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[S] Worked on nim.

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eline
2023-11-29 00:22:39 +01:00
parent 8e703198b8
commit e774316a70
10 changed files with 1089 additions and 2 deletions
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9
elinethingz/README.md
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@@ -14,11 +14,18 @@ format:
# mic_reg.nim
[Broken]
Checks if Windows OSD is enabeld.
Checks if Windows OSD is enabled.
# encfile.nim
Has multiple functions to encrypt text and/or files (streams) with AES-256 derived using HMAC (SHA512_256). Max. password size 1024.
Has a fingerprint/is detectable.
# OFFENSIVEencfile.nim
Very stripped-down encryption tool. Takes a stream and encrypts it (AES256 with HMAC SHA512_256). No max. password size.
Has a fingerprint/is detectable.
# Packer.nim
Ideally a "packer"/loader for the main stage. Still very experimental and needs heavy rework.
# bsod.nim
Serves a BSOD to targets on Windows.

2
elinethingz/security/encfile.nim
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@@ -20,7 +20,7 @@ proc stretch(passw: string, iv1: array[16, byte]): array[32, byte] =
copyMem(addr passwBytes[0], unsafeAddr passw[0], len(passw))
for i in 1 .. 8192:
var sha: sha256
var sha: sha512_256
sha.init()
sha.update(digest)
sha.update(passwBytes[0..len(passw)-1])

230
elinethingz/security/packer/OFFENSIVEencfile.nim Normal file
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@@ -0,0 +1,230 @@
# _____ ___ ____ ____ _____ ____ ____ _____ _____
# |_ _/ _ \| _ \ / ___|| ____/ ___| _ \| ____|_ _|
# | || | | | |_) | \___ \| _|| | | |_) | _| | |
# | || |_| | __/ ___) | |__| |___| _ <| |___ | |
# |_| \___/|_| |____/|_____\____|_| \_\_____| |_|
# OFFENSIVEencfile.nim
# Modified version of the original "encfile.nim".
# This fork will be only supports encryption and not decryption.
# However, it encodes all information necessary to decrypt using "encfile.nim"
# It has no error handling. Good luck. In case of problem, check your password length.
# - Eline.
# Decryption HAS been tested as of 28 November 2023 (initial release).
# TODO: use sysargs to encrypt files :p
# i.e ./offensiveencfile input output password
# or maybe only get password interactively. hmm...
import nimcrypto
import std/sysrand
import std/streams
const
# default encryption/decryption buffer size - 64KB
bufferSizeDef = 64 * 1024
# maximum password length (number of chars)
# AES block size in bytes
AESBlockSize = 16
# password stretching function
proc stretch(passw: string, iv1: array[16, byte]): array[32, byte] =
var digest: array[32, byte]
copyMem(addr digest[0], unsafeAddr iv1[0], len(iv1))
var passwBytes: array[1024, byte]
copyMem(addr passwBytes[0], unsafeAddr passw[0], len(passw))
for i in 1 .. 8192:
var sha: sha512_256
sha.init()
sha.update(digest)
sha.update(passwBytes[0..len(passw)-1])
digest = sha.finish().data
return digest
# encrypt binary stream function
# arguments:
# fIn: input binary stream
# fOut: output binary stream
# passw: encryption password
# bufferSize: encryption buffer size, must be a multiple of
# AES block size (16)
# using a larger buffer speeds up things when dealing
# with long streams
proc encryptStream*(fIn: Stream, fOut: Stream, passw: string, bufferSize: int) =
# validate bufferSize
if bufferSize mod AESBlockSize != 0:
raise newException(OSError, "Buffer size must be a multiple of AES block size.")
# generate external iv (used to encrypt the main iv and the
# encryption key)
# let iv1 = urandom(AESBlockSize)
let initIv1 = urandom(AESBlockSize)
var iv1: array[16, byte]
for i in [0..15]:
iv1[i]=initIv1[i]
# stretch password and iv
let key = stretch(passw, iv1)
# generate random main iv
var iv0 = urandom(AESBlockSize)
# generate random internal key
var intKey = urandom(32)
# instantiate AES cipher
var encryptor0: CBC[aes256]
encryptor0.init(intKey, iv0)
# instantiate HMAC-SHA256 for the ciphertext
var hmac0: HMAC[sha512_256]
hmac0.init(intKey)
# instantiate another AES cipher
var encryptor1: CBC[aes256]
encryptor1.init(key, iv1)
# encrypt main iv and key
var plainText = newString(len(iv0)+len(intKey))
var c_iv_key = newString(len(iv0)+len(intKey))
copyMem(addr plainText[0], unsafeAddr iv0[0], len(iv0))
copyMem(addr plainText[0+len(iv0)], unsafeAddr intKey[0], len(intKey))
encryptor1.encrypt(plainText, c_iv_key)
# calculate HMAC-SHA256 of the encrypted iv and key
var hmac1: HMAC[sha512_256]
hmac1.init(key)
hmac1.update(c_iv_key)
# write header
fOut.write("AES")
# write version (AES Crypt version 2 file format -
# see https://www.aescrypt.com/aes_file_format.html)
fOut.write([byte 2])
# reserved byte (set to zero)
fOut.write([byte 0])
# setup "CREATED-BY" extension
var cby = "Confidential "
# write "CREATED-BY" extension length
fOut.write([byte 0, cast[uint8](1+len("CREATED_BY")+len(cby))])
# write "CREATED-BY" extension
fOut.write("CREATED_BY")
fOut.write([byte 0])
fOut.write(cby)
# write "container" extension length
fOut.write([byte 0, 128])
# write "container" extension
for i in 1 .. 128:
fOut.write([byte 0])
# write end-of-extensions tag
fOut.write([byte 0, 0])
# write the iv used to encrypt the main iv and the
# encryption key
fOut.write(iv1)
# write encrypted main iv and key
fOut.write(c_iv_key)
# write HMAC-SHA256 of the encrypted iv and key
fOut.write(hmac1.finish())
var fs16 = 0
# encrypt file while reading it
var fdata = newString(bufferSize)
var cText = newString(bufferSize)
while true:
# try to read bufferSize bytes
let bytesRead = fIn.readData(addr fdata[0], bufferSize)
# check if EOF was reached
if bytesRead < bufferSize:
# file size mod 16, lsb positions
fs16 = bytesRead mod AESBlockSize
# pad data (this is NOT PKCS#7!)
# ...unless no bytes or a multiple of a block size
# of bytes was read
var padLen: int
if bytesRead mod AESBlockSize == 0:
padLen = 0
else:
padLen = 16 - bytesRead mod AESBlockSize
# todo handl the pading to get the nb AES block & file with padLen, restrict the input of encrypt to x block
# fdata += bytes([padLen])*padLen
for i in bytesRead..bytesRead+padLen:
fdata[i]=cast[char](padLen)
# encrypt data
encryptor0.encrypt(fdata[0..bytesRead+padLen-1], cText)
# update HMAC
hmac0.update(cText[0..bytesRead+padLen-1])
# write encrypted file content
fOut.write(cText[0..bytesRead+padLen-1])
break
# ...otherwise a full bufferSize was read
else:
# encrypt data
encryptor0.encrypt(fdata, cText)
# update HMAC
hmac0.update(cText)
# write encrypted file content
fOut.write(cText)
# write plaintext file size mod 16 lsb positions
fOut.write(cast[uint8](fs16))
# write HMAC-SHA256 of the encrypted file
fOut.write(hmac0.finish())
# encrypt file function
# arguments:
# infile: plaintext file path
# outfile: ciphertext file path
# passw: encryption password
# bufferSize: optional buffer size, must be a multiple of
# AES block size (16)
# using a larger buffer speeds up things when dealing
# with big files
# Default is 64KB.
proc encryptFile*(infile: string, outfile: string, passw: string, bufferSize: int = bufferSizeDef) =
try:
let fIn = newFileStream(infile, mode = fmRead)
defer: fIn.close()
let fOut = newFileStream(outfile, mode = fmWrite)
defer: fOut.close()
encryptStream(fIn, fOut, passw, bufferSize)
except CatchableError:
let
e = getCurrentException()
msg = getCurrentExceptionMsg()
echo "Inside checkIn, got exception ", repr(e), " with message ", msg
#encryptFile("dza.png", "file.aes", "long-and-random-password", 1024)
#decryptFile("file.aes", "fileDecrypt.png", "long-and-random-password", 1024)

76
elinethingz/security/packer/packer.nim Normal file
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@@ -0,0 +1,76 @@
# _____ ___ ____ ____ _____ ____ ____ _____ _____
# |_ _/ _ \| _ \ / ___|| ____/ ___| _ \| ____|_ _|
# | || | | | |_) | \___ \| _|| | | |_) | _| | |
# | || |_| | __/ ___) | |__| |___| _ <| |___ | |
# |_| \___/|_| |____/|_____\____|_| \_\_____| |_|
# see https://github.com/byt3bl33d3r/OffensiveNim/blob/master/src/pop_bin.nim
# see https://github.com/byt3bl33d3r/OffensiveNim/blob/master/src/shellcode_bin.nim
import os
import system
const
MEM_COMMIT = 0x1000
MEM_RESERVE = 0x2000
PAGE_EXECUTE_READWRITE = 0x40
type
HANDLE* = int
HWND* = HANDLE
UINT* = int32
LPCSTR* = cstring
proc MessageBox*(hWnd: HWND, lpText: LPCSTR, lpCaption: LPCSTR, uType: UINT): int32
{.discardable, stdcall, dynlib: "user32", importc: "MessageBoxA".}
MessageBox(0, "Hello, world !", "Nim is Powerful", 0)
#  LPVOID VirtualAllocEx(
#  [in] HANDLE hProcess,
#  [in, optional] LPVOID lpAddress, BUT IF NULL: automatically calculated
#  [in] SIZE_T dwSize, is an int? size in bytes of memory region. "The size of the region of memory to allocate, in bytes."
#  [in] DWORD flAllocationType, see https://learn.microsoft.com/en-us/windows/win32/api/memoryapi/nf-memoryapi-virtualallocex
#  [in] DWORD flProtect
#  );
# proc NimVirtualAllocEx*(hWnd: HWND, lpAddress: pointer, dwSize: LPCSTR, uType: UINT): int32
# {.discardable, stdcall, dynlib: "user32", importc: "VirtualAllocEx".}
# Declare the VirtualAlloc function from Windows API
proc VirtualAlloc*(addr: pointer void, size: csize_t, allocType: cuint, protect: cuint): pointer cvoid {.importwinapi: "VirtualAlloc".}
# Declare a simple function that will be loaded into the allocated memory
proc helloWorld() =
echo "Hello, World from allocated memory!"
# Main procedure
proc main(): int =
# Calculate the size needed for the function
let codeSize = procSize(helloWorld)
# Allocate memory using VirtualAlloc
let allocatedMemory = VirtualAlloc(nil, codeSize, MEM_COMMIT or MEM_RESERVE, PAGE_EXECUTE_READWRITE)
if allocatedMemory == nil:
echo "Failed to allocate memory."
return 1 # Return an error code
# Copy the function code to the allocated memory
memcpy(allocatedMemory, addr(helloWorld), codeSize)
# Cast the allocated memory to a function pointer
let funcPointer: proc() {.cdecl.} = cast[proc()](allocatedMemory)
# Execute the function in the allocated memory
funcPointer()
# Deallocate the memory (optional)
os.free(allocatedMemory)
return 0 # Return 0 to indicate successful execution
when isMainModule:
main()

31
elinethingz/utils/basicadware.nim Normal file
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@@ -0,0 +1,31 @@
# _____ ___ ____ ____ _____ ____ ____ _____ _____
# |_ _/ _ \| _ \ / ___|| ____/ ___| _ \| ____|_ _|
# | || | | | |_) | \___ \| _|| | | |_) | _| | |
# | || |_| | __/ ___) | |__| |___| _ <| |___ | |
# |_| \___/|_| |____/|_____\____|_| \_\_____| |_|
import std/random
type
HANDLE* = int
HWND* = HANDLE
UINT* = int32
LPCSTR* = cstring
proc MessageBox*(hWnd: HWND, lpText: LPCSTR, lpCaption: LPCSTR, uType: UINT): int32
{.discardable, stdcall, dynlib: "user32", importc: "MessageBoxA".}
# example implementation: MessageBox(0, "Hello, world !", "Nim is Powerful", 0)
var
titlemessages = @["Are you really free?",
"Window on the street, only mesmerized and pondering... Am I in the right?"]
captionmessages = @["From the river to the sea, Palestine will be free.",
"I believe and have faith in you."]
randomize() # seeds randomizer
var
randomtitle:string = sample(titlemessages)
randommessage:string = sample(captionmessages)

1
elinethingz/utils/nimwinreg/.gitignore vendored Normal file
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@@ -0,0 +1 @@
nimcache/

19
elinethingz/utils/nimwinreg/README.md Normal file
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@@ -0,0 +1,19 @@
# nim-win-registry
A Windows Registry wrapper for Nim. Nim procs for the raw
[C function definitions](https://msdn.microsoft.com/en-us/library/windows/desktop/ms724868(v=vs.85).aspx) are defined
in `registrydef.nim`. `registry.nim` provides a more high-level API for interacting with the registry, but doesn't
support specialized cases like interacting with the security settings. It should cover most cases for storing
application settings, though. The higher-level wrapper is modeled after the
[C#-API](https://msdn.microsoft.com/en-us/library/microsoft.win32.registrykey(v=vs.110).aspx) for the registry. It
also checks for error codes automatically and throws exceptions if an error occured.
Sample Usage:
```nim
let key = HKEY_CURRENT_USER.openSubKey("SOFTWARE\\YourCompany\\YourSoftware", true)
echo key.getValue("version", "1.0.0")
key.setValue("version", "1.1.0")
key.close()
```
If you opened a key, do not forget to close it if you don't need it anymore.

393
elinethingz/utils/nimwinreg/registry.nim Normal file
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@@ -0,0 +1,393 @@
import registrydef, strutils, typetraits, winlean
type
RegistryError* = object of ValueError
const
FORMAT_MESSAGE_ALLOCATE_BUFFER = 0x100
FORMAT_MESSAGE_IGNORE_INSERTS = 0x200
FORMAT_MESSAGE_FROM_SYSTEM = 0x1000
ERROR_SUCCESS = 0
ERROR_FILE_NOT_FOUND = 2
USER_LANGUAGE = 0x0400
MAX_KEY_LEN = 255
MAX_VALUE_LEN = 16383
proc getErrorMessage(code: int32): string {.raises: [].} =
var msgbuf: pointer
when useWinUnicode:
discard formatMessageW(FORMAT_MESSAGE_FROM_SYSTEM or FORMAT_MESSAGE_ALLOCATE_BUFFER or
FORMAT_MESSAGE_IGNORE_INSERTS, nil, code, USER_LANGUAGE, msgbuf.addr, 0, nil)
result = $cast[WideCString](msgbuf)
else:
discard formatMessageA(FORMAT_MESSAGE_FROM_SYSTEM or FORMAT_MESSAGE_ALLOCATE_BUFFER or
FORMAT_MESSAGE_IGNORE_INSERTS, nil, code, USER_LANGUAGE, msgbuf.addr, 0, nil)
result = $cast[CString](msgbuf)
localFree(msgbuf)
proc raiseError(code: int32) {.inline, raises: [RegistryError].} =
raise newException(RegistryError, $code & ": " & getErrorMessage(code))
proc close*(this: RegistryKey) {.raises: [RegistryError].} =
## Closes the key and flushes it to disk if its contents have been modified.
let code = regCloseKey(this)
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
proc createSubKey*(this: RegistryKey, subkey: string, writable: bool): RegistryKey {.raises: [RegistryError].} =
## Creates a new subkey or opens an existing subkey with the specified access.
var createdHandle: RegistryKey
when useWinUnicode:
let code = regCreateKeyExW(this, newWideCString(subkey), 0, nil, 0,
if writable: KEY_ALL_ACCESS else: KEY_READ, nil, createdHandle.addr, nil)
else:
let code = regCreateKeyExA(this, newCString(subkey), 0, nil, 0,
if writable: KEY_ALL_ACCESS else: KEY_READ, nil, createdHandle.addr, nil)
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
return createdHandle
proc createSubKey*(this: RegistryKey, subkey: string): RegistryKey {.raises: [RegistryError].} =
## Creates a new subkey or opens an existing subkey for write access.
return this.createSubKey(subkey, true)
proc deleteSubKey*(this: RegistryKey, subkey: string, raiseOnMissingSubKey: bool) {.raises: [RegistryError].} =
## Deletes the specified subkey, and specifies whether an exception is raised if the subkey is not found.
when useWinUnicode:
let code = regDeleteKeyW(this, newWideCString(subkey))
else:
let code = regDeleteKeyA(this, newCString(subkey))
if unlikely(code != ERROR_SUCCESS) and (raiseOnMissingSubKey or code != ERROR_FILE_NOT_FOUND):
raiseError(code)
proc deleteSubKey*(this: RegistryKey, subkey: string) {.raises: [RegistryError].} =
## Deletes the specified subkey.
this.deleteSubKey(subkey, true)
proc deleteSubKeyTree*(this: RegistryKey, subkey: string, raiseOnMissingSubKey: bool)
{.raises: [RegistryError].} =
## Deletes the specified subkey and any child subkeys recursively, and
## specifies whether an exception is raised if the subkey is not found.
when useWinUnicode:
let code = regDeleteTreeW(this, newWideCString(subkey))
else:
let code = regDeleteTreeA(this, newCString(subkey))
if unlikely(code != ERROR_SUCCESS) and (raiseOnMissingSubKey or code != ERROR_FILE_NOT_FOUND):
raiseError(code)
proc deleteSubKeyTree*(this: RegistryKey, subkey: string) {.raises: [RegistryError].} =
## Deletes a subkey and any child subkeys recursively.
this.deleteSubKeyTree(subkey, true)
proc deleteValue*(this: RegistryKey, name: string, raiseOnMissingValue: bool) {.raises: [RegistryError].} =
## Deletes the specified value from this key, and specifies whether
## an exception is raised if the value is not found.
when useWinUnicode:
let code = regDeleteKeyValueW(this, nil, newWideCString(name))
else:
let code = regDeleteKeyValueA(this, nil, newCString(name))
if unlikely(code != ERROR_SUCCESS) and (raiseOnMissingValue or code != ERROR_FILE_NOT_FOUND):
raiseError(code)
proc deleteValue*(this: RegistryKey, name: string) {.raises: [RegistryError].} =
## Deletes the specified value from this key.
this.deleteValue(name, true)
proc flush*(this: RegistryKey) {.raises: [RegistryError].} =
## Writes all the attributes of the specified open registry key into the registry.
let code = regFlushKey(this)
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
iterator getSubKeyNames*(this: RegistryKey): string {.raises: [RegistryError].} =
## Retrieves an iterator of strings that runs over all the subkey names.
var keyCount: int32
when useWinUnicode:
let code = regQueryInfoKeyW(this, nil, nil, nil, keyCount.addr, nil, nil, nil, nil, nil, nil, nil)
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
var nameBuffer: WideCString
unsafeNew(nameBuffer, (MAX_KEY_LEN + 1) * sizeof(Utf16Char))
for i in 0..<keyCount:
var nameLen: int32 = MAX_KEY_LEN
let code = regEnumKeyExW(this, int32(i), nameBuffer, nameLen.addr, nil, nil, nil, nil)
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
nameBuffer[nameLen] = Utf16Char(0)
yield $nameBuffer
else:
let code = regQueryInfoKeyA(this, nil, nil, nil, keyCount.addr, nil, nil, nil, nil, nil, nil, nil)
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
var nameBuffer: CString
unsafeNew(nameBuffer, MAX_KEY_LEN + 1)
for i in 0..<keyCount:
var nameLen: int32 = MAX_KEY_LEN
let code = regEnumKeyExA(this, int32(i), nameBuffer, nameLen.addr, nil, nil, nil, nil)
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
nameBuffer[nameLen] = 0
yield $nameBuffer
proc tryGetValue*[T](this: RegistryKey, name: string, value: var T): bool
{.raises: [RegistryError, ValueError, Defect].} =
## Retrieves the value associated with the specified name.
## Attempts to convert values to the correct type, if applicable.
var kind: RegistryValueType
var size: int32
when useWinUnicode:
let code = regQueryValueExW(this, newWideCString(name), nil, kind.addr, nil, size.addr)
else:
let code = regQueryValueExA(this, newCString(name), nil, kind.addr, nil, size.addr)
if code == ERROR_FILE_NOT_FOUND:
return false
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
case kind:
of REG_DWORD:
var tmp: int32
size = int32(sizeof(tmp))
when useWinUnicode:
let code = regGetValueW(this, nil, newWideCString(name), 0x0000ffff, nil,
cast[pointer](tmp.addr), size.addr)
else:
let code = regGetValueA(this, nil, newCString(name), 0x0000ffff, nil,
cast[pointer](tmp.addr), size.addr)
if code == ERROR_FILE_NOT_FOUND:
return false
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
when T is SomeNumber:
value = T(tmp)
return true
elif T is string:
value = $tmp
return true
else:
{.fatal: "The type " & T.name & " is not supported yet.".}
of REG_QWORD:
var tmp: int64
size = int32(sizeof(tmp))
when useWinUnicode:
let code = regGetValueW(this, nil, newWideCString(name), 0x0000ffff, nil,
cast[pointer](tmp.addr), size.addr)
else:
let code = regGetValueA(this, nil, newCString(name), 0x0000ffff, nil,
cast[pointer](tmp.addr), size.addr)
if code == ERROR_FILE_NOT_FOUND:
return false
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
when T is SomeNumber:
value = T(tmp)
return true
elif T is string:
value = $tmp
return true
else:
{.fatal: "The type " & T.name & " is not supported yet.".}
of REG_BINARY:
var tmp: float64
size = int32(sizeof(tmp))
when useWinUnicode:
let code = regGetValueW(this, nil, newWideCString(name), 0x0000ffff, nil,
cast[pointer](tmp.addr), size.addr)
else:
let code = regGetValueA(this, nil, newCString(name), 0x0000ffff, nil,
cast[pointer](tmp.addr), size.addr)
if code == ERROR_FILE_NOT_FOUND:
return false
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
when T is SomeNumber:
value = T(tmp)
return true
elif T is string:
value = $tmp
return true
else:
{.fatal: "The type " & T.name & " is not supported yet.".}
of REG_SZ, REG_EXPAND_SZ:
when useWinUnicode:
var buffer: WideCString
unsafeNew(buffer, size + sizeof(Utf16Char))
buffer[size div sizeof(Utf16Char) - 1] = Utf16Char(0)
let code = regGetValueW(this, nil, newWideCString(name), 0x0000ffff, nil,
cast[pointer](buffer), size.addr)
else:
var buffer: CString
unsafeNew(buffer, size + 1)
buffer[size - 1] = 0
let code = regGetValueA(this, nil, newCString(name), 0x0000ffff, nil,
cast[pointer](buffer), size.addr)
if code == ERROR_FILE_NOT_FOUND:
return false
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
when T is SomeOrdinal:
value = parseInt($buffer)
return true
elif T is SomeNumber:
value = parseFloat($buffer)
return true
elif T is string:
value = $buffer
return true
else:
{.fatal: "The type " & T.name & " is not supported yet.".}
else:
raise newException(RegistryError, "The registry value is of type " & $kind & ", which is not supported")
proc getValue*[T](this: RegistryKey, name: string, default: T): T
{.raises: [RegistryError, ValueError, Defect].} =
## Retrieves the value associated with the specified name. If the name is not found, returns
## the default value that you provide. Attempts to convert values to the correct type, if applicable.
if not this.tryGetValue(name, result):
result = default
proc getValueKind*(this: RegistryKey, name: string): RegistryValueType {.raises: [RegistryError].} =
## Retrieves the registry data type of the value associated with the specified name.
when useWinUnicode:
let code = regQueryValueExW(this, newWideCString(name), nil, result.addr, nil, nil)
else:
let code = regQueryValueExA(this, newCString(name), nil, result.addr, nil, nil)
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
iterator getValueNames*(this: RegistryKey): string {.raises: [RegistryError].} =
## Retrieves an iterator of strings that runs over all the value names associated with this key.
var valCount: int32
when useWinUnicode:
let code = regQueryInfoKeyW(this, nil, nil, nil, nil, nil, nil, valCount.addr, nil, nil, nil, nil)
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
var nameBuffer: WideCString
unsafeNew(nameBuffer, (MAX_VALUE_LEN + 1) * sizeof(Utf16Char))
for i in 0..<valCount:
var nameLen: int32 = MAX_VALUE_LEN
let code = regEnumValueW(this, int32(i), nameBuffer, nameLen.addr, nil, nil, nil, nil)
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
nameBuffer[nameLen] = Utf16Char(0)
yield $nameBuffer
else:
let code = regQueryInfoKeyA(this, nil, nil, nil, nil, nil, nil, valCount.addr, nil, nil, nil, nil)
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
var nameBuffer: CString
unsafeNew(nameBuffer, MAX_VALUE_LEN + 1)
for i in 0..<valCount:
var nameLen: int32 = MAX_VALUE_LEN
let code = regEnumValueA(this, int32(i), nameBuffer, nameLen.addr, nil, nil, nil, nil)
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
nameBuffer[nameLen] = 0
yield $nameBuffer
proc openSubKey*(this: RegistryKey, name: string, writable: bool): RegistryKey {.raises: [RegistryError].} =
## Retrieves a specified subkey, and specifies whether write access is to be applied to the key.
when useWinUnicode:
let code = regOpenKeyExW(this, newWideCString(name), 0, if writable: KEY_ALL_ACCESS else: KEY_READ, result.addr)
else:
let code = regOpenKeyExA(this, newCString(name), 0, if writable: KEY_ALL_ACCESS else: KEY_READ, result.addr)
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
proc openSubKey*(this: RegistryKey, name: string): RegistryKey {.raises: [RegistryError].} =
## Retrieves a subkey as read-only.
return this.openSubKey(name, false)
proc setValue[T](this: RegistryKey, name: string, value: T, valueKind: RegistryValueType) {.raises: [RegistryError].} =
## Sets the specified name/value pair in the registry key, using the specified registry data type.
when T is string:
when useWinUnicode:
let wstr = newWideCString(value)
let code = regSetKeyValueW(this, nil, newWideCString(name), valueKind,
cast[pointer](wstr), int32(wstr.len * sizeof(Utf16Char) + sizeof(Utf16Char)))
else:
let cstr = newCString(value)
let code = regSetKeyValueExA(this, nil, newCString(name), valueKind,
cast[pointer](cstr), int32(cstr.len + 1))
elif T is SomeNumber:
var val = value
when useWinUnicode:
let code = regSetKeyValueW(this, nil, newWideCString(name), valueKind, val.addr, int32(sizeof(value)))
else:
let code = regSetKeyValueA(this, nil, newCString(name), valueKind, val.addr, int32(sizeof(value)))
else:
{.fatal: "A value of type " & T.name & " cannot be written directly to the registry.".}
if unlikely(code != ERROR_SUCCESS):
raiseError(code)
proc setValue*[T](this: RegistryKey, name: string, value: T) {.raises: [RegistryError].} =
## Sets the specified name/value pair.
# int and uint get a special handling on 64bit because of consistency,
# else writing the value on 64bit and reading the value on 32bit might cause problems.
when T is int and sizeof(int) == 8:
{.warning: "Only a REG_DWORD is written when using int in 64bit mode.".}
this.setValue(name, int32(value), REG_DWORD)
when T is uint and sizeof(uint) == 8:
{.warning: "Only a REG_DWORD is written when using uint in 64bit mode.".}
this.setValue(name, uint32(value), REG_DWORD)
when T is int64 or T is uint64:
this.setValue(name, value, REG_QWORD)
elif T is SomeOrdinal:
this.setValue(name, value, REG_DWORD)
elif T is SomeNumber:
this.setValue(name, float64(value), REG_BINARY)
elif T is string:
this.setValue(name, value, REG_SZ)
else:
{.fatal: "A value of type " & T.name & " cannot be written directly to the registry.".}

319
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import winlean
{.deadCodeElim: on.}
const
REG_LIB = "Advapi32"
type
RegistryKey* = Handle
RegistrySecurityAccess* = enum
KEY_QUERY_VALUE = 0x0001,
KEY_SET_VALUE = 0x0002,
KEY_CREATE_SUB_KEY = 0x0004,
KEY_ENUMERATE_SUB_KEYS = 0x0008,
KEY_NOTIFY = 0x0010,
KEY_CREATE_LINK = 0x0020,
KEY_WOW64_64KEY = 0x0100,
KEY_WOW64_32KEY = 0x0200,
KEY_WRITE = 0x20006,
KEY_READ = 0x20019,
KEY_ALL_ACCESS = 0xf003f
RegistryValueType* = enum
REG_NONE = 0i32,
REG_SZ = 1i32,
REG_EXPAND_SZ = 2i32,
REG_BINARY = 3i32,
REG_DWORD = 4i32,
REG_DWORD_BIG_ENDIAN = 5i32,
REG_LINK = 6i32,
REG_MULTI_SZ = 7i32,
REG_RESOURCE_LIST = 8i32,
REG_FULL_RESOURCE_DESCRIPTOR = 9i32,
REG_RESOURCE_REQUIREMENTS_LIST = 10i32,
REG_QWORD = 11i32
ACL = object
aclRevision: uint8
sbz1: uint8
aclSize: uint16
aceCount: uint16
sbz2: uint16
SECURITY_INFORMATION = DWORD
SECURITY_DESCRIPTOR = object
revision: uint8
sbz1: uint8
control: uint16
owner: pointer
group: pointer
sacl: ptr ACL
dacl: ptr ACL
when useWinUnicode:
type
VALENT = object
veValuename: WideCString
veValuelen: DWORD
veValueptr: DWORD
veType: DWORD
else:
type
VALENT = object
veValuename: CString
veValuelen: DWORD
veValueptr: DWORD
veType: DWORD
const
HKEY_CLASSES_ROOT* = RegistryKey(0x80000000)
HKEY_CURRENT_USER* = RegistryKey(0x80000001)
HKEY_LOCAL_MACHINE* = RegistryKey(0x80000002)
HKEY_USERS* = RegistryKey(0x80000003)
HKEY_PERFORMANCE_DATA* = RegistryKey(0x80000004)
HKEY_CURRENT_CONFIG* = RegistryKey(0x80000005)
HKEY_DYN_DATA* {.deprecated.} = RegistryKey(0x80000006)
proc regCloseKey*(hKey: RegistryKey): int32 {.stdcall, dynlib: REG_LIB, importc: "RegCloseKey".}
when useWinUnicode:
proc regConnectRegistryW*(lpMachineName: WideCString, hKey: RegistryKey, phkResult: ptr RegistryKey): int32
{.stdcall, dynlib: REG_LIB, importc: "RegConnectRegistryW".}
else:
proc regConnectRegistryA*(lpMachineName: CString, hKey: RegistryKey, phkResult: ptr RegistryKey): int32
{.stdcall, dynlib: REG_LIB, importc: "RegConnectRegistryA".}
when useWinUnicode:
proc regCopyTreeW*(hKeySrc: RegistryKey, lpSubKey: WideCString, hKeyDest: RegistryKey): int32
{.stdcall, dynlib: REG_LIB, importc: "RegCopyTreeW".}
else:
proc regCopyTreeA*(hKeySrc: RegistryKey, lpSubKey: CString, hKeyDest: RegistryKey): int32
{.stdcall, dynlib: REG_LIB, importc: "RegCopyTreeA".}
when useWinUnicode:
proc regCreateKeyExW*(hKey: RegistryKey, lpSubKey: WideCString, reserved: int32, lpClass: WideCString, dwOptions: int32,
samDesired: RegistrySecurityAccess, lpSecurityAttributes: ptr SECURITY_ATTRIBUTES, phkResult: ptr RegistryKey,
lpdwDisposition: ptr DWORD): int32 {.stdcall, dynlib: REG_LIB, importc: "RegCreateKeyExW".}
else:
proc regCreateKeyExA*(hKey: RegistryKey, lpSubKey: CString, reserved: int32, lpClass: CString, dwOptions: int32,
samDesired: RegistrySecurityAccess, lpSecurityAttributes: ptr SECURITY_ATTRIBUTES, phkResult: ptr RegistryKey,
lpdwDisposition: ptr DWORD): int32 {.stdcall, dynlib: REG_LIB, importc: "RegCreateKeyExA".}
when useWinUnicode:
proc regCreateKeyTransactedW*(hKey: RegistryKey, lpSubKey: WideCString, reserved: DWORD, lpClass: WideCString,
dwOptions: DWORD, samDesired: RegistrySecurityAccess, lpSecurityAttributes: ptr SECURITY_ATTRIBUTES, phkResult: ptr RegistryKey,
lpdwDisposition: ptr DWORD, hTransaction: Handle, pExtendedParameter: pointer): int32
{.stdcall, dynlib: REG_LIB, importc: "RegCreateKeyTransactedW".}
else:
proc regCreateKeyTransactedA*(hKey: RegistryKey, lpSubKey: CString, reserved: DWORD, lpClass: CString,
dwOptions: DWORD, samDesired: RegistrySecurityAccess, lpSecurityAttributes: ptr SECURITY_ATTRIBUTES, phkResult: ptr RegistryKey,
lpdwDisposition: ptr DWORD, hTransaction: Handle, pExtendedParameter: pointer): int32
{.stdcall, dynlib: REG_LIB, importc: "RegCreateKeyTransactedA".}
when useWinUnicode:
proc regDeleteKeyW*(hKey: RegistryKey, lpSubKey: WideCString): int32 {.stdcall, dynlib: REG_LIB, importc: "RegDeleteKeyW".}
else:
proc regDeleteKeyA*(hKey: RegistryKey, lpSubKey: CString): int32 {.stdcall, dynlib: REG_LIB, importc: "RegDeleteKeyA".}
when useWinUnicode:
proc regDeleteKeyExW*(hKey: RegistryKey, lpSubKey: WideCString, samDesired: RegistrySecurityAccess, reserved: DWORD): int32
{.stdcall, dynlib: REG_LIB, importc: "RegDeleteKeyExW".}
else:
proc regDeleteKeyExA*(hKey: RegistryKey, lpSubKey: CString, samDesired: RegistrySecurityAccess, reserved: DWORD): int32
{.stdcall, dynlib: REG_LIB, importc: "RegDeleteKeyExA".}
when useWinUnicode:
proc regDeleteKeyTransactedW*(hKey: RegistryKey, lpSubKey: WideCString, samDesired: RegistrySecurityAccess, reserved: DWORD,
hTransaction: Handle, pExtendedParameter: pointer): int32
{.stdcall, dynlib: REG_LIB, importc: "RegDeleteKeyTransactedW".}
else:
proc regDeleteKeyTransactedA*(hKey: RegistryKey, lpSubKey: CString, samDesired: RegistrySecurityAccess, reserved: DWORD,
hTransaction: Handle, pExtendedParameter: pointer): int32
{.stdcall, dynlib: REG_LIB, importc: "RegDeleteKeyTransactedA".}
when useWinUnicode:
proc regDeleteKeyValueW*(hKey: RegistryKey, lpSubKey: WideCString, lpValueName: WideCString): int32
{.stdcall, dynlib: REG_LIB, importc: "RegDeleteKeyValueW".}
else:
proc regDeleteKeyValueA*(hKey: RegistryKey, lpSubKey: CString, lpValueName: CString): int32
{.stdcall, dynlib: REG_LIB, importc: "RegDeleteKeyValueA".}
when useWinUnicode:
proc regDeleteTreeW*(hKey: RegistryKey, lpSubKey: WideCString): int32
{.stdcall, dynlib: REG_LIB, importc: "RegDeleteTreeW".}
else:
proc regDeleteTreeA*(hKey: RegistryKey, lpSubKey: CString): int32
{.stdcall, dynlib: REG_LIB, importc: "RegDeleteTreeA".}
when useWinUnicode:
proc regDeleteValueW*(hKey: RegistryKey, lpValueName: WideCString): int32
{.stdcall, dynlib: REG_LIB, importc: "RegDeleteValueW".}
else:
proc regDeleteValueA*(hKey: RegistryKey, lpValueName: CString): int32
{.stdcall, dynlib: REG_LIB, importc: "RegDeleteValueA".}
proc regDisablePredefinedCache*(): int32 {.stdcall, dynlib: REG_LIB, importc: "RegDisablePredefinedCache".}
proc regDisablePredefinedCacheEx*(): int32 {.stdcall, dynlib: REG_LIB, importc: "RegDisablePredefinedCacheEx".}
proc regDisableReflectionKey*(hBase: RegistryKey): int32 {.stdcall, dynlib: REG_LIB, importc: "RegDisableReflectionKey".}
proc regEnableReflectionKey*(hBase: RegistryKey): int32 {.stdcall, dynlib: REG_LIB, importc: "RegEnableReflectionKey".}
when useWinUnicode:
proc regEnumKeyExW*(hKey: RegistryKey, dwIndex: DWORD, lpName: WideCString, lpcName: ptr DWORD, lpReserved: ptr DWORD,
lpClass: WideCString, lpcClass: ptr DWORD, lpftLastWriteTime: ptr FILETIME): int32
{.stdcall, dynlib: REG_LIB, importc: "RegEnumKeyExW".}
else:
proc regEnumKeyExA*(hKey: RegistryKey, dwIndex: DWORD, lpName: CString, lpcName: ptr DWORD, lpReserved: ptr DWORD,
lpClass: CString, lpcClass: ptr DWORD, lpftLastWriteTime: ptr FILETIME): int32
{.stdcall, dynlib: REG_LIB, importc: "RegEnumKeyExA".}
when useWinUnicode:
proc regEnumValueW*(hKey: RegistryKey, dwIndex: DWORD, lpValueName: WideCString, lpcchValueName: ptr DWORD,
lpReserved: ptr DWORD, lpType: ptr DWORD, lpData: ptr uint8, lpcbData: ptr DWORD): int32
{.stdcall, dynlib: REG_LIB, importc: "RegEnumValueW".}
else:
proc regEnumValueA*(hKey: RegistryKey, dwIndex: DWORD, lpValueName: CString, lpcchValueName: ptr DWORD,
lpReserved: ptr DWORD, lpType: ptr DWORD, lpData: ptr uint8, lpcbData: ptr DWORD): int32
{.stdcall, dynlib: REG_LIB, importc: "RegEnumValueA".}
proc regFlushKey*(hKey: RegistryKey): int32 {.stdcall, dynlib: REG_LIB, importc: "RegFlushKey".}
proc regGetKeySecurity*(hKey: RegistryKey, securityInformation: SECURITY_INFORMATION,
pSecurityDescriptor: ptr SECURITY_DESCRIPTOR, lpcbSecurityDescriptor: ptr DWORD): int32
{.stdcall, dynlib: REG_LIB, importc: "RegGetKeySecurity".}
when useWinUnicode:
proc regGetValueW*(hKey: RegistryKey, lpSubKey: WideCString, lpValue: WideCString, dwFlags: DWORD, pdwType: ptr DWORD,
pvData: pointer, pcbData: ptr DWORD): int32 {.stdcall, dynlib: REG_LIB, importc: "RegGetValueW".}
else:
proc regGetValueA*(hKey: RegistryKey, lpSubKey: CString, lpValue: CString, dwFlags: DWORD, pdwType: ptr DWORD,
pvData: pointer, pcbData: ptr DWORD): int32 {.stdcall, dynlib: REG_LIB, importc: "RegGetValueA".}
when useWinUnicode:
proc regLoadKeyW*(hKey: RegistryKey, lpSubKey: WideCString, lpFile: WideCString): int32
{.stdcall, dynlib: REG_LIB, importc: "RegLoadKeyW".}
else:
proc regLoadKeyA*(hKey: RegistryKey, lpSubKey: CString, lpFile: CString): int32
{.stdcall, dynlib: REG_LIB, importc: "RegLoadKeyA".}
when useWinUnicode:
proc regLoadMUIStringW*(hKey: RegistryKey, pszValue: WideCString, pszOutBuf: WideCString, cbOutBuf: DWORD,
pcbData: ptr DWORD, flags: DWORD, pszDirectory: WideCString): int32
{.stdcall, dynlib: REG_LIB, importc: "RegLoadMUIStringW".}
else:
proc regLoadMUIStringA*(hKey: RegistryKey, pszValue: CString, pszOutBuf: CString, cbOutBuf: DWORD,
pcbData: ptr DWORD, flags: DWORD, pszDirectory: CString): int32
{.stdcall, dynlib: REG_LIB, importc: "RegLoadMUIStringA".}
proc regNotifyChangeKeyValue*(hKey: RegistryKey, bWatchSubtree: WINBOOL, dwNotifyFilter: DWORD, hEvent: Handle,
fAsynchronous: WINBOOL): int32 {.stdcall, dynlib: REG_LIB, importc: "RegNotifyChangeKeyValue".}
proc regOpenCurrentUser*(samDesired: RegistrySecurityAccess, phkResult: ptr RegistryKey): int32
{.stdcall, dynlib: REG_LIB, importc: "RegOpenCurrentUser".}
when useWinUnicode:
proc regOpenKeyExW*(hKey: RegistryKey, lpSubKey: WideCString, ulOptions: DWORD, samDesired: RegistrySecurityAccess,
phkResult: ptr RegistryKey): int32 {.stdcall, dynlib: REG_LIB, importc: "RegOpenKeyExW".}
else:
proc regOpenKeyExA*(hKey: RegistryKey, lpSubKey: CString, ulOptions: DWORD, samDesired: RegistrySecurityAccess,
phkResult: ptr RegistryKey): int32 {.stdcall, dynlib: REG_LIB, importc: "RegOpenKeyExA".}
when useWinUnicode:
proc regOpenKeyTransactedW*(hKey: RegistryKey, lpSubKey: WideCString, ulOptions: DWORD, samDesired: RegistrySecurityAccess,
phkResult: ptr RegistryKey, hTransaction: Handle, pExtendedParameter: pointer): int32
{.stdcall, dynlib: REG_LIB, importc: "RegOpenKeyTransactedW".}
else:
proc regOpenKeyTransactedA*(hKey: RegistryKey, lpSubKey: CString, ulOptions: DWORD, samDesired: RegistrySecurityAccess,
phkResult: ptr RegistryKey, hTransaction: Handle, pExtendedParameter: pointer): int32
{.stdcall, dynlib: REG_LIB, importc: "RegOpenKeyTransactedA".}
proc regOpenUserClassesRoot*(hToken: Handle, dwOptions: DWORD, samDesired: RegistrySecurityAccess, phkResult: ptr RegistryKey): int32
{.stdcall, dynlib: REG_LIB, importc: "RegOpenUserClassesRoot".}
proc regOverridePredefKey*(hKey: RegistryKey, hNewHKey: RegistryKey): int32
{.stdcall, dynlib: REG_LIB, importc: "RegOverridePredefKey".}
when useWinUnicode:
proc regQueryInfoKeyW*(hKey: RegistryKey, lpClass: WideCString, lpcClass: ptr DWORD, lpReserved: ptr DWORD,
lpcSubKeys: ptr DWORD, lpcMaxSubKeyLen: ptr DWORD, lpcMaxClassLen: ptr DWORD, lpcValues: ptr DWORD,
lpcMaxValueNameLen: ptr DWORD, lpcValueLen: ptr DWORD, lpcbSecurityDescription: ptr DWORD,
lpftLastWriteTime: ptr FILETIME): int32 {.stdcall, dynlib: REG_LIB, importc: "RegQueryInfoKeyW".}
else:
proc regQueryInfoKeyA*(hKey: RegistryKey, lpClass: CString, lpcClass: ptr DWORD, lpReserved: ptr DWORD,
lpcSubKeys: ptr DWORD, lpcMaxSubKeyLen: ptr DWORD, lpcMaxClassLen: ptr DWORD, lpcValues: ptr DWORD,
lpcMaxValueNameLen: ptr DWORD, lpcValueLen: ptr DWORD, lpcbSecurityDescription: ptr DWORD,
lpftLastWriteTime: ptr FILETIME): int32 {.stdcall, dynlib: REG_LIB, importc: "RegQueryInfoKeyA".}
when useWinUnicode:
proc regQueryMultipleValuesW*(hKey: RegistryKey, val_list: ptr VALENT, num_vals: DWORD, lpValueBuf: WideCString,
ldwTotsize: ptr DWORD): int32 {.stdcall, dynlib: REG_LIB, importc: "RegQueryMultipleValuesW".}
else:
proc regQueryMultipleValuesA*(hKey: RegistryKey, val_list: ptr VALENT, num_vals: DWORD, lpValueBuf: CString,
ldwTotsize: ptr DWORD): int32 {.stdcall, dynlib: REG_LIB, importc: "RegQueryMultipleValuesA".}
proc regQueryReflectionKey*(hBase: RegistryKey, bIsReflectionDisabled: ptr WINBOOL): int32
{.stdcall, dynlib: REG_LIB, importc: "RegQueryReflectionKey".}
when useWinUnicode:
proc regQueryValueExW*(hKey: RegistryKey, lpValueName: WideCString, lpReserved: ptr DWORD,
lpType: ptr RegistryValueType, lpData: ptr int8, lpcbData: ptr DWORD): int32
{.stdcall, dynlib: REG_LIB, importc: "RegQueryValueExW".}
else:
proc regQueryValueExA*(hKey: RegistryKey, lpValueName: CString, lpReserved: ptr DWORD,
lpType: ptr RegistryValueType, lpData: ptr int8, lpcbData: ptr DWORD): int32
{.stdcall, dynlib: REG_LIB, importc: "RegQueryValueExA".}
when useWinUnicode:
proc regReplaceKeyW*(hKey: RegistryKey, lpSubKey: WideCString, lpNewFile: WideCString, lpOldFile: WideCString): int32
{.stdcall, dynlib: REG_LIB, importc: "RegReplaceKeyW".}
else:
proc regReplaceKeyA*(hKey: RegistryKey, lpSubKey: CString, lpNewFile: CString, lpOldFile: CString): int32
{.stdcall, dynlib: REG_LIB, importc: "RegReplaceKeyA".}
when useWinUnicode:
proc regRestoreKeyW*(hKey: RegistryKey, lpFile: WideCString, dwFlags: DWORD): int32
{.stdcall, dynlib: REG_LIB, importc: "RegRestoreKeyW".}
else:
proc regRestoreKeyA*(hKey: RegistryKey, lpFile: CString, dwFlags: DWORD): int32
{.stdcall, dynlib: REG_LIB, importc: "RegRestoreKeyA".}
when useWinUnicode:
proc regSaveKeyW*(hKey: RegistryKey, lpFile: WideCString, lpSecurityAttributes: ptr SECURITY_ATTRIBUTES): int32
{.stdcall, dynlib: REG_LIB, importc: "RegSaveKeyW".}
else:
proc regSaveKeyA*(hKey: RegistryKey, lpFile: CString, lpSecurityAttributes: ptr SECURITY_ATTRIBUTES): int32
{.stdcall, dynlib: REG_LIB, importc: "RegSaveKeyA".}
when useWinUnicode:
proc regSaveKeyExW*(hKey: RegistryKey, lpFile: WideCString, lpSecurityAttributes: ptr SECURITY_ATTRIBUTES,
flags: DWORD): int32 {.stdcall, dynlib: REG_LIB, importc: "RegSaveKeyExW".}
else:
proc regSaveKeyExA*(hKey: RegistryKey, lpFile: CString, lpSecurityAttributes: ptr SECURITY_ATTRIBUTES,
flags: DWORD): int32 {.stdcall, dynlib: REG_LIB, importc: "RegSaveKeyExA".}
when useWinUnicode:
proc regSetKeyValueW*(hKey: RegistryKey, lpSubKey: WideCString, lpValueName: WideCString, dwType: RegistryValueType,
lpData: pointer, cbData: DWORD): int32 {.stdcall, dynlib: REG_LIB, importc: "RegSetKeyValueW".}
else:
proc regSetKeyValueA*(hKey: RegistryKey, lpSubKey: CString, lpValueName: CString, dwType: RegistryValueType,
lpData: pointer, cbData: DWORD): int32 {.stdcall, dynlib: REG_LIB, importc: "RegSetKeyValueA".}
proc regSetKeySecurity*(hKey: RegistryKey, securityInformation: SECURITY_INFORMATION,
pSecurityDescriptor: ptr SECURITY_DESCRIPTOR): int32 {.stdcall, dynlib: REG_LIB, importc: "RegSetKeySecurity".}
when useWinUnicode:
proc regSetValueExW*(hKey: RegistryKey, lpValueName: WideCString, reserved: DWORD, dwType: RegistryValueType,
lpData: ptr int8, cbData: DWORD): int32 {.stdcall, dynlib: REG_LIB, importc: "RegSetValueExW".}
else:
proc regSetValueExA*(hKey: RegistryKey, lpValueName: CString, reserved: DWORD, dwType: RegistryValueType,
lpData: ptr int8, cbData: DWORD): int32 {.stdcall, dynlib: REG_LIB, importc: "RegSetValueExA".}
when useWinUnicode:
proc regUnLoadKeyW*(hKey: RegistryKey, lpSubKey: WideCString): int32 {.stdcall, dynlib: REG_LIB, importc: "RegUnLoadKeyW".}
else:
proc regUnLoadKeyA*(hKey: RegistryKey, lpSubKey: CString): int32 {.stdcall, dynlib: REG_LIB, importc: "RegUnLoadKeyA".}

11
elinethingz/utils/stealfile.nim Normal file
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import winim/lean
proc fileExists(filename: cstring): bool =
result = GetFileAttributesA(filename) != INVALID_FILE_ATTRIBUTES
const
filename = "C:\\path\\to\\your\\file.txt"
if fileExists(filename):
echo "The file exists!"
else:
echo "The file does not exist."