ref: 65121e6d5d2b9cb15283a0d5c46addeb67d20a7b
dir: /src/link/output.c/
/*
* This file is part of RGBDS.
*
* Copyright (c) 2019, Eldred Habert and RGBDS contributors.
*
* SPDX-License-Identifier: MIT
*/
#include <stdlib.h>
#include <stdint.h>
#include "link/output.h"
#include "link/main.h"
#include "link/section.h"
#include "link/symbol.h"
#include "extern/err.h"
FILE * outputFile;
FILE *overlayFile;
FILE *symFile;
FILE *mapFile;
struct SortedSection {
struct Section const *section;
struct SortedSection *next;
};
static struct {
uint32_t nbBanks;
struct SortedSections {
struct SortedSection *sections;
struct SortedSection *zeroLenSections;
} *banks;
} sections[SECTTYPE_INVALID];
void out_AddSection(struct Section const *section)
{
static uint32_t maxNbBanks[] = {
[SECTTYPE_ROM0] = 1,
[SECTTYPE_ROMX] = UINT32_MAX,
[SECTTYPE_VRAM] = 2,
[SECTTYPE_SRAM] = UINT32_MAX,
[SECTTYPE_WRAM0] = 1,
[SECTTYPE_WRAMX] = 7,
[SECTTYPE_OAM] = 1,
[SECTTYPE_HRAM] = 1
};
uint32_t targetBank = section->bank - bankranges[section->type][0];
uint32_t minNbBanks = targetBank + 1;
if (minNbBanks > maxNbBanks[section->type])
errx(1, "Section \"%s\" has invalid bank range (%u > %u)",
section->name, section->bank,
maxNbBanks[section->type] - 1);
if (minNbBanks > sections[section->type].nbBanks) {
sections[section->type].banks =
realloc(sections[section->type].banks,
sizeof(*sections[0].banks) * minNbBanks);
for (uint32_t i = sections[section->type].nbBanks;
i < minNbBanks; i++) {
sections[section->type].banks[i].sections = NULL;
sections[section->type].banks[i].zeroLenSections = NULL;
}
sections[section->type].nbBanks = minNbBanks;
}
if (!sections[section->type].banks)
err(1, "Failed to realloc banks");
struct SortedSection *newSection = malloc(sizeof(*newSection));
struct SortedSection **ptr = section->size
? §ions[section->type].banks[targetBank].sections
: §ions[section->type].banks[targetBank].zeroLenSections;
if (!newSection)
err(1, "Failed to add new section \"%s\"", section->name);
newSection->section = section;
while (*ptr && (*ptr)->section->org < section->org)
ptr = &(*ptr)->next;
newSection->next = *ptr;
*ptr = newSection;
}
struct Section const *out_OverlappingSection(struct Section const *section)
{
struct SortedSection *ptr =
sections[section->type].banks[section->bank].sections;
while (ptr) {
if (ptr->section->org < section->org + section->size
&& section->org < ptr->section->org + ptr->section->size)
return ptr->section;
ptr = ptr->next;
}
return NULL;
}
/**
* Performs sanity checks on the overlay file.
*/
static void checkOverlay(void)
{
if (!overlayFile)
return;
if (fseek(overlayFile, 0, SEEK_END) != 0) {
warnx("Overlay file is not seekable, cannot check if properly formed");
return;
}
long overlaySize = ftell(overlayFile);
if (overlaySize % 0x4000)
errx(1, "Overlay file must have a size multiple of 0x4000");
/* Reset back to beginning */
fseek(overlayFile, 0, SEEK_SET);
uint32_t nbOverlayBanks = overlaySize / 0x4000 - 1;
if (nbOverlayBanks < 1)
errx(1, "Overlay must be at least 0x8000 bytes large");
if (nbOverlayBanks > sections[SECTTYPE_ROMX].nbBanks) {
sections[SECTTYPE_ROMX].banks =
realloc(sections[SECTTYPE_ROMX].banks,
sizeof(*sections[SECTTYPE_ROMX].banks) *
nbOverlayBanks);
if (!sections[SECTTYPE_ROMX].banks)
err(1, "Failed to realloc banks for overlay");
for (uint32_t i = sections[SECTTYPE_ROMX].nbBanks;
i < nbOverlayBanks; i++) {
sections[SECTTYPE_ROMX].banks[i].sections = NULL;
sections[SECTTYPE_ROMX].banks[i].zeroLenSections = NULL;
}
sections[SECTTYPE_ROMX].nbBanks = nbOverlayBanks;
}
}
/**
* Write a ROM bank's sections to the output file.
* @param bankSections The bank's sections, ordered by increasing address
* @param baseOffset The address of the bank's first byte in GB address space
* @param size The size of the bank
*/
static void writeBank(struct SortedSection *bankSections, uint16_t baseOffset,
uint16_t size)
{
uint16_t offset = 0;
while (bankSections) {
struct Section const *section = bankSections->section;
/* Output padding up to the next SECTION */
while (offset + baseOffset < section->org) {
putc(overlayFile ? getc(overlayFile) : padValue,
outputFile);
offset++;
}
/* Output the section itself */
fwrite(section->data, sizeof(*section->data), section->size,
outputFile);
if (overlayFile) {
/* Skip bytes even with pipes */
for (uint16_t i = 0; i < section->size; i++)
getc(overlayFile);
}
offset += section->size;
bankSections = bankSections->next;
}
while (offset < size) {
putc(overlayFile ? getc(overlayFile) : padValue, outputFile);
offset++;
}
}
/**
* Writes a ROM file to the output.
*/
static void writeROM(void)
{
outputFile = openFile(outputFileName, "wb");
overlayFile = openFile(overlayFileName, "rb");
checkOverlay();
if (outputFile) {
if (sections[SECTTYPE_ROM0].nbBanks > 0)
writeBank(sections[SECTTYPE_ROM0].banks[0].sections,
0x0000, 0x4000);
for (uint32_t i = 0 ; i < sections[SECTTYPE_ROMX].nbBanks; i++)
writeBank(sections[SECTTYPE_ROMX].banks[i].sections,
0x4000, 0x4000);
}
closeFile(outputFile);
closeFile(overlayFile);
}
/**
* Get the lowest section by address out of the two
* @param s1 One choice
* @param s2 The other
* @return The lowest section of the two, or the non-NULL one if applicable
*/
static struct SortedSection const **nextSection(struct SortedSection const **s1,
struct SortedSection const **s2)
{
if (!*s1)
return s2;
if (!*s2)
return s1;
return (*s1)->section->org < (*s2)->section->org ? s1 : s2;
}
/**
* Write a bank's contents to the sym file
* @param bankSections The bank's sections
*/
static void writeSymBank(struct SortedSections const *bankSections)
{
if (!symFile)
return;
struct {
struct SortedSection const *sections;
#define sect sections->section /* Fake member as a shortcut */
uint32_t i;
struct Symbol const *sym;
uint16_t addr;
} sectList = { .sections = bankSections->sections, .i = 0 },
zlSectList = { .sections = bankSections->zeroLenSections, .i = 0 },
*minSectList;
for (;;) {
while (sectList.sections
&& sectList.i == sectList.sect->nbSymbols) {
sectList.sections = sectList.sections->next;
sectList.i = 0;
}
while (zlSectList.sections
&& zlSectList.i == zlSectList.sect->nbSymbols) {
zlSectList.sections = zlSectList.sections->next;
zlSectList.i = 0;
}
if (!sectList.sections && !zlSectList.sections) {
break;
} else if (sectList.sections && zlSectList.sections) {
sectList.sym = sectList.sect->symbols[sectList.i];
zlSectList.sym = zlSectList.sect->symbols[zlSectList.i];
sectList.addr =
sectList.sym->offset + sectList.sect->org;
zlSectList.addr =
zlSectList.sym->offset + zlSectList.sect->org;
minSectList = sectList.addr < zlSectList.addr
? §List
: &zlSectList;
} else if (sectList.sections) {
sectList.sym = sectList.sect->symbols[sectList.i];
sectList.addr =
sectList.sym->offset + sectList.sect->org;
minSectList = §List;
} else {
zlSectList.sym = zlSectList.sect->symbols[zlSectList.i];
zlSectList.addr =
zlSectList.sym->offset + zlSectList.sect->org;
minSectList = &zlSectList;
}
fprintf(symFile, "%02x:%04x %s\n",
minSectList->sect->bank, minSectList->addr,
minSectList->sym->name);
minSectList->i++;
}
#undef sect
}
/**
* Write a bank's contents to the map file
* @param bankSections The bank's sections
*/
static void writeMapBank(struct SortedSections const *sectList,
enum SectionType type, uint32_t bank)
{
if (!mapFile)
return;
struct SortedSection const *section = sectList->sections;
struct SortedSection const *zeroLenSection = sectList->zeroLenSections;
fprintf(mapFile, "%s bank #%u:\n", typeNames[type],
bank + bankranges[type][0]);
uint16_t slack = maxsize[type];
while (section || zeroLenSection) {
struct SortedSection const **pickedSection =
nextSection(§ion, &zeroLenSection);
struct Section const *sect = (*pickedSection)->section;
slack -= sect->size;
fprintf(mapFile, " SECTION: $%04x-$%04x ($%04x byte%s) [\"%s\"]\n",
sect->org, sect->org + sect->size - 1, sect->size,
sect->size == 1 ? "" : "s", sect->name);
for (size_t i = 0; i < sect->nbSymbols; i++)
fprintf(mapFile, " $%04x = %s\n",
sect->symbols[i]->offset + sect->org,
sect->symbols[i]->name);
*pickedSection = (*pickedSection)->next;
}
if (slack == maxsize[type])
fputs(" EMPTY\n\n", mapFile);
else
fprintf(mapFile, " SLACK: $%04x byte%s\n\n", slack,
slack == 1 ? "" : "s");
}
/**
* Writes the sym and/or map files, if applicable.
*/
static void writeSymAndMap(void)
{
if (!symFileName && !mapFileName)
return;
enum SectionType typeMap[SECTTYPE_INVALID] = {
SECTTYPE_ROM0,
SECTTYPE_ROMX,
SECTTYPE_VRAM,
SECTTYPE_SRAM,
SECTTYPE_WRAM0,
SECTTYPE_WRAMX,
SECTTYPE_OAM,
SECTTYPE_HRAM
};
symFile = openFile(symFileName, "w");
mapFile = openFile(mapFileName, "w");
if (symFileName)
fputs("; File generated by rgblink\n", symFile);
for (uint8_t i = 0; i < SECTTYPE_INVALID; i++) {
enum SectionType type = typeMap[i];
if (sections[type].nbBanks > 0) {
for (uint32_t bank = 0; bank < sections[type].nbBanks;
bank++) {
writeSymBank(§ions[type].banks[bank]);
writeMapBank(§ions[type].banks[bank],
type, bank);
}
}
}
closeFile(symFile);
closeFile(mapFile);
}
static void cleanupSections(struct SortedSection *section)
{
while (section) {
struct SortedSection *next = section->next;
free(section);
section = next;
}
}
static void cleanup(void)
{
for (enum SectionType type = 0; type < SECTTYPE_INVALID; type++) {
if (sections[type].nbBanks > 0) {
for (uint32_t i = 0; i < sections[type].nbBanks; i++) {
struct SortedSections *bank =
§ions[type].banks[i];
cleanupSections(bank->sections);
cleanupSections(bank->zeroLenSections);
}
free(sections[type].banks);
}
}
}
void out_WriteFiles(void)
{
writeROM();
writeSymAndMap();
cleanup();
}