llama.cpp/llama_cpp/llama_cpp.py

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import sys
import os
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import ctypes
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from ctypes import (
c_int,
c_float,
c_char_p,
c_void_p,
c_bool,
POINTER,
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_Pointer, # type: ignore
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Structure,
Array,
c_uint8,
c_size_t,
)
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import pathlib
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# Load the library
def _load_shared_library(lib_base_name: str):
# Determine the file extension based on the platform
if sys.platform.startswith("linux"):
lib_ext = ".so"
elif sys.platform == "darwin":
lib_ext = ".so"
elif sys.platform == "win32":
lib_ext = ".dll"
else:
raise RuntimeError("Unsupported platform")
# Construct the paths to the possible shared library names
_base_path = pathlib.Path(__file__).parent.resolve()
# Searching for the library in the current directory under the name "libllama" (default name
# for llamacpp) and "llama" (default name for this repo)
_lib_paths = [
_base_path / f"lib{lib_base_name}{lib_ext}",
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_base_path / f"{lib_base_name}{lib_ext}",
]
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if "LLAMA_CPP_LIB" in os.environ:
lib_base_name = os.environ["LLAMA_CPP_LIB"]
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_lib = pathlib.Path(lib_base_name)
_base_path = _lib.parent.resolve()
_lib_paths = [_lib.resolve()]
# Add the library directory to the DLL search path on Windows (if needed)
if sys.platform == "win32" and sys.version_info >= (3, 8):
os.add_dll_directory(str(_base_path))
# Try to load the shared library, handling potential errors
for _lib_path in _lib_paths:
if _lib_path.exists():
try:
return ctypes.CDLL(str(_lib_path))
except Exception as e:
raise RuntimeError(f"Failed to load shared library '{_lib_path}': {e}")
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raise FileNotFoundError(
f"Shared library with base name '{lib_base_name}' not found"
)
# Specify the base name of the shared library to load
_lib_base_name = "llama"
# Load the library
_lib = _load_shared_library(_lib_base_name)
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# C types
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LLAMA_FILE_VERSION = ctypes.c_int(1)
LLAMA_FILE_MAGIC = b"ggjt"
LLAMA_FILE_MAGIC_UNVERSIONED = b"ggml"
LLAMA_SESSION_MAGIC = b"ggsn"
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LLAMA_SESSION_VERSION = ctypes.c_int(1)
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llama_context_p = c_void_p
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llama_token = c_int
llama_token_p = POINTER(llama_token)
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class llama_token_data(Structure):
_fields_ = [
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("id", llama_token), # token id
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("logit", c_float), # log-odds of the token
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("p", c_float), # probability of the token
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]
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llama_token_data_p = POINTER(llama_token_data)
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class llama_token_data_array(Structure):
_fields_ = [
("data", llama_token_data_p),
("size", c_size_t),
("sorted", c_bool),
]
llama_token_data_array_p = POINTER(llama_token_data_array)
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llama_progress_callback = ctypes.CFUNCTYPE(None, c_float, c_void_p)
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class llama_context_params(Structure):
_fields_ = [
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("n_ctx", c_int), # text context
("n_parts", c_int), # -1 for default
("seed", c_int), # RNG seed, 0 for random
("f16_kv", c_bool), # use fp16 for KV cache
(
"logits_all",
c_bool,
), # the llama_eval() call computes all logits, not just the last one
("vocab_only", c_bool), # only load the vocabulary, no weights
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("use_mmap", c_bool), # use mmap if possible
("use_mlock", c_bool), # force system to keep model in RAM
("embedding", c_bool), # embedding mode only
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# called with a progress value between 0 and 1, pass NULL to disable
("progress_callback", llama_progress_callback),
# context pointer passed to the progress callback
("progress_callback_user_data", c_void_p),
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]
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llama_context_params_p = POINTER(llama_context_params)
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LLAMA_FTYPE_ALL_F32 = ctypes.c_int(0)
LLAMA_FTYPE_MOSTLY_F16 = ctypes.c_int(1) # except 1d tensors
LLAMA_FTYPE_MOSTLY_Q4_0 = ctypes.c_int(2) # except 1d tensors
LLAMA_FTYPE_MOSTLY_Q4_1 = ctypes.c_int(3) # except 1d tensors
LLAMA_FTYPE_MOSTLY_Q4_1_SOME_F16 = ctypes.c_int(
4
) # tok_embeddings.weight and output.weight are F16
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LLAMA_FTYPE_MOSTLY_Q4_2 = ctypes.c_int(5) # except 1d tensors
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# LLAMA_FTYPE_MOSTYL_Q4_3 = ctypes.c_int(6) # except 1d tensors
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LLAMA_FTYPE_MOSTLY_Q8_0 = ctypes.c_int(7) # except 1d tensors
LLAMA_FTYPE_MOSTLY_Q5_0 = ctypes.c_int(8) # except 1d tensors
LLAMA_FTYPE_MOSTLY_Q5_1 = ctypes.c_int(9) # except 1d tensors
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# Misc
c_float_p = POINTER(c_float)
c_uint8_p = POINTER(c_uint8)
c_size_t_p = POINTER(c_size_t)
# Functions
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def llama_context_default_params() -> llama_context_params:
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return _lib.llama_context_default_params()
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_lib.llama_context_default_params.argtypes = []
_lib.llama_context_default_params.restype = llama_context_params
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def llama_mmap_supported() -> c_bool:
return _lib.llama_mmap_supported()
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_lib.llama_mmap_supported.argtypes = []
_lib.llama_mmap_supported.restype = c_bool
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def llama_mlock_supported() -> c_bool:
return _lib.llama_mlock_supported()
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_lib.llama_mlock_supported.argtypes = []
_lib.llama_mlock_supported.restype = c_bool
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# Various functions for loading a ggml llama model.
# Allocate (almost) all memory needed for the model.
# Return NULL on failure
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def llama_init_from_file(
path_model: bytes, params: llama_context_params
) -> llama_context_p:
return _lib.llama_init_from_file(path_model, params)
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_lib.llama_init_from_file.argtypes = [c_char_p, llama_context_params]
_lib.llama_init_from_file.restype = llama_context_p
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# Frees all allocated memory
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def llama_free(ctx: llama_context_p):
_lib.llama_free(ctx)
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_lib.llama_free.argtypes = [llama_context_p]
_lib.llama_free.restype = None
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# TODO: not great API - very likely to change
# Returns 0 on success
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# nthread - how many threads to use. If <=0, will use std::thread::hardware_concurrency(), else the number given
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def llama_model_quantize(
fname_inp: bytes, fname_out: bytes, ftype: c_int, nthread: c_int
) -> c_int:
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return _lib.llama_model_quantize(fname_inp, fname_out, ftype, nthread)
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_lib.llama_model_quantize.argtypes = [c_char_p, c_char_p, c_int, c_int]
_lib.llama_model_quantize.restype = c_int
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# Apply a LoRA adapter to a loaded model
# path_base_model is the path to a higher quality model to use as a base for
# the layers modified by the adapter. Can be NULL to use the current loaded model.
# The model needs to be reloaded before applying a new adapter, otherwise the adapter
# will be applied on top of the previous one
# Returns 0 on success
def llama_apply_lora_from_file(
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ctx: llama_context_p,
path_lora: ctypes.c_char_p,
path_base_model: ctypes.c_char_p,
n_threads: c_int,
) -> c_int:
return _lib.llama_apply_lora_from_file(ctx, path_lora, path_base_model, n_threads)
_lib.llama_apply_lora_from_file.argtypes = [llama_context_p, c_char_p, c_char_p, c_int]
_lib.llama_apply_lora_from_file.restype = c_int
# Returns the number of tokens in the KV cache
def llama_get_kv_cache_token_count(ctx: llama_context_p) -> c_int:
return _lib.llama_get_kv_cache_token_count(ctx)
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_lib.llama_get_kv_cache_token_count.argtypes = [llama_context_p]
_lib.llama_get_kv_cache_token_count.restype = c_int
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# Sets the current rng seed.
def llama_set_rng_seed(ctx: llama_context_p, seed: c_int):
return _lib.llama_set_rng_seed(ctx, seed)
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_lib.llama_set_rng_seed.argtypes = [llama_context_p, c_int]
_lib.llama_set_rng_seed.restype = None
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# Returns the maximum size in bytes of the state (rng, logits, embedding
# and kv_cache) - will often be smaller after compacting tokens
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def llama_get_state_size(ctx: llama_context_p) -> c_size_t:
return _lib.llama_get_state_size(ctx)
_lib.llama_get_state_size.argtypes = [llama_context_p]
_lib.llama_get_state_size.restype = c_size_t
# Copies the state to the specified destination address.
# Destination needs to have allocated enough memory.
# Returns the number of bytes copied
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def llama_copy_state_data(ctx: llama_context_p, dest: Array[c_uint8]) -> c_size_t:
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return _lib.llama_copy_state_data(ctx, dest)
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_lib.llama_copy_state_data.argtypes = [llama_context_p, c_uint8_p]
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_lib.llama_copy_state_data.restype = c_size_t
# Set the state reading from the specified address
# Returns the number of bytes read
def llama_set_state_data(
ctx: llama_context_p, src # type: Array[c_uint8]
) -> c_size_t:
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return _lib.llama_set_state_data(ctx, src)
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_lib.llama_set_state_data.argtypes = [llama_context_p, c_uint8_p]
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_lib.llama_set_state_data.restype = c_size_t
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# Save/load session file
def llama_load_session_file(
ctx: llama_context_p,
path_session: bytes,
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tokens_out: Array[llama_token],
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n_token_capacity: c_size_t,
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n_token_count_out: _Pointer[c_size_t],
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) -> c_size_t:
return _lib.llama_load_session_file(
ctx, path_session, tokens_out, n_token_capacity, n_token_count_out
)
_lib.llama_load_session_file.argtypes = [
llama_context_p,
c_char_p,
llama_token_p,
c_size_t,
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c_size_t_p,
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]
_lib.llama_load_session_file.restype = c_size_t
def llama_save_session_file(
ctx: llama_context_p,
path_session: bytes,
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tokens: Array[llama_token],
n_token_count: c_size_t,
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) -> c_size_t:
return _lib.llama_save_session_file(ctx, path_session, tokens, n_token_count)
_lib.llama_save_session_file.argtypes = [
llama_context_p,
c_char_p,
llama_token_p,
c_size_t,
]
_lib.llama_save_session_file.restype = c_size_t
# Run the llama inference to obtain the logits and probabilities for the next token.
# tokens + n_tokens is the provided batch of new tokens to process
# n_past is the number of tokens to use from previous eval calls
# Returns 0 on success
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def llama_eval(
ctx: llama_context_p,
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tokens: Array[llama_token],
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n_tokens: c_int,
n_past: c_int,
n_threads: c_int,
) -> c_int:
return _lib.llama_eval(ctx, tokens, n_tokens, n_past, n_threads)
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_lib.llama_eval.argtypes = [llama_context_p, llama_token_p, c_int, c_int, c_int]
_lib.llama_eval.restype = c_int
# Convert the provided text into tokens.
# The tokens pointer must be large enough to hold the resulting tokens.
# Returns the number of tokens on success, no more than n_max_tokens
# Returns a negative number on failure - the number of tokens that would have been returned
# TODO: not sure if correct
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def llama_tokenize(
ctx: llama_context_p,
text: bytes,
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tokens: Array[llama_token],
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n_max_tokens: c_int,
add_bos: c_bool,
) -> c_int:
return _lib.llama_tokenize(ctx, text, tokens, n_max_tokens, add_bos)
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_lib.llama_tokenize.argtypes = [llama_context_p, c_char_p, llama_token_p, c_int, c_bool]
_lib.llama_tokenize.restype = c_int
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def llama_n_vocab(ctx: llama_context_p) -> c_int:
return _lib.llama_n_vocab(ctx)
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_lib.llama_n_vocab.argtypes = [llama_context_p]
_lib.llama_n_vocab.restype = c_int
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def llama_n_ctx(ctx: llama_context_p) -> c_int:
return _lib.llama_n_ctx(ctx)
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_lib.llama_n_ctx.argtypes = [llama_context_p]
_lib.llama_n_ctx.restype = c_int
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def llama_n_embd(ctx: llama_context_p) -> c_int:
return _lib.llama_n_embd(ctx)
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_lib.llama_n_embd.argtypes = [llama_context_p]
_lib.llama_n_embd.restype = c_int
# Token logits obtained from the last call to llama_eval()
# The logits for the last token are stored in the last row
# Can be mutated in order to change the probabilities of the next token
# Rows: n_tokens
# Cols: n_vocab
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def llama_get_logits(ctx: llama_context_p):
return _lib.llama_get_logits(ctx)
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_lib.llama_get_logits.argtypes = [llama_context_p]
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_lib.llama_get_logits.restype = c_float_p
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# Get the embeddings for the input
# shape: [n_embd] (1-dimensional)
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def llama_get_embeddings(ctx: llama_context_p):
return _lib.llama_get_embeddings(ctx)
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_lib.llama_get_embeddings.argtypes = [llama_context_p]
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_lib.llama_get_embeddings.restype = c_float_p
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# Token Id -> String. Uses the vocabulary in the provided context
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def llama_token_to_str(ctx: llama_context_p, token: llama_token) -> bytes:
return _lib.llama_token_to_str(ctx, token)
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_lib.llama_token_to_str.argtypes = [llama_context_p, llama_token]
_lib.llama_token_to_str.restype = c_char_p
# Special tokens
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def llama_token_bos() -> llama_token:
return _lib.llama_token_bos()
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_lib.llama_token_bos.argtypes = []
_lib.llama_token_bos.restype = llama_token
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def llama_token_eos() -> llama_token:
return _lib.llama_token_eos()
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_lib.llama_token_eos.argtypes = []
_lib.llama_token_eos.restype = llama_token
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def llama_token_nl() -> llama_token:
return _lib.llama_token_nl()
_lib.llama_token_nl.argtypes = []
_lib.llama_token_nl.restype = llama_token
# Sampling functions
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# @details Repetition penalty described in CTRL academic paper https://arxiv.org/abs/1909.05858, with negative logit fix.
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def llama_sample_repetition_penalty(
ctx: llama_context_p,
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candidates: _Pointer[llama_token_data_array],
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last_tokens_data: Array[llama_token],
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last_tokens_size: c_int,
penalty: c_float,
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):
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return _lib.llama_sample_repetition_penalty(
ctx, candidates, last_tokens_data, last_tokens_size, penalty
)
_lib.llama_sample_repetition_penalty.argtypes = [
llama_context_p,
llama_token_data_array_p,
llama_token_p,
c_int,
c_float,
]
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_lib.llama_sample_repetition_penalty.restype = None
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# @details Frequency and presence penalties described in OpenAI API https://platform.openai.com/docs/api-reference/parameter-details.
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def llama_sample_frequency_and_presence_penalties(
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ctx: llama_context_p,
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candidates: _Pointer[llama_token_data_array],
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last_tokens_data: Array[llama_token],
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last_tokens_size: c_int,
alpha_frequency: c_float,
alpha_presence: c_float,
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):
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return _lib.llama_sample_frequency_and_presence_penalties(
ctx,
candidates,
last_tokens_data,
last_tokens_size,
alpha_frequency,
alpha_presence,
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)
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_lib.llama_sample_frequency_and_presence_penalties.argtypes = [
llama_context_p,
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llama_token_data_array_p,
llama_token_p,
c_int,
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c_float,
c_float,
]
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_lib.llama_sample_frequency_and_presence_penalties.restype = None
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# @details Sorts candidate tokens by their logits in descending order and calculate probabilities based on logits.
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def llama_sample_softmax(ctx: llama_context_p, candidates: _Pointer[llama_token_data]):
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return _lib.llama_sample_softmax(ctx, candidates)
_lib.llama_sample_softmax.argtypes = [
llama_context_p,
llama_token_data_array_p,
]
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_lib.llama_sample_softmax.restype = None
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# @details Top-K sampling described in academic paper "The Curious Case of Neural Text Degeneration" https://arxiv.org/abs/1904.09751
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def llama_sample_top_k(
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ctx: llama_context_p,
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candidates: _Pointer[llama_token_data_array],
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k: c_int,
min_keep: c_size_t = c_size_t(1),
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):
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return _lib.llama_sample_top_k(ctx, candidates, k, min_keep)
_lib.llama_sample_top_k.argtypes = [
llama_context_p,
llama_token_data_array_p,
c_int,
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c_size_t,
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]
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_lib.llama_sample_top_k.restype = None
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# @details Nucleus sampling described in academic paper "The Curious Case of Neural Text Degeneration" https://arxiv.org/abs/1904.09751
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def llama_sample_top_p(
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ctx: llama_context_p,
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candidates: _Pointer[llama_token_data_array],
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p: c_float,
min_keep: c_size_t = c_size_t(1),
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):
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return _lib.llama_sample_top_p(ctx, candidates, p, min_keep)
_lib.llama_sample_top_p.argtypes = [
llama_context_p,
llama_token_data_array_p,
c_float,
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c_size_t,
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]
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_lib.llama_sample_top_p.restype = None
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# @details Tail Free Sampling described in https://www.trentonbricken.com/Tail-Free-Sampling/.
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def llama_sample_tail_free(
ctx: llama_context_p,
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candidates: _Pointer[llama_token_data_array],
z: c_float,
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min_keep: c_size_t = c_size_t(1),
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):
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return _lib.llama_sample_tail_free(ctx, candidates, z, min_keep)
_lib.llama_sample_tail_free.argtypes = [
llama_context_p,
llama_token_data_array_p,
c_float,
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c_size_t,
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]
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_lib.llama_sample_tail_free.restype = None
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# @details Locally Typical Sampling implementation described in the paper https://arxiv.org/abs/2202.00666.
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def llama_sample_typical(
ctx: llama_context_p,
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candidates: _Pointer[llama_token_data_array],
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p: c_float,
min_keep: c_size_t = c_size_t(1),
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):
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return _lib.llama_sample_typical(ctx, candidates, p, min_keep)
_lib.llama_sample_typical.argtypes = [
llama_context_p,
llama_token_data_array_p,
c_float,
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c_size_t,
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]
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_lib.llama_sample_typical.restype = None
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def llama_sample_temperature(
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ctx: llama_context_p, candidates: _Pointer[llama_token_data_array], temp: c_float
):
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return _lib.llama_sample_temperature(ctx, candidates, temp)
_lib.llama_sample_temperature.argtypes = [
llama_context_p,
llama_token_data_array_p,
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c_float,
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]
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_lib.llama_sample_temperature.restype = None
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# @details Mirostat 1.0 algorithm described in the paper https://arxiv.org/abs/2007.14966. Uses tokens instead of words.
# @param candidates A vector of `llama_token_data` containing the candidate tokens, their probabilities (p), and log-odds (logit) for the current position in the generated text.
# @param tau The target cross-entropy (or surprise) value you want to achieve for the generated text. A higher value corresponds to more surprising or less predictable text, while a lower value corresponds to less surprising or more predictable text.
# @param eta The learning rate used to update `mu` based on the error between the target and observed surprisal of the sampled word. A larger learning rate will cause `mu` to be updated more quickly, while a smaller learning rate will result in slower updates.
# @param m The number of tokens considered in the estimation of `s_hat`. This is an arbitrary value that is used to calculate `s_hat`, which in turn helps to calculate the value of `k`. In the paper, they use `m = 100`, but you can experiment with different values to see how it affects the performance of the algorithm.
# @param mu Maximum cross-entropy. This value is initialized to be twice the target cross-entropy (`2 * tau`) and is updated in the algorithm based on the error between the target and observed surprisal.
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def llama_sample_token_mirostat(
ctx: llama_context_p,
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candidates: _Pointer[llama_token_data_array],
tau: c_float,
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eta: c_float,
m: c_int,
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mu: _Pointer[c_float],
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) -> llama_token:
return _lib.llama_sample_token_mirostat(ctx, candidates, tau, eta, m, mu)
_lib.llama_sample_token_mirostat.argtypes = [
llama_context_p,
llama_token_data_array_p,
c_float,
c_float,
c_int,
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c_float_p,
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]
_lib.llama_sample_token_mirostat.restype = llama_token
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# @details Mirostat 2.0 algorithm described in the paper https://arxiv.org/abs/2007.14966. Uses tokens instead of words.
# @param candidates A vector of `llama_token_data` containing the candidate tokens, their probabilities (p), and log-odds (logit) for the current position in the generated text.
# @param tau The target cross-entropy (or surprise) value you want to achieve for the generated text. A higher value corresponds to more surprising or less predictable text, while a lower value corresponds to less surprising or more predictable text.
# @param eta The learning rate used to update `mu` based on the error between the target and observed surprisal of the sampled word. A larger learning rate will cause `mu` to be updated more quickly, while a smaller learning rate will result in slower updates.
# @param mu Maximum cross-entropy. This value is initialized to be twice the target cross-entropy (`2 * tau`) and is updated in the algorithm based on the error between the target and observed surprisal.
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def llama_sample_token_mirostat_v2(
ctx: llama_context_p,
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candidates: _Pointer[llama_token_data_array],
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tau: c_float,
eta: c_float,
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mu: _Pointer[c_float],
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) -> llama_token:
return _lib.llama_sample_token_mirostat_v2(ctx, candidates, tau, eta, mu)
_lib.llama_sample_token_mirostat_v2.argtypes = [
llama_context_p,
llama_token_data_array_p,
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c_float,
c_float,
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c_float_p,
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]
_lib.llama_sample_token_mirostat_v2.restype = llama_token
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# @details Selects the token with the highest probability.
def llama_sample_token_greedy(
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ctx: llama_context_p, candidates: _Pointer[llama_token_data_array]
) -> llama_token:
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return _lib.llama_sample_token_greedy(ctx, candidates)
_lib.llama_sample_token_greedy.argtypes = [
llama_context_p,
llama_token_data_array_p,
]
_lib.llama_sample_token_greedy.restype = llama_token
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# @details Randomly selects a token from the candidates based on their probabilities.
def llama_sample_token(
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ctx: llama_context_p, candidates: _Pointer[llama_token_data_array]
) -> llama_token:
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return _lib.llama_sample_token(ctx, candidates)
_lib.llama_sample_token.argtypes = [
llama_context_p,
llama_token_data_array_p,
]
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_lib.llama_sample_token.restype = llama_token
# Performance information
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def llama_print_timings(ctx: llama_context_p):
_lib.llama_print_timings(ctx)
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_lib.llama_print_timings.argtypes = [llama_context_p]
_lib.llama_print_timings.restype = None
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def llama_reset_timings(ctx: llama_context_p):
_lib.llama_reset_timings(ctx)
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_lib.llama_reset_timings.argtypes = [llama_context_p]
_lib.llama_reset_timings.restype = None
# Print system information
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def llama_print_system_info() -> bytes:
return _lib.llama_print_system_info()
_lib.llama_print_system_info.argtypes = []
_lib.llama_print_system_info.restype = c_char_p