raze/source/core/gameinput.cpp
Mitchell Richters 4ef9ec93ea - Remove fixedhoriz::asbuildf() and associated buildf friend.
* The new friend `tanhoriz()` is just for the input code for now.
2022-10-25 07:06:53 +02:00

489 lines
14 KiB
C++

//-------------------------------------------------------------------------
/*
Copyright (C) 2019 Christoph Oelckers
Copyright (C) 2020 Mitchell Richters
This 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 2
of the License, or (at your option) any later version.
This program 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 program; if not, write to the Free Software
Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*/
//-------------------------------------------------------------------------
#include "gamecontrol.h"
#include "gameinput.h"
#include "gamestruct.h"
#include "serializer.h"
#include "gamefuncs.h"
//---------------------------------------------------------------------------
//
// Input scale helper functions.
//
//---------------------------------------------------------------------------
inline static double getTicrateScale(const double value)
{
return value / GameTicRate;
}
inline static double getCorrectedScale(const double scaleAdjust)
{
// When using the output of I_GetInputFrac() to scale input adjustments at framerate, deviations of over 100 ms can occur.
// Below formula corrects the deviation, with 0.2125 being an average between an ideal value of 0.205 for 40Hz and 0.22 for 30Hz.
// We use the average value here as the difference is under 5 ms and is not worth complicating the algorithm for such precision.
return scaleAdjust < 1. ? scaleAdjust * (1. + 0.2125 * (1. - scaleAdjust)) : scaleAdjust;
}
inline static fixedhoriz getscaledhoriz(const double value, const double scaleAdjust, const fixedhoriz object, const double push)
{
return tanhoriz(getCorrectedScale(scaleAdjust) * ((object.Tan() * getTicrateScale(value)) + push));
}
inline static DAngle getscaledangle(const double value, const double scaleAdjust, const DAngle object, const DAngle push)
{
return ((object.Normalized180() * getTicrateScale(value)) + push) * getCorrectedScale(scaleAdjust);
}
inline static void scaletozero(fixedhoriz& object, const double value, const double scaleAdjust, const double push = DBL_MAX)
{
if (auto sgn = object.Sgn())
{
object -= getscaledhoriz(value, scaleAdjust, object, push == DBL_MAX ? sgn * (1. / 576.) : push);
if (sgn != object.Sgn()) object = q16horiz(0);
}
}
inline static void scaletozero(DAngle& object, const double value, const double scaleAdjust, const DAngle push = -minAngle)
{
if (auto sgn = object.Sgn())
{
object -= getscaledangle(value, scaleAdjust, object, push == -minAngle ? DAngle::fromDeg(sgn * 5. / 128.) : push);
if (sgn != object.Sgn()) object = nullAngle;
}
}
//---------------------------------------------------------------------------
//
// Functions for determining whether its turbo turn time (turn key held for a number of tics).
//
//---------------------------------------------------------------------------
/*
// Turbo turn time.
Blood: 24 * 30 = 720;
Duke: 120 / 8 * 30 = 450;
SW: 120 / 8 * 40 = 600;
Exhumed: N/A;
Average: 590.;
*/
enum
{
BUILDTICRATE = 120,
TURBOTURNBASE = 590,
};
static double turnheldtime;
void updateTurnHeldAmt(double const scaleAdjust)
{
turnheldtime += getTicrateScale(BUILDTICRATE) * scaleAdjust;
}
bool isTurboTurnTime()
{
return turnheldtime >= getTicrateScale(TURBOTURNBASE);
}
void resetTurnHeldAmt()
{
turnheldtime = 0;
}
//---------------------------------------------------------------------------
//
// Player's movement function, called from game's ticker or from gi->GetInput() as required.
//
//---------------------------------------------------------------------------
/*
// Running speed.
Blood: 92 / 4 * 2 * 30 = 1380;
Duke: 15 * 2 * 2 * 30 = 1800;
SW: 28 * 1.40625 * 40 = 1575; // Precisely, ((((28 * 12) + ((28 * 12) / 4)) * 3) / 32) * 40
Exhumed: 12 * 4 * 30 = 1440;
Average: 1548.75;
// Normal speed.
Blood: 92 / 4 * 30 = 690;
Duke: 15 * 2 * 30 = 900;
SW: 18 * 1.40625 * 40 = 1012.5; // Precisely, (((((12 + 6) * 12) + (((12 + 6) * 12) / 4)) * 3) / 32) * 40
Exhumed: 8 * 4 * 30 = 960;
Average: 890.625;
// Preamble.
Blood: N/A;
Exhumed: N/A;
Duke: 5 * 2 * 30 = 300;
SW: 3 * 1.40625 * 40 = 168.75; // Precisely, ((((3 * 12) + ((3 * 12) / 4)) * 3) / 32) * 40
Average: 234.375;
*/
static constexpr double TURNSPEEDS[3] = { 234.375, 890.625, 1548.75 };
static constexpr double PREAMBLESCALE = TURNSPEEDS[0] / TURNSPEEDS[1];
void processMovement(InputPacket* const currInput, InputPacket* const inputBuffer, ControlInfo* const hidInput, double const scaleAdjust, int const drink_amt, bool const allowstrafe, double const turnscale)
{
// set up variables.
int const keymove = 1 << int(!!(inputBuffer->actions & SB_RUN));
float const hidspeed = float(getTicrateScale(TURNSPEEDS[2]) * turnscale * BAngToDegree);
float const scaleAdjustf = float(scaleAdjust);
// determine player input.
auto const turning = buttonMap.ButtonDown(gamefunc_Turn_Right) - buttonMap.ButtonDown(gamefunc_Turn_Left);
auto const moving = buttonMap.ButtonDown(gamefunc_Move_Forward) - buttonMap.ButtonDown(gamefunc_Move_Backward) + hidInput->dz * scaleAdjustf;
auto const strafing = buttonMap.ButtonDown(gamefunc_Strafe_Right) - buttonMap.ButtonDown(gamefunc_Strafe_Left) - hidInput->dx * scaleAdjustf;
// process player angle input.
if (!(buttonMap.ButtonDown(gamefunc_Strafe) && allowstrafe))
{
float const turndir = clamp(turning + strafing * !allowstrafe, -1.f, 1.f);
float const turnspeed = float(getTicrateScale(TURNSPEEDS[keymove]) * turnscale * BAngToDegree * (isTurboTurnTime() ? 1. : PREAMBLESCALE));
currInput->avel += hidInput->mouseturnx + (hidInput->dyaw * hidspeed + turndir * turnspeed) * scaleAdjustf;
if (turndir) updateTurnHeldAmt(scaleAdjust); else resetTurnHeldAmt();
}
else
{
currInput->svel += hidInput->mousemovex + (hidInput->dyaw + turning) * keymove * scaleAdjustf;
}
// process player pitch input.
if (!(inputBuffer->actions & SB_AIMMODE))
currInput->horz -= hidInput->mouseturny + hidInput->dpitch * hidspeed * scaleAdjustf;
else
currInput->fvel -= hidInput->mousemovey + hidInput->dpitch * keymove * scaleAdjustf;
// process movement input.
currInput->fvel += moving * keymove;
currInput->svel += strafing * keymove * allowstrafe;
if (isRR() && drink_amt >= 66 && drink_amt <= 87) currInput->svel += drink_amt & 1 ? -currInput->fvel : currInput->fvel;
// add collected input to game's local input accumulation packet.
inputBuffer->fvel = clamp<float>(inputBuffer->fvel + currInput->fvel, -keymove, keymove);
inputBuffer->svel = clamp<float>(inputBuffer->svel + currInput->svel, -keymove, keymove);
inputBuffer->avel += currInput->avel;
inputBuffer->horz += currInput->horz;
}
//---------------------------------------------------------------------------
//
// Player's horizon function, called from game's ticker or from gi->GetInput() as required.
//
//---------------------------------------------------------------------------
/*
// Aim speed.
Duke: 6 * 30 = 180;
SW: (16 / 2) * 40 = 320;
Average: 250.;
// Look speed.
Duke: 12 * 30 = 360;
SW: 16 * 40 = 640;
Average: 500.;
// Return to centre speed.
Duke: (1 / 3) * 30 = 10;
SW: (1 / 4) * 40 = 10;
Average: 10.;
*/
enum
{
AIMSPEED = 250,
LOOKSPEED = 500,
CNTRSPEED = 10,
};
void PlayerHorizon::applyinput(float const horz, ESyncBits* actions, double const scaleAdjust)
{
// Process only if movement isn't locked.
if (!movementlocked())
{
// Test if we have input to process.
if (horz || *actions & (SB_AIM_UP | SB_AIM_DOWN | SB_LOOK_UP | SB_LOOK_DOWN))
{
// Store current horizon as true pitch.
double pitch = horiz.Degrees();
// Process mouse input.
if (horz)
{
*actions &= ~SB_CENTERVIEW;
pitch += horz;
}
// Process keyboard input.
auto doKbdInput = [&](ESyncBits_ const up, ESyncBits_ const down, double const rate, bool const lock)
{
if (*actions & (up | down))
{
if (lock) *actions &= ~SB_CENTERVIEW; else *actions |= SB_CENTERVIEW;
double const amount = scaleAdjust * HorizToPitch(getTicrateScale(rate));
if (*actions & down)
pitch -= amount;
if (*actions & up)
pitch += amount;
}
};
doKbdInput(SB_AIM_UP, SB_AIM_DOWN, AIMSPEED, true);
doKbdInput(SB_LOOK_UP, SB_LOOK_DOWN, LOOKSPEED, false);
// clamp before converting back to horizon
horiz = q16horiz(clamp(PitchToHoriz(pitch), gi->playerHorizMin(), gi->playerHorizMax()));
}
// return to center if conditions met.
if ((*actions & SB_CENTERVIEW) && !(*actions & (SB_LOOK_UP|SB_LOOK_DOWN)))
{
scaletozero(horiz, CNTRSPEED, scaleAdjust);
if (!horiz.asq16()) *actions &= ~SB_CENTERVIEW;
}
}
else
{
*actions &= ~SB_CENTERVIEW;
}
}
//---------------------------------------------------------------------------
//
// Player's angle function, called from game's ticker or from gi->GetInput() as required.
//
//---------------------------------------------------------------------------
/*
// Rotate return speed.
Duke: (1 / 2) * 30 = 15;
// Look return speed.
Duke: (1 / 4) * 30 = 7.5;
// Rotating speed.
Duke: 24 * 30 = 720;
// Looking speed.
Duke: 152 * 30 = 4560;
// Spin standing speed.
Duke: 128 * 30 = 3840;
Blood: 128 * 30 = 3840;
// Looking speed.
Blood: 64 * 30 = 1920;
*/
static constexpr double ROTRETURNSPEED = (1. / 2.) * 30.;
static constexpr double LOOKRETURNSPEED = (1. / 4.) * 30.;
enum
{
ROTATESPEED = 720,
LOOKINGSPEED = 4560,
SPINSTAND = 3840,
SPINCROUCH = 1920,
};
void PlayerAngle::applyinput(float const avel, ESyncBits* actions, double const scaleAdjust)
{
// Process angle return to zeros.
scaletozero(rotscrnang, ROTRETURNSPEED, scaleAdjust);
scaletozero(look_ang, LOOKRETURNSPEED, scaleAdjust);
// Process keyboard input.
auto doLookKeys = [&](ESyncBits_ const key, double const direction)
{
if (*actions & key)
{
look_ang += DAngle::fromDeg(getTicrateScale(LOOKINGSPEED) * getCorrectedScale(scaleAdjust) * direction * BAngToDegree);
rotscrnang -= DAngle::fromDeg(getTicrateScale(ROTATESPEED) * getCorrectedScale(scaleAdjust) * direction * BAngToDegree);
}
};
doLookKeys(SB_LOOK_LEFT, -1);
doLookKeys(SB_LOOK_RIGHT, 1);
if (!movementlocked())
{
if (*actions & SB_TURNAROUND)
{
if (spin == nullAngle)
{
// currently not spinning, so start a spin
spin = -DAngle180;
}
*actions &= ~SB_TURNAROUND;
}
if (avel)
{
// add player's input
ang += DAngle::fromDeg(avel);
}
if (spin < nullAngle)
{
// return spin to 0
DAngle add = DAngle::fromDeg(getTicrateScale(!(*actions & SB_CROUCH) ? SPINSTAND : SPINCROUCH) * scaleAdjust * BAngToDegree);
spin += add;
if (spin > nullAngle)
{
// Don't overshoot our target. With variable factor this is possible.
add -= spin;
spin = nullAngle;
}
ang += add;
}
}
else
{
spin = nullAngle;
}
}
//---------------------------------------------------------------------------
//
// Player's slope tilt when playing without a mouse and on a slope.
//
//---------------------------------------------------------------------------
/*
// Horizoff centre speed.
Duke: (1 / 8) * 30 = 3.75;
SW: (1 / 8) * 40 = 5;
Average: 4.375;
*/
static constexpr double HORIZOFFSPEED = (1. / 8.) * 35.;
enum
{
// Values used by Duke/SW, where this function originated from.
DEFSINSHIFT = 5,
DEFVIEWPITCH = 160,
// Values used by Blood since it calculates differently to Duke/SW.
BLOODSINSHIFT = 8,
SINSHIFTDELTA = BLOODSINSHIFT - DEFSINSHIFT,
BLOODVIEWPITCH = (0x4000 >> SINSHIFTDELTA) - (DEFVIEWPITCH << (SINSHIFTDELTA - 1)), // 1408.
};
void PlayerHorizon::calcviewpitch(const DVector2& pos, DAngle const ang, bool const aimmode, bool const canslopetilt, sectortype* const cursectnum, double const scaleAdjust, bool const climbing)
{
if (cl_slopetilting && cursectnum != nullptr)
{
if (aimmode && canslopetilt) // If the floor is sloped
{
// Get a point, 512 (64 for Blood) units ahead of player's position
auto rotpt = pos + ang.ToVector() * (isBlood() ? 4 : 32);
auto tempsect = cursectnum;
updatesector(rotpt, &tempsect);
if (tempsect != nullptr) // If the new point is inside a valid sector...
{
// Get the floorz as if the new (x,y) point was still in
// your sector
double const j = getflorzofslopeptr(cursectnum, pos);
double const k = getflorzofslopeptr(tempsect, rotpt);
// If extended point is in same sector as you or the slopes
// of the sector of the extended point and your sector match
// closely (to avoid accidently looking straight out when
// you're at the edge of a sector line) then adjust horizon
// accordingly
if (cursectnum == tempsect || (!isBlood() && abs(getflorzofslopeptr(tempsect, rotpt) - k) <= 4))
{
horizoff += q16horiz(fixed_t(scaleAdjust * ((j - k) * 256 * (!isBlood() ? DEFVIEWPITCH : BLOODVIEWPITCH))));
}
}
}
if (climbing)
{
// tilt when climbing but you can't even really tell it.
if (horizoff.Degrees() < 38) horizoff += getscaledhoriz(HORIZOFFSPEED, scaleAdjust, pitchhoriz(38) - horizoff, 0.0078125);
}
else
{
// Make horizoff grow towards 0 since horizoff is not modified when you're not on a slope.
scaletozero(horizoff, HORIZOFFSPEED, scaleAdjust, horizoff.Sgn() * (1. / 128.));
}
}
}
//---------------------------------------------------------------------------
//
//
//
//---------------------------------------------------------------------------
FSerializer& Serialize(FSerializer& arc, const char* keyname, PlayerAngle& w, PlayerAngle* def)
{
if (arc.BeginObject(keyname))
{
arc("ang", w.ang)
("lookang", w.look_ang)
("rotscrnang", w.rotscrnang)
("spin", w.spin)
("inputdisabled", w.inputdisabled)
.EndObject();
if (arc.isReading())
{
w.oang = w.ang;
w.olook_ang = w.look_ang;
w.orotscrnang = w.rotscrnang;
w.inputdisabled = w.inputdisabled;
w.resetadjustment();
}
}
return arc;
}
FSerializer& Serialize(FSerializer& arc, const char* keyname, PlayerHorizon& w, PlayerHorizon* def)
{
if (arc.BeginObject(keyname))
{
arc("horiz", w.horiz)
("horizoff", w.horizoff)
("inputdisabled", w.inputdisabled)
.EndObject();
if (arc.isReading())
{
w.ohoriz = w.horiz;
w.ohorizoff = w.horizoff;
w.inputdisabled = w.inputdisabled;
w.resetadjustment();
}
}
return arc;
}