ref: 797f8bc3a2be6ddec3497496e9989ab66d21800e
dir: /src/asm/section.c/
/*
* This file is part of RGBDS.
*
* Copyright (c) 2022, RGBDS contributors.
*
* SPDX-License-Identifier: MIT
*/
#include <assert.h>
#include <errno.h>
#include <inttypes.h>
#include <stdbool.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "asm/fstack.h"
#include "asm/main.h"
#include "asm/output.h"
#include "asm/rpn.h"
#include "asm/section.h"
#include "asm/symbol.h"
#include "asm/warning.h"
#include "error.h"
#include "linkdefs.h"
#include "platform.h" // strdup
uint8_t fillByte;
struct UnionStackEntry {
uint32_t start;
uint32_t size;
struct UnionStackEntry *next;
} *unionStack = NULL;
struct SectionStackEntry {
struct Section *section;
struct Section *loadSection;
char const *scope; // Section's symbol scope
uint32_t offset;
int32_t loadOffset;
struct UnionStackEntry *unionStack;
struct SectionStackEntry *next;
};
struct SectionStackEntry *sectionStack;
uint32_t curOffset; // Offset into the current section (see sect_GetSymbolOffset)
struct Section *currentSection = NULL;
static struct Section *currentLoadSection = NULL;
int32_t loadOffset; // Offset into the LOAD section's parent (see sect_GetOutputOffset)
// A quick check to see if we have an initialized section
attr_(warn_unused_result) static bool checksection(void)
{
if (currentSection)
return true;
error("Cannot output data outside of a SECTION\n");
return false;
}
// A quick check to see if we have an initialized section that can contain
// this much initialized data
attr_(warn_unused_result) static bool checkcodesection(void)
{
if (!checksection())
return false;
if (sect_HasData(currentSection->type))
return true;
error("Section '%s' cannot contain code or data (not ROM0 or ROMX)\n",
currentSection->name);
return false;
}
attr_(warn_unused_result) static bool checkSectionSize(struct Section const *sect, uint32_t size)
{
uint32_t maxSize = sectionTypeInfo[sect->type].size;
// If the new size is reasonable, keep going
if (size <= maxSize)
return true;
error("Section '%s' grew too big (max size = 0x%" PRIX32
" bytes, reached 0x%" PRIX32 ").\n", sect->name, maxSize, size);
return false;
}
// Check if the section has grown too much.
attr_(warn_unused_result) static bool reserveSpace(uint32_t delta_size)
{
// This check is here to trap broken code that generates sections that are too big and to
// prevent the assembler from generating huge object files or trying to allocate too much
// memory.
// A check at the linking stage is still necessary.
// If the section has already overflowed, skip the check to avoid erroring out ad nauseam
if (currentSection->size != UINT32_MAX
&& !checkSectionSize(currentSection, curOffset + loadOffset + delta_size))
// Mark the section as overflowed, to avoid repeating the error
currentSection->size = UINT32_MAX;
if (currentLoadSection && currentLoadSection->size != UINT32_MAX
&& !checkSectionSize(currentLoadSection, curOffset + delta_size))
currentLoadSection->size = UINT32_MAX;
return currentSection->size != UINT32_MAX
&& (!currentLoadSection || currentLoadSection->size != UINT32_MAX);
}
struct Section *sect_FindSectionByName(char const *name)
{
for (struct Section *sect = sectionList; sect; sect = sect->next) {
if (strcmp(name, sect->name) == 0)
return sect;
}
return NULL;
}
#define mask(align) ((1U << (align)) - 1)
#define fail(...) \
do { \
error(__VA_ARGS__); \
nbSectErrors++; \
} while (0)
static unsigned int mergeSectUnion(struct Section *sect, enum SectionType type, uint32_t org,
uint8_t alignment, uint16_t alignOffset)
{
assert(alignment < 16); // Should be ensured by the caller
unsigned int nbSectErrors = 0;
// Unionized sections only need "compatible" constraints, and they end up with the strictest
// combination of both.
if (sect_HasData(type))
fail("Cannot declare ROM sections as UNION\n");
if (org != (uint32_t)-1) {
// If both are fixed, they must be the same
if (sect->org != (uint32_t)-1 && sect->org != org)
fail("Section already declared as fixed at different address $%04"
PRIx32 "\n", sect->org);
else if (sect->align != 0 && (mask(sect->align) & (org - sect->alignOfs)))
fail("Section already declared as aligned to %u bytes (offset %"
PRIu16 ")\n", 1U << sect->align, sect->alignOfs);
else
// Otherwise, just override
sect->org = org;
} else if (alignment != 0) {
// Make sure any fixed address given is compatible
if (sect->org != (uint32_t)-1) {
if ((sect->org - alignOffset) & mask(alignment))
fail("Section already declared as fixed at incompatible address $%04"
PRIx32 "\n", sect->org);
// Check if alignment offsets are compatible
} else if ((alignOffset & mask(sect->align))
!= (sect->alignOfs & mask(alignment))) {
fail("Section already declared with incompatible %u"
"-byte alignment (offset %" PRIu16 ")\n",
1u << sect->align, sect->alignOfs);
} else if (alignment > sect->align) {
// If the section is not fixed, its alignment is the largest of both
sect->align = alignment;
sect->alignOfs = alignOffset;
}
}
return nbSectErrors;
}
static unsigned int mergeFragments(struct Section *sect, enum SectionType type, uint32_t org,
uint8_t alignment, uint16_t alignOffset)
{
(void)type;
assert(alignment < 16); // Should be ensured by the caller
unsigned int nbSectErrors = 0;
// Fragments only need "compatible" constraints, and they end up with the strictest
// combination of both.
// The merging is however performed at the *end* of the original section!
if (org != (uint32_t)-1) {
uint16_t curOrg = org - sect->size;
// If both are fixed, they must be the same
if (sect->org != (uint32_t)-1 && sect->org != curOrg)
fail("Section already declared as fixed at incompatible address $%04"
PRIx32 " (cur addr = %04" PRIx32 ")\n",
sect->org, sect->org + sect->size);
else if (sect->align != 0 && (mask(sect->align) & (curOrg - sect->alignOfs)))
fail("Section already declared as aligned to %u bytes (offset %"
PRIu16 ")\n", 1U << sect->align, sect->alignOfs);
else
// Otherwise, just override
sect->org = curOrg;
} else if (alignment != 0) {
int32_t curOfs = (alignOffset - sect->size) % (1U << alignment);
if (curOfs < 0)
curOfs += 1U << alignment;
// Make sure any fixed address given is compatible
if (sect->org != (uint32_t)-1) {
if ((sect->org - curOfs) & mask(alignment))
fail("Section already declared as fixed at incompatible address $%04"
PRIx32 "\n", sect->org);
// Check if alignment offsets are compatible
} else if ((curOfs & mask(sect->align)) != (sect->alignOfs & mask(alignment))) {
fail("Section already declared with incompatible %u"
"-byte alignment (offset %" PRIu16 ")\n",
1u << sect->align, sect->alignOfs);
} else if (alignment > sect->align) {
// If the section is not fixed, its alignment is the largest of both
sect->align = alignment;
sect->alignOfs = curOfs;
}
}
return nbSectErrors;
}
static void mergeSections(struct Section *sect, enum SectionType type, uint32_t org, uint32_t bank,
uint8_t alignment, uint16_t alignOffset, enum SectionModifier mod)
{
unsigned int nbSectErrors = 0;
if (type != sect->type)
fail("Section already exists but with type %s\n", sectionTypeInfo[sect->type].name);
if (sect->modifier != mod) {
fail("Section already declared as %s section\n", sectionModNames[sect->modifier]);
} else {
switch (mod) {
case SECTION_UNION:
case SECTION_FRAGMENT:
nbSectErrors += (mod == SECTION_UNION ? mergeSectUnion : mergeFragments)
(sect, type, org, alignment, alignOffset);
// Common checks
// If the section's bank is unspecified, override it
if (sect->bank == (uint32_t)-1)
sect->bank = bank;
// If both specify a bank, it must be the same one
else if (bank != (uint32_t)-1 && sect->bank != bank)
fail("Section already declared with different bank %" PRIu32 "\n",
sect->bank);
break;
case SECTION_NORMAL:
fail("Section already defined previously at ");
fstk_Dump(sect->src, sect->fileLine);
putc('\n', stderr);
break;
}
}
if (nbSectErrors)
fatalerror("Cannot create section \"%s\" (%u error%s)\n",
sect->name, nbSectErrors, nbSectErrors == 1 ? "" : "s");
}
#undef fail
// Create a new section, not yet in the list.
static struct Section *createSection(char const *name, enum SectionType type,
uint32_t org, uint32_t bank, uint8_t alignment,
uint16_t alignOffset, enum SectionModifier mod)
{
struct Section *sect = malloc(sizeof(*sect));
if (sect == NULL)
fatalerror("Not enough memory for section: %s\n", strerror(errno));
sect->name = strdup(name);
if (sect->name == NULL)
fatalerror("Not enough memory for section name: %s\n", strerror(errno));
sect->type = type;
sect->modifier = mod;
sect->src = fstk_GetFileStack();
sect->fileLine = lexer_GetLineNo();
sect->size = 0;
sect->org = org;
sect->bank = bank;
sect->align = alignment;
sect->alignOfs = alignOffset;
sect->next = NULL;
sect->patches = NULL;
// It is only needed to allocate memory for ROM sections.
if (sect_HasData(type)) {
sect->data = malloc(sectionTypeInfo[type].size);
if (sect->data == NULL)
fatalerror("Not enough memory for section: %s\n", strerror(errno));
} else {
sect->data = NULL;
}
return sect;
}
// Find a section by name and type. If it doesn't exist, create it.
static struct Section *getSection(char const *name, enum SectionType type, uint32_t org,
struct SectionSpec const *attrs, enum SectionModifier mod)
{
uint32_t bank = attrs->bank;
uint8_t alignment = attrs->alignment;
uint16_t alignOffset = attrs->alignOfs;
// First, validate parameters, and normalize them if applicable
if (bank != (uint32_t)-1) {
if (type != SECTTYPE_ROMX && type != SECTTYPE_VRAM
&& type != SECTTYPE_SRAM && type != SECTTYPE_WRAMX)
error("BANK only allowed for ROMX, WRAMX, SRAM, or VRAM sections\n");
else if (bank < sectionTypeInfo[type].firstBank || bank > sectionTypeInfo[type].lastBank)
error("%s bank value $%04" PRIx32 " out of range ($%04" PRIx32 " to $%04"
PRIx32 ")\n", sectionTypeInfo[type].name, bank,
sectionTypeInfo[type].firstBank, sectionTypeInfo[type].lastBank);
} else if (nbbanks(type) == 1) {
// If the section type only has a single bank, implicitly force it
bank = sectionTypeInfo[type].firstBank;
}
if (alignOffset >= 1 << alignment) {
error("Alignment offset (%" PRIu16 ") must be smaller than alignment size (%u)\n",
alignOffset, 1U << alignment);
alignOffset = 0;
}
if (org != (uint32_t)-1) {
if (org < sectionTypeInfo[type].startAddr || org > endaddr(type))
error("Section \"%s\"'s fixed address %#" PRIx32
" is outside of range [%#" PRIx16 "; %#" PRIx16 "]\n",
name, org, sectionTypeInfo[type].startAddr, endaddr(type));
}
if (alignment != 0) {
if (alignment > 16) {
error("Alignment must be between 0 and 16, not %u\n", alignment);
alignment = 16;
}
// It doesn't make sense to have both alignment and org set
uint32_t mask = mask(alignment);
if (org != (uint32_t)-1) {
if ((org - alignOffset) & mask)
error("Section \"%s\"'s fixed address doesn't match its alignment\n",
name);
alignment = 0; // Ignore it if it's satisfied
} else if (sectionTypeInfo[type].startAddr & mask) {
error("Section \"%s\"'s alignment cannot be attained in %s\n",
name, sectionTypeInfo[type].name);
alignment = 0; // Ignore it if it's unattainable
org = 0;
} else if (alignment == 16) {
// Treat an alignment of 16 as being fixed at address 0
alignment = 0;
org = 0;
// The address is known to be valid, since the alignment is
}
}
// Check if another section exists with the same name; merge if yes, otherwise create one
struct Section *sect = sect_FindSectionByName(name);
if (sect) {
mergeSections(sect, type, org, bank, alignment, alignOffset, mod);
} else {
sect = createSection(name, type, org, bank, alignment, alignOffset, mod);
// Add the new section to the list (order doesn't matter)
sect->next = sectionList;
sectionList = sect;
}
return sect;
}
// Set the current section
static void changeSection(void)
{
if (unionStack)
fatalerror("Cannot change the section within a UNION\n");
sym_SetCurrentSymbolScope(NULL);
}
// Set the current section by name and type
void sect_NewSection(char const *name, uint32_t type, uint32_t org,
struct SectionSpec const *attribs, enum SectionModifier mod)
{
if (currentLoadSection)
fatalerror("Cannot change the section within a `LOAD` block\n");
for (struct SectionStackEntry *stack = sectionStack; stack; stack = stack->next) {
if (stack->section && !strcmp(name, stack->section->name))
fatalerror("Section '%s' is already on the stack\n", name);
}
struct Section *sect = getSection(name, type, org, attribs, mod);
changeSection();
curOffset = mod == SECTION_UNION ? 0 : sect->size;
loadOffset = 0; // This is still used when checking for section size overflow!
currentSection = sect;
}
// Set the current section by name and type
void sect_SetLoadSection(char const *name, uint32_t type, uint32_t org,
struct SectionSpec const *attribs, enum SectionModifier mod)
{
// Important info: currently, UNION and LOAD cannot interact, since UNION is prohibited in
// "code" sections, whereas LOAD is restricted to them.
// Therefore, any interactions are NOT TESTED, so lift either of those restrictions at
// your own peril! ^^
if (!checkcodesection())
return;
if (currentLoadSection) {
error("`LOAD` blocks cannot be nested\n");
return;
}
if (sect_HasData(type)) {
error("`LOAD` blocks cannot create a ROM section\n");
return;
}
if (mod == SECTION_FRAGMENT) {
error("`LOAD FRAGMENT` is not allowed\n");
return;
}
struct Section *sect = getSection(name, type, org, attribs, mod);
changeSection();
loadOffset = curOffset - (mod == SECTION_UNION ? 0 : sect->size);
curOffset -= loadOffset;
currentLoadSection = sect;
}
void sect_EndLoadSection(void)
{
if (!currentLoadSection) {
error("Found `ENDL` outside of a `LOAD` block\n");
return;
}
changeSection();
curOffset += loadOffset;
loadOffset = 0;
currentLoadSection = NULL;
}
struct Section *sect_GetSymbolSection(void)
{
return currentLoadSection ? currentLoadSection : currentSection;
}
// The offset into the section above
uint32_t sect_GetSymbolOffset(void)
{
return curOffset;
}
uint32_t sect_GetOutputOffset(void)
{
return curOffset + loadOffset;
}
void sect_AlignPC(uint8_t alignment, uint16_t offset)
{
if (!checksection())
return;
struct Section *sect = sect_GetSymbolSection();
uint16_t alignSize = 1 << alignment; // Size of an aligned "block"
if (sect->org != (uint32_t)-1) {
if ((sym_GetPCValue() - offset) % alignSize)
error("Section's fixed address fails required alignment (PC = $%04" PRIx32
")\n", sym_GetPCValue());
} else if (sect->align != 0) {
if ((((sect->alignOfs + curOffset) % (1 << sect->align)) - offset) % alignSize) {
error("Section's alignment fails required alignment (offset from section start = $%04"
PRIx32 ")\n", curOffset);
} else if (alignment > sect->align) {
sect->align = alignment;
sect->alignOfs = (offset - curOffset) % alignSize;
}
} else {
sect->align = alignment;
// We need `(sect->alignOfs + curOffset) % alignSize == offset
sect->alignOfs = (offset - curOffset) % alignSize;
}
}
static void growSection(uint32_t growth)
{
curOffset += growth;
if (curOffset + loadOffset > currentSection->size)
currentSection->size = curOffset + loadOffset;
if (currentLoadSection && curOffset > currentLoadSection->size)
currentLoadSection->size = curOffset;
}
static void writebyte(uint8_t byte)
{
currentSection->data[sect_GetOutputOffset()] = byte;
growSection(1);
}
static void writeword(uint16_t b)
{
writebyte(b & 0xFF);
writebyte(b >> 8);
}
static void writelong(uint32_t b)
{
writebyte(b & 0xFF);
writebyte(b >> 8);
writebyte(b >> 16);
writebyte(b >> 24);
}
static void createPatch(enum PatchType type, struct Expression const *expr, uint32_t pcShift)
{
out_CreatePatch(type, expr, sect_GetOutputOffset(), pcShift);
}
void sect_StartUnion(void)
{
// Important info: currently, UNION and LOAD cannot interact, since UNION is prohibited in
// "code" sections, whereas LOAD is restricted to them.
// Therefore, any interactions are NOT TESTED, so lift either of those restrictions at
// your own peril! ^^
if (!currentSection) {
error("UNIONs must be inside a SECTION\n");
return;
}
if (sect_HasData(currentSection->type)) {
error("Cannot use UNION inside of ROM0 or ROMX sections\n");
return;
}
struct UnionStackEntry *entry = malloc(sizeof(*entry));
if (!entry)
fatalerror("Failed to allocate new union stack entry: %s\n", strerror(errno));
entry->start = curOffset;
entry->size = 0;
entry->next = unionStack;
unionStack = entry;
}
static void endUnionMember(void)
{
uint32_t memberSize = curOffset - unionStack->start;
if (memberSize > unionStack->size)
unionStack->size = memberSize;
curOffset = unionStack->start;
}
void sect_NextUnionMember(void)
{
if (!unionStack) {
error("Found NEXTU outside of a UNION construct\n");
return;
}
endUnionMember();
}
void sect_EndUnion(void)
{
if (!unionStack) {
error("Found ENDU outside of a UNION construct\n");
return;
}
endUnionMember();
curOffset += unionStack->size;
struct UnionStackEntry *next = unionStack->next;
free(unionStack);
unionStack = next;
}
void sect_CheckUnionClosed(void)
{
if (unionStack)
error("Unterminated UNION construct!\n");
}
// Output an absolute byte
void sect_AbsByte(uint8_t b)
{
if (!checkcodesection())
return;
if (!reserveSpace(1))
return;
writebyte(b);
}
void sect_AbsByteGroup(uint8_t const *s, size_t length)
{
if (!checkcodesection())
return;
if (!reserveSpace(length))
return;
while (length--)
writebyte(*s++);
}
void sect_AbsWordGroup(uint8_t const *s, size_t length)
{
if (!checkcodesection())
return;
if (!reserveSpace(length * 2))
return;
while (length--)
writeword(*s++);
}
void sect_AbsLongGroup(uint8_t const *s, size_t length)
{
if (!checkcodesection())
return;
if (!reserveSpace(length * 4))
return;
while (length--)
writelong(*s++);
}
// Skip this many bytes
void sect_Skip(uint32_t skip, bool ds)
{
if (!checksection())
return;
if (!reserveSpace(skip))
return;
if (!sect_HasData(currentSection->type)) {
growSection(skip);
} else {
if (!ds)
warning(WARNING_EMPTY_DATA_DIRECTIVE, "%s directive without data in ROM\n",
(skip == 4) ? "DL" : (skip == 2) ? "DW" : "DB");
// We know we're in a code SECTION
while (skip--)
writebyte(fillByte);
}
}
// Output a NULL terminated string (excluding the NULL-character)
void sect_String(char const *s)
{
if (!checkcodesection())
return;
if (!reserveSpace(strlen(s)))
return;
while (*s)
writebyte(*s++);
}
// Output a relocatable byte. Checking will be done to see if it
// is an absolute value in disguise.
void sect_RelByte(struct Expression *expr, uint32_t pcShift)
{
if (!checkcodesection())
return;
if (!reserveSpace(1))
return;
if (!rpn_isKnown(expr)) {
createPatch(PATCHTYPE_BYTE, expr, pcShift);
writebyte(0);
} else {
writebyte(expr->val);
}
rpn_Free(expr);
}
// Output several copies of a relocatable byte. Checking will be done to see if
// it is an absolute value in disguise.
void sect_RelBytes(uint32_t n, struct Expression *exprs, size_t size)
{
if (!checkcodesection())
return;
if (!reserveSpace(n))
return;
for (uint32_t i = 0; i < n; i++) {
struct Expression *expr = &exprs[i % size];
if (!rpn_isKnown(expr)) {
createPatch(PATCHTYPE_BYTE, expr, i);
writebyte(0);
} else {
writebyte(expr->val);
}
}
for (size_t i = 0; i < size; i++)
rpn_Free(&exprs[i]);
}
// Output a relocatable word. Checking will be done to see if
// it's an absolute value in disguise.
void sect_RelWord(struct Expression *expr, uint32_t pcShift)
{
if (!checkcodesection())
return;
if (!reserveSpace(2))
return;
if (!rpn_isKnown(expr)) {
createPatch(PATCHTYPE_WORD, expr, pcShift);
writeword(0);
} else {
writeword(expr->val);
}
rpn_Free(expr);
}
// Output a relocatable longword. Checking will be done to see if
// is an absolute value in disguise.
void sect_RelLong(struct Expression *expr, uint32_t pcShift)
{
if (!checkcodesection())
return;
if (!reserveSpace(2))
return;
if (!rpn_isKnown(expr)) {
createPatch(PATCHTYPE_LONG, expr, pcShift);
writelong(0);
} else {
writelong(expr->val);
}
rpn_Free(expr);
}
// Output a PC-relative relocatable byte. Checking will be done to see if it
// is an absolute value in disguise.
void sect_PCRelByte(struct Expression *expr, uint32_t pcShift)
{
if (!checkcodesection())
return;
if (!reserveSpace(1))
return;
struct Symbol const *pc = sym_GetPC();
if (!rpn_IsDiffConstant(expr, pc)) {
createPatch(PATCHTYPE_JR, expr, pcShift);
writebyte(0);
} else {
struct Symbol const *sym = rpn_SymbolOf(expr);
// The offset wraps (jump from ROM to HRAM, for example)
int16_t offset;
// Offset is relative to the byte *after* the operand
if (sym == pc)
offset = -2; // PC as operand to `jr` is lower than reference PC by 2
else
offset = sym_GetValue(sym) - (sym_GetValue(pc) + 1);
if (offset < -128 || offset > 127) {
error("jr target out of reach (expected -129 < %" PRId16 " < 128)\n",
offset);
writebyte(0);
} else {
writebyte(offset);
}
}
rpn_Free(expr);
}
// Output a binary file
void sect_BinaryFile(char const *s, int32_t startPos)
{
if (startPos < 0) {
error("Start position cannot be negative (%" PRId32 ")\n", startPos);
startPos = 0;
}
if (!checkcodesection())
return;
char *fullPath = NULL;
size_t size = 0;
FILE *f = NULL;
if (fstk_FindFile(s, &fullPath, &size))
f = fopen(fullPath, "rb");
free(fullPath);
if (!f) {
if (generatedMissingIncludes) {
if (verbose)
printf("Aborting (-MG) on INCBIN file '%s' (%s)\n", s, strerror(errno));
failedOnMissingInclude = true;
return;
}
error("Error opening INCBIN file '%s': %s\n", s, strerror(errno));
return;
}
int32_t fsize = -1;
int byte;
if (fseek(f, 0, SEEK_END) != -1) {
fsize = ftell(f);
if (startPos > fsize) {
error("Specified start position is greater than length of file\n");
goto cleanup;
}
fseek(f, startPos, SEEK_SET);
if (!reserveSpace(fsize - startPos))
goto cleanup;
} else {
error("Error determining size of INCBIN file '%s': %s\n",
s, strerror(errno));
// The file isn't seekable, so we'll just skip bytes
while (startPos--)
(void)fgetc(f);
}
while ((byte = fgetc(f)) != EOF) {
if (fsize == -1)
growSection(1);
writebyte(byte);
}
if (ferror(f))
error("Error reading INCBIN file '%s': %s\n", s, strerror(errno));
cleanup:
fclose(f);
}
void sect_BinaryFileSlice(char const *s, int32_t start_pos, int32_t length)
{
if (start_pos < 0) {
error("Start position cannot be negative (%" PRId32 ")\n", start_pos);
start_pos = 0;
}
if (length < 0) {
error("Number of bytes to read cannot be negative (%" PRId32 ")\n", length);
length = 0;
}
if (!checkcodesection())
return;
if (length == 0) // Don't even bother with 0-byte slices
return;
if (!reserveSpace(length))
return;
char *fullPath = NULL;
size_t size = 0;
FILE *f = NULL;
if (fstk_FindFile(s, &fullPath, &size))
f = fopen(fullPath, "rb");
free(fullPath);
if (!f) {
if (generatedMissingIncludes) {
if (verbose)
printf("Aborting (-MG) on INCBIN file '%s' (%s)\n", s, strerror(errno));
failedOnMissingInclude = true;
} else {
error("Error opening INCBIN file '%s': %s\n", s, strerror(errno));
}
return;
}
int32_t fsize;
if (fseek(f, 0, SEEK_END) != -1) {
fsize = ftell(f);
if (start_pos > fsize) {
error("Specified start position is greater than length of file\n");
goto cleanup;
}
if ((start_pos + length) > fsize) {
error("Specified range in INCBIN is out of bounds (%" PRIu32 " + %" PRIu32
" > %" PRIu32 ")\n", start_pos, length, fsize);
goto cleanup;
}
fseek(f, start_pos, SEEK_SET);
} else {
error("Error determining size of INCBIN file '%s': %s\n",
s, strerror(errno));
// The file isn't seekable, so we'll just skip bytes
while (start_pos--)
(void)fgetc(f);
}
while (length--) {
int byte = fgetc(f);
if (byte != EOF) {
writebyte(byte);
} else if (ferror(f)) {
error("Error reading INCBIN file '%s': %s\n", s, strerror(errno));
} else {
error("Premature end of file (%" PRId32 " bytes left to read)\n",
length + 1);
}
}
cleanup:
fclose(f);
}
// Section stack routines
void sect_PushSection(void)
{
struct SectionStackEntry *entry = malloc(sizeof(*entry));
if (entry == NULL)
fatalerror("No memory for section stack: %s\n", strerror(errno));
entry->section = currentSection;
entry->loadSection = currentLoadSection;
entry->scope = sym_GetCurrentSymbolScope();
entry->offset = curOffset;
entry->loadOffset = loadOffset;
entry->unionStack = unionStack;
entry->next = sectionStack;
sectionStack = entry;
// Reset the section scope
currentSection = NULL;
currentLoadSection = NULL;
sym_SetCurrentSymbolScope(NULL);
unionStack = NULL;
}
void sect_PopSection(void)
{
if (!sectionStack)
fatalerror("No entries in the section stack\n");
if (currentLoadSection)
fatalerror("Cannot change the section within a `LOAD` block!\n");
struct SectionStackEntry *entry = sectionStack;
changeSection();
currentSection = entry->section;
currentLoadSection = entry->loadSection;
sym_SetCurrentSymbolScope(entry->scope);
curOffset = entry->offset;
loadOffset = entry->loadOffset;
unionStack = entry->unionStack;
sectionStack = entry->next;
free(entry);
}
bool sect_IsSizeKnown(struct Section const *sect)
{
// SECTION UNION and SECTION FRAGMENT can still grow
if (sect->modifier != SECTION_NORMAL)
return false;
// The current section (or current load section if within one) is still growing
if (sect == currentSection || sect == currentLoadSection)
return false;
// Any section on the stack is still growing
for (struct SectionStackEntry *stack = sectionStack; stack; stack = stack->next) {
if (stack->section && !strcmp(sect->name, stack->section->name))
return false;
}
return true;
}