END_TEST
START_TEST (null_sequence)
{
reset_errno();
assert_null(sequence_get(NULL, 0));
assert_errno(EINVAL);
}
END_TEST
START_TEST (key_anchor)
{
document_model *model = anchor_setup(KEY_ANCHOR_YAML);
node *root = model_document_root(model, 0);
reset_errno();
node *one = mapping_get(root, (uint8_t *)"one", 3ul);
assert_noerr();
assert_not_null(one);
assert_node_kind(one, SEQUENCE);
assert_node_size(one, 2);
reset_errno();
node *alias1 = sequence_get(one, 1);
assert_noerr();
assert_not_null(alias1);
assert_node_kind(alias1, ALIAS);
node *one_1 = alias_target(alias1);
assert_noerr();
assert_not_null(one_1);
assert_node_kind(one_1, SCALAR);
assert_scalar_kind(one_1, SCALAR_STRING);
assert_scalar_value(one_1, "one");
reset_errno();
node *alias2 = mapping_get(root, (uint8_t *)"two", 3ul);
assert_noerr();
assert_not_null(alias2);
node *two = alias_target(alias2);
assert_node_kind(two, SCALAR);
assert_scalar_kind(two, SCALAR_STRING);
assert_scalar_value(two, "one");
}
static qeo_retcode_t data_member_accessor(qeocore_data_t *data,
qeocore_member_id_t id,
void *value,
int get)
{
qeo_retcode_t rc = QEO_EINVAL;
DDS_ReturnCode_t ddsrc;
DDS_DynamicTypeMember mtype = DDS_DynamicTypeMember__alloc();
DDS_DynamicType dyntype = dtype_from_data(data, &data->d.dynamic);
DDS_DynamicData dyndata = (DDS_DynamicData)sample_from_data(data);
if (NULL != mtype) {
ddsrc = DDS_DynamicType_get_member(dyntype, mtype, id);
qeo_log_dds_rc("DDS_DynamicType_get_member", ddsrc);
if (DDS_RETCODE_OK == ddsrc) {
DDS_ReturnCode_t ddsrc = DDS_RETCODE_BAD_PARAMETER;
DDS_MemberDescriptor mdesc = { 0 };
DDS_TypeDescriptor tdesc = { 0 };
ddsrc = DDS_DynamicTypeMember_get_descriptor(mtype, &mdesc);
qeo_log_dds_rc("DDS_DynamicTypeMember_get_descriptor", ddsrc);
ddsrc = DDS_DynamicType_get_descriptor(mdesc.type, &tdesc);
qeo_log_dds_rc("DDS_DynamicType_get_descriptor", ddsrc);
switch (tdesc.kind) {
case DDS_BOOLEAN_TYPE: {
if (get) {
ddsrc = DDS_DynamicData_get_boolean_value(dyndata, (qeo_boolean_t *)value, id);
qeo_log_dds_rc("DDS_DynamicData_get_boolean_value", ddsrc);
}
else {
ddsrc = DDS_DynamicData_set_boolean_value(dyndata, id, *((qeo_boolean_t *)value));
qeo_log_dds_rc("DDS_DynamicData_set_boolean_value", ddsrc);
}
break;
}
case DDS_BYTE_TYPE: /* QEOCORE_TYPECODE_INT8 */
if (get) {
ddsrc = DDS_DynamicData_get_byte_value(dyndata, (unsigned char *)value, id);
qeo_log_dds_rc("DDS_DynamicData_get_byte_value", ddsrc);
}
else {
ddsrc = DDS_DynamicData_set_byte_value(dyndata, id, *((unsigned char *)value));
qeo_log_dds_rc("DDS_DynamicData_set_byte_value", ddsrc);
}
break;
case DDS_INT_16_TYPE: /* QEOCORE_TYPECODE_INT16 */
if (get) {
ddsrc = DDS_DynamicData_get_int16_value(dyndata, (int16_t *)value, id);
qeo_log_dds_rc("DDS_DynamicData_get_int16_value", ddsrc);
}
else {
ddsrc = DDS_DynamicData_set_int16_value(dyndata, id, *((int16_t *)value));
qeo_log_dds_rc("DDS_DynamicData_set_int16_value", ddsrc);
}
break;
case DDS_INT_32_TYPE: /* QEOCORE_TYPECODE_INT32 */
case DDS_ENUMERATION_TYPE: /* QEOCORE_TYPECODE_ENUM */
if (get) {
ddsrc = DDS_DynamicData_get_int32_value(dyndata, (int32_t *)value, id);
qeo_log_dds_rc("DDS_DynamicData_get_int32_value", ddsrc);
}
else {
ddsrc = DDS_DynamicData_set_int32_value(dyndata, id, *((int32_t *)value));
qeo_log_dds_rc("DDS_DynamicData_set_int32_value", ddsrc);
}
break;
case DDS_INT_64_TYPE: /* QEOCORE_TYPECODE_INT64 */
if (get) {
ddsrc = DDS_DynamicData_get_int64_value(dyndata, (int64_t *)value, id);
qeo_log_dds_rc("DDS_DynamicData_get_int64_value", ddsrc);
}
else {
ddsrc = DDS_DynamicData_set_int64_value(dyndata, id, *((int64_t *)value));
qeo_log_dds_rc("DDS_DynamicData_set_int64_value", ddsrc);
}
break;
case DDS_FLOAT_32_TYPE: /* QEOCORE_TYPECODE_FLOAT32 */
if (get) {
ddsrc = DDS_DynamicData_get_float32_value(dyndata, (float *)value, id);
qeo_log_dds_rc("DDS_DynamicData_get_float32_value", ddsrc);
}
else {
ddsrc = DDS_DynamicData_set_float32_value(dyndata, id, *((float *)value));
qeo_log_dds_rc("DDS_DynamicData_set_float32_value", ddsrc);
}
break;
case DDS_STRING_TYPE: /* QEOCORE_TYPECODE_STRING */
if (get) {
char **string = (char **)value;
int len = DDS_DynamicData_get_string_length(dyndata, id);
if (len > -1) {
*string = malloc(len + 1);
if (NULL != *string) {
ddsrc = DDS_DynamicData_get_string_value(dyndata, *string, id);
qeo_log_dds_rc("DDS_DynamicData_get_string_value", ddsrc);
if (DDS_RETCODE_OK != ddsrc) {
free(*string);
*string = NULL;
}
}
}
}
else {
char **string = (char **)value;
ddsrc = DDS_DynamicData_set_string_value(dyndata, id, *string);
qeo_log_dds_rc("DDS_DynamicData_set_string_value", ddsrc);
}
break;
case DDS_SEQUENCE_TYPE: { /* QEOCORE_TYPECODE_SEQUENCE */
if (get) {
ddsrc = sequence_get(value, dyndata, id, mdesc.type);
}
else {
ddsrc = sequence_set(value, dyndata, id);
}
break;
}
case DDS_STRUCTURE_TYPE: { /* QEOCORE_TYPECODE_STRUCT */
qeocore_data_t **inner_data = (qeocore_data_t **)value;
if (get) {
ddsrc = struct_get(inner_data, dyndata, id, &mdesc);
}
else {
ddsrc = struct_set(inner_data, dyndata, id);
}
break;
}
default:
qeo_log_e("unsupported type %d", tdesc.kind);
abort(); // unsupported for now
break;
}
DDS_MemberDescriptor__clear(&mdesc);
DDS_TypeDescriptor__clear(&tdesc);
//TODO: Make the following code more generic and use the overall error translation function
if ((DDS_RETCODE_OK == ddsrc) || (DDS_RETCODE_NO_DATA == ddsrc)){
rc = QEO_OK;
} else if (DDS_RETCODE_OUT_OF_RESOURCES == ddsrc) {
rc = QEO_ENOMEM;
} else {
rc = QEO_EFAIL;
}
}
DDS_DynamicTypeMember__free(mtype);
}
return rc;
}
END_TEST
static void assert_model_state(loader_context *loader, document_model *model)
{
assert_int_eq(LOADER_SUCCESS, loader_status(loader));
assert_not_null(model);
assert_uint_eq(1, model_document_count(model));
reset_errno();
node *root = model_document_root(model, 0);
assert_noerr();
assert_not_null(root);
assert_node_kind(root, MAPPING);
assert_node_size(root, 5);
reset_errno();
node *one = mapping_get(root, (uint8_t *)"one", 3ul);
assert_noerr();
assert_not_null(one);
assert_node_kind(one, SEQUENCE);
assert_node_size(one, 2);
reset_errno();
node *one_0 = sequence_get(one, 0);
assert_noerr();
assert_node_kind(one_0, SCALAR);
assert_scalar_value(one_0, "foo1");
assert_scalar_kind(one_0, SCALAR_STRING);
reset_errno();
node *one_1 = sequence_get(one, 1);
assert_noerr();
assert_node_kind(one_1, SCALAR);
assert_scalar_value(one_1, "bar1");
assert_scalar_kind(one_1, SCALAR_STRING);
reset_errno();
node *two = mapping_get(root, (uint8_t *)"two", 3ul);
assert_noerr();
assert_not_null(two);
assert_node_kind(two, SCALAR);
assert_scalar_value(two, "foo2");
assert_scalar_kind(two, SCALAR_STRING);
reset_errno();
node *three = mapping_get(root, (uint8_t *)"three", 5ul);
assert_noerr();
assert_not_null(three);
assert_node_kind(three, SCALAR);
assert_scalar_value(three, "null");
assert_scalar_kind(three, SCALAR_NULL);
reset_errno();
node *four = mapping_get(root, (uint8_t *)"four", 4ul);
assert_noerr();
assert_not_null(four);
assert_node_kind(four, SEQUENCE);
reset_errno();
node *four_0 = sequence_get(four, 0);
assert_noerr();
assert_node_kind(four_0, SCALAR);
assert_scalar_value(four_0, "true");
assert_scalar_kind(four_0, SCALAR_BOOLEAN);
assert_true(scalar_boolean_is_true(four_0));
assert_false(scalar_boolean_is_false(four_0));
reset_errno();
node *four_1 = sequence_get(four, 1);
assert_noerr();
assert_node_kind(four_0, SCALAR);
assert_scalar_value(four_1, "false");
assert_scalar_kind(four_1, SCALAR_BOOLEAN);
assert_true(scalar_boolean_is_false(four_1));
assert_false(scalar_boolean_is_true(four_1));
reset_errno();
node *five = mapping_get(root, (uint8_t *)"five", 4ul);
assert_noerr();
assert_not_null(five);
assert_node_kind(five, SEQUENCE);
node *five_0 = sequence_get(five, 0);
assert_noerr();
assert_node_kind(five_0, SCALAR);
assert_scalar_value(five_0, "1.5");
assert_scalar_kind(five_0, SCALAR_REAL);
reset_errno();
node *five_1 = sequence_get(five, 1);
assert_noerr();
assert_node_kind(five_1, SCALAR);
assert_scalar_value(five_1, "42");
assert_scalar_kind(five_1, SCALAR_INTEGER);
reset_errno();
node *five_2 = sequence_get(five, 2);
assert_noerr();
assert_node_kind(five_2, SCALAR);
assert_scalar_value(five_2, "1978-07-26 10:15");
assert_scalar_kind(five_2, SCALAR_TIMESTAMP);
reset_errno();
}
END_TEST
START_TEST (sequence_type)
{
reset_errno();
Node *r = model_document_root(model, 0);
assert_noerr();
assert_not_null(r);
assert_node_kind(r, MAPPING);
reset_errno();
Node *s = mapping_get(mapping(r), (uint8_t *)"one", 3ul);
assert_noerr();
assert_not_null(s);
assert_node_kind(s, SEQUENCE);
assert_node_size(s, 2);
reset_errno();
Node *zero = sequence_get(sequence(s), 0);
assert_noerr();
assert_not_null(zero);
assert_node_kind(zero, SCALAR);
reset_errno();
Node *one = sequence_get(sequence(s), 1);
assert_noerr();
assert_not_null(one);
assert_node_kind(one, SCALAR);
reset_errno();
Scalar *x = make_scalar_node((uint8_t *)"x", 1, SCALAR_STRING);
assert_noerr();
assert_not_null(x);
reset_errno();
Scalar *y = make_scalar_node((uint8_t *)"y", 1, SCALAR_STRING);
assert_noerr();
assert_not_null(y);
reset_errno();
Scalar *z = make_scalar_node((uint8_t *)"z", 1, SCALAR_STRING);
assert_noerr();
assert_not_null(z);
reset_errno();
Sequence *xyz = make_sequence_node();
assert_noerr();
assert_not_null(xyz);
reset_errno();
sequence_add(xyz, node(x));
assert_noerr();
reset_errno();
sequence_add(xyz, node(y));
assert_noerr();
reset_errno();
sequence_add(xyz, node(z));
assert_noerr();
assert_uint_eq(3, node_size(node(xyz)));
assert_ptr_eq(node(x), sequence_get(xyz, 0));
assert_ptr_eq(node(y), sequence_get(xyz, 1));
assert_ptr_eq(node(z), sequence_get(xyz, 2));
node_free(node(xyz));
}
if ((XRESET_GPIO_pin > 7) || (DREQ_GPIO_pin > 7))
return MP3_VS1053_INVALID_PARAMETER;
mp3_VS1053_prvt_ctx.hSpiMaster = spi_master_handle;
mp3_VS1053_prvt_ctx.XRESET_GPIO_port = XRESET_GPIO_port;
mp3_VS1053_prvt_ctx.XRESET_GPIO_pin = XRESET_GPIO_pin;
mp3_VS1053_prvt_ctx.DREQ_GPIO_port = DREQ_GPIO_port;
mp3_VS1053_prvt_ctx.DREQ_GPIO_pin = DREQ_GPIO_pin;
mp3_VS1053_prvt_ctx.SDI_CS_identifier = SDI_CS_identifier;
mp3_VS1053_prvt_ctx.SCI_CS_identifier = SCI_CS_identifier;
return MP3_VS1053_OK;
}
int mp3_VS1053_detach()
{
mp3_VS1053_prvt_ctx.hSpiMaster = NULL;
return MP3_VS1053_OK;
}
int mp3_VS1053_hard_reset(void)
{
unsigned char mask;
mask = 0x01 << mp3_VS1053_prvt_ctx.XRESET_GPIO_pin;
switch (mp3_VS1053_prvt_ctx.XRESET_GPIO_port)
{
case PORT_A:
vII_gpio_data_tx_pa_1 &= (~mask); // set the pin LOW
vos_delay_msecs(3); // wait for some time
vII_gpio_data_tx_pa_1 |= mask; // set the pin HIGH
break;
case PORT_B:
vII_gpio_data_tx_pb_1 &= (~mask); // set the pin LOW
vos_delay_msecs(3); // wait for some time
vII_gpio_data_tx_pb_1 |= mask; // set the pin HIGH
break;
case PORT_C:
vII_gpio_data_tx_pc_1 &= (~mask); // set the pin LOW
vos_delay_msecs(3); // wait for some time
vII_gpio_data_tx_pc_1 |= mask; // set the pin HIGH
break;
case PORT_D:
vII_gpio_data_tx_pd_1 &= (~mask); // set the pin LOW
vos_delay_msecs(3); // wait for some time
vII_gpio_data_tx_pd_1 |= mask; // set the pin HIGH
break;
case PORT_E:
vII_gpio_data_tx_pe_1 &= (~mask); // set the pin LOW
vos_delay_msecs(3); // wait for some time
vII_gpio_data_tx_pe_1 |= mask; // set the pin HIGH
break;
default:
return MP3_VS1053_INVALID_PARAMETER;
}
return MP3_VS1053_OK;
}
int mp3_VS1053_soft_reset(void)
{
mp3_VS1053_write_reg(SCI_MODE, MASK_SM_RESET); // Set Reset bit in mode register
vos_delay_msecs(2); // At least 2 millisecond delay
mp3_VS1053_wait_for_dreq(); // wait for startup
// Then set mode register and clock register again
mp3_VS1053_write_reg(SCI_MODE, MASK_SM_SDINEW_VS1002);
mp3_VS1053_write_reg(SCI_CLOCKF, 0x8800);
vos_delay_msecs(1); // 1 millisecond delay
mp3_VS1053_wait_for_dreq(); // wait for the commands to complete
return MP3_VS1053_OK;
}
int mp3_VS1053_setup(void)
{
unsigned short regVal;
common_ioctl_cb_t spim_iocb;
// Initialize SPI pins
// Reset VS1053 codec hardware
mp3_VS1053_hard_reset();
// Configure VS1053 defaults
mp3_VS1053_write_reg(SCI_MODE, MASK_SM_SDINEW_VS1002);
mp3_VS1053_write_reg(SCI_CLOCKF, 0xe000);
return 0;
}
// Waits for the DREQ line to go high...
int mp3_VS1053_wait_for_dreq(void)
{
unsigned char port_value = 0, mask;
int timeout = 0;
mask = 0x01 << mp3_VS1053_prvt_ctx.DREQ_GPIO_pin;
switch (mp3_VS1053_prvt_ctx.DREQ_GPIO_port)
{
case PORT_A:
// Read the pin. If the pin is LOW, continue reading it until it is HIGH
do
{
port_value = vII_gpio_data_rx_pa_1;
}
while ((port_value & mask) == 0);
break;
case PORT_B:
// Read the pin. If the pin is LOW, continue reading it until it is HIGH
do {
port_value = vII_gpio_data_rx_pb_1;
//vos_delay_msecs(1);
} while ((port_value & mask) == 0);
break;
case PORT_C:
// Read the pin. If the pin is LOW, continue reading it until it is HIGH
do
{
port_value = vII_gpio_data_rx_pc_1;
}
while ((port_value & mask) == 0);
break;
case PORT_D:
// Read the pin. If the pin is LOW, continue reading it until it is HIGH
do
{
port_value = vII_gpio_data_rx_pd_1;
}
while ((port_value & mask) == 0);
break;
case PORT_E:
// Read the pin. If the pin is LOW, continue reading it until it is HIGH
do
{
port_value = vII_gpio_data_rx_pe_1;
}
while ((port_value & mask) == 0);
break;
default:
return MP3_VS1053_INVALID_PARAMETER;
}
}
int mp3_VS1053_select_control(void)
{
if (mp3_VS1053_prvt_ctx.SCI_CS_identifier == SPI_CHIP_SELECT_0)
spim_iocb.ioctl_code = VOS_IOCTL_SPI_MASTER_SS_0;
else if (mp3_VS1053_prvt_ctx.SCI_CS_identifier == SPI_CHIP_SELECT_1)
spim_iocb.ioctl_code = VOS_IOCTL_SPI_MASTER_SS_1;
spim_iocb.set.param = SPI_MASTER_SS_ENABLE;
vos_dev_ioctl(mp3_VS1053_prvt_ctx.hSpiMaster, &spim_iocb);
return MP3_VS1053_OK;
