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zern/std/std.zr

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include "std/linux_constants.zr"
func panic[msg: str] : void
io.print("PANIC: ")
io.println(msg)
// for gdb backtrace
_builtin_syscall(SYS_kill, os.getpid(), SIGABRT)
os.exit(1)
const MEM_BLOCK_SIZE = 32
struct mem.Block
size: i64
free: bool
next: mem.Block
prev: mem.Block
func mem.align[x: i64] : i64
return (x + 7) & -8
func mem.Block._split[blk: mem.Block, needed: i64] : void
if blk->size >= needed + MEM_BLOCK_SIZE + 8
new_blk := (blk as ptr + MEM_BLOCK_SIZE + needed) as mem.Block
new_blk->size = blk->size - needed - MEM_BLOCK_SIZE
new_blk->free = true
new_blk->next = blk->next
new_blk->prev = blk
if blk->next as ptr
blk->next->prev = new_blk
else
mem.write64(_builtin_heap_tail(), new_blk)
blk->size = needed
blk->next = new_blk
func mem._request_space[size: i64] : mem.Block
needed := size + MEM_BLOCK_SIZE
alloc_size := (needed + 4095) & -4096
blk := _builtin_syscall(SYS_mmap, 0, alloc_size, PROT_READ|PROT_WRITE, MAP_PRIVATE|MAP_ANONYMOUS, -1, 0) as mem.Block
if (blk as ptr as i64) == -1
panic("mem._request_space: failed to mmap")
blk->size = alloc_size - MEM_BLOCK_SIZE
blk->free = false
blk->next = 0 as mem.Block
blk->prev = 0 as mem.Block
tail := mem.read64(_builtin_heap_tail()) as mem.Block
if tail as ptr
tail->next = blk
blk->prev = tail
mem.write64(_builtin_heap_tail(), blk)
return blk
func mem.alloc[size: i64] : ptr
if size <= 0
panic("mem.alloc: called with nonpositive size")
size = mem.align(size)
cur := mem.read64(_builtin_heap_head()) as mem.Block
while cur as ptr
if cur->free && cur->size >= size
cur->_split(size)
cur->free = false
return cur as ptr + MEM_BLOCK_SIZE
cur = cur->next
blk := mem._request_space(size)
if !mem.read64(_builtin_heap_head())
mem.write64(_builtin_heap_head(), blk)
blk->_split(size)
return blk as ptr + MEM_BLOCK_SIZE
func mem.free[x: any] : void
ptr.free(x as ptr)
func ptr.free[x: ptr] : void
if x == 0
return
blk := (x - MEM_BLOCK_SIZE) as mem.Block
if blk->free
return
blk->free = true
next := blk->next
if next as ptr && next->free
expected_next := (blk as ptr + MEM_BLOCK_SIZE + blk->size) as mem.Block
if expected_next as ptr == next as ptr
blk->size += MEM_BLOCK_SIZE + next->size
blk->next = next->next
if next->next as ptr
next->next->prev = blk
if mem.read64(_builtin_heap_tail()) == next as ptr
mem.write64(_builtin_heap_tail(), blk)
prev := blk->prev
if prev as ptr && prev->free
expected_blk := (prev as ptr + MEM_BLOCK_SIZE + prev->size) as mem.Block
if expected_blk as ptr == blk as ptr
prev->size += MEM_BLOCK_SIZE + blk->size
prev->next = blk->next
if blk->next as ptr
blk->next->prev = prev
if mem.read64(_builtin_heap_tail()) == blk as ptr
mem.write64(_builtin_heap_tail(), prev)
blk = prev
block_total := blk->size + MEM_BLOCK_SIZE
if (blk as i64 & 4095) == 0 && (block_total & 4095) == 0
if blk->prev as ptr
blk->prev->next = blk->next
else
mem.write64(_builtin_heap_head(), blk->next)
if blk->next as ptr
blk->next->prev = blk->prev
else
mem.write64(_builtin_heap_tail(), blk->prev)
_builtin_syscall(SYS_munmap, blk, block_total)
func ptr.realloc[x: ptr, new_size: i64] : ptr
if !x
return mem.alloc(new_size)
if new_size < 0
panic("mem.realloc: called with negative new_size")
if new_size == 0
x->free()
return 0 as ptr
new_size = mem.align(new_size)
blk := (x - MEM_BLOCK_SIZE) as mem.Block
if blk->size >= new_size
blk->_split(new_size)
return x
next := blk->next
expected_next := (blk as ptr + MEM_BLOCK_SIZE + blk->size) as mem.Block
if next as ptr && next->free && expected_next as ptr == next as ptr
combined := blk->size + MEM_BLOCK_SIZE + next->size
if combined >= new_size
blk->size = combined
blk->next = next->next
if next->next as ptr
next->next->prev = blk
if mem.read64(_builtin_heap_tail()) == next as ptr
mem.write64(_builtin_heap_tail(), blk)
blk->_split(new_size)
return x
new_ptr := mem.alloc(new_size)
mem.copy(x, new_ptr, math.min(blk->size, new_size))
x->free()
return new_ptr
func ptr.zero_and_free[x: ptr, size: i64] : void
mem.zero(x, size)
x->free()
func mem.zero[x: ptr, size: i64] : void
i := 0
while i + 8 <= size
mem.write64(x + i, 0)
i += 8
while i < size
x[i] = 0 as u8
i += 1
func mem.copy[src: ptr, dst: ptr, n: i64] : void
if dst > src && dst < src + n
i := n
while i - 8 >= 0
i -= 8
mem.write64(dst + i, mem.read64(src + i))
while i > 0
i -= 1
dst[i] = src[i]
else
i := 0
while i + 8 <= n
mem.write64(dst + i, mem.read64(src + i))
i += 8
while i < n
dst[i] = src[i]
i += 1
func mem.read8[x: ptr] : u8
return x[0]
func mem.read16[x: ptr] : i64
return x[0] as i64 | (x[1] << 8)
func mem.read16be[x: ptr] : i64
return (x[0] << 8) as i64 | x[1]
func mem.read32[x: ptr] : i64
return x[0] as i64 | (x[1] << 8) | (x[2] << 16) | (x[3] << 24)
func mem.read32be[x: ptr] : i64
return (x[0] as i64 << 24) | (x[1] << 16) | (x[2] << 8) | x[3]
func mem.read64[x: ptr] : i64
return _builtin_read64(x)
func mem.write32[x: ptr, d: i64] : void
x[0] = d & 0xff
x[1] = (d >> 8) & 0xff
x[2] = (d >> 16) & 0xff
x[3] = (d >> 24) & 0xff
func mem.write16[x: ptr, d: i64] : void
x[0] = d & 0xff
x[1] = (d >> 8) & 0xff
func mem.write16be[x: ptr, d: i64] : void
x[0] = (d >> 8) & 0xff
x[1] = d & 0xff
func mem.write64[x: ptr, d: any] : void
_builtin_set64(x, d)
func io.printf[..] : void
s := _var_arg(0) as ptr
i := 1
while s[0]
if s[0] == '%'
s += 1
if s[0] == 'd'
io.print_i64(_var_arg(i) as i64)
i += 1
else if s[0] == 'x'
io.print_i64_hex(_var_arg(i) as i64)
i += 1
else if s[0] == 's'
io.print(_var_arg(i) as str)
i += 1
else if s[0] == 'c'
io.print_char(_var_arg(i) as u8)
i += 1
else if s[0] == 'f'
io.print_f64(_var_arg(i) as i64)
i += 1
else if s[0] == '%'
io.print_char('%')
else if s[0] == 0
break
else
panic("io.printf: unrecognized format")
else
io.print_char(s[0])
s += 1
func io.print_sized[x: ptr, size: i64] : void
_builtin_syscall(SYS_write, STDOUT, x, size)
func io.print[x: str] : void
io.print_sized(x as ptr, x->len())
func io.println[x: str] : void
io.print(x)
io.print("\n")
func io.print_char[x: u8] : void
io.print_sized(^x, 1)
func io.print_bool[x: bool] : void
if x
io.print("true")
else
io.print("false")
func io.print_i64[x: i64] : void
s := _stackalloc(21)
x->to_str_buf(s)
io.print(s as str)
func io.print_i64_hex[x: i64] : void
s := _stackalloc(17)
x->to_hex_str_buf(s)
io.print(s as str)
func io.println_i64[x: i64] : void
s := _stackalloc(21)
x->to_str_buf(s)
io.println(s as str)
// TODO: fix when we implement f64 params
func io.print_f64[x: i64] : void
s := _stackalloc(64)
f64.to_str_buf(x, s)
io.print(s as str)
func f64.to_str_buf[x: i64, buf: ptr] : void
bits := x
sign := (bits >> 63) & 1
exp := (bits >> 52) & 0x7ff
mant := bits & 0x000fffffffffffff
if exp == 0x7ff
if mant == 0
if sign
mem.copy("-inf" as ptr, buf, 5)
else
mem.copy("inf" as ptr, buf, 4)
else
mem.copy("nan" as ptr, buf, 4)
return
p := 0
if sign
buf[p] = '-'
p += 1
bits = bits & 0x7fffffffffffffff
if exp == 0 && mant == 0
buf[p] = '0'
buf[p+1] = '.'
buf[p+2] = '0'
buf[p+3] = 0
return
sig := mant
if exp != 0
sig = sig | 0x0010000000000000
shift := exp - 1075
if shift >= 0
(sig << shift)->to_str_buf(buf + p)
while buf[p]
p += 1
buf[p] = '.'
buf[p+1] = '0'
buf[p+2] = 0
return
ns := -shift
if ns <= 52
int_part := sig >> ns
int_part->to_str_buf(buf + p)
while buf[p]
p += 1
else
buf[p] = '0'
p += 1
buf[p] = '.'
p += 1
mask := (1 << ns) - 1
frac := sig & mask
for i in 0..6
if frac == 0
if i > 0
break
buf[p] = '0'
p += 1
break
frac = frac * 10
digit := frac >> ns
buf[p] = '0' + digit as u8
p += 1
frac = frac & mask
buf[p] = 0
func io.read_char[] : u8
c := 0 as u8
_builtin_syscall(SYS_read, STDIN, ^c, 1)
return c
func io.read_line[] : str
b := new str.Builder
while true
c := io.read_char()
if c == '\n'
break
b->append_char(c)
s := b->build()
b->destroy()
return s
func io.read_text_file[path: str] : str, bool
fd := _builtin_syscall(SYS_openat, AT_FDCWD, path, O_RDONLY, 0)
if fd < 0
return 0 as str, false
size := _builtin_syscall(SYS_lseek, fd, 0, SEEK_END)
_builtin_syscall(SYS_lseek, fd, 0, SEEK_SET)
buffer := mem.alloc(size + 1)
n := _builtin_syscall(SYS_read, fd, buffer, size)
_builtin_syscall(SYS_close, fd)
if n != size
buffer->free()
return 0 as str, false
buffer[n] = 0
return buffer as str, true
func io.read_binary_file[path: str] : Blob, bool
fd := _builtin_syscall(SYS_openat, AT_FDCWD, path, O_RDONLY, 0)
if fd < 0
return 0 as Blob, false
buf := new* Blob
buf->size = _builtin_syscall(SYS_lseek, fd, 0, SEEK_END)
_builtin_syscall(SYS_lseek, fd, 0, SEEK_SET)
buf->data = mem.alloc(buf->size)
n := _builtin_syscall(SYS_read, fd, buf->data, buf->size)
_builtin_syscall(SYS_close, fd)
if n != buf->size
buf->free()
return 0 as Blob, false
return buf, true
func io.write_file[path: str, content: str] : bool
return io.write_binary_file(path, content as ptr, content->len())
func io.write_binary_file[path: str, content: ptr, size: i64] : bool
fd := _builtin_syscall(SYS_openat, AT_FDCWD, path, O_WRONLY|O_CREAT|O_TRUNC, math.octal_to_decimal(644))
if fd < 0
return false
n := _builtin_syscall(SYS_write, fd, content, size)
_builtin_syscall(SYS_close, fd)
if n != size
return false
return true
func str.free[s: str] : void
mem.free(s)
func str.len[s: str] : i64
i := 0
while s[i]
i += 1
return i
func str.make_copy[s: str] : str
size := s->len() + 1
dup := mem.alloc(size) as str
mem.copy(s as ptr, dup as ptr, size)
return dup
func str.equal[a: str, b: str] : bool
i := 0
while a[i] != 0 && b[i] != 0
if a[i] != b[i]
return false
i += 1
return a[i] == b[i]
func str.format_into[..] : i64
buf := _var_arg(0) as ptr
size := _var_arg(1) as i64
if size <= 0
return 0
s := _var_arg(2) as ptr
i := 3
n := 0
tmp := _stackalloc(64) as str
while s[0]
if s[0] == '%'
s += 1
if s[0] == 'd'
(_var_arg(i) as i64)->to_str_buf(tmp as ptr)
tmp_len := tmp->len()
remaining := size - n - 1
mem.copy(tmp as ptr, buf + n, math.min(tmp_len, remaining))
n += tmp_len
i += 1
else if s[0] == 'x'
(_var_arg(i) as i64)->to_hex_str_buf(tmp as ptr)
tmp_len := tmp->len()
remaining := size - n - 1
mem.copy(tmp as ptr, buf + n, math.min(tmp_len, remaining))
n += tmp_len
i += 1
else if s[0] == 's'
tmp_str := _var_arg(i) as str
tmp_len := tmp_str->len()
remaining := size - n - 1
mem.copy(tmp_str as ptr, buf + n, math.min(tmp_len, remaining))
n += tmp_len
i += 1
else if s[0] == 'c'
if n < size - 1
buf[n] = _var_arg(i) as u8
n += 1
i += 1
else if s[0] == 'f'
// TODO: fix when we implement f64 params
f64.to_str_buf(_var_arg(i), tmp as ptr)
tmp_len := tmp->len()
remaining := size - n - 1
mem.copy(tmp as ptr, buf + n, math.min(tmp_len, remaining))
n += tmp_len
i += 1
else if s[0] == '%'
if n < size - 1
buf[n] = '%'
n += 1
else if s[0] == 0
break
else
panic("str.format_into: unrecognized format")
else
if n < size - 1
buf[n] = s[0]
n += 1
s += 1
if n < size
buf[n] = 0
else if size > 0
buf[size - 1] = 0
return n
func str.concat[a: str, b: str] : str
a_len := a->len()
b_len := b->len()
out := mem.alloc(a_len + b_len + 1) as str
mem.copy(a as ptr, out as ptr, a_len)
mem.copy(b as ptr, out as ptr + a_len, b_len)
out[a_len + b_len] = 0
return out
func str.contains[haystack: str, needle: str] : bool
return haystack->find(needle) != -1
func str.find[haystack: str, needle: str] : i64
haystack_len := haystack->len()
needle_len := needle->len()
if needle_len == 0
return 0
if needle_len > haystack_len
return -1
for i in 0..(haystack_len - needle_len + 1)
if haystack[i] != needle[0]
continue
if needle_len == 1
return i
match := true
for j in 1..needle_len
if haystack[i + j] != needle[j]
match = false
break
if match
return i
return -1
func str.substr[s: str, start: i64, length: i64] : str
out := mem.alloc(length + 1) as str
mem.copy(s as ptr + start, out as ptr, length)
out[length] = 0
return out
func str.trim[s: str] : str
len := s->len()
if len == 0
out := mem.alloc(1) as str
out[0] = 0
return out
start := 0
end := len - 1
while start <= end && s[start]->is_whitespace()
start += 1
while end >= start && s[end]->is_whitespace()
end -= 1
return s->substr(start, end - start + 1)
func str.split[haystack: str, needle: str]: Array
haystack_len := haystack->len()
needle_len := needle->len()
result := []
if !needle_len
if !haystack_len
return result
else
for i in 0..haystack_len
result->push(haystack->substr(i, 1))
return result
start := 0
i := 0
while i < haystack_len
if i <= haystack_len - needle_len
match := true
for j in 0..needle_len
if haystack[i + j] != needle[j]
match = false
break
if match
result->push(haystack->substr(start, i - start))
start = i + needle_len
i += needle_len
continue
i += 1
result->push(haystack->substr(start, haystack_len - start))
return result
func str.reverse[s: str] : str
len := s->len()
out := mem.alloc(len + 1) as str
for i in 0..len
out[i] = s[len - i - 1]
out[len] = 0
return out
func str.parse_i64[s: str] : i64
len := s->len()
i := 0
sign := 1
if i < len && s[i] == '-'
sign = -1
i += 1
num := 0
while i < len
d := s[i]
if !d->is_digit()
break
num = num * 10 + (d - '0')
i += 1
return num * sign
func str.hex_encode[s: str, s_len: i64] : str
hex_chars := "0123456789abcdef"
out := mem.alloc(s_len * 2 + 1) as str
for i in 0..s_len
b := s[i]
out[i * 2] = hex_chars[(b >> 4) & 15]
out[i * 2 + 1] = hex_chars[b & 15]
out[s_len * 2] = 0
return out
func str._hex_digit_to_int[d: u8] : u8
if d->is_digit()
return d - '0'
lower : u8 = d | 32
if lower >= 'a' && lower <= 'f'
return lower - 'a' + 10
panic("invalid hex digit passed to str._hex_digit_to_int")
func str.hex_decode[s: str] : str
s_len := s->len()
if s_len % 2 != 0
panic("invalid hex string passed to str.hex_decode")
out_len := s_len / 2
out := mem.alloc(out_len + 1) as str
for i in 0..out_len
high := str._hex_digit_to_int(s[i * 2])
low := str._hex_digit_to_int(s[i * 2 + 1])
out[i] = (high << 4) | low
out[out_len] = 0
return out
struct str.Builder
data: ptr
size: i64
capacity: i64
func str.Builder._grow[b: str.Builder, needed: i64] : void
if b->size + needed > b->capacity
new_capacity := 64
if b->capacity != 0
new_capacity = b->capacity * 2
while new_capacity < b->size + needed
new_capacity = new_capacity * 2
b->data = b->data->realloc(new_capacity)
b->capacity = new_capacity
func str.Builder.append_char[b: str.Builder, c: u8] : void
b->_grow(1)
b->data[b->size] = c
b->size += 1
func str.Builder.append[b: str.Builder, s: str] : void
len := s->len()
b->_grow(len)
mem.copy(s as ptr, b->data + b->size, len)
b->size += len
func str.Builder.build[b: str.Builder] : str
s := mem.alloc(b->size + 1) as str
mem.copy(b->data, s as ptr, b->size)
s[b->size] = 0
return s
func str.Builder.destroy[b: str.Builder] : void
if b->data != 0
b->data->free()
b->size = 0
b->capacity = 0
func u8.is_whitespace[x: u8] : bool
return x == ' ' || x == '\n' || x == '\t' || x == '\r'
func u8.is_digit[x: u8] : bool
return x >= '0' && x <= '9'
func u8.is_hex_digit[x: u8] : bool
return (x >= '0' && x <= '9') || (x >= 'a' && x <= 'f') || (x >= 'A' && x <= 'F')
func u8.is_lowercase[x: u8] : bool
return x >= 'a' && x <= 'z'
func u8.is_uppercase[x: u8] : bool
return x >= 'A' && x <= 'Z'
func u8.is_letter[x: u8] : bool
return x->is_uppercase() || x->is_lowercase()
func u8.is_alphanumeric[x: u8] : bool
return x->is_letter() || x->is_digit()
func u8.to_str[c: u8] : str
s := mem.alloc(2) as str
s[0] = c
s[1] = 0
return s
func i64.abs[n: i64] : i64
if n == -9223372036854775808
panic("MIN_I64 passed to math.abs")
if n < 0
return -n
return n
func i64.sign[n: i64] : i64
if n < 0
return -1
else if n > 0
return 1
else
return 0
func i64.isqrt[n: i64] : i64
if n < 0
panic("negative number passed to math.isqrt")
if n == 0 || n == 1
return n
guess := n
next_guess := (guess + n / guess) / 2
while next_guess < guess
guess = next_guess
next_guess = (guess + n / guess) / 2
return guess
func i64.is_prime[n: i64]: bool
if n <= 1
return false
if n == 2 || n == 3
return true
if n % 2 == 0 || n % 3 == 0
return false
i := 5
while i * i <= n
if n % i == 0 || n % (i + 2) == 0
return false
i += 6
return true
func i64.to_str[n: i64] : str
out := mem.alloc(21)
n->to_str_buf(out)
return out as str
func i64.to_str_buf[n: i64, buf: ptr] : void
if n == 0
buf[0] = '0'
buf[1] = 0
return
neg : bool = n < 0
if neg
// MIN_I64 will fail but i so dont care
n = -n
tmp := _stackalloc(21)
end := 20
tmp[end] = 0
end -= 1
for i in 0..19
if n == 0
break
tmp[end] = '0' + (n % 10)
n = n / 10
end -= 1
if neg
tmp[end] = '-'
end -= 1
len := 19 - end
for i in 0..len
buf[i] = tmp[end + 1 + i]
buf[len] = 0
func i64.to_hex_str[n: i64] : str
out := mem.alloc(17)
n->to_hex_str_buf(out)
return out as str
func i64.to_hex_str_buf[n: i64, buf: ptr] : void
hex_chars := "0123456789abcdef"
if n == 0
buf[0] = '0'
buf[1] = 0
return
mask := (1 << 60) - 1
tmp := _stackalloc(17)
len := 0
for i in 0..16
if n == 0
break
tmp[len] = hex_chars[n & 15]
n = (n >> 4) & mask
len += 1
for j in 0..len
buf[j] = tmp[len - 1 - j]
buf[len] = 0
func math.gcd[a: i64, b: i64] : i64
a = a->abs()
b = b->abs()
while b != 0
tmp := b
b = a % b
a = tmp
return a
func math.min[a: i64, b: i64] : i64
if a < b
return a
return b
func math.max[a: i64, b: i64] : i64
if a > b
return a
return b
func math.pow[b: i64, e: i64] : i64
if e < 0
panic("negative exponent passed to math.pow")
out := 1
while e > 0
if e & 1
out = out * b
b = b * b
e = e >> 1
return out
func math.lcm[a: i64, b: i64] : i64
return (a / math.gcd(a, b)) * b
func math.octal_to_decimal[octal: i64] : i64
decimal := 0
base := 1
while octal > 0
digit := octal % 10
decimal += digit * base
base = base * 8
octal = octal / 10
return decimal
struct Blob
data: ptr
size: i64
func Blob.alloc[size: i64] : Blob
buffer := new* Blob
buffer->size = size
buffer->data = mem.alloc(size)
return buffer
func Blob.free[buf: Blob] : void
buf->data->free()
mem.free(buf)
struct Array
data: ptr
size: i64
capacity: i64
func Array.new_preallocated_and_zeroed[size: i64] : Array
xs := new* Array
if size > 0
xs->data = mem.alloc(size * 8)
mem.zero(xs->data, size * 8)
xs->size = size
xs->capacity = size
return xs
func Array.nth[xs: Array, n: i64] : any
if n < 0 || n >= xs->size
panic("Array.nth out of bounds")
return mem.read64(xs->data + n * 8)
func Array.set[xs: Array, n: i64, x: any] : void
if n < 0 || n >= xs->size
panic("array.set out of bounds")
mem.write64(xs->data + n * 8, x)
func Array.push[xs: Array, x: any] : void
if xs->size == xs->capacity
new_capacity := 4
if xs->capacity != 0
new_capacity = xs->capacity * 2
xs->data = xs->data->realloc(new_capacity * 8)
xs->capacity = new_capacity
mem.write64(xs->data + xs->size * 8, x)
xs->size += 1
func Array.free[xs: Array] : void
if xs->data != 0
xs->data->free()
mem.free(xs)
func Array.free_with_items[xs: Array] : void
if xs->data != 0
for i in 0..xs->size
mem.free(xs->nth(i))
xs->data->free()
mem.free(xs)
func Array.pop[xs: Array] : any
if xs->size == 0
panic("Array.pop on empty array")
x : any = Array.last(xs)
xs->size = xs->size - 1
return x
func Array.last[xs: Array] : any
if xs->size == 0
panic("Array.last on empty array")
return xs->nth(xs->size - 1)
func Array.slice[xs: Array, start: i64, length: i64] : Array
if start < 0 || length < 0 || start + length > xs->size
panic("Array.slice out of bounds")
new_array := Array.new_preallocated_and_zeroed(length)
mem.copy(xs->data + start * 8, new_array->data, length * 8)
return new_array
func Array.concat[a: Array, b: Array] : Array
new_array := Array.new_preallocated_and_zeroed(a->size + b->size)
mem.copy(a->data, new_array->data, a->size * 8)
mem.copy(b->data, new_array->data + a->size * 8, b->size * 8)
return new_array
func Array.quicksort[arr: Array] : void
arr->_do_quicksort(0, arr->size - 1)
func Array._do_quicksort[arr: Array, low: i64, high: i64] : void
if low < high
i := arr->_partition(low, high)
arr->_do_quicksort(low, i - 1)
arr->_do_quicksort(i + 1, high)
func Array._partition[arr: Array, low: i64, high: i64] : i64
pivot : i64 = arr->nth(high)
i := low - 1
for j in (low)..high
if arr->nth(j) as i64 <= pivot
i += 1
temp : i64 = arr->nth(i)
arr->set(i, arr->nth(j))
arr->set(j, temp)
temp : i64 = arr->nth(i + 1)
arr->set(i + 1, arr->nth(high))
arr->set(high, temp)
return i + 1
func Array.contains_str[arr: Array, s: str] : bool
for i in 0..arr->size
if (arr->nth(i) as str)->equal(s)
return true
return false
func Array.count[arr: Array, item: any] : i64
count := 0
for i in 0..arr->size
if arr->nth(i) == item
count += 1
return count
func Array.map[arr: Array, fn: ptr] : Array
out := Array.new_preallocated_and_zeroed(arr->size)
for i in 0..arr->size
out->set(i, fn(arr->nth(i)))
return out
func Array.filter[arr: Array, fn: ptr] : Array
out := []
for i in 0..arr->size
if fn(arr->nth(i))
out->push(arr->nth(i))
return out
func Array.reduce[arr: Array, fn: ptr, acc: any] : any
for i in 0..arr->size
acc = fn(acc, arr->nth(i))
return acc
const HashMap._TABLE_SIZE = 100
struct HashMap
table: Array
struct HashMap._Node
key: str
value: any
next: HashMap._Node
func HashMap.new[] : HashMap
map := new* HashMap
map->table = Array.new_preallocated_and_zeroed(HashMap._TABLE_SIZE)
return map
func HashMap.insert[map: HashMap, key: str, value: any] : void
index := HashMap._djb2(key)
current : HashMap._Node = map->table->nth(index)
while current as ptr
if current->key->equal(key)
current->value = value
return
current = current->next
new_node := new* HashMap._Node
new_node->key = key->make_copy()
new_node->value = value
new_node->next = map->table->nth(index)
map->table->set(index, new_node)
func HashMap.get[map: HashMap, key: str] : any, bool
index := HashMap._djb2(key)
current : HashMap._Node = map->table->nth(index)
while current as ptr
if current->key->equal(key)
return current->value, true
current = current->next
return 0 as any, false
func HashMap.delete[map: HashMap, key: str] : void
index := HashMap._djb2(key)
current : HashMap._Node = map->table->nth(index)
prev := 0 as HashMap._Node
while current as ptr
if current->key->equal(key)
if prev as ptr
prev->next = current->next
else
map->table->set(index, current->next)
current->key->free()
mem.free(current)
return
prev = current
current = current->next
func HashMap._djb2[key: str] : i64
hash := 5381
for i in 0..key->len()
hash = ((hash << 5) + hash) + key[i]
hash = (hash & 0x7fffffffffffffff) // prevent negative
return hash % HashMap._TABLE_SIZE
func HashMap.free[map: HashMap] : void
for i in 0..HashMap._TABLE_SIZE
current : HashMap._Node = map->table->nth(i)
while current as ptr
tmp := current
current = current->next
tmp->key->free()
mem.free(tmp)
map->table->free()
mem.free(map)
func os.exit[code: i64] : void
_builtin_syscall(SYS_exit, code)
func os.getpid[] : i64
return _builtin_syscall(SYS_getpid)
func os.basename[path: str] : str
i := path->len() - 1
while i >= 0 && path[i] != '/'
i -= 1
return path->substr(i + 1, path->len() - i - 1)
struct os.Timespec
tv_sec: i64
tv_nsec: i64
func os.sleep[ms: i64] : void
if ms < 0
panic("negative time passed to os.sleep")
req := new os.Timespec
req->tv_sec = ms / 1000
req->tv_nsec = (ms % 1000) * 1000000
_builtin_syscall(SYS_nanosleep, req, 0)
func os.urandom_buf[buf: ptr, n: i64] : void
pos := 0
while pos < n
ret := _builtin_syscall(SYS_getrandom, buf + pos, n - pos, 0)
if ret <= 0
panic("os.urandom_buf: syscall failed")
pos += ret
func os.urandom[n: i64]: ptr
buf := mem.alloc(n)
os.urandom_buf(buf, n)
return buf
func os.urandom_i64[] : i64
n := 0
os.urandom_buf(^n, 8)
return n
struct os.Timeval
tv_sec: i64
tv_usec: i64
func os.time[] : i64
tv := new os.Timeval
_builtin_syscall(SYS_gettimeofday, tv, 0)
out := tv->tv_sec * 1000 + tv->tv_usec / 1000
return out
func os.run_shell_command[command: str] : i64, bool
pid := _builtin_syscall(SYS_fork)
if pid < 0
return -1, false
if pid == 0
argv := ["sh", "-c", command, 0] // gets freed after child process exits
_builtin_syscall(SYS_execve, "/bin/sh", argv->data, _builtin_environ())
os.exit(1)
else
status := 0
wp := _builtin_syscall(SYS_wait4, pid, ^status, 0, 0)
if wp < 0
return -1, false
st := status & 0xffffffff
if (st & 0x7f) == 0
return (st >> 8) & 0xff, true
else
return -(st & 0x7f), true
func os.file_exists[path: str] : bool
return _builtin_syscall(SYS_faccessat, AT_FDCWD, path, F_OK, 0) == 0
func os.is_a_directory[path: str] : bool
st := _stackalloc(256) // it has 21 mixed-size fields so ptr for now
rc := _builtin_syscall(SYS_newfstatat, AT_FDCWD, path, st, 0)
if rc != 0
return false
return (mem.read32(st + 24) & S_IFMT) == S_IFDIR
func os.list_directory[path: str] : Array, bool
fd := _builtin_syscall(SYS_openat, AT_FDCWD, path, O_RDONLY, 0)
if fd < 0
return 0 as Array, false
files := []
buf := _stackalloc(1024)
while true
n := _builtin_syscall(SYS_getdents64, fd, buf, 1024)
if n < 0
files->free_with_items()
_builtin_syscall(SYS_close, fd)
return 0 as Array, false
else if n == 0
break
pos := 0
while pos < n
len := mem.read16(buf + pos + 16)
name : ptr = buf + pos + 19
if name[0]
skip := false
// skip if name is exactly '.' or '..'
if name[0] == '.'
if name[1] == 0
skip = true
else if name[1] == '.'
if name[2] == 0
skip = true
if !skip
files->push((name as str)->make_copy())
pos += len
_builtin_syscall(SYS_close, fd)
return files, true