// Copyright 2015-2016 Espressif Systems (Shanghai) PTE LTD // // 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. #include "catch.hpp" #include "nvs.hpp" #include "nvs_flash.h" #include "spi_flash_emulation.h" #include #include using namespace std; using namespace nvs; stringstream s_perf; void dumpBytes(const uint8_t* data, size_t count) { for (uint32_t i = 0; i < count; ++i) { if (i % 32 == 0) { printf("%08x ", i); } printf("%02x ", data[i]); if ((i + 1) % 32 == 0) { printf("\n"); } } } TEST_CASE("crc32 behaves as expected", "[nvs]") { Item item1; item1.datatype = ItemType::I32; item1.nsIndex = 1; item1.crc32 = 0; item1.reserved = 0xff; fill_n(item1.key, sizeof(item1.key), 0xbb); fill_n(item1.data, sizeof(item1.data), 0xaa); auto crc32_1 = item1.calculateCrc32(); Item item2 = item1; item2.crc32 = crc32_1; CHECK(crc32_1 == item2.calculateCrc32()); item2 = item1; item2.nsIndex = 2; CHECK(crc32_1 != item2.calculateCrc32()); item2 = item1; item2.datatype = ItemType::U32; CHECK(crc32_1 != item2.calculateCrc32()); item2 = item1; strlcpy(item2.key, "foo", Item::MAX_KEY_LENGTH); CHECK(crc32_1 != item2.calculateCrc32()); } TEST_CASE("starting with empty flash, page is in uninitialized state", "[nvs]") { SpiFlashEmulator emu(1); Page page; CHECK(page.state() == Page::PageState::INVALID); CHECK(page.load(0) == ESP_OK); CHECK(page.state() == Page::PageState::UNINITIALIZED); } TEST_CASE("can distinguish namespaces", "[nvs]") { SpiFlashEmulator emu(1); Page page; CHECK(page.load(0) == ESP_OK); int32_t val1 = 0x12345678; CHECK(page.writeItem(1, ItemType::I32, "intval1", &val1, sizeof(val1)) == ESP_OK); int32_t val2 = 0x23456789; CHECK(page.writeItem(2, ItemType::I32, "intval1", &val2, sizeof(val2)) == ESP_OK); int32_t readVal; CHECK(page.readItem(2, ItemType::I32, "intval1", &readVal, sizeof(readVal)) == ESP_OK); CHECK(readVal == val2); } TEST_CASE("reading with different type causes type mismatch error", "[nvs]") { SpiFlashEmulator emu(1); Page page; CHECK(page.load(0) == ESP_OK); int32_t val = 0x12345678; CHECK(page.writeItem(1, ItemType::I32, "intval1", &val, sizeof(val)) == ESP_OK); CHECK(page.readItem(1, ItemType::U32, "intval1", &val, sizeof(val)) == ESP_ERR_NVS_TYPE_MISMATCH); } TEST_CASE("when page is erased, it's state becomes UNITIALIZED", "[nvs]") { SpiFlashEmulator emu(1); Page page; CHECK(page.load(0) == ESP_OK); int32_t val = 0x12345678; CHECK(page.writeItem(1, ItemType::I32, "intval1", &val, sizeof(val)) == ESP_OK); CHECK(page.erase() == ESP_OK); CHECK(page.state() == Page::PageState::UNINITIALIZED); } TEST_CASE("when writing and erasing, used/erased counts are updated correctly", "[nvs]") { SpiFlashEmulator emu(1); Page page; CHECK(page.load(0) == ESP_OK); CHECK(page.getUsedEntryCount() == 0); CHECK(page.getErasedEntryCount() == 0); uint32_t foo1 = 0; CHECK(page.writeItem(1, "foo1", foo1) == ESP_OK); CHECK(page.getUsedEntryCount() == 1); CHECK(page.writeItem(2, "foo1", foo1) == ESP_OK); CHECK(page.getUsedEntryCount() == 2); CHECK(page.eraseItem(2, "foo1") == ESP_OK); CHECK(page.getUsedEntryCount() == 1); CHECK(page.getErasedEntryCount() == 1); for (size_t i = 0; i < Page::ENTRY_COUNT - 2; ++i) { char name[16]; snprintf(name, sizeof(name), "i%ld", i); CHECK(page.writeItem(1, name, i) == ESP_OK); } CHECK(page.getUsedEntryCount() == Page::ENTRY_COUNT - 1); CHECK(page.getErasedEntryCount() == 1); for (size_t i = 0; i < Page::ENTRY_COUNT - 2; ++i) { char name[16]; snprintf(name, sizeof(name), "i%ld", i); CHECK(page.eraseItem(1, itemTypeOf(), name) == ESP_OK); } CHECK(page.getUsedEntryCount() == 1); CHECK(page.getErasedEntryCount() == Page::ENTRY_COUNT - 1); } TEST_CASE("when page is full, adding an element fails", "[nvs]") { SpiFlashEmulator emu(1); Page page; CHECK(page.load(0) == ESP_OK); for (size_t i = 0; i < Page::ENTRY_COUNT; ++i) { char name[16]; snprintf(name, sizeof(name), "i%ld", i); CHECK(page.writeItem(1, name, i) == ESP_OK); } CHECK(page.writeItem(1, "foo", 64UL) == ESP_ERR_NVS_PAGE_FULL); } TEST_CASE("page maintains its seq number") { SpiFlashEmulator emu(1); { Page page; CHECK(page.load(0) == ESP_OK); CHECK(page.setSeqNumber(123) == ESP_OK); int32_t val = 42; CHECK(page.writeItem(1, ItemType::I32, "dummy", &val, sizeof(val)) == ESP_OK); } { Page page; CHECK(page.load(0) == ESP_OK); uint32_t seqno; CHECK(page.getSeqNumber(seqno) == ESP_OK); CHECK(seqno == 123); } } TEST_CASE("can write and read variable length data", "[nvs]") { SpiFlashEmulator emu(1); Page page; CHECK(page.load(0) == ESP_OK); const char str[] = "foobar1234foobar1234foobar1234foobar1234foobar1234foobar1234foobar1234foobar1234"; size_t len = strlen(str); CHECK(page.writeItem(1, "stuff1", 42) == ESP_OK); CHECK(page.writeItem(1, "stuff2", 1) == ESP_OK); CHECK(page.writeItem(1, ItemType::SZ, "foobaar", str, len + 1) == ESP_OK); CHECK(page.writeItem(1, "stuff3", 2) == ESP_OK); CHECK(page.writeItem(1, ItemType::BLOB, "baz", str, len) == ESP_OK); CHECK(page.writeItem(1, "stuff4", 0x7abbccdd) == ESP_OK); char buf[sizeof(str) + 16]; int32_t value; CHECK(page.readItem(1, "stuff1", value) == ESP_OK); CHECK(value == 42); CHECK(page.readItem(1, "stuff2", value) == ESP_OK); CHECK(value == 1); CHECK(page.readItem(1, "stuff3", value) == ESP_OK); CHECK(value == 2); CHECK(page.readItem(1, "stuff4", value) == ESP_OK); CHECK(value == 0x7abbccdd); fill_n(buf, sizeof(buf), 0xff); CHECK(page.readItem(1, ItemType::SZ, "foobaar", buf, sizeof(buf)) == ESP_OK); CHECK(memcmp(buf, str, strlen(str) + 1) == 0); fill_n(buf, sizeof(buf), 0xff); CHECK(page.readItem(1, ItemType::BLOB, "baz", buf, sizeof(buf)) == ESP_OK); CHECK(memcmp(buf, str, strlen(str)) == 0); } TEST_CASE("can init PageManager in empty flash", "[nvs]") { SpiFlashEmulator emu(4); PageManager pm; CHECK(pm.load(0, 4) == ESP_OK); } TEST_CASE("PageManager adds page in the correct order", "[nvs]") { const size_t pageCount = 8; SpiFlashEmulator emu(pageCount); uint32_t pageNo[pageCount] = { -1U, 50, 11, -1U, 23, 22, 24, 49}; for (uint32_t i = 0; i < pageCount; ++i) { Page p; p.load(i); if (pageNo[i] != -1U) { p.setSeqNumber(pageNo[i]); p.writeItem(1, "foo", 10U); } } PageManager pageManager; CHECK(pageManager.load(0, pageCount) == ESP_OK); uint32_t lastSeqNo = 0; for (auto it = std::begin(pageManager); it != std::end(pageManager); ++it) { uint32_t seqNo; CHECK(it->getSeqNumber(seqNo) == ESP_OK); CHECK(seqNo > lastSeqNo); } } TEST_CASE("can init storage in empty flash", "[nvs]") { SpiFlashEmulator emu(8); Storage storage; emu.setBounds(4, 8); CHECK(storage.init(4, 4) == ESP_OK); s_perf << "Time to init empty storage (4 sectors): " << emu.getTotalTime() << " us" << std::endl; } TEST_CASE("storage doesn't add duplicates within one page", "[nvs]") { SpiFlashEmulator emu(8); Storage storage; emu.setBounds(4, 8); CHECK(storage.init(4, 4) == ESP_OK); int bar = 0; CHECK(storage.writeItem(1, "bar", bar) == ESP_OK); CHECK(storage.writeItem(1, "bar", bar) == ESP_OK); Page page; page.load(4); CHECK(page.getUsedEntryCount() == 1); CHECK(page.getErasedEntryCount() == 1); } TEST_CASE("can write one item a thousand times", "[nvs]") { SpiFlashEmulator emu(8); Storage storage; emu.setBounds(4, 8); CHECK(storage.init(4, 4) == ESP_OK); for (size_t i = 0; i < Page::ENTRY_COUNT * 4 * 2; ++i) { REQUIRE(storage.writeItem(1, "i", static_cast(i)) == ESP_OK); } s_perf << "Time to write one item a thousand times: " << emu.getTotalTime() << " us (" << emu.getEraseOps() << " " << emu.getWriteOps() << " " << emu.getReadOps() << " " << emu.getWriteBytes() << " " << emu.getReadBytes() << ")" << std::endl; } TEST_CASE("storage doesn't add duplicates within multiple pages", "[nvs]") { SpiFlashEmulator emu(8); Storage storage; emu.setBounds(4, 8); CHECK(storage.init(4, 4) == ESP_OK); int bar = 0; CHECK(storage.writeItem(1, "bar", bar) == ESP_OK); for (size_t i = 0; i < Page::ENTRY_COUNT; ++i) { CHECK(storage.writeItem(1, "foo", static_cast(bar)) == ESP_OK); } CHECK(storage.writeItem(1, "bar", bar) == ESP_OK); Page page; page.load(4); CHECK(page.findItem(1, itemTypeOf(), "bar") == ESP_ERR_NVS_NOT_FOUND); page.load(5); CHECK(page.findItem(1, itemTypeOf(), "bar") == ESP_OK); } TEST_CASE("can write and read variable length data lots of times", "[nvs]") { SpiFlashEmulator emu(8); Storage storage; emu.setBounds(4, 8); CHECK(storage.init(4, 4) == ESP_OK); const char str[] = "foobar1234foobar1234foobar1234foobar1234foobar1234foobar1234foobar1234foobar1234"; char buf[sizeof(str) + 16]; size_t len = strlen(str); for (size_t i = 0; i < Page::ENTRY_COUNT * 4 * 2; ++i) { CAPTURE(i); CHECK(storage.writeItem(1, ItemType::SZ, "foobaar", str, len + 1) == ESP_OK); CHECK(storage.writeItem(1, "foo", static_cast(i)) == ESP_OK); uint32_t value; CHECK(storage.readItem(1, "foo", value) == ESP_OK); CHECK(value == i); fill_n(buf, sizeof(buf), 0xff); CHECK(storage.readItem(1, ItemType::SZ, "foobaar", buf, sizeof(buf)) == ESP_OK); CHECK(memcmp(buf, str, strlen(str) + 1) == 0); } s_perf << "Time to write one string and one integer a thousand times: " << emu.getTotalTime() << " us (" << emu.getEraseOps() << " " << emu.getWriteOps() << " " << emu.getReadOps() << " " << emu.getWriteBytes() << " " << emu.getReadBytes() << ")" << std::endl; } TEST_CASE("can get length of variable length data", "[nvs]") { SpiFlashEmulator emu(8); emu.randomize(200); Storage storage; emu.setBounds(4, 8); CHECK(storage.init(4, 4) == ESP_OK); const char str[] = "foobar1234foobar1234foobar1234foobar1234foobar1234foobar1234foobar1234foobar1234"; size_t len = strlen(str); CHECK(storage.writeItem(1, ItemType::SZ, "foobaar", str, len + 1) == ESP_OK); size_t dataSize; CHECK(storage.getItemDataSize(1, ItemType::SZ, "foobaar", dataSize) == ESP_OK); CHECK(dataSize == len + 1); CHECK(storage.writeItem(2, ItemType::BLOB, "foobaar", str, len) == ESP_OK); CHECK(storage.getItemDataSize(2, ItemType::BLOB, "foobaar", dataSize) == ESP_OK); CHECK(dataSize == len); } TEST_CASE("can create namespaces", "[nvs]") { SpiFlashEmulator emu(8); Storage storage; emu.setBounds(4, 8); CHECK(storage.init(4, 4) == ESP_OK); uint8_t nsi; CHECK(storage.createOrOpenNamespace("wifi", false, nsi) == ESP_ERR_NVS_NOT_FOUND); CHECK(storage.createOrOpenNamespace("wifi", true, nsi) == ESP_OK); Page page; page.load(4); CHECK(page.findItem(Page::NS_INDEX, ItemType::U8, "wifi") == ESP_OK); } TEST_CASE("storage may become full", "[nvs]") { SpiFlashEmulator emu(8); Storage storage; emu.setBounds(4, 8); CHECK(storage.init(4, 4) == ESP_OK); for (size_t i = 0; i < Page::ENTRY_COUNT * 3; ++i) { char name[Item::MAX_KEY_LENGTH + 1]; snprintf(name, sizeof(name), "key%05d", static_cast(i)); REQUIRE(storage.writeItem(1, name, static_cast(i)) == ESP_OK); } REQUIRE(storage.writeItem(1, "foo", 10) == ESP_ERR_NVS_NOT_ENOUGH_SPACE); } TEST_CASE("can modify an item on a page which will be erased", "[nvs]") { SpiFlashEmulator emu(2); Storage storage; CHECK(storage.init(0, 2) == ESP_OK); for (size_t i = 0; i < Page::ENTRY_COUNT * 3 + 1; ++i) { REQUIRE(storage.writeItem(1, "foo", 42U) == ESP_OK); } } #define TEST_ESP_ERR(rc, res) CHECK((rc) == (res)) #define TEST_ESP_OK(rc) CHECK((rc) == ESP_OK) TEST_CASE("nvs api tests", "[nvs]") { SpiFlashEmulator emu(10); emu.randomize(100); nvs_handle handle_1; const uint32_t NVS_FLASH_SECTOR = 6; const uint32_t NVS_FLASH_SECTOR_COUNT_MIN = 3; emu.setBounds(NVS_FLASH_SECTOR, NVS_FLASH_SECTOR + NVS_FLASH_SECTOR_COUNT_MIN); TEST_ESP_ERR(nvs_open("namespace1", NVS_READWRITE, &handle_1), ESP_ERR_NVS_NOT_INITIALIZED); for (uint16_t i = NVS_FLASH_SECTOR; i (count)); const uint32_t NVS_FLASH_SECTOR = 6; const uint32_t NVS_FLASH_SECTOR_COUNT_MIN = 3; emu.setBounds(NVS_FLASH_SECTOR, NVS_FLASH_SECTOR + NVS_FLASH_SECTOR_COUNT_MIN); TEST_ESP_OK(nvs_flash_init(NVS_FLASH_SECTOR, NVS_FLASH_SECTOR_COUNT_MIN)); nvs_handle handle_1; TEST_ESP_ERR(nvs_open("namespace1", NVS_READONLY, &handle_1), ESP_ERR_NVS_NOT_FOUND); TEST_ESP_OK(nvs_open("namespace1", NVS_READWRITE, &handle_1)); TEST_ESP_OK(nvs_set_i32(handle_1, "foo", 0x12345678)); for (size_t i = 0; i < 500; ++i) { nvs_handle handle_2; TEST_ESP_OK(nvs_open("namespace2", NVS_READWRITE, &handle_2)); TEST_ESP_OK(nvs_set_i32(handle_1, "foo", 0x23456789 % (i + 1))); TEST_ESP_OK(nvs_set_i32(handle_2, "foo", static_cast(i))); const char* str = "value 0123456789abcdef0123456789abcdef %09d"; char str_buf[128]; snprintf(str_buf, sizeof(str_buf), str, i + count * 1024); TEST_ESP_OK(nvs_set_str(handle_2, "key", str_buf)); int32_t v1; TEST_ESP_OK(nvs_get_i32(handle_1, "foo", &v1)); CHECK(0x23456789 % (i + 1) == v1); int32_t v2; TEST_ESP_OK(nvs_get_i32(handle_2, "foo", &v2)); CHECK(static_cast(i) == v2); char buf[128]; size_t buf_len = sizeof(buf); TEST_ESP_OK(nvs_get_str(handle_2, "key", buf, &buf_len)); CHECK(0 == strcmp(buf, str_buf)); nvs_close(handle_2); } nvs_close(handle_1); } } extern "C" void nvs_dump(); class RandomTest { static const size_t nKeys = 9; int32_t v1 = 0, v2 = 0; uint64_t v3 = 0, v4 = 0; static const size_t strBufLen = 1024; char v5[strBufLen], v6[strBufLen], v7[strBufLen], v8[strBufLen], v9[strBufLen]; bool written[nKeys]; public: RandomTest() { std::fill_n(written, nKeys, false); } template esp_err_t doRandomThings(nvs_handle handle, TGen gen, size_t& count) { const char* keys[] = {"foo", "bar", "longkey_0123456", "another key", "param1", "param2", "param3", "param4", "param5"}; const ItemType types[] = {ItemType::I32, ItemType::I32, ItemType::U64, ItemType::U64, ItemType::SZ, ItemType::SZ, ItemType::SZ, ItemType::SZ, ItemType::SZ}; void* values[] = {&v1, &v2, &v3, &v4, &v5, &v6, &v7, &v8, &v9}; const size_t nKeys = sizeof(keys) / sizeof(keys[0]); static_assert(nKeys == sizeof(types) / sizeof(types[0]), ""); static_assert(nKeys == sizeof(values) / sizeof(values[0]), ""); auto randomRead = [&](size_t index) -> esp_err_t { switch (types[index]) { case ItemType::I32: { int32_t val; auto err = nvs_get_i32(handle, keys[index], &val); if (err == ESP_ERR_FLASH_OP_FAIL) { return err; } if (!written[index]) { REQUIRE(err == ESP_ERR_NVS_NOT_FOUND); } else { REQUIRE(err == ESP_OK); REQUIRE(val == *reinterpret_cast(values[index])); } break; } case ItemType::U64: { uint64_t val; auto err = nvs_get_u64(handle, keys[index], &val); if (err == ESP_ERR_FLASH_OP_FAIL) { return err; } if (!written[index]) { REQUIRE(err == ESP_ERR_NVS_NOT_FOUND); } else { REQUIRE(err == ESP_OK); REQUIRE(val == *reinterpret_cast(values[index])); } break; } case ItemType::SZ: { char buf[strBufLen]; size_t len = strBufLen; auto err = nvs_get_str(handle, keys[index], buf, &len); if (err == ESP_ERR_FLASH_OP_FAIL) { return err; } if (!written[index]) { REQUIRE(err == ESP_ERR_NVS_NOT_FOUND); } else { REQUIRE(err == ESP_OK); REQUIRE(strncmp(buf, reinterpret_cast(values[index]), strBufLen) == 0); } break; } default: assert(0); } return ESP_OK; }; auto randomWrite = [&](size_t index) -> esp_err_t { switch (types[index]) { case ItemType::I32: { int32_t val = static_cast(gen()); auto err = nvs_set_i32(handle, keys[index], val); if (err == ESP_ERR_FLASH_OP_FAIL) { return err; } if (err == ESP_ERR_NVS_REMOVE_FAILED) { written[index] = true; *reinterpret_cast(values[index]) = val; return ESP_ERR_FLASH_OP_FAIL; } REQUIRE(err == ESP_OK); written[index] = true; *reinterpret_cast(values[index]) = val; break; } case ItemType::U64: { uint64_t val = static_cast(gen()); auto err = nvs_set_u64(handle, keys[index], val); if (err == ESP_ERR_FLASH_OP_FAIL) { return err; } if (err == ESP_ERR_NVS_REMOVE_FAILED) { written[index] = true; *reinterpret_cast(values[index]) = val; return ESP_ERR_FLASH_OP_FAIL; } REQUIRE(err == ESP_OK); written[index] = true; *reinterpret_cast(values[index]) = val; break; } case ItemType::SZ: { char buf[strBufLen]; size_t len = strBufLen; size_t strLen = gen() % (strBufLen - 1); std::generate_n(buf, strLen, [&]() -> char { const char c = static_cast(gen() % 127); return (c < 32) ? 32 : c; }); buf[strLen] = 0; auto err = nvs_set_str(handle, keys[index], buf); if (err == ESP_ERR_FLASH_OP_FAIL) { return err; } if (err == ESP_ERR_NVS_REMOVE_FAILED) { written[index] = true; strlcpy(reinterpret_cast(values[index]), buf, strBufLen); return ESP_ERR_FLASH_OP_FAIL; } REQUIRE(err == ESP_OK); written[index] = true; strlcpy(reinterpret_cast(values[index]), buf, strBufLen); break; } default: assert(0); } return ESP_OK; }; for (; count != 0; --count) { size_t index = gen() % nKeys; switch (gen() % 3) { case 0: // read, 1/3 if (randomRead(index) == ESP_ERR_FLASH_OP_FAIL) { return ESP_ERR_FLASH_OP_FAIL; } break; default: // write, 2/3 if (randomWrite(index) == ESP_ERR_FLASH_OP_FAIL) { return ESP_ERR_FLASH_OP_FAIL; } break; } } return ESP_OK; } }; TEST_CASE("monkey test", "[nvs][monkey]") { std::random_device rd; std::mt19937 gen(rd()); uint32_t seed = 3; gen.seed(seed); SpiFlashEmulator emu(10); emu.randomize(seed); emu.clearStats(); const uint32_t NVS_FLASH_SECTOR = 6; const uint32_t NVS_FLASH_SECTOR_COUNT_MIN = 3; emu.setBounds(NVS_FLASH_SECTOR, NVS_FLASH_SECTOR + NVS_FLASH_SECTOR_COUNT_MIN); TEST_ESP_OK(nvs_flash_init(NVS_FLASH_SECTOR, NVS_FLASH_SECTOR_COUNT_MIN)); nvs_handle handle; TEST_ESP_OK(nvs_open("namespace1", NVS_READWRITE, &handle)); RandomTest test; size_t count = 1000; CHECK(test.doRandomThings(handle, gen, count) == ESP_OK); s_perf << "Monkey test: nErase=" << emu.getEraseOps() << " nWrite=" << emu.getWriteOps() << std::endl; } TEST_CASE("test recovery from sudden poweroff", "[.][long][nvs][recovery][monkey]") { std::random_device rd; std::mt19937 gen(rd()); uint32_t seed = 3; gen.seed(seed); const size_t iter_count = 2000; SpiFlashEmulator emu(10); const uint32_t NVS_FLASH_SECTOR = 6; const uint32_t NVS_FLASH_SECTOR_COUNT_MIN = 3; emu.setBounds(NVS_FLASH_SECTOR, NVS_FLASH_SECTOR + NVS_FLASH_SECTOR_COUNT_MIN); size_t totalOps = 0; int lastPercent = -1; for (uint32_t errDelay = 4; ; ++errDelay) { INFO(errDelay); emu.randomize(seed); emu.clearStats(); emu.failAfter(errDelay); RandomTest test; if (totalOps != 0) { int percent = errDelay * 100 / totalOps; if (percent != lastPercent) { printf("%d/%d (%d%%)\r\n", errDelay, static_cast(totalOps), percent); lastPercent = percent; } } TEST_ESP_OK(nvs_flash_init(NVS_FLASH_SECTOR, NVS_FLASH_SECTOR_COUNT_MIN)); nvs_handle handle; TEST_ESP_OK(nvs_open("namespace1", NVS_READWRITE, &handle)); size_t count = iter_count; if(test.doRandomThings(handle, gen, count) != ESP_ERR_FLASH_OP_FAIL) { nvs_close(handle); break; } nvs_close(handle); TEST_ESP_OK(nvs_flash_init(NVS_FLASH_SECTOR, NVS_FLASH_SECTOR_COUNT_MIN)); TEST_ESP_OK(nvs_open("namespace1", NVS_READWRITE, &handle)); auto res = test.doRandomThings(handle, gen, count); if (res != ESP_OK) { nvs_dump(); CHECK(0); } nvs_close(handle); totalOps = emu.getEraseOps() + emu.getWriteOps(); } } TEST_CASE("dump all performance data", "[nvs]") { std::cout << "====================" << std::endl << "Dumping benchmarks" << std::endl; std::cout << s_perf.str() << std::endl; std::cout << "====================" << std::endl; }