/**
* libgammamm -- C++ wrapper for libgamma
* Copyright (C) 2014 Mattias Andrée (maandree@member.fsf.org)
*
* This library is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this library. If not, see .
*/
#ifndef LIBGAMMA_METHOD_HH
#define LIBGAMMA_METHOD_HH
#include
#include
#include "libgamma-native.hh"
#include "libgamma-error.hh"
#ifndef __GCC__
# define __attribute__(X) /* emtpy */
#endif
namespace libgamma
{
/**
* Cathode ray tube controller information data structure.
*/
class CRTCInformation;
/**
* Capabilities of adjustment methods.
*/
class MethodCapabilities;
/**
* Site state.
*
* On operating systems that integrate a graphical environment
* there is usually just one site. However, one systems with
* pluggable graphics, like Unix-like systems such as GNU/Linux
* and the BSD:s, there can usually be any (feasible) number of
* sites. In X.org parlance they are called displays.
*/
class Site;
/**
* Partition state.
*
* Probably the majority of display server only one partition
* per site. However, X.org can, and traditional used to have
* on multi-headed environments, multiple partitions per site.
* In X.org partitions are called 'screens'. It is not to be
* confused with monitor. A screen is a collection of monitors,
* and the mapping from monitors to screens is a surjection.
* On hardware-level adjustment methods, such as Direct
* Rendering Manager, a partition is a graphics card.
*/
class Partition;
/**
* Cathode ray tube controller state.
*
* The CRTC controls the gamma ramps for the
* monitor that is plugged in to the connector
* that the CRTC belongs to.
*/
class CRTC;
/**
* Capabilities of adjustment methods.
*/
class MethodCapabilities
{
public:
/**
* Constructor.
*/
MethodCapabilities();
/**
* Constructor.
*
* @param caps The information in the native structure.
*/
MethodCapabilities(libgamma_method_capabilities_t* caps);
/**
* Copy constructor.
*
* @param other The information to copy.
*/
MethodCapabilities(const MethodCapabilities& other);
/**
* Destructor.
*/
~MethodCapabilities() __attribute__((const));
/**
* Copy operator.
*
* @param other The information to copy.
*/
MethodCapabilities& operator =(const MethodCapabilities& other);
/**
* OR of the CRTC information fields in `libgamma_crtc_information_t`
* that may (but can fail) be read successfully.
*/
int32_t crtc_information;
/**
* Whether the default site is known, if true the site is integrated
* to the system or can be determined using environment variables.
*/
bool default_site_known;
/**
* Whether the adjustment method supports multiple sites rather
* than just the default site.
*/
bool multiple_sites;
/**
* Whether the adjustment method supports multiple partitions
* per site.
*/
bool multiple_partitions;
/**
* Whether the adjustment method supports multiple CRTC:s
* per partition per site.
*/
bool multiple_crtcs;
/**
* Whether the partition to graphics card is a bijection.
*/
bool partitions_are_graphics_cards;
/**
* Whether the adjustment method supports `libgamma_site_restore`.
*/
bool site_restore;
/**
* Whether the adjustment method supports `libgamma_partition_restore`.
*/
bool partition_restore;
/**
* Whether the adjustment method supports `libgamma_crtc_restore`.
*/
bool crtc_restore;
/**
* Whether the `red_gamma_size`, `green_gamma_size` and `blue_gamma_size`
* fields in `libgamma_crtc_information_t` will always have the same
* values as each other for the adjustment method.
*/
bool identical_gamma_sizes;
/**
* Whether the `red_gamma_size`, `green_gamma_size` and `blue_gamma_size`
* fields in `libgamma_crtc_information_t` will always be filled with the
* same value for the adjustment method.
*/
bool fixed_gamma_size;
/**
* Whether the `gamma_depth` field in `libgamma_crtc_information_t`
* will always be filled with the same value for the adjustment method.
*/
bool fixed_gamma_depth;
/**
* Whether the adjustment method will actually perform adjustments.
*/
bool real;
/**
* Whether the adjustment method is implement using a translation layer.
*/
bool fake;
};
/**
* Types for connectors.
*/
typedef libgamma_connector_type_t ConnectorType;
/**
* Orders for subpixels. Currently the possible values are
* very biased to LCD, Plasma and monochrome monitors.
*/
typedef libgamma_subpixel_order_t SubpixelOrder;
/**
* Cathode ray tube controller information data structure.
*/
class CRTCInformation
{
public:
/**
* Constructor.
*/
CRTCInformation();
/**
* Constructor.
*
* @param info The information in the native structure.
*/
CRTCInformation(libgamma_crtc_information_t* info);
/**
* Copy constructor.
*
* @param other The information to copy.
*/
CRTCInformation(const CRTCInformation& other);
/**
* Destructor.
*/
~CRTCInformation();
/**
* Copy operator.
*
* @param other The information to copy.
*/
CRTCInformation& operator =(const CRTCInformation& other);
/**
* The Extended Display Identification Data associated with
* the attached monitor. This is raw byte array that is usually
* 128 bytes long. It is not NUL-terminate, rather its length
* is stored in `edid_length`.
*/
unsigned char* edid;
/**
* The length of `edid`.
*/
size_t edid_length;
/**
* Zero on success, positive it holds the value `errno` had
* when the reading failed, otherwise (negative) the value
* of an error identifier provided by this library.
*/
int edid_error;
/**
* The phyical width, in millimetres, of the viewport of the
* attached monitor, as reported by the adjustment method. This
* value may be incorrect, which is a known issue with the X
* server where it is the result of the X server attempting
* the estimate the size on its own.
* Zero means that its is not applicable, which is the case
* for projectors.
*/
size_t width_mm;
/**
* Zero on success, positive it holds the value `errno` had
* when the reading failed, otherwise (negative) the value
* of an error identifier provided by this library.
*/
int width_mm_error;
/**
* The phyical height, in millimetres, of the viewport of the
* attached monitor, as reported by the adjustment method. This
* value may be incorrect, which is a known issue with the X
* server where it is the result of the X server attempting
* the estimate the size on its own.
* Zero means that its is not applicable, which is the case
* for projectors.
*/
size_t height_mm;
/**
* Zero on success, positive it holds the value `errno` had
* when the reading failed, otherwise (negative) the value
* of an error identifier provided by this library.
*/
int height_mm_error;
/**
* The phyical width, in millimetres, of the viewport of the
* attached monitor, as reported by it the monitor's Extended
* Display Information Data. This value can only contain whole
* centimetres, which means that the result is always zero
* modulus ten. However, this could change with revisions of
* the EDID structure.
* Zero means that its is not applicable, which is the case
* for projectors.
*/
size_t width_mm_edid;
/**
* Zero on success, positive it holds the value `errno` had
* when the reading failed, otherwise (negative) the value
* of an error identifier provided by this library.
*/
int width_mm_edid_error;
/**
* The phyical height, in millimetres, of the viewport of the
* attached monitor, as reported by it the monitor's Extended
* Display Information Data. This value can only contain whole
* centimetres, which means that the result is always zero
* modulus ten. However, this could change with revisions of
* the EDID structure.
* Zero means that its is not applicable, which is the case
* for projectors.
*/
size_t height_mm_edid;
/**
* Zero on success, positive it holds the value `errno` had
* when the reading failed, otherwise (negative) the value
* of an error identifier provided by this library.
*/
int height_mm_edid_error;
/**
* The size of the encoding axis of the red gamma ramp.
*/
size_t red_gamma_size;
/**
* The size of the encoding axis of the green gamma ramp.
*/
size_t green_gamma_size;
/**
* The size of the encoding axis of the blue gamma ramp.
*/
size_t blue_gamma_size;
/**
* Zero on success, positive it holds the value `errno` had
* when the reading failed, otherwise (negative) the value
* of an error identifier provided by this library.
*/
int gamma_size_error;
/**
* The bit-depth of the value axes of gamma ramps,
* -1 for single precision floating point, and -2 for
* double precision floating point.
*/
signed gamma_depth;
/**
* Zero on success, positive it holds the value `errno` had
* when the reading failed, otherwise (negative) the value
* of an error identifier provided by this library.
*/
int gamma_depth_error;
/**
* Non-zero gamma ramp adjustments are supported.
*/
int gamma_support;
/**
* Zero on success, positive it holds the value `errno` had
* when the reading failed, otherwise (negative) the value
* of an error identifier provided by this library.
*/
int gamma_support_error;
/**
* The layout of the subpixels.
* You cannot count on this value --- especially for CRT:s ---
* but it is provided anyway as a means of distinguishing monitors.
*/
SubpixelOrder subpixel_order;
/**
* Zero on success, positive it holds the value `errno` had
* when the reading failed, otherwise (negative) the value
* of an error identifier provided by this library.
*/
int subpixel_order_error;
/**
* Whether there is a monitors connected to the CRTC.
*/
int active;
/**
* Zero on success, positive it holds the value `errno` had
* when the reading failed, otherwise (negative) the value
* of an error identifier provided by this library.
*/
int active_error;
/**
* The name of the connector as designated by the display
* server or as give by this library in case the display
* server lacks this feature.
*/
std::string* connector_name;
/**
* Zero on success, positive it holds the value `errno` had
* when the reading failed, otherwise (negative) the value
* of an error identifier provided by this library.
*/
int connector_name_error;
/**
* The type of the connector that is associated with the CRTC.
*/
ConnectorType connector_type;
/**
* Zero on success, positive it holds the value `errno` had
* when the reading failed, otherwise (negative) the value
* of an error identifier provided by this library.
*/
int connector_type_error;
/**
* The gamma characteristics of the monitor as reported
* in its Extended Display Information Data. The value
* holds the value for the red channel. If you do not have
* and more accurate measurement of the gamma for the
* monitor this could be used to give a rought gamma
* correction; simply divide the value with 2.2 and use
* the result for the red channel in the gamma correction.
*/
float gamma_red;
/**
* The gamma characteristics of the monitor as reported
* in its Extended Display Information Data. The value
* holds the value for the green channel. If you do not have
* and more accurate measurement of the gamma for the
* monitor this could be used to give a rought gamma
* correction; simply divide the value with 2.2 and use
* the result for the green channel in the gamma correction.
*/
float gamma_green;
/**
* The gamma characteristics of the monitor as reported
* in its Extended Display Information Data. The value
* holds the value for the blue channel. If you do not have
* and more accurate measurement of the gamma for the
* monitor this could be used to give a rought gamma
* correction; simply divide the value with 2.2 and use
* the result for the blue channel in the gamma correction.
*/
float gamma_blue;
/**
* Zero on success, positive it holds the value `errno` had
* when the reading failed, otherwise (negative) the value
* of an error identifier provided by this library.
*/
int gamma_error;
};
#ifdef __GCC__
# pragma GCC diagnostic push
# pragma GCC diagnostic ignored "-Weffc++"
/* Lets ignore that we do not override the copy constructor
* and the copy operator. */
#endif
/**
* One single Gamma ramp.
*/
template
class Ramp
{
public:
/**
* Constructor.
*
* @param native_ramp The ramp.
* @param ramp_size The size of the ramp.
*/
Ramp(T* native_ramp, size_t ramp_size)
{
this->ramp = native_ramp;
this->size = ramp_size;
}
/**
* Destructor.
*/
~Ramp()
{
/* Do nothing */
}
/**
* Subscript operator.
*
* @param index The index of the stop to set or get.
* @return A reference to the stop's value.
*/
T& operator [](size_t index)
{
return this->ramp[index];
}
/**
* Subscript operator.
*
* @param index The index of the stop to get.
* @return The value of the stop.
*/
const T& operator [](size_t index) const
{
return this->ramp[index];
}
/**
* The size of the ramp.
*/
size_t size;
/**
* The ramp (internal data).
*/
T* ramp;
};
/**
* Gamma ramp structure.
*/
template
class GammaRamps
{
public:
/**
* Constructor.
*/
GammaRamps() :
red(Ramp(nullptr, 0)),
green(Ramp(nullptr, 0)),
blue(Ramp(nullptr, 0)),
depth(0)
{
/* Do nothing. */
}
/**
* Constructor.
*
* @param red_ramp The red gamma ramp.
* @param green_ramp The green gamma ramp.
* @param blue_ramp The blue gamma ramp.
* @param red_size The size of the gamma ramp for the red channel.
* @param green_size The size of the gamma ramp for the green channel.
* @param blue_size The size of the gamma ramp for the blue channel.
* @param gamma_depth The bit-depth of the gamma ramps, -1 for single precision
* floating point, and -2 for double precision floating point.
*/
GammaRamps(T* red_ramp, T* green_ramp, T* blue_ramp,
size_t red_size, size_t green_size, size_t blue_size, signed gamma_depth) :
red(Ramp(red_ramp, red_size)),
green(Ramp(green_ramp, green_size)),
blue(Ramp(blue_ramp, blue_size)),
depth(gamma_depth)
{
/* Do nothing. */
}
/**
* Destructor.
*/
~GammaRamps()
{
free(this->red.ramp);
}
/**
* The red gamma ramp.
*/
Ramp red;
/**
* The green gamma ramp.
*/
Ramp green;
/**
* The blue gamma ramp.
*/
Ramp blue;
/**
* The bit-depth of the gamma ramps, -1 for single precision
* floating point, and -2 for double precision floating point.
*/
signed depth;
};
/**
* Site state.
*
* On operating systems that integrate a graphical environment
* there is usually just one site. However, one systems with
* pluggable graphics, like Unix-like systems such as GNU/Linux
* and the BSD:s, there can usually be any (feasible) number of
* sites. In X.org parlance they are called displays.
*/
class Site
{
public:
/**
* Constructor.
*/
Site();
/**
* Constructor.
*
* @param method The adjustment method of the site.
* @param site The site identifier, will be moved into
* the structure, must be `delete`:able.
*/
Site(int method, std::string* site = nullptr);
/**
* Destructor.
*/
~Site();
/**
* Restore the gamma ramps all CRTC:s with a site to
* the system settings.
*/
void restore();
/**
* This field specifies, for the methods if this library,
* which adjustment method (display server and protocol)
* is used to adjust the gamma ramps.
*/
int method;
/**
* The site identifier. It can either be `nullptr` or a string.
* `nullptr` indicates the default site. On systems like the
* Unix-like systems, where the graphics are pluggable, this
* is usually resolved by an environment variable, such as
* "DISPLAY" for X.org.
*/
std::string* site;
/**
* The number of partitions that is available on this site.
* Probably the majority of display server only one partition
* per site. However, X.org can, and traditional used to have
* on multi-headed environments, multiple partitions per site.
* In X.org partitions are called 'screens'. It is not to be
* confused with monitor. A screen is a collection of monitors,
* and the mapping from monitors to screens is a surjection.
* On hardware-level adjustment methods, such as Direct
* Rendering Manager, a partition is a graphics card.
*/
size_t partitions_available;
/**
* The state in the native structure.
*/
libgamma_site_state_t* native;
};
/**
* Partition state.
*
* Probably the majority of display server only one partition
* per site. However, X.org can, and traditional used to have
* on multi-headed environments, multiple partitions per site.
* In X.org partitions are called 'screens'. It is not to be
* confused with monitor. A screen is a collection of monitors,
* and the mapping from monitors to screens is a surjection.
* On hardware-level adjustment methods, such as Direct
* Rendering Manager, a partition is a graphics card.
*/
class Partition
{
public:
/**
* Constructor.
*/
Partition();
/**
* Constructor.
*
* @param site The site of the partition.
* @param partition The index of the partition.
*/
Partition(Site* site, size_t partition);
/**
* Destructor.
*/
~Partition();
/**
* Restore the gamma ramps all CRTC:s with a partition
* to the system settings.
*/
void restore();
/**
* The site this partition belongs to.
*/
Site* site;
/**
* The index of the partition.
*/
size_t partition;
/**
* The number of CRTC:s that are available under this
* partition. Note that the CRTC:s are not necessarily
* online.
*/
size_t crtcs_available;
/**
* The state in the native structure.
*/
libgamma_partition_state_t* native;
};
/**
* Cathode ray tube controller state.
*
* The CRTC controls the gamma ramps for the
* monitor that is plugged in to the connector
* that the CRTC belongs to.
*/
class CRTC
{
public:
/**
* Constructor.
*/
CRTC();
/**
* Constructor.
*
* @param partition The partition of the CRTC.
* @param crtc The index of the CRTC.
*/
CRTC(Partition* partition, size_t crtc);
/**
* Destructor.
*/
~CRTC();
/**
* Restore the gamma ramps for a CRTC to the system
* settings for that CRTC.
*/
void restore();
/**
* Read information about a CRTC.
*
* @param output Instance of a data structure to fill with the information about the CRTC.
* @param fields OR:ed identifiers for the information about the CRTC that should be read.
* @return Whether an error has occurred and is stored in a `*_error` field.
*/
bool information(CRTCInformation* output, int32_t fields);
#define __LIBGAMMA_GET_GAMMA(AFFIX) \
libgamma_gamma_ramps ## AFFIX ## _t ramps_; \
int r; \
ramps_.red = ramps->red.ramp; \
ramps_.green = ramps->green.ramp; \
ramps_.blue = ramps->blue.ramp; \
ramps_.red_size = ramps->red.size; \
ramps_.green_size = ramps->green.size; \
ramps_.blue_size = ramps->blue.size; \
r = libgamma_crtc_get_gamma_ramps ## AFFIX(this->native, &ramps_); \
if (r != 0) \
throw create_error(r)
/**
* Get the current gamma ramps for the CRTC.
*
* @param ramps The gamma ramps to fill with the current values.
*/
void get_gamma(GammaRamps* ramps)
{
__LIBGAMMA_GET_GAMMA(8);
}
/**
* Get the current gamma ramps for the CRTC.
*
* @param ramps The gamma ramps to fill with the current values.
*/
void get_gamma(GammaRamps* ramps)
{
__LIBGAMMA_GET_GAMMA(16);
}
/**
* Get the current gamma ramps for the CRTC.
*
* @param ramps The gamma ramps to fill with the current values.
*/
void get_gamma(GammaRamps* ramps)
{
__LIBGAMMA_GET_GAMMA(32);
}
/**
* Get the current gamma ramps for the CRTC.
*
* @param ramps The gamma ramps to fill with the current values.
*/
void get_gamma(GammaRamps* ramps)
{
__LIBGAMMA_GET_GAMMA(64);
}
/**
* Get the current gamma ramps for the CRTC.
*
* @param ramps The gamma ramps to fill with the current values.
*/
void get_gamma(GammaRamps* ramps)
{
__LIBGAMMA_GET_GAMMA(f);
}
/**
* Get the current gamma ramps for the CRTC.
*
* @param ramps The gamma ramps to fill with the current values.
*/
void get_gamma(GammaRamps* ramps)
{
__LIBGAMMA_GET_GAMMA(d);
}
#undef __LIBGAMMA_GET_GAMMA
#define __LIBGAMMA_SET_GAMMA(AFFIX) \
libgamma_gamma_ramps ## AFFIX ## _t ramps_; \
int r; \
ramps_.red = ramps->red.ramp; \
ramps_.green = ramps->green.ramp; \
ramps_.blue = ramps->blue.ramp; \
ramps_.red_size = ramps->red.size; \
ramps_.green_size = ramps->green.size; \
ramps_.blue_size = ramps->blue.size; \
r = libgamma_crtc_set_gamma_ramps ## AFFIX(this->native, ramps_); \
if (r != 0) \
throw create_error(r)
/**
* Set gamma ramps for the CRTC.
*
* @param ramps The gamma ramps to fill with the current values.
*/
void set_gamma(GammaRamps* ramps)
{
__LIBGAMMA_SET_GAMMA(8);
}
/**
* Set gamma ramps for the CRTC.
*
* @param ramps The gamma ramps to fill with the current values.
*/
void set_gamma(GammaRamps* ramps)
{
__LIBGAMMA_SET_GAMMA(16);
}
/**
* Set gamma ramps for the CRTC.
*
* @param ramps The gamma ramps to fill with the current values.
*/
void set_gamma(GammaRamps* ramps)
{
__LIBGAMMA_SET_GAMMA(32);
}
/**
* Set gamma ramps for the CRTC.
*
* @param ramps The gamma ramps to fill with the current values.
*/
void set_gamma(GammaRamps* ramps)
{
__LIBGAMMA_SET_GAMMA(64);
}
/**
* Set gamma ramps for the CRTC.
*
* @param ramps The gamma ramps to fill with the current values.
*/
void set_gamma(GammaRamps* ramps)
{
__LIBGAMMA_SET_GAMMA(f);
}
/**
* Set gamma ramps for the CRTC.
*
* @param ramps The gamma ramps to fill with the current values.
*/
void set_gamma(GammaRamps* ramps)
{
__LIBGAMMA_SET_GAMMA(d);
}
#undef __LIBGAMMA_SET_GAMMA
/**
* The partition this CRTC belongs to.
*/
Partition* partition;
/**
* The index of the CRTC within its partition.
*/
size_t crtc;
/**
* The state in the native structure.
*/
libgamma_crtc_state_t* native;
};
#ifdef __GCC__
# pragma GCC diagnostic pop
#endif
}
#endif