claunia/cuetools.net
1
0
Fork 0
mirror of https://github.com/claunia/cuetools.net.git synced 2025-12-16 18:14:25 +00:00
Code Issues Packages Projects Releases Wiki Activity

Compatibility issues with HD4XXX, Fermi

Browse Source
This commit is contained in:
chudov
2010-11-20 19:27:42 +00:00
parent 72c1f0b5ce
commit f981d1bb65
2 changed files with 67 additions and 63 deletions
Download Patch File Download Diff File Expand all files Collapse all files

62
CUETools.Codecs.FLACCL/FLACCLWriter.cs
View File

@@ -195,7 +195,7 @@ namespace CUETools.Codecs.FLACCL
_path = path;
_IO = IO;
eparams.flake_set_defaults(_compressionLevel, !_settings.GPUOnly);
eparams.flake_set_defaults(_compressionLevel);
eparams.padding_size = 8192;
crc8 = new Crc8();
@@ -238,7 +238,7 @@ namespace CUETools.Codecs.FLACCL
if (value < 0 || value > 11)
throw new Exception("unsupported compression level");
_compressionLevel = value;
eparams.flake_set_defaults(_compressionLevel, !_settings.GPUOnly);
eparams.flake_set_defaults(_compressionLevel);
}
}
@@ -261,7 +261,6 @@ namespace CUETools.Codecs.FLACCL
//_settings.GPUOnly = true;
_settings.MappedMemory = true;
}
eparams.flake_set_defaults(_compressionLevel, !_settings.GPUOnly);
}
}
@@ -1582,19 +1581,6 @@ namespace CUETools.Codecs.FLACCL
// If true, RequireImageSupport will filter out any devices without image support
// In this project we don't need image support though, so we set it to false
OCLMan.RequireImageSupport = false;
// The Defines string gets prepended to any and all sources that are compiled
// and serve as a convenient way to pass configuration information to the compilation process
OCLMan.Defines =
"#define MAX_ORDER " + eparams.max_prediction_order.ToString() + "\n" +
"#define GROUP_SIZE " + groupSize.ToString() + "\n" +
"#define FLACCL_VERSION \"" + vendor_string + "\"\n" +
(_settings.GPUOnly ? "#define DO_PARTITIONS\n" : "") +
(_settings.DoRice ? "#define DO_RICE\n" : "") +
#if DEBUG
"#define DEBUG\n" +
#endif
(_settings.DeviceType == OpenCLDeviceType.CPU ? "#define FLACCL_CPU\n" : "") +
_settings.Defines + "\n";
// The BuildOptions string is passed directly to clBuild and can be used to do debug builds etc
OCLMan.BuildOptions = "";
OCLMan.SourcePath = System.IO.Path.GetDirectoryName(GetType().Assembly.Location);
@@ -1620,7 +1606,23 @@ namespace CUETools.Codecs.FLACCL
OCLMan.CreateDefaultContext(platformId, (DeviceType)_settings.DeviceType);
if (OCLMan.Context.Devices[0].Extensions.Contains("cl_khr_local_int32_extended_atomics"))
OCLMan.Defines += "#define HAVE_ATOM\n";
_settings.Defines += "#define HAVE_ATOM\n";
else
_settings.GPUOnly = false;
// The Defines string gets prepended to any and all sources that are compiled
// and serve as a convenient way to pass configuration information to the compilation process
OCLMan.Defines =
"#define MAX_ORDER " + eparams.max_prediction_order.ToString() + "\n" +
"#define GROUP_SIZE " + groupSize.ToString() + "\n" +
"#define FLACCL_VERSION \"" + vendor_string + "\"\n" +
(_settings.GPUOnly ? "#define DO_PARTITIONS\n" : "") +
(_settings.DoRice ? "#define DO_RICE\n" : "") +
#if DEBUG
"#define DEBUG\n" +
#endif
(_settings.DeviceType == OpenCLDeviceType.CPU ? "#define FLACCL_CPU\n" : "") +
_settings.Defines + "\n";
try
{
@@ -2146,7 +2148,7 @@ namespace CUETools.Codecs.FLACCL
public bool do_seektable;
public int flake_set_defaults(int lvl, bool encode_on_cpu)
public int flake_set_defaults(int lvl)
{
compression = lvl;
@@ -2165,7 +2167,7 @@ namespace CUETools.Codecs.FLACCL
min_prediction_order = 1;
max_prediction_order = 12;
min_partition_order = 0;
max_partition_order = 6;
max_partition_order = 8;
variable_block_size = 0;
lpc_min_precision_search = 0;
lpc_max_precision_search = 0;
@@ -2183,7 +2185,6 @@ namespace CUETools.Codecs.FLACCL
do_midside = false;
window_function = WindowFunction.Bartlett;
orders_per_window = 1;
max_partition_order = 4;
max_prediction_order = 7;
min_fixed_order = 3;
max_fixed_order = 2;
@@ -2197,7 +2198,6 @@ namespace CUETools.Codecs.FLACCL
min_fixed_order = 2;
max_fixed_order = 2;
max_prediction_order = 7;
max_partition_order = 4;
break;
case 2:
do_constant = false;
@@ -2207,7 +2207,6 @@ namespace CUETools.Codecs.FLACCL
min_fixed_order = 2;
max_fixed_order = 2;
max_prediction_order = 8;
max_partition_order = 4;
break;
case 3:
do_constant = false;
@@ -2272,9 +2271,6 @@ namespace CUETools.Codecs.FLACCL
break;
}
if (!encode_on_cpu)
max_partition_order = 8;
return 0;
}
}
@@ -2456,14 +2452,14 @@ namespace CUETools.Codecs.FLACCL
clSelectedTasks = openCLProgram.Context.CreateBuffer(MemFlags.READ_WRITE | MemFlags.ALLOC_HOST_PTR, selectedLen);
clRiceOutput = openCLProgram.Context.CreateBuffer(MemFlags.READ_WRITE | MemFlags.ALLOC_HOST_PTR, riceLen);
clSamplesBytesPtr = openCLCQ.EnqueueMapBuffer(clSamplesBytes, true, MapFlags.WRITE, 0, samplesBufferLen / 2);
clResidualPtr = openCLCQ.EnqueueMapBuffer(clResidual, true, MapFlags.WRITE, 0, residualBufferLen);
clBestRiceParamsPtr = openCLCQ.EnqueueMapBuffer(clBestRiceParams, true, MapFlags.WRITE, 0, riceParamsLen / 4);
clResidualTasksPtr = openCLCQ.EnqueueMapBuffer(clResidualTasks, true, MapFlags.WRITE, 0, residualTasksLen);
clBestResidualTasksPtr = openCLCQ.EnqueueMapBuffer(clBestResidualTasks, true, MapFlags.WRITE, 0, bestResidualTasksLen);
clWindowFunctionsPtr = openCLCQ.EnqueueMapBuffer(clWindowFunctions, true, MapFlags.WRITE, 0, wndLen);
clSelectedTasksPtr = openCLCQ.EnqueueMapBuffer(clSelectedTasks, true, MapFlags.WRITE, 0, selectedLen);
clRiceOutputPtr = openCLCQ.EnqueueMapBuffer(clRiceOutput, true, MapFlags.WRITE, 0, riceLen);
clSamplesBytesPtr = openCLCQ.EnqueueMapBuffer(clSamplesBytes, true, MapFlags.READ_WRITE, 0, samplesBufferLen / 2);
clResidualPtr = openCLCQ.EnqueueMapBuffer(clResidual, true, MapFlags.READ_WRITE, 0, residualBufferLen);
clBestRiceParamsPtr = openCLCQ.EnqueueMapBuffer(clBestRiceParams, true, MapFlags.READ_WRITE, 0, riceParamsLen / 4);
clResidualTasksPtr = openCLCQ.EnqueueMapBuffer(clResidualTasks, true, MapFlags.READ_WRITE, 0, residualTasksLen);
clBestResidualTasksPtr = openCLCQ.EnqueueMapBuffer(clBestResidualTasks, true, MapFlags.READ_WRITE, 0, bestResidualTasksLen);
clWindowFunctionsPtr = openCLCQ.EnqueueMapBuffer(clWindowFunctions, true, MapFlags.READ_WRITE, 0, wndLen);
clSelectedTasksPtr = openCLCQ.EnqueueMapBuffer(clSelectedTasks, true, MapFlags.READ_WRITE, 0, selectedLen);
clRiceOutputPtr = openCLCQ.EnqueueMapBuffer(clRiceOutput, true, MapFlags.READ_WRITE, 0, riceLen);
//clSamplesBytesPtr = clSamplesBytes.HostPtr;
//clResidualPtr = clResidual.HostPtr;

66
CUETools.Codecs.FLACCL/flac.cl
View File

@@ -865,6 +865,10 @@ void clEstimateResidual(
obits * bs);
}
#else
#define MAX_BLOCKSIZE 4096
#define ESTPARTLOG 5
__kernel /*__attribute__(( vec_type_hint (int4)))*/ __attribute__((reqd_work_group_size(GROUP_SIZE, 1, 1)))
void clEstimateResidual(
__global int*samples,
@@ -877,7 +881,7 @@ void clEstimateResidual(
__local volatile int idata[GROUP_SIZE];
#endif
__local FLACCLSubframeTask task;
__local int psum[64];
__local int psum[MAX_BLOCKSIZE >> ESTPARTLOG];
__local float fcoef[32];
__local int selectedTask;
@@ -896,15 +900,13 @@ void clEstimateResidual(
if (tid < 32)
//fcoef[tid] = select(0.0f, - ((float) task.coefs[tid]) / (1 << task.data.shift), tid < ro);
fcoef[tid] = tid < MAX_ORDER && tid + ro - MAX_ORDER >= 0 ? - ((float) task.coefs[tid + ro - MAX_ORDER]) / (1 << task.data.shift) : 0.0f;
if (tid < 64)
psum[tid] = 0;
for (int offs = tid; offs < (MAX_BLOCKSIZE >> ESTPARTLOG); offs += GROUP_SIZE)
psum[offs] = 0;
data[tid] = 0.0f;
// need to initialize "extra" data, because NaNs can produce wierd results even when multipled by zero extra coefs
if (tid < 32)
data[GROUP_SIZE * 2 + tid] = 0.0f;
int partOrder = max(6, clz(64) - clz(bs - 1) + 1);
barrier(CLK_LOCAL_MEM_FENCE);
#ifdef AMD
@@ -960,35 +962,35 @@ void clEstimateResidual(
// convert to unsigned
t = (t << 1) ^ (t >> 31);
#if !defined(AMD) || !defined(HAVE_ATOM)
// convert to unsigned
idata[tid] = t;
barrier(CLK_LOCAL_MEM_FENCE);
int ps = (1 << partOrder) - 1;
int lane = tid & ps;
for (int l = 1 << (partOrder - 1); l > WARP_SIZE; l >>= 1)
{
if (lane < l) idata[tid] += idata[tid + l];
barrier(CLK_LOCAL_MEM_FENCE);
}
if (lane < WARP_SIZE)
for (int l = WARP_SIZE; l > 0; l >>= 1)
for (int l = 16; l > 1; l >>= 1)
idata[tid] += idata[tid + l];
if (lane == 0)
psum[min(63,offs >> partOrder)] += idata[tid];
if ((tid & 31) == 0)
psum[min(MAX_BLOCKSIZE - 1, offs) >> ESTPARTLOG] = idata[tid] + idata[tid + 1];
#else
atom_add(&psum[min(63,offs >> partOrder)], t);
atom_add(&psum[min(MAX_BLOCKSIZE - 1, offs) >> ESTPARTLOG], t);
#endif
}
// calculate rice partition bit length for every (1 << partOrder) samples
// calculate rice partition bit length for every 32 samples
barrier(CLK_LOCAL_MEM_FENCE);
if (tid < 64)
{
int k = iclamp(clz(1 << partOrder) - clz(psum[tid]), 0, 14); // 27 - clz(res) == clz(16) - clz(res) == log2(res / 16)
psum[tid] = (k << partOrder) + (psum[tid] >> k);
}
// Bug: if (MAX_BLOCKSIZE >> (ESTPARTLOG + 1)) > GROUP_SIZE
int pl = get_local_id(0) < (MAX_BLOCKSIZE >> (ESTPARTLOG + 1)) ? pl = psum[tid * 2] + psum[tid * 2 + 1] : 0;
barrier(CLK_LOCAL_MEM_FENCE);
for (int l = 32; l > 0; l >>= 1)
// for (int pos = 0; pos < (MAX_BLOCKSIZE >> ESTPARTLOG) / 2; pos += GROUP_SIZE)
// {
//int offs = pos + tid;
//int pl = offs < (MAX_BLOCKSIZE >> ESTPARTLOG) / 2 ? psum[offs * 2] + psum[offs * 2 + 1] : 0;
////int pl = psum[offs * 2] + psum[offs * 2 + 1];
//barrier(CLK_LOCAL_MEM_FENCE);
//if (offs < (MAX_BLOCKSIZE >> ESTPARTLOG) / 2)
// psum[offs] = pl;
// }
int k = iclamp(31 - (ESTPARTLOG + 1) - clz(pl), 0, 14); // 26 - clz(res) == clz(32) - clz(res) == log2(res / 32)
if (tid < (MAX_BLOCKSIZE >> ESTPARTLOG) / 2)
psum[tid] = (k << (ESTPARTLOG + 1)) + (pl >> k);
barrier(CLK_LOCAL_MEM_FENCE);
for (int l = MAX_BLOCKSIZE >> (ESTPARTLOG + 2); l > 0; l >>= 1)
{
if (tid < l)
psum[tid] += psum[tid + l];
@@ -1796,7 +1798,11 @@ void clRiceEncoding(
unsigned int bb = bw.bit_buf << bw.bit_left;
bw.bit_buf = 0;
bw.bit_left += (32 - b);
#ifdef AMD
bw.buffer[bw.buf_ptr++] = as_int(as_char4(bb).wzyx);
#else
bw.buffer[bw.buf_ptr++] = (bb >> 24) | ((bb >> 8) & 0xff00) | ((bb << 8) & 0xff0000) | ((bb << 24) & 0xff000000);
#endif
}
bits -= b;
}
@@ -1811,7 +1817,11 @@ void clRiceEncoding(
unsigned int bb = (bw.bit_buf << bw.bit_left) | (val >> (bits - bw.bit_left));
bw.bit_buf = val;
bw.bit_left += (32 - bits);
#ifdef AMD
bw.buffer[bw.buf_ptr++] = as_int(as_char4(bb).wzyx);
#else
bw.buffer[bw.buf_ptr++] = (bb >> 24) | ((bb >> 8) & 0xff00) | ((bb << 8) & 0xff0000) | ((bb << 24) & 0xff000000);
#endif
}
////if (get_group_id(0) == 0) printf("%x ", v);
//writebits(&bw, (v >> k) + 1, 1);
@@ -1916,10 +1926,8 @@ void clRiceEncoding(
atom_or(&data[qpos0 + 1], qval1);
start = mypos[GROUP_SIZE - 1];
barrier(CLK_LOCAL_MEM_FENCE);
unsigned int bb = data[tid];
bb = (bb >> 24) | ((bb >> 8) & 0xff00U) | ((bb << 8) & 0xff0000U) | (bb << 24);
if ((start32 + tid) * 32 <= start)
output[start32 + tid] = bb;
output[start32 + tid] = as_int(as_char4(data[tid]).wzyx);
unsigned int remainder = data[start / 32 - start32];
barrier(CLK_LOCAL_MEM_FENCE);
data[tid] = select(0U, remainder, tid == 0);