ref: defb221c9834a15da53fc9b1023f9c55e2637f12
dir: /src/link/assign.c/
/*
* This file is part of RGBDS.
*
* Copyright (c) 1997-2018, Carsten Sorensen and RGBDS contributors.
*
* SPDX-License-Identifier: MIT
*/
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <stdbool.h>
#include <string.h>
#include "extern/err.h"
#include "link/assign.h"
#include "link/mylink.h"
#include "link/main.h"
#include "link/script.h"
#include "link/symbol.h"
struct sFreeArea {
int32_t nOrg;
int32_t nSize;
struct sFreeArea *pPrev, *pNext;
};
struct sSectionAttributes {
const char *name;
/* bank + offset = bank originally stored in a section struct */
int32_t bank;
int32_t offset;
int32_t minBank;
int32_t bankCount;
};
struct sFreeArea *BankFree[BANK_INDEX_MAX];
int32_t MaxAvail[BANK_INDEX_MAX];
int32_t MaxBankUsed;
int32_t MaxWBankUsed;
int32_t MaxSBankUsed;
int32_t MaxVBankUsed;
const enum eSectionType SECT_MIN = SECT_WRAM0;
const enum eSectionType SECT_MAX = SECT_OAM;
const struct sSectionAttributes SECT_ATTRIBUTES[] = {
{"WRAM0", BANK_INDEX_WRAM0, 0, 0, BANK_COUNT_WRAM0},
{"VRAM", BANK_INDEX_VRAM, 0, 0, BANK_COUNT_VRAM},
{"ROMX", BANK_INDEX_ROMX, -BANK_MIN_ROMX, BANK_MIN_ROMX, BANK_COUNT_ROMX},
{"ROM0", BANK_INDEX_ROM0, 0, 0, BANK_COUNT_ROM0},
{"HRAM", BANK_INDEX_HRAM, 0, 0, BANK_COUNT_HRAM},
{"WRAMX", BANK_INDEX_WRAMX, -BANK_MIN_WRAMX, BANK_MIN_WRAMX, BANK_COUNT_WRAMX},
{"SRAM", BANK_INDEX_SRAM, 0, 0, BANK_COUNT_SRAM},
{"OAM", BANK_INDEX_OAM, 0, 0, BANK_COUNT_OAM}
};
static void do_max_bank(enum eSectionType Type, int32_t nBank)
{
switch (Type) {
case SECT_ROMX:
if (nBank > MaxBankUsed)
MaxBankUsed = nBank;
break;
case SECT_WRAMX:
if (nBank > MaxWBankUsed)
MaxWBankUsed = nBank;
break;
case SECT_SRAM:
if (nBank > MaxSBankUsed)
MaxSBankUsed = nBank;
break;
case SECT_VRAM:
if (nBank > MaxVBankUsed)
MaxVBankUsed = nBank;
break;
case SECT_ROM0:
case SECT_WRAM0:
case SECT_OAM:
case SECT_HRAM:
default:
break;
}
}
void ensureSectionTypeIsValid(enum eSectionType type)
{
if (type < SECT_MIN || type > SECT_MAX)
errx(1, "%s: Invalid section type found: %d", __func__, type);
}
int BankIndexIsROM0(int32_t bank)
{
return (bank >= BANK_INDEX_ROM0) &&
(bank < (BANK_INDEX_ROM0 + BANK_COUNT_ROM0));
}
int BankIndexIsROMX(int32_t bank)
{
return (bank >= BANK_INDEX_ROMX) &&
(bank < (BANK_INDEX_ROMX + BANK_COUNT_ROMX));
}
int BankIndexIsWRAM0(int32_t bank)
{
return (bank >= BANK_INDEX_WRAM0) &&
(bank < (BANK_INDEX_WRAM0 + BANK_COUNT_WRAM0));
}
int BankIndexIsWRAMX(int32_t bank)
{
return (bank >= BANK_INDEX_WRAMX) &&
(bank < (BANK_INDEX_WRAMX + BANK_COUNT_WRAMX));
}
int BankIndexIsVRAM(int32_t bank)
{
return (bank >= BANK_INDEX_VRAM) &&
(bank < (BANK_INDEX_VRAM + BANK_COUNT_VRAM));
}
int BankIndexIsOAM(int32_t bank)
{
return (bank >= BANK_INDEX_OAM) &&
(bank < (BANK_INDEX_OAM + BANK_COUNT_OAM));
}
int BankIndexIsHRAM(int32_t bank)
{
return (bank >= BANK_INDEX_HRAM) &&
(bank < (BANK_INDEX_HRAM + BANK_COUNT_HRAM));
}
int BankIndexIsSRAM(int32_t bank)
{
return (bank >= BANK_INDEX_SRAM) &&
(bank < (BANK_INDEX_SRAM + BANK_COUNT_SRAM));
}
int32_t area_Avail(int32_t bank)
{
int32_t r;
struct sFreeArea *pArea;
r = 0;
pArea = BankFree[bank];
while (pArea) {
r += pArea->nSize;
pArea = pArea->pNext;
}
return r;
}
int32_t area_doAlloc(struct sFreeArea *pArea, int32_t org, int32_t size)
{
if ((org >= pArea->nOrg)
&& ((org + size) <= (pArea->nOrg + pArea->nSize))) {
if (org == pArea->nOrg) {
pArea->nOrg += size;
pArea->nSize -= size;
return org;
}
if ((org + size) == (pArea->nOrg + pArea->nSize)) {
pArea->nSize -= size;
return org;
}
struct sFreeArea *pNewArea;
pNewArea = malloc(sizeof(struct sFreeArea));
if (pNewArea == NULL)
err(1, "%s: Failed to allocate memory", __func__);
*pNewArea = *pArea;
pNewArea->pPrev = pArea;
pArea->pNext = pNewArea;
pArea->nSize = org - pArea->nOrg;
pNewArea->nOrg = org + size;
pNewArea->nSize -= size + pArea->nSize;
return org;
}
return -1;
}
int32_t area_AllocAbs(struct sFreeArea **ppArea, int32_t org, int32_t size)
{
struct sFreeArea *pArea;
pArea = *ppArea;
while (pArea) {
int32_t result = area_doAlloc(pArea, org, size);
if (result != -1)
return result;
ppArea = &(pArea->pNext);
pArea = *ppArea;
}
return -1;
}
int32_t area_AllocAbsAnyBank(int32_t org, int32_t size, enum eSectionType type)
{
ensureSectionTypeIsValid(type);
int32_t startBank = SECT_ATTRIBUTES[type].bank;
int32_t bankCount = SECT_ATTRIBUTES[type].bankCount;
for (int32_t i = 0; i < bankCount; i++) {
if (area_AllocAbs(&BankFree[startBank + i], org, size) != -1)
return startBank + i;
}
return -1;
}
int32_t area_Alloc(struct sFreeArea **ppArea, int32_t size, int32_t alignment)
{
struct sFreeArea *pArea;
if (alignment < 1)
alignment = 1;
pArea = *ppArea;
while (pArea) {
int32_t org = pArea->nOrg;
if (org % alignment)
org += alignment;
org -= org % alignment;
int32_t result = area_doAlloc(pArea, org, size);
if (result != -1)
return result;
ppArea = &(pArea->pNext);
pArea = *ppArea;
}
return -1;
}
int32_t area_AllocAnyBank(int32_t size, int32_t alignment,
enum eSectionType type)
{
ensureSectionTypeIsValid(type);
int32_t i, org;
int32_t startBank = SECT_ATTRIBUTES[type].bank;
int32_t bankCount = SECT_ATTRIBUTES[type].bankCount;
for (i = 0; i < bankCount; i++) {
org = area_Alloc(&BankFree[startBank + i], size, alignment);
if (org != -1)
return ((startBank + i) << 16) | org;
}
return -1;
}
struct sSection *FindLargestSection(enum eSectionType type, bool bankFixed)
{
struct sSection *pSection, *r = NULL;
int32_t nLargest = 0;
int32_t nLargestAlignment = 0;
pSection = pSections;
while (pSection) {
if (pSection->oAssigned == 0 && pSection->Type == type
&& (bankFixed ^ (pSection->nBank == -1))) {
if (pSection->nAlign > nLargestAlignment
|| (pSection->nAlign == nLargestAlignment
&& pSection->nByteSize > nLargest)) {
nLargest = pSection->nByteSize;
nLargestAlignment = pSection->nAlign;
r = pSection;
}
}
pSection = pSection->pNext;
}
return r;
}
int32_t IsSectionNameInUse(const char *name)
{
const struct sSection *pSection = pSections;
while (pSection) {
if (strcmp(pSection->pzName, name) == 0)
return 1;
pSection = pSection->pNext;
}
return 0;
}
struct sSection *GetSectionByName(const char *name)
{
struct sSection *pSection = pSections;
while (pSection) {
if (strcmp(pSection->pzName, name) == 0)
return pSection;
pSection = pSection->pNext;
}
return NULL;
}
int32_t IsSectionSameTypeBankAndAttrs(const char *name,
enum eSectionType type, int32_t bank,
int32_t org, int32_t align)
{
const struct sSection *pSection;
for (pSection = pSections; pSection; pSection = pSection->pNext) {
/* Skip if it has already been assigned */
if (pSection->oAssigned == 1)
continue;
/* Check if it has the same name */
if (strcmp(pSection->pzName, name) != 0)
continue;
/*
* The section has the same name, now check if there is a
* mismatch or not.
*/
/* Section must have the same attributes or float */
if ((pSection->nOrg != -1 && pSection->nOrg != org) ||
(pSection->nAlign != 1 && pSection->nAlign != align))
return 0;
/* It must have the same type in source and linkerscript */
if (pSection->Type != type)
return 0;
/* Bank number must be unassigned in source or equal */
if (pSection->nBank != -1 && pSection->nBank != bank)
return 0;
return 1;
}
errx(1, "Section \"%s\" not found (or already used).\n", name);
}
uint32_t AssignSectionAddressAndBankByName(const char *name, uint32_t address,
int32_t bank)
{
struct sSection *pSection;
for (pSection = pSections; pSection; pSection = pSection->pNext) {
/* Skip if it has already been assigned */
if (pSection->oAssigned == 1)
continue;
/* Check if it has the same name */
if (strcmp(pSection->pzName, name) != 0)
continue;
/* Section has been found. */
/* The bank can be left as unassigned or be the same */
if (pSection->nBank != -1 && pSection->nBank != bank) {
errx(1, "Section \"%s\" from linkerscript has different bank number than in the source.\n",
name);
}
pSection->nOrg = address;
pSection->nBank = bank;
pSection->nAlign = -1;
return pSection->nByteSize;
}
errx(1, "Section \"%s\" not found (or already used).\n", name);
}
bool VerifyAndSetBank(struct sSection *pSection)
{
enum eSectionType Type = pSection->Type;
ensureSectionTypeIsValid(Type);
if (pSection->nBank >= SECT_ATTRIBUTES[Type].minBank) {
if (pSection->nBank < SECT_ATTRIBUTES[Type].minBank
+ SECT_ATTRIBUTES[Type].bankCount) {
pSection->nBank += SECT_ATTRIBUTES[Type].bank
+ SECT_ATTRIBUTES[Type].offset;
return true;
}
}
return false;
}
void AssignFixedBankSections(enum eSectionType type)
{
ensureSectionTypeIsValid(type);
struct sSection *pSection;
while ((pSection = FindLargestSection(type, true))) {
if (VerifyAndSetBank(pSection)) {
pSection->nOrg = area_Alloc(&BankFree[pSection->nBank],
pSection->nByteSize,
pSection->nAlign);
if (pSection->nOrg != -1) {
pSection->oAssigned = 1;
do_max_bank(pSection->Type, pSection->nBank);
continue;
}
}
if (pSection->nAlign <= 1) {
errx(1, "Unable to place '%s' (%s section) in bank $%02lX",
pSection->pzName,
SECT_ATTRIBUTES[pSection->Type].name,
pSection->nBank);
} else {
errx(1, "Unable to place '%s' (%s section) in bank $%02lX (with $%lX-byte alignment)",
pSection->pzName,
SECT_ATTRIBUTES[pSection->Type].name,
pSection->nBank, pSection->nAlign);
}
}
}
void AssignFloatingBankSections(enum eSectionType type)
{
ensureSectionTypeIsValid(type);
struct sSection *pSection;
while ((pSection = FindLargestSection(type, false))) {
int32_t org;
org = area_AllocAnyBank(pSection->nByteSize, pSection->nAlign,
type);
if (org != -1) {
if (options & OPT_OVERLAY)
errx(1, "All sections must be fixed when using an overlay file.");
pSection->nOrg = org & 0xFFFF;
pSection->nBank = org >> 16;
pSection->oAssigned = 1;
do_max_bank(pSection->Type, pSection->nBank);
} else {
const char *locality = "anywhere";
if (SECT_ATTRIBUTES[pSection->Type].bankCount > 1)
locality = "in any bank";
if (pSection->nAlign <= 1) {
errx(1, "Unable to place '%s' (%s section) %s",
pSection->pzName,
SECT_ATTRIBUTES[type].name, locality);
} else {
errx(1, "Unable to place '%s' (%s section) %s (with $%lX-byte alignment)",
pSection->pzName,
SECT_ATTRIBUTES[type].name, locality,
pSection->nAlign);
}
}
}
}
char *tzLinkerscriptName;
void SetLinkerscriptName(char *tzLinkerscriptFile)
{
tzLinkerscriptName = tzLinkerscriptFile;
}
void AssignSections(void)
{
struct sSection *pSection;
MaxBankUsed = 0;
/*
* Initialize the memory areas
*/
for (int32_t i = 0; i < BANK_INDEX_MAX; i += 1) {
BankFree[i] = malloc(sizeof(*BankFree[i]));
if (!BankFree[i]) {
errx(1, "%s: Couldn't allocate mem for bank %d",
__func__, i);
}
if (BankIndexIsROM0(i)) {
/* ROM0 bank */
BankFree[i]->nOrg = 0x0000;
if (options & OPT_TINY)
BankFree[i]->nSize = 0x8000;
else
BankFree[i]->nSize = 0x4000;
} else if (BankIndexIsROMX(i)) {
/* Swappable ROM bank */
BankFree[i]->nOrg = 0x4000;
BankFree[i]->nSize = 0x4000;
} else if (BankIndexIsWRAM0(i)) {
/* WRAM */
BankFree[i]->nOrg = 0xC000;
if (options & OPT_CONTWRAM)
BankFree[i]->nSize = 0x2000;
else
BankFree[i]->nSize = 0x1000;
} else if (BankIndexIsSRAM(i)) {
/* Swappable SRAM bank */
BankFree[i]->nOrg = 0xA000;
BankFree[i]->nSize = 0x2000;
} else if (BankIndexIsWRAMX(i)) {
/* Swappable WRAM bank */
BankFree[i]->nOrg = 0xD000;
BankFree[i]->nSize = 0x1000;
} else if (BankIndexIsVRAM(i)) {
/* Swappable VRAM bank */
BankFree[i]->nOrg = 0x8000;
if (options & OPT_DMG_MODE && i != BANK_INDEX_VRAM)
BankFree[i]->nSize = 0;
else
BankFree[i]->nSize = 0x2000;
} else if (BankIndexIsOAM(i)) {
BankFree[i]->nOrg = 0xFE00;
BankFree[i]->nSize = 0x00A0;
} else if (BankIndexIsHRAM(i)) {
/* HRAM */
BankFree[i]->nOrg = 0xFF80;
BankFree[i]->nSize = 0x007F;
} else {
errx(1, "%s: Unknown bank type %d", __func__, i);
}
MaxAvail[i] = BankFree[i]->nSize;
BankFree[i]->pPrev = NULL;
BankFree[i]->pNext = NULL;
}
/*
* First, let's parse the linkerscript.
*/
if (tzLinkerscriptName) {
script_InitSections();
script_Parse(tzLinkerscriptName);
}
/*
* Second, let's assign all the fixed sections...
*/
for (pSection = pSections ; pSection; pSection = pSection->pNext) {
if (!((pSection->nOrg != -1 || pSection->nBank != -1)
&& pSection->oAssigned == 0))
continue;
/* User wants to have a say... */
switch (pSection->Type) {
case SECT_WRAM0:
case SECT_HRAM:
case SECT_ROM0:
case SECT_OAM:
pSection->nBank = SECT_ATTRIBUTES[pSection->Type].bank;
if (area_AllocAbs(&BankFree[pSection->nBank],
pSection->nOrg,
pSection->nByteSize) == -1) {
errx(1, "Unable to place '%s' (%s section) at $%X",
pSection->pzName,
SECT_ATTRIBUTES[pSection->Type].name,
pSection->nOrg);
}
pSection->oAssigned = 1;
break;
case SECT_SRAM:
case SECT_WRAMX:
case SECT_VRAM:
case SECT_ROMX:
if (!(pSection->nBank != -1 && pSection->nOrg != -1))
break;
if (VerifyAndSetBank(pSection) &&
area_AllocAbs(&BankFree[pSection->nBank],
pSection->nOrg,
pSection->nByteSize) != -1) {
do_max_bank(pSection->Type, pSection->nBank);
pSection->oAssigned = 1;
} else {
errx(1, "Unable to place '%s' (%s section) at $%X in bank $%02X",
pSection->pzName,
SECT_ATTRIBUTES[pSection->Type].name,
pSection->nOrg, pSection->nBank);
}
break;
default:
errx(1, "%s: Internal error: Type %d", __func__,
pSection->Type);
}
}
/*
* Next, let's assign all the bankfixed ONLY sections...
*/
for (enum eSectionType i = SECT_MIN; i <= SECT_MAX; i++)
AssignFixedBankSections(i);
/*
* Now, let's assign all the floating bank but fixed ROMX sections...
*/
for (pSection = pSections ; pSection; pSection = pSection->pNext) {
if (!(pSection->oAssigned == 0
&& pSection->nOrg != -1 && pSection->nBank == -1))
continue;
if (options & OPT_OVERLAY) {
errx(1, "All sections must be fixed when using an overlay file: '%s'",
pSection->pzName);
}
switch (pSection->Type) {
case SECT_ROMX:
case SECT_VRAM:
case SECT_SRAM:
case SECT_WRAMX:
pSection->nBank =
area_AllocAbsAnyBank(pSection->nOrg,
pSection->nByteSize,
pSection->Type);
if (pSection->nBank == -1) {
errx(1, "Unable to place '%s' (%s section) at $%X in any bank",
pSection->pzName,
SECT_ATTRIBUTES[pSection->Type].name,
pSection->nOrg);
}
pSection->oAssigned = 1;
do_max_bank(pSection->Type, pSection->nBank);
break;
case SECT_ROM0:
case SECT_WRAM0:
case SECT_OAM:
case SECT_HRAM:
default: /* Handle other sections later */
break;
}
}
/*
* OK, all that nasty stuff is done so let's assign all the other
* sections
*/
for (enum eSectionType i = SECT_MIN; i <= SECT_MAX; i++)
AssignFloatingBankSections(i);
}
void CreateSymbolTable(void)
{
const struct sSection *pSect;
sym_Init();
pSect = pSections;
while (pSect) {
int32_t i;
i = pSect->nNumberOfSymbols;
while (i--) {
const struct sSymbol *tSymbol = pSect->tSymbols[i];
if ((tSymbol->Type == SYM_EXPORT) &&
((tSymbol->pSection == pSect) ||
(tSymbol->pSection == NULL))) {
if (tSymbol->pSection == NULL) {
sym_CreateSymbol(tSymbol->pzName,
tSymbol->nOffset,
-1,
tSymbol->pzObjFileName,
tSymbol->pzFileName,
tSymbol->nFileLine);
} else {
sym_CreateSymbol(tSymbol->pzName,
pSect->nOrg +
tSymbol->nOffset,
pSect->nBank,
tSymbol->pzObjFileName,
tSymbol->pzFileName,
tSymbol->nFileLine);
}
}
}
pSect = pSect->pNext;
}
}