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钟尚武
dlib
Commits
fc6cce9f
Commit
fc6cce9f
authored
Nov 25, 2017
by
Davis King
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Plain Diff
Made find_max_global() automatically apply a log-scale transform to variables
that obviously need it.
parent
99621934
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Showing
2 changed files
with
67 additions
and
3 deletions
+67
-3
find_max_global.h
dlib/global_optimization/find_max_global.h
+43
-3
find_max_global_abstract.h
dlib/global_optimization/find_max_global_abstract.h
+24
-0
No files found.
dlib/global_optimization/find_max_global.h
View file @
fc6cce9f
...
@@ -117,21 +117,55 @@ template <typename T> static auto go(T&& f, const matrix<double, 0, 1>& a) -> de
...
@@ -117,21 +117,55 @@ template <typename T> static auto go(T&& f, const matrix<double, 0, 1>& a) -> de
>
>
std
::
pair
<
size_t
,
function_evaluation
>
find_max_global
(
std
::
pair
<
size_t
,
function_evaluation
>
find_max_global
(
std
::
vector
<
funct
>&
functions
,
std
::
vector
<
funct
>&
functions
,
const
std
::
vector
<
function_spec
>&
specs
,
std
::
vector
<
function_spec
>
specs
,
const
max_function_calls
num
,
const
max_function_calls
num
,
const
std
::
chrono
::
nanoseconds
max_runtime
=
FOREVER
,
const
std
::
chrono
::
nanoseconds
max_runtime
=
FOREVER
,
double
solver_epsilon
=
1e-11
double
solver_epsilon
=
1e-11
)
)
{
{
// Decide which parameters should be searched on a log scale. Basically, it's
// common for machine learning models to have parameters that should be searched on
// a log scale (e.g. SVM C). These parameters are usually identifiable because
// they have bounds like [1e-5 1e10], that is, they span a very large range of
// magnitudes from really small to really big. So there we are going to check for
// that and if we find parameters with that kind of bound constraints we will
// transform them to a log scale automatically.
std
::
vector
<
std
::
vector
<
bool
>>
log_scale
(
specs
.
size
());
for
(
size_t
i
=
0
;
i
<
specs
.
size
();
++
i
)
{
for
(
long
j
=
0
;
j
<
specs
[
i
].
lower
.
size
();
++
j
)
{
if
(
!
specs
[
i
].
is_integer_variable
[
j
]
&&
specs
[
i
].
lower
(
j
)
>
0
&&
specs
[
i
].
upper
(
j
)
/
specs
[
i
].
lower
(
j
)
>
1000
)
{
log_scale
[
i
].
push_back
(
true
);
specs
[
i
].
lower
(
j
)
=
std
::
log
(
specs
[
i
].
lower
(
j
));
specs
[
i
].
upper
(
j
)
=
std
::
log
(
specs
[
i
].
upper
(
j
));
}
else
{
log_scale
[
i
].
push_back
(
false
);
}
}
}
global_function_search
opt
(
specs
);
global_function_search
opt
(
specs
);
opt
.
set_solver_epsilon
(
solver_epsilon
);
opt
.
set_solver_epsilon
(
solver_epsilon
);
const
auto
time_to_stop
=
std
::
chrono
::
steady_clock
::
now
()
+
max_runtime
;
const
auto
time_to_stop
=
std
::
chrono
::
steady_clock
::
now
()
+
max_runtime
;
// Now run the main solver loop.
for
(
size_t
i
=
0
;
i
<
num
.
max_calls
&&
std
::
chrono
::
steady_clock
::
now
()
<
time_to_stop
;
++
i
)
for
(
size_t
i
=
0
;
i
<
num
.
max_calls
&&
std
::
chrono
::
steady_clock
::
now
()
<
time_to_stop
;
++
i
)
{
{
auto
next
=
opt
.
get_next_x
();
auto
next
=
opt
.
get_next_x
();
double
y
=
call_function_and_expand_args
(
functions
[
next
.
function_idx
()],
next
.
x
());
matrix
<
double
,
0
,
1
>
x
=
next
.
x
();
// Undo any log-scaling that was applied to the variables before we pass them
// to the functions being optimized.
for
(
long
j
=
0
;
j
<
x
.
size
();
++
j
)
{
if
(
log_scale
[
next
.
function_idx
()][
j
])
x
(
j
)
=
std
::
exp
(
x
(
j
));
}
double
y
=
call_function_and_expand_args
(
functions
[
next
.
function_idx
()],
x
);
next
.
set
(
y
);
next
.
set
(
y
);
}
}
...
@@ -140,6 +174,12 @@ template <typename T> static auto go(T&& f, const matrix<double, 0, 1>& a) -> de
...
@@ -140,6 +174,12 @@ template <typename T> static auto go(T&& f, const matrix<double, 0, 1>& a) -> de
double
y
;
double
y
;
size_t
function_idx
;
size_t
function_idx
;
opt
.
get_best_function_eval
(
x
,
y
,
function_idx
);
opt
.
get_best_function_eval
(
x
,
y
,
function_idx
);
// Undo any log-scaling that was applied to the variables before we output them.
for
(
long
j
=
0
;
j
<
x
.
size
();
++
j
)
{
if
(
log_scale
[
function_idx
][
j
])
x
(
j
)
=
std
::
exp
(
x
(
j
));
}
return
std
::
make_pair
(
function_idx
,
function_evaluation
(
x
,
std
::
move
(
y
)));
return
std
::
make_pair
(
function_idx
,
function_evaluation
(
x
,
std
::
move
(
y
)));
}
}
...
@@ -160,7 +200,7 @@ template <typename T> static auto go(T&& f, const matrix<double, 0, 1>& a) -> de
...
@@ -160,7 +200,7 @@ template <typename T> static auto go(T&& f, const matrix<double, 0, 1>& a) -> de
{
{
std
::
vector
<
funct
>
functions
(
1
,
std
::
move
(
f
));
std
::
vector
<
funct
>
functions
(
1
,
std
::
move
(
f
));
std
::
vector
<
function_spec
>
specs
(
1
,
function_spec
(
bound1
,
bound2
,
is_integer_variable
));
std
::
vector
<
function_spec
>
specs
(
1
,
function_spec
(
bound1
,
bound2
,
is_integer_variable
));
return
find_max_global
(
functions
,
s
pecs
,
num
,
max_runtime
,
solver_epsilon
).
second
;
return
find_max_global
(
functions
,
s
td
::
move
(
specs
)
,
num
,
max_runtime
,
solver_epsilon
).
second
;
}
}
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
...
...
dlib/global_optimization/find_max_global_abstract.h
View file @
fc6cce9f
...
@@ -118,6 +118,18 @@ namespace dlib
...
@@ -118,6 +118,18 @@ namespace dlib
- find_max_global() runs until one of the following is true:
- find_max_global() runs until one of the following is true:
- The total number of calls to the provided functions is == num.max_calls
- The total number of calls to the provided functions is == num.max_calls
- More than max_runtime time has elapsed since the start of this function.
- More than max_runtime time has elapsed since the start of this function.
- Any variables that satisfy the following conditions are optimized on a log-scale:
- The lower bound on the variable is > 0
- The ratio of the upper bound to lower bound is > 1000
- The variable is not an integer variable
We do this because it's common to optimize machine learning models that have
parameters with bounds in a range such as [1e-5 to 1e10] (e.g. the SVM C
parameter) and it's much more appropriate to optimize these kinds of
variables on a log scale. So we transform them by applying std::log() to
them and then undo the transform via std::exp() before invoking the function
being optimized. Therefore, this transformation is invisible to the user
supplied functions. In most cases, it improves the efficiency of the
optimizer.
!*/
!*/
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
...
@@ -170,6 +182,18 @@ namespace dlib
...
@@ -170,6 +182,18 @@ namespace dlib
- find_max_global() runs until one of the following is true:
- find_max_global() runs until one of the following is true:
- The total number of calls to f() is == num.max_calls
- The total number of calls to f() is == num.max_calls
- More than max_runtime time has elapsed since the start of this function.
- More than max_runtime time has elapsed since the start of this function.
- Any variables that satisfy the following conditions are optimized on a log-scale:
- The lower bound on the variable is > 0
- The ratio of the upper bound to lower bound is > 1000
- The variable is not an integer variable
We do this because it's common to optimize machine learning models that have
parameters with bounds in a range such as [1e-5 to 1e10] (e.g. the SVM C
parameter) and it's much more appropriate to optimize these kinds of
variables on a log scale. So we transform them by applying std::log() to
them and then undo the transform via std::exp() before invoking the function
being optimized. Therefore, this transformation is invisible to the user
supplied functions. In most cases, it improves the efficiency of the
optimizer.
!*/
!*/
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
...
...
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