boinc/api/mac_carbon_dsp.c

849 lines
33 KiB
C
Executable File

// The contents of this file are subject to the Mozilla Public License
// Version 1.0 (the "License"); you may not use this file except in
// compliance with the License. You may obtain a copy of the License at
// http://www.mozilla.org/MPL/
//
// Software distributed under the License is distributed on an "AS IS"
// basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See the
// License for the specific language governing rights and limitations
// under the License.
//
// The Original Code is the Berkeley Open Infrastructure for Network Computing.
//
// The Initial Developer of the Original Code is the SETI@home project.
// Portions created by the SETI@home project are Copyright (C) 2002
// University of California at Berkeley. All Rights Reserved.
//
// Contributor(s):
//
/*
Contains: Functions to enable building and destroying a DSp fullscreen context
Written by: Geoff Stahl (ggs)
Copyright: Copyright © 1999 Apple Computer, Inc., All Rights Reserved
Change History (most recent first):
<3> 3/26/01 ggs Add DSp version check and other items for full screen on X
<2> 3/26/01 ggs Add new DSp functinality for Mac OS X
<1> 1/19/01 ggs Initial re-add
<7> 3/21/00 ggs Added windowed mode and clean up various implementation details
<6> 2/22/00 ggs fix fades
<5> 1/26/00 ggs Add fade code back in, ensure NULL pointer/context checks are in
<4> 1/24/00 ggs add new disclaimer, protection from NULL dispose, better
software renderer handling
<3> 12/18/99 ggs Fixed err use before init
<2> 12/18/99 ggs Fix headers
<1> 11/28/99 ggs Initial add. Split of just DSp handling functions. Added total
device RAM checks, better step downs using actual supported
resolutions. Need to add user verify for contexts that require
it, integration of this in context step down, and a freq bit
field.
<1> 11/11/99 ggs Initial Add
Disclaimer: You may incorporate this sample code into your applications without
restriction, though the sample code has been provided "AS IS" and the
responsibility for its operation is 100% yours. However, what you are
not permitted to do is to redistribute the source as "DSC Sample Code"
after having made changes. If you're going to re-distribute the source,
we require that you make it clear in the source that the code was
descended from Apple Sample Code, but that you've made changes.
Adapted to BOINC by Eric Heien
*/
// Usage notes:
//kUseRAMCheck enables estimated video card RAM checks
#define kUseRAMCheck
// system includes ----------------------------------------------------------
#ifndef __APPLE_CC__
#include <events.h>
#include <sound.h>
#include <fp.h>
#endif
// project includes ---------------------------------------------------------
#include "mac_carbon_dsp.h"
// globals (internal/private) -----------------------------------------------
enum
{
kMaxNumRes = 64, // max number of resolution slots
kMaxRefreshFreq = 75
};
Boolean gDSpStarted = false; // will never be true unless DSp is installed and start succeeds
Boolean gNeedFade = false;
// prototypes (internal/private) --------------------------------------------
DSpContextReference * ReserveUnusedDevices (GDHandle hGD);
OSStatus FreeUnusedDevices (GDHandle hGD, DSpContextReference ** ppContextRefUnused);
void BuildResolutionList (GDHandle hGD, Point * pResList, SInt32 * pFreqList);
OSStatus DoDeviceRAMCheck (pstructGLInfo pcontextInfo, Point * pResList, SInt32 * pFreqList, GLint depthSizeSupport);
Boolean DoContextStepDown (pstructGLInfo pcontextInfo, DSpContextAttributes * pContextAttributes, Point * pResList, SInt32 * pFreqList);
// functions (internal/private) ---------------------------------------------
// ReserveUnusedDevices
// reserves contexts on unused devices to vprevent their selection by DSp, returns list of these devices
DSpContextReference * ReserveUnusedDevices (GDHandle hGD)
{
DSpContextAttributes theContextAttributes;
DSpContextReference * pContextRefUnused = NULL;
GDHandle hDevice = DMGetFirstScreenDevice (true); // check number of screens
DisplayIDType displayID = 0;
short numDevices = 0, indexDevice = 0;
do
{
numDevices++;
hDevice = DMGetNextScreenDevice (hDevice, true);
}
while (hDevice);
numDevices--; // only count unused screens
if (numDevices)
{
pContextRefUnused = (DSpContextReference *) NewPtr ((long) sizeof (DSpContextReference) * numDevices);
hDevice = DMGetFirstScreenDevice (true); // check number of screens
do
{
if (hDevice != hGD) // if this device is not the one the user chose
{
if (noErr == DSpReportError (DMGetDisplayIDByGDevice (hDevice, &displayID, false)))
if (noErr == DSpReportError (DSpGetFirstContext (displayID, &pContextRefUnused [indexDevice]))) // get a context and
if (noErr == DSpReportError (DSpContext_GetAttributes (pContextRefUnused [indexDevice], &theContextAttributes))) // find attributes
DSpReportError (DSpContext_Reserve (pContextRefUnused [indexDevice], &theContextAttributes)); // reserve it
indexDevice++;
}
hDevice = DMGetNextScreenDevice (hDevice, true);
}
while (hDevice);
}
return pContextRefUnused;
}
// --------------------------------------------------------------------------
// FreeUnusedDevices
// frees screen that were previously reserved to prevent selection
OSStatus FreeUnusedDevices (GDHandle hGD, DSpContextReference ** ppContextRefUnused)
{
OSStatus err = noErr;
GDHandle hDevice = DMGetFirstScreenDevice (true); // check number of screens
short indexDevice = 0;
do
{
if (hDevice != hGD) // if this device is not the one the user chose
{
err = DSpContext_Release (*ppContextRefUnused [indexDevice]); // release it
DSpReportError (err);
indexDevice++;
}
hDevice = DMGetNextScreenDevice (hDevice, true);
}
while (hDevice);
if (*ppContextRefUnused)
DisposePtr ((Ptr) *ppContextRefUnused);
*ppContextRefUnused = NULL;
return err;
}
// --------------------------------------------------------------------------
// BuildResolutionList
// builds a list of supported resolutions and frequencies for GDevice
void BuildResolutionList (GDHandle hGD, Point * pResList, SInt32 * pFreqList)
{
DSpContextAttributes theContextAttributes;
DSpContextReference currContext;
OSStatus err;
DisplayIDType displayID = 0;
short i;
for (i = 0; i < kMaxNumRes; i++) // clear resolution list
{
pResList [i].h = 0x7FFF;
pResList [i].v = 0x7FFF;
pFreqList [i] = 0; // some context require certain frequencies find highest for each (not higher than 85
}
err = DMGetDisplayIDByGDevice (hGD, &displayID, true);
if (noErr != err)
ReportErrorNum ("DMGetDisplayIDByGDevice error", err);
else
{
if (noErr == DSpReportError (DSpGetFirstContext (displayID, &currContext)))
do
{
// insertion sort into resolution list
if (noErr == DSpReportError (DSpContext_GetAttributes (currContext, &theContextAttributes)))
{
Point pntTemp;
Boolean fDone = false;
short i = 0;
while ((i < kMaxNumRes) && (!fDone))
{
if ((theContextAttributes.displayWidth == pResList [i].h) && (theContextAttributes.displayHeight == pResList [i].v)) //skip
{
if ((pFreqList [i] == 0) || ((theContextAttributes.frequency <= (kMaxRefreshFreq << 16)) && (theContextAttributes.frequency > pFreqList [i])))
pFreqList [i] = theContextAttributes.frequency;
break;
}
if (theContextAttributes.displayWidth * theContextAttributes.displayHeight < pResList [i].h * pResList [i].v) //insert
{
pntTemp = pResList [i];
pResList [i].h = (short) theContextAttributes.displayWidth;
pResList [i].v = (short) theContextAttributes.displayHeight;
pFreqList [i] = theContextAttributes.frequency;
fDone = true;
}
i++;
}
// i points to next element to switch; finish array swaps (if
while ((i < kMaxNumRes) && (fDone))
{
Point pntSwitch = pResList [i];
pResList [i++] = pntTemp;
pntTemp = pntSwitch;
}
}
err = DSpGetNextContext (currContext, &currContext);
if (noErr != err)
{
if (kDSpContextNotFoundErr != err)
DSpReportError (err);
currContext = 0; // ensure we drop out
}
}
while (currContext);
else
ReportErrorNum ("DSpGetFirstContext error", err);
}
// zeroize unused elements
for (i = 0; i < kMaxNumRes; i++)
{
if ((pResList [i].h == 0x7FFF) || (pResList [i].v == 0x7FFF))
{
pResList [i].h = 0;
pResList [i].v = 0;
}
}
}
// --------------------------------------------------------------------------
// DoDeviceRAMCheck
// checks requested allocation against device RAM
// Note: may modify pcontextInfo
// this should be equal or less strigent than OpenGL actual allocation to avoid failing on valid drawables
OSStatus DoDeviceRAMCheck (pstructGLInfo pcontextInfo, Point * pResList, SInt32 * pFreqList, GLint depthSizeSupport)
{
float frontBufferFactor = 1.0f, backBufferFactor = 0.0f; // amount of screen(front) or request(back) sized buffers required, in bytes
Point pntFrontBuffer; // size of front buffer that wil be allocated
short i, indexFrontBuffer;
OSStatus err = noErr;
// must take into account the entire front buffer, so figure out what screen resolution we are really going to use
// find front buffer for request
i = 0;
while (((pResList [i].h < pcontextInfo->width) || (pResList [i].v < pcontextInfo->height)) &&
((pResList [i].h != 0) || (pResList [i].v != 0)) &&
(i < kMaxNumRes))
i++;
// save front buffer sizes
pntFrontBuffer.h = pResList [i].h;
pntFrontBuffer.v = pResList [i].v;
// if we have a valid frequnecy for the context set it (to ensure a good selection
pcontextInfo->freq = pFreqList [i] >> 16;
indexFrontBuffer = i;
// front buffers required
if (16 == pcontextInfo->pixelDepth)
frontBufferFactor *= 2.0;
else if (32 == pcontextInfo->pixelDepth)
frontBufferFactor *= 4.0;
// back buffers required
backBufferFactor = 0.0f;
i = 0;
while (64 > i)
if (AGL_DOUBLEBUFFER == pcontextInfo->aglAttributes[i++])
{
if (16 == pcontextInfo->pixelDepth)
backBufferFactor = 2.0f;
else if (32 == pcontextInfo->pixelDepth)
backBufferFactor = 4.0f;
break;
}
i = 0;
while (64 > i)
if (AGL_DEPTH_SIZE == pcontextInfo->aglAttributes[i++])
{
long requestDepth = pcontextInfo->aglAttributes[i];
GLint bit = 0x00000001;
short currDepth = 0, prevDepth = 0;
// if (depthSizeSupport)
// {
do
{
if (bit & depthSizeSupport) // if the card supports the depth
{
prevDepth = currDepth;
switch (bit)
{
case AGL_1_BIT:
currDepth = 1;
break;
case AGL_2_BIT:
currDepth = 2;
break;
case AGL_3_BIT:
currDepth = 3;
break;
case AGL_4_BIT:
currDepth = 4;
break;
case AGL_5_BIT:
currDepth = 5;
break;
case AGL_6_BIT:
currDepth = 6;
break;
case AGL_8_BIT:
currDepth = 8;
break;
case AGL_10_BIT:
currDepth = 10;
break;
case AGL_12_BIT:
currDepth = 12;
break;
case AGL_16_BIT:
currDepth = 16;
break;
case AGL_24_BIT:
currDepth = 24;
break;
case AGL_32_BIT:
currDepth = 32;
break;
case AGL_48_BIT:
currDepth = 48;
break;
case AGL_64_BIT:
currDepth = 64;
break;
case AGL_96_BIT:
currDepth = 96;
break;
case AGL_128_BIT:
currDepth = 128;
break;
}
}
bit *= 2;
} while (!((requestDepth > prevDepth) && (requestDepth <= currDepth)) && (bit < AGL_128_BIT + 1));
// }
// else // no card depth support info
// currDepth = requestDepth; // we don't have card info thus assume we can support exact depth requested (may fail later but will always be equal or less stringent)
if ((AGL_128_BIT >= bit) && (0 != currDepth))
backBufferFactor += (float) currDepth / 8.0;
break;
}
// What we now have:
// pcontextInfo->width, height: request width and height
// pResList: sorted list of resolutions supported on this display
// pntFrontBuffer : size of front buffer that will currently be allocated
// indexFrontBuffer: position in array of current front buffer request
// frontBufferFactor: number of screen resolution size buffers that will be needed
// backBufferFactor: number of request size buffers that will be needed
// if we see zero VRAM here we must be looking at the software renderer thus this check is moot.
if (pcontextInfo->VRAM == 0)
{
// no changes required
return noErr;
}
// find a context size that can support our texture requirements in the current total VRAM
if ((pcontextInfo->VRAM - pcontextInfo->textureRAM) < (pntFrontBuffer.h * pntFrontBuffer.v * frontBufferFactor +
pcontextInfo->width * pcontextInfo->height * backBufferFactor))
{
if (pcontextInfo->fDepthMust && pcontextInfo->fSizeMust)
{
// cannot accomdate request
ReportError ("Not enough total VRAM for drawable and textures (depth buffer and pixel size must be as requested)");
return err;
}
else if (pcontextInfo->fSizeMust) // if we can adjust the size, try adjusting the
{
// try 16 bit if must size is true
if ((pcontextInfo->pixelDepth > 16) &&
(pcontextInfo->VRAM - pcontextInfo->textureRAM) > (pntFrontBuffer.h * pntFrontBuffer.v * frontBufferFactor / 2.0 +
pcontextInfo->width * pcontextInfo->height * (backBufferFactor - 2.0)))
pcontextInfo->pixelDepth = 16;
else
{
// cannot accomdate request
ReportError ("Not enough total VRAM for drawable and textures");
return err;
}
}
else // can adjust size and might be able to adjust depth
{ // make drawable fit
Boolean fFound = false;
// see if we can just adjust the pixel depth
if ((pcontextInfo->pixelDepth > 16) && // if we are requesting 32 bit
(!pcontextInfo->fDepthMust) && // if we can adjust the pixel depth
(pcontextInfo->VRAM - pcontextInfo->textureRAM) > (pntFrontBuffer.h * pntFrontBuffer.v * frontBufferFactor / 2.0 +
pcontextInfo->width * pcontextInfo->height * (backBufferFactor - 2.0)))
{
fFound = true;
pcontextInfo->pixelDepth = 16;
}
else // pixel depth alone wont do it
{
i = (short) (indexFrontBuffer - 1);
while (i >= 0)
{
//
if ((pcontextInfo->VRAM - pcontextInfo->textureRAM) > (pResList [i].h * pResList [i].v * frontBufferFactor +
pResList [i].h * pResList [i].v * backBufferFactor))
{
fFound = true;
pcontextInfo->width = pResList [i].h;
pcontextInfo->height = pResList [i].v;
pcontextInfo->freq = pFreqList [i] >> 16;
break;
}
else if ((pcontextInfo->pixelDepth > 16) && // if we are requesting 32 bit
(!pcontextInfo->fDepthMust) && // if we can adjust the pixel depth
(pcontextInfo->VRAM - pcontextInfo->textureRAM) > (pResList [i].h * pResList [i].v * frontBufferFactor / 2.0 +
pResList [i].h * pResList [i].v * (backBufferFactor - 2.0)))
{
fFound = true;
pcontextInfo->width = pResList [i].h;
pcontextInfo->height = pResList [i].v;
pcontextInfo->freq = pFreqList [i] >> 16;
pcontextInfo->pixelDepth = 16;
break;
}
i--;
}
// we tried the smallest screen size and still need to use less VRAM, adjust backbuffer to what is available
if ((!fFound) && (((pcontextInfo->VRAM - pcontextInfo->textureRAM) - pResList [0].h * pResList [0].v * frontBufferFactor) > 0))
{
float factor;
fFound = true;
factor = (float) sqrt((float) (pcontextInfo->width * pcontextInfo->height * backBufferFactor) /
(float) ((pcontextInfo->VRAM - pcontextInfo->textureRAM) - pResList [0].h * pResList [0].v * frontBufferFactor));
pcontextInfo->width /= factor;
pcontextInfo->height /= factor;
pcontextInfo->freq = pFreqList [0] >> 16;
}
}
if (!fFound)
{
// cannot accomdate request
ReportError ("Not enough total VRAM for drawable and textures");
return err;
}
}
}
return noErr;
}
// --------------------------------------------------------------------------
// DoContextStepDown
// steps down through frequencies, depths and sizes to try to find a valid context
// bounded by flags for SizeMust and DepthMust
// Note: may modify pcontextInfo
Boolean DoContextStepDown (pstructGLInfo pcontextInfo, DSpContextAttributes * pContextAttributes, Point * pResList, SInt32 * pFreqList)
{
// find current resolution
short i = 0;
while (((pResList [i].h <= pContextAttributes->displayWidth) || (pResList [i].v <= pContextAttributes->displayHeight)) &&
((pResList [i].h != 0) || (pResList [i].v != 0)) &&
(i < kMaxNumRes))
i++;
i--; // i points to index of current resolution
if (pcontextInfo->fSizeMust) // adjust depth only
{
if (pcontextInfo->pixelDepth > 16) // also try pixel depth step down
{
pContextAttributes->displayBestDepth = 16;
pContextAttributes->backBufferBestDepth = 16;
}
else
return false; // no more options to try
}
else if (pcontextInfo->fDepthMust) // adjust size only
{
if (i > 0)
{
i--; // i was pointing at current resolution, now it is pointing at new resolution to try
// set new resolution
pContextAttributes->displayWidth = pResList [i].h;
pContextAttributes->displayHeight = pResList [i].v;
pcontextInfo->freq = pFreqList [i] >> 16;
}
else
return false;
}
else // adjust size and depth
{
if (pContextAttributes->displayBestDepth > 16)
{
pContextAttributes->displayBestDepth = 16;
pContextAttributes->backBufferBestDepth = 16;
}
else if (i > 0)
{
i--; // i was pointing at current resolution, now it is pointing at new resolution to try
// reset pixel depth
pContextAttributes->displayBestDepth = pcontextInfo->pixelDepth;
pContextAttributes->backBufferBestDepth = pcontextInfo->pixelDepth;
// set new resolution
pContextAttributes->displayWidth = pResList [i].h;
pContextAttributes->displayHeight = pResList [i].v;
pcontextInfo->freq = pFreqList [i] >> 16;
}
else
return false;
}
return true;
}
#pragma mark -
// functions (public) -------------------------------------------------------
// GetDSpVersion
// Gets the current version of DSp
NumVersion GetDSpVersion (void)
{
NumVersion versionDSp = { 0, 0, 0, 0 };
OSStatus err = noErr;
if (!gDSpStarted)
err = StartDSp ();
if (noErr == err)
versionDSp = DSpGetVersion ();
return versionDSp;
}
// --------------------------------------------------------------------------
// StartDSp
// handles starting up DrawSprocket
OSStatus StartDSp (void)
{
OSStatus err = noErr;
if (!gDSpStarted)
{
// check for DSp
if ((Ptr) kUnresolvedCFragSymbolAddress == (Ptr) DSpStartup)
{
ReportError ("DSp not installed");
return kDSpNotInitializedErr;
}
else
{
err = DSpReportError (DSpStartup()); // start DSp
if (noErr != err)
return err;
else
gDSpStarted = true;
}
}
return err;
}
// --------------------------------------------------------------------------
// ShutdownDSpContext
// shuts down DrawSprocket
void ShutdownDSp (void)
{
if (gDSpStarted)
{
DSpShutdown ();
gDSpStarted = false;
}
}
#pragma mark -
// --------------------------------------------------------------------------
// GetDSpDrawable
// Just returns the front buffer
// Inputs: *pdspContext
// pcontextInfo: request and requirements for cotext and drawable
// Outputs: returns CGrafPtr thaat is front buffer of context
// if error: will return NULL
CGrafPtr GetDSpDrawable (DSpContextReference dspContext)
{
CGrafPtr pCGraf = NULL;
if (noErr == DSpReportError (DSpContext_GetFrontBuffer (dspContext, &pCGraf)))
return pCGraf;
else
return NULL;
}
// --------------------------------------------------------------------------
// BuildDSpContext
// contextInfo and tries to allocate the corresponding DSp context
// Inputs: hGD: GDHandle to device to look at
// pcontextInfo: request and requirements for cotext and drawable
// Outputs: *pdspContext as allocated
// pcontextInfo: allocated parameters
// if fail to allocate: pdspContext will be NULL
// if error: will return error pdspContext will be NULL
OSStatus BuildDSpContext (DSpContextReference* pdspContext, GDHandle hGD, GLint depthSizeSupport, pstructGLInfo pcontextInfo)
{
DSpContextAttributes theContextAttributes, foundAttributes;
DSpContextReference * pContextRefUnused;
SInt32 aFreqList [kMaxNumRes];
Point aResList [kMaxNumRes]; // list for resolution information
OSStatus err = noErr;
*pdspContext = 0;
// check for DSp
if (noErr != StartDSp ())
{
ReportError ("DSp startup failed");
return noErr; // already reported
}
// reserve contexts on other screens to prevent their selection
pContextRefUnused = ReserveUnusedDevices (hGD);
// build resolution list
BuildResolutionList (hGD, aResList, aFreqList);
// handle default pixel depths
if (pcontextInfo->pixelDepth == 0) // default
{
pcontextInfo->pixelDepth = (**(**hGD).gdPMap).pixelSize;
if (pcontextInfo->pixelDepth < 16)
pcontextInfo->pixelDepth = 16;
}
#ifdef kUseRAMCheck
if (noErr != DoDeviceRAMCheck (pcontextInfo, aResList, aFreqList, depthSizeSupport))
return err;
#endif // kUseRAMCheck
// Note: DSp < 1.7.3 REQUIRES the back buffer attributes even if only one buffer is required
BlockZero (&theContextAttributes, sizeof (DSpContextAttributes));
// memset(&theContextAttributes, 0, sizeof (DSpContextAttributes));
theContextAttributes.displayWidth = pcontextInfo->width;
theContextAttributes.displayHeight = pcontextInfo->height;
theContextAttributes.displayBestDepth = pcontextInfo->pixelDepth;
theContextAttributes.backBufferBestDepth = pcontextInfo->pixelDepth;
do
{
theContextAttributes.frequency = pcontextInfo->freq * 0x10000;
theContextAttributes.colorNeeds = kDSpColorNeeds_Require;
theContextAttributes.displayDepthMask = kDSpDepthMask_All;
theContextAttributes.backBufferDepthMask = kDSpDepthMask_All;
theContextAttributes.pageCount = 1; // only the front buffer is needed
err = DSpFindBestContext(&theContextAttributes, pdspContext);
if (noErr != err) // if we had any errors, reset for next try
if (!DoContextStepDown (pcontextInfo, &theContextAttributes, aResList, aFreqList))
break; // have run out of options
} while (err == kDSpContextNotFoundErr);
// check find best context errors
if (kDSpContextNotFoundErr == err)
{
*pdspContext = 0;
return noErr;
}
else if (noErr != err)
{
DSpReportError (err);
*pdspContext = 0;
return err;
}
err = DSpReportError (DSpContext_GetAttributes (*pdspContext, &foundAttributes));
if (noErr != err)
{
*pdspContext = 0;
return err;
}
// reset width and height to full screen and handle our own centering
// HWA will not correctly center less than full screen size contexts
theContextAttributes.displayWidth = foundAttributes.displayWidth;
theContextAttributes.displayHeight = foundAttributes.displayHeight;
theContextAttributes.pageCount = 1; // only the front buffer is needed
theContextAttributes.contextOptions = 0 | kDSpContextOption_DontSyncVBL; // no page flipping and no VBL sync needed
err = DSpReportError (DSpContext_Reserve(*pdspContext, &theContextAttributes )); // reserve our context
if (noErr != err)
{
*pdspContext = 0;
return err;
}
if (gNeedFade == true)
{
DSpReportError (DSpContext_CustomFadeGammaOut (NULL, NULL, fadeTicks));
gNeedFade = false;
}
err = DSpReportError (DSpContext_SetState (*pdspContext, kDSpContextState_Active)); // activate our context
if (noErr != err)
{
DSpContext_Release (*pdspContext);
DSpReportError (DSpContext_CustomFadeGammaIn (NULL, NULL, fadeTicks));
*pdspContext = 0;
return err;
}
FreeUnusedDevices (hGD, &pContextRefUnused);
if (!pcontextInfo->fSizeMust) // if we got whatever was available
{
// reset inputs to what was allocated (constrain aspect ratio)
// unless we ask for smaller, then leave the same
if ((pcontextInfo->width > foundAttributes.displayWidth) || (pcontextInfo->height > foundAttributes.displayHeight))
{
float hFactor = (float) pcontextInfo->width / (float) foundAttributes.displayWidth;
float vFactor = (float) pcontextInfo->height / (float) foundAttributes.displayHeight;
if (hFactor > vFactor)
{
pcontextInfo->width = (short) foundAttributes.displayWidth;
pcontextInfo->height /= hFactor;
}
else
{
pcontextInfo->height = (short) foundAttributes.displayHeight;
pcontextInfo->width /= vFactor;
}
}
}
// else still use inputs to allocate drawable
pcontextInfo->freq = foundAttributes.frequency / 0x10000;
pcontextInfo->pixelDepth = foundAttributes.displayBestDepth;
return noErr;
}
//-----------------------------------------------------------------------------------------------------------------------
// Deactivates and dumps context
void DestroyDSpContext (DSpContextReference* pdspContext)
{
if (gDSpStarted)
{
if (*pdspContext)
{
DSpReportError (DSpContext_SetState(*pdspContext, kDSpContextState_Inactive));
DSpReportError (DSpContext_CustomFadeGammaIn (NULL, NULL, fadeTicks));
DSpReportError (DSpContext_Release (*pdspContext));
*pdspContext = NULL;
}
}
}
#pragma mark -
//-----------------------------------------------------------------------------------------------------------------------
OSStatus DSpContext_CustomFadeGammaIn (DSpContextReference inContext, const RGBColor *fadeColor, long fadeTicks)
{
OSStatus err = noErr;
RGBColor inZeroIntensityColor;
UInt32 currTick;
UInt16 step = (UInt16) (800 / fadeTicks);
long x, percent = 0;
if (gDSpStarted)
{
if (fadeTicks == 0)
fadeTicks = 1;
if (fadeColor == NULL)
{
inZeroIntensityColor.red = 0x0000;
inZeroIntensityColor.green = 0x0000;
inZeroIntensityColor.blue = 0x0000;
}
else
inZeroIntensityColor = *fadeColor;
currTick = TickCount ();
for (x = 1; x <= fadeTicks; x++)
{
percent = step * x / 8;
err = DSpContext_FadeGamma(inContext, percent, &inZeroIntensityColor);
if (err != noErr)
break;
while (currTick >= TickCount ()) {}
// SystemTask ();
currTick = TickCount ();
}
if (err == noErr)
err = DSpContext_FadeGamma(inContext, 100, &inZeroIntensityColor);
}
return err;
}
//-----------------------------------------------------------------------------------------------------------------------
OSStatus DSpContext_CustomFadeGammaOut (DSpContextReference inContext, const RGBColor *fadeColor, long fadeTicks )
{
OSStatus err = noErr;
RGBColor inZeroIntensityColor;
UInt32 currTick;
UInt16 step = (UInt16) (800 / fadeTicks);
long x, percent = 0;
if (gDSpStarted)
{
if (fadeTicks == 0)
fadeTicks = 1; // ensure we do not have zero fade time
if (fadeColor == NULL)
{
inZeroIntensityColor.red = 0x0000;
inZeroIntensityColor.green = 0x0000;
inZeroIntensityColor.blue = 0x0000;
}
else
inZeroIntensityColor = *fadeColor;
currTick = TickCount ();
for (x = fadeTicks - 1; x >= 0; x--)
{
percent = step * x / 8;
err = DSpContext_FadeGamma(inContext, percent, &inZeroIntensityColor);
if (err != noErr)
break;
while (currTick >= TickCount ()) {}
// SystemTask ();
currTick = TickCount ();
}
}
return err;
}