upsilon/firmware/rtl/autoapproach/bram_interface_sim.cpp

#include <limits>
#include <cstdlib>
#include <random>
#include <unistd.h>
#include <verilated.h>

#include "Vbram_interface.h"
#include "../testbench.hpp"

TB<Vbram_interface> *tb;
constexpr uint32_t start_addr = 0x12340;
std::array<uint32_t, WORD_AMNT> ram_refresh_data;

static void handle_ram() {
	static int timer = 0;
	constexpr auto TIMER_MAX = 10;
	bool flip_flop = false;

	if (tb->mod.ram_read) {
		timer++;
		if (timer == TIMER_MAX) {
			tb->mod.ram_valid = 1;
			if (tb->mod.ram_dma_addr < start_addr ||
			    tb->mod.ram_dma_addr >= start_addr + WORD_AMNT*4) {
				printf("bad address %x\n", tb->mod.ram_dma_addr);
				exit(1);
			}
			my_assert(tb->mod.ram_dma_addr >= start_addr, "left oob access %x", tb->mod.ram_dma_addr);
			my_assert(tb->mod.ram_dma_addr < start_addr + WORD_AMNT*4, "right oob access %x", tb->mod.ram_dma_addr);
			my_assert(tb->mod.ram_dma_addr % 2 == 0, "unaligned access %x", tb->mod.ram_dma_addr);

			if (tb->mod.ram_dma_addr % 4 == 0) {
				tb->mod.ram_word = ram_refresh_data[(tb->mod.ram_dma_addr - start_addr)/4]& 0xFFFF;
			} else {
				tb->mod.ram_word = ram_refresh_data[(tb->mod.ram_dma_addr - start_addr)/4] >> 16;
			}
		}
	} else {
		tb->mod.ram_valid = 0;
		timer = 0;
	}
}

static void handle_read_aa(size_t &i) {
	if (tb->mod.word_ok) {
		uint32_t val = sign_extend(tb->mod.word, 20);
		tb->mod.word_next = 0;

		my_assert(val == ram_refresh_data[i], "received value %x (%zu) != %x", i, val, ram_refresh_data[i]);
		i++;
	} else if (!tb->mod.word_next) {
		tb->mod.word_next = 1;
	}
}

/* Test reading the entire array twice. */
static void test_aa_read_1() {
	size_t ind = 0;

	tb->mod.word_next = 1;
	tb->run_clock();
	while (!tb->mod.word_last || (tb->mod.word_last && tb->mod.word_next)) {
		handle_read_aa(ind);
		tb->run_clock();
	}
	my_assert(ind == WORD_AMNT, "read value %zu != %d\n", ind, WORD_AMNT);

	tb->mod.word_next = 1;
	tb->run_clock();
	ind = 0;
	while (!tb->mod.word_last || (tb->mod.word_last && tb->mod.word_next)) {
		handle_read_aa(ind);
		tb->run_clock();
	}
	my_assert(ind == WORD_AMNT, "second read value %zu != %d\n", ind, WORD_AMNT);
}

static void test_aa_read_interrupted() {
	size_t ind = 0;

	tb->mod.word_next = 1;
	tb->run_clock();
	for (int i = 0; i < 100; i++) {
		handle_read_aa(ind);
		tb->run_clock();
		my_assert(!tb->mod.word_last, "too many reads");
	}
	tb->mod.word_rst = 1;
	tb->run_clock();
	tb->mod.word_rst = 0;
	tb->run_clock();

	test_aa_read_1();
}

static void refresh_data() {
	for (size_t i = 0; i < RAM_WID; i++) {
		ram_refresh_data[i] = mask_extend(rand(), 20);
	}

	tb->mod.refresh_start = 1;
	tb->mod.start_addr = start_addr;
	tb->run_clock();

	while (!tb->mod.refresh_finished) {
		handle_ram();
		tb->run_clock();
	}

	tb->mod.refresh_start = 0;
	tb->run_clock();

}

int main(int argc, char *argv[]) {
	Verilated::traceEverOn(true);
	tb = new TB<Vbram_interface>(argc, argv);

	printf("test basic read/write\n");
	refresh_data();
	test_aa_read_1();
	refresh_data();
	test_aa_read_1();

	printf("test resetting\n");
	test_aa_read_interrupted();

	printf("ok\n");

	return 0;
}
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`#include <limits>`
			`#include <cstdlib>`
			`#include <random>`
			`#include <unistd.h>`
			`#include <verilated.h>`

			`#include "Vbram_interface.h"`
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`#include "../testbench.hpp"`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`TB<Vbram_interface> *tb;`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`constexpr uint32_t start_addr = 0x12340;`
			`std::array<uint32_t, WORD_AMNT> ram_refresh_data;`

			`static void handle_ram() {`
			`static int timer = 0;`
			`constexpr auto TIMER_MAX = 10;`
			`bool flip_flop = false;`

refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`if (tb->mod.ram_read) {`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`timer++;`
			`if (timer == TIMER_MAX) {`
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`tb->mod.ram_valid = 1;`
			`if (tb->mod.ram_dma_addr < start_addr \|\|`
			`tb->mod.ram_dma_addr >= start_addr + WORD_AMNT*4) {`
			`printf("bad address %x\n", tb->mod.ram_dma_addr);`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`exit(1);`
			`}`
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`my_assert(tb->mod.ram_dma_addr >= start_addr, "left oob access %x", tb->mod.ram_dma_addr);`
			`my_assert(tb->mod.ram_dma_addr < start_addr + WORD_AMNT*4, "right oob access %x", tb->mod.ram_dma_addr);`
			`my_assert(tb->mod.ram_dma_addr % 2 == 0, "unaligned access %x", tb->mod.ram_dma_addr);`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`if (tb->mod.ram_dma_addr % 4 == 0) {`
			`tb->mod.ram_word = ram_refresh_data[(tb->mod.ram_dma_addr - start_addr)/4]& 0xFFFF;`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`} else {`
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`tb->mod.ram_word = ram_refresh_data[(tb->mod.ram_dma_addr - start_addr)/4] >> 16;`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`}`
			`}`
			`} else {`
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`tb->mod.ram_valid = 0;`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`timer = 0;`
			`}`
			`}`

			`static void handle_read_aa(size_t &i) {`
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`if (tb->mod.word_ok) {`
			`uint32_t val = sign_extend(tb->mod.word, 20);`
			`tb->mod.word_next = 0;`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00
			`my_assert(val == ram_refresh_data[i], "received value %x (%zu) != %x", i, val, ram_refresh_data[i]);`
			`i++;`
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`} else if (!tb->mod.word_next) {`
			`tb->mod.word_next = 1;`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`}`
			`}`

			`/* Test reading the entire array twice. */`
			`static void test_aa_read_1() {`
			`size_t ind = 0;`

refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`tb->mod.word_next = 1;`
			`tb->run_clock();`
			`while (!tb->mod.word_last \|\| (tb->mod.word_last && tb->mod.word_next)) {`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`handle_read_aa(ind);`
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`tb->run_clock();`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`}`
			`my_assert(ind == WORD_AMNT, "read value %zu != %d\n", ind, WORD_AMNT);`

refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`tb->mod.word_next = 1;`
			`tb->run_clock();`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`ind = 0;`
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`while (!tb->mod.word_last \|\| (tb->mod.word_last && tb->mod.word_next)) {`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`handle_read_aa(ind);`
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`tb->run_clock();`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`}`
			`my_assert(ind == WORD_AMNT, "second read value %zu != %d\n", ind, WORD_AMNT);`
			`}`

autoapproach: add reset test to bram 2023-01-22 23:58:38 -05:00			`static void test_aa_read_interrupted() {`
			`size_t ind = 0;`

refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`tb->mod.word_next = 1;`
			`tb->run_clock();`
autoapproach: add reset test to bram 2023-01-22 23:58:38 -05:00			`for (int i = 0; i < 100; i++) {`
			`handle_read_aa(ind);`
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`tb->run_clock();`
			`my_assert(!tb->mod.word_last, "too many reads");`
autoapproach: add reset test to bram 2023-01-22 23:58:38 -05:00			`}`
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`tb->mod.word_rst = 1;`
			`tb->run_clock();`
			`tb->mod.word_rst = 0;`
			`tb->run_clock();`
autoapproach: add reset test to bram 2023-01-22 23:58:38 -05:00
			`test_aa_read_1();`
			`}`

autoapproach: test refreshing bram 2023-01-22 23:47:12 -05:00			`static void refresh_data() {`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`for (size_t i = 0; i < RAM_WID; i++) {`
			`ram_refresh_data[i] = mask_extend(rand(), 20);`
			`}`

refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`tb->mod.refresh_start = 1;`
			`tb->mod.start_addr = start_addr;`
			`tb->run_clock();`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`while (!tb->mod.refresh_finished) {`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`handle_ram();`
refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`tb->run_clock();`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`}`

refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`tb->mod.refresh_start = 0;`
			`tb->run_clock();`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00
autoapproach: test refreshing bram 2023-01-22 23:47:12 -05:00			`}`

refactor bram interface simulation 2023-01-27 17:27:20 -05:00			`int main(int argc, char *argv[]) {`
			`Verilated::traceEverOn(true);`
bram: more refactor 2023-01-27 17:58:29 -05:00			`tb = new TB<Vbram_interface>(argc, argv);`
autoapproach: test refreshing bram 2023-01-22 23:47:12 -05:00
autoapproach: add reset test to bram 2023-01-22 23:58:38 -05:00			`printf("test basic read/write\n");`
autoapproach: test refreshing bram 2023-01-22 23:47:12 -05:00			`refresh_data();`
			`test_aa_read_1();`
			`refresh_data();`
autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`test_aa_read_1();`
autoapproach: add reset test to bram 2023-01-22 23:58:38 -05:00
			`printf("test resetting\n");`
			`test_aa_read_interrupted();`

autoapproach: add bram and test 2023-01-22 23:43:51 -05:00			`printf("ok\n");`

			`return 0;`
			`}`