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Adding example source to support MCJIT/Kaleidoscope blog posts.

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llvm-svn: 186854
This commit is contained in:
Andrew Kaylor 2013-07-22 18:47:24 +00:00
parent 1e13d52088
commit 208108a8e0
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examples/Kaleidoscope/MCJIT/README.txt Normal file
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//===----------------------------------------------------------------------===/
// Kaleidoscope with MCJIT
//===----------------------------------------------------------------------===//
The files in this directory are meant to accompany a series of blog posts
that describe the process of porting the Kaleidoscope tutorial to use the MCJIT
execution engine instead of the older JIT engine.
When the blog posts are ready this file will be updated with links to the posts.
These directories contain Makefiles that allow the code to be built in a
standalone manner, independent of the larger LLVM build infrastructure.

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all: toy-mcjit toy-jit toy-ir-gen
toy-mcjit : toy.cpp
clang++ toy.cpp -g -O3 -rdynamic -fno-rtti `llvm-config --cppflags --ldflags --libs core mcjit native irreader` -o toy-mcjit
toy-jit : toy-jit.cpp
clang++ toy-jit.cpp -g -O3 -rdynamic -fno-rtti `llvm-config --cppflags --ldflags --libs core jit native irreader` -o toy-jit
# This is a special build for the purpose of converting Kaleidoscope input to an IR file
toy-ir-gen : toy-jit.cpp
clang++ toy-jit.cpp -g -O3 -rdynamic -fno-rtti -DDUMP_FINAL_MODULE `llvm-config --cppflags --ldflags --libs core jit native irreader` -o toy-ir-gen

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examples/Kaleidoscope/MCJIT/cached/README.txt Normal file
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//===----------------------------------------------------------------------===/
// Kaleidoscope with MCJIT
//===----------------------------------------------------------------------===//
The files in this directory are meant to accompany the first in a series of
three blog posts that describe the process of porting the Kaleidoscope tutorial
to use the MCJIT execution engine instead of the older JIT engine.
When the blog post is ready this file will be updated with a link to the post.
The source code in this directory demonstrates the third version of the
program, now modified to accept an input IR file on the command line and,
optionally, to use a basic caching mechanism to store generated object images.
The toy-jit.cpp file contains a version of the original JIT-based source code
that has been modified to support the input IR file command line option.
This directory contain a Makefile that allow the code to be built in a
standalone manner, independent of the larger LLVM build infrastructure. To build
the program you will need to have 'clang++' and 'llvm-config' in your path. If
you attempt to build using the LLVM 3.3 release, some minor modifications will
be required.
This directory also contains a Python script that may be used to generate random
input for the program and test scripts to capture data for rough performance
comparisons. Another Python script will split generated input files into
definitions and function calls for the purpose of testing the IR input and
caching facilities.

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#!/usr/bin/env python
import sys
import random
class TimingScriptGenerator:
"""Used to generate a bash script which will invoke the toy and time it"""
def __init__(self, scriptname, outputname):
self.timeFile = outputname
self.shfile = open(scriptname, 'w')
self.shfile.write("echo \"\" > %s\n" % self.timeFile)
def writeTimingCall(self, filename, numFuncs, funcsCalled, totalCalls):
"""Echo some comments and invoke both versions of toy"""
rootname = filename
if '.' in filename:
rootname = filename[:filename.rfind('.')]
self.shfile.write("echo \"%s: Calls %d of %d functions, %d total\" >> %s\n" % (filename, funcsCalled, numFuncs, totalCalls, self.timeFile))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"With MCJIT\" >> %s\n" % self.timeFile)
self.shfile.write("/usr/bin/time -f \"Command %C\\n\\tuser time: %U s\\n\\tsytem time: %S s\\n\\tmax set: %M kb\"")
self.shfile.write(" -o %s -a " % self.timeFile)
self.shfile.write("./toy-mcjit < %s > %s-mcjit.out 2> %s-mcjit.err\n" % (filename, rootname, rootname))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"With JIT\" >> %s\n" % self.timeFile)
self.shfile.write("/usr/bin/time -f \"Command %C\\n\\tuser time: %U s\\n\\tsytem time: %S s\\n\\tmax set: %M kb\"")
self.shfile.write(" -o %s -a " % self.timeFile)
self.shfile.write("./toy-jit < %s > %s-jit.out 2> %s-jit.err\n" % (filename, rootname, rootname))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
class KScriptGenerator:
"""Used to generate random Kaleidoscope code"""
def __init__(self, filename):
self.kfile = open(filename, 'w')
self.nextFuncNum = 1
self.lastFuncNum = None
self.callWeighting = 0.1
# A mapping of calls within functions with no duplicates
self.calledFunctionTable = {}
# A list of function calls which will actually be executed
self.calledFunctions = []
# A comprehensive mapping of calls within functions
# used for computing the total number of calls
self.comprehensiveCalledFunctionTable = {}
self.totalCallsExecuted = 0
def updateTotalCallCount(self, callee):
# Count this call
self.totalCallsExecuted += 1
# Then count all the functions it calls
if callee in self.comprehensiveCalledFunctionTable:
for child in self.comprehensiveCalledFunctionTable[callee]:
self.updateTotalCallCount(child)
def updateFunctionCallMap(self, caller, callee):
"""Maintains a map of functions that are called from other functions"""
if not caller in self.calledFunctionTable:
self.calledFunctionTable[caller] = []
if not callee in self.calledFunctionTable[caller]:
self.calledFunctionTable[caller].append(callee)
if not caller in self.comprehensiveCalledFunctionTable:
self.comprehensiveCalledFunctionTable[caller] = []
self.comprehensiveCalledFunctionTable[caller].append(callee)
def updateCalledFunctionList(self, callee):
"""Maintains a list of functions that will actually be called"""
# Update the total call count
self.updateTotalCallCount(callee)
# If this function is already in the list, don't do anything else
if callee in self.calledFunctions:
return
# Add this function to the list of those that will be called.
self.calledFunctions.append(callee)
# If this function calls other functions, add them too
if callee in self.calledFunctionTable:
for subCallee in self.calledFunctionTable[callee]:
self.updateCalledFunctionList(subCallee)
def setCallWeighting(self, weight):
""" Sets the probably of generating a function call"""
self.callWeighting = weight
def writeln(self, line):
self.kfile.write(line + '\n')
def writeComment(self, comment):
self.writeln('# ' + comment)
def writeEmptyLine(self):
self.writeln("")
def writePredefinedFunctions(self):
self.writeComment("Define ':' for sequencing: as a low-precedence operator that ignores operands")
self.writeComment("and just returns the RHS.")
self.writeln("def binary : 1 (x y) y;")
self.writeEmptyLine()
self.writeComment("Helper functions defined within toy")
self.writeln("extern putchard(x);")
self.writeln("extern printd(d);")
self.writeln("extern printlf();")
self.writeEmptyLine()
self.writeComment("Print the result of a function call")
self.writeln("def printresult(N Result)")
self.writeln(" # 'result('")
self.writeln(" putchard(114) : putchard(101) : putchard(115) : putchard(117) : putchard(108) : putchard(116) : putchard(40) :")
self.writeln(" printd(N) :");
self.writeln(" # ') = '")
self.writeln(" putchard(41) : putchard(32) : putchard(61) : putchard(32) :")
self.writeln(" printd(Result) :");
self.writeln(" printlf();")
self.writeEmptyLine()
def writeRandomOperation(self, LValue, LHS, RHS):
shouldCallFunc = (self.lastFuncNum > 2 and random.random() < self.callWeighting)
if shouldCallFunc:
funcToCall = random.randrange(1, self.lastFuncNum - 1)
self.updateFunctionCallMap(self.lastFuncNum, funcToCall)
self.writeln(" %s = func%d(%s, %s) :" % (LValue, funcToCall, LHS, RHS))
else:
possibleOperations = ["+", "-", "*", "/"]
operation = random.choice(possibleOperations)
if operation == "-":
# Don't let our intermediate value become zero
# This is complicated by the fact that '<' is our only comparison operator
self.writeln(" if %s < %s then" % (LHS, RHS))
self.writeln(" %s = %s %s %s" % (LValue, LHS, operation, RHS))
self.writeln(" else if %s < %s then" % (RHS, LHS))
self.writeln(" %s = %s %s %s" % (LValue, LHS, operation, RHS))
self.writeln(" else")
self.writeln(" %s = %s %s %f :" % (LValue, LHS, operation, random.uniform(1, 100)))
else:
self.writeln(" %s = %s %s %s :" % (LValue, LHS, operation, RHS))
def getNextFuncNum(self):
result = self.nextFuncNum
self.nextFuncNum += 1
self.lastFuncNum = result
return result
def writeFunction(self, elements):
funcNum = self.getNextFuncNum()
self.writeComment("Auto-generated function number %d" % funcNum)
self.writeln("def func%d(X Y)" % funcNum)
self.writeln(" var temp1 = X,")
self.writeln(" temp2 = Y,")
self.writeln(" temp3 in")
# Initialize the variable names to be rotated
first = "temp3"
second = "temp1"
third = "temp2"
# Write some random operations
for i in range(elements):
self.writeRandomOperation(first, second, third)
# Rotate the variables
temp = first
first = second
second = third
third = temp
self.writeln(" " + third + ";")
self.writeEmptyLine()
def writeFunctionCall(self):
self.writeComment("Call the last function")
arg1 = random.uniform(1, 100)
arg2 = random.uniform(1, 100)
self.writeln("printresult(%d, func%d(%f, %f) )" % (self.lastFuncNum, self.lastFuncNum, arg1, arg2))
self.writeEmptyLine()
self.updateCalledFunctionList(self.lastFuncNum)
def writeFinalFunctionCounts(self):
self.writeComment("Called %d of %d functions" % (len(self.calledFunctions), self.lastFuncNum))
def generateKScript(filename, numFuncs, elementsPerFunc, funcsBetweenExec, callWeighting, timingScript):
""" Generate a random Kaleidoscope script based on the given parameters """
print "Generating " + filename
print(" %d functions, %d elements per function, %d functions between execution" %
(numFuncs, elementsPerFunc, funcsBetweenExec))
print(" Call weighting = %f" % callWeighting)
script = KScriptGenerator(filename)
script.setCallWeighting(callWeighting)
script.writeComment("===========================================================================")
script.writeComment("Auto-generated script")
script.writeComment(" %d functions, %d elements per function, %d functions between execution"
% (numFuncs, elementsPerFunc, funcsBetweenExec))
script.writeComment(" call weighting = %f" % callWeighting)
script.writeComment("===========================================================================")
script.writeEmptyLine()
script.writePredefinedFunctions()
funcsSinceLastExec = 0
for i in range(numFuncs):
script.writeFunction(elementsPerFunc)
funcsSinceLastExec += 1
if funcsSinceLastExec == funcsBetweenExec:
script.writeFunctionCall()
funcsSinceLastExec = 0
# Always end with a function call
if funcsSinceLastExec > 0:
script.writeFunctionCall()
script.writeEmptyLine()
script.writeFinalFunctionCounts()
funcsCalled = len(script.calledFunctions)
print " Called %d of %d functions, %d total" % (funcsCalled, numFuncs, script.totalCallsExecuted)
timingScript.writeTimingCall(filename, numFuncs, funcsCalled, script.totalCallsExecuted)
# Execution begins here
random.seed()
timingScript = TimingScriptGenerator("time-toy.sh", "timing-data.txt")
dataSets = [(5000, 3, 50, 0.50), (5000, 10, 100, 0.10), (5000, 10, 5, 0.10), (5000, 10, 1, 0.0),
(1000, 3, 10, 0.50), (1000, 10, 100, 0.10), (1000, 10, 5, 0.10), (1000, 10, 1, 0.0),
( 200, 3, 2, 0.50), ( 200, 10, 40, 0.10), ( 200, 10, 2, 0.10), ( 200, 10, 1, 0.0)]
# Generate the code
for (numFuncs, elementsPerFunc, funcsBetweenExec, callWeighting) in dataSets:
filename = "test-%d-%d-%d-%d.k" % (numFuncs, elementsPerFunc, funcsBetweenExec, int(callWeighting * 100))
generateKScript(filename, numFuncs, elementsPerFunc, funcsBetweenExec, callWeighting, timingScript)
print "All done!"

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#!/usr/bin/env python
class TimingScriptGenerator:
"""Used to generate a bash script which will invoke the toy and time it"""
def __init__(self, scriptname, outputname):
self.shfile = open(scriptname, 'w')
self.timeFile = outputname
self.shfile.write("echo \"\" > %s\n" % self.timeFile)
def writeTimingCall(self, irname, callname):
"""Echo some comments and invoke both versions of toy"""
rootname = irname
if '.' in irname:
rootname = irname[:irname.rfind('.')]
self.shfile.write("echo \"%s: Calls %s\" >> %s\n" % (callname, irname, self.timeFile))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"With MCJIT\" >> %s\n" % self.timeFile)
self.shfile.write("/usr/bin/time -f \"Command %C\\n\\tuser time: %U s\\n\\tsytem time: %S s\\n\\tmax set: %M kb\"")
self.shfile.write(" -o %s -a " % self.timeFile)
self.shfile.write("./toy-mcjit -use-object-cache -input-IR=%s < %s > %s-mcjit.out 2> %s-mcjit.err\n" % (irname, callname, rootname, rootname))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"With MCJIT again\" >> %s\n" % self.timeFile)
self.shfile.write("/usr/bin/time -f \"Command %C\\n\\tuser time: %U s\\n\\tsytem time: %S s\\n\\tmax set: %M kb\"")
self.shfile.write(" -o %s -a " % self.timeFile)
self.shfile.write("./toy-mcjit -use-object-cache -input-IR=%s < %s > %s-mcjit.out 2> %s-mcjit.err\n" % (irname, callname, rootname, rootname))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"With JIT\" >> %s\n" % self.timeFile)
self.shfile.write("/usr/bin/time -f \"Command %C\\n\\tuser time: %U s\\n\\tsytem time: %S s\\n\\tmax set: %M kb\"")
self.shfile.write(" -o %s -a " % self.timeFile)
self.shfile.write("./toy-jit -input-IR=%s < %s > %s-mcjit.out 2> %s-mcjit.err\n" % (irname, callname, rootname, rootname))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
class LibScriptGenerator:
"""Used to generate a bash script which will convert Kaleidoscope files to IR"""
def __init__(self, filename):
self.shfile = open(filename, 'w')
def writeLibGenCall(self, libname, irname):
self.shfile.write("./toy-ir-gen < %s 2> %s\n" % (libname, irname))
def splitScript(inputname, libGenScript, timingScript):
rootname = inputname[:-2]
libname = rootname + "-lib.k"
irname = rootname + "-lib.ir"
callname = rootname + "-call.k"
infile = open(inputname, "r")
libfile = open(libname, "w")
callfile = open(callname, "w")
print "Splitting %s into %s and %s" % (inputname, callname, libname)
for line in infile:
if not line.startswith("#"):
if line.startswith("print"):
callfile.write(line)
else:
libfile.write(line)
libGenScript.writeLibGenCall(libname, irname)
timingScript.writeTimingCall(irname, callname)
# Execution begins here
libGenScript = LibScriptGenerator("make-libs.sh")
timingScript = TimingScriptGenerator("time-lib.sh", "lib-timing.txt")
script_list = ["test-5000-3-50-50.k", "test-5000-10-100-10.k", "test-5000-10-5-10.k", "test-5000-10-1-0.k",
"test-1000-3-10-50.k", "test-1000-10-100-10.k", "test-1000-10-5-10.k", "test-1000-10-1-0.k",
"test-200-3-2-50.k", "test-200-10-40-10.k", "test-200-10-2-10.k", "test-200-10-1-0.k"]
for script in script_list:
splitScript(script, libGenScript, timingScript)
print "All done!"

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all: toy
toy : toy.cpp
clang++ toy.cpp -g -O3 -rdynamic -fno-rtti `llvm-config --cppflags --ldflags --libs core jit mcjit native irreader` -o toy

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//===----------------------------------------------------------------------===/
// Kaleidoscope with MCJIT
//===----------------------------------------------------------------------===//
The files in this directory are meant to accompany the first in a series of
three blog posts that describe the process of porting the Kaleidoscope tutorial
to use the MCJIT execution engine instead of the older JIT engine.
When the blog post is ready this file will be updated with a link to the post.
The source code in this directory combines all previous versions, including the
old JIT-based implementation, into a single file for easy comparison with
command line options to select between the various possibilities.
This directory contain a Makefile that allow the code to be built in a
standalone manner, independent of the larger LLVM build infrastructure. To build
the program you will need to have 'clang++' and 'llvm-config' in your path. If
you attempt to build using the LLVM 3.3 release, some minor modifications will
be required.
This directory also contains a Python script that may be used to generate random
input for the program and test scripts to capture data for rough performance
comparisons. Another Python script will split generated input files into
definitions and function calls for the purpose of testing the IR input and
caching facilities.

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#!/usr/bin/env python
import sys
import random
class TimingScriptGenerator:
"""Used to generate a bash script which will invoke the toy and time it"""
def __init__(self, scriptname, outputname):
self.timeFile = outputname
self.shfile = open(scriptname, 'w')
self.shfile.write("echo \"\" > %s\n" % self.timeFile)
def writeTimingCall(self, filename, numFuncs, funcsCalled, totalCalls):
"""Echo some comments and invoke both versions of toy"""
rootname = filename
if '.' in filename:
rootname = filename[:filename.rfind('.')]
self.shfile.write("echo \"%s: Calls %d of %d functions, %d total\" >> %s\n" % (filename, funcsCalled, numFuncs, totalCalls, self.timeFile))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"With MCJIT (original)\" >> %s\n" % self.timeFile)
self.shfile.write("/usr/bin/time -f \"Command %C\\n\\tuser time: %U s\\n\\tsytem time: %S s\\n\\tmax set: %M kb\"")
self.shfile.write(" -o %s -a " % self.timeFile)
self.shfile.write("./toy -suppress-prompts -use-mcjit=true -enable-lazy-compilation=false < %s > %s-mcjit.out 2> %s-mcjit.err\n" % (filename, rootname, rootname))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"With MCJIT (lazy)\" >> %s\n" % self.timeFile)
self.shfile.write("/usr/bin/time -f \"Command %C\\n\\tuser time: %U s\\n\\tsytem time: %S s\\n\\tmax set: %M kb\"")
self.shfile.write(" -o %s -a " % self.timeFile)
self.shfile.write("./toy -suppress-prompts -use-mcjit=true -enable-lazy-compilation=true < %s > %s-mcjit-lazy.out 2> %s-mcjit-lazy.err\n" % (filename, rootname, rootname))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"With JIT\" >> %s\n" % self.timeFile)
self.shfile.write("/usr/bin/time -f \"Command %C\\n\\tuser time: %U s\\n\\tsytem time: %S s\\n\\tmax set: %M kb\"")
self.shfile.write(" -o %s -a " % self.timeFile)
self.shfile.write("./toy -suppress-prompts -use-mcjit=false < %s > %s-jit.out 2> %s-jit.err\n" % (filename, rootname, rootname))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
class KScriptGenerator:
"""Used to generate random Kaleidoscope code"""
def __init__(self, filename):
self.kfile = open(filename, 'w')
self.nextFuncNum = 1
self.lastFuncNum = None
self.callWeighting = 0.1
# A mapping of calls within functions with no duplicates
self.calledFunctionTable = {}
# A list of function calls which will actually be executed
self.calledFunctions = []
# A comprehensive mapping of calls within functions
# used for computing the total number of calls
self.comprehensiveCalledFunctionTable = {}
self.totalCallsExecuted = 0
def updateTotalCallCount(self, callee):
# Count this call
self.totalCallsExecuted += 1
# Then count all the functions it calls
if callee in self.comprehensiveCalledFunctionTable:
for child in self.comprehensiveCalledFunctionTable[callee]:
self.updateTotalCallCount(child)
def updateFunctionCallMap(self, caller, callee):
"""Maintains a map of functions that are called from other functions"""
if not caller in self.calledFunctionTable:
self.calledFunctionTable[caller] = []
if not callee in self.calledFunctionTable[caller]:
self.calledFunctionTable[caller].append(callee)
if not caller in self.comprehensiveCalledFunctionTable:
self.comprehensiveCalledFunctionTable[caller] = []
self.comprehensiveCalledFunctionTable[caller].append(callee)
def updateCalledFunctionList(self, callee):
"""Maintains a list of functions that will actually be called"""
# Update the total call count
self.updateTotalCallCount(callee)
# If this function is already in the list, don't do anything else
if callee in self.calledFunctions:
return
# Add this function to the list of those that will be called.
self.calledFunctions.append(callee)
# If this function calls other functions, add them too
if callee in self.calledFunctionTable:
for subCallee in self.calledFunctionTable[callee]:
self.updateCalledFunctionList(subCallee)
def setCallWeighting(self, weight):
""" Sets the probably of generating a function call"""
self.callWeighting = weight
def writeln(self, line):
self.kfile.write(line + '\n')
def writeComment(self, comment):
self.writeln('# ' + comment)
def writeEmptyLine(self):
self.writeln("")
def writePredefinedFunctions(self):
self.writeComment("Define ':' for sequencing: as a low-precedence operator that ignores operands")
self.writeComment("and just returns the RHS.")
self.writeln("def binary : 1 (x y) y;")
self.writeEmptyLine()
self.writeComment("Helper functions defined within toy")
self.writeln("extern putchard(x);")
self.writeln("extern printd(d);")
self.writeln("extern printlf();")
self.writeEmptyLine()
self.writeComment("Print the result of a function call")
self.writeln("def printresult(N Result)")
self.writeln(" # 'result('")
self.writeln(" putchard(114) : putchard(101) : putchard(115) : putchard(117) : putchard(108) : putchard(116) : putchard(40) :")
self.writeln(" printd(N) :");
self.writeln(" # ') = '")
self.writeln(" putchard(41) : putchard(32) : putchard(61) : putchard(32) :")
self.writeln(" printd(Result) :");
self.writeln(" printlf();")
self.writeEmptyLine()
def writeRandomOperation(self, LValue, LHS, RHS):
shouldCallFunc = (self.lastFuncNum > 2 and random.random() < self.callWeighting)
if shouldCallFunc:
funcToCall = random.randrange(1, self.lastFuncNum - 1)
self.updateFunctionCallMap(self.lastFuncNum, funcToCall)
self.writeln(" %s = func%d(%s, %s) :" % (LValue, funcToCall, LHS, RHS))
else:
possibleOperations = ["+", "-", "*", "/"]
operation = random.choice(possibleOperations)
if operation == "-":
# Don't let our intermediate value become zero
# This is complicated by the fact that '<' is our only comparison operator
self.writeln(" if %s < %s then" % (LHS, RHS))
self.writeln(" %s = %s %s %s" % (LValue, LHS, operation, RHS))
self.writeln(" else if %s < %s then" % (RHS, LHS))
self.writeln(" %s = %s %s %s" % (LValue, LHS, operation, RHS))
self.writeln(" else")
self.writeln(" %s = %s %s %f :" % (LValue, LHS, operation, random.uniform(1, 100)))
else:
self.writeln(" %s = %s %s %s :" % (LValue, LHS, operation, RHS))
def getNextFuncNum(self):
result = self.nextFuncNum
self.nextFuncNum += 1
self.lastFuncNum = result
return result
def writeFunction(self, elements):
funcNum = self.getNextFuncNum()
self.writeComment("Auto-generated function number %d" % funcNum)
self.writeln("def func%d(X Y)" % funcNum)
self.writeln(" var temp1 = X,")
self.writeln(" temp2 = Y,")
self.writeln(" temp3 in")
# Initialize the variable names to be rotated
first = "temp3"
second = "temp1"
third = "temp2"
# Write some random operations
for i in range(elements):
self.writeRandomOperation(first, second, third)
# Rotate the variables
temp = first
first = second
second = third
third = temp
self.writeln(" " + third + ";")
self.writeEmptyLine()
def writeFunctionCall(self):
self.writeComment("Call the last function")
arg1 = random.uniform(1, 100)
arg2 = random.uniform(1, 100)
self.writeln("printresult(%d, func%d(%f, %f) )" % (self.lastFuncNum, self.lastFuncNum, arg1, arg2))
self.writeEmptyLine()
self.updateCalledFunctionList(self.lastFuncNum)
def writeFinalFunctionCounts(self):
self.writeComment("Called %d of %d functions" % (len(self.calledFunctions), self.lastFuncNum))
def generateKScript(filename, numFuncs, elementsPerFunc, funcsBetweenExec, callWeighting, timingScript):
""" Generate a random Kaleidoscope script based on the given parameters """
print "Generating " + filename
print(" %d functions, %d elements per function, %d functions between execution" %
(numFuncs, elementsPerFunc, funcsBetweenExec))
print(" Call weighting = %f" % callWeighting)
script = KScriptGenerator(filename)
script.setCallWeighting(callWeighting)
script.writeComment("===========================================================================")
script.writeComment("Auto-generated script")
script.writeComment(" %d functions, %d elements per function, %d functions between execution"
% (numFuncs, elementsPerFunc, funcsBetweenExec))
script.writeComment(" call weighting = %f" % callWeighting)
script.writeComment("===========================================================================")
script.writeEmptyLine()
script.writePredefinedFunctions()
funcsSinceLastExec = 0
for i in range(numFuncs):
script.writeFunction(elementsPerFunc)
funcsSinceLastExec += 1
if funcsSinceLastExec == funcsBetweenExec:
script.writeFunctionCall()
funcsSinceLastExec = 0
# Always end with a function call
if funcsSinceLastExec > 0:
script.writeFunctionCall()
script.writeEmptyLine()
script.writeFinalFunctionCounts()
funcsCalled = len(script.calledFunctions)
print " Called %d of %d functions, %d total" % (funcsCalled, numFuncs, script.totalCallsExecuted)
timingScript.writeTimingCall(filename, numFuncs, funcsCalled, script.totalCallsExecuted)
# Execution begins here
random.seed()
timingScript = TimingScriptGenerator("time-toy.sh", "timing-data.txt")
dataSets = [(5000, 3, 50, 0.50), (5000, 10, 100, 0.10), (5000, 10, 5, 0.10), (5000, 10, 1, 0.0),
(1000, 3, 10, 0.50), (1000, 10, 100, 0.10), (1000, 10, 5, 0.10), (1000, 10, 1, 0.0),
( 200, 3, 2, 0.50), ( 200, 10, 40, 0.10), ( 200, 10, 2, 0.10), ( 200, 10, 1, 0.0)]
# Generate the code
for (numFuncs, elementsPerFunc, funcsBetweenExec, callWeighting) in dataSets:
filename = "test-%d-%d-%d-%d.k" % (numFuncs, elementsPerFunc, funcsBetweenExec, int(callWeighting * 100))
generateKScript(filename, numFuncs, elementsPerFunc, funcsBetweenExec, callWeighting, timingScript)
print "All done!"

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#!/usr/bin/env python
class TimingScriptGenerator:
"""Used to generate a bash script which will invoke the toy and time it"""
def __init__(self, scriptname, outputname):
self.shfile = open(scriptname, 'w')
self.timeFile = outputname
self.shfile.write("echo \"\" > %s\n" % self.timeFile)
def writeTimingCall(self, irname, callname):
"""Echo some comments and invoke both versions of toy"""
rootname = irname
if '.' in irname:
rootname = irname[:irname.rfind('.')]
self.shfile.write("echo \"%s: Calls %s\" >> %s\n" % (callname, irname, self.timeFile))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"With MCJIT\" >> %s\n" % self.timeFile)
self.shfile.write("/usr/bin/time -f \"Command %C\\n\\tuser time: %U s\\n\\tsytem time: %S s\\n\\tmax set: %M kb\"")
self.shfile.write(" -o %s -a " % self.timeFile)
self.shfile.write("./toy -suppress-prompts -use-mcjit=true -enable-lazy-compilation=true -use-object-cache -input-IR=%s < %s > %s-mcjit.out 2> %s-mcjit.err\n" % (irname, callname, rootname, rootname))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"With MCJIT again\" >> %s\n" % self.timeFile)
self.shfile.write("/usr/bin/time -f \"Command %C\\n\\tuser time: %U s\\n\\tsytem time: %S s\\n\\tmax set: %M kb\"")
self.shfile.write(" -o %s -a " % self.timeFile)
self.shfile.write("./toy -suppress-prompts -use-mcjit=true -enable-lazy-compilation=true -use-object-cache -input-IR=%s < %s > %s-mcjit.out 2> %s-mcjit.err\n" % (irname, callname, rootname, rootname))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"With JIT\" >> %s\n" % self.timeFile)
self.shfile.write("/usr/bin/time -f \"Command %C\\n\\tuser time: %U s\\n\\tsytem time: %S s\\n\\tmax set: %M kb\"")
self.shfile.write(" -o %s -a " % self.timeFile)
self.shfile.write("./toy -suppress-prompts -use-mcjit=false -input-IR=%s < %s > %s-mcjit.out 2> %s-mcjit.err\n" % (irname, callname, rootname, rootname))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
class LibScriptGenerator:
"""Used to generate a bash script which will invoke the toy and time it"""
def __init__(self, filename):
self.shfile = open(filename, 'w')
def writeLibGenCall(self, libname, irname):
self.shfile.write("./toy -suppress-prompts -use-mcjit=false -dump-modules < %s 2> %s\n" % (libname, irname))
def splitScript(inputname, libGenScript, timingScript):
rootname = inputname[:-2]
libname = rootname + "-lib.k"
irname = rootname + "-lib.ir"
callname = rootname + "-call.k"
infile = open(inputname, "r")
libfile = open(libname, "w")
callfile = open(callname, "w")
print "Splitting %s into %s and %s" % (inputname, callname, libname)
for line in infile:
if not line.startswith("#"):
if line.startswith("print"):
callfile.write(line)
else:
libfile.write(line)
libGenScript.writeLibGenCall(libname, irname)
timingScript.writeTimingCall(irname, callname)
# Execution begins here
libGenScript = LibScriptGenerator("make-libs.sh")
timingScript = TimingScriptGenerator("time-lib.sh", "lib-timing.txt")
script_list = ["test-5000-3-50-50.k", "test-5000-10-100-10.k", "test-5000-10-5-10.k", "test-5000-10-1-0.k",
"test-1000-3-10-50.k", "test-1000-10-100-10.k", "test-1000-10-5-10.k", "test-1000-10-1-0.k",
"test-200-3-2-50.k", "test-200-10-40-10.k", "test-200-10-2-10.k", "test-200-10-1-0.k"]
for script in script_list:
splitScript(script, libGenScript, timingScript)
print "All done!"

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all: toy-mcjit
toy-mcjit : toy.cpp
clang++ toy.cpp -g -O3 -rdynamic -fno-rtti `llvm-config --cppflags --ldflags --libs core mcjit native` -o toy-mcjit

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//===----------------------------------------------------------------------===/
// Kaleidoscope with MCJIT
//===----------------------------------------------------------------------===//
The files in this directory are meant to accompany the first in a series of
three blog posts that describe the process of porting the Kaleidoscope tutorial
to use the MCJIT execution engine instead of the older JIT engine.
When the blog post is ready this file will be updated with a link to the post.
The source code in this directory demonstrates the initial working version of
the program before subsequent performance improvements are applied.
This directory contain a Makefile that allow the code to be built in a
standalone manner, independent of the larger LLVM build infrastructure. To build
the program you will need to have 'clang++' and 'llvm-config' in your path. If
you attempt to build using the LLVM 3.3 release, some minor modifications will
be required, as mentioned in the blog posts.

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all: toy-mcjit toy-jit
toy-mcjit : toy.cpp
clang++ toy.cpp -g -O3 -rdynamic -fno-rtti `llvm-config --cppflags --ldflags --libs core mcjit native` -o toy-mcjit
toy-jit : toy-jit.cpp
clang++ toy-jit.cpp -g -O3 -rdynamic `llvm-config --cppflags --ldflags --libs core jit native` -o toy-jit

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//===----------------------------------------------------------------------===/
// Kaleidoscope with MCJIT
//===----------------------------------------------------------------------===//
The files in this directory are meant to accompany the first in a series of
three blog posts that describe the process of porting the Kaleidoscope tutorial
to use the MCJIT execution engine instead of the older JIT engine.
When the blog post is ready this file will be updated with a link to the post.
The source code in this directory demonstrates the second version of the
program, now modified to implement a sort of 'lazy' compilation.
The toy-jit.cpp file contains a version of the original JIT-based source code
that has been modified to disable most stderr output for timing purposes.
This directory contain a Makefile that allow the code to be built in a
standalone manner, independent of the larger LLVM build infrastructure. To build
the program you will need to have 'clang++' and 'llvm-config' in your path. If
you attempt to build using the LLVM 3.3 release, some minor modifications will
be required.
This directory also contains a Python script that may be used to generate random
input for the program and test scripts to capture data for rough performance
comparisons.

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#!/usr/bin/env python
import sys
import random
class TimingScriptGenerator:
"""Used to generate a bash script which will invoke the toy and time it"""
def __init__(self, scriptname, outputname):
self.timeFile = outputname
self.shfile = open(scriptname, 'w')
self.shfile.write("echo \"\" > %s\n" % self.timeFile)
def writeTimingCall(self, filename, numFuncs, funcsCalled, totalCalls):
"""Echo some comments and invoke both versions of toy"""
rootname = filename
if '.' in filename:
rootname = filename[:filename.rfind('.')]
self.shfile.write("echo \"%s: Calls %d of %d functions, %d total\" >> %s\n" % (filename, funcsCalled, numFuncs, totalCalls, self.timeFile))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"With MCJIT\" >> %s\n" % self.timeFile)
self.shfile.write("/usr/bin/time -f \"Command %C\\n\\tuser time: %U s\\n\\tsytem time: %S s\\n\\tmax set: %M kb\"")
self.shfile.write(" -o %s -a " % self.timeFile)
self.shfile.write("./toy-mcjit < %s > %s-mcjit.out 2> %s-mcjit.err\n" % (filename, rootname, rootname))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"With JIT\" >> %s\n" % self.timeFile)
self.shfile.write("/usr/bin/time -f \"Command %C\\n\\tuser time: %U s\\n\\tsytem time: %S s\\n\\tmax set: %M kb\"")
self.shfile.write(" -o %s -a " % self.timeFile)
self.shfile.write("./toy-jit < %s > %s-jit.out 2> %s-jit.err\n" % (filename, rootname, rootname))
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
self.shfile.write("echo \"\" >> %s\n" % self.timeFile)
class KScriptGenerator:
"""Used to generate random Kaleidoscope code"""
def __init__(self, filename):
self.kfile = open(filename, 'w')
self.nextFuncNum = 1
self.lastFuncNum = None
self.callWeighting = 0.1
# A mapping of calls within functions with no duplicates
self.calledFunctionTable = {}
# A list of function calls which will actually be executed
self.calledFunctions = []
# A comprehensive mapping of calls within functions
# used for computing the total number of calls
self.comprehensiveCalledFunctionTable = {}
self.totalCallsExecuted = 0
def updateTotalCallCount(self, callee):
# Count this call
self.totalCallsExecuted += 1
# Then count all the functions it calls
if callee in self.comprehensiveCalledFunctionTable:
for child in self.comprehensiveCalledFunctionTable[callee]:
self.updateTotalCallCount(child)
def updateFunctionCallMap(self, caller, callee):
"""Maintains a map of functions that are called from other functions"""
if not caller in self.calledFunctionTable:
self.calledFunctionTable[caller] = []
if not callee in self.calledFunctionTable[caller]:
self.calledFunctionTable[caller].append(callee)
if not caller in self.comprehensiveCalledFunctionTable:
self.comprehensiveCalledFunctionTable[caller] = []
self.comprehensiveCalledFunctionTable[caller].append(callee)
def updateCalledFunctionList(self, callee):
"""Maintains a list of functions that will actually be called"""
# Update the total call count
self.updateTotalCallCount(callee)
# If this function is already in the list, don't do anything else
if callee in self.calledFunctions:
return
# Add this function to the list of those that will be called.
self.calledFunctions.append(callee)
# If this function calls other functions, add them too
if callee in self.calledFunctionTable:
for subCallee in self.calledFunctionTable[callee]:
self.updateCalledFunctionList(subCallee)
def setCallWeighting(self, weight):
""" Sets the probably of generating a function call"""
self.callWeighting = weight
def writeln(self, line):
self.kfile.write(line + '\n')
def writeComment(self, comment):
self.writeln('# ' + comment)
def writeEmptyLine(self):
self.writeln("")
def writePredefinedFunctions(self):
self.writeComment("Define ':' for sequencing: as a low-precedence operator that ignores operands")
self.writeComment("and just returns the RHS.")
self.writeln("def binary : 1 (x y) y;")
self.writeEmptyLine()
self.writeComment("Helper functions defined within toy")
self.writeln("extern putchard(x);")
self.writeln("extern printd(d);")
self.writeln("extern printlf();")
self.writeEmptyLine()
self.writeComment("Print the result of a function call")
self.writeln("def printresult(N Result)")
self.writeln(" # 'result('")
self.writeln(" putchard(114) : putchard(101) : putchard(115) : putchard(117) : putchard(108) : putchard(116) : putchard(40) :")
self.writeln(" printd(N) :");
self.writeln(" # ') = '")
self.writeln(" putchard(41) : putchard(32) : putchard(61) : putchard(32) :")
self.writeln(" printd(Result) :");
self.writeln(" printlf();")
self.writeEmptyLine()
def writeRandomOperation(self, LValue, LHS, RHS):
shouldCallFunc = (self.lastFuncNum > 2 and random.random() < self.callWeighting)
if shouldCallFunc:
funcToCall = random.randrange(1, self.lastFuncNum - 1)
self.updateFunctionCallMap(self.lastFuncNum, funcToCall)
self.writeln(" %s = func%d(%s, %s) :" % (LValue, funcToCall, LHS, RHS))
else:
possibleOperations = ["+", "-", "*", "/"]
operation = random.choice(possibleOperations)
if operation == "-":
# Don't let our intermediate value become zero
# This is complicated by the fact that '<' is our only comparison operator
self.writeln(" if %s < %s then" % (LHS, RHS))
self.writeln(" %s = %s %s %s" % (LValue, LHS, operation, RHS))
self.writeln(" else if %s < %s then" % (RHS, LHS))
self.writeln(" %s = %s %s %s" % (LValue, LHS, operation, RHS))
self.writeln(" else")
self.writeln(" %s = %s %s %f :" % (LValue, LHS, operation, random.uniform(1, 100)))
else:
self.writeln(" %s = %s %s %s :" % (LValue, LHS, operation, RHS))
def getNextFuncNum(self):
result = self.nextFuncNum
self.nextFuncNum += 1
self.lastFuncNum = result
return result
def writeFunction(self, elements):
funcNum = self.getNextFuncNum()
self.writeComment("Auto-generated function number %d" % funcNum)
self.writeln("def func%d(X Y)" % funcNum)
self.writeln(" var temp1 = X,")
self.writeln(" temp2 = Y,")
self.writeln(" temp3 in")
# Initialize the variable names to be rotated
first = "temp3"
second = "temp1"
third = "temp2"
# Write some random operations
for i in range(elements):
self.writeRandomOperation(first, second, third)
# Rotate the variables
temp = first
first = second
second = third
third = temp
self.writeln(" " + third + ";")
self.writeEmptyLine()
def writeFunctionCall(self):
self.writeComment("Call the last function")
arg1 = random.uniform(1, 100)
arg2 = random.uniform(1, 100)
self.writeln("printresult(%d, func%d(%f, %f) )" % (self.lastFuncNum, self.lastFuncNum, arg1, arg2))
self.writeEmptyLine()
self.updateCalledFunctionList(self.lastFuncNum)
def writeFinalFunctionCounts(self):
self.writeComment("Called %d of %d functions" % (len(self.calledFunctions), self.lastFuncNum))
def generateKScript(filename, numFuncs, elementsPerFunc, funcsBetweenExec, callWeighting, timingScript):
""" Generate a random Kaleidoscope script based on the given parameters """
print "Generating " + filename
print(" %d functions, %d elements per function, %d functions between execution" %
(numFuncs, elementsPerFunc, funcsBetweenExec))
print(" Call weighting = %f" % callWeighting)
script = KScriptGenerator(filename)
script.setCallWeighting(callWeighting)
script.writeComment("===========================================================================")
script.writeComment("Auto-generated script")
script.writeComment(" %d functions, %d elements per function, %d functions between execution"
% (numFuncs, elementsPerFunc, funcsBetweenExec))
script.writeComment(" call weighting = %f" % callWeighting)
script.writeComment("===========================================================================")
script.writeEmptyLine()
script.writePredefinedFunctions()
funcsSinceLastExec = 0
for i in range(numFuncs):
script.writeFunction(elementsPerFunc)
funcsSinceLastExec += 1
if funcsSinceLastExec == funcsBetweenExec:
script.writeFunctionCall()
funcsSinceLastExec = 0
# Always end with a function call
if funcsSinceLastExec > 0:
script.writeFunctionCall()
script.writeEmptyLine()
script.writeFinalFunctionCounts()
funcsCalled = len(script.calledFunctions)
print " Called %d of %d functions, %d total" % (funcsCalled, numFuncs, script.totalCallsExecuted)
timingScript.writeTimingCall(filename, numFuncs, funcsCalled, script.totalCallsExecuted)
# Execution begins here
random.seed()
timingScript = TimingScriptGenerator("time-toy.sh", "timing-data.txt")
dataSets = [(5000, 3, 50, 0.50), (5000, 10, 100, 0.10), (5000, 10, 5, 0.10), (5000, 10, 1, 0.0),
(1000, 3, 10, 0.50), (1000, 10, 100, 0.10), (1000, 10, 5, 0.10), (1000, 10, 1, 0.0),
( 200, 3, 2, 0.50), ( 200, 10, 40, 0.10), ( 200, 10, 2, 0.10), ( 200, 10, 1, 0.0)]
# Generate the code
for (numFuncs, elementsPerFunc, funcsBetweenExec, callWeighting) in dataSets:
filename = "test-%d-%d-%d-%d.k" % (numFuncs, elementsPerFunc, funcsBetweenExec, int(callWeighting * 100))
generateKScript(filename, numFuncs, elementsPerFunc, funcsBetweenExec, callWeighting, timingScript)
print "All done!"

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