ref: f3635416112b6444c0f1dd53744a72b3e05c9c19
dir: /src/asm/rpn.c/
/*
* This file is part of RGBDS.
*
* Copyright (c) 1997-2018, Carsten Sorensen and RGBDS contributors.
*
* SPDX-License-Identifier: MIT
*/
/*
* Controls RPN expressions for objectfiles
*/
#include <assert.h>
#include <stdint.h>
#include <stdio.h>
#include <string.h>
#include "asm/asm.h"
#include "asm/main.h"
#include "asm/rpn.h"
#include "asm/symbol.h"
#include "asm/output.h"
#include "asm/warning.h"
#include "linkdefs.h"
void mergetwoexpressions(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
assert(src1->tRPN != NULL && src2->tRPN != NULL);
if (src1->nRPNLength + src2->nRPNLength > MAXRPNLEN)
fatalerror("RPN expression is too large");
uint32_t len = src1->nRPNLength + src2->nRPNLength;
expr->nVal = 0;
expr->tRPN = src1->tRPN;
if (src1->nRPNCapacity >= len) {
expr->nRPNCapacity = src1->nRPNCapacity;
} else {
uint32_t cap1 = src1->nRPNCapacity;
uint32_t cap2 = src2->nRPNCapacity;
uint32_t cap = (cap1 > cap2) ? cap1 : cap2;
if (len > cap)
cap = (cap <= MAXRPNLEN / 2) ? cap * 2 : MAXRPNLEN;
expr->nRPNCapacity = cap;
expr->tRPN = realloc(expr->tRPN, expr->nRPNCapacity);
if (expr->tRPN == NULL)
fatalerror("No memory for RPN expression");
}
memcpy(expr->tRPN + src1->nRPNLength, src2->tRPN, src2->nRPNLength);
free(src2->tRPN);
expr->nRPNLength = len;
expr->nRPNPatchSize = src1->nRPNPatchSize + src2->nRPNPatchSize;
expr->nRPNOut = 0;
expr->isReloc = src1->isReloc || src2->isReloc;
}
/*
* Add a byte to the RPN expression
*/
void pushbyte(struct Expression *expr, uint8_t b)
{
if (expr->nRPNLength == expr->nRPNCapacity) {
if (expr->nRPNCapacity == 0)
expr->nRPNCapacity = 256;
else if (expr->nRPNCapacity == MAXRPNLEN)
fatalerror("RPN expression is too large");
else if (expr->nRPNCapacity > MAXRPNLEN / 2)
expr->nRPNCapacity = MAXRPNLEN;
else
expr->nRPNCapacity *= 2;
expr->tRPN = realloc(expr->tRPN, expr->nRPNCapacity);
if (expr->tRPN == NULL)
fatalerror("No memory for RPN expression");
}
expr->tRPN[expr->nRPNLength++] = b;
}
/*
* Init the RPN expression
*/
void rpn_Init(struct Expression *expr)
{
expr->tRPN = NULL;
expr->nRPNCapacity = 0;
expr->nRPNLength = 0;
expr->nRPNPatchSize = 0;
expr->nRPNOut = 0;
expr->isReloc = 0;
}
/*
* Free the RPN expression
*/
void rpn_Free(struct Expression *expr)
{
free(expr->tRPN);
rpn_Init(expr);
}
/*
* Returns the next rpn byte in expression
*/
uint16_t rpn_PopByte(struct Expression *expr)
{
if (expr->nRPNOut == expr->nRPNLength)
return 0xDEAD;
return expr->tRPN[expr->nRPNOut++];
}
/*
* Determine if the current expression is relocatable
*/
uint32_t rpn_isReloc(const struct Expression *expr)
{
return expr->isReloc;
}
/*
* Add symbols, constants and operators to expression
*/
void rpn_Number(struct Expression *expr, uint32_t i)
{
rpn_Init(expr);
pushbyte(expr, RPN_CONST);
pushbyte(expr, i);
pushbyte(expr, i >> 8);
pushbyte(expr, i >> 16);
pushbyte(expr, i >> 24);
expr->nVal = i;
expr->nRPNPatchSize += 5;
}
void rpn_Symbol(struct Expression *expr, char *tzSym)
{
struct sSymbol *sym = sym_FindSymbol(tzSym);
if (!sym || !sym_IsConstant(sym)) {
rpn_Init(expr);
sym_Ref(tzSym);
expr->isReloc = 1;
pushbyte(expr, RPN_SYM);
while (*tzSym)
pushbyte(expr, *tzSym++);
pushbyte(expr, 0);
expr->nRPNPatchSize += 5;
} else {
rpn_Number(expr, sym_GetConstantValue(tzSym));
}
}
void rpn_BankSelf(struct Expression *expr)
{
rpn_Init(expr);
if (pCurrentSection->nBank == -1)
/*
* This is not really relocatable, but this makes the assembler
* write this expression as a RPN patch to the object file.
*/
expr->isReloc = 1;
else
expr->nVal = pCurrentSection->nBank;
pushbyte(expr, RPN_BANK_SELF);
expr->nRPNPatchSize++;
}
void rpn_BankSymbol(struct Expression *expr, char *tzSym)
{
struct sSymbol const *sym = sym_FindSymbol(tzSym);
/* The @ symbol is treated differently. */
if (sym == pPCSymbol) {
rpn_BankSelf(expr);
return;
}
if (sym && sym_IsConstant(sym)) {
yyerror("BANK argument must be a relocatable identifier");
} else {
rpn_Init(expr);
sym_Ref(tzSym);
pushbyte(expr, RPN_BANK_SYM);
for (unsigned int i = 0; tzSym[i]; i++)
pushbyte(expr, tzSym[i]);
pushbyte(expr, 0);
expr->nRPNPatchSize += 5;
/* If the symbol didn't exist, `sym_Ref` created it */
struct sSymbol *pSymbol = sym_FindSymbol(tzSym);
if (pSymbol->pSection && pSymbol->pSection->nBank != -1)
/* Symbol's section is known and bank's fixed */
expr->nVal = pSymbol->pSection->nBank;
else
expr->isReloc = 1;
}
}
void rpn_BankSection(struct Expression *expr, char *tzSectionName)
{
rpn_Init(expr);
struct Section *pSection = out_FindSectionByName(tzSectionName);
if (pSection && pSection->nBank != -1)
expr->nVal = pSection->nBank;
else
/*
* This is not really relocatable, but this makes the assembler
* write this expression as a RPN patch to the object file.
*/
expr->isReloc = 1;
pushbyte(expr, RPN_BANK_SECT);
expr->nRPNPatchSize++;
while (*tzSectionName) {
pushbyte(expr, *tzSectionName++);
expr->nRPNPatchSize++;
}
pushbyte(expr, 0);
expr->nRPNPatchSize++;
}
void rpn_CheckHRAM(struct Expression *expr, const struct Expression *src)
{
*expr = *src;
pushbyte(expr, RPN_HRAM);
expr->nRPNPatchSize++;
}
void rpn_CheckRST(struct Expression *expr, const struct Expression *src)
{
*expr = *src;
pushbyte(expr, RPN_RST);
expr->nRPNPatchSize++;
}
void rpn_LOGNOT(struct Expression *expr, const struct Expression *src)
{
*expr = *src;
expr->nVal = !expr->nVal;
pushbyte(expr, RPN_LOGUNNOT);
expr->nRPNPatchSize++;
}
void rpn_LOGOR(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
expr->nVal = (src1->nVal || src2->nVal);
pushbyte(expr, RPN_LOGOR);
expr->nRPNPatchSize++;
}
void rpn_LOGAND(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
expr->nVal = (src1->nVal && src2->nVal);
pushbyte(expr, RPN_LOGAND);
expr->nRPNPatchSize++;
}
void rpn_HIGH(struct Expression *expr, const struct Expression *src)
{
*expr = *src;
expr->nVal = (expr->nVal >> 8) & 0xFF;
pushbyte(expr, RPN_CONST);
pushbyte(expr, 8);
pushbyte(expr, 0);
pushbyte(expr, 0);
pushbyte(expr, 0);
pushbyte(expr, RPN_SHR);
pushbyte(expr, RPN_CONST);
pushbyte(expr, 0xFF);
pushbyte(expr, 0);
pushbyte(expr, 0);
pushbyte(expr, 0);
pushbyte(expr, RPN_AND);
expr->nRPNPatchSize += 12;
}
void rpn_LOW(struct Expression *expr, const struct Expression *src)
{
*expr = *src;
expr->nVal = expr->nVal & 0xFF;
pushbyte(expr, RPN_CONST);
pushbyte(expr, 0xFF);
pushbyte(expr, 0);
pushbyte(expr, 0);
pushbyte(expr, 0);
pushbyte(expr, RPN_AND);
expr->nRPNPatchSize += 6;
}
void rpn_LOGEQU(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
expr->nVal = (src1->nVal == src2->nVal);
pushbyte(expr, RPN_LOGEQ);
expr->nRPNPatchSize++;
}
void rpn_LOGGT(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
expr->nVal = (src1->nVal > src2->nVal);
pushbyte(expr, RPN_LOGGT);
expr->nRPNPatchSize++;
}
void rpn_LOGLT(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
expr->nVal = (src1->nVal < src2->nVal);
pushbyte(expr, RPN_LOGLT);
expr->nRPNPatchSize++;
}
void rpn_LOGGE(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
expr->nVal = (src1->nVal >= src2->nVal);
pushbyte(expr, RPN_LOGGE);
expr->nRPNPatchSize++;
}
void rpn_LOGLE(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
expr->nVal = (src1->nVal <= src2->nVal);
pushbyte(expr, RPN_LOGLE);
expr->nRPNPatchSize++;
}
void rpn_LOGNE(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
expr->nVal = (src1->nVal != src2->nVal);
pushbyte(expr, RPN_LOGNE);
expr->nRPNPatchSize++;
}
void rpn_ADD(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
expr->nVal = ((uint32_t)src1->nVal + (uint32_t)src2->nVal);
pushbyte(expr, RPN_ADD);
expr->nRPNPatchSize++;
}
void rpn_SUB(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
expr->nVal = ((uint32_t)src1->nVal - (uint32_t)src2->nVal);
pushbyte(expr, RPN_SUB);
expr->nRPNPatchSize++;
}
void rpn_XOR(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
expr->nVal = (src1->nVal ^ src2->nVal);
pushbyte(expr, RPN_XOR);
expr->nRPNPatchSize++;
}
void rpn_OR(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
expr->nVal = (src1->nVal | src2->nVal);
pushbyte(expr, RPN_OR);
expr->nRPNPatchSize++;
}
void rpn_AND(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
expr->nVal = (src1->nVal & src2->nVal);
pushbyte(expr, RPN_AND);
expr->nRPNPatchSize++;
}
static int32_t shift(int32_t shiftee, int32_t amount)
{
if (shiftee < 0)
warning(WARNING_SHIFT, "Shifting negative value %d", shiftee);
if (amount >= 0) {
// Left shift
if (amount >= 32) {
warning(WARNING_SHIFT_AMOUNT, "Shifting left by large amount %d",
amount);
return 0;
} else {
/*
* Use unsigned to force a bitwise shift
* Casting back is OK because the types implement two's
* complement behavior
*/
return (uint32_t)shiftee << amount;
}
} else {
// Right shift
amount = -amount;
if (amount >= 32) {
warning(WARNING_SHIFT_AMOUNT, "Shifting right by large amount %d",
amount);
return shiftee < 0 ? -1 : 0;
} else if (shiftee >= 0) {
return shiftee >> amount;
} else {
/*
* The C standard leaves shifting right negative values
* undefined, so use a left shift manually sign-extended
*/
return (uint32_t)shiftee >> amount
| -((uint32_t)1 << (32 - amount));
}
}
}
void rpn_SHL(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
if (!expr->isReloc) {
if (src2->nVal < 0)
warning(WARNING_SHIFT_AMOUNT, "Shifting left by negative value: %d",
src2->nVal);
expr->nVal = shift(src1->nVal, src2->nVal);
}
pushbyte(expr, RPN_SHL);
expr->nRPNPatchSize++;
}
void rpn_SHR(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
if (!expr->isReloc) {
if (src2->nVal < 0)
warning(WARNING_SHIFT_AMOUNT, "Shifting right by negative value: %d",
src2->nVal);
expr->nVal = shift(src1->nVal, -src2->nVal);
}
pushbyte(expr, RPN_SHR);
expr->nRPNPatchSize++;
}
void rpn_MUL(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
expr->nVal = ((uint32_t)src1->nVal * (uint32_t)src2->nVal);
pushbyte(expr, RPN_MUL);
expr->nRPNPatchSize++;
}
void rpn_DIV(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
if (!expr->isReloc) {
if (src2->nVal == 0)
fatalerror("Division by zero");
if (src1->nVal == INT32_MIN && src2->nVal == -1) {
warning(WARNING_DIV, "Division of min value by -1");
expr->nVal = INT32_MIN;
} else {
expr->nVal = (src1->nVal / src2->nVal);
}
}
pushbyte(expr, RPN_DIV);
expr->nRPNPatchSize++;
}
void rpn_MOD(struct Expression *expr, const struct Expression *src1,
const struct Expression *src2)
{
mergetwoexpressions(expr, src1, src2);
if (!expr->isReloc) {
if (src2->nVal == 0)
fatalerror("Division by zero");
if (src1->nVal == INT32_MIN && src2->nVal == -1)
expr->nVal = 0;
else
expr->nVal = (src1->nVal % src2->nVal);
}
pushbyte(expr, RPN_MOD);
expr->nRPNPatchSize++;
}
void rpn_UNNEG(struct Expression *expr, const struct Expression *src)
{
*expr = *src;
expr->nVal = -(uint32_t)expr->nVal;
pushbyte(expr, RPN_UNSUB);
expr->nRPNPatchSize++;
}
void rpn_UNNOT(struct Expression *expr, const struct Expression *src)
{
*expr = *src;
expr->nVal = ~expr->nVal;
pushbyte(expr, RPN_UNNOT);
expr->nRPNPatchSize++;
}