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Refactor to reduce nesting depth some more (#1740)

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This commit is contained in:
Rangi
2025-07-09 22:46:40 -04:00
committed by GitHub
parent bf6875f160
commit 34cf959c9d
8 changed files with 348 additions and 356 deletions
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31
src/asm/lexer.cpp
View File

@@ -1735,6 +1735,23 @@ static bool isGarbageCharacter(int c) {
&& (c == '\0' || !strchr("; \t~[](),+-*/|^=!<>:&%`\"\r\n\\", c));
}
static void reportGarbageCharacters(int c) {
// '#' can be garbage if it doesn't start a raw string or identifier
assume(isGarbageCharacter(c) || c == '#');
if (isGarbageCharacter(peek())) {
// At least two characters are garbage; group them into one error report
std::string garbage = printChar(c);
while (isGarbageCharacter(peek())) {
c = nextChar();
garbage += ", ";
garbage += printChar(c);
}
error("Unknown characters %s", garbage.c_str());
} else {
error("Unknown character %s", printChar(c));
}
}
static Token yylex_NORMAL() {
if (int nextToken = lexerState->nextToken; nextToken) {
lexerState->nextToken = 0;
@@ -2083,19 +2100,7 @@ static Token yylex_NORMAL() {
// Do not report weird characters when capturing, it'll be done later
if (!lexerState->capturing) {
assume(isGarbageCharacter(c) || c == '#');
if (isGarbageCharacter(peek())) {
// At least two characters are garbage; group them into one error report
std::string garbage = printChar(c);
while (isGarbageCharacter(peek())) {
c = nextChar();
garbage += ", ";
garbage += printChar(c);
}
error("Unknown characters %s", garbage.c_str());
} else {
error("Unknown character %s", printChar(c));
}
reportGarbageCharacters(c);
}
}
lexerState->atLineStart = false;

86
src/asm/main.cpp
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@@ -124,6 +124,51 @@ static void fatalWithUsage(char const *fmt, ...) {
exit(1);
}
// Parse a comma-separated string of '-s/--state' features
static std::vector<StateFeature> parseStateFeatures(char *str) {
std::vector<StateFeature> features;
for (char *feature = str; feature;) {
// Split "<feature>,<rest>" so `feature` is "<feature>" and `next` is "<rest>"
char *next = strchr(feature, ',');
if (next) {
*next++ = '\0';
}
// Trim whitespace from the beginning of `feature`...
feature += strspn(feature, " \t");
// ...and from the end
if (char *end = strpbrk(feature, " \t"); end) {
*end = '\0';
}
// A feature must be specified
if (*feature == '\0') {
fatal("Empty feature for option 's'");
}
// Parse the `feature` and update the `features` list
if (!strcasecmp(feature, "all")) {
if (!features.empty()) {
warnx("Redundant feature before \"%s\" for option 's'", feature);
}
features.assign({STATE_EQU, STATE_VAR, STATE_EQUS, STATE_CHAR, STATE_MACRO});
} else {
StateFeature value = !strcasecmp(feature, "equ") ? STATE_EQU
: !strcasecmp(feature, "var") ? STATE_VAR
: !strcasecmp(feature, "equs") ? STATE_EQUS
: !strcasecmp(feature, "char") ? STATE_CHAR
: !strcasecmp(feature, "macro") ? STATE_MACRO
: NB_STATE_FEATURES;
if (value == NB_STATE_FEATURES) {
fatal("Invalid feature for option 's': \"%s\"", feature);
} else if (std::find(RANGE(features), value) != features.end()) {
warnx("Ignoring duplicate feature for option 's': \"%s\"", feature);
} else {
features.push_back(value);
}
}
feature = next;
}
return features;
}
int main(int argc, char *argv[]) {
time_t now = time(nullptr);
// Support SOURCE_DATE_EPOCH for reproducible builds
@@ -278,46 +323,7 @@ int main(int argc, char *argv[]) {
}
*name++ = '\0';
std::vector<StateFeature> features;
for (char *feature = musl_optarg; feature;) {
// Split "<feature>,<rest>" so `feature` is "<feature>" and `next` is "<rest>"
char *next = strchr(feature, ',');
if (next) {
*next++ = '\0';
}
// Trim whitespace from the beginning of `feature`...
feature += strspn(feature, " \t");
// ...and from the end
if (char *end = strpbrk(feature, " \t"); end) {
*end = '\0';
}
// A feature must be specified
if (*feature == '\0') {
fatal("Empty feature for option 's'");
}
// Parse the `feature` and update the `features` list
if (!strcasecmp(feature, "all")) {
if (!features.empty()) {
warnx("Redundant feature before \"%s\" for option 's'", feature);
}
features.assign({STATE_EQU, STATE_VAR, STATE_EQUS, STATE_CHAR, STATE_MACRO});
} else {
StateFeature value = !strcasecmp(feature, "equ") ? STATE_EQU
: !strcasecmp(feature, "var") ? STATE_VAR
: !strcasecmp(feature, "equs") ? STATE_EQUS
: !strcasecmp(feature, "char") ? STATE_CHAR
: !strcasecmp(feature, "macro") ? STATE_MACRO
: NB_STATE_FEATURES;
if (value == NB_STATE_FEATURES) {
fatal("Invalid feature for option 's': \"%s\"", feature);
} else if (std::find(RANGE(features), value) != features.end()) {
warnx("Ignoring duplicate feature for option 's': \"%s\"", feature);
} else {
features.push_back(value);
}
}
feature = next;
}
std::vector<StateFeature> features = parseStateFeatures(musl_optarg);
if (stateFileSpecs.find(name) != stateFileSpecs.end()) {
warnx("Overriding state filename %s", name);

2
src/extern/getopt.cpp vendored
View File

@@ -1,6 +1,6 @@
// SPDX-License-Identifier: MIT
// This implementation was taken from musl and modified for RGBDS
// This implementation was taken from musl and modified for RGBDS.
#include "extern/getopt.hpp"

12
src/extern/utf8decoder.cpp vendored
View File

@@ -1,6 +1,8 @@
// SPDX-License-Identifier: MIT
// UTF-8 decoder: http://bjoern.hoehrmann.de/utf-8/decoder/dfa/
// This implementation was taken from
// http://bjoern.hoehrmann.de/utf-8/decoder/dfa/
// and modified for RGBDS.
#include "extern/utf8decoder.hpp"
@@ -33,10 +35,8 @@ static uint8_t const utf8d[] = {
};
uint32_t decode(uint32_t *state, uint32_t *codep, uint8_t byte) {
uint32_t type = utf8d[byte];
*codep = (*state != 0) ? (byte & 0x3FU) | (*codep << 6) : (0xFF >> type) & (byte);
*state = utf8d[256 + *state * 16 + type];
uint8_t type = utf8d[byte];
*codep = *state != 0 ? (byte & 0b111111) | (*codep << 6) : byte & (0xFF >> type);
*state = utf8d[0x100 + *state * 0x10 + type];
return *state;
}

5
src/fix/main.cpp
View File

@@ -461,10 +461,7 @@ static MbcType parseMBC(char const *name) {
break;
case 'A':
case 'a':
if (*ptr != 'M' && *ptr != 'm') {
return MBC_BAD;
}
ptr++;
tryReadSlice("M");
features |= RAM;
break;
default:

272
src/gfx/main.cpp
View File

@@ -594,6 +594,143 @@ static char *parseArgv(int argc, char *argv[]) {
return nullptr; // Done processing this argv
}
static void verboseOutputConfig() {
fprintf(stderr, "rgbgfx %s\n", get_package_version_string());
if (options.verbosity >= Options::VERB_VVVVVV) {
putc('\n', stderr);
// clang-format off: vertically align values
static std::array<uint16_t, 21> gfx{
0b0111111110,
0b1111111111,
0b1110011001,
0b1110011001,
0b1111111111,
0b1111111111,
0b1110000001,
0b1111000011,
0b0111111110,
0b0001111000,
0b0111111110,
0b1111111111,
0b1111111111,
0b1111111111,
0b1101111011,
0b1101111011,
0b0011111100,
0b0011001100,
0b0111001110,
0b0111001110,
0b0111001110,
};
// clang-format on
static std::array<char const *, 3> textbox{
" ,----------------------------------------.",
" | Augh, dimensional interference again?! |",
" `----------------------------------------'",
};
for (size_t i = 0; i < gfx.size(); ++i) {
uint16_t row = gfx[i];
for (uint8_t _ = 0; _ < 10; ++_) {
unsigned char c = row & 1 ? '0' : ' ';
putc(c, stderr);
// Double the pixel horizontally, otherwise the aspect ratio looks wrong
putc(c, stderr);
row >>= 1;
}
if (i < textbox.size()) {
fputs(textbox[i], stderr);
}
putc('\n', stderr);
}
putc('\n', stderr);
}
fputs("Options:\n", stderr);
if (options.columnMajor) {
fputs("\tVisit image in column-major order\n", stderr);
}
if (options.allowDedup) {
fputs("\tAllow deduplicating tiles\n", stderr);
}
if (options.allowMirroringX) {
fputs("\tAllow deduplicating horizontally mirrored tiles\n", stderr);
}
if (options.allowMirroringY) {
fputs("\tAllow deduplicating vertically mirrored tiles\n", stderr);
}
if (options.useColorCurve) {
fputs("\tUse color curve\n", stderr);
}
fprintf(stderr, "\tBit depth: %" PRIu8 "bpp\n", options.bitDepth);
if (options.trim != 0) {
fprintf(stderr, "\tTrim the last %" PRIu64 " tiles\n", options.trim);
}
fprintf(stderr, "\tMaximum %" PRIu16 " palettes\n", options.nbPalettes);
fprintf(stderr, "\tPalettes contain %" PRIu8 " colors\n", options.nbColorsPerPal);
fprintf(stderr, "\t%s palette spec\n", [] {
switch (options.palSpecType) {
case Options::NO_SPEC:
return "No";
case Options::EXPLICIT:
return "Explicit";
case Options::EMBEDDED:
return "Embedded";
case Options::DMG:
return "DMG";
}
return "???";
}());
if (options.palSpecType == Options::EXPLICIT) {
fputs("\t[\n", stderr);
for (auto const &pal : options.palSpec) {
fputs("\t\t", stderr);
for (auto &color : pal) {
if (color) {
fprintf(stderr, "#%06x, ", color->toCSS() >> 8);
} else {
fputs("#none, ", stderr);
}
}
putc('\n', stderr);
}
fputs("\t]\n", stderr);
}
fprintf(
stderr,
"\tInput image slice: %" PRIu16 "x%" PRIu16 " pixels starting at (%" PRIu16 ", %" PRIu16
")\n",
options.inputSlice.width,
options.inputSlice.height,
options.inputSlice.left,
options.inputSlice.top
);
fprintf(
stderr,
"\tBase tile IDs: [%" PRIu8 ", %" PRIu8 "]\n",
options.baseTileIDs[0],
options.baseTileIDs[1]
);
fprintf(stderr, "\tBase palette ID: %" PRIu8 "\n", options.basePalID);
fprintf(
stderr,
"\tMaximum %" PRIu16 " tiles in bank 0, %" PRIu16 " in bank 1\n",
options.maxNbTiles[0],
options.maxNbTiles[1]
);
auto printPath = [](char const *name, std::string const &path) {
if (!path.empty()) {
fprintf(stderr, "\t%s: %s\n", name, path.c_str());
}
};
printPath("Input image", options.input);
printPath("Output tile data", options.output);
printPath("Output tilemap", options.tilemap);
printPath("Output attrmap", options.attrmap);
printPath("Output palettes", options.palettes);
fputs("Ready.\n", stderr);
}
int main(int argc, char *argv[]) {
struct AtFileStackEntry {
int parentInd; // Saved offset into parent argv
@@ -714,140 +851,7 @@ int main(int argc, char *argv[]) {
// LCOV_EXCL_START
if (options.verbosity >= Options::VERB_CFG) {
fprintf(stderr, "rgbgfx %s\n", get_package_version_string());
if (options.verbosity >= Options::VERB_VVVVVV) {
putc('\n', stderr);
// clang-format off: vertically align values
static std::array<uint16_t, 21> gfx{
0b0111111110,
0b1111111111,
0b1110011001,
0b1110011001,
0b1111111111,
0b1111111111,
0b1110000001,
0b1111000011,
0b0111111110,
0b0001111000,
0b0111111110,
0b1111111111,
0b1111111111,
0b1111111111,
0b1101111011,
0b1101111011,
0b0011111100,
0b0011001100,
0b0111001110,
0b0111001110,
0b0111001110,
};
// clang-format on
static std::array<char const *, 3> textbox{
" ,----------------------------------------.",
" | Augh, dimensional interference again?! |",
" `----------------------------------------'",
};
for (size_t i = 0; i < gfx.size(); ++i) {
uint16_t row = gfx[i];
for (uint8_t _ = 0; _ < 10; ++_) {
unsigned char c = row & 1 ? '0' : ' ';
putc(c, stderr);
// Double the pixel horizontally, otherwise the aspect ratio looks wrong
putc(c, stderr);
row >>= 1;
}
if (i < textbox.size()) {
fputs(textbox[i], stderr);
}
putc('\n', stderr);
}
putc('\n', stderr);
}
fputs("Options:\n", stderr);
if (options.columnMajor) {
fputs("\tVisit image in column-major order\n", stderr);
}
if (options.allowDedup) {
fputs("\tAllow deduplicating tiles\n", stderr);
}
if (options.allowMirroringX) {
fputs("\tAllow deduplicating horizontally mirrored tiles\n", stderr);
}
if (options.allowMirroringY) {
fputs("\tAllow deduplicating vertically mirrored tiles\n", stderr);
}
if (options.useColorCurve) {
fputs("\tUse color curve\n", stderr);
}
fprintf(stderr, "\tBit depth: %" PRIu8 "bpp\n", options.bitDepth);
if (options.trim != 0) {
fprintf(stderr, "\tTrim the last %" PRIu64 " tiles\n", options.trim);
}
fprintf(stderr, "\tMaximum %" PRIu16 " palettes\n", options.nbPalettes);
fprintf(stderr, "\tPalettes contain %" PRIu8 " colors\n", options.nbColorsPerPal);
fprintf(stderr, "\t%s palette spec\n", [] {
switch (options.palSpecType) {
case Options::NO_SPEC:
return "No";
case Options::EXPLICIT:
return "Explicit";
case Options::EMBEDDED:
return "Embedded";
case Options::DMG:
return "DMG";
}
return "???";
}());
if (options.palSpecType == Options::EXPLICIT) {
fputs("\t[\n", stderr);
for (auto const &pal : options.palSpec) {
fputs("\t\t", stderr);
for (auto &color : pal) {
if (color) {
fprintf(stderr, "#%06x, ", color->toCSS() >> 8);
} else {
fputs("#none, ", stderr);
}
}
putc('\n', stderr);
}
fputs("\t]\n", stderr);
}
fprintf(
stderr,
"\tInput image slice: %" PRIu16 "x%" PRIu16 " pixels starting at (%" PRIu16 ", %" PRIu16
")\n",
options.inputSlice.width,
options.inputSlice.height,
options.inputSlice.left,
options.inputSlice.top
);
fprintf(
stderr,
"\tBase tile IDs: [%" PRIu8 ", %" PRIu8 "]\n",
options.baseTileIDs[0],
options.baseTileIDs[1]
);
fprintf(stderr, "\tBase palette ID: %" PRIu8 "\n", options.basePalID);
fprintf(
stderr,
"\tMaximum %" PRIu16 " tiles in bank 0, %" PRIu16 " in bank 1\n",
options.maxNbTiles[0],
options.maxNbTiles[1]
);
auto printPath = [](char const *name, std::string const &path) {
if (!path.empty()) {
fprintf(stderr, "\t%s: %s\n", name, path.c_str());
}
};
printPath("Input image", options.input);
printPath("Output tile data", options.output);
printPath("Output tilemap", options.tilemap);
printPath("Output attrmap", options.attrmap);
printPath("Output palettes", options.palettes);
fputs("Ready.\n", stderr);
verboseOutputConfig();
}
// LCOV_EXCL_STOP

94
src/link/assign.cpp
View File

@@ -122,49 +122,49 @@ static ssize_t getPlacement(Section const &section, MemoryLocation &location) {
if (spaceIdx < bankMem.size()) {
location.address = bankMem[spaceIdx].address;
}
// Process locations in that bank
while (spaceIdx < bankMem.size()) {
// If that location is OK, return it
if (isLocationSuitable(section, bankMem[spaceIdx], location)) {
return spaceIdx;
}
// Go to the next *possible* location
if (section.isAddressFixed) {
// If the address is fixed, there can be only
// one candidate block per bank; if we already
// reached it, give up.
if (location.address < section.org) {
location.address = section.org;
} else {
break; // Try again in next bank
}
} else if (section.isAlignFixed) {
// Move to next aligned location
// Move back to alignment boundary
location.address -= section.alignOfs;
// Ensure we're there (e.g. on first check)
location.address &= ~section.alignMask;
// Go to next align boundary and add offset
location.address += section.alignMask + 1 + section.alignOfs;
} else {
// Any location is fine, so, next free block
spaceIdx++;
if (spaceIdx < bankMem.size()) {
location.address = bankMem[spaceIdx].address;
}
}
// If that location is past the current block's end,
// go forwards until that is no longer the case.
while (spaceIdx < bankMem.size()
&& location.address >= bankMem[spaceIdx].address + bankMem[spaceIdx].size) {
spaceIdx++;
}
// Try again with the new location/free space combo
// Process locations in that bank
while (spaceIdx < bankMem.size()) {
// If that location is OK, return it
if (isLocationSuitable(section, bankMem[spaceIdx], location)) {
return spaceIdx;
}
// Go to the next *possible* location
if (section.isAddressFixed) {
// If the address is fixed, there can be only
// one candidate block per bank; if we already
// reached it, give up.
if (location.address < section.org) {
location.address = section.org;
} else {
break; // Try again in next bank
}
} else if (section.isAlignFixed) {
// Move to next aligned location
// Move back to alignment boundary
location.address -= section.alignOfs;
// Ensure we're there (e.g. on first check)
location.address &= ~section.alignMask;
// Go to next align boundary and add offset
location.address += section.alignMask + 1 + section.alignOfs;
} else {
// Any location is fine, so, next free block
spaceIdx++;
if (spaceIdx < bankMem.size()) {
location.address = bankMem[spaceIdx].address;
}
}
// If that location is past the current block's end,
// go forwards until that is no longer the case.
while (spaceIdx < bankMem.size()
&& location.address >= bankMem[spaceIdx].address + bankMem[spaceIdx].size) {
spaceIdx++;
}
// Try again with the new location/free space combo
}
// Try again in the next bank, if one is available.
@@ -208,22 +208,22 @@ static ssize_t getPlacement(Section const &section, MemoryLocation &location) {
// Places a section in a suitable location, or error out if it fails to.
// Due to the implemented algorithm, this should be called with sections of decreasing size!
static void placeSection(Section &section) {
MemoryLocation location;
// Specially handle 0-byte SECTIONs, as they can't overlap anything
if (section.size == 0) {
// Unless the SECTION's address was fixed, the starting address
// is fine for any alignment, as checked in sect_DoSanityChecks.
location.address =
section.isAddressFixed ? section.org : sectionTypeInfo[section.type].startAddr;
location.bank =
section.isBankFixed ? section.bank : sectionTypeInfo[section.type].firstBank;
MemoryLocation location = {
.address =
section.isAddressFixed ? section.org : sectionTypeInfo[section.type].startAddr,
.bank = section.isBankFixed ? section.bank : sectionTypeInfo[section.type].firstBank,
};
assignSection(section, location);
return;
}
// Place section using first-fit decreasing algorithm
// https://en.wikipedia.org/wiki/Bin_packing_problem#First-fit_algorithm
MemoryLocation location;
if (ssize_t spaceIdx = getPlacement(section, location); spaceIdx != -1) {
std::deque<FreeSpace> &bankMem =
memory[section.type][location.bank - sectionTypeInfo[section.type].firstBank];

202
src/link/output.cpp
View File

@@ -168,7 +168,6 @@ static uint8_t getNextFillByte() {
return padValue;
}
// Write a ROM bank's sections, ordered by increasing address, to the output file.
static void
writeBank(std::deque<Section const *> *bankSections, uint16_t baseOffset, uint16_t size) {
uint16_t offset = 0;
@@ -202,7 +201,6 @@ static void
}
}
// Writes a ROM file to the output.
static void writeROM() {
if (outputFileName) {
if (strcmp(outputFileName, "-")) {
@@ -263,9 +261,7 @@ static void writeROM() {
}
}
// Prints a symbol's name to a file, assuming that the first character is legal.
// Illegal characters are UTF-8-decoded (errors are replaced by U+FFFD) and emitted as '\u'/'\U'.
static void printSymName(std::string const &name, FILE *file) {
static void writeSymName(std::string const &name, FILE *file) {
for (char const *ptr = name.c_str(); *ptr != '\0';) {
char c = *ptr;
@@ -274,7 +270,7 @@ static void printSymName(std::string const &name, FILE *file) {
putc(c, file);
++ptr;
} else {
// Output illegal characters using Unicode escapes
// Output illegal characters using Unicode escapes ('\u' or '\U')
// Decode the UTF-8 codepoint; or at least attempt to
uint32_t state = 0, codepoint;
@@ -323,27 +319,26 @@ static bool compareSymbols(SortedSymbol const &sym1, SortedSymbol const &sym2) {
return sym1_name < sym2_name;
}
// Write a bank's contents to the sym file
static void writeSymBank(SortedSections const &bankSections, SectionType type, uint32_t bank) {
#define forEachSortedSection(sect, ...) \
do { \
for (auto it = bankSections.zeroLenSections.begin(); \
it != bankSections.zeroLenSections.end(); \
it++) { \
for (Section const *sect = *it; sect; sect = sect->nextu.get()) { \
__VA_ARGS__ \
} \
} \
for (auto it = bankSections.sections.begin(); it != bankSections.sections.end(); it++) { \
for (Section const *sect = *it; sect; sect = sect->nextu.get()) { \
__VA_ARGS__ \
} \
} \
} while (0)
template<typename F>
static void forEachSortedSection(SortedSections const &bankSections, F callback) {
for (Section const *sect : bankSections.zeroLenSections) {
for (; sect; sect = sect->nextu.get()) {
callback(*sect);
}
}
for (Section const *sect : bankSections.sections) {
for (; sect; sect = sect->nextu.get()) {
callback(*sect);
}
}
}
static void writeSymBank(SortedSections const &bankSections, SectionType type, uint32_t bank) {
uint32_t nbSymbols = 0;
forEachSortedSection(sect, { nbSymbols += sect->symbols.size(); });
forEachSortedSection(bankSections, [&](Section const &sect) {
nbSymbols += sect.symbols.size();
});
if (!nbSymbols) {
return;
@@ -353,36 +348,35 @@ static void writeSymBank(SortedSections const &bankSections, SectionType type, u
symList.reserve(nbSymbols);
forEachSortedSection(sect, {
for (Symbol const *sym : sect->symbols) {
forEachSortedSection(bankSections, [&](Section const &sect) {
for (Symbol const *sym : sect.symbols) {
// Don't output symbols that begin with an illegal character
if (!sym->name.empty() && startsIdentifier(sym->name[0])) {
uint16_t addr = static_cast<uint16_t>(sym->label().offset + sect->org);
uint16_t parentAddr = addr;
if (auto pos = sym->name.find('.'); pos != std::string::npos) {
std::string parentName = sym->name.substr(0, pos);
if (Symbol const *parentSym = sym_GetSymbol(parentName);
parentSym && std::holds_alternative<Label>(parentSym->data)) {
auto const &parentLabel = parentSym->label();
assume(parentLabel.section != nullptr);
parentAddr =
static_cast<uint16_t>(parentLabel.offset + parentLabel.section->org);
}
}
symList.push_back({.sym = sym, .addr = addr, .parentAddr = parentAddr});
if (sym->name.empty() || !startsIdentifier(sym->name[0])) {
continue;
}
uint16_t addr = static_cast<uint16_t>(sym->label().offset + sect.org);
uint16_t parentAddr = addr;
if (auto pos = sym->name.find('.'); pos != std::string::npos) {
std::string parentName = sym->name.substr(0, pos);
if (Symbol const *parentSym = sym_GetSymbol(parentName);
parentSym && std::holds_alternative<Label>(parentSym->data)) {
auto const &parentLabel = parentSym->label();
assume(parentLabel.section != nullptr);
parentAddr =
static_cast<uint16_t>(parentLabel.offset + parentLabel.section->org);
}
}
symList.push_back({.sym = sym, .addr = addr, .parentAddr = parentAddr});
}
});
#undef forEachSortedSection
std::stable_sort(RANGE(symList), compareSymbols);
uint32_t symBank = bank + sectionTypeInfo[type].firstBank;
for (SortedSymbol &sym : symList) {
fprintf(symFile, "%02" PRIx32 ":%04" PRIx16 " ", symBank, sym.addr);
printSymName(sym.sym->name, symFile);
writeSymName(sym.sym->name, symFile);
putc('\n', symFile);
}
}
@@ -402,8 +396,7 @@ static void writeEmptySpace(uint16_t begin, uint16_t end) {
}
}
// Prints a section's name to a file.
static void printSectionName(std::string const &name, FILE *file) {
static void writeSectionName(std::string const &name, FILE *file) {
for (char c : name) {
// Escape characters that need escaping
switch (c) {
@@ -427,7 +420,47 @@ static void printSectionName(std::string const &name, FILE *file) {
}
}
// Write a bank's contents to the map file
template<typename F>
uint16_t forEachSection(SortedSections const &sectList, F callback) {
uint16_t used = 0;
auto section = sectList.sections.begin();
auto zeroLenSection = sectList.zeroLenSections.begin();
while (section != sectList.sections.end() || zeroLenSection != sectList.zeroLenSections.end()) {
// Pick the lowest section by address out of the two
auto &pickedSection = section == sectList.sections.end() ? zeroLenSection
: zeroLenSection == sectList.zeroLenSections.end() ? section
: (*section)->org < (*zeroLenSection)->org ? section
: zeroLenSection;
used += (*pickedSection)->size;
callback(**pickedSection);
pickedSection++;
}
return used;
}
static void writeMapSymbols(Section const *sect) {
for (uint16_t org = sect->org; sect; sect = sect->nextu.get()) {
for (Symbol *sym : sect->symbols) {
// Don't output symbols that begin with an illegal character
if (sym->name.empty() || !startsIdentifier(sym->name[0])) {
continue;
}
// Space matches "\tSECTION: $xxxx ..."
fprintf(mapFile, "\t $%04" PRIx32 " = ", sym->label().offset + org);
writeSymName(sym->name, mapFile);
putc('\n', mapFile);
}
// Announce the following "piece"
if (SectionModifier mod = sect->nextu ? sect->nextu->modifier : SECTION_NORMAL;
mod == SECTION_UNION) {
fputs("\t ; Next union\n", mapFile);
} else if (mod == SECTION_FRAGMENT) {
fputs("\t ; Next fragment\n", mapFile);
}
}
}
static void writeMapBank(SortedSections const &sectList, SectionType type, uint32_t bank) {
fprintf(
mapFile,
@@ -436,60 +469,27 @@ static void writeMapBank(SortedSections const &sectList, SectionType type, uint3
bank + sectionTypeInfo[type].firstBank
);
uint16_t used = 0;
auto section = sectList.sections.begin();
auto zeroLenSection = sectList.zeroLenSections.begin();
uint16_t prevEndAddr = sectionTypeInfo[type].startAddr;
uint16_t used = forEachSection(sectList, [&](Section const &sect) {
assume(sect.offset == 0);
while (section != sectList.sections.end() || zeroLenSection != sectList.zeroLenSections.end()) {
// Pick the lowest section by address out of the two
auto &pickedSection = section == sectList.sections.end() ? zeroLenSection
: zeroLenSection == sectList.zeroLenSections.end() ? section
: (*section)->org < (*zeroLenSection)->org ? section
: zeroLenSection;
Section const *sect = *pickedSection;
writeEmptySpace(prevEndAddr, sect.org);
used += sect->size;
assume(sect->offset == 0);
prevEndAddr = sect.org + sect.size;
writeEmptySpace(prevEndAddr, sect->org);
prevEndAddr = sect->org + sect->size;
fprintf(mapFile, "\tSECTION: $%04" PRIx16, sect->org);
if (sect->size != 0) {
fprintf(mapFile, "\tSECTION: $%04" PRIx16, sect.org);
if (sect.size != 0) {
fprintf(mapFile, "-$%04x", prevEndAddr - 1);
}
fprintf(mapFile, " ($%04" PRIx16 " byte%s) [\"", sect->size, sect->size == 1 ? "" : "s");
printSectionName(sect->name, mapFile);
fprintf(mapFile, " ($%04" PRIx16 " byte%s) [\"", sect.size, sect.size == 1 ? "" : "s");
writeSectionName(sect.name, mapFile);
fputs("\"]\n", mapFile);
if (!noSymInMap) {
// Also print symbols in the following "pieces"
for (uint16_t org = sect->org; sect; sect = sect->nextu.get()) {
for (Symbol *sym : sect->symbols) {
// Don't output symbols that begin with an illegal character
if (!sym->name.empty() && startsIdentifier(sym->name[0])) {
// Space matches "\tSECTION: $xxxx ..."
fprintf(mapFile, "\t $%04" PRIx32 " = ", sym->label().offset + org);
printSymName(sym->name, mapFile);
putc('\n', mapFile);
}
}
if (sect->nextu) {
// Announce the following "piece"
if (sect->nextu->modifier == SECTION_UNION) {
fputs("\t ; Next union\n", mapFile);
} else if (sect->nextu->modifier == SECTION_FRAGMENT) {
fputs("\t ; Next fragment\n", mapFile);
}
}
}
writeMapSymbols(&sect);
}
pickedSection++;
}
});
if (used == 0) {
fputs("\tEMPTY\n", mapFile);
@@ -504,7 +504,6 @@ static void writeMapBank(SortedSections const &sectList, SectionType type, uint3
}
}
// Write the total used and free space by section type to the map file
static void writeMapSummary() {
fputs("SUMMARY:\n", mapFile);
@@ -525,24 +524,7 @@ static void writeMapSummary() {
uint32_t usedTotal = 0;
for (uint32_t bank = 0; bank < nbBanks; bank++) {
uint16_t used = 0;
auto &sectList = sections[type][bank];
auto section = sectList.sections.begin();
auto zeroLenSection = sectList.zeroLenSections.begin();
while (section != sectList.sections.end()
|| zeroLenSection != sectList.zeroLenSections.end()) {
// Pick the lowest section by address out of the two
auto &pickedSection = section == sectList.sections.end() ? zeroLenSection
: zeroLenSection == sectList.zeroLenSections.end() ? section
: (*section)->org < (*zeroLenSection)->org ? section
: zeroLenSection;
used += (*pickedSection)->size;
pickedSection++;
}
usedTotal += used;
usedTotal += forEachSection(sections[type][bank], [](Section const &) {});
}
fprintf(
@@ -560,7 +542,6 @@ static void writeMapSummary() {
}
}
// Writes the sym file, if applicable.
static void writeSym() {
if (!symFileName) {
return;
@@ -606,12 +587,11 @@ static void writeSym() {
int32_t val = std::get<int32_t>(sym->data);
int width = val < 0x100 ? 2 : val < 0x10000 ? 4 : 8;
fprintf(symFile, "%0*" PRIx32 " ", width, val);
printSymName(sym->name, symFile);
writeSymName(sym->name, symFile);
putc('\n', symFile);
}
}
// Writes the map file, if applicable.
static void writeMap() {
if (!mapFileName) {
return;