is quite rare, so there are more advantages than
+** disadvantages.
+*/
{
unsigned Changes = 0;
CodeEntry* E = CS_GetEntry (S, I);
/* Check:
- * - if it's a branch,
- * - if it has a jump label,
- * - if this jump label is not attached to the instruction itself,
- * - if the target instruction is itself a branch,
- * - if either the first branch is unconditional or the target of
- * the second branch is internal to the function.
- * The latter condition will avoid conditional branches to targets
- * outside of the function (usually incspx), which won't simplify the
- * code, since conditional far branches are emulated by a short branch
- * around a jump.
- */
+ ** - if it's a branch,
+ ** - if it has a jump label,
+ ** - if this jump label is not attached to the instruction itself,
+ ** - if the target instruction is itself a branch,
+ ** - if either the first branch is unconditional or the target of
+ ** the second branch is internal to the function.
+ ** The latter condition will avoid conditional branches to targets
+ ** outside of the function (usually incspx), which won't simplify the
+ ** code, since conditional far branches are emulated by a short branch
+ ** around a jump.
+ */
if ((E->Info & OF_BRA) != 0 &&
(OldLabel = E->JumpTo) != 0 &&
(N = OldLabel->Owner) != E &&
((E->Info & OF_CBRA) == 0 ||
N->JumpTo != 0)) {
- /* Check if we can use the final target label. This is the case,
- * if the target branch is an absolut branch, or if it is a
- * conditional branch checking the same condition as the first one.
- */
+ /* Check if we can use the final target label. That is the case,
+ ** if the target branch is an absolute branch; or, if it is a
+ ** conditional branch checking the same condition as the first one.
+ */
if ((N->Info & OF_UBRA) != 0 ||
((E->Info & OF_CBRA) != 0 &&
GetBranchCond (E->OPC) == GetBranchCond (N->OPC))) {
/* This is a jump cascade and we may jump to the final target,
- * provided that the other insn does not jump to itself. If
- * this is the case, we can also jump to ourselves, otherwise
- * insert a jump to the new instruction and remove the old one.
- */
+ ** provided that the other insn does not jump to itself. If
+ ** this is the case, we can also jump to ourselves, otherwise
+ ** insert a jump to the new instruction and remove the old one.
+ */
CodeEntry* X;
CodeLabel* LN = N->JumpTo;
if (LN != 0 && LN->Owner == N) {
/* We found a jump to a jump to itself. Replace our jump
- * by a jump to itself.
- */
+ ** by a jump to itself.
+ */
CodeLabel* LE = CS_GenLabel (S, E);
X = NewCodeEntry (E->OPC, E->AM, LE->Name, LE, E->LI);
++Changes;
/* Check if both are conditional branches, and the condition of
- * the second is the inverse of that of the first. In this case,
- * the second branch will never be taken, and we may jump directly
- * to the instruction behind this one.
- */
+ ** the second is the inverse of that of the first. In this case,
+ ** the second branch will never be taken, and we may jump directly
+ ** to the instruction behind this one.
+ */
} else if ((E->Info & OF_CBRA) != 0 && (N->Info & OF_CBRA) != 0) {
CodeEntry* X; /* Instruction behind N */
}
/* We may jump behind this conditional branch. Get the
- * pointer to the next instruction
- */
+ ** pointer to the next instruction
+ */
if ((X = CS_GetNextEntry (S, CS_GetEntryIndex (S, N))) == 0) {
/* N is the last entry, bail out */
goto NextEntry;
unsigned OptRTS (CodeSeg* S)
/* Optimize subroutine calls followed by an RTS. The subroutine call will get
- * replaced by a jump. Don't bother to delete the RTS if it does not have a
- * label, the dead code elimination should take care of it.
- */
+** replaced by a jump. Don't bother to delete the RTS if it does not have a
+** label, the dead code elimination should take care of it.
+*/
{
unsigned Changes = 0;
unsigned OptJumpTarget1 (CodeSeg* S)
/* If the instruction preceeding an unconditional branch is the same as the
- * instruction preceeding the jump target, the jump target may be moved
- * one entry back. This is a size optimization, since the instruction before
- * the branch gets removed.
- */
+** instruction preceeding the jump target, the jump target may be moved
+** one entry back. This is a size optimization, since the instruction before
+** the branch gets removed.
+*/
{
unsigned Changes = 0;
CodeEntry* E1; /* Entry 1 */
E2 = CS_GetNextEntry (S, I);
/* Check if we have a jump or branch without a label attached, and
- * a jump target, which is not attached to the jump itself
- */
+ ** a jump target, which is not attached to the jump itself
+ */
if (E2 != 0 &&
(E2->Info & OF_UBRA) != 0 &&
!CE_HasLabel (E2) &&
}
/* The entry preceeding the branch target may not be the branch
- * insn.
- */
+ ** insn.
+ */
if (T1 == E2) {
goto NextEntry;
}
}
/* Get the label for the instruction preceeding the jump target.
- * This routine will create a new label if the instruction does
- * not already have one.
- */
+ ** This routine will create a new label if the instruction does
+ ** not already have one.
+ */
TL1 = CS_GenLabel (S, T1);
/* Change the jump target to point to this new label */
CS_MoveLabelRef (S, E2, TL1);
/* If the instruction preceeding the jump has labels attached,
- * move references to this label to the new label.
- */
+ ** move references to this label to the new label.
+ */
if (CE_HasLabel (E1)) {
CS_MoveLabels (S, E1, T1);
}
unsigned OptJumpTarget2 (CodeSeg* S)
/* If a bcs jumps to a sec insn or a bcc jumps to clc, skip this insn, since
- * it's job is already done.
- */
+** it's job is already done.
+*/
{
unsigned Changes = 0;
}
/* Get the owner insn of the jump target and check if it's the one, we
- * will skip if present.
- */
+ ** will skip if present.
+ */
T = E->JumpTo->Owner;
if (T->OPC != OPC) {
goto NextEntry;
}
/* Get the label for the instruction following the jump target.
- * This routine will create a new label if the instruction does
- * not already have one.
- */
+ ** This routine will create a new label if the instruction does
+ ** not already have one.
+ */
L = CS_GenLabel (S, N);
/* Change the jump target to point to this new label */
unsigned OptJumpTarget3 (CodeSeg* S)
/* Jumps to load instructions of a register, that do already have the matching
- * register contents may skip the load instruction, since it's job is already
- * done.
- */
+** register contents may skip the load instruction, since it's job is already
+** done.
+*/
{
unsigned Changes = 0;
unsigned I;
CodeEntry* E = CS_GetEntry (S, I);
/* Check if this is a load insn with a label and the next insn is not
- * a conditional branch that needs the flags from the load.
- */
+ ** a conditional branch that needs the flags from the load.
+ */
if ((E->Info & OF_LOAD) != 0 &&
CE_IsConstImm (E) &&
CE_HasLabel (E) &&
CodeLabel* L = CE_GetLabel (E, J);
/* Loop over all insn that reference this label. Since we may
- * eventually remove a reference in the loop, we must loop
- * from end down to start.
- */
+ ** eventually remove a reference in the loop, we must loop
+ ** from end down to start.
+ */
for (K = CL_GetRefCount (L) - 1; K >= 0; --K) {
/* Get the entry that jumps here */
/* Check if the outgoing value is the one thats's loaded */
if (Val == (unsigned char) E->Num) {
- /* Ok, skip the insn. First, generate a label for the
- * next insn after E.
- */
+ /* OK, skip the insn. First, generate a label for the
+ ** next insn after E.
+ */
if (LN == 0) {
LN = CS_GenLabel (S, N);
}
unsigned OptCondBranches1 (CodeSeg* S)
/* Performs several optimization steps:
- *
- * - If an immidiate load of a register is followed by a conditional jump that
- * is never taken because the load of the register sets the flags in such a
- * manner, remove the conditional branch.
- * - If the conditional branch is always taken because of the register load,
- * replace it by a jmp.
- * - If a conditional branch jumps around an unconditional branch, remove the
- * conditional branch and make the jump a conditional branch with the
- * inverse condition of the first one.
- */
+**
+** - If an immediate load of a register is followed by a conditional jump that
+** is never taken because the load of the register sets the flags in such a
+** manner, remove the conditional branch.
+** - If the conditional branch is always taken because of the register load,
+** replace it by a jmp.
+** - If a conditional branch jumps around an unconditional branch, remove the
+** conditional branch and make the jump a conditional branch with the
+** inverse condition of the first one.
+*/
{
unsigned Changes = 0;
(N = CS_GetNextEntry (S, I)) != 0 && /* There is a following entry */
(N->Info & OF_UBRA) != 0 && /* ..which is an uncond branch, */
!CE_HasLabel (N) && /* ..has no label attached */
- L->Owner == CS_GetNextEntry (S, I+1)) {/* ..and jump target follows */
+ L->Owner == CS_GetNextEntry (S, I+1)) { /* ..and jump target follows */
/* Replace the jump by a conditional branch with the inverse branch
- * condition than the branch around it.
- */
+ ** condition than the branch around it.
+ */
CE_ReplaceOPC (N, GetInverseBranch (E->OPC));
/* Remove the conditional branch */
unsigned OptCondBranches2 (CodeSeg* S)
/* If on entry to a "rol a" instruction the accu is zero, and a beq/bne follows,
- * we can remove the rol and branch on the state of the carry flag.
- */
+** we can remove the rol and branch on the state of the carry flag.
+*/
{
unsigned Changes = 0;
unsigned I;
(E->Chg & REG_ZP) != 0) {
/* Check for the zero page location. We know that there cannot be
- * more than one zero page location involved in the store.
- */
+ ** more than one zero page location involved in the store.
+ */
unsigned R = E->Chg & REG_ZP;
/* Get register usage and check if the register value is used later */
case OP65_STA:
/* If we store into a known zero page location, and this
- * location does already contain the value to be stored,
- * remove the store.
- */
+ ** location does already contain the value to be stored,
+ ** remove the store.
+ */
if (RegValIsKnown (In->RegA) && /* Value of A is known */
E->AM == AM65_ZP && /* Store into zp */
In->RegA == ZPRegVal (E->Chg, In)) { /* Value identical */
case OP65_STX:
/* If we store into a known zero page location, and this
- * location does already contain the value to be stored,
- * remove the store.
- */
+ ** location does already contain the value to be stored,
+ ** remove the store.
+ */
if (RegValIsKnown (In->RegX) && /* Value of A is known */
E->AM == AM65_ZP && /* Store into zp */
In->RegX == ZPRegVal (E->Chg, In)) { /* Value identical */
Delete = 1;
/* If the value in the X register is known and the same as
- * that in the A register, replace the store by a STA. The
- * optimizer will then remove the load instruction for X
- * later. STX does support the zeropage,y addressing mode,
- * so be sure to check for that.
- */
+ ** that in the A register, replace the store by a STA. The
+ ** optimizer will then remove the load instruction for X
+ ** later. STX does support the zeropage,y addressing mode,
+ ** so be sure to check for that.
+ */
} else if (RegValIsKnown (In->RegX) &&
In->RegX == In->RegA &&
E->AM != AM65_ABSY &&
case OP65_STY:
/* If we store into a known zero page location, and this
- * location does already contain the value to be stored,
- * remove the store.
- */
+ ** location does already contain the value to be stored,
+ ** remove the store.
+ */
if (RegValIsKnown (In->RegY) && /* Value of Y is known */
E->AM == AM65_ZP && /* Store into zp */
In->RegY == ZPRegVal (E->Chg, In)) { /* Value identical */
Delete = 1;
/* If the value in the Y register is known and the same as
- * that in the A register, replace the store by a STA. The
- * optimizer will then remove the load instruction for Y
- * later. If replacement by A is not possible try a
- * replacement by X, but check for invalid addressing modes
- * in this case.
- */
+ ** that in the A register, replace the store by a STA. The
+ ** optimizer will then remove the load instruction for Y
+ ** later. If replacement by A is not possible try a
+ ** replacement by X, but check for invalid addressing modes
+ ** in this case.
+ */
} else if (RegValIsKnown (In->RegY)) {
if (In->RegY == In->RegA) {
CE_ReplaceOPC (E, OP65_STA);
case OP65_STZ:
/* If we store into a known zero page location, and this
- * location does already contain the value to be stored,
- * remove the store.
- */
+ ** location does already contain the value to be stored,
+ ** remove the store.
+ */
if ((CPUIsets[CPU] & CPU_ISET_65SC02) != 0 && E->AM == AM65_ZP) {
if (ZPRegVal (E->Chg, In) == 0) {
Delete = 1;
CodeEntry* E = CS_GetEntry (S, I);
/* Check if it is a store instruction followed by a load from the
- * same address which is itself not followed by a conditional branch.
- */
+ ** same address which is itself not followed by a conditional branch.
+ */
if ((E->Info & OF_STORE) != 0 &&
(N = CS_GetNextEntry (S, I)) != 0 &&
!CE_HasLabel (N) &&
(E->OPC == OP65_TYA && N->OPC == OP65_TAY && !RegAUsed (S, I+2))) {
/* If the next insn is a conditional branch, check if the insn
- * preceeding the first xfr will set the flags right, otherwise we
- * may not remove the sequence.
- */
+ ** preceeding the first xfr will set the flags right, otherwise we
+ ** may not remove the sequence.
+ */
if ((X = CS_GetNextEntry (S, I+1)) == 0) {
goto NextEntry;
}
unsigned OptTransfers2 (CodeSeg* S)
/* Replace loads followed by a register transfer by a load with the second
- * register if possible.
- */
+** register if possible.
+*/
{
unsigned Changes = 0;
CodeEntry* E = CS_GetEntry (S, I);
/* Check if we have a load followed by a transfer where the loaded
- * register is not used later.
- */
+ ** register is not used later.
+ */
if ((E->Info & OF_LOAD) != 0 &&
(N = CS_GetNextEntry (S, I)) != 0 &&
!CE_HasLabel (N) &&
X = NewCodeEntry (OP65_LDA, E->AM, E->Arg, 0, N->LI);
} else if (E->OPC == OP65_LDX && N->OPC == OP65_TXA) {
/* LDX/TXA. LDA doesn't support zp,y, so we must map it to
- * abs,y instead.
- */
+ ** abs,y instead.
+ */
am_t AM = (E->AM == AM65_ZPY)? AM65_ABSY : E->AM;
X = NewCodeEntry (OP65_LDA, AM, E->Arg, 0, N->LI);
}
unsigned OptTransfers3 (CodeSeg* S)
/* Replace a register transfer followed by a store of the second register by a
- * store of the first register if this is possible.
- */
+** store of the first register if this is possible.
+*/
{
unsigned Changes = 0;
unsigned UsedRegs = REG_NONE; /* Track used registers */
} State = Initialize;
/* Walk over the entries. Look for a xfer instruction that is followed by
- * a store later, where the value of the register is not used later.
- */
+ ** a store later, where the value of the register is not used later.
+ */
unsigned I = 0;
while (I < CS_GetEntryCount (S)) {
case FoundXfer:
/* If we find a conditional jump, abort the sequence, since
- * handling them makes things really complicated.
- */
+ ** handling them makes things really complicated.
+ */
if (E->Info & OF_CBRA) {
/* Switch back to searching */
} else if ((E->Use & XferEntry->Chg) != 0) {
/* It it's a store instruction, and the block is a basic
- * block, proceed. Otherwise restart
- */
+ ** block, proceed. Otherwise restart
+ */
if ((E->Info & OF_STORE) != 0 &&
CS_IsBasicBlock (S, Xfer, I)) {
Store = I;
} else if (E->Chg & XferEntry->Chg) {
/* We *may* add code here to remove the transfer, but I'm
- * currently not sure about the consequences, so I won't
- * do that and bail out instead.
- */
+ ** currently not sure about the consequences, so I won't
+ ** do that and bail out instead.
+ */
I = Xfer;
State = Initialize;
case FoundStore:
/* We are at the instruction behind the store. If the register
- * isn't used later, and we have an address mode match, we can
- * replace the transfer by a store and remove the store here.
- */
+ ** isn't used later, and we have an address mode match, we can
+ ** replace the transfer by a store and remove the store here.
+ */
if ((GetRegInfo (S, I, XferEntry->Chg) & XferEntry->Chg) == 0 &&
(StoreEntry->AM == AM65_ABS ||
StoreEntry->AM == AM65_ZP) &&
unsigned OptTransfers4 (CodeSeg* S)
/* Replace a load of a register followed by a transfer insn of the same register
- * by a load of the second register if possible.
- */
+** by a load of the second register if possible.
+*/
{
unsigned Changes = 0;
unsigned Load = 0; /* Index of load insn */
} State = Search;
/* Walk over the entries. Look for a load instruction that is followed by
- * a load later.
- */
+ ** a load later.
+ */
unsigned I = 0;
while (I < CS_GetEntryCount (S)) {
case FoundLoad:
/* If we find a conditional jump, abort the sequence, since
- * handling them makes things really complicated.
- */
+ ** handling them makes things really complicated.
+ */
if (E->Info & OF_CBRA) {
/* Switch back to searching */
} else if ((E->Use & LoadEntry->Chg) != 0) {
/* It it's a xfer instruction, and the block is a basic
- * block, proceed. Otherwise restart
- */
+ ** block, proceed. Otherwise restart
+ */
if ((E->Info & OF_XFR) != 0 &&
CS_IsBasicBlock (S, Load, I)) {
Xfer = I;
} else if (E->Chg & LoadEntry->Chg) {
/* We *may* add code here to remove the load, but I'm
- * currently not sure about the consequences, so I won't
- * do that and bail out instead.
- */
+ ** currently not sure about the consequences, so I won't
+ ** do that and bail out instead.
+ */
I = Load;
State = Search;
}
case FoundXfer:
/* We are at the instruction behind the xfer. If the register
- * isn't used later, and we have an address mode match, we can
- * replace the transfer by a load and remove the initial load.
- */
+ ** isn't used later, and we have an address mode match, we can
+ ** replace the transfer by a load and remove the initial load.
+ */
if ((GetRegInfo (S, I, LoadEntry->Chg) & LoadEntry->Chg) == 0 &&
(LoadEntry->AM == AM65_ABS ||
LoadEntry->AM == AM65_ZP ||
} State = Searching;
/* Walk over the entries. Look for a push instruction that is followed by
- * a pop later, where the pop is not followed by an conditional branch,
- * and where the value of the A register is not used later on.
- * Look out for the following problems:
- *
- * - There may be another PHA/PLA inside the sequence: Restart it.
- * - If the PLA has a label, all jumps to this label must be inside
- * the sequence, otherwise we cannot remove the PHA/PLA.
- */
+ ** a pop later, where the pop is not followed by an conditional branch,
+ ** and where the value of the A register is not used later on.
+ ** Look out for the following problems:
+ **
+ ** - There may be another PHA/PLA inside the sequence: Restart it.
+ ** - If the PLA has a label, all jumps to this label must be inside
+ ** the sequence, otherwise we cannot remove the PHA/PLA.
+ */
unsigned I = 0;
while (I < CS_GetEntryCount (S)) {
/* Found a matching pop */
Pop = I;
/* Check that the block between Push and Pop is a basic
- * block (one entry, one exit). Otherwise ignore it.
- */
+ ** block (one entry, one exit). Otherwise ignore it.
+ */
if (CS_IsBasicBlock (S, Push, Pop)) {
State = FoundPop;
} else {
case FoundPop:
/* We're at the instruction after the PLA.
- * Check for the following conditions:
- * - If this instruction is a store of A that doesn't use
- * another register, if the instruction does not have a
- * label, and A is not used later, we may replace the PHA
- * by the store and remove pla if several other conditions
- * are met.
- * - If this instruction is not a conditional branch, and A
- * is either unused later, or not changed by the code
- * between push and pop, we may remove PHA and PLA.
- */
+ ** Check for the following conditions:
+ ** - If this instruction is a store of A that doesn't use
+ ** another register, if the instruction does not have a
+ ** label, and A is not used later, we may replace the PHA
+ ** by the store and remove pla if several other conditions
+ ** are met.
+ ** - If this instruction is not a conditional branch, and A
+ ** is either unused later, or not changed by the code
+ ** between push and pop, we may remove PHA and PLA.
+ */
if (E->OPC == OP65_STA &&
(E->AM == AM65_ABS || E->AM == AM65_ZP) &&
!CE_HasLabel (E) &&
unsigned OptPrecalc (CodeSeg* S)
/* Replace immediate operations with the accu where the current contents are
- * known by a load of the final value.
- */
+** known by a load of the final value.
+*/
{
unsigned Changes = 0;
unsigned I;
case OP65_ADC:
case OP65_SBC:
/* If this is an operation with an immediate operand of zero,
- * and the register is zero, the operation won't give us any
- * results we don't already have (including the flags), so
- * remove it. Something like this is generated as a result of
- * a compare where parts of the values are known to be zero.
- */
+ ** and the register is zero, the operation won't give us any
+ ** results we don't already have (including the flags), so
+ ** remove it. Something like this is generated as a result of
+ ** a compare where parts of the values are known to be zero.
+ */
if (In->RegA == 0 && CE_IsKnownImm (E, 0x00)) {
/* 0-0 or 0+0 -> remove */
CS_DelEntry (S, I);
unsigned OptIndLoads1 (CodeSeg* S)
/* Change
- *
- * lda (zp),y
- *
- * into
- *
- * lda (zp,x)
- *
- * provided that x and y are both zero.
- */
+**
+** lda (zp),y
+**
+** into
+**
+** lda (zp,x)
+**
+** provided that x and y are both zero.
+*/
{
unsigned Changes = 0;
unsigned I;
unsigned OptIndLoads2 (CodeSeg* S)
/* Change
- *
- * lda (zp,x)
- *
- * into
- *
- * lda (zp),y
- *
- * provided that x and y are both zero.
- */
+**
+** lda (zp,x)
+**
+** into
+**
+** lda (zp),y
+**
+** provided that x and y are both zero.
+*/
{
unsigned Changes = 0;
unsigned I;