/* See LICENSE file for copyright and license details. */
#include "libgamma-facade.hh"
#include "libgamma-error.hh"
#include <cstdlib>
namespace libgamma
{
/**
* List available adjustment methods by their order of preference based on the environment.
*
* @param operation Allowed values:
* 0: Methods that the environment suggests will work, excluding fake.
* 1: Methods that the environment suggests will work, including fake.
* 2: All real non-fake methods.
* 3: All real methods.
* 4: All methods.
* Other values invoke undefined behaviour.
* @return Array of methods.
*/
std::vector<int> list_methods(int operation)
{
int* methods = (int*)malloc(LIBGAMMA_METHOD_COUNT * sizeof(int));
size_t n, i;
std::vector<int> rc;
n = libgamma_list_methods(methods, LIBGAMMA_METHOD_COUNT, operation);
if (n > LIBGAMMA_METHOD_COUNT)
{
free(methods);
methods = (int*)malloc(n * sizeof(int));
libgamma_list_methods(methods, n, operation);
}
for (i = 0; i < n; i++)
rc.push_back(methods[i]);
free(methods);
return rc;
}
/**
* Check whether an adjustment method is available, non-existing (invalid) methods will be
* identified as not available under the rationale that the library may be out of date.
*
* @param method The adjustment method.
* @return Whether the adjustment method is available.
*/
int is_method_available(int method)
{
return libgamma_is_method_available(method);
}
/**
* Return the capabilities of an adjustment method.
*
* @param output The data structure to fill with the method's capabilities,
* @param method The adjustment method (display server and protocol).
*/
void method_capabilities(MethodCapabilities* output, int method)
{
libgamma_method_capabilities_t caps;
libgamma_method_capabilities(&caps, method);
*output = MethodCapabilities(&caps);
}
/**
* Return the default site for an adjustment method.
*
* @param method The adjustment method (display server and protocol.)
* @return The default site, `nullptr` if it cannot be determined or if
* multiple sites are not supported by the adjustment method.
*/
std::string* method_default_site(int method)
{
char* cstr = libgamma_method_default_site(method);
if (cstr == nullptr)
return nullptr;
return new std::string(cstr);
}
/**
* Return the default variable that determines
* the default site for an adjustment method.
*
* @param method The adjustment method (display server and protocol.)
* @return The environ variables that is used to determine the
* default site. `nullptr` if there is none, that is, if
* the method does not support multiple sites.
* This value should not be `free`:d.
*/
std::string* method_default_site_variable(int method)
{
const char* cstr = libgamma_method_default_site_variable(method);
if (cstr == nullptr)
return nullptr;
return new std::string(cstr);
}
/**
* Convert a raw representation of an EDID to a lowercase hexadecimal representation.
*
* @param edid The EDID in raw representation.
* @param length The length of `edid`.
* @return The EDID in lowercase hexadecimal representation.
*/
std::string behex_edid(const unsigned char* edid, size_t length)
{
return behex_edid_lowercase(edid, length);
}
/**
* Convert a raw representation of an EDID to a lowercase hexadecimal representation.
*
* @param edid The EDID in raw representation.
* @param length The length of `edid`.
* @return The EDID in lowercase hexadecimal representation.
*/
std::string behex_edid_lowercase(const unsigned char* edid, size_t length)
{
char* cstr = libgamma_behex_edid_lowercase(edid, length);
std::string rc = std::string(cstr);
free(cstr);
return rc;
}
/**
* Convert a raw representation of an EDID to an uppercase hexadecimal representation.
*
* @param edid The EDID in raw representation.
* @param length The length of `edid`.
* @return The EDID in uppercase hexadecimal representation.
*/
std::string behex_edid_uppercase(const unsigned char* edid, size_t length)
{
char* cstr = libgamma_behex_edid_uppercase(edid, length);
std::string rc = std::string(cstr);
free(cstr);
return rc;
}
/**
* Convert an hexadecimal representation of an EDID to a raw representation.
*
* @param edid The EDID in hexadecimal representation.
* @return The EDID in raw representation, it will be half the length
* of `edid` (the input value).
*/
unsigned char* unhex_edid(const std::string edid)
{
const char* cstr = edid.c_str();
return libgamma_unhex_edid(cstr);
}
/**
* Initialise a gamma ramp in the proper way that allows all adjustment
* methods to read from and write to it without causing segmentation violation.
*
* @param ramps The gamma ramp to initialise.
* @param red The size of the gamma ramp for the red channel.
* @param green The size of the gamma ramp for the green channel.
* @param blue The size of the gamma ramp for the blue channel.
*/
void gamma_ramps8_initialise(GammaRamps<uint8_t>* ramps, size_t red, size_t blue, size_t green)
{
libgamma_gamma_ramps8_t native;
int r;
native.red_size = ramps->red.size = red;
native.green_size = ramps->green.size = green;
native.blue_size = ramps->blue.size = blue;
ramps->depth = 8;
r = libgamma_gamma_ramps8_initialise(&native);
if (r != 0)
throw create_error(r);
ramps->red.ramp = native.red;
ramps->green.ramp = native.green;
ramps->blue.ramp = native.blue;
}
/**
* Initialise a gamma ramp in the proper way that allows all adjustment
* methods to read from and write to it without causing segmentation violation.
*
* @param ramps The gamma ramp to initialise.
* @param red The size of the gamma ramp for the red channel.
* @param green The size of the gamma ramp for the green channel.
* @param blue The size of the gamma ramp for the blue channel.
*/
void gamma_ramps16_initialise(GammaRamps<uint16_t>* ramps, size_t red, size_t blue, size_t green)
{
libgamma_gamma_ramps16_t native;
int r;
native.red_size = ramps->red.size = red;
native.green_size = ramps->green.size = green;
native.blue_size = ramps->blue.size = blue;
ramps->depth = 16;
r = libgamma_gamma_ramps16_initialise(&native);
if (r != 0)
throw create_error(r);
ramps->red.ramp = native.red;
ramps->green.ramp = native.green;
ramps->blue.ramp = native.blue;
}
/**
* Initialise a gamma ramp in the proper way that allows all adjustment
* methods to read from and write to it without causing segmentation violation.
*
* @param ramps The gamma ramp to initialise.
* @param red The size of the gamma ramp for the red channel.
* @param green The size of the gamma ramp for the green channel.
* @param blue The size of the gamma ramp for the blue channel.
*/
void gamma_ramps32_initialise(GammaRamps<uint32_t>* ramps, size_t red, size_t blue, size_t green)
{
libgamma_gamma_ramps32_t native;
int r;
native.red_size = ramps->red.size = red;
native.green_size = ramps->green.size = green;
native.blue_size = ramps->blue.size = blue;
ramps->depth = 32;
r = libgamma_gamma_ramps32_initialise(&native);
if (r != 0)
throw create_error(r);
ramps->red.ramp = native.red;
ramps->green.ramp = native.green;
ramps->blue.ramp = native.blue;
}
/**
* Initialise a gamma ramp in the proper way that allows all adjustment
* methods to read from and write to it without causing segmentation violation.
*
* @param ramps The gamma ramp to initialise.
* @param red The size of the gamma ramp for the red channel.
* @param green The size of the gamma ramp for the green channel.
* @param blue The size of the gamma ramp for the blue channel.
*/
void gamma_ramps64_initialise(GammaRamps<uint64_t>* ramps, size_t red, size_t blue, size_t green)
{
libgamma_gamma_ramps64_t native;
int r;
native.red_size = ramps->red.size = red;
native.green_size = ramps->green.size = green;
native.blue_size = ramps->blue.size = blue;
ramps->depth = 64;
r = libgamma_gamma_ramps64_initialise(&native);
if (r != 0)
throw create_error(r);
ramps->red.ramp = native.red;
ramps->green.ramp = native.green;
ramps->blue.ramp = native.blue;
}
/**
* Initialise a gamma ramp in the proper way that allows all adjustment
* methods to read from and write to it without causing segmentation violation.
*
* @param ramps The gamma ramp to initialise.
* @param red The size of the gamma ramp for the red channel.
* @param green The size of the gamma ramp for the green channel.
* @param blue The size of the gamma ramp for the blue channel.
*/
void gamma_rampsf_initialise(GammaRamps<float>* ramps, size_t red, size_t blue, size_t green)
{
libgamma_gamma_rampsf_t native;
int r;
native.red_size = ramps->red.size = red;
native.green_size = ramps->green.size = green;
native.blue_size = ramps->blue.size = blue;
ramps->depth = -1;
r = libgamma_gamma_rampsf_initialise(&native);
if (r != 0)
throw create_error(r);
ramps->red.ramp = native.red;
ramps->green.ramp = native.green;
ramps->blue.ramp = native.blue;
}
/**
* Initialise a gamma ramp in the proper way that allows all adjustment
* methods to read from and write to it without causing segmentation violation.
*
* @param ramps The gamma ramp to initialise.
* @param red The size of the gamma ramp for the red channel.
* @param green The size of the gamma ramp for the green channel.
* @param blue The size of the gamma ramp for the blue channel.
*/
void gamma_rampsd_initialise(GammaRamps<double>* ramps, size_t red, size_t blue, size_t green)
{
libgamma_gamma_rampsd_t native;
int r;
native.red_size = ramps->red.size = red;
native.green_size = ramps->green.size = green;
native.blue_size = ramps->blue.size = blue;
ramps->depth = -2;
r = libgamma_gamma_rampsd_initialise(&native);
if (r != 0)
throw create_error(r);
ramps->red.ramp = native.red;
ramps->green.ramp = native.green;
ramps->blue.ramp = native.blue;
}
/**
* Create a gamma ramp in the proper way that allows all adjustment
* methods to read from and write to it without causing segmentation violation.
*
* @param red The size of the gamma ramp for the red channel.
* @param green The size of the gamma ramp for the green channel.
* @param blue The size of the gamma ramp for the blue channel.
* @return The gamma ramp.
*/
GammaRamps<uint8_t>* gamma_ramps8_create(size_t red, size_t blue, size_t green)
{
libgamma_gamma_ramps8_t ramps;
int r;
ramps.red_size = red;
ramps.green_size = green;
ramps.blue_size = blue;
r = libgamma_gamma_ramps8_initialise(&ramps);
if (r != 0)
throw create_error(r);
return new GammaRamps<uint8_t>(ramps.red, ramps.green, ramps.blue, red, green, blue, 8);
}
/**
* Create a gamma ramp in the proper way that allows all adjustment
* methods to read from and write to it without causing segmentation violation.
*
* @param red The size of the gamma ramp for the red channel.
* @param green The size of the gamma ramp for the green channel.
* @param blue The size of the gamma ramp for the blue channel.
* @return The gamma ramp.
*/
GammaRamps<uint16_t>* gamma_ramps16_create(size_t red, size_t blue, size_t green)
{
libgamma_gamma_ramps16_t ramps;
int r;
ramps.red_size = red;
ramps.green_size = green;
ramps.blue_size = blue;
r = libgamma_gamma_ramps16_initialise(&ramps);
if (r != 0)
throw create_error(r);
return new GammaRamps<uint16_t>(ramps.red, ramps.green, ramps.blue, red, green, blue, 16);
}
/**
* Create a gamma ramp in the proper way that allows all adjustment
* methods to read from and write to it without causing segmentation violation.
*
* @param red The size of the gamma ramp for the red channel.
* @param green The size of the gamma ramp for the green channel.
* @param blue The size of the gamma ramp for the blue channel.
* @return The gamma ramp.
*/
GammaRamps<uint32_t>* gamma_ramps32_create(size_t red, size_t blue, size_t green)
{
libgamma_gamma_ramps32_t ramps;
int r;
ramps.red_size = red;
ramps.green_size = green;
ramps.blue_size = blue;
r = libgamma_gamma_ramps32_initialise(&ramps);
if (r != 0)
throw create_error(r);
return new GammaRamps<uint32_t>(ramps.red, ramps.green, ramps.blue, red, green, blue, 32);
}
/**
* Create a gamma ramp in the proper way that allows all adjustment
* methods to read from and write to it without causing segmentation violation.
*
* @param red The size of the gamma ramp for the red channel.
* @param green The size of the gamma ramp for the green channel.
* @param blue The size of the gamma ramp for the blue channel.
* @return The gamma ramp.
*/
GammaRamps<uint64_t>* gamma_ramps64_create(size_t red, size_t blue, size_t green)
{
libgamma_gamma_ramps64_t ramps;
int r;
ramps.red_size = red;
ramps.green_size = green;
ramps.blue_size = blue;
r = libgamma_gamma_ramps64_initialise(&ramps);
if (r != 0)
throw create_error(r);
return new GammaRamps<uint64_t>(ramps.red, ramps.green, ramps.blue, red, green, blue, 64);
}
/**
* Create a gamma ramp in the proper way that allows all adjustment
* methods to read from and write to it without causing segmentation violation.
*
* @param red The size of the gamma ramp for the red channel.
* @param green The size of the gamma ramp for the green channel.
* @param blue The size of the gamma ramp for the blue channel.
* @return The gamma ramp.
*/
GammaRamps<float>* gamma_rampsf_create(size_t red, size_t blue, size_t green)
{
libgamma_gamma_rampsf_t ramps;
int r;
ramps.red_size = red;
ramps.green_size = green;
ramps.blue_size = blue;
r = libgamma_gamma_rampsf_initialise(&ramps);
if (r != 0)
throw create_error(r);
return new GammaRamps<float>(ramps.red, ramps.green, ramps.blue, red, green, blue, -1);
}
/**
* Create a gamma ramp in the proper way that allows all adjustment
* methods to read from and write to it without causing segmentation violation.
*
* @param red The size of the gamma ramp for the red channel.
* @param green The size of the gamma ramp for the green channel.
* @param blue The size of the gamma ramp for the blue channel.
* @return The gamma ramp.
*/
GammaRamps<double>* gamma_rampsd_create(size_t red, size_t blue, size_t green)
{
libgamma_gamma_rampsd_t ramps;
int r;
ramps.red_size = red;
ramps.green_size = green;
ramps.blue_size = blue;
r = libgamma_gamma_rampsd_initialise(&ramps);
if (r != 0)
throw create_error(r);
return new GammaRamps<double>(ramps.red, ramps.green, ramps.blue, red, green, blue, -2);
}
}