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# include "common.h"
# include "llama.h"
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# include <cmath>
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# include <cstdio>
# include <cstring>
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# include <ctime>
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# include <sstream>
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# include <thread>
# include <mutex>
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# include <atomic>
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# include <vector>
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# include <array>
# include <fstream>
# include <sstream>
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# if defined(_MSC_VER)
# pragma warning(disable: 4244 4267) // possible loss of data
# endif
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struct results_perplexity {
std : : vector < llama_token > tokens ;
double ppl_value ;
std : : vector < float > logits ;
std : : vector < float > probs ;
} ;
struct results_log_softmax {
double log_softmax ;
float logit ;
float prob ;
} ;
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static void write_logfile (
const llama_context * ctx , const gpt_params & params , const llama_model * model ,
const struct results_perplexity & results
) {
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if ( params . logdir . empty ( ) ) {
return ;
}
if ( params . hellaswag ) {
fprintf ( stderr , " %s: warning: logging results is not implemented for HellaSwag. No files will be written. \n " , __func__ ) ;
return ;
}
const std : : string timestamp = get_sortable_timestamp ( ) ;
const bool success = create_directory_with_parents ( params . logdir ) ;
if ( ! success ) {
fprintf ( stderr , " %s: warning: failed to create logdir %s, cannot write logfile \n " ,
__func__ , params . logdir . c_str ( ) ) ;
return ;
}
const std : : string logfile_path = params . logdir + timestamp + " .yml " ;
FILE * logfile = fopen ( logfile_path . c_str ( ) , " w " ) ;
if ( logfile = = NULL ) {
fprintf ( stderr , " %s: failed to open logfile %s \n " , __func__ , logfile_path . c_str ( ) ) ;
return ;
}
fprintf ( logfile , " binary: main \n " ) ;
char model_desc [ 128 ] ;
llama_model_desc ( model , model_desc , sizeof ( model_desc ) ) ;
dump_non_result_info_yaml ( logfile , params , ctx , timestamp , results . tokens , model_desc ) ;
fprintf ( logfile , " \n " ) ;
fprintf ( logfile , " ###################### \n " ) ;
fprintf ( logfile , " # Perplexity Results # \n " ) ;
fprintf ( logfile , " ###################### \n " ) ;
fprintf ( logfile , " \n " ) ;
dump_vector_float_yaml ( logfile , " logits " , results . logits ) ;
fprintf ( logfile , " ppl_value: %f \n " , results . ppl_value ) ;
dump_vector_float_yaml ( logfile , " probs " , results . probs ) ;
llama_dump_timing_info_yaml ( logfile , ctx ) ;
fclose ( logfile ) ;
}
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static std : : vector < float > softmax ( const std : : vector < float > & logits ) {
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std : : vector < float > probs ( logits . size ( ) ) ;
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float max_logit = logits [ 0 ] ;
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for ( float v : logits ) {
max_logit = std : : max ( max_logit , v ) ;
}
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double sum_exp = 0.0 ;
for ( size_t i = 0 ; i < logits . size ( ) ; i + + ) {
// Subtract the maximum logit value from the current logit value for numerical stability
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const float logit = logits [ i ] - max_logit ;
const float exp_logit = expf ( logit ) ;
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sum_exp + = exp_logit ;
probs [ i ] = exp_logit ;
}
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for ( size_t i = 0 ; i < probs . size ( ) ; i + + ) {
probs [ i ] / = sum_exp ;
}
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return probs ;
}
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static results_log_softmax log_softmax ( int n_vocab , const float * logits , int tok ) {
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float max_logit = logits [ 0 ] ;
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for ( int i = 1 ; i < n_vocab ; + + i ) {
max_logit = std : : max ( max_logit , logits [ i ] ) ;
}
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double sum_exp = 0.0 ;
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for ( int i = 0 ; i < n_vocab ; + + i ) {
sum_exp + = expf ( logits [ i ] - max_logit ) ;
}
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return { logits [ tok ] - max_logit - log ( sum_exp ) , logits [ tok ] , expf ( logits [ tok ] - max_logit ) / ( float ) sum_exp } ;
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}
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static inline int nearest_int ( float fval ) {
//assert(fval <= 4194303.f);
float val = fval + 12582912.f ;
int i ; memcpy ( & i , & val , sizeof ( int ) ) ;
return ( i & 0x007fffff ) - 0x00400000 ;
}
static double log_softmax ( int n_vocab , const float * logits , uint16_t * log_prob , int tok ) {
float max_logit = logits [ 0 ] ;
float min_logit = logits [ 0 ] ;
for ( int i = 1 ; i < n_vocab ; + + i ) {
max_logit = std : : max ( max_logit , logits [ i ] ) ;
min_logit = std : : min ( min_logit , logits [ i ] ) ;
}
min_logit = std : : max ( min_logit , max_logit - 16 ) ;
double sum_exp = 0.0 ;
for ( int i = 0 ; i < n_vocab ; + + i ) {
sum_exp + = expf ( logits [ i ] - max_logit ) ;
}
const float log_sum_exp = log ( sum_exp ) ;
const float min_log_prob = min_logit - max_logit - log_sum_exp ;
const float scale = ( max_logit - min_logit ) / 65535.f ;
float * d = ( float * ) log_prob ;
d [ 0 ] = scale ;
d [ 1 ] = min_log_prob ;
log_prob + = 4 ;
if ( scale ) {
const float inv_scale = 1 / scale ;
for ( int i = 0 ; i < n_vocab ; + + i ) {
log_prob [ i ] = logits [ i ] > min_logit ? nearest_int ( inv_scale * ( logits [ i ] - min_logit ) ) : 0 ;
}
} else {
std : : memset ( log_prob , 0 , n_vocab * sizeof ( uint16_t ) ) ;
}
return max_logit + log_sum_exp - logits [ tok ] ;
}
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static void process_logits (
int n_vocab , const float * logits , const int * tokens , int n_token , std : : vector < std : : thread > & workers ,
double & nll , double & nll2 , float * logit_history , float * prob_history
) {
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std : : mutex mutex ;
int counter = 0 ;
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auto compute = [ & mutex , & counter , & nll , & nll2 , logit_history , prob_history , n_vocab , logits , tokens , n_token ] ( ) {
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double local_nll = 0 ;
double local_nll2 = 0 ;
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while ( true ) {
std : : unique_lock < std : : mutex > lock ( mutex ) ;
int i = counter + + ;
if ( i > = n_token ) {
nll + = local_nll ; nll2 + = local_nll2 ;
break ;
}
lock . unlock ( ) ;
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const results_log_softmax results = log_softmax ( n_vocab , logits + i * n_vocab , tokens [ i + 1 ] ) ;
const double v = - results . log_softmax ;
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local_nll + = v ;
local_nll2 + = v * v ;
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logit_history [ i ] = results . logit ;
prob_history [ i ] = results . prob ;
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}
} ;
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for ( auto & w : workers ) {
w = std : : thread ( compute ) ;
}
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compute ( ) ;
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for ( auto & w : workers ) {
w . join ( ) ;
}
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}
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static void process_logits ( std : : ostream & out , int n_vocab , const float * logits , const int * tokens , int n_token ,
std : : vector < std : : thread > & workers , std : : vector < uint16_t > & log_probs , double & nll , double & nll2 ) {
std : : mutex mutex ;
const int nv = 2 * ( ( n_vocab + 1 ) / 2 ) + 4 ;
int counter = 0 ;
auto compute = [ & mutex , & counter , & log_probs , & nll , & nll2 , n_vocab , logits , tokens , n_token , nv ] ( ) {
double local_nll = 0 ;
double local_nll2 = 0 ;
while ( true ) {
std : : unique_lock < std : : mutex > lock ( mutex ) ;
int i = counter + + ;
if ( i > = n_token ) {
nll + = local_nll ; nll2 + = local_nll2 ;
break ;
}
lock . unlock ( ) ;
const double v = log_softmax ( n_vocab , logits + i * n_vocab , log_probs . data ( ) + i * nv , tokens [ i + 1 ] ) ;
local_nll + = v ;
local_nll2 + = v * v ;
}
} ;
for ( auto & w : workers ) {
w = std : : thread ( compute ) ;
}
compute ( ) ;
for ( auto & w : workers ) {
w . join ( ) ;
}
out . write ( ( const char * ) log_probs . data ( ) , n_token * nv * sizeof ( uint16_t ) ) ;
}
struct kl_divergence_result {
double sum_nll = 0 ;
double sum_nll2 = 0 ;
double sum_kld = 0 ;
double sum_kld2 = 0 ;
double sum_nll_diff = 0 ;
double sum_nll_diff2 = 0 ;
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size_t n_same_top = 0 ;
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size_t count = 0 ;
} ;
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static double log_softmax ( int n_vocab , const float * logits , const uint16_t * base_log_prob , int tok , kl_divergence_result & kld ) {
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float max_logit = logits [ 0 ] ;
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int imax = 0 ;
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for ( int i = 1 ; i < n_vocab ; + + i ) {
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if ( logits [ i ] > max_logit ) {
max_logit = logits [ i ] ;
imax = i ;
}
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}
double sum_exp = 0.0 ;
for ( int i = 0 ; i < n_vocab ; + + i ) {
sum_exp + = expf ( logits [ i ] - max_logit ) ;
}
const float log_sum_exp = log ( sum_exp ) ;
const float * d = ( const float * ) base_log_prob ;
const float scale = d [ 0 ] ;
const float min_log_prob = d [ 1 ] ;
base_log_prob + = 4 ;
float nll = max_logit + log_sum_exp - logits [ tok ] ;
kld . sum_nll + = nll ;
kld . sum_nll2 + = nll * nll ;
nll + = ( scale * base_log_prob [ tok ] + min_log_prob ) ;
kld . sum_nll_diff + = nll ;
kld . sum_nll_diff2 + = nll * nll ;
max_logit + = log_sum_exp ;
double sum = 0 ;
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int imax_base = - 1 ;
float p_log_base_max = 0 ;
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for ( int i = 0 ; i < n_vocab ; + + i ) {
const float p_log_base = scale * base_log_prob [ i ] + min_log_prob ;
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if ( i = = 0 | | p_log_base > p_log_base_max ) {
p_log_base_max = p_log_base ;
imax_base = i ;
}
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if ( p_log_base > - 16.f ) {
const float p_base = expf ( p_log_base ) ;
sum + = p_base * ( p_log_base - logits [ i ] + max_logit ) ;
}
}
kld . sum_kld + = sum ;
kld . sum_kld2 + = sum * sum ;
+ + kld . count ;
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if ( imax = = imax_base ) + + kld . n_same_top ;
return sum ;
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}
static void process_logits ( int n_vocab , const float * logits , const int * tokens , int n_token ,
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std : : vector < std : : thread > & workers , const std : : vector < uint16_t > & base_log_probs , kl_divergence_result & kld ,
float * kld_values ) {
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std : : mutex mutex ;
const int nv = 2 * ( ( n_vocab + 1 ) / 2 ) + 4 ;
int counter = 0 ;
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auto compute = [ & mutex , & counter , & base_log_probs , & kld , n_vocab , logits , tokens , n_token , nv , kld_values ] ( ) {
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kl_divergence_result local_kld ;
while ( true ) {
std : : unique_lock < std : : mutex > lock ( mutex ) ;
int i = counter + + ;
if ( i > = n_token ) {
kld . sum_nll + = local_kld . sum_nll ;
kld . sum_nll2 + = local_kld . sum_nll2 ;
kld . sum_kld + = local_kld . sum_kld ;
kld . sum_kld2 + = local_kld . sum_kld2 ;
kld . sum_nll_diff + = local_kld . sum_nll_diff ;
kld . sum_nll_diff2 + = local_kld . sum_nll_diff2 ;
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kld . n_same_top + = local_kld . n_same_top ;
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kld . count + = local_kld . count ;
break ;
}
lock . unlock ( ) ;
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double v = log_softmax ( n_vocab , logits + i * n_vocab , base_log_probs . data ( ) + i * nv , tokens [ i + 1 ] , local_kld ) ;
kld_values [ i ] = ( float ) v ;
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}
} ;
for ( auto & w : workers ) {
w = std : : thread ( compute ) ;
}
compute ( ) ;
for ( auto & w : workers ) {
w . join ( ) ;
}
}
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static results_perplexity perplexity_v2 ( llama_context * ctx , const gpt_params & params ) {
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// Download: https://s3.amazonaws.com/research.metamind.io/wikitext/wikitext-2-raw-v1.zip?ref=salesforce-research
// Run `./perplexity -m models/7B/ggml-model-q4_0.bin -f wiki.test.raw`
// Output: `perplexity: 13.5106 [114/114]`
// BOS tokens will be added for each chunk before eval
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const bool add_bos = llama_should_add_bos_token ( llama_get_model ( ctx ) ) ;
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fprintf ( stderr , " %s: tokenizing the input .. \n " , __func__ ) ;
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std : : vector < llama_token > tokens = : : llama_tokenize ( ctx , params . prompt , add_bos ) ;
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const int n_ctx = llama_n_ctx ( ctx ) ;
if ( int ( tokens . size ( ) ) < 2 * n_ctx ) {
fprintf ( stderr , " %s: you need at least %d tokens to evaluate perplexity with a context of %d \n " , __func__ , 2 * n_ctx ,
n_ctx ) ;
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fprintf ( stderr , " %s: the data file you provided tokenizes to only %zu tokens \n " , __func__ , tokens . size ( ) ) ;
return { std : : move ( tokens ) , 0. , { } , { } } ;
}
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std : : vector < float > logit_history ;
std : : vector < float > prob_history ;
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logit_history . resize ( tokens . size ( ) ) ;
prob_history . resize ( tokens . size ( ) ) ;
if ( params . ppl_stride < = 0 ) {
fprintf ( stderr , " %s: stride is %d but must be greater than zero! \n " , __func__ , params . ppl_stride ) ;
return { tokens , - 1 , logit_history , prob_history } ;
}
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const int calc_chunk = n_ctx ;
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fprintf ( stderr , " %s: have %zu tokens. Calculation chunk = %d \n " , __func__ , tokens . size ( ) , calc_chunk ) ;
if ( int ( tokens . size ( ) ) < = calc_chunk ) {
fprintf ( stderr , " %s: there are only %zu tokens, this is not enough for a context size of %d and stride %d \n " , __func__ ,
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tokens . size ( ) , n_ctx , params . ppl_stride ) ;
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return { tokens , - 1 , logit_history , prob_history } ;
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}
const int n_chunk_max = ( tokens . size ( ) - calc_chunk + params . ppl_stride - 1 ) / params . ppl_stride ;
const int n_chunk = params . n_chunks < 0 ? n_chunk_max : std : : min ( params . n_chunks , n_chunk_max ) ;
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const int n_vocab = llama_n_vocab ( llama_get_model ( ctx ) ) ;
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const int n_batch = params . n_batch ;
int count = 0 ;
double nll = 0.0 ;
fprintf ( stderr , " %s: calculating perplexity over %d chunks, batch_size=%d \n " , __func__ , n_chunk , n_batch ) ;
for ( int i = 0 ; i < n_chunk ; + + i ) {
const int start = i * params . ppl_stride ;
const int end = start + calc_chunk ;
const int num_batches = ( calc_chunk + n_batch - 1 ) / n_batch ;
//fprintf(stderr, "%s: evaluating %d...%d using %d batches\n", __func__, start, end, num_batches);
std : : vector < float > logits ;
const auto t_start = std : : chrono : : high_resolution_clock : : now ( ) ;
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// clear the KV cache
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llama_kv_cache_clear ( ctx ) ;
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for ( int j = 0 ; j < num_batches ; + + j ) {
const int batch_start = start + j * n_batch ;
const int batch_size = std : : min ( end - batch_start , n_batch ) ;
//fprintf(stderr, " Batch %d: starts at %d, size is %d, n_past is %d\n",j,batch_start,batch_size,j * n_batch);
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if ( llama_decode ( ctx , llama_batch_get_one ( tokens . data ( ) + batch_start , batch_size , j * n_batch , 0 ) ) ) {
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//fprintf(stderr, "%s : failed to eval\n", __func__);
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return { tokens , - 1 , logit_history , prob_history } ;
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}
// save original token and restore it after eval
const auto token_org = tokens [ batch_start ] ;
// add BOS token for the first batch of each chunk
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if ( add_bos & & j = = 0 ) {
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tokens [ batch_start ] = llama_token_bos ( llama_get_model ( ctx ) ) ;
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}
const auto batch_logits = llama_get_logits ( ctx ) ;
logits . insert ( logits . end ( ) , batch_logits , batch_logits + batch_size * n_vocab ) ;
if ( j = = 0 ) {
tokens [ batch_start ] = token_org ;
}
}
const auto t_end = std : : chrono : : high_resolution_clock : : now ( ) ;
if ( i = = 0 ) {
const float t_total = std : : chrono : : duration < float > ( t_end - t_start ) . count ( ) ;
fprintf ( stderr , " %s: %.2f seconds per pass - ETA " , __func__ , t_total ) ;
int total_seconds = ( int ) ( t_total * n_chunk ) ;
if ( total_seconds > = 60 * 60 ) {
fprintf ( stderr , " %d hours " , total_seconds / ( 60 * 60 ) ) ;
total_seconds = total_seconds % ( 60 * 60 ) ;
}
fprintf ( stderr , " %.2f minutes \n " , total_seconds / 60.0 ) ;
}
//fprintf(stderr, "%s: using tokens %d...%d\n",__func__,params.n_ctx - params.ppl_stride + start, params.n_ctx + start);
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for ( int j = n_ctx - params . ppl_stride - 1 ; j < n_ctx - 1 ; + + j ) {
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// Calculate probability of next token, given the previous ones.
const std : : vector < float > tok_logits (
logits . begin ( ) + ( j + 0 ) * n_vocab ,
logits . begin ( ) + ( j + 1 ) * n_vocab ) ;
const float prob = softmax ( tok_logits ) [ tokens [ start + j + 1 ] ] ;
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logit_history [ start + j + 1 ] = tok_logits [ tokens [ start + j + 1 ] ] ;
prob_history [ start + j + 1 ] = prob ;
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nll + = - std : : log ( prob ) ;
+ + count ;
}
// perplexity is e^(average negative log-likelihood)
if ( params . ppl_output_type = = 0 ) {
printf ( " [%d]%.4lf, " , i + 1 , std : : exp ( nll / count ) ) ;
} else {
printf ( " %8d %.4lf \n " , i * params . ppl_stride , std : : exp ( nll / count ) ) ;
}
fflush ( stdout ) ;
}
printf ( " \n " ) ;
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return { tokens , std : : exp ( nll / count ) , logit_history , prob_history } ;
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}
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static results_perplexity perplexity ( llama_context * ctx , const gpt_params & params ) {
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if ( params . ppl_stride > 0 ) {
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return perplexity_v2 ( ctx , params ) ;
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}
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// Download: https://s3.amazonaws.com/research.metamind.io/wikitext/wikitext-2-raw-v1.zip?ref=salesforce-research
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// Run `./perplexity -m models/7B/ggml-model-q4_0.bin -f wiki.test.raw`
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// Output: `perplexity: 13.5106 [114/114]`
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// BOS tokens will be added for each chunk before eval
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const bool add_bos = llama_should_add_bos_token ( llama_get_model ( ctx ) ) ;
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const int n_ctx = llama_n_ctx ( ctx ) ;
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std : : ofstream logits_stream ;
if ( ! params . logits_file . empty ( ) ) {
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logits_stream . open ( params . logits_file . c_str ( ) , std : : ios : : binary ) ;
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if ( ! logits_stream . is_open ( ) ) {
fprintf ( stderr , " %s: failed to open %s for writing \n " , __func__ , params . logits_file . c_str ( ) ) ;
return { } ;
}
fprintf ( stderr , " %s: saving all logits to %s \n " , __func__ , params . logits_file . c_str ( ) ) ;
logits_stream . write ( " _logits_ " , 8 ) ;
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logits_stream . write ( reinterpret_cast < const char * > ( & n_ctx ) , sizeof ( n_ctx ) ) ;
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}
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auto tim1 = std : : chrono : : high_resolution_clock : : now ( ) ;
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fprintf ( stderr , " %s: tokenizing the input .. \n " , __func__ ) ;
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std : : vector < llama_token > tokens = : : llama_tokenize ( ctx , params . prompt , add_bos ) ;
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auto tim2 = std : : chrono : : high_resolution_clock : : now ( ) ;
fprintf ( stderr , " %s: tokenization took %g ms \n " , __func__ , 1e-3 * std : : chrono : : duration_cast < std : : chrono : : microseconds > ( tim2 - tim1 ) . count ( ) ) ;
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if ( int ( tokens . size ( ) ) < 2 * n_ctx ) {
fprintf ( stderr , " %s: you need at least %d tokens to evaluate perplexity with a context of %d \n " , __func__ , 2 * n_ctx ,
n_ctx ) ;
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fprintf ( stderr , " %s: the data file you provided tokenizes to only %zu tokens \n " , __func__ , tokens . size ( ) ) ;
return { std : : move ( tokens ) , 0. , { } , { } } ;
}
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std : : vector < float > logit_history ;
logit_history . resize ( tokens . size ( ) ) ;
std : : vector < float > prob_history ;
prob_history . resize ( tokens . size ( ) ) ;
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const int n_chunk_max = tokens . size ( ) / n_ctx ;
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const int n_chunk = params . n_chunks < 0 ? n_chunk_max : std : : min ( params . n_chunks , n_chunk_max ) ;
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const int n_vocab = llama_n_vocab ( llama_get_model ( ctx ) ) ;
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const int n_batch = params . n_batch ;
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int count = 0 ;
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double nll = 0.0 ;
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double nll2 = 0.0 ;
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const int num_batches = ( n_ctx + n_batch - 1 ) / n_batch ;
std : : vector < float > logits ;
if ( num_batches > 1 ) {
logits . reserve ( ( size_t ) n_ctx * n_vocab ) ;
}
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fprintf ( stderr , " %s: calculating perplexity over %d chunks, batch_size=%d \n " , __func__ , n_chunk , n_batch ) ;
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std : : vector < std : : thread > workers ( std : : thread : : hardware_concurrency ( ) - 1 ) ;
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std : : vector < uint16_t > log_probs ;
if ( ! params . logits_file . empty ( ) ) {
logits_stream . write ( ( const char * ) & n_vocab , sizeof ( n_vocab ) ) ;
logits_stream . write ( ( const char * ) & n_chunk , sizeof ( n_chunk ) ) ;
logits_stream . write ( ( const char * ) tokens . data ( ) , n_chunk * n_ctx * sizeof ( tokens [ 0 ] ) ) ;
const int nv = 2 * ( ( n_vocab + 1 ) / 2 ) + 4 ;
log_probs . resize ( n_ctx * nv ) ;
}
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for ( int i = 0 ; i < n_chunk ; + + i ) {
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const int start = i * n_ctx ;
const int end = start + n_ctx ;
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const auto t_start = std : : chrono : : high_resolution_clock : : now ( ) ;
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// clear the KV cache
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llama_kv_cache_clear ( ctx ) ;
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for ( int j = 0 ; j < num_batches ; + + j ) {
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const int batch_start = start + j * n_batch ;
const int batch_size = std : : min ( end - batch_start , n_batch ) ;
// save original token and restore it after eval
const auto token_org = tokens [ batch_start ] ;
// add BOS token for the first batch of each chunk
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if ( add_bos & & j = = 0 ) {
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tokens [ batch_start ] = llama_token_bos ( llama_get_model ( ctx ) ) ;
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}
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if ( llama_decode ( ctx , llama_batch_get_one ( tokens . data ( ) + batch_start , batch_size , j * n_batch , 0 ) ) ) {
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fprintf ( stderr , " %s : failed to eval \n " , __func__ ) ;
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return { tokens , - 1 , logit_history , prob_history } ;
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}
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// restore the original token in case it was set to BOS
tokens [ batch_start ] = token_org ;
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if ( num_batches > 1 ) {
const auto * batch_logits = llama_get_logits ( ctx ) ;
logits . insert ( logits . end ( ) , batch_logits , batch_logits + batch_size * n_vocab ) ;
}
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}
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const auto t_end = std : : chrono : : high_resolution_clock : : now ( ) ;
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if ( i = = 0 ) {
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const float t_total = std : : chrono : : duration < float > ( t_end - t_start ) . count ( ) ;
fprintf ( stderr , " %s: %.2f seconds per pass - ETA " , __func__ , t_total ) ;
int total_seconds = ( int ) ( t_total * n_chunk ) ;
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if ( total_seconds > = 60 * 60 ) {
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fprintf ( stderr , " %d hours " , total_seconds / ( 60 * 60 ) ) ;
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total_seconds = total_seconds % ( 60 * 60 ) ;
}
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fprintf ( stderr , " %.2f minutes \n " , total_seconds / 60.0 ) ;
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}
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// We get the logits for all the tokens in the context window (params.n_ctx)
// from llama_eval above. Now, based on https://huggingface.co/docs/transformers/perplexity,
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// calculate the perplexity over the last half of the window (so the model always has
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// some context to predict the token).
//
// We rely on the fact that attention in the forward pass only looks at previous
// tokens here, so the logits returned for each token are an accurate representation
// of what the model would have predicted at that point.
//
// Example, we have a context window of 512, we will compute perplexity for each of the
// last 256 tokens. Then, we split the input up into context window size chunks to
// process the entire prompt.
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const int first = n_ctx / 2 ;
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const float * all_logits = num_batches > 1 ? logits . data ( ) : llama_get_logits ( ctx ) ;
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if ( ! params . logits_file . empty ( ) ) {
process_logits ( logits_stream , n_vocab , all_logits + first * n_vocab , tokens . data ( ) + start + first , n_ctx - 1 - first ,
workers , log_probs , nll , nll2 ) ;
} else {
process_logits ( n_vocab , all_logits + first * n_vocab , tokens . data ( ) + start + first , n_ctx - 1 - first ,
workers , nll , nll2 , logit_history . data ( ) + start + first , prob_history . data ( ) + start + first ) ;
}
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count + = n_ctx - first - 1 ;
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// perplexity is e^(average negative log-likelihood)
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if ( params . ppl_output_type = = 0 ) {
printf ( " [%d]%.4lf, " , i + 1 , std : : exp ( nll / count ) ) ;
} else {
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double av = nll / count ;
double av2 = nll2 / count - av * av ;
if ( av2 > 0 ) av2 = sqrt ( av2 / ( count - 1 ) ) ;
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printf ( " %8d %.4lf %4lf %4lf \n " , i * n_ctx , std : : exp ( nll / count ) , av , av2 ) ;
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}
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fflush ( stdout ) ;
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logits . clear ( ) ;
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}
printf ( " \n " ) ;
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nll2 / = count ;
nll / = count ;
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const double ppl = exp ( nll ) ;
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nll2 - = nll * nll ;
if ( nll2 > 0 ) {
nll2 = sqrt ( nll2 / ( count - 1 ) ) ;
printf ( " Final estimate: PPL = %.4lf +/- %.5lf \n " , ppl , nll2 * ppl ) ;
} else {
printf ( " Unexpected negative standard deviation of log(prob) \n " ) ;
}
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return { tokens , ppl , logit_history , prob_history } ;
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}
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static bool decode_helper ( llama_context * ctx , llama_batch & batch , std : : vector < float > & batch_logits , int32_t n_batch , int32_t n_vocab ) {
for ( int32_t i = 0 ; i < ( int32_t ) batch . n_tokens ; i + = n_batch ) {
const int32_t n_tokens = std : : min ( n_batch , ( int32_t ) ( batch . n_tokens - i ) ) ;
llama_batch batch_view = {
n_tokens ,
batch . token + i ,
nullptr ,
batch . pos + i ,
batch . n_seq_id + i ,
batch . seq_id + i ,
batch . logits + i ,
0 , 0 , 0 , // unused
} ;
const int ret = llama_decode ( ctx , batch_view ) ;
if ( ret ! = 0 ) {
LOG_TEE ( " failed to decode the batch, n_batch = %d, ret = %d \n " , n_batch , ret ) ;
return false ;
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}
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memcpy ( batch_logits . data ( ) + i * n_vocab , llama_get_logits ( ctx ) , n_tokens * n_vocab * sizeof ( float ) ) ;
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}
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return true ;
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}
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# define K_TOKEN_CHUNK 4
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static void compute_logprobs ( const float * batch_logits , int n_vocab , std : : vector < std : : thread > & workers ,
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const std : : vector < std : : pair < size_t , llama_token > > & eval_pairs , std : : vector < float > & eval_results ) {
if ( eval_results . size ( ) ! = eval_pairs . size ( ) ) {
eval_results . resize ( eval_pairs . size ( ) ) ;
}
if ( eval_pairs . empty ( ) ) return ;
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size_t max_threads = std : : min ( ( eval_pairs . size ( ) + K_TOKEN_CHUNK - 1 ) / K_TOKEN_CHUNK , workers . size ( ) ) ;
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std : : atomic < int > counter ( 0 ) ;
auto compute = [ & counter , & eval_pairs , & eval_results , batch_logits , n_vocab ] ( ) {
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float local_logprobs [ K_TOKEN_CHUNK ] ;
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while ( true ) {
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size_t first = counter . fetch_add ( K_TOKEN_CHUNK , std : : memory_order_relaxed ) ;
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if ( first > = eval_results . size ( ) ) break ;
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size_t last = std : : min ( first + K_TOKEN_CHUNK , eval_results . size ( ) ) ;
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for ( size_t i = first ; i < last ; + + i ) {
auto logits = batch_logits + eval_pairs [ i ] . first * n_vocab ;
float max_logit = logits [ 0 ] ;
for ( int j = 1 ; j < n_vocab ; + + j ) {
max_logit = std : : max ( max_logit , logits [ j ] ) ;
}
float sum_p = 0.f ;
for ( int j = 0 ; j < n_vocab ; + + j ) {
sum_p + = expf ( logits [ j ] - max_logit ) ;
}
local_logprobs [ i - first ] = logits [ eval_pairs [ i ] . second ] - max_logit - std : : log ( sum_p ) ;
}
std : : memcpy ( eval_results . data ( ) + first , local_logprobs , ( last - first ) * sizeof ( float ) ) ;
}
} ;
for ( size_t it = 0 ; it < max_threads ; + + it ) {
workers [ it ] = std : : thread ( compute ) ;
}
for ( size_t it = 0 ; it < max_threads ; + + it ) {
workers [ it ] . join ( ) ;
}
}
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static void hellaswag_score ( llama_context * ctx , const gpt_params & params ) {
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// Calculates hellaswag score (acc_norm) from prompt
//
// Data extracted from the HellaSwag validation dataset (MIT license) https://github.com/rowanz/hellaswag/blob/master/data/hellaswag_val.jsonl
// All used data fields are preprocessed as in https://github.com/EleutherAI/lm-evaluation-harness/blob/df3da98c5405deafd519c2ddca52bb7c3fe36bef/lm_eval/tasks/hellaswag.py#L62-L68
//
// All 10042 tasks should be extracted to keep the results standardized like other implementations.
//
// Datafile layout:
// ['??'] denotes json fields
// 6 lines per task:
// ['activity_label'] + ": " +['ctx'] - The first part of the query, the context
// ['label'] - The index the best common sense ending aka gold ending
// ['endings'][0] - Endings added to the first part of the query
// ['endings'][1]
// ['endings'][2]
// ['endings'][3]
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std : : vector < std : : string > prompt_lines ;
std : : istringstream strstream ( params . prompt ) ;
std : : string line ;
while ( std : : getline ( strstream , line , ' \n ' ) ) {
prompt_lines . push_back ( line ) ;
}
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if ( prompt_lines . size ( ) % 6 ! = 0 ) {
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fprintf ( stderr , " %s : number of lines in prompt not a multiple of 6. \n " , __func__ ) ;
return ;
}
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size_t hs_task_count = prompt_lines . size ( ) / 6 ;
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fprintf ( stderr , " %s : loaded %zu tasks from prompt. \n " , __func__ , hs_task_count ) ;
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const bool is_spm = llama_vocab_type ( llama_get_model ( ctx ) ) = = LLAMA_VOCAB_TYPE_SPM ;
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fprintf ( stderr , " ================================= is_spm = %d \n " , is_spm ) ;
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// This is needed as usual for LLaMA models
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const bool add_bos = llama_should_add_bos_token ( llama_get_model ( ctx ) ) ;
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// The tasks should be randomized so the score stabilizes quickly.
bool randomize_tasks = true ;
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// Number of tasks to use when computing the score
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if ( params . hellaswag_tasks < hs_task_count ) {
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hs_task_count = params . hellaswag_tasks ;
}
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// The random seed should not impact the final result if the computation is done over enough tasks, so kept hardcoded for now
std : : mt19937 rng ( 1 ) ;
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// Dataholder for hellaswag tasks
struct hs_data_t {
std : : string context ;
size_t gold_ending_idx ;
std : : string ending [ 4 ] ;
size_t ending_logprob_count [ 4 ] ;
double ending_logprob [ 4 ] ;
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size_t i_batch ; // starting index in the llama_batch
size_t common_prefix ; // max number of initial tokens that are the same in all sentences
size_t required_tokens ; // needed number of tokens to evaluate all 4 endings
std : : vector < llama_token > seq_tokens [ 4 ] ;
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} ;
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fprintf ( stderr , " %s : selecting %zu %s tasks. \n " , __func__ , hs_task_count , ( randomize_tasks ? " randomized " : " the first " ) ) ;
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// Select and read data from prompt lines
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std : : vector < hs_data_t > hs_data ( hs_task_count ) ;
for ( size_t i = 0 ; i < hs_task_count ; i + + ) {
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size_t idx = i ;
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auto & hs_cur = hs_data [ i ] ;
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// Select a random example of those left in the prompt
if ( randomize_tasks ) {
std : : uniform_int_distribution < size_t > dist ( 0 , prompt_lines . size ( ) / 6 - 1 ) ;
idx = dist ( rng ) ;
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}
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hs_cur . context = prompt_lines [ idx * 6 ] ;
hs_cur . gold_ending_idx = std : : stoi ( prompt_lines [ idx * 6 + 1 ] ) ;
for ( size_t j = 0 ; j < 4 ; j + + ) {
hs_cur . ending [ j ] = prompt_lines [ idx * 6 + 2 + j ] ;
hs_cur . seq_tokens [ j ] = : : llama_tokenize ( ctx , hs_cur . context + " " + hs_cur . ending [ j ] , add_bos ) ;
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}
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// determine the common prefix of the endings
hs_cur . common_prefix = 0 ;
for ( size_t k = 0 ; k < hs_cur . seq_tokens [ 0 ] . size ( ) ; k + + ) {
if ( hs_cur . seq_tokens [ 0 ] [ k ] ! = hs_cur . seq_tokens [ 1 ] [ k ] | |
hs_cur . seq_tokens [ 0 ] [ k ] ! = hs_cur . seq_tokens [ 2 ] [ k ] | |
hs_cur . seq_tokens [ 0 ] [ k ] ! = hs_cur . seq_tokens [ 3 ] [ k ] ) {
break ;
}
hs_cur . common_prefix + + ;
}
hs_cur . required_tokens = hs_cur . common_prefix +
hs_cur . seq_tokens [ 0 ] . size ( ) - hs_cur . common_prefix +
hs_cur . seq_tokens [ 1 ] . size ( ) - hs_cur . common_prefix +
hs_cur . seq_tokens [ 2 ] . size ( ) - hs_cur . common_prefix +
hs_cur . seq_tokens [ 3 ] . size ( ) - hs_cur . common_prefix ;
//GGML_ASSERT(hs_cur.common_prefix >= ::llama_tokenize(ctx, hs_cur.context, add_bos).size());
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// Delete the selected random example from the prompt
if ( randomize_tasks ) {
prompt_lines . erase ( std : : next ( prompt_lines . begin ( ) , idx * 6 ) , std : : next ( prompt_lines . begin ( ) , idx * 6 + 6 ) ) ;
}
}
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fprintf ( stderr , " %s : calculating hellaswag score over selected tasks. \n " , __func__ ) ;
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printf ( " \n task \t acc_norm \n " ) ;
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double acc = 0.0f ;
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const int n_vocab = llama_n_vocab ( llama_get_model ( ctx ) ) ;
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const int n_ctx = llama_n_ctx ( ctx ) ;
const int n_batch = params . n_batch ;
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const int max_tasks_per_batch = 32 ;
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const int max_seq = 4 * max_tasks_per_batch ;
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llama_batch batch = llama_batch_init ( n_ctx , 0 , max_seq ) ;
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std : : vector < float > tok_logits ( n_vocab ) ;
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std : : vector < float > batch_logits ( n_vocab * n_ctx ) ;
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std : : vector < std : : pair < size_t , llama_token > > eval_pairs ;
std : : vector < float > eval_results ;
std : : vector < std : : thread > workers ( std : : thread : : hardware_concurrency ( ) ) ;
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for ( size_t i0 = 0 ; i0 < hs_task_count ; i0 + + ) {
int n_cur = 0 ;
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size_t i1 = i0 ;
size_t i_batch = 0 ; // this tells us where in `llama_batch` we are currently
llama_batch_clear ( batch ) ;
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// batch as much tasks as possible into the available context
// each task has 4 unique seuqnce ids - one for each ending
// the common prefix is shared among the 4 sequences to save tokens
// we extract logits only from the last common token and from all ending tokens of each sequence
while ( n_cur + ( int ) hs_data [ i1 ] . required_tokens < = n_ctx ) {
auto & hs_cur = hs_data [ i1 ] ;
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const int s0 = 4 * ( i1 - i0 ) ;
if ( s0 + 4 > max_seq ) {
break ;
}
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for ( size_t i = 0 ; i < hs_cur . common_prefix ; + + i ) {
llama_batch_add ( batch , hs_cur . seq_tokens [ 0 ] [ i ] , i , { s0 + 0 , s0 + 1 , s0 + 2 , s0 + 3 } , false ) ;
}
batch . logits [ batch . n_tokens - 1 ] = true ; // we need logits for the last token of the common prefix
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for ( int s = 0 ; s < 4 ; + + s ) {
for ( size_t i = hs_cur . common_prefix ; i < hs_cur . seq_tokens [ s ] . size ( ) ; + + i ) {
llama_batch_add ( batch , hs_cur . seq_tokens [ s ] [ i ] , i , { s0 + s } , true ) ;
}
}
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hs_cur . i_batch = i_batch ;
i_batch + = hs_cur . required_tokens ;
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n_cur + = hs_data [ i1 ] . required_tokens ;
if ( + + i1 = = hs_task_count ) {
break ;
}
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}
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if ( i0 = = i1 ) {
fprintf ( stderr , " %s : task %zu does not fit in the context window \n " , __func__ , i0 ) ;
return ;
}
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llama_kv_cache_clear ( ctx ) ;
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// decode all tasks [i0, i1)
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if ( ! decode_helper ( ctx , batch , batch_logits , n_batch , n_vocab ) ) {
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fprintf ( stderr , " %s: llama_decode() failed \n " , __func__ ) ;
return ;
}
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// Compute log-probs in parallel
// First we collect all tasks
eval_pairs . clear ( ) ;
for ( size_t i = i0 ; i < i1 ; + + i ) {
auto & hs_cur = hs_data [ i ] ;
size_t li = hs_cur . common_prefix ;
for ( int s = 0 ; s < 4 ; + + s ) {
for ( size_t j = hs_cur . common_prefix ; j < hs_cur . seq_tokens [ s ] . size ( ) - 1 ; j + + ) {
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eval_pairs . emplace_back ( hs_cur . i_batch + li + + , hs_cur . seq_tokens [ s ] [ j + 1 ] ) ;
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}
+ + li ;
}
}
// Then we do the actual calculation
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compute_logprobs ( batch_logits . data ( ) , n_vocab , workers , eval_pairs , eval_results ) ;
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size_t ir = 0 ;
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// compute the logprobs for each ending of the decoded tasks
for ( size_t i = i0 ; i < i1 ; + + i ) {
auto & hs_cur = hs_data [ i ] ;
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std : : memcpy ( tok_logits . data ( ) , batch_logits . data ( ) + n_vocab * ( hs_cur . i_batch + hs_cur . common_prefix - 1 ) , n_vocab * sizeof ( float ) ) ;
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const auto first_probs = softmax ( tok_logits ) ;
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for ( int s = 0 ; s < 4 ; + + s ) {
hs_cur . ending_logprob_count [ s ] = 1 ;
hs_cur . ending_logprob [ s ] = std : : log ( first_probs [ hs_cur . seq_tokens [ s ] [ hs_cur . common_prefix ] ] ) ;
for ( size_t j = hs_cur . common_prefix ; j < hs_cur . seq_tokens [ s ] . size ( ) - 1 ; j + + ) {
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hs_cur . ending_logprob [ s ] + = eval_results [ ir + + ] ;
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hs_cur . ending_logprob_count [ s ] + + ;
}
hs_cur . ending_logprob [ s ] / = hs_cur . ending_logprob_count [ s ] ;
}
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// Find the ending with maximum logprob
size_t ending_logprob_max_idx = 0 ;
double ending_logprob_max_val = hs_cur . ending_logprob [ 0 ] ;
for ( size_t s = 1 ; s < 4 ; s + + ) {
if ( hs_cur . ending_logprob [ s ] > ending_logprob_max_val ) {
ending_logprob_max_idx = s ;
ending_logprob_max_val = hs_cur . ending_logprob [ s ] ;
}
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}
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//printf("max logprob ending idx %lu, gold ending idx %lu\n", ending_logprob_max_idx, hs_cur.gold_ending_idx);
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// If the gold ending got the maximum logprobe add one accuracy point
if ( ending_logprob_max_idx = = hs_cur . gold_ending_idx ) {
acc + = 1.0 ;
}
// Print the accumulated accuracy mean x 100
printf ( " %zu \t %.8lf \n " , i + 1 , acc / double ( i + 1 ) * 100.0 ) ;
fflush ( stdout ) ;
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}
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i0 = i1 - 1 ;
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}
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llama_batch_free ( batch ) ;
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printf ( " \n " ) ;
}
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struct winogrande_entry {
std : : string first ;
std : : string second ;
std : : array < std : : string , 2 > choices ;
int answer ;
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size_t i_batch ;
size_t common_prefix ;
size_t required_tokens ;
size_t n_base1 ; // number of tokens for context + choice 1
size_t n_base2 ; // number of tokens for context + choice 2
std : : vector < llama_token > seq_tokens [ 2 ] ;
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} ;
static std : : vector < winogrande_entry > load_winogrande_from_csv ( const std : : string & prompt ) {
std : : vector < winogrande_entry > result ;
std : : istringstream in ( prompt ) ;
std : : string line ;
std : : array < int , 4 > comma_pos ;
while ( true ) {
std : : getline ( in , line ) ;
if ( in . fail ( ) | | in . eof ( ) ) break ;
int ipos = 0 ;
bool quote_open = false ;
for ( int i = 0 ; i < int ( line . size ( ) ) ; + + i ) {
if ( ! quote_open ) {
if ( line [ i ] = = ' , ' ) {
comma_pos [ ipos + + ] = i ;
if ( ipos = = 4 ) break ;
}
else if ( line [ i ] = = ' " ' ) {
quote_open = true ;
}
}
else {
if ( line [ i ] = = ' " ' ) {
quote_open = false ;
}
}
}
if ( ipos ! = 4 ) {
printf ( " %s: failed to find comma separators in <%s> \n " , __func__ , line . c_str ( ) ) ;
continue ;
}
auto sentence = line [ comma_pos [ 0 ] + 1 ] = = ' " ' ? line . substr ( comma_pos [ 0 ] + 2 , comma_pos [ 1 ] - comma_pos [ 0 ] - 3 )
: line . substr ( comma_pos [ 0 ] + 1 , comma_pos [ 1 ] - comma_pos [ 0 ] - 1 ) ;
auto choice1 = line . substr ( comma_pos [ 1 ] + 1 , comma_pos [ 2 ] - comma_pos [ 1 ] - 1 ) ;
auto choice2 = line . substr ( comma_pos [ 2 ] + 1 , comma_pos [ 3 ] - comma_pos [ 2 ] - 1 ) ;
auto answer = line . substr ( comma_pos [ 3 ] + 1 , line . size ( ) - comma_pos [ 3 ] - 1 ) ;
auto index = line . substr ( 0 , comma_pos [ 0 ] ) ;
int where = 0 ;
for ( ; where < int ( sentence . size ( ) ) ; + + where ) {
if ( sentence [ where ] = = ' _ ' ) break ;
}
if ( where = = int ( sentence . size ( ) ) ) {
printf ( " %s: no _ in <%s> \n " , __func__ , sentence . c_str ( ) ) ;
continue ;
}
std : : istringstream stream ( answer . c_str ( ) ) ;
int i_answer ; stream > > i_answer ;
if ( stream . fail ( ) | | i_answer < 1 | | i_answer > 2 ) {
printf ( " %s: failed to parse answer <%s> \n " , __func__ , answer . c_str ( ) ) ;
continue ;
}
result . emplace_back ( ) ;
auto & wg = result . back ( ) ;
wg . first = sentence . substr ( 0 , where ) ;
wg . second = sentence . substr ( where + 1 , sentence . size ( ) - where - 1 ) ;
wg . choices [ 0 ] = std : : move ( choice1 ) ;
wg . choices [ 1 ] = std : : move ( choice2 ) ;
wg . answer = i_answer ;
}
return result ;
}
/*
* Evaluates the Winogrande score .
* Uses a CSV containing task index , dentence , choice 1 , choice 2 , answer ( 1 or 2 )
* You can get one such dataset from e . g . https : //huggingface.co/datasets/ikawrakow/winogrande-eval-for-llama.cpp
* As an example , the 1 st row in the above dataset is
*
* 0 , Sarah was a much better surgeon than Maria so _ always got the easier cases . , Sarah , Maria , 2
*
*/
static void winogrande_score ( llama_context * ctx , const gpt_params & params ) {
constexpr int k_min_trailing_ctx = 3 ;
auto data = load_winogrande_from_csv ( params . prompt ) ;
if ( data . empty ( ) ) {
fprintf ( stderr , " %s: no tasks \n " , __func__ ) ;
return ;
}
fprintf ( stderr , " %s : loaded %zu tasks from prompt. \n " , __func__ , data . size ( ) ) ;
if ( params . winogrande_tasks > 0 & & params . winogrande_tasks < data . size ( ) ) {
fprintf ( stderr , " %s : selecting %zu random tasks \n " , __func__ , params . winogrande_tasks ) ;
std : : mt19937 rng ( 1 ) ;
std : : vector < int > aux ( data . size ( ) ) ;
for ( int i = 0 ; i < int ( data . size ( ) ) ; + + i ) {
aux [ i ] = i ;
}
float scale = 1 / ( 1.f + ( float ) rng . max ( ) ) ;
std : : vector < winogrande_entry > selected ;
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selected . resize ( params . winogrande_tasks ) ;
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for ( int i = 0 ; i < int ( params . winogrande_tasks ) ; + + i ) {
int j = int ( scale * rng ( ) * aux . size ( ) ) ;
selected [ i ] = std : : move ( data [ aux [ j ] ] ) ;
aux [ j ] = aux . back ( ) ;
aux . pop_back ( ) ;
}
data = std : : move ( selected ) ;
}
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fprintf ( stderr , " %s : tokenizing selected tasks \n " , __func__ ) ;
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// This is needed as usual for LLaMA models
const bool add_bos = llama_should_add_bos_token ( llama_get_model ( ctx ) ) ;
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for ( auto & task : data ) {
task . seq_tokens [ 0 ] = : : llama_tokenize ( ctx , task . first + task . choices [ 0 ] + task . second , add_bos ) ;
task . seq_tokens [ 1 ] = : : llama_tokenize ( ctx , task . first + task . choices [ 1 ] + task . second , add_bos ) ;
task . common_prefix = 0 ;
for ( size_t k = 0 ; k < task . seq_tokens [ 0 ] . size ( ) ; k + + ) {
if ( task . seq_tokens [ 0 ] [ k ] ! = task . seq_tokens [ 1 ] [ k ] ) {
break ;
}
task . common_prefix + + ;
}
task . required_tokens = task . common_prefix +
task . seq_tokens [ 0 ] . size ( ) - task . common_prefix +
task . seq_tokens [ 1 ] . size ( ) - task . common_prefix ;
task . n_base1 = : : llama_tokenize ( ctx , task . first + task . choices [ 0 ] , add_bos ) . size ( ) ;
task . n_base2 = : : llama_tokenize ( ctx , task . first + task . choices [ 1 ] , add_bos ) . size ( ) ;
}
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fprintf ( stderr , " %s : calculating winogrande score over selected tasks. \n " , __func__ ) ;
const int n_vocab = llama_n_vocab ( llama_get_model ( ctx ) ) ;
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const int n_ctx = llama_n_ctx ( ctx ) ;
const int n_batch = params . n_batch ;
const int max_tasks_per_batch = 128 ;
const int max_seq = 2 * max_tasks_per_batch ;
llama_batch batch = llama_batch_init ( n_ctx , 0 , max_seq ) ;
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std : : vector < float > tok_logits ( n_vocab ) ;
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std : : vector < float > batch_logits ( n_vocab * n_ctx ) ;
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std : : vector < std : : pair < size_t , llama_token > > eval_pairs ;
std : : vector < float > eval_results ;
std : : vector < std : : thread > workers ( std : : thread : : hardware_concurrency ( ) ) ;
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int n_correct = 0 ;
int n_done = 0 ;
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for ( size_t i0 = 0 ; i0 < data . size ( ) ; i0 + + ) {
int n_cur = 0 ;
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size_t i1 = i0 ;
size_t i_batch = 0 ;
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llama_batch_clear ( batch ) ;
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while ( n_cur + ( int ) data [ i1 ] . required_tokens < = n_ctx ) {
const int s0 = 2 * ( i1 - i0 ) ;
if ( s0 + 2 > max_seq ) {
break ;
}
for ( size_t i = 0 ; i < data [ i1 ] . common_prefix ; + + i ) {
llama_batch_add ( batch , data [ i1 ] . seq_tokens [ 0 ] [ i ] , i , { s0 + 0 , s0 + 1 } , false ) ;
}
batch . logits [ batch . n_tokens - 1 ] = true ;
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for ( int s = 0 ; s < 2 ; + + s ) {
for ( size_t i = data [ i1 ] . common_prefix ; i < data [ i1 ] . seq_tokens [ s ] . size ( ) ; + + i ) {
llama_batch_add ( batch , data [ i1 ] . seq_tokens [ s ] [ i ] , i , { s0 + s } , true ) ;
}
}
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data [ i1 ] . i_batch = i_batch ;
i_batch + = data [ i1 ] . required_tokens ;
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n_cur + = data [ i1 ] . required_tokens ;
if ( + + i1 = = data . size ( ) ) {
break ;
}
}
if ( i0 = = i1 ) {
fprintf ( stderr , " %s : task %zu does not fit in the context window \n " , __func__ , i0 ) ;
return ;
}
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llama_kv_cache_clear ( ctx ) ;
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// decode all tasks [i0, i1)
if ( ! decode_helper ( ctx , batch , batch_logits , n_batch , n_vocab ) ) {
fprintf ( stderr , " %s: llama_decode() failed \n " , __func__ ) ;
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return ;
}
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eval_pairs . clear ( ) ;
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for ( size_t i = i0 ; i < i1 ; + + i ) {
auto & task = data [ i ] ;
const bool skip_choice =
task . seq_tokens [ 0 ] . size ( ) - task . common_prefix > k_min_trailing_ctx & &
task . seq_tokens [ 1 ] . size ( ) - task . common_prefix > k_min_trailing_ctx ;
const auto & n_base1 = skip_choice ? task . n_base1 : task . common_prefix ;
const int last_1st = task . seq_tokens [ 0 ] . size ( ) - n_base1 > 1 ? 1 : 0 ;
size_t li = n_base1 - 1 ;
for ( size_t j = n_base1 - 1 ; j < task . seq_tokens [ 0 ] . size ( ) - 1 - last_1st ; + + j ) {
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eval_pairs . emplace_back ( task . i_batch + li + + , task . seq_tokens [ 0 ] [ j + 1 ] ) ;
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}
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const auto & n_base2 = skip_choice ? task . n_base2 : task . common_prefix ;
const int last_2nd = task . seq_tokens [ 1 ] . size ( ) - n_base2 > 1 ? 1 : 0 ;
li = task . seq_tokens [ 0 ] . size ( ) - task . common_prefix + n_base2 - 1 ;
for ( size_t j = n_base2 - 1 ; j < task . seq_tokens [ 1 ] . size ( ) - 1 - last_2nd ; + + j ) {
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eval_pairs . emplace_back ( task . i_batch + li + + , task . seq_tokens [ 1 ] [ j + 1 ] ) ;
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}
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}
compute_logprobs ( batch_logits . data ( ) , n_vocab , workers , eval_pairs , eval_results ) ;
size_t ir = 0 ;
for ( size_t i = i0 ; i < i1 ; + + i ) {
auto & task = data [ i ] ;
const bool skip_choice =
task . seq_tokens [ 0 ] . size ( ) - task . common_prefix > k_min_trailing_ctx & &
task . seq_tokens [ 1 ] . size ( ) - task . common_prefix > k_min_trailing_ctx ;
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float score_1st = 0 ;
const auto & n_base1 = skip_choice ? task . n_base1 : task . common_prefix ;
const int last_1st = task . seq_tokens [ 0 ] . size ( ) - n_base1 > 1 ? 1 : 0 ;
for ( size_t j = n_base1 - 1 ; j < task . seq_tokens [ 0 ] . size ( ) - 1 - last_1st ; + + j ) {
score_1st + = eval_results [ ir + + ] ;
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}
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score_1st / = ( task . seq_tokens [ 0 ] . size ( ) - n_base1 - last_1st ) ;
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float score_2nd = 0 ;
const auto & n_base2 = skip_choice ? task . n_base2 : task . common_prefix ;
const int last_2nd = task . seq_tokens [ 1 ] . size ( ) - n_base2 > 1 ? 1 : 0 ;
for ( size_t j = n_base2 - 1 ; j < task . seq_tokens [ 1 ] . size ( ) - 1 - last_2nd ; + + j ) {
score_2nd + = eval_results [ ir + + ] ;
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}
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score_2nd / = ( task . seq_tokens [ 1 ] . size ( ) - n_base2 - last_2nd ) ;
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int result = score_1st > score_2nd ? 1 : 2 ;
if ( result = = task . answer ) {
+ + n_correct ;
}
+ + n_done ;
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// print the accumulated accuracy mean x 100
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printf ( " %zu \t %.4lf \t %10.6f %10.6f %d %d \n " , i + 1 , 100.0 * n_correct / n_done , score_1st , score_2nd , result , task . answer ) ;
fflush ( stdout ) ;
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}
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i0 = i1 - 1 ;
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}
printf ( " \n " ) ;
if ( n_done < 100 ) return ;
const float p = 1.f * n_correct / n_done ;
const float sigma = 100.f * sqrt ( p * ( 1 - p ) / ( n_done - 1 ) ) ;
printf ( " Final Winogrande score(%d tasks): %.4lf +/- %.4lf \n " , n_done , 100 * p , sigma ) ;
}
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static bool deserialize_string ( std : : istream & in , std : : string & str ) {
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uint32_t size ;
if ( ! in . read ( ( char * ) & size , sizeof ( size ) ) . fail ( ) ) {
str . resize ( size ) ;
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if ( ! in . read ( ( char * ) & str [ 0 ] , size ) . fail ( ) ) return true ;
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}
return false ;
}
struct multiple_choice_answers {
std : : vector < std : : string > answers ;
std : : vector < int > labels ;
bool deserialize ( std : : istream & in ) {
uint32_t n ;
in . read ( ( char * ) & n , sizeof ( n ) ) ;
if ( in . fail ( ) | | n > 100 ) return false ; // 100 as max. number of answers should be good enough for any practical purpose
answers . resize ( n ) ;
labels . resize ( n ) ;
for ( auto & a : answers ) {
if ( ! deserialize_string ( in , a ) ) return false ;
}
in . read ( ( char * ) labels . data ( ) , n * sizeof ( int ) ) ;
return ! in . fail ( ) ;
}
} ;
struct multiple_choice_task {
std : : string question ; // the question (or context that needs to be continued)
multiple_choice_answers mc1 ; // possible answers (continuations) with a single correct answer
multiple_choice_answers mc2 ; // possible answers (continuations) with multiple correct answers - not handled yet
bool deserialize ( std : : istream & in ) {
if ( ! deserialize_string ( in , question ) ) return false ;
return mc1 . deserialize ( in ) & & mc2 . deserialize ( in ) ;
}
// For evaluation
size_t i_batch ; // starting index in the llama_batch
size_t common_prefix ; // max number of initial tokens that are the same in all sentences
size_t required_tokens ; // needed number of tokens to evaluate all answers
std : : vector < std : : vector < llama_token > > seq_tokens ;
std : : vector < float > log_probs ;
} ;
static bool multiple_choice_prepare_one_task ( llama_context * ctx , bool add_bos , multiple_choice_task & task , bool log_error ) {
if ( task . question . empty ( ) | | task . mc1 . answers . empty ( ) ) {
if ( log_error ) {
printf ( " %s: found bad task with empty question and/or answers \n " , __func__ ) ;
}
return false ;
}
task . seq_tokens . reserve ( task . mc1 . answers . size ( ) ) ;
for ( auto & answer : task . mc1 . answers ) {
if ( answer . empty ( ) ) {
if ( log_error ) {
printf ( " %s: found empty answer \n " , __func__ ) ;
}
return false ;
}
task . seq_tokens . emplace_back ( : : llama_tokenize ( ctx , task . question + " " + answer , add_bos ) ) ;
}
auto min_len = task . seq_tokens . front ( ) . size ( ) ;
for ( auto & seq : task . seq_tokens ) {
min_len = std : : min ( min_len , seq . size ( ) ) ;
}
task . common_prefix = 0 ;
for ( size_t k = 0 ; k < min_len ; + + k ) {
auto token = task . seq_tokens [ 0 ] [ k ] ;
bool all_same = true ;
for ( size_t i = 1 ; i < task . seq_tokens . size ( ) ; + + i ) {
if ( task . seq_tokens [ i ] [ k ] ! = token ) {
all_same = false ;
break ;
}
}
if ( ! all_same ) {
break ;
}
+ + task . common_prefix ;
}
task . required_tokens = task . common_prefix ;
for ( auto & seq : task . seq_tokens ) {
task . required_tokens + = seq . size ( ) - task . common_prefix ;
}
return true ;
}
//
// Calculates score for multiple choice tasks with single correct answer from prompt.
// Commonly used LLM evaluation metrics of this type are
// * ARC
// * HellaSwag
// * MMLU
// * TruthfulQA
//
// Validation datasets for these 4 tests can be found at
// https://huggingface.co/datasets/ikawrakow/validation-datasets-for-llama.cpp
// The data for these datasets was extracted from
// git@hf.co:datasets/allenai/ai2_arc
// https://github.com/rowanz/hellaswag/blob/master/data/hellaswag_val.jsonl
// git@hf.co:datasets/Stevross/mmlu
// https://huggingface.co/datasets/truthful_qa
//
static void multiple_choice_score ( llama_context * ctx , const gpt_params & params ) {
std : : istringstream strstream ( params . prompt ) ;
uint32_t n_task ;
strstream . read ( ( char * ) & n_task , sizeof ( n_task ) ) ;
if ( strstream . fail ( ) | | n_task = = 0 ) {
printf ( " %s: no tasks \n " , __func__ ) ;
return ;
}
printf ( " %s: there are %u tasks in prompt \n " , __func__ , n_task ) ;
std : : vector < uint32_t > task_pos ( n_task ) ;
strstream . read ( ( char * ) task_pos . data ( ) , task_pos . size ( ) * sizeof ( uint32_t ) ) ;
if ( strstream . fail ( ) ) {
printf ( " %s: failed to raad task positions from prompt \n " , __func__ ) ;
return ;
}
std : : vector < multiple_choice_task > tasks ;
if ( params . multiple_choice_tasks = = 0 | | params . multiple_choice_tasks > = ( size_t ) n_task ) {
// Use all tasks
tasks . resize ( n_task ) ;
printf ( " %s: reading tasks " , __func__ ) ;
int n_dot = n_task / 100 ;
int i = 0 ;
for ( auto & task : tasks ) {
+ + i ;
if ( ! task . deserialize ( strstream ) ) {
printf ( " %s: failed to read task %d of %u \n " , __func__ , i , n_task ) ;
return ;
}
if ( i % n_dot = = 0 ) printf ( " . " ) ;
}
printf ( " done \n " ) ;
}
else {
printf ( " %s: selecting %zu random tasks from %u tasks available \n " , __func__ , params . multiple_choice_tasks , n_task ) ;
std : : mt19937 rng ( 1 ) ;
std : : vector < int > aux ( n_task ) ;
for ( uint32_t i = 0 ; i < n_task ; + + i ) aux [ i ] = i ;
float scale = 1.f / ( 1.f + ( float ) std : : mt19937 : : max ( ) ) ;
tasks . resize ( params . multiple_choice_tasks ) ;
for ( auto & task : tasks ) {
int j = ( int ) ( scale * rng ( ) * aux . size ( ) ) ;
int idx = aux [ j ] ;
aux [ j ] = aux . back ( ) ;
aux . pop_back ( ) ;
strstream . seekg ( task_pos [ idx ] , std : : ios : : beg ) ;
if ( ! task . deserialize ( strstream ) ) {
printf ( " %s: failed to read task %d at position %u \n " , __func__ , idx , task_pos [ idx ] ) ;
return ;
}
}
n_task = params . multiple_choice_tasks ;
}
// This is needed as usual for LLaMA models
const bool add_bos = llama_should_add_bos_token ( llama_get_model ( ctx ) ) ;
printf ( " %s: preparing task data " , __func__ ) ;
fflush ( stdout ) ;
if ( n_task > 500 ) {
printf ( " ... " ) ;
fflush ( stdout ) ;
std : : atomic < int > counter ( 0 ) ;
std : : atomic < int > n_bad ( 0 ) ;
auto prepare = [ & counter , & n_bad , & tasks , ctx , add_bos ] ( ) {
int num_tasks = tasks . size ( ) ;
int n_bad_local = 0 ;
while ( true ) {
int first = counter . fetch_add ( K_TOKEN_CHUNK ) ;
if ( first > = num_tasks ) {
if ( n_bad_local > 0 ) n_bad + = n_bad_local ;
break ;
}
int last = std : : min ( first + K_TOKEN_CHUNK , num_tasks ) ;
for ( int i = first ; i < last ; + + i ) {
if ( ! multiple_choice_prepare_one_task ( ctx , add_bos , tasks [ i ] , false ) ) + + n_bad_local ;
}
}
} ;
size_t max_thread = std : : thread : : hardware_concurrency ( ) ;
max_thread = std : : min ( max_thread , ( tasks . size ( ) + K_TOKEN_CHUNK - 1 ) / K_TOKEN_CHUNK ) ;
std : : vector < std : : thread > workers ( max_thread - 1 ) ;
for ( auto & w : workers ) w = std : : thread ( prepare ) ;
prepare ( ) ;
for ( auto & w : workers ) w . join ( ) ;
printf ( " done \n " ) ;
fflush ( stdout ) ;
int nbad = n_bad ;
if ( nbad > 0 ) {
printf ( " %s: found %d malformed tasks \n " , __func__ , nbad ) ;
return ;
}
} else {
int n_dot = n_task / 100 ;
int i_task = 0 ;
for ( auto & task : tasks ) {
+ + i_task ;
if ( ! multiple_choice_prepare_one_task ( ctx , add_bos , task , true ) ) {
return ;
}
if ( i_task % n_dot = = 0 ) {
printf ( " . " ) ;
fflush ( stdout ) ;
}
}
printf ( " done \n " ) ;
}
printf ( " %s : calculating TruthfulQA score over %zu tasks. \n " , __func__ , tasks . size ( ) ) ;
printf ( " \n task \t acc_norm \n " ) ;
const int n_vocab = llama_n_vocab ( llama_get_model ( ctx ) ) ;
const int n_ctx = llama_n_ctx ( ctx ) ;
const int n_batch = params . n_batch ;
const int max_tasks_per_batch = 32 ;
const int max_seq = 4 * max_tasks_per_batch ;
llama_batch batch = llama_batch_init ( n_ctx , 0 , max_seq ) ;
std : : vector < float > tok_logits ( n_vocab ) ;
std : : vector < float > batch_logits ( n_vocab * n_ctx ) ;
std : : vector < std : : pair < size_t , llama_token > > eval_pairs ;
std : : vector < float > eval_results ;
std : : vector < std : : thread > workers ( std : : thread : : hardware_concurrency ( ) ) ;
std : : vector < int > batch_indeces ;
int n_done = 0 ;
int n_correct = 0 ;
int n_tot_answers = 0 ;
for ( size_t i0 = 0 ; i0 < tasks . size ( ) ; i0 + + ) {
int n_cur = 0 ;
size_t i1 = i0 ;
size_t i_batch = 0 ; // this tells us where in `llama_batch` we are currently
llama_batch_clear ( batch ) ;
// batch as much tasks as possible into the available context
// each task has 4 unique seuqnce ids - one for each ending
// the common prefix is shared among the 4 sequences to save tokens
// we extract logits only from the last common token and from all ending tokens of each sequence
int s0 = 0 ;
while ( n_cur + ( int ) tasks [ i1 ] . required_tokens < = n_ctx ) {
auto & cur_task = tasks [ i1 ] ;
int num_answers = cur_task . seq_tokens . size ( ) ;
if ( s0 + num_answers > max_seq ) {
break ;
}
if ( int ( batch_indeces . size ( ) ) ! = num_answers ) {
batch_indeces . resize ( num_answers ) ;
}
for ( int s = 0 ; s < num_answers ; + + s ) batch_indeces [ s ] = s0 + s ;
for ( size_t i = 0 ; i < cur_task . common_prefix ; + + i ) {
//llama_batch_add(batch, cur_task.seq_tokens[0][i], i, { s0 + 0, s0 + 1, s0 + 2, s0 + 3}, false);
llama_batch_add ( batch , cur_task . seq_tokens [ 0 ] [ i ] , i , batch_indeces , false ) ;
}
batch . logits [ batch . n_tokens - 1 ] = true ; // we need logits for the last token of the common prefix
for ( int s = 0 ; s < int ( cur_task . seq_tokens . size ( ) ) ; + + s ) {
for ( size_t i = cur_task . common_prefix ; i < cur_task . seq_tokens [ s ] . size ( ) ; + + i ) {
llama_batch_add ( batch , cur_task . seq_tokens [ s ] [ i ] , i , { s0 + s } , true ) ;
}
}
s0 + = num_answers ;
cur_task . i_batch = i_batch ;
i_batch + = cur_task . required_tokens ;
n_cur + = cur_task . required_tokens ;
if ( + + i1 = = tasks . size ( ) ) {
break ;
}
}
if ( i0 = = i1 ) {
fprintf ( stderr , " %s : task %zu does not fit in the context window \n " , __func__ , i0 ) ;
return ;
}
llama_kv_cache_clear ( ctx ) ;
// decode all tasks [i0, i1)
if ( ! decode_helper ( ctx , batch , batch_logits , n_batch , n_vocab ) ) {
fprintf ( stderr , " %s: llama_decode() failed \n " , __func__ ) ;
return ;
}
// Compute log-probs in parallel
// First we collect all tasks
eval_pairs . clear ( ) ;
for ( size_t i = i0 ; i < i1 ; + + i ) {
auto & cur_task = tasks [ i ] ;
size_t li = cur_task . common_prefix ;
for ( int s = 0 ; s < int ( cur_task . seq_tokens . size ( ) ) ; + + s ) {
for ( size_t j = cur_task . common_prefix ; j < cur_task . seq_tokens [ s ] . size ( ) - 1 ; j + + ) {
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eval_pairs . emplace_back ( cur_task . i_batch + li + + , cur_task . seq_tokens [ s ] [ j + 1 ] ) ;
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}
+ + li ;
}
}
// Then we do the actual calculation
compute_logprobs ( batch_logits . data ( ) , n_vocab , workers , eval_pairs , eval_results ) ;
size_t ir = 0 ;
// compute the logprobs for each ending of the decoded tasks
for ( size_t i = i0 ; i < i1 ; + + i ) {
auto & cur_task = tasks [ i ] ;
//printf("==== Evaluating <%s> with correct answer ", cur_task.question.c_str());
//for (int j = 0; j < int(cur_task.mc1.labels.size()); ++j) {
// if (cur_task.mc1.labels[j] == 1) {
// printf("%d", j+1);
// }
//}
//printf("\n common_prefix: %zu\n", cur_task.common_prefix);
std : : memcpy ( tok_logits . data ( ) , batch_logits . data ( ) + n_vocab * ( cur_task . i_batch + cur_task . common_prefix - 1 ) , n_vocab * sizeof ( float ) ) ;
const auto first_probs = softmax ( tok_logits ) ;
cur_task . log_probs . resize ( cur_task . seq_tokens . size ( ) ) ;
for ( int s = 0 ; s < int ( cur_task . seq_tokens . size ( ) ) ; + + s ) {
size_t count = 1 ;
float log_prob = std : : log ( first_probs [ cur_task . seq_tokens [ s ] [ cur_task . common_prefix ] ] ) ;
for ( size_t j = cur_task . common_prefix ; j < cur_task . seq_tokens [ s ] . size ( ) - 1 ; j + + ) {
//printf(" %zu %g\n", ir, eval_results[ir]);
+ + count ;
log_prob + = eval_results [ ir + + ] ;
}
cur_task . log_probs [ s ] = log_prob / count ;
//printf(" Final: %g\n", log_prob / count);
//printf(" <%s> : %g\n", cur_task.mc1.answers[s].c_str(), log_prob/count);
}
// Find the ending with maximum logprob
size_t logprob_max_idx = 0 ;
float logprob_max_val = cur_task . log_probs [ 0 ] ;
for ( size_t s = 1 ; s < cur_task . log_probs . size ( ) ; s + + ) {
if ( cur_task . log_probs [ s ] > logprob_max_val ) {
logprob_max_val = cur_task . log_probs [ s ] ;
logprob_max_idx = s ;
}
}
n_tot_answers + = cur_task . log_probs . size ( ) ;
if ( cur_task . mc1 . labels [ logprob_max_idx ] = = 1 ) {
+ + n_correct ;
}
+ + n_done ;
// Print the accumulated accuracy mean x 100
printf ( " %d \t %.8lf \n " , n_done , 100. * n_correct / n_done ) ;
fflush ( stdout ) ;
}
i0 = i1 - 1 ;
}
llama_batch_free ( batch ) ;
if ( n_done < 100 ) return ;
float p = 1.f * n_correct / n_done ;
float sigma = sqrt ( p * ( 1 - p ) / ( n_done - 1 ) ) ;
printf ( " \n Final result: %.4f +/- %.4f \n " , 100.f * p , 100.f * sigma ) ;
p = 1.f * n_done / n_tot_answers ;
sigma = sqrt ( p * ( 1 - p ) / ( n_done - 1 ) ) ;
printf ( " Random chance: %.4f +/- %.4f \n " , 100.f * p , 100.f * sigma ) ;
printf ( " \n " ) ;
}
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static void kl_divergence ( llama_context * ctx , const gpt_params & params ) {
if ( params . logits_file . empty ( ) ) {
fprintf ( stderr , " %s: you must provide a name of a file containing the log probabilities of the base model \n " , __func__ ) ;
return ;
}
std : : ifstream in ( params . logits_file . c_str ( ) , std : : ios : : binary ) ;
if ( ! in ) {
fprintf ( stderr , " %s: failed to open %s \n " , __func__ , params . logits_file . c_str ( ) ) ;
return ;
}
{
char check [ 9 ] ; check [ 8 ] = 0 ;
in . read ( check , 8 ) ;
if ( in . fail ( ) | | strncmp ( " _logits_ " , check , 8 ) ! = 0 ) {
fprintf ( stderr , " %s: %s does not look like a file containing log-probabilities \n " , __func__ , params . logits_file . c_str ( ) ) ;
return ;
}
}
uint32_t n_ctx ;
in . read ( ( char * ) & n_ctx , sizeof ( n_ctx ) ) ;
if ( n_ctx > llama_n_ctx ( ctx ) ) {
fprintf ( stderr , " %s: %s has been computed with %d, while the current context is %d. Increase it with -c and retry \n " ,
__func__ , params . logits_file . c_str ( ) , n_ctx , params . n_ctx ) ;
}
int n_vocab , n_chunk ;
in . read ( ( char * ) & n_vocab , sizeof ( n_vocab ) ) ;
in . read ( ( char * ) & n_chunk , sizeof ( n_chunk ) ) ;
if ( in . fail ( ) ) {
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fprintf ( stderr , " %s: failed reading n_vocab, n_chunk from %s \n " , __func__ , params . logits_file . c_str ( ) ) ;
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return ;
}
if ( n_vocab ! = llama_n_vocab ( llama_get_model ( ctx ) ) ) {
fprintf ( stderr , " %s: inconsistent vocabulary (%d vs %d) \n " , __func__ , n_vocab , llama_n_vocab ( llama_get_model ( ctx ) ) ) ;
}
std : : vector < llama_token > tokens ( n_ctx * n_chunk ) ;
if ( in . read ( ( char * ) tokens . data ( ) , tokens . size ( ) * sizeof ( tokens [ 0 ] ) ) . fail ( ) ) {
fprintf ( stderr , " %s: failed reading evaluation tokens from %s \n " , __func__ , params . logits_file . c_str ( ) ) ;
return ;
}
const int n_batch = params . n_batch ;
const int num_batches = ( n_ctx + n_batch - 1 ) / n_batch ;
const int nv = 2 * ( ( n_vocab + 1 ) / 2 ) + 4 ;
const bool add_bos = llama_should_add_bos_token ( llama_get_model ( ctx ) ) ;
std : : vector < uint16_t > log_probs_uint16 ( size_t ( n_ctx - 1 - n_ctx / 2 ) * nv ) ;
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std : : vector < float > kld_values ( size_t ( n_ctx - 1 - n_ctx / 2 ) * n_chunk ) ;
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std : : vector < float > logits ;
if ( num_batches > 1 ) {
logits . reserve ( n_ctx * n_vocab ) ;
}
std : : vector < std : : thread > workers ( std : : thread : : hardware_concurrency ( ) - 1 ) ;
auto mean_and_uncertainty = [ ] ( double sum , double sum2 , size_t count ) {
if ( count < 1 ) {
return std : : make_pair ( 0. , 0. ) ;
}
double f = sum / count ;
double df = sum2 / count - f * f ;
df = df > 0 & & count > 10 ? sqrt ( df / ( count - 1 ) ) : 0. ;
return std : : make_pair ( f , df ) ;
} ;
kl_divergence_result kld ;
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auto kld_ptr = kld_values . data ( ) ;
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for ( int i = 0 ; i < n_chunk ; + + i ) {
const int start = i * n_ctx ;
const int end = start + n_ctx ;
const auto t_start = std : : chrono : : high_resolution_clock : : now ( ) ;
if ( in . read ( ( char * ) log_probs_uint16 . data ( ) , log_probs_uint16 . size ( ) * sizeof ( uint16_t ) ) . fail ( ) ) {
fprintf ( stderr , " %s: failed reading log-probs for chunk %d \n " , __func__ , i ) ;
return ;
}
// clear the KV cache
llama_kv_cache_clear ( ctx ) ;
for ( int j = 0 ; j < num_batches ; + + j ) {
const int batch_start = start + j * n_batch ;
const int batch_size = std : : min ( end - batch_start , n_batch ) ;
// save original token and restore it after eval
const auto token_org = tokens [ batch_start ] ;
// add BOS token for the first batch of each chunk
if ( add_bos & & j = = 0 ) {
tokens [ batch_start ] = llama_token_bos ( llama_get_model ( ctx ) ) ;
}
if ( llama_decode ( ctx , llama_batch_get_one ( tokens . data ( ) + batch_start , batch_size , j * n_batch , 0 ) ) ) {
fprintf ( stderr , " %s : failed to eval \n " , __func__ ) ;
return ;
}
// restore the original token in case it was set to BOS
tokens [ batch_start ] = token_org ;
if ( num_batches > 1 ) {
const auto * batch_logits = llama_get_logits ( ctx ) ;
logits . insert ( logits . end ( ) , batch_logits , batch_logits + batch_size * n_vocab ) ;
}
}
const auto t_end = std : : chrono : : high_resolution_clock : : now ( ) ;
if ( i = = 0 ) {
const float t_total = std : : chrono : : duration < float > ( t_end - t_start ) . count ( ) ;
fprintf ( stderr , " %s: %.2f seconds per pass - ETA " , __func__ , t_total ) ;
int total_seconds = ( int ) ( t_total * n_chunk ) ;
if ( total_seconds > = 60 * 60 ) {
fprintf ( stderr , " %d hours " , total_seconds / ( 60 * 60 ) ) ;
total_seconds = total_seconds % ( 60 * 60 ) ;
}
fprintf ( stderr , " %.2f minutes \n " , total_seconds / 60.0 ) ;
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printf ( " \n chunk PPL ln(PPL(Q)/PPL(base)) KL-Divergence Same top \n " ) ;
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}
const int first = n_ctx / 2 ;
const float * all_logits = num_batches > 1 ? logits . data ( ) : llama_get_logits ( ctx ) ;
process_logits ( n_vocab , all_logits + first * n_vocab , tokens . data ( ) + start + first , n_ctx - 1 - first ,
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workers , log_probs_uint16 , kld , kld_ptr ) ;
kld_ptr + = n_ctx - 1 - first ;
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auto ppl = mean_and_uncertainty ( kld . sum_nll , kld . sum_nll2 , kld . count ) ;
auto log_ppl_ratio = mean_and_uncertainty ( kld . sum_nll_diff , kld . sum_nll_diff2 , kld . count ) ;
auto kl_div = mean_and_uncertainty ( kld . sum_kld , kld . sum_kld2 , kld . count ) ;
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auto p_top = 1. * kld . n_same_top / kld . count ;
auto d_p_top = sqrt ( p_top * ( 1 - p_top ) / ( kld . count - 1 ) ) ;
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printf ( " %4d %10.4lf %10.5lf ± %10.5f %10.5f ± %10.5lf %.5f ± %.5f \n " , i + 1 , exp ( ppl . first ) ,
log_ppl_ratio . first , log_ppl_ratio . second , kl_div . first , kl_div . second ,
p_top , d_p_top ) ;
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fflush ( stdout ) ;
logits . clear ( ) ;
}
printf ( " \n " ) ;
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if ( kld . count < 100 ) return ; // we do not wish to do statistics on so few values
std : : sort ( kld_values . begin ( ) , kld_values . end ( ) ) ;
printf ( " ===== KL-divergence statistics \n " ) ;
auto kl_div = mean_and_uncertainty ( kld . sum_kld , kld . sum_kld2 , kld . count ) ;
printf ( " Average: %10.6f ±%10.6lf \n " , kl_div . first , kl_div . second ) ;
auto kld_median = kld_values . size ( ) % 2 = = 0 ? 0.5f * ( kld_values [ kld_values . size ( ) / 2 ] + kld_values [ kld_values . size ( ) / 2 - 1 ] )
: kld_values [ kld_values . size ( ) / 2 ] ;
printf ( " Median : %10.6f \n " , kld_median ) ;
auto percentile = [ & kld_values ] ( float fraction ) {
if ( fraction < = 0 ) return kld_values . front ( ) ;
if ( fraction > = 1 ) return kld_values . back ( ) ;
float p = fraction * ( kld_values . size ( ) - 1 ) ;
size_t ip = size_t ( p ) ; p - = ip ;
return ( 1 - p ) * kld_values [ ip ] + p * kld_values [ std : : min ( ip + 1 , kld_values . size ( ) - 1 ) ] ;
} ;
printf ( " Maximum: %10.6f \n " , kld_values . back ( ) ) ;
printf ( " KLD_99 : %10.6f \n " , percentile ( 0.99f ) ) ;
printf ( " KLD_95 : %10.6f \n " , percentile ( 0.95f ) ) ;
printf ( " KLD_90 : %10.6f \n " , percentile ( 0.90f ) ) ;
printf ( " Minimum: %10.6f \n " , kld_values . front ( ) ) ;
printf ( " KLD_01 : %10.6f \n " , percentile ( 0.01f ) ) ;
printf ( " KLD_05 : %10.6f \n " , percentile ( 0.05f ) ) ;
printf ( " KLD_10 : %10.6f \n " , percentile ( 0.10f ) ) ;
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}
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int main ( int argc , char * * argv ) {
gpt_params params ;
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params . n_batch = 512 ;
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if ( ! gpt_params_parse ( argc , argv , params ) ) {
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return 1 ;
}
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params . logits_all = true ;
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params . n_batch = std : : min ( params . n_batch , params . n_ctx ) ;
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if ( params . ppl_stride > 0 ) {
fprintf ( stderr , " Will perform strided perplexity calculation -> adjusting context size from %d to %d \n " ,
params . n_ctx , params . n_ctx + params . ppl_stride / 2 ) ;
params . n_ctx + = params . ppl_stride / 2 ;
}
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print_build_info ( ) ;
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if ( params . seed = = LLAMA_DEFAULT_SEED ) {
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params . seed = time ( NULL ) ;
}
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fprintf ( stderr , " %s: seed = %u \n " , __func__ , params . seed ) ;
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std : : mt19937 rng ( params . seed ) ;
if ( params . random_prompt ) {
params . prompt = gpt_random_prompt ( rng ) ;
}
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llama_backend_init ( params . numa ) ;
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llama_model * model ;
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llama_context * ctx ;
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// load the model and apply lora adapter, if any
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std : : tie ( model , ctx ) = llama_init_from_gpt_params ( params ) ;
if ( model = = NULL ) {
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fprintf ( stderr , " %s: error: unable to load model \n " , __func__ ) ;
return 1 ;
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}
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const int n_ctx_train = llama_n_ctx_train ( model ) ;
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if ( params . n_ctx > n_ctx_train ) {
fprintf ( stderr , " %s: warning: model was trained on only %d context tokens (%d specified) \n " ,
__func__ , n_ctx_train , params . n_ctx ) ;
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}
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// print system information
{
fprintf ( stderr , " \n " ) ;
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fprintf ( stderr , " %s \n " , get_system_info ( params ) . c_str ( ) ) ;
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}
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struct results_perplexity results ;
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if ( params . hellaswag ) {
hellaswag_score ( ctx , params ) ;
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} else if ( params . winogrande ) {
winogrande_score ( ctx , params ) ;
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} else if ( params . multiple_choice ) {
multiple_choice_score ( ctx , params ) ;
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} else if ( params . kl_divergence ) {
kl_divergence ( ctx , params ) ;
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} else {
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results = perplexity ( ctx , params ) ;
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}
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llama_print_timings ( ctx ) ;
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write_logfile ( ctx , params , model , results ) ;
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llama_free ( ctx ) ;
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llama_free_model ( model ) ;
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llama_backend_free ( ) ;
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return 0 ;
}