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test-cderiv.cc
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test-cderiv.cc
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#include <assert.h>
#include <math.h>
#include <cmath>
#include <iostream>
#include <memory>
#include <string>
#include <vector>
#include "clstm.h"
#include "clstm_compute.h"
#include "extras.h"
#include "utils.h"
using std_string = std::string;
#define string std_string
using std::vector;
using std::shared_ptr;
using std::unique_ptr;
using std::to_string;
using std::make_pair;
using std::cout;
using std::stoi;
using namespace Eigen;
using namespace ocropus;
typedef vector<Params> ParamVec;
double sqr(double x) { return x * x; }
double randu() {
static int count = 1;
for (;;) {
double x = cos(count * 3.7);
count++;
if (fabs(x) > 0.1) return x;
}
}
void randseq(Sequence &a, int N, int n, int m) {
bool finit = getienv("finit", 0);
a.resize(N, n, m);
for (int t = 0; t < N; t++) {
for (int i = 0; i < n; i++) {
for (int j = 0; j < m; j++) {
if (finit) {
a[t].v(i, j) = 10000 * t + 100 * i + j;
a[t].d(i, j) = 10000 * t + 100 * i + j + 0.5;
} else {
a[t].v(i, j) = randu();
a[t].d(i, j) = randu();
}
}
}
}
a.check();
}
void randparams(ParamVec &a, const vector<vector<int>> &specs) {
int N = specs.size();
a.resize(N);
for (int k = 0; k < N; k++) {
int n = specs[k][0];
int m = specs[k][1];
a[k].setZero(n, m);
for (int i = 0; i < n; i++) {
for (int j = 0; j < m; j++) {
a[k].v(i, j) = randu();
a[k].d(i, j) = randu();
}
}
}
}
double maxerr(Sequence &out, Sequence &target) {
assert(out.size() == target.size());
assert(out.rows() == target.rows());
assert(out.cols() == target.cols());
int N = out.size(), n = out.rows(), m = out.cols();
double maxerr = 0.0;
for (int t = 0; t < N; t++) {
for (int i = 0; i < n; i++) {
for (int j = 0; j < m; j++) {
double delta = target[t].v(i, j) - out[t].v(i, j);
if (fabs(delta) > maxerr) maxerr = fabs(delta);
}
}
}
return maxerr;
}
double avgerr(Sequence &out, Sequence &target) {
assert(out.size() == target.size());
assert(out.rows() == target.rows());
assert(out.cols() == target.cols());
int N = out.size(), n = out.rows(), m = out.cols();
double total = 0.0;
int count = 0;
for (int t = 0; t < N; t++) {
for (int i = 0; i < n; i++) {
for (int j = 0; j < m; j++) {
double delta = target[t].v(i, j) - out[t].v(i, j);
total += fabs(delta);
count++;
}
}
}
return total / count;
}
double mse(Sequence &out, Sequence &target) {
assert(out.size() == target.size());
assert(out.rows() == target.rows());
assert(out.cols() == target.cols());
int N = out.size(), n = out.rows(), m = out.cols();
double total = 0.0;
for (int t = 0; t < N; t++) {
out[t].zeroGrad();
for (int i = 0; i < n; i++) {
for (int j = 0; j < m; j++) {
double delta = target[t].v(i, j) - out[t].v(i, j);
out[t].d(i, j) = delta;
total += sqr(delta);
}
}
}
return total;
}
struct Minimizer {
double value = INFINITY;
double param = 0;
void add(double value, double param = NAN) {
if (value >= this->value) return;
this->value = value;
this->param = param;
}
};
struct Maximizer {
double value = -INFINITY;
double param = 0;
void add(double value, double param = NAN) {
if (value <= this->value) return;
this->value = value;
this->param = param;
}
};
struct Testcase;
vector<Testcase *> testcases;
struct Testcase {
virtual ~Testcase() {}
Sequence inputs;
ParamVec ps;
Sequence outputs;
Sequence targets;
virtual string name() { return typeid(*this).name(); }
// Store random initial test values appropriate for
// the test case into inputs, ps, and targets
virtual void init() {
// reasonable defaults
randseq(inputs, 1, 7, 4);
randseq(targets, 1, 3, 4);
randparams(ps, {{3, 7}});
}
// Perform forward and backward steps using inputs,
// outputs, and ps.
virtual void forward() = 0;
virtual void backward() = 0;
};
void test_net(Testcase &tc) {
int verbose = getienv("verbose", 0);
print("testing", tc.name());
tc.init();
// make backups for computing derivatives
Sequence inputs = tc.inputs;
Sequence targets = tc.targets;
ParamVec ps = tc.ps;
Maximizer maxinerr;
int N = inputs.size();
int ninput = inputs.rows();
int bs = inputs.cols();
for (int t = 0; t < N; t++) {
for (int i = 0; i < ninput; i++) {
for (int b = 0; b < bs; b++) {
Minimizer minerr;
for (float h = 1e-6; h < 1.0; h *= 10) {
tc.inputs = inputs;
tc.outputs.like(targets);
tc.forward();
double out = mse(tc.outputs, targets);
tc.inputs.zeroGrad();
for (Params &p : tc.ps) p.zeroGrad();
tc.backward();
double a_deriv = tc.inputs[t].d(i, b);
tc.inputs[t].v(i, b) += h;
tc.forward();
double out1 = mse(tc.outputs, targets);
double num_deriv = (out1 - out) / h;
double error = fabs(1.0 - num_deriv / a_deriv / -2.0);
if (verbose > 1)
print(t, i, b, ":", error, h, "num:", num_deriv, "analytic:",
a_deriv, "out:", out1, out);
minerr.add(error, h);
}
if (verbose) print("deltas", t, i, b, minerr.value, minerr.param);
assert(minerr.value < 0.1);
maxinerr.add(minerr.value);
}
}
}
Maximizer maxparamerr;
for (int k = 0; k < ps.size(); k++) {
int n = ps[k].rows();
int m = ps[k].cols();
for (int i = 0; i < n; i++) {
for (int j = 0; j < m; j++) {
Minimizer minerr;
for (float h = 1e-6; h < 1.0; h *= 10) {
tc.ps = ps;
tc.inputs = inputs;
tc.outputs.like(targets);
tc.forward();
double out = mse(tc.outputs, targets);
tc.inputs.zeroGrad();
for (Params &p : tc.ps) p.zeroGrad();
tc.backward();
double a_deriv = tc.ps[k].d(i, j);
tc.ps[k].v(i, j) += h;
tc.forward();
double out1 = mse(tc.outputs, targets);
double num_deriv = (out1 - out) / h;
double error = fabs(1.0 - num_deriv / a_deriv / -2.0);
if (verbose > 1)
print(k, i, j, ":", error, h, "/", num_deriv, a_deriv, out1, out);
minerr.add(error, h);
}
maxparamerr.add(minerr.value);
}
}
}
tc.inputs = inputs;
tc.ps = ps;
tc.targets = targets;
print("OK", maxinerr.value, maxparamerr.value);
}
struct TestFull1Sigmoid : Testcase {
virtual void init() {
randseq(inputs, 1, 7, 4);
randseq(targets, 1, 3, 4);
randparams(ps, {{3, 8}});
}
void forward() { forward_full1(outputs[0], ps[0], inputs[0], SIG); }
void backward() { backward_full1(outputs[0], ps[0], inputs[0], SIG); }
};
struct TestFull1Tanh : Testcase {
virtual void init() {
randseq(inputs, 1, 7, 4);
randseq(targets, 1, 3, 4);
randparams(ps, {{3, 8}});
}
void forward() { forward_full1(outputs[0], ps[0], inputs[0], TANH); }
void backward() { backward_full1(outputs[0], ps[0], inputs[0], TANH); }
};
struct TestFull1Logmag : Testcase {
virtual void init() {
randseq(inputs, 1, 7, 4);
randseq(targets, 1, 3, 4);
randparams(ps, {{3, 8}});
}
void forward() { forward_full1(outputs[0], ps[0], inputs[0], LOGMAG); }
void backward() { backward_full1(outputs[0], ps[0], inputs[0], LOGMAG); }
};
struct TestStack : Testcase {
virtual void init() {
randseq(inputs, 2, 7, 4);
randseq(targets, 1, 14, 4);
randparams(ps, {});
}
void forward() { forward_stack(outputs[0], inputs[0], inputs[1]); }
void backward() { backward_stack(outputs[0], inputs[0], inputs[1]); }
};
struct TestStackDelay : Testcase {
virtual void init() {
randseq(inputs, 2, 7, 4);
randseq(targets, 1, 14, 4);
randparams(ps, {});
}
void forward() { forward_stack_delay(outputs[0], inputs[0], inputs, 1); }
void backward() { backward_stack_delay(outputs[0], inputs[0], inputs, 1); }
};
#ifdef DEPRECATED
struct TestFullSigmoid : Testcase {
void forward() { forward_full<SigmoidNonlin>(outputs[0], ps[0], inputs[0]); }
void backward() {
backward_full<SigmoidNonlin>(outputs[0], ps[0], inputs[0]);
}
};
struct TestFullTanh : Testcase {
void forward() { forward_full<SigmoidNonlin>(outputs[0], ps[0], inputs[0]); }
void backward() {
backward_full<SigmoidNonlin>(outputs[0], ps[0], inputs[0]);
}
};
struct TestStack1Delay : Testcase {
virtual void init() {
randseq(inputs, 2, 7, 4);
randseq(targets, 1, 15, 4);
randparams(ps, {});
}
void forward() { forward_stack1(outputs[0], inputs[0], inputs, 1); }
void backward() { backward_stack1(outputs[0], inputs[0], inputs, 1); }
};
#endif
struct TestReverse : Testcase {
virtual void init() {
randseq(inputs, 5, 7, 4);
randseq(targets, 5, 7, 4);
randparams(ps, {});
}
void forward() { forward_reverse(outputs, inputs); }
void backward() { backward_reverse(outputs, inputs); }
};
struct TestBtswitch : Testcase {
virtual void init() {
randseq(inputs, 5, 7, 4);
randseq(targets, 4, 7, 5);
randparams(ps, {});
}
void forward() { forward_btswitch(outputs, inputs); }
void backward() { backward_btswitch(outputs, inputs); }
};
struct TestBatchstack : Testcase {
virtual void init() {
randseq(inputs, 5, 4, 11);
randseq(targets, 5, 12, 11);
randparams(ps, {});
}
void forward() { forward_batchstack(outputs, inputs, 1, 1); }
void backward() { backward_batchstack(outputs, inputs, 1, 1); }
};
struct TestStatemem : Testcase {
virtual void init() {
randseq(inputs, 4, 7, 4);
randseq(targets, 1, 7, 4);
randparams(ps, {});
}
void forward() {
forward_statemem(outputs[0], inputs[0], inputs[1], inputs, 2, inputs[3]);
}
void backward() {
backward_statemem(outputs[0], inputs[0], inputs[1], inputs, 2, inputs[3]);
}
};
struct TestNonlingate : Testcase {
virtual void init() {
randseq(inputs, 2, 7, 4);
randseq(targets, 1, 7, 4);
randparams(ps, {});
}
void forward() { forward_nonlingate(outputs[0], inputs[0], inputs[1], TANH); }
void backward() {
backward_nonlingate(outputs[0], inputs[0], inputs[1], TANH);
}
};
inline Eigen::array<ptrdiff_t, 1> indexes(int i) {
return Eigen::array<ptrdiff_t, 1>({i});
}
inline Eigen::array<ptrdiff_t, 2> indexes(int i, int j) {
return Eigen::array<ptrdiff_t, 2>({i, j});
}
#ifdef DEPRECATED
void test_full() {
print("comparing full and full1");
Sequence inputs;
ParamVec ps;
Sequence outputs;
randseq(inputs, 1, 7, 4);
randparams(ps, {{3, 8}});
randseq(outputs, 2, 3, 4);
Batch inputs1;
inputs1.resize(8, 4);
inputs1.v().slice(indexes(0, 0), indexes(1, 4)).setConstant(Float(1));
inputs1.v().slice(indexes(1, 0), indexes(7, 4)) = inputs[0].v();
forward_full1<SigmoidNonlin>(outputs[0], ps[0], inputs[0]);
forward_full<SigmoidNonlin>(outputs[1], ps[0], inputs1);
EigenTensor1 err = (outputs[0].v() - outputs[1].v()).abs().maximum();
assert(err(0) < 0.001);
print("OK", err(0));
backward_full1<SigmoidNonlin>(outputs[0], ps[0], inputs[0]);
backward_full<SigmoidNonlin>(outputs[1], ps[0], inputs1);
EigenTensor1 derr =
(inputs[0].d() - inputs1.d().slice(indexes(1, 0), indexes(7, 4)))
.abs()
.maximum();
// assert(derr(0) < 0.001);
print("OK", derr(0));
}
#endif
int main(int argc, char **argv) {
TRY {
test_net(*new TestBatchstack);
test_net(*new TestFull1Sigmoid);
test_net(*new TestFull1Tanh);
test_net(*new TestFull1Logmag);
test_net(*new TestStack);
test_net(*new TestStackDelay);
test_net(*new TestReverse);
test_net(*new TestBtswitch);
test_net(*new TestStatemem);
test_net(*new TestNonlingate);
#ifdef DEPRECATED
test_net(*new TestFullSigmoid);
test_net(*new TestFullTanh);
test_net(*new TestStack1Delay);
test_full();
#endif
}
CATCH(const char *message) { print("ERROR", message); }
}