remove djstdlib hardcopy

1 week ago · 133a02593d
--- a/djstdlib/.clangd
+++ b/djstdlib/.clangd
@@ -1,3 +0,0 @@
 CompileFlags:
  Add: 
    - -DOS_LINUX
--- a/djstdlib/app.cpp
+++ b/djstdlib/app.cpp
@@ -1,14 +0,0 @@
 #include <stdio.h>
 #include "core.cpp"
 #include "core.h"
 int main(int argc, char **argv) {
    int statusCode = 0;
    initialiseCore();
    Arena *arena = arenaAlloc(Megabytes(64));
    list<string> args = getArgs(arena, argc, argv);
    prinft("%S", strSplit(arena, "-"_s, "hallo-world"_s));
    return statusCode;
 }
--- a/djstdlib/build
+++ b/djstdlib/build
@@ -1,3 +0,0 @@
 #!/bin/bash
 g++ -g -g3 -lm -DOS_LINUX=1 -DENABLE_ASSERT=1 ./app.cpp -o ./target/app
--- a/djstdlib/build.bat
+++ b/djstdlib/build.bat
@@ -1,27 +0,0 @@
@echo off
 if NOT EXIST .\target mkdir .\target
 set commonLinkerFlags=-opt:ref
 set commonCompilerFlags=^
    -MT                                                             %= Make sure the C runtime library is statically linked =%^
    -Gm-                                                            %= Turns off incremental building =%^
    -nologo                                                         %= No one cares you made the compiler Microsoft =%^
    -Oi                                                             %= Always use intrinsics  =%^
    -EHa-                                                           %= Disable exception handling =%^
    -GR-                                                            %= Never use runtime type info from C++ =%^
    -WX -W4 -wd4201 -wd4100 -wd4189 -wd4505                         %= Compiler warnings, -WX warnings as errors, -W4 warning level 4, -wdXXXX disable warning XXXX =%^
    -DAPP_DEBUG=0 -DENABLE_ASSERT=1 -DOS_WINDOWS=1                  %= Custom #defines =%^
    -D_CRT_SECURE_NO_WARNINGS=1^
    -FC                                                             %= Full path of source code file in diagnostics =%^
    -Zi                                                             %= Generate debugger info =%
 pushd .\target
 cl %commonCompilerFlags% -Fe:.\app.exe ..\app.cpp /link -incremental:no %commonLinkerFlags%
 popd
 exit /b
 :error
 echo Failed with error #%errorlevel%.
 exit /b %errorlevel%
--- a/djstdlib/core.cpp
+++ b/djstdlib/core.cpp
@@ -1,436 +0,0 @@
 #include "os.cpp"
 #include <math.h>
 #include <string.h>
 #include "core.h"
 #define STB_SPRINTF_IMPLEMENTATION
 #include "vendor/stb_sprintf.h"
 void *pushSizeFill(Arena *arena, size_t bytes, byte fill) {
    if (arena->capacity - arena->head >= bytes) {
        void *ptr = (char *)arena->memory + arena->head;
        arena->head += bytes;
        memset(ptr, fill, bytes);
        return ptr;
    }
    return 0;
 }
 void *pushSize(Arena *arena, size_t bytes) {
    if (arena->capacity - arena->head >= bytes) {
        void *ptr = (char *)arena->memory + arena->head;
        arena->head += bytes;
        return ptr;
    }
    return 0;
 }
 Arena *arenaAlloc(size_t capacity) {
    Arena *result = (Arena *)os_alloc(sizeof(Arena) + capacity);
    result->memory = result + sizeof(Arena);
    result->capacity = capacity;
    result->head = 0;
    return result;
 }
 void arenaFree(Arena *arena) {
    os_free(arena, arena->capacity);
 }
 void arenaFreeFrom(Arena *arena, size_t position) {
    arena->head = position;
 }
 void arenaPopTo(Arena *arena, void *position) {
    arena->head = (byte *)position - (byte *)arena->memory;
 }
 Arena *scratchArenas[2];
 void initialiseCore() {
    for (EachInArray(scratchArenas, i)) {
        scratchArenas[i] = arenaAlloc(Megabytes(64));
    }
 }
 Scratch scratchStart(Arena **conflicts, size_t conflictCount) {
    Scratch scratch = {0};
    for (size_t i = 0; i < ArrayCount(scratchArenas); i += 1) {
        bool conflicted = false;
        for (Arena **conflict = conflicts; conflict < conflicts + conflictCount; conflict += 1) {
            if (*conflict == scratchArenas[i]) {
                conflicted = true;
                break;
            }
        }
        if (conflicted == false) {
            scratch.arena = scratchArenas[i];
            scratch.start = scratch.arena->head;
            break;
        }
    }
    return scratch;
 }
 #define DeferLoop(begin_stmnt, end_stmnt) for(int __defer_i = ((begin_stmnt), 0); __defer_i < 1; (++__defer_i, (end_stmnt)))
 #define WithScratch(scratchName) Scratch scratchName; DeferLoop(scratchName = scratchStart(0, 0), scratchEnd(scratchName))
 void scratchEnd(Scratch scratch) {
    arenaFreeFrom(scratch.arena, scratch.start);
 }
 template <typename T>
 T *appendList(list<T> *list, T element) {
    if (list->head < list->length) {
        list->data[list->head] = element;
        list->head++;
        return &(list->data[list->head - 1]);
    } else {
        return 0;
    }
 }
 template <typename T>
 void zeroListFull(list<T> *list) {
    memset(list->data, 0, list->head * sizeof(T));
 }
 template <typename T>
 void zeroList(list<T> *list) {
    list->head = 0;
    memset(list->data, 0, list->head * sizeof(T));
 }
 inline string operator""_s(const char *cstrLiteral, size_t length) {
    return {
        (char *)cstrLiteral,
        length,
    };
 }
 const char *cstring(Arena *arena, list<char> buf) {
    char *arr = PushArray(arena, char, buf.length + 1);
    memmove(arr, buf.data, buf.length);
    arr[buf.length] = '\0';
    return arr;
 }
 const char *cstring(Arena *arena, string str) {
    char *arr = PushArray(arena, char, str.length + 1);
    memmove(arr, str.str, str.length);
    arr[str.length] = '\0';
    return arr;
 }
 bool strStartsWith(string str, string testStr) {
    if (str.length < testStr.length) {
        return false;
    }
    for (size_t i = 0; i < testStr.length; i++) {
        if (str.str[i] != testStr.str[i]) {
            return false;
        }
    }
    return true;
 }
 bool strEql(string s1, string s2) {
    if (s1.length != s2.length) {
        return false;
    }
    for (size_t i = 0; i < s1.length; i++) {
        if (s1.str[i] != s2.str[i]) {
            return false;
        }
    }
    return true;
 }
 size_t calcStringLen(const char *str) {
    size_t size = 0;
    if (str == NULL) {
        return size;
    }
    while (str[size] != '\0') {
        size++;
    }
    return size;
 }
 string strFromCString(Arena *arena, const char *str) {
    string result = PushString(arena, calcStringLen(str));
    memcpy(result.str, str, result.length);
    return result;
 }
 string strReverse(Arena *arena, string str) {
    string reversed = PushString(arena, str.length);
    for (
        size_t mainIndex = str.length - 1, reversedIndex = 0; 
        mainIndex < str.length; 
        mainIndex--, reversedIndex++
    ) {
        reversed.str[reversedIndex] = str.str[mainIndex];
    }
    return reversed;
 }
 string strPrintfv(Arena *arena, const char *fmt, va_list args) {
    string result = {0};
    va_list argsCopy;
    va_copy(argsCopy, args);
    uint64 bufSize = stb_vsnprintf(0, 0, fmt, args) + 1;
    result.str = PushArray(arena, char, bufSize);
    result.length = bufSize - 1;
    stb_vsnprintf((char *)result.str, (int)bufSize, fmt, argsCopy);
    return result;
 }
 string strPrintf(Arena *arena, const char *fmt, ...) {
    string result = {0};
    va_list args;
    va_start(args, fmt);
    result = strPrintfv(arena, fmt, args);
    va_end(args);
    return result;
 }
 template <typename T>
 list<T> listSlice(list<T> l, size_t start, size_t stop) {
    if (stop == 0) {
        stop = l.head;
    }
    // TODO(djledda): maybe assert instead
    if (stop > l.head || start > stop) {
        return {0};
    }
    return {
        l.data + start,
        stop - start,
        stop - start,
    };
 }
 string strSlice(string str, size_t start, size_t stop) {
    if (stop == 0) {
        stop = str.length;
    }
    // TODO(djledda): maybe assert instead
    if (stop > str.length || start > stop) {
        return {0};
    }
    return {
        str.str + start,
        stop - start,
    };
 }
 string strSlice(char *data, size_t start, size_t stop) {
    return {
        data + start,
        stop - start,
    };
 }
 bool stringContains(string str, char c) {
    for (size_t i = 0; i < str.length; i++) {
        if (str.str[i] == c) {
            return true;
        }
    }
    return false;
 }
 string NUMERIC_CHARS = "0123456789"_s;
 inline bool isNumeric(char c) {
    return stringContains(NUMERIC_CHARS, c);
 }
 list<string> strSplit(Arena *arena, string splitStr, string inputStr) {
    list<string> result = {0};
    if (inputStr.length > 0) {
        size_t splitCount = 0;
        size_t c = 0;
        size_t start = 0;
        void *beginning = (char *)arena->memory + arena->head;
        while (c < inputStr.length - splitStr.length) {
            if (strEql(strSlice(inputStr, c, c + splitStr.length), splitStr)) {
                string *splitString = PushStruct(arena, string);
                splitString->str = inputStr.str + start;
                splitString->length = c - start;
                splitCount++;
                start = c + 1;
            }
            c++;
        }
        string *splitString = PushStruct(arena, string);
        splitString->str = inputStr.str + start;
        splitString->length = inputStr.length - start;
        splitCount++;
        result.data = (string *)beginning,
        result.head = splitCount,
        result.length = splitCount;
    }
    return result;
 }
 ParsePositiveIntResult parsePositiveInt(string str, size_t *lengthPointer) {
    size_t numEnd = 0;
    char currChar = str.str[numEnd];
    while (numEnd < str.length && isNumeric(currChar)) {
        currChar = str.str[++numEnd];
        *lengthPointer += 1;
    }
    *lengthPointer -= 1;
    if (numEnd > 0) {
        uint8 result = 0;
        for (size_t i = 0; i < numEnd; i++) {
            result *= 10;
            result += str.str[i] - '0';
        }
        return {result, true};
    } else {
        return {0, false};
    }
 }
 ParsePositiveReal32Result parsePositiveReal32(string str, size_t *lengthPointer) {
    ParsePositiveReal32Result result = {NAN, false};
    string wholePartStr = string{0};
    string fractionalPartStr = string{0};
    bool split = false;
    size_t c = 0;
    while (c < str.length) {
        if (str.str[c] == '.') {
            wholePartStr.str = str.str;
            wholePartStr.length = c;
            fractionalPartStr.str = str.str + c + 1;
            fractionalPartStr.length = str.length - c - 1;
            split = true;
            break;
        }
        c++;
    }
    if (split) {
        ParsePositiveIntResult wholePartParsed = parsePositiveInt(wholePartStr, lengthPointer);
        *lengthPointer += 1;
        ParsePositiveIntResult fractionalPartParsed = parsePositiveInt(fractionalPartStr, lengthPointer);
        if (wholePartParsed.valid && fractionalPartParsed.valid) {
            // TODO(dledda): implement powf with intrinsics? or just custom
            real32 fractionalPartMultiplier = 1.0f / powf(10.0f, (real32)fractionalPartStr.length);
            result.result = (real32)wholePartParsed.result + (real32)fractionalPartParsed.result * (real32)fractionalPartMultiplier;
            result.valid = true;
        }
    } else if (c > 0) {
        ParsePositiveIntResult intPartParsed = parsePositiveInt(str, lengthPointer);
        if (intPartParsed.valid) {
            result.result = (real32)intPartParsed.result;
            result.valid = true;
        }
    }
    return result;
 }
 list<string> getArgs(Arena *arena, int argc, char **argv) {
    list<string> args = PushList(arena, string, (size_t)argc - 1);
    for (int i = 1; i < argc; i++) {
        appendList(&args, strFromCString(arena, argv[i]));
    }
    return args;
 }
 UnixTimestamp getSystemUnixTime() {
    time_t now;
    time(&now);
    return (UnixTimestamp)now;
 }
 Timestamp timestampFromUnixTime(UnixTimestamp *unixTimestamp) {
    tm timestamp = {0};
    gmtime_r((time_t *)unixTimestamp, &timestamp);
    return timestamp;
 }
 string formatTimeHms(Arena *arena, UnixTimestamp time) {
    local_persist const string format = "HH-MM-SS"_s;
    string buf = PushString(arena, format.length);
    tm *timestamp = gmtime((time_t *)&time);
    strftime(buf.str, buf.length + 1, "%T", timestamp);
    return buf;
 }
 string formatTimeHms(Arena *arena, Timestamp *time) {
    local_persist const string format = "HH-MM-SS"_s;
    string buf = PushString(arena, format.length);
    strftime(buf.str, buf.length + 1, "%T", (tm *)time);
    return buf;
 }
 string formatTimeYmd(Arena *arena, UnixTimestamp time) {
    local_persist const string format = "YYYY-mm-dd"_s;
    string buf = PushString(arena, format.length);
    tm *timestamp = gmtime((time_t *)&time);
    strftime(buf.str, buf.length + 1, "%Y-%m-%d", timestamp);
    return buf;
 }
 string formatTimeYmd(Arena *arena, Timestamp *time) {
    local_persist const string format = "YYYY-mm-dd"_s;
    string buf = PushString(arena, format.length);
    strftime(buf.str, buf.length + 1, "%Y-%m-%d", (tm *)time);
    return buf;
 }
 void logErr(const char *fmt, ...) {
    va_list argList;
    va_start(argList, fmt);
    os_log(LogTarget_stdout, fmt, argList);
    va_end(argList);
 }
 function void logStdout(const char *fmt, ...) {
    va_list argList;
    va_start(argList, fmt);
    os_log(LogTarget_stdout, fmt, argList);
    va_end(argList);
 }
 void log(const char *fmt, ...) {
    va_list argList;
    va_start(argList, fmt);
    os_log(LogTarget_stdout, fmt, argList);
    va_end(argList);
 }
 void log(list<int> l, LogTarget target) {
    void (*logFn)(const char *fmt, ...) = target == LogTarget_stdout ? &logStdout : &logErr;
    logFn("{ ");
    for (size_t i = 0; i < l.length; i++) {
        if (i != 0) {
            logFn(", ");
        }
        logFn("%i", l.data[i]);
    }
    logFn(" } length: %zu, head: %zu\n", l.length, l.head);
 }
 void log(list<string> l, LogTarget target) {
    void (*logFn)(const char *fmt, ...) = target == LogTarget_stdout ? &logStdout : &logErr;
    logFn("{ ");
    for (size_t i = 0; i < l.length; i++) {
        if (i != 0) {
            logFn(", ");
        } 
        logFn("\"%S\"", l.data[i]);
    }
    logFn(" } length: %zu, head: %zu\n", l.length, l.head);
 }
 int intCompare(const void *a, const void *b) {
    int *x = (int *)a;
    int *y = (int *)b;
    return (*x > *y) - (*x < *y);
 }
--- a/djstdlib/core.h
+++ b/djstdlib/core.h
@@ -1,270 +0,0 @@
 #ifndef CORE_H
 #define CORE_H
 // cstdlib includes
 #include <math.h>
 #include <stdint.h> // necessary for int type sizes
 #include <stdio.h>
 #include <time.h> // TODO(djledda): try not to depend on this one
 // ### Misc macros ### 
 #if ENABLE_ASSERT
 #define Assert(expression) if (!(expression)) {*(volatile int *)0 = 0;}
 #else
 #define Assert(expression) 
 #endif
 #define function static
 #define global static 
 #define local_persist static
 // ### Types ###
 typedef int8_t int8;
 typedef int16_t int16;
 typedef int32_t int32;
 typedef int64_t int64;
 typedef uint8_t uint8;
 typedef uint16_t uint16;
 typedef uint32_t uint32;
 typedef uint64_t uint64;
 typedef uint8_t byte;
 typedef float real32;
 typedef double real64;
 // ### Sizes and Numbers ###
 #define Bytes(n) (n)
 #define Kilobytes(n) (n << 10)
 #define Megabytes(n) (n << 20)
 #define Gigabytes(n) (((uint64)n) << 30)
 #define Terabytes(n) (((uint64)n) << 40)
 #define Thousand(n) ((n)*1000)
 #define Million(n)  ((n)*1000000)
 #define Billion(n)  ((n)*1000000000LL)
 #define ArrayCount(arr) (sizeof(arr) / sizeof((arr)[0]))
 // ### Arenas ###
 struct Arena {
    void *memory;
    size_t capacity;
    size_t head;
 };
 struct Scratch {
    Arena *arena;
    size_t start;
 };
 void *pushSize(Arena *arena, size_t bytes);
 void *pushSizeFill(Arena *arena, size_t bytes, byte fill);
 Arena *arenaAlloc(size_t capacity);
 void arenaFree(Arena *arena);
 void arenaFreeFrom(Arena *arena, size_t pos);
 void arenaPopTo(Arena *arena, void *pos);
 void initialiseCore();
 Scratch scratchStart(Arena **conflicts, size_t conflictCount); 
 void scratchEnd(Scratch scratch); 
 #define PushArray(arena, type, size) (type *)pushSize(arena, sizeof(type) * (size))
 #define PushArrayZero(arena, type, size) (type *)pushSizeFill(arena, sizeof(type) * (size), 0)
 #define PushStruct(arena, type) (type *)pushSize(arena, sizeof(type))
 #define PushStructZero(arena, type) (type *)pushSizeFill(arena, sizeof(type), 0)
 // ### Vectors ###
 template <typename T>
 union Vector2 {
    struct {
        T x;
        T y;
    };
    T vec[2];
 };
 template <typename T>
 inline function Vector2<T> vec2(T x, T y) {
    Vector2<T> result = {0};
    result.x = x;
    result.y = y;
    return result;
 }
 template <typename T>
 union Vector3 {
    struct {
        T x;
        T y;
        T z;
    };
    T vec[3];
 };
 template <typename T>
 inline function Vector3<T> vec3(T x, T y, T z) {
    Vector3<T> result = {0};
    result.x = x;
    result.y = y;
    result.z = z;
    return result;
 }
 template <typename T>
 union Vector4 {
    struct {
        T x;
        T y;
        T z;
        T w;
    };
    T vec[4];
 };
 template <typename T>
 inline function Vector4<T> vec4(T x, T y, T z, T w) {
    Vector4<T> result = {0};
    result.x = x;
    result.y = y;
    result.z = z;
    result.w = w;
    return result;
 }
 // ### Lists ###
 template <typename T>
 struct list {
    T* data;
    size_t length;
    size_t head;
 };
 #define PushList(arena, type, size) (list<type>{ PushArray(arena, type, size), size, 0 })
 #define PushListZero(arena, type, size) (list<type>{ PushArrayZero(arena, type, size), size, 0 })
 #define PushFullList(arena, type, size) (list<type>{ PushArray(arena, type, size), size, size })
 #define PushFullListZero(arena, type, size) (list<type>{ PushArrayZero(arena, type, size), size, size })
 template <typename T> T *appendList(list<T> *list, T element); 
 template <typename T> void zeroList(list<T> *list); 
 template <typename T> void zeroListFull(list<T> *list); 
 template <typename T> list<T> listSlice(list<T> l, size_t start, size_t stop = 0); 
 // ### Strings ###
 struct string {
    char *str;
    size_t length;
 };
 #define STB_SPRINTF_DECORATE(name) stb_##name // define this before including if you want to change the names
 #include "vendor/stb_sprintf.h"
 #define strlit(lit) (string{(char *)(lit), sizeof(lit) - 1})
 #define PushString(arena, length) (string{ (char *)pushSize(arena, length), (length) })
 #define PushStringFill(arena, length, characterByte) (string{ (char *)pushSizeFill(arena, length, characterByte), (length) })
 string operator""_s(const char *cstrLiteral, size_t length);
 // C Strings
 const char *cstring(Arena *arena, list<char> buf); 
 const char *cstring(Arena *arena, string str); 
 size_t calcStringLen(const char *str); 
 string strFromCString(Arena *arena, const char *str); 
 bool strEql(string s1, string s2); 
 bool strStartsWith(string str, string testStr);
 bool stringContains(string str, char c); 
 string strReverse(Arena *arena, string str); 
 string strSlice(string str, size_t start, size_t stop = 0); 
 string strSlice(char *data, size_t start, size_t stop = 0); 
 list<string> strSplit(Arena *arena, string splitStr, string inputStr); 
 string strPrintfv(Arena *arena, const char *fmt, va_list args);
 string strPrintf(Arena *arena, const char *fmt, ...);
 struct ParsePositiveIntResult { uint8 result; bool valid; };
 ParsePositiveIntResult parsePositiveInt(string str, size_t *lengthPointer); 
 struct ParsePositiveReal32Result { real32 result; bool valid; };
 ParsePositiveReal32Result parsePositiveReal32(Arena *arena, string str, size_t *lengthPointer); 
 inline function bool isNumeric(char c); 
 // ### Cmdline ###
 list<string> getArgs(Arena *arena, int argc, char **argv); 
 // ### Time ###
 typedef uint64 UnixTimestamp;
 typedef tm Timestamp;
 UnixTimestamp getSystemUnixTime(); 
 Timestamp timestampFromUnixTime(UnixTimestamp *unixTimestamp); 
 string formatTimeHms(Arena *arena, UnixTimestamp time); 
 string formatTimeHms(Arena *arena, Timestamp *time); 
 string formatTimeYmd(Arena *arena, UnixTimestamp time); 
 string formatTimeYmd(Arena *arena, Timestamp *time); 
 // ### Linked Lists ###
 // TODO(djledda): implement basic linked lists (based on arenas?)
 // ### Logging ###
 enum LogTarget {
    LogTarget_stdout,
    LogTarget_stdin,
    LogTarget_stderr,
    LogTarget_count,
 };
 #define ANSI_INSTRUCTION_FROM_ENUM(ansiCodeEnum) ANSI_INSTRUCTION(ansiCodeEnum)
 #define ANSI_INSTRUCTION(ansiCode) "\u001b[" #ansiCode "m"
 #define ANSI_INSTRUCTION_STR(ansiCodeStr) "\u001b[" ansiCodeStr "m"
 #define ANSI_RESET ANSI_INSTRUCTION(0)
 #define ANSI_fg_black 30
 #define ANSI_fg_red 31
 #define ANSI_fg_green 32
 #define ANSI_fg_yellow 33
 #define ANSI_fg_blue 34
 #define ANSI_fg_magenta 35
 #define ANSI_fg_cyan 36
 #define ANSI_fg_white 37
 #define ANSI_fg_bblack 90
 #define ANSI_fg_bred 91
 #define ANSI_fg_bgreen 92
 #define ANSI_fg_byellow 93
 #define ANSI_fg_bblue 94
 #define ANSI_fg_bmagenta 95
 #define ANSI_fg_bcyan 96
 #define ANSI_fg_bwhite 97
 #define ANSI_bg_black 40
 #define ANSI_bg_red 41
 #define ANSI_bg_green 42
 #define ANSI_bg_yellow 43
 #define ANSI_bg_blue 44
 #define ANSI_bg_magenta 45
 #define ANSI_bg_cyan 46
 #define ANSI_bg_white 47
 #define ANSI_bg_bblack 100
 #define ANSI_bg_bred 101
 #define ANSI_bg_bgreen 102
 #define ANSI_bg_byellow 103
 #define ANSI_bg_bblue 104
 #define ANSI_bg_bmagenta 105
 #define ANSI_bg_bcyan 106
 #define ANSI_bg_bwhite 107
 #define COLOR_TEXT(text, foregroundcolor) ANSI_INSTRUCTION_FROM_ENUM(foregroundcolor) text ANSI_RESET
 #define COLOR_TEXT_BG(text, backgroundcolor) ANSI_INSTRUCTION_FROM_ENUM(backgroundcolor) text ANSI_RESET
 #define COLOR_TEXT_FG_BG(text, foregroundcolor, backgroundcolor) ANSI_INSTRUCTION_FROM_ENUM(foregroundcolor) ANSI_INSTRUCTION_FROM_ENUM(backgroundcolor) text  ANSI_RESET
 #define COLOR_TEXT_RGB(text, red, green, blue) ANSI_INSTRUCTION_STR("38;2;" #red ";" #green ";" #blue) text ANSI_RESET
 void log(list<int> l, LogTarget target = LogTarget_stdout);
 void log(list<string> l, LogTarget target = LogTarget_stdout);
 void log(const char *fmt, ...);
 void logError(const char *fmt, ...);
 // ### Loops ###
 #define EachIn(list, it) size_t it = 0; it < (list).head; it++
 #define EachInReversed(list, it) size_t it = (list).head - 1; it >= 0 && it < (list).head; it--
 #define EachInArray(arr, it)  size_t it = 0; it < ArrayCount(arr); ++it
 // ### Misc ###
 int intCompare(const void *a, const void *b); 
 #endif
--- a/djstdlib/os.cpp
+++ b/djstdlib/os.cpp
@@ -1,12 +0,0 @@
 #ifndef OS_CPP
 #define OS_CPP
 #if OS_WINDOWS
 #include "os_win32.cpp"
 #elif OS_LINUX
 #include "os_linux.cpp"
 #else 
    #error Development environment not supported.
 #endif
 #endif
--- a/djstdlib/os.h
+++ b/djstdlib/os.h
@@ -1,20 +0,0 @@
 #ifndef OS_H
 #define OS_H
 #include "core.h"
 // ### Memory ###
 void *os_alloc(size_t capacity);
 void os_reserve(void *ptr);
 void os_decommit(void *ptr);
 void os_free(void *ptr, size_t freeSize);
 // ### File IO ###
 string os_readEntireFile(Arena *arena, string filename); 
 bool os_writeEntireFile(Arena *arena, string filename, const byte *contents, size_t contentsLength); 
 bool os_fileAppend(Arena *arena, string filename, const byte *contents, size_t contentsLength); 
 // ### Standard IO ###
 void os_log(LogTarget target, const char *fmt, va_list argList);
 #endif
--- a/djstdlib/os_linux.cpp
+++ b/djstdlib/os_linux.cpp
@@ -1,98 +0,0 @@
 #ifndef OS_IMPL_LINUX_CPP
 #define OS_IMPL_LINUX_CPP
 #include "os.h"
 #include <sys/mman.h>
 #include <sys/stat.h>
 #include <unistd.h>
 void *os_alloc(size_t capacity) {
    return mmap(0, capacity, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANONYMOUS, -1, 0);
 }
 void os_commit(void *ptr) {
 }
 void os_decommit(void *ptr) {
 }
 void os_free(void *ptr, size_t size) {
    int err = munmap(ptr, size);
    Assert(err != -1);
 }
 string os_readEntireFile(Arena *arena, string filename) {
    Scratch temp = scratchStart(&arena, 1);
    FILE *input = fopen(cstring(temp.arena, filename), "r");
    string readBuffer;
    if (input) {
        struct stat st;
        stat((char *)filename.str, &st);
        size_t fsize = st.st_size;
        readBuffer = PushString(arena, fsize);
        fread(readBuffer.str, sizeof(byte), readBuffer.length, input);
        fclose(input);
    } else {
        readBuffer = PushString(arena, 0);
    }
    scratchEnd(temp);
    return readBuffer;
 }
 bool os_writeEntireFile(Arena *arena, string filename, const byte *contents, size_t contentsLength) {
    Scratch temp = scratchStart(&arena, 1);
    bool result = false;
    FILE *output = fopen(cstring(temp.arena, filename), "w");
    if (output) {
        fwrite(contents, sizeof(byte), contentsLength, output);
        fclose(output);
        result = true;
    }
    scratchEnd(temp);
    return result;
 }
 bool os_fileAppend(Arena *arena, string filename, const byte *contents, size_t contentsLength) {
    Scratch temp = scratchStart(&arena, 1);
    bool result = false;
    FILE *output = fopen(cstring(temp.arena, filename), "a");
    if (output) {
        fwrite(contents, sizeof(byte), contentsLength, output);
        fclose(output);
        result = true;
    }
    scratchEnd(temp);
    return result;
 }
 void os_log(LogTarget target, const char *fmt, va_list argList) {
    Scratch temp = scratchStart(0, 0);
    string result = strPrintfv(temp.arena, fmt, argList);
    // TODO(djledda): finish implementation without cstdlib
    switch (target) {
        case LogTarget_stdin: 
            write(0, (const void *)result.str, result.length);
            break;
        case LogTarget_stderr: 
            fflush(stderr);
            write(2, (const void *)result.str, result.length);
            break;
        case LogTarget_stdout: 
        default:
            fflush(stdout);
            write(1, (const void *)result.str, result.length);
            break;
    }
    scratchEnd(temp);
 }
 #endif
--- a/djstdlib/os_win32.cpp
+++ b/djstdlib/os_win32.cpp
@@ -1,92 +0,0 @@
 #ifndef OS_IMPL_WIN32_CPP
 #define OS_IMPL_WIN32_CPP
 #include "Windows.h" 
 #include "os.h"
 void *os_alloc(size_t commitSize) {
    return VirtualAlloc(NULL, commitSize, MEM_RESERVE | MEM_COMMIT, PAGE_READWRITE);
 }
 void os_reserve(void *ptr) {
 }
 void os_decommit(void *ptr) {
 }
 void os_free(void *ptr, size_t size) {
    VirtualFree(ptr, NULL, MEM_RELEASE);
 }
 string os_readEntireFile(Arena *arena, string filename) {
    string result = {0};
    HANDLE fileHandle = CreateFileA(cstring(arena, filename), GENERIC_READ, FILE_SHARE_READ, NULL, OPEN_EXISTING, NULL, NULL);
    if (fileHandle != INVALID_HANDLE_VALUE) {
        LARGE_INTEGER fileSize;
        if (GetFileSizeEx(fileHandle, &fileSize)) {
            string readfile = PushString(arena, (size_t)fileSize.QuadPart);
            if (readfile.str) {
                DWORD bytesRead;
                if (ReadFile(fileHandle, readfile.str, (DWORD)fileSize.QuadPart, &bytesRead, NULL) && (fileSize.QuadPart == bytesRead)) {
                    result = readfile;
                }
            }
        }
        CloseHandle(fileHandle);
    }
    return result;
 }
 bool os_writeEntireFile(Arena *arena, string filename, const byte *contents, size_t contentsLength) {
    bool result = false;
    HANDLE fileHandle = CreateFileA(cstring(arena, filename), GENERIC_WRITE, FILE_SHARE_READ, NULL, CREATE_ALWAYS, NULL, NULL);
    if (fileHandle != INVALID_HANDLE_VALUE) {
        DWORD bytesWritten;
        if (WriteFile(fileHandle, contents, (DWORD)contentsLength, &bytesWritten, NULL)) {
            // file written successfully
            result = bytesWritten == contentsLength;
        }  
        CloseHandle(fileHandle);
    }  
    return result;
 }
 bool os_fileAppend(Arena *arena, string filename, const byte *contents, size_t contentsLength) {
    bool result = false;
    HANDLE fileHandle = CreateFileA(cstring(arena, filename), FILE_APPEND_DATA | FILE_GENERIC_READ, FILE_SHARE_READ, NULL, OPEN_ALWAYS, FILE_ATTRIBUTE_NORMAL, NULL);
    if (fileHandle != INVALID_HANDLE_VALUE) {
        DWORD bytesWritten;
        DWORD position = SetFilePointer(fileHandle, 0, NULL, FILE_END);
        if (WriteFile(fileHandle, contents, (DWORD)contentsLength, &bytesWritten, NULL)) {
            // file written successfully
            result = bytesWritten == contentsLength;
        }
        CloseHandle(fileHandle);
    }
    return result;
 }
 function void os_log(LogTarget target, const char *fmt, va_list argList) {
    Scratch scratch = scratchStart(0, 0);
    string result = strPrintfv(scratch.arena, fmt, argList);
    DWORD done;
    HANDLE stdHandle;
    switch (target) {
        case LogTarget_stdin: 
            stdHandle = GetStdHandle(STD_INPUT_HANDLE);
            break;
        case LogTarget_stdout: 
            stdHandle = GetStdHandle(STD_ERROR_HANDLE);
            break;
        case LogTarget_stderr: 
            stdHandle = GetStdHandle(STD_OUTPUT_HANDLE);
            break;
        default:
            stdHandle = GetStdHandle(STD_OUTPUT_HANDLE);
            break;
    }
    WriteFile(stdHandle, result.str, (DWORD)result.length, &done, 0);
    scratchEnd(scratch);
 }
 #endif 
--- a/djstdlib/vendor/stb_sprintf.h
+++ b/djstdlib/vendor/stb_sprintf.h