Files
rocm-systems/rocclr/runtime/device/gpu/gpuprintf.cpp
T
foreman ef83d84899 P4 to Git Change 1599194 by gandryey@gera-w8 on 2018/08/28 18:38:33
SWDEV-79445 - OCL generic changes and code clean-up
	- Move printf setup in the kernels to the abstraction layer

Affected files ...

... //depot/stg/opencl/drivers/opencl/runtime/device/devkernel.cpp#2 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/devkernel.hpp#2 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/gpu/gpukernel.cpp#329 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/gpu/gpukernel.hpp#131 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/gpu/gpuprintf.cpp#47 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/gpu/gpuprintf.hpp#16 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/gpu/gpuprogram.cpp#238 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/gpu/gpuprogram.hpp#71 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/pal/palkernel.cpp#62 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/pal/palkernel.hpp#21 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/pal/palprintf.cpp#10 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/pal/palprintf.hpp#4 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/rocm/rockernel.cpp#41 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/rocm/rockernel.hpp#25 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/rocm/rocprintf.cpp#11 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/rocm/rocprintf.hpp#6 edit
2018-08-28 18:48:05 -04:00

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//
// Copyright (c) 2010 Advanced Micro Devices, Inc. All rights reserved.
//
#include "top.hpp"
#include "os/os.hpp"
#include "device/device.hpp"
#include "device/gpu/gpudefs.hpp"
#include "device/gpu/gpumemory.hpp"
#include "device/gpu/gpukernel.hpp"
#include "device/gpu/gpuprogram.hpp"
#include "device/gpu/gpuprintf.hpp"
#include <cstdio>
#include <algorithm>
#include <math.h>
namespace gpu {
PrintfDbg::PrintfDbg(Device& device, FILE* file)
: dbgBuffer_(NULL),
dbgFile_(file),
gpuDevice_(device),
wiDbgSize_(0),
initCntValue_(device, 4) {}
PrintfDbg::~PrintfDbg() { delete dbgBuffer_; }
bool PrintfDbg::create() {
// Create a resource for the init count value
if (initCntValue_.create(Resource::Remote)) {
uint32_t* value = reinterpret_cast<uint32_t*>(initCntValue_.map(NULL));
// The counter starts from 1
if (NULL != value) {
*value = 1;
} else {
return false;
}
initCntValue_.unmap(NULL);
return true;
}
return false;
}
bool PrintfDbg::init(VirtualGPU& gpu, bool printfEnabled, const amd::NDRange& size) {
// Set up debug output buffer (if printf active)
if (printfEnabled) {
if (!allocate()) {
return false;
}
// Make sure that the size isn't bigger than the reported max
if (size.product() <= dev().settings().maxWorkGroupSize_) {
size_t wiDbgSizeTmp;
// Calculate the debug buffer size per workitem
wiDbgSizeTmp = std::min(dbgBuffer_->size() / size.product(), dev().xferRead().bufSize());
// Make sure the size is DWORD aligned
wiDbgSizeTmp = amd::alignDown(wiDbgSizeTmp, sizeof(uint32_t));
// If the new size is different, then clear the initial values
if (wiDbgSize_ != wiDbgSizeTmp) {
wiDbgSize_ = wiDbgSizeTmp;
if (!clearWorkitems(gpu, 0, size.product())) {
wiDbgSize_ = 0;
return false;
}
}
}
}
return true;
}
bool PrintfDbg::output(VirtualGPU& gpu, bool printfEnabled, const amd::NDRange& size,
const std::vector<device::PrintfInfo>& printfInfo) {
// Are we expected to generate debug output?
if (printfEnabled && !printfInfo.empty()) {
uint32_t* workitemData;
size_t i, j, k, z;
bool realloc = false;
// Wait for kernel execution
gpu.waitAllEngines();
size_t zdim = 1;
size_t ydim = 1;
size_t xdim = 1;
switch (size.dimensions()) {
case 3:
zdim = size[2];
// Fall through ...
case 2:
ydim = size[1];
// Fall through ...
case 1:
xdim = size[0];
// Fall through ...
default:
break;
}
for (k = 0; k < zdim; ++k) {
for (j = 0; j < ydim; ++j) {
for (i = 0; i < xdim; ++i) {
size_t idx = (xdim * (ydim * k + j) + i);
workitemData = mapWorkitem(gpu, idx, &realloc);
if (NULL != workitemData) {
uint32_t wp = workitemData[0]; // write pointer (i.e. first unwritten element)
// Walk through each PrintfDbg entry
for (z = 1; (z < (wiDbgSize() / sizeof(uint32_t))) && (z < wp);) {
if (printfInfo.size() < workitemData[z]) {
LogError("The format string wasn't reported");
return false;
}
// Get the PrintfDbg info
const device::PrintfInfo& info = printfInfo[workitemData[z++]];
// There's something in this buffer
outputDbgBuffer(info, workitemData, z);
}
}
unmapWorkitem(gpu, workitemData);
}
}
}
// Reallocate debug buffer if necessary
if (!allocate(realloc)) {
return false;
}
}
return true;
}
uint64_t PrintfDbg::bufOffset() const { return dbgBuffer_->hbOffset(); }
bool PrintfDbg::allocate(bool realloc) {
if (NULL == dbgBuffer_) {
dbgBuffer_ = dev().createScratchBuffer(dev().info().printfBufferSize_);
} else if (realloc) {
LogWarning("Debug buffer reallocation!");
// Double the buffer size if it's not big enough
size_t size = dbgBuffer_->size();
delete dbgBuffer_;
dbgBuffer_ = dev().createScratchBuffer(size << 1);
}
return (NULL != dbgBuffer_) ? true : false;
}
bool PrintfDbg::checkFloat(const std::string& fmt) const {
switch (fmt[fmt.size() - 1]) {
case 'e':
case 'E':
case 'f':
case 'g':
case 'G':
case 'a':
return true;
break;
default:
break;
}
return false;
}
bool PrintfDbg::checkString(const std::string& fmt) const {
if (fmt[fmt.size() - 1] == 's') return true;
return false;
}
int PrintfDbg::checkVectorSpecifier(const std::string& fmt, size_t startPos, size_t& curPos) const {
int vectorSize = 0;
size_t pos = curPos;
size_t size = curPos - startPos;
if (size >= 3) {
size = 0;
// no modifiers
if (fmt[curPos - 3] == 'v') {
size = 2;
}
// the modifiers are "h" or "l"
else if (fmt[curPos - 4] == 'v') {
size = 3;
}
// the modifier is "hh"
else if ((curPos >= 5) && (fmt[curPos - 5] == 'v')) {
size = 4;
}
if (size > 0) {
curPos = size;
pos -= curPos;
// Get vector size
vectorSize = fmt[pos++] - '0';
// PrintfDbg supports only 2, 3, 4, 8 and 16 wide vectors
switch (vectorSize) {
case 1:
if ((fmt[pos++] - '0') == 6) {
vectorSize = 16;
} else {
vectorSize = 0;
}
break;
case 2:
case 3:
case 4:
case 8:
break;
default:
vectorSize = 0;
break;
}
}
}
return vectorSize;
}
static const size_t ConstStr = 0xffffffff;
static const char Separator[] = ",\0";
size_t PrintfDbg::outputArgument(const std::string& fmt, bool printFloat, size_t size,
const uint32_t* argument) const {
// Serialize the output to the screen
amd::ScopedLock k(dev().lockAsyncOps());
size_t copiedBytes = size;
// Print the string argument, using standard PrintfDbg()
if (checkString(fmt.c_str())) {
// copiedBytes should be as number of printed chars
copiedBytes = 0;
//(null) should be printed
if (*argument == 0) {
amd::Os::printf(fmt.data(), 0);
// copiedBytes = strlen("(null)")
copiedBytes = 6;
} else {
const unsigned char* argumentStr = reinterpret_cast<const unsigned char*>(argument);
amd::Os::printf(fmt.data(), argumentStr);
// copiedBytes = strlen(argumentStr)
while (argumentStr[copiedBytes++] != 0)
;
}
}
// Print the argument(except for string ), using standard PrintfDbg()
else {
bool hlModifier = (strstr(fmt.c_str(), "hl") != NULL);
std::string hlFmt;
if (hlModifier) {
hlFmt = fmt;
hlFmt.erase(hlFmt.find_first_of("hl"), 2);
}
switch (size) {
case 0: {
const char* str = reinterpret_cast<const char*>(argument);
amd::Os::printf(fmt.data(), str);
// Find the string length
while (str[copiedBytes++] != 0)
;
} break;
case 1:
amd::Os::printf(fmt.data(), *(reinterpret_cast<const unsigned char*>(argument)));
break;
case 2:
case 4:
if (printFloat) {
static const char* fSpecifiers = "eEfgGa";
std::string fmtF = fmt;
size_t posS = fmtF.find_first_of("%");
size_t posE = fmtF.find_first_of(fSpecifiers);
if (posS != std::string::npos && posE != std::string::npos) {
fmtF.replace(posS + 1, posE - posS, "s");
}
float fArg = *(reinterpret_cast<const float*>(argument));
float fSign = copysign(1.0, fArg);
if (isinf(fArg) && !isnan(fArg)) {
if (fSign < 0) {
amd::Os::printf(fmtF.data(), "-infinity");
} else {
amd::Os::printf(fmtF.data(), "infinity");
}
} else if (isnan(fArg)) {
if (fSign < 0) {
amd::Os::printf(fmtF.data(), "-nan");
} else {
amd::Os::printf(fmtF.data(), "nan");
}
} else if (hlModifier) {
amd::Os::printf(hlFmt.data(), fArg);
} else {
amd::Os::printf(fmt.data(), fArg);
}
} else {
bool hhModifier = (strstr(fmt.c_str(), "hh") != NULL);
if (hhModifier) {
// current implementation of printf in gcc 4.5.2 runtime libraries, doesn`t recognize
// "hh" modifier ==>
// argument should be explicitly converted to unsigned char (uchar) before printing and
// fmt should be updated not to contain "hh" modifier
std::string hhFmt = fmt;
hhFmt.erase(hhFmt.find_first_of("h"), 2);
amd::Os::printf(hhFmt.data(), *(reinterpret_cast<const unsigned char*>(argument)));
} else if (hlModifier) {
amd::Os::printf(hlFmt.data(), *argument);
} else {
amd::Os::printf(fmt.data(), *argument);
}
}
break;
case 8:
if (printFloat) {
if (hlModifier) {
amd::Os::printf(hlFmt.data(), *(reinterpret_cast<const double*>(argument)));
} else {
amd::Os::printf(fmt.data(), *(reinterpret_cast<const double*>(argument)));
}
} else {
std::string out = fmt;
// Use 'll' for 64 bit printf
out.insert((out.size() - 1), 1, 'l');
amd::Os::printf(out.data(), *(reinterpret_cast<const uint64_t*>(argument)));
}
break;
case ConstStr: {
const char* str = reinterpret_cast<const char*>(argument);
amd::Os::printf(fmt.data(), str);
} break;
default:
amd::Os::printf("Error: Unsupported data size for PrintfDbg. %d bytes",
static_cast<int>(size));
return 0;
}
}
fflush(stdout);
return copiedBytes;
}
void PrintfDbg::outputDbgBuffer(const device::PrintfInfo& info, const uint32_t* workitemData,
size_t& i) const {
static const char* specifiers = "cdieEfgGaosuxXp";
static const char* modifiers = "hl";
static const char* special = "%n";
static const std::string sepStr = "%s";
const uint32_t* s = workitemData;
size_t pos = 0;
// Find the format string
std::string str = info.fmtString_;
std::string fmt;
size_t posStart, posEnd;
// Print all arguments
// Note: the following code walks through all arguments, provided by the kernel and
// finds the corresponding specifier in the format string.
// Then it splits the original string into substrings with a single specifier and
// uses standard PrintfDbg() to print each argument
for (uint j = 0; j < info.arguments_.size(); ++j) {
do {
posStart = str.find_first_of("%", pos);
if (posStart != std::string::npos) {
posStart++;
// Erase all spaces after %
while (str[posStart] == ' ') {
str.erase(posStart, 1);
}
size_t tmp = str.find_first_of(special, posStart);
size_t tmp2 = str.find_first_of(specifiers, posStart);
// Special cases. Special symbol is located before any specifier
if (tmp < tmp2) {
posEnd = posStart + 1;
fmt = str.substr(pos, posEnd - pos);
fmt.erase(posStart - pos - 1, 1);
pos = posStart = posEnd;
outputArgument(sepStr, false, ConstStr, reinterpret_cast<const uint32_t*>(fmt.data()));
continue;
}
break;
} else if (pos < str.length()) {
outputArgument(sepStr, false, ConstStr,
reinterpret_cast<const uint32_t*>((str.substr(pos)).data()));
}
} while (posStart != std::string::npos);
if (posStart != std::string::npos) {
bool printFloat = false;
int vectorSize = 0;
size_t length;
size_t idPos = 0;
// Search for PrintfDbg specifier in the format string.
// It will be a split point for the output
posEnd = str.find_first_of(specifiers, posStart);
if (posEnd == std::string::npos) {
pos = posStart = posEnd;
break;
}
posEnd++;
size_t curPos = posEnd;
vectorSize = checkVectorSpecifier(str, posStart, curPos);
// Get substring from the last position to the current specifier
fmt = str.substr(pos, posEnd - pos);
// Readjust the string pointer if PrintfDbg outputs a vector
if (vectorSize != 0) {
size_t posVecSpec = fmt.length() - (curPos + 1);
size_t posVecMod = fmt.find_first_of(modifiers, posVecSpec + 1);
size_t posMod = str.find_first_of(modifiers, posStart);
if (posMod < posEnd) {
fmt = fmt.erase(posVecSpec, posVecMod - posVecSpec);
} else {
fmt = fmt.erase(posVecSpec, curPos);
}
idPos = posStart - pos - 1;
}
pos = posStart = posEnd;
// Find out if the argument is a float
printFloat = checkFloat(fmt);
// Is it a scalar value?
if (vectorSize == 0) {
length = outputArgument(fmt, printFloat, info.arguments_[j], &s[i]);
if (0 == length) {
return;
}
i += amd::alignUp(length, sizeof(uint32_t)) / sizeof(uint32_t);
} else {
// 3-component vector's size is defined as 4 * size of each scalar component
size_t elemSize = info.arguments_[j] / (vectorSize == 3 ? 4 : vectorSize);
size_t k = i * sizeof(uint32_t);
std::string elementStr = fmt.substr(idPos, fmt.size());
// Print first element with full string
if (0 == outputArgument(fmt, printFloat, elemSize, &s[i])) {
return;
}
// Print other elemnts with separator if available
for (int e = 1; e < vectorSize; ++e) {
const char* t = reinterpret_cast<const char*>(s);
// Output the vector separator
outputArgument(sepStr, false, ConstStr, reinterpret_cast<const uint32_t*>(Separator));
// Output the next element
outputArgument(elementStr, printFloat, elemSize,
reinterpret_cast<const uint32_t*>(&t[k + e * elemSize]));
}
i += (amd::alignUp(info.arguments_[j], sizeof(uint32_t))) / sizeof(uint32_t);
}
}
}
if (pos != std::string::npos) {
fmt = str.substr(pos, str.size() - pos);
outputArgument(sepStr, false, ConstStr, reinterpret_cast<const uint32_t*>(fmt.data()));
}
}
bool PrintfDbg::clearWorkitems(VirtualGPU& gpu, size_t idxStart, size_t number) const {
// Go through all locations for every thread and copy 1
for (uint i = idxStart; i < idxStart + number; ++i) {
amd::Coord3D dst(i * wiDbgSize(), 0, 0);
amd::Coord3D size(sizeof(uint32_t), 0, 0);
// Copy 1 into the corresponding location in the debug buffer
if (!initCntValue_.partialMemCopyTo(gpu, amd::Coord3D(0, 0, 0), dst, size, *dbgBuffer_)) {
return false;
}
}
return true;
}
uint32_t* PrintfDbg::mapWorkitem(VirtualGPU& gpu, size_t idx, bool* realloc) {
uint32_t wiSize = 0;
amd::Coord3D src(idx * wiDbgSize(), 0, 0);
xferBufRead_ = &(dev().xferRead().acquire());
// Copy workitem size from the corresponding location in the debug buffer
if (!dbgBuffer_->partialMemCopyTo(gpu, src, amd::Coord3D(0, 0, 0),
amd::Coord3D(sizeof(uint32_t), 0, 0), *xferBufRead_)) {
return NULL;
}
// Get memory pointer to the satged buffer
uint32_t* workitem = reinterpret_cast<uint32_t*>(xferBufRead_->map(&gpu));
if (NULL == workitem) {
return NULL;
}
// Copy size value
wiSize = *workitem;
xferBufRead_->unmap(&gpu);
// Check if the cuurent workitem almost reached the size limit
if ((wiDbgSize() - static_cast<size_t>(wiSize)) < 3) {
*realloc = true;
}
// If the current workitem had any output then get the data
if ((wiSize > 1) && (wiSize <= wiDbgSize())) {
amd::Coord3D size(wiSize * sizeof(uint32_t), 0, 0);
// Copy the current workitem output data to the staged buffer
if (!dbgBuffer_->partialMemCopyTo(gpu, src, amd::Coord3D(0, 0, 0), size, *xferBufRead_) ||
// Clear the write pointer back to index 1 for the current workitem
!clearWorkitems(gpu, idx, 1)) {
LogError("Reading the workitem data failed!");
return NULL;
}
// Get a pointer to the workitem data
uint32_t* workitem = reinterpret_cast<uint32_t*>(xferBufRead_->map(&gpu));
return workitem;
}
return NULL;
}
void PrintfDbg::unmapWorkitem(VirtualGPU& gpu, const uint32_t* workitemData) const {
if (NULL != workitemData) {
xferBufRead_->unmap(&gpu);
}
dev().xferRead().release(gpu, *xferBufRead_);
}
bool PrintfDbgHSA::init(VirtualGPU& gpu, bool printfEnabled) {
// Set up debug output buffer (if printf active)
if (printfEnabled) {
if (!allocate()) {
return false;
}
// The first two DWORDs in the printf buffer are as follows:
// First DWORD = Offset to where next information is to
// be written, initialized to 0
// Second DWORD = Number of bytes available for printf data
// = buffer size 2*sizeof(uint32_t)
const uint8_t initSize = 2 * sizeof(uint32_t);
uint8_t sysMem[initSize];
memset(sysMem, 0, initSize);
uint32_t dbgBufferSize = dbgBuffer_->size() - initSize;
memcpy(&sysMem[4], &dbgBufferSize, sizeof(dbgBufferSize));
// Copy offset and number of bytes available for printf data
// into the corresponding location in the debug buffer
dbgBuffer_->writeRawData(gpu, initSize, sysMem, true);
}
return true;
}
bool PrintfDbgHSA::output(VirtualGPU& gpu, bool printfEnabled,
const std::vector<device::PrintfInfo>& printfInfo) {
if (printfEnabled) {
uint32_t offsetSize = 0;
xferBufRead_ = &(dev().xferRead().acquire());
// Copy offset from the first DWORD in the debug buffer
if (!dbgBuffer_->partialMemCopyTo(gpu, amd::Coord3D(0, 0, 0), amd::Coord3D(0, 0, 0),
amd::Coord3D(sizeof(uint32_t), 0, 0), *xferBufRead_)) {
return false;
}
// Get memory pointer to the satged buffer
uint32_t* dbgBufferPtr = reinterpret_cast<uint32_t*>(xferBufRead_->map(&gpu));
if (NULL == dbgBufferPtr) {
return false;
}
offsetSize = *dbgBufferPtr;
xferBufRead_->unmap(&gpu);
if (offsetSize == 0) {
LogInfo("The printf buffer is empty!");
dev().xferRead().release(gpu, *xferBufRead_);
return true;
}
size_t bufSize = dev().xferRead().bufSize();
size_t copySize = offsetSize;
while (copySize != 0) {
// Copy the buffer data (i.e., the printfID followed by the
// argument data for each printf call in th kernel) to the staged buffer
if (!dbgBuffer_->partialMemCopyTo(
gpu, amd::Coord3D(2 * sizeof(uint32_t) + offsetSize - copySize, 0, 0),
amd::Coord3D(0, 0, 0), std::min(copySize, bufSize), *xferBufRead_)) {
return false;
}
// Get a pointer to the buffer data
dbgBufferPtr = reinterpret_cast<uint32_t*>(xferBufRead_->map(&gpu));
if (NULL == dbgBufferPtr) {
return false;
}
uint sb = 0;
uint sbt = 0;
// parse the debug buffer
while (sbt < copySize) {
if (*dbgBufferPtr >= printfInfo.size()) {
LogError("Couldn't find the reported PrintfID!");
return false;
}
const device::PrintfInfo& info = printfInfo[(*dbgBufferPtr)];
sb += sizeof(uint32_t);
for (const auto& it : info.arguments_) {
sb += it;
}
if (sbt + sb > bufSize) {
break; // Need new portion of data in staging buffer
}
size_t idx = 1;
// There's something in the debug buffer
outputDbgBuffer(info, dbgBufferPtr, idx);
sbt += sb;
dbgBufferPtr += sb / sizeof(uint32_t);
sb = 0;
}
copySize -= sbt;
xferBufRead_->unmap(&gpu);
}
dev().xferRead().release(gpu, *xferBufRead_);
}
return true;
}
} // namespace gpu