MWCC/compiler_and_linker/unsorted/VectorArraysToRegs.c

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C
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#include "compiler/VectorArraysToRegs.h"
#include "compiler/CError.h"
#include "compiler/CFunc.h"
#include "compiler/BitVectors.h"
#include "compiler/CompilerTools.h"
#include "compiler/PCode.h"
#include "compiler/PCodeInfo.h"
#include "compiler/Registers.h"
#include "compiler/UseDefChains.h"
#include "compiler/objects.h"
#include "compiler/types.h"
typedef struct LocalVectorArray {
struct LocalVectorArray *next;
Object *object;
unsigned int invalid:1;
SInt32 arraySize;
SInt32 elementCount;
int totalUses;
int elements[1];
} LocalVectorArray;
typedef struct VectorPropInfo {
UInt32 *use;
UInt32 *def;
UInt32 *in;
UInt32 *out;
} VectorPropInfo;
typedef struct ADDI {
PCode *instr;
RegUseOrDef *list;
} ADDI;
static int number_of_ADDIs;
static ADDI *ADDIs;
static VectorPropInfo *vectorpropinfo;
static int *naddsinblock;
static int *firstaddinblock;
static Boolean converted_arrays;
static LocalVectorArray *scanforlocalvectorarrays(void) {
SInt32 elementCount;
LocalVectorArray *head;
LocalVectorArray *array;
ObjectList *list;
int i;
SInt32 arraySize;
head = NULL;
for (list = locals; list; list = list->next) {
if (
list->object &&
!(IS_TYPE_POINTER(list->object->type) ? (TPTR_QUAL(list->object->type) & Q_VOLATILE) : (list->object->qual & Q_VOLATILE)) &&
list->object->type &&
IS_TYPE_ARRAY(list->object->type) &&
IS_TYPE_VECTOR(TPTR_TARGET(list->object->type))
) {
arraySize = list->object->type->size;
elementCount = arraySize / 16;
if (elementCount > 0 && elementCount <= 8) {
array = oalloc(sizeof(int) * (elementCount - 1) + sizeof(LocalVectorArray));
array->next = head;
head = array;
array->object = list->object;
array->arraySize = arraySize;
array->elementCount = elementCount;
array->totalUses = 0;
array->invalid = 0;
for (i = 0; i < elementCount; i++) {
array->elements[i] = 0;
}
}
}
}
return head;
}
static LocalVectorArray *lookup_vector_array_object(LocalVectorArray *arrays, Object *object) {
while (arrays) {
if (arrays->object == object)
return arrays;
arrays = arrays->next;
}
return NULL;
}
static void scaninstructions(LocalVectorArray *arrays) {
PCodeBlock *block;
PCode *instr;
int counter;
int i;
PCodeArg *op;
LocalVectorArray *array;
int element;
naddsinblock = oalloc(sizeof(int) * pcblockcount);
memclrw(naddsinblock, sizeof(int) * pcblockcount);
firstaddinblock = oalloc(sizeof(int) * pcblockcount);
memclrw(firstaddinblock, sizeof(int) * pcblockcount);
number_of_ADDIs = 0;
for (block = pcbasicblocks; block; block = block->nextBlock) {
firstaddinblock[block->blockIndex] = number_of_ADDIs;
counter = 0;
for (instr = block->firstPCode; instr; instr = instr->nextPCode) {
if (!(instr->flags & fPCodeFlag1) && instr->argCount) {
op = instr->args;
i = instr->argCount;
while (i--) {
if (
op->kind == PCOp_MEMORY &&
(PCOpMemoryArg) op->arg == PCOpMemory1 &&
(array = lookup_vector_array_object(arrays, op->data.mem.obj)) &&
!array->invalid
)
{
if (instr->op != PC_ADDI) {
array->invalid = 1;
} else if (instr->args[0].data.reg.reg < n_real_registers[RegClass_GPR]) {
array->invalid = 1;
} else {
number_of_ADDIs++;
counter++;
}
if (!array->invalid) {
element = op->data.mem.offset / 16;
if (element < array->elementCount)
array->elements[element]++;
else
array->invalid = 1;
}
}
op++;
}
}
}
naddsinblock[block->blockIndex] = counter;
}
}
static void computeaddilist(LocalVectorArray *arrays) {
PCodeBlock *block;
PCode *instr;
RegUseOrDef *list;
ADDI *addi;
UInt32 *vec;
LocalVectorArray *array;
UseOrDef *def;
int defID;
UseOrDef *use;
int useID;
ADDIs = oalloc(sizeof(ADDI) * number_of_ADDIs);
memclrw(ADDIs, sizeof(ADDI) * number_of_ADDIs);
vec = oalloc(4 * ((number_of_Uses + 31) >> 5));
for (block = pcbasicblocks; block; block = block->nextBlock) {
if (naddsinblock[block->blockIndex]) {
bitvectorcopy(vec, usedefinfo[block->blockIndex].usevec1C, number_of_Uses);
addi = &ADDIs[firstaddinblock[block->blockIndex] + naddsinblock[block->blockIndex] - 1];
for (instr = block->lastPCode; instr; instr = instr->prevPCode) {
if (!(instr->flags & fPCodeFlag1) && instr->argCount) {
int reg; // r18
if (
instr->op == PC_ADDI &&
(reg = instr->args[0].data.reg.reg) >= n_real_registers[RegClass_GPR] &&
instr->args[2].kind == PCOp_MEMORY &&
(PCOpMemoryArg) instr->args[2].arg == PCOpMemory1 &&
(array = lookup_vector_array_object(arrays, instr->args[2].data.mem.obj)) &&
!array->invalid
)
{
addi->instr = instr;
addi->list = NULL;
for (list = reg_Uses[RegClass_GPR][reg]; list; list = list->next) {
if (bitvectorgetbit(list->id, vec)) {
RegUseOrDef *node = oalloc(sizeof(RegUseOrDef));
node->id = list->id;
node->next = addi->list;
addi->list = node;
}
}
addi--;
}
for (def = &Defs[defID = instr->defID]; defID < number_of_Defs && def->pcode == instr; def++, defID++) {
if (def->v.kind == PCOp_REGISTER) {
RegUseOrDef *l;
for (l = reg_Uses[def->v.arg][def->v.u.reg]; l; l = l->next)
bitvectorclearbit(l->id, vec);
}
}
for (use = &Uses[useID = instr->useID]; useID < number_of_Uses && use->pcode == instr; use++, useID++) {
if (use->v.kind == PCOp_REGISTER)
bitvectorsetbit(useID, vec);
}
}
}
}
}
}
static void allocatevectorpropinfo(void) {
VectorPropInfo *info;
int i;
vectorpropinfo = oalloc(sizeof(VectorPropInfo) * pcblockcount);
for (i = 0, info = vectorpropinfo; i < pcblockcount; i++, info++) {
info->use = oalloc(4 * ((number_of_ADDIs + 31) >> 5));
info->def = oalloc(4 * ((number_of_ADDIs + 31) >> 5));
info->in = oalloc(4 * ((number_of_ADDIs + 31) >> 5));
info->out = oalloc(4 * ((number_of_ADDIs + 31) >> 5));
}
}
static void computelocalvectorpropinfo(LocalVectorArray *arrays) {
VectorPropInfo *info;
PCodeBlock *block;
PCode *instr;
UInt32 *vec0;
UInt32 *vec4;
int index;
PCodeArg *op;
int i;
int addi_i;
ADDI *addi;
LocalVectorArray *array;
for (block = pcbasicblocks; block; block = block->nextBlock) {
info = &vectorpropinfo[block->blockIndex];
vec0 = info->use;
vec4 = info->def;
bitvectorinitialize(vec0, number_of_ADDIs, 0);
bitvectorinitialize(vec4, number_of_ADDIs, 0);
index = firstaddinblock[block->blockIndex];
for (instr = block->firstPCode; instr; instr = instr->nextPCode) {
if (!(instr->flags & fPCodeFlag1) && instr->argCount) {
i = instr->argCount;
op = instr->args;
while (i--) {
if (op->kind == PCOp_REGISTER && op->arg == RegClass_GPR && (op->data.reg.effect & EffectWrite)) {
for (addi_i = 0, addi = ADDIs; addi_i < number_of_ADDIs; addi_i++, addi++) {
if (
addi->instr &&
addi->instr->args[0].arg == op->arg &&
addi->instr->args[0].data.reg.reg == op->data.reg.reg
)
{
if (addi->instr->block == block)
bitvectorclearbit(addi_i, vec0);
else
bitvectorsetbit(addi_i, vec4);
}
}
}
op++;
}
if (
instr->op == PC_ADDI &&
instr->args[2].kind == PCOp_MEMORY &&
(PCOpMemoryArg) instr->args[2].arg == PCOpMemory1 &&
(array = lookup_vector_array_object(arrays, instr->args[2].data.mem.obj)) &&
!array->invalid
)
{
bitvectorsetbit(index, vec0);
index++;
}
}
}
}
}
static void computeglobalvectorpropinfo(void) {
VectorPropInfo *info;
PCodeBlock *block;
UInt32 *vec0;
UInt32 *vec4;
UInt32 *vec8;
UInt32 *vecC;
int bitvecsize;
int blockIndex;
int i;
int j;
int flag;
PCLink *preds;
UInt32 val;
bitvecsize = (number_of_ADDIs + 31) >> 5;
flag = 1;
info = &vectorpropinfo[pcbasicblocks->blockIndex];
bitvectorinitialize(info->in, number_of_ADDIs, 0);
bitvectorcopy(info->out, info->use, number_of_ADDIs);
for (block = pcbasicblocks->nextBlock; block; block = block->nextBlock) {
info = &vectorpropinfo[block->blockIndex];
vecC = info->out;
vec4 = info->def;
for (i = 0; i < bitvecsize; vecC++, vec4++, i++)
*vecC = ~*vec4;
}
while (flag) {
flag = 0;
for (blockIndex = 0; blockIndex < pcblockcount; blockIndex++) {
if (depthfirstordering[blockIndex]) {
info = &vectorpropinfo[depthfirstordering[blockIndex]->blockIndex];
if ((preds = depthfirstordering[blockIndex]->predecessors)) {
vec8 = info->in;
bitvectorcopy(vec8, vectorpropinfo[preds->block->blockIndex].out, number_of_ADDIs);
for (preds = preds->nextLink; preds; preds = preds->nextLink)
bitvectorintersect(vec8, vectorpropinfo[preds->block->blockIndex].out, number_of_ADDIs);
}
vecC = info->out;
vec8 = info->in;
vec0 = info->use;
vec4 = info->def;
for (j = 0; j < bitvecsize; j++) {
val = *vec0 | (*vec8 & ~*vec4);
if (val != *vecC) {
*vecC = val;
flag = 1;
}
vec8++;
vecC++;
vec4++;
vec0++;
}
}
}
}
}
static int precedes(PCode *a, PCode *b) {
PCode *scan;
for (scan = a->nextPCode; scan; scan = scan->nextPCode) {
if (scan == b)
return 1;
}
return 0;
}
static int checkvectorstoreorload(int addiID, int useID) {
PCode *addiInstr;
UseOrDef *use;
addiInstr = ADDIs[addiID].instr;
use = Uses + useID;
if (!addiInstr)
return 0;
if (addiInstr->args[0].data.reg.reg < n_real_registers[RegClass_GPR])
return 0;
if (use->pcode->op != PC_LVX && use->pcode->op != PC_STVX)
return 0;
if (
use->pcode->args[1].kind != PCOp_REGISTER ||
use->pcode->args[1].arg != RegClass_GPR ||
use->pcode->args[1].data.reg.reg != 0
)
return 0;
return use->pcode->args[2].data.reg.reg == addiInstr->args[0].data.reg.reg;
}
static int checkalluses(LocalVectorArray *arrays, int addiID) {
RegUseOrDef *list;
PCode *instr;
LocalVectorArray *array;
instr = ADDIs[addiID].instr;
for (list = ADDIs[addiID].list; list; list = list->next) {
if (list && !checkvectorstoreorload(addiID, list->id)) {
array = lookup_vector_array_object(arrays, instr->args[2].data.mem.obj);
array->invalid = 1;
return 0;
}
}
return 1;
}
static void convert_array_to_register(LocalVectorArray *arrays, int addiID) {
ADDI *addi;
int newReg;
RegUseOrDef *list;
PCode *instr;
PCode *useInstr;
LocalVectorArray *array;
int element;
addi = ADDIs + addiID;
if (!(instr = addi->instr))
return;
if (
!(array = lookup_vector_array_object(arrays, instr->args[2].data.mem.obj)) ||
array->invalid
)
return;
element = instr->args[2].data.mem.offset / 16;
if (element > array->elementCount)
return;
newReg = array->elements[element];
for (list = addi->list; list; list = list->next) {
useInstr = Uses[list->id].pcode;
if (useInstr->op == PC_LVX) {
converted_arrays = 1;
change_opcode(useInstr, PC_VMR);
change_num_operands(useInstr, 2);
useInstr->args[1].kind = PCOp_REGISTER;
useInstr->args[1].arg = RegClass_VR;
useInstr->args[1].data.reg.reg = newReg;
useInstr->args[1].data.reg.effect = EffectRead;
} else if (useInstr->op == PC_STVX) {
converted_arrays = 1;
change_opcode(useInstr, PC_VMR);
change_num_operands(useInstr, 2);
useInstr->args[1] = useInstr->args[0];
useInstr->args[0].kind = PCOp_REGISTER;
useInstr->args[0].arg = RegClass_VR;
useInstr->args[0].data.reg.reg = newReg;
useInstr->args[0].data.reg.effect = EffectWrite;
} else {
#line 661
CError_FATAL();
}
}
deletepcode(addi->instr);
}
static void convert_arrays_to_registers(LocalVectorArray *arrays) {
int i;
int counter;
LocalVectorArray **ptr;
LocalVectorArray *array;
for (i = 0; i < number_of_ADDIs; i++)
checkalluses(arrays, i);
counter = 0;
ptr = &arrays;
array = *ptr;
while (array) {
if (array->invalid) {
*ptr = array->next;
array = *ptr;
continue;
}
counter += array->elementCount;
for (i = 0; i < array->elementCount; i++)
array->totalUses += array->elements[i];
array = array->next;
}
if (arrays) {
while (counter > 32) {
LocalVectorArray *best;
int score;
score = 0;
best = NULL;
for (array = arrays; array; array = array->next) {
if (best) {
if (array->totalUses < score) {
score = array->totalUses;
best = array;
}
} else {
best = array;
score = array->totalUses;
}
}
if (!best)
break;
if (best == arrays) {
arrays = best->next;
} else {
for (array = arrays; array; array = array->next) {
if (array->next == best) {
array->next = best->next;
break;
}
}
}
counter -= best->elementCount;
}
if (!(array = arrays))
return;
while (array) {
for (i = 0; i < array->elementCount; i++)
array->elements[i] = used_virtual_registers[RegClass_VR]++;
array = array->next;
}
if (arrays) {
for (i = 0; i < number_of_ADDIs; i++)
convert_array_to_register(arrays, i);
}
}
}
int vectorarraystoregs(void) {
LocalVectorArray *arrays;
converted_arrays = 0;
if ((arrays = scanforlocalvectorarrays())) {
scaninstructions(arrays);
if (number_of_ADDIs > 0) {
computeusedefchains(0);
computeaddilist(arrays);
allocatevectorpropinfo();
computelocalvectorpropinfo(arrays);
computedepthfirstordering();
computeglobalvectorpropinfo();
convert_arrays_to_registers(arrays);
}
}
freeoheap();
return converted_arrays;
}