I have a question related to how tensorflow evaluates expressions in a tf.cond
statement.
I use a custom operation that gives me batches of data of either type A or type B. Its signature looks like that
REGISTER_OP("GetData")
.Attr("path: string")
.Output("data: int32")
.Output("type: int32")
.SetIsStateful()
The type
output is 1 for type A and 2 for type B. Depending on the type, I want to run a different (custom) operation, say opA
or opB
. Of course, their output has the same type. To express this data flow, I use tf.cond
as in:
(data, type) = get_data(path = "...")
opA = op_a(data)
opB = op_b(dat
def perfromA(): return opA
def perfromB(): return opB
joined_op = tf.cond(tf.equal(type, tf.constant(1, dtype=tf.int32)), perfromA, perfromB)
I added some debug statements to getData
, opA
and opB
. For a data sequence ABA I hope to get
getData: returning type A
opA: got some data
getData: returning type B
opB: got some data
getData: returning type A
opA: got some data
However, I do get
getData: returning type A
opA: got some data
opB: got some data
getData: returning type B
opA: got some data
opB: got some data
getData: returning type A
opA: got some data
opB: got some data
Is this the expected behaviour? The result of the joined_op
does correctly take the if-else into account but still, both operations are always computed. This is not only a computational burden but also defeats the purpose if opA
and opA
perform actions that affect variables (such as an optimization step).
CORRECT SOLUTION as pointed out by @Yaroslav
def perfromA(): return op_a(data)
def perfromB(): return op_b(data)
For a more detailed example, please see the dummy implementation of the three operations below:
#include "tensorflow/core/framework/op.h"
#include "tensorflow/core/framework/op_kernel.h"
#include "tensorflow/core/lib/random/philox_random.h"
#include "tensorflow/core/lib/random/simple_philox.h"
using namespace std;
using namespace tensorflow;
REGISTER_OP("GetData")
.Attr("path: string")
.Output("data: int32")
.Output("type: int32")
.SetIsStateful();
class GetData : public OpKernel {
public:
explicit GetData(OpKernelConstruction* ctx) : OpKernel(ctx) {}
void Compute(OpKernelContext* ctx) override
{
Tensor data(DT_INT32, TensorShape({}));
Tensor type(DT_INT32, TensorShape({}));
if(rng_.Uniform(2) == 0){
type.scalar<int32>()() = 1;
data.scalar<int32>()() = 100;
LOG(INFO) << "returning type A";
}
else{
type.scalar<int32>()() = 2;
data.scalar<int32>()() = 200;
LOG(INFO) << "returning type B";
}
ctx->set_output(0, data);
ctx->set_output(1, type);
}
private:
random::PhiloxRandom philox_ = random::PhiloxRandom(10) ;
random::SimplePhilox rng_ = random::SimplePhilox(&philox_);
};
REGISTER_KERNEL_BUILDER(Name("GetData").Device(DEVICE_CPU), GetData);
REGISTER_OP("OpA")
.Input("input: int32")
.Output("output: int32");
class OpA : public OpKernel {
public:
explicit OpA(OpKernelConstruction* ctx) : OpKernel(ctx) {}
void Compute(OpKernelContext* ctx) override
{
const Tensor& data = ctx->input(0);
LOG(INFO) << "A: got some data";
ctx->set_output(0, data);
}
};
REGISTER_KERNEL_BUILDER(Name("OpA").Device(DEVICE_CPU), OpA);
REGISTER_OP("OpB")
.Input("input: int32")
.Output("output: int32");
class OpB : public OpKernel {
public:
explicit OpB(OpKernelConstruction* ctx) : OpKernel(ctx) {}
void Compute(OpKernelContext* ctx) override
{
const Tensor& data = ctx->input(0);
LOG(INFO) << "B: got some data";
ctx->set_output(0, data);
}
};
REGISTER_KERNEL_BUILDER(Name("OpB").Device(DEVICE_CPU), OpB);