From e5e2676409a936431f87d31fb74d825257b20804 Mon Sep 17 00:00:00 2001
From: Eric Kunze <eric.kunze@arm.com>
Date: Tue, 13 Oct 2020 16:11:07 -0700
Subject: Initial checkin of TOSA reference_model and tests

Change-Id: I2f8e7fa63e2ae40203e57d2cc8814bde3b312cb6
Signed-off-by: Eric Kunze <eric.kunze@arm.com>
---
 verif/tosa_serializer.py | 718 +++++++++++++++++++++++++++++++++++++++++++++++
 1 file changed, 718 insertions(+)
 create mode 100644 verif/tosa_serializer.py

(limited to 'verif/tosa_serializer.py')

diff --git a/verif/tosa_serializer.py b/verif/tosa_serializer.py
new file mode 100644
index 0000000..7ba68c3
--- /dev/null
+++ b/verif/tosa_serializer.py
@@ -0,0 +1,718 @@
+
+
+# Copyright (c) 2020, ARM Limited.
+#
+#    Licensed under the Apache License, Version 2.0 (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.apache.org/licenses/LICENSE-2.0
+#
+#    Unless required by applicable law or agreed to in writing, software
+#    distributed under the License is distributed on an "AS IS" BASIS,
+#    WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+#    See the License for the specific language governing permissions and
+#    limitations under the License.
+
+#!/usr/bin/env python3
+
+import flatbuffers
+import numpy as np
+from enum import Enum, IntEnum, unique
+from tosa import TosaGraph, TosaBasicBlock, TosaTensor, TosaOperator, DType, Format, Usage, Op, ResizeMode, Version
+import tosa
+import os
+import json
+
+# With the way flatc generates its python types, there is no programatic way
+# to get string names for the integer types.  Manually maintain a string table
+# here.
+DTypeNames = [ 'UNKNOWN',
+               'BOOL',
+               'AINT8',
+               'UINT8',
+               'INT4',
+               'INT8',
+               'INT16',
+               'INT32',
+               'INT48',
+               'FLOAT' ]
+
+def dtype_str_to_val(name):
+
+    for i in range(len(DTypeNames)):
+        if name.casefold() == DTypeNames[i].casefold():
+            return i
+    raise Exception('Unable to parse DType name {}'.format(name))
+
+
+class TosaSerializerUnion:
+    '''This class handles encapsulating and serializing union types into flatbuffers'''
+    def __init__(self):
+
+        # A tuple of the start and end functions.  Set by the options constructors below
+        self.optFcns = None
+
+        # The type from the tosa.Options enumeration.  Set by the options constructors below.
+        self.utype = None
+
+        # Each of these lists is a tuple of the add function and the
+        # value being added.  Set by the options constructors below.
+        self.ints = []
+        self.bools = []
+        self.floats = []
+        self.strings = []
+        self.intvecs = []
+
+    def serialize(self, builder):
+
+        # We have to build strings and vectors first
+        strList = []
+        intVecList = []
+
+        for fcn, val in self.strings:
+            strList.append((fcn, builder.CreateString(val)))
+
+        for fcn, val in self.intvecs:
+            intVecList.append((fcn, TosaSerializer.serializeInt32Vec(builder, val)))
+
+        startFcn, endFcn = self.optFcns
+
+        # Then serialize the options object from the list of primitives and
+        # other serialized values
+        startFcn(builder)
+        for fcn, val in self.ints:
+            fcn(builder, val)
+
+        for fcn, val in self.bools:
+            fcn(builder, val)
+
+        for fcn, val in self.floats:
+            fcn(builder, val)
+
+        for fcn, val in strList:
+            fcn(builder, val)
+
+        for fcn, val in intVecList:
+            fcn(builder, val)
+
+        return endFcn(builder)
+
+class TosaSerializerAttribute(TosaSerializerUnion):
+    '''This class handles encapsulating all of the enumerated types for attributes'''
+
+    def __init__(self):
+        super().__init__()
+
+    def Pool2dAttribute(self, kernel, stride, padding):
+        from tosa import Pool2dAttribute as a, Attribute
+
+        self.utype = Attribute.Attribute().Pool2dAttribute
+
+        self.optFcns = (a.Pool2dAttributeStart, a.Pool2dAttributeEnd)
+        self.intvecs.append((a.Pool2dAttributeAddPadding,
+                             padding))
+        self.intvecs.append((a.Pool2dAttributeAddKernel,
+                             kernel))
+        self.intvecs.append((a.Pool2dAttributeAddStride,
+                             stride))
+
+    def Conv2dAttribute(self, padding, stride, dilation):
+        from tosa import Conv2dAttribute as a, Attribute
+
+        self.utype = Attribute.Attribute().Conv2dAttribute
+        self.optFcns = (a.Conv2dAttributeStart, a.Conv2dAttributeEnd)
+
+        self.intvecs.append((a.Conv2dAttributeAddPadding,
+                             padding))
+        self.intvecs.append((a.Conv2dAttributeAddStride,
+                             stride))
+        self.intvecs.append((a.Conv2dAttributeAddDilation,
+                             dilation))
+
+    def TransposeConv2DAttribute(self, outpad, stride, dilation, output_shape):
+        from tosa import TransposeConv2dAttribute as a, Attribute
+
+        self.utype = Attribute.Attribute().TransposeConv2dAttribute
+        self.optFcns = (a.TransposeConv2dAttributeStart, a.TransposeConv2dAttributeEnd)
+
+        self.intvecs.append((a.TransposeConv2dAttributeAddOutpad,
+                             outpad))
+        self.intvecs.append((a.TransposeConv2dAttributeAddStride,
+                             stride))
+        self.intvecs.append((a.TransposeConv2dAttributeAddDilation,
+                             dilation))
+        self.intvecs.append((a.TransposeConv2dAttributeAddOutputShape,
+                             output_shape))
+
+    def ReluNAttribute(self, maxint, maxfp):
+        from tosa import ReluNAttribute as a, Attribute
+
+        self.utype = Attribute.Attribute().ReluNAttribute
+        self.optFcns = (a.ReluNAttributeStart, a.ReluNAttributeEnd)
+
+        self.ints.append((a.ReluNAttributeAddMaxInt, maxint))
+        self.ints.append((a.ReluNAttributeAddMaxFp, maxfp))
+
+
+    def AxisAttribute(self, axis):
+        from tosa import AxisAttribute as a, Attribute
+
+        self.utype = Attribute.Attribute().AxisAttribute
+        self.optFcns = (a.AxisAttributeStart, a.AxisAttributeEnd)
+
+        self.ints.append((a.AxisAttributeAddAxis,
+                          axis))
+
+    def ReshapeAttribute(self, shape):
+        from tosa import ReshapeAttribute as a, Attribute
+
+        self.utype = Attribute.Attribute().ReshapeAttribute
+        self.optFcns = (a.ReshapeAttributeStart, a.ReshapeAttributeEnd)
+
+        self.intvecs.append((a.ReshapeAttributeAddShape,
+                             shape))
+
+    def SliceAttribute(self, begin, size):
+        from tosa import SliceAttribute as a, Attribute
+
+        self.utype = Attribute.Attribute().SliceAttribute
+        self.optFcns = (a.SliceAttributeStart, a.SliceAttributeEnd)
+
+        self.intvecs.append((a.SliceAttributeAddBegin,
+                             begin))
+        self.intvecs.append((a.SliceAttributeAddSize,
+                             size))
+
+    def TileAttribute(self, multiples):
+        from tosa import TileAttribute as a, Attribute
+
+        self.utype = Attribute.Attribute().TileAttribute
+        self.optFcns = (a.TileAttributeStart, a.TileAttributeEnd)
+
+        self.intvecs.append((a.TileAttributeAddMultiples,
+                             multiples))
+
+    def ResizeAttribute(self, output_size, stride, offset, shift, mode):
+        from tosa import ResizeAttribute as a, Attribute
+
+        self.utype = Attribute.Attribute().ResizeAttribute
+        self.optFcns = (a.ResizeAttributeStart, a.ResizeAttributeEnd)
+
+        self.intvecs.append((a.ResizeAttributeAddOutputSize,
+                             output_size))
+        self.intvecs.append((a.ResizeAttributeAddStride,
+                             stride))
+        self.intvecs.append((a.ResizeAttributeAddOffset,
+                             offset))
+        self.ints.append((a.ResizeAttributeAddShift,
+                         shift))
+        self.ints.append((a.ResizeAttributeAddMode,
+                         mode))
+
+    def ClampAttribute(self, minint, maxint, minfp, maxfp):
+        from tosa import ClampAttribute as a, Attribute
+
+        self.utype = Attribute.Attribute().ClampAttribute
+        self.optFcns = (a.ClampAttributeStart, a.ClampAttributeEnd)
+
+        self.ints.append((a.ClampAttributeAddMinInt,
+                          minint))
+        self.ints.append((a.ClampAttributeAddMaxInt,
+                          maxint))
+
+        self.ints.append((a.ClampAttributeAddMinFp,
+                          minfp))
+        self.ints.append((a.ClampAttributeAddMaxFp,
+                          maxfp))
+
+    def RescaleAttribute(self, input_zp, output_zp, multiplier, shift, scale32, double_round, per_channel):
+        from tosa import RescaleAttribute as a, Attribute
+
+        self.utype = Attribute.Attribute().RescaleAttribute
+        self.optFcns = (a.RescaleAttributeStart, a.RescaleAttributeEnd)
+
+        self.ints.append((a.RescaleAttributeAddInputZp,
+                         input_zp))
+        self.ints.append((a.RescaleAttributeAddOutputZp,
+                         output_zp))
+        self.intvecs.append((a.RescaleAttributeAddMultiplier,
+                             multiplier))
+        self.intvecs.append((a.RescaleAttributeAddShift,
+                             shift))
+        self.bools.append((a.RescaleAttributeAddScale32,
+                           scale32))
+        self.bools.append((a.RescaleAttributeAddDoubleRound,
+                           double_round))
+        self.bools.append((a.RescaleAttributeAddPerChannel,
+                           per_channel))
+
+    def CustomAttribute(self, identifier):
+        from tosa import CustomAttribute as a, Attribute
+
+        self.utype = Attribute.Attribute().CustomAttribute
+        self.optFcns = (a.CustomAttributeStart, a.CustomAttributeEnd)
+
+        self.strings.append((a.CustomAttributeAddIdentifier,
+                         identifier))
+
+    def CondIfAttribute(self, then_branch, else_branch):
+        from tosa import CondIfAttribute as a, Attribute
+
+        self.utype = Attribute.Attribute().CondIfAttribute
+        self.optFcns = (a.CondIfAttributeStart, a.CondIfAttributeEnd)
+
+        self.strings.append((a.CondIfAttributeAddThenBranch,
+                         then_branch))
+        self.strings.append((a.CondIfAttributeAddElseBranch,
+                         else_branch))
+
+    def WhileLoopAttribute(self, cond_branch, body_branch):
+        from tosa import WhileLoopAttribute as a, Attribute
+
+        self.utype = Attribute.Attribute().WhileLoopAttribute
+        self.optFcns = (a.WhileLoopAttributeStart, a.WhileLoopAttributeEnd)
+
+        self.strings.append((a.WhileLoopAttributeAddCondBranch,
+                         cond_branch))
+        self.strings.append((a.WhileLoopAttributeAddBodyBranch,
+                         body_branch))
+
+class TosaSerializerQuantInfo(TosaSerializerUnion):
+    '''This class handles encapsulating all of the enumerated types for quantinfo types'''
+    def __init__(self):
+        super().__init__()
+
+    def ConvQuantInfo(self, input_zp, weight_zp):
+        from tosa import ConvQuantInfo as q, QuantInfo
+
+        self.utype = QuantInfo.QuantInfo().ConvQuantInfo
+        self.optFcns = (q.ConvQuantInfoStart, q.ConvQuantInfoEnd)
+        self.ints.append((q.ConvQuantInfoAddInputZp, input_zp))
+        self.ints.append((q.ConvQuantInfoAddWeightZp, weight_zp))
+
+    def UnaryQuantInfo(self, input_zp, output_zp):
+        from tosa import UnaryQuantInfo as q, QuantInfo
+
+        self.utype = QuantInfo.QuantInfo().UnaryQuantInfo
+        self.optFcns = (q.UnaryQuantInfoStart, q.UnaryQuantInfoEnd)
+        self.ints.append((q.UnaryQuantInfoAddInputZp, input_zp))
+        self.ints.append((q.UnaryQuantInfoAddOutputZp, output_zp))
+
+    def MatMulQuantInfo(self, a_zp, b_zp):
+        from tosa import MatMulQuantInfo as q, QuantInfo
+
+        self.utype = QuantInfo.QuantInfo().MatMulQuantInfo
+        self.optFcns = (q.MatMulQuantInfoStart, q.MatMulQuantInfoEnd)
+        self.ints.append((q.MatMulQuantInfoAddAZp, a_zp))
+        self.ints.append((q.MatMulQuantInfoAddBZp, b_zp))
+
+    def PadQuantInfo(self, input_zp):
+        from tosa import PadQuantInfo as q, QuantInfo
+
+        self.utype = QuantInfo.QuantInfo().PadQuantInfo
+        self.optFcns = (q.PadQuantInfoStart, q.PadQuantInfoEnd)
+        self.ints.append((q.PadQuantInfoAddInputZp, input_zp))
+
+class TosaSerializerTensor:
+    def __init__(self, name, shape, dtype, usage, dformat, filename = None, placeholderFilename = None):
+        self.name = name
+
+        if isinstance(shape, np.ndarray):
+            shape = shape.astype(int).tolist()
+        shape = list(map(int, shape))
+
+        self.shape = shape
+        self.dtype = dtype
+        self.usage = TosaSerializer.toList(usage)
+        self.dformat = TosaSerializer.toList(dformat)
+
+        # Filename for const tensors.  This gets written to the .tosa serialization
+        self.filename = filename
+
+        # Filename for placeholder tensors.  These get generated by the test generation
+        # process and are written to disk, but are considered input tensors by the network
+        # so they do not appear in the TOSA serialiazation.  However, if we want to form a unit
+        # test around these input tensors, we can get the filename from here.
+        self.placeholderFilename = placeholderFilename
+
+    def __str__(self):
+        str = 'TosaSerializerTensor name: {} shape: {} dtype: {} Usage: {} format {} filename: {}'.format(
+            self.name, self.shape, DTypeNames[self.dtype], self.usage, self.dformat, self.filename)
+        return str
+
+    def addUsage(self, usage):
+        self.usage.append(usage)
+
+    def addFormat(self, format):
+        self.dformat.append(format)
+
+    def setDtype(self, dtype):
+        self.dtype = dtype
+
+    def merge(self, name, shape, dtype, usage, dformat, filename = None):
+        # Merge in additional usage/formats to the list
+        found = 0
+        for i in self.usage:
+            if i == usage:
+                found = 1
+                break
+        if not found:
+            self.usage.append(usage)
+
+        found = 0
+        for i in self.dformat:
+            if i == dformat:
+                found = 1
+                break
+        if not found:
+            self.dformat.append(dformat)
+
+    def serialize(self, builder):
+        fb_name = builder.CreateString(self.name)
+        if self.filename:
+            fb_filename = builder.CreateString(self.filename)
+        fb_shapes = TosaSerializer.serializeInt32Vec(builder, self.shape)
+        fb_usage = TosaSerializer.serializeInt32Vec(builder, self.usage)
+        fb_dformat = TosaSerializer.serializeInt32Vec(builder, self.dformat)
+
+        TosaTensor.TosaTensorStart(builder)
+        TosaTensor.TosaTensorAddName(builder, fb_name)
+        TosaTensor.TosaTensorAddShape(builder, fb_shapes)
+        TosaTensor.TosaTensorAddType(builder, self.dtype)
+        TosaTensor.TosaTensorAddUsage(builder, fb_usage)
+        TosaTensor.TosaTensorAddFormat(builder, fb_dformat)
+        if self.filename:
+            TosaTensor.TosaTensorAddNpyFilename(builder, fb_filename)
+
+        return TosaTensor.TosaTensorEnd(builder)
+
+class TosaSerializerOperator:
+    def __init__(self, op, inputs, outputs, attributes = None, quantInfo = None):
+        self.op = op
+        self.attributes = attributes
+        self.inputs = TosaSerializer.toList(inputs)
+        self.outputs = TosaSerializer.toList(outputs)
+        self.quantInfo = quantInfo
+
+    def __str__(self):
+        str = 'Op {}\n----\n'.format(self.op)
+
+        for i in self.inputs:
+            str = str + '  Input:  {}\n'.format(i)
+        for o in self.outputs:
+            str = str + '  Output: {}\n'.format(o)
+
+        return str
+
+    def serialize(self, builder):
+        fb_inputs = TosaSerializer.serializeStrVec(builder, self.inputs, TosaOperator.TosaOperatorStartInputsVector)
+        fb_outputs = TosaSerializer.serializeStrVec(builder, self.outputs, TosaOperator.TosaOperatorStartOutputsVector)
+        # Need to serialize quant_info and attributes enums still
+        if self.attributes is not None:
+            fb_attributes = self.attributes.serialize(builder)
+
+        if self.quantInfo is not None:
+            fb_qinfo = self.quantInfo.serialize(builder)
+
+        TosaOperator.TosaOperatorStart(builder)
+        TosaOperator.TosaOperatorAddOp(builder, self.op)
+        TosaOperator.TosaOperatorAddInputs(builder, fb_inputs)
+        TosaOperator.TosaOperatorAddOutputs(builder, fb_outputs)
+        if self.attributes is not None:
+            TosaOperator.TosaOperatorAddAttributeType(builder, self.attributes.utype)
+            TosaOperator.TosaOperatorAddAttribute(builder, fb_attributes)
+        if self.quantInfo is not None:
+            TosaOperator.TosaOperatorAddQuantInfoType(builder, self.quantInfo.utype)
+            TosaOperator.TosaOperatorAddQuantInfo(builder, fb_qinfo)
+
+        return TosaOperator.TosaOperatorEnd(builder)
+
+class TosaSerializerBasicBlock:
+    def __init__(self, name):
+        self.name = name
+        self.operators = []
+
+        # Dict assures uniqueness, but allows us to look up by name
+        self.tensors = dict()
+
+        self.inputs = []
+        self.outputs = []
+
+    def addTensor(self, name, shape, dtype, usage, dformat, filename = None, placeholderFilename = None):
+        try:
+            # Someone already added this tensor.
+            # We may have to add more usages and formats
+            tens = self.tensors[name]
+            filename = tens.merge(name, shape, dtype, usage, dformat, filename)
+        except KeyError:
+            self.tensors[name] = TosaSerializerTensor(name, shape, dtype, usage, dformat, filename, placeholderFilename)
+
+        return self.tensors[name]
+
+    def addInput(self, name):
+        self.inputs.append(name)
+
+    def addOutput(self, name):
+        self.outputs.append(name)
+
+    def addOperator(self, op, inputs, outputs, attributes = None, quant_info = None):
+        self.operators.append(TosaSerializerOperator(op, inputs, outputs, attributes, quant_info))
+
+    def serialize(self, builder):
+        fb_name = builder.CreateString(self.name)
+        fbv_inputs  = TosaSerializer.serializeStrVec(builder, list(self.inputs), TosaBasicBlock.TosaBasicBlockStartInputsVector)
+        fbv_outputs = TosaSerializer.serializeStrVec(builder, list(self.outputs), TosaBasicBlock.TosaBasicBlockStartOutputsVector)
+        fbv_tensors = TosaSerializer.serializeObjVec(builder, list(self.tensors.values()), TosaBasicBlock.TosaBasicBlockStartTensorsVector)
+        fbv_operators = TosaSerializer.serializeObjVec(builder, self.operators, TosaBasicBlock.TosaBasicBlockStartOperatorsVector)
+
+        TosaBasicBlock.TosaBasicBlockStart(builder)
+        TosaBasicBlock.TosaBasicBlockAddName(builder, fb_name)
+        TosaBasicBlock.TosaBasicBlockAddInputs(builder, fbv_inputs)
+        TosaBasicBlock.TosaBasicBlockAddOutputs(builder, fbv_outputs)
+        TosaBasicBlock.TosaBasicBlockAddTensors(builder, fbv_tensors)
+        TosaBasicBlock.TosaBasicBlockAddOperators(builder, fbv_operators)
+        return TosaBasicBlock.TosaBasicBlockEnd(builder)
+
+@unique
+class TensorDir(IntEnum):
+    PLACEHOLDER = 0
+    CONST = 1
+    INTERMEDIATE = 2
+    RESULT = 3
+
+class TosaSerializer:
+    def __init__(self, pathPrefix):
+
+        # Get the global TOSA version if not already defined
+        try:
+            TOSA_VERSION
+        except NameError:
+            TosaSerializer.setTosaVersion()
+
+        self.builder = flatbuffers.Builder(0)
+
+        self.basicBlocks = []
+        self.startBasicBlock('main')
+        self.pathPrefix = pathPrefix
+
+        # Indicies used for adding/naming tensors
+        self.currInputIdx = 0
+        self.currConstIdx = 0
+        self.currLayerIdx = 1
+        self.currResultIdx = 0
+
+        # Is this an illegal test that is expected to fail?
+        self.expectedFailure = False
+        self.expectedFailureDesc = ''
+
+    def __str__(self):
+        str = ''
+        for bb in self.basicBlocks:
+            str = str + bb.__str__()
+        return str
+
+    def addPlaceholder(self, shape, dtype, usage, dformat, vals):
+        if not self.currBasicBlock:
+            raise Exception('addTensor called without valid basic block')
+
+        name = 'input-{}'.format(self.currInputIdx)
+        filename = '{}.npy'.format(name)
+        self.currInputIdx = self.currInputIdx + 1
+
+        tens = self.currBasicBlock.addTensor(name, shape, dtype, usage, dformat, None, filename)
+        # This is always an input to the block
+        self.currBasicBlock.addInput(name)
+        # Add the operator now
+        self.currBasicBlock.addOperator(tosa.Op.Op().PLACEHOLDER, [], name)
+
+        if vals is not None:
+            np.save(os.path.join(self.pathPrefix, filename), vals, False)
+
+        return tens
+
+    def addConst(self, shape, dtype, usage, dformat, vals):
+        if not self.currBasicBlock:
+            raise Exception('addTensor called without valid basic block')
+
+        name = 'const-{}'.format(self.currInputIdx)
+        filename = '{}.npy'.format(name)
+        self.currInputIdx = self.currInputIdx + 1
+
+        tens = self.currBasicBlock.addTensor(name, shape, dtype, usage, dformat, filename)
+        # Add the operator now
+        self.currBasicBlock.addOperator(tosa.Op.Op().CONST, [], name)
+
+        if vals is not None:
+            np.save(os.path.join(self.pathPrefix, filename), vals, False)
+        return tens
+
+    def addIntermediate(self, shape, dtype, usage, dformat):
+
+        if not self.currBasicBlock:
+            raise Exception('addTensor called without valid basic block')
+
+        name = 'layer-{}'.format(self.currLayerIdx)
+        filename = None # No file, so no filename
+        self.currLayerIdx = self.currLayerIdx + 1
+
+        tens = self.currBasicBlock.addTensor(name, shape, dtype, usage, dformat, filename)
+
+        return tens
+
+    def addInputTensor(self, tensor):
+        self.currBasicBlock.addOperator(tosa.Op.Op().PLACEHOLDER, [], tensor.name)
+        self.currBasicBlock.addTensor(tensor.name, tensor.shape, tensor.dtype, tensor.usage, tensor.dformat)
+        self.currBasicBlock.addInput(tensor.name)
+
+    def addOutputTensor(self, tensor):
+        self.currBasicBlock.addOutput(tensor.name)
+
+    def addOutput(self, shape, dtype, usage, dformat):
+        if not self.currBasicBlock:
+            raise Exception('addTensor called without valid basic block')
+
+        name = 'result-{}'.format(self.currResultIdx)
+        self.currResultIdx = self.currResultIdx + 1
+
+        tens = self.currBasicBlock.addTensor(name, shape, dtype, usage, dformat, None)
+        self.currBasicBlock.addOutput(name)
+        return tens
+
+    def addOperator(self, op, inputs, outputs, attributes = None, quant_info = None):
+
+        if op == tosa.Op.Op().PLACEHOLDER or \
+           op == tosa.Op.Op().CONST:
+            raise Exception('Use addPlaceholderTensor() or addConstTensor() to add PLACEHOLDER and CONST ops')
+
+        return self.currBasicBlock.addOperator(op, inputs, outputs, attributes, quant_info)
+
+    def setExpectedFailure(self, desc='', val=True):
+        self.expectedFailure = val
+        self.expectedFailureDesc = desc
+
+    def setExpectedFailure(self, desc='', val=True):
+        self.expectedFailure = val
+        self.expectedFailureDesc = desc
+
+    def serialize(self):
+
+        builder = self.builder
+
+        Version.VersionStart(builder)
+        Version.VersionAdd_major(builder, TOSA_VERSION[0])
+        Version.VersionAdd_minor(builder, TOSA_VERSION[1])
+        Version.VersionAdd_patch(builder, TOSA_VERSION[2])
+        Version.VersionAdd_experimental(builder, TOSA_VERSION[3])
+        version = Version.VersionEnd(builder)
+
+        fbv_bb = TosaSerializer.serializeObjVec(builder, self.basicBlocks, TosaGraph.TosaGraphStartBlocksVector)
+
+        TosaGraph.TosaGraphStart(builder)
+        TosaGraph.TosaGraphAddVersion(builder, version)
+        TosaGraph.TosaGraphAddBlocks(builder, fbv_bb)
+        graph = TosaGraph.TosaGraphEnd(builder)
+
+        self.builder.Finish(graph)
+        return self.builder.Output()
+
+    def writeJson(self, tosa_filename):
+        '''Write a json test file so that it is fairly easy to pick up the test
+           and generate commands for third party tool'''
+        test_desc = dict()
+
+        test_desc['tosa_file'] = tosa_filename
+        ifm_name = []
+        ifm_shape = []
+        ifm_file = []
+        ofm_name = []
+        ofm_file = []
+        ofm_shape = []
+
+        for b in self.basicBlocks:
+            if b.name == 'main':
+                for i in b.inputs:
+                    ifm_name.append(i)
+                    ifm_shape.append(b.tensors[i].shape)
+                    ifm_file.append(b.tensors[i].placeholderFilename)
+                for o in b.outputs:
+                    ofm_name.append(o)
+                    ofm_shape.append(b.tensors[o].shape)
+                    # Make up an OFM filename here.  One isn't generated until the reference tool is
+                    # run, so any name is a good name
+                    ofm_file.append('ref-{}.npy'.format(o))
+
+        test_desc['ifm_placeholder'] = ifm_name
+        test_desc['ifm_file'] = ifm_file
+        test_desc['ifm_shape'] = ifm_shape
+        test_desc['ofm_name'] = ofm_name
+        test_desc['ofm_shape'] = ofm_shape
+        test_desc['ofm_file'] = ofm_file
+        test_desc['expected_failure'] = self.expectedFailure
+        if self.expectedFailureDesc:
+            test_desc['expected_failure_desc'] = self.expectedFailureDesc
+
+        return json.dumps(test_desc, indent='  ')
+
+    def startBasicBlock(self, name):
+        self.currBasicBlock = TosaSerializerBasicBlock(name)
+        self.basicBlocks.append(self.currBasicBlock)
+
+    @staticmethod
+    def serializeStrVec(builder, vec, start_fcn):
+        fb_strs = [builder.CreateString(i) for i in vec]
+        start_fcn(builder, len(fb_strs))
+        for s in fb_strs[::-1]:
+            builder.PrependUOffsetTRelative(s)
+        return builder.EndVector(len(fb_strs))
+
+    @staticmethod
+    def serializeInt32Vec(builder, vec):
+        builder.StartVector(4, len(vec), 4)
+        for v in vec[::-1]:
+            builder.PrependInt32(v)
+        return builder.EndVector(len(vec))
+
+    @staticmethod
+    def serializeObjVec(builder, vec, start_fcn):
+        serialized_vec = []
+        for v in vec[::-1]:
+            serialized_vec.append(v.serialize(builder))
+
+        start_fcn(builder, len(vec))
+        for v in serialized_vec:
+            builder.PrependUOffsetTRelative(v)
+        return builder.EndVector(len(vec))
+
+    @staticmethod
+    def toList(val):
+        if isinstance(val, list):
+            return val
+        else:
+            return [val]
+
+    @staticmethod
+    def setTosaVersion():
+        # Create a dummy flatbuffers file with the default version information
+        # There does not appear to be a better way to get a constant from a
+        # flatbuffer schema file
+        builder = flatbuffers.Builder(0)
+        Version.VersionStart(builder)
+        ver = Version.VersionEnd(builder)
+        TosaGraph.TosaGraphStart(builder)
+        TosaGraph.TosaGraphAddVersion(builder, ver)
+        gr = TosaGraph.TosaGraphEnd(builder)
+        builder.Finish(gr)
+
+        out = builder.Output()
+
+        gr = TosaGraph.TosaGraph()
+        root = gr.GetRootAsTosaGraph(out, 0)
+
+        # Store the version as a global variable so that it only needs to be
+        # generated once per process.
+        global TOSA_VERSION
+        TOSA_VERSION = [root.Version()._major(),
+                        root.Version()._minor(),
+                        root.Version()._patch(),
+                        root.Version()._experimental() ]
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