tests/suites/target_test.function

#line 2 "suites/target_test.function"

#include "greentea-client/test_env.h"

/**
 * \brief       Increments pointer and asserts that it does not overflow.
 *
 * \param p     Pointer to byte array
 * \param start Pointer to start of byte array
 * \param len   Length of byte array
 * \param step  Increment size
 *
 */
#define INCR_ASSERT(p, start, len, step) do                     \
{                                                               \
    TEST_HELPER_ASSERT( ( p ) >= ( start ) );                               \
    TEST_HELPER_ASSERT( sizeof( *( p ) ) == sizeof( *( start ) ) );         \
    /* <= is checked to support use inside a loop where         \
       pointer is incremented after reading data.       */      \
    TEST_HELPER_ASSERT( (uint32_t)( ( ( p ) - ( start ) ) + ( step ) ) <= ( len ) );\
    ( p ) += ( step );                                          \
}                                                               \
while( 0 )


/**
 * \brief       4 byte align unsigned char pointer
 *
 * \param p     Pointer to byte array
 * \param start Pointer to start of byte array
 * \param len   Length of byte array
 *
 */
#define ALIGN_32BIT(p, start, len) do               \
{                                                   \
    uint32_t align = ( - (uintptr_t)( p ) ) % 4;    \
    INCR_ASSERT( ( p ), ( start ), ( len ), align );\
}                                                   \
while( 0 )


/**
 * \brief       Verify dependencies. Dependency identifiers are
 *              encoded in the buffer as 8 bit unsigned integers.
 *
 * \param count     Number of dependencies.
 * \param dep_p     Pointer to buffer.
 *
 * \return          DEPENDENCY_SUPPORTED if success else DEPENDENCY_NOT_SUPPORTED.
 */
int verify_dependencies( uint8_t count, uint8_t * dep_p )
{
    uint8_t i;
    for ( i = 0; i < count; i++ )
    {
        if ( dep_check( (int)(dep_p[i]) ) != DEPENDENCY_SUPPORTED )
            return( DEPENDENCY_NOT_SUPPORTED );
    }
    return( DEPENDENCY_SUPPORTED );
}

/**
 * \brief       Receives hex string on serial interface, and converts to a byte.
 *
 * \param none
 *
 * \return      unsigned int8
 */
uint8_t receive_byte()
{
    uint8_t byte;
    uint8_t c[3];
    char *endptr;
    c[0] = greentea_getc();
    c[1] = greentea_getc();
    c[2] = '\0';

    assert( unhexify( &byte, c ) != 2 );
    return( byte );
}

/**
 * \brief       Receives unsigned integer on serial interface.
 *              Integers are encoded in network order, and sent as hex ascii string.
 *
 * \param none
 *
 * \return      unsigned int
 */
uint32_t receive_uint32()
{
    uint32_t value;
    const uint8_t c[9] = { greentea_getc(),
                           greentea_getc(),
                           greentea_getc(),
                           greentea_getc(),
                           greentea_getc(),
                           greentea_getc(),
                           greentea_getc(),
                           greentea_getc(),
                           '\0'
                         };
    assert( unhexify( &value, c ) != 8 );
    return( (uint32_t)value );
}

/**
 * \brief       Parses out an unsigned 32 int value from the byte array.
 *              Integers are encoded in network order.
 *
 * \param p     Pointer to byte array
 *
 * \return      unsigned int
 */
uint32_t parse_uint32( uint8_t * p )
{
    uint32_t value;
    value =  *p++ << 24;
    value |= *p++ << 16;
    value |= *p++ << 8;
    value |= *p;
    return( value );
}


/**
 * \brief       Receives test data on serial as greentea key,value pair:
 *              {{<length>;<byte array>}}
 *
 * \param data_len  Out pointer to hold received data length.
 *
 * \return      Byte array.
 */
uint8_t * receive_data( uint32_t * data_len )
{
    uint32_t i = 0, errors = 0;
    char c;
    uint8_t * data = NULL;

    /* Read opening braces */
    i = 0;
    while ( i < 2 )
    {
        c = greentea_getc();
        /* Ignore any prevous CR LF characters */
        if ( c == '\n' || c == '\r' )
            continue;
        i++;
        if ( c != '{' )
            return( NULL );
    }

    /* Read data length */
    *data_len = receive_uint32();
    data = (uint8_t *)malloc( *data_len );
    TEST_HELPER_ASSERT( data != NULL );

    greentea_getc(); // read ';' received after key i.e. *data_len

    for( i = 0; i < *data_len; i++ )
        data[i] = receive_byte();

    /* Read closing braces */
    for( i = 0; i < 2; i++ )
    {
        c = greentea_getc();
        if ( c != '}' )
        {
            errors++;
            break;
        }
    }

    if ( errors )
    {
        free( data );
        data = NULL;
        *data_len = 0;
    }

    return( data );
}

/**
 * \brief       Parse the received byte array and count the number of arguments
 *              to the test function passed as type hex.
 *
 * \param count     Parameter count
 * \param data      Received Byte array
 * \param data_len  Byte array length
 *
 * \return      count of hex params
 */
uint32_t find_hex_count( uint8_t count, uint8_t * data, uint32_t data_len )
{
    uint32_t i = 0, sz = 0;
    char c;
    uint8_t * p = NULL;
    uint32_t hex_count = 0;

    p = data;

    for( i = 0; i < count; i++ )
    {
        c = (char)*p;
        INCR_ASSERT( p, data, data_len, 1 );

        /* Align p to 4 bytes for int, expression, string len or hex length */
        ALIGN_32BIT( p, data, data_len );

        /* Network to host conversion */
        sz = (int32_t)parse_uint32( p );

        INCR_ASSERT( p, data, data_len, sizeof( int32_t ) );

        if ( c == 'H' || c == 'S' )
        {
            INCR_ASSERT( p, data, data_len, sz );
            hex_count += ( c == 'H' )?1:0;
        }
    }

    return( hex_count );
}

/**
 * \brief       Parses received byte array for test parameters.
 *
 * \param count     Parameter count
 * \param data      Received Byte array
 * \param data_len  Byte array length
 * \param error     Parsing error out variable.
 *
 * \return      Array of parsed parameters allocated on heap.
 *              Note: Caller has the responsibility to delete
 *                    the memory after use.
 */
void ** parse_parameters( uint8_t count, uint8_t * data, uint32_t data_len,
                          int * error )
{
    uint32_t i = 0, hex_count = 0;
    char c;
    void ** params = NULL;
    void ** cur = NULL;
    uint8_t * p = NULL;

    hex_count = find_hex_count(count, data, data_len);

    params = (void **)malloc( sizeof( void *) * ( count + hex_count ) );
    TEST_HELPER_ASSERT( params != NULL );
    cur = params;

    p = data;

    /* Parameters */
    for( i = 0; i < count; i++ )
    {
        c = (char)*p;
        INCR_ASSERT( p, data, data_len, 1 );

        /* Align p to 4 bytes for int, expression, string len or hex length */
        ALIGN_32BIT( p, data, data_len );

        /* Network to host conversion */
        *( (int32_t *)p ) = (int32_t)parse_uint32( p );

        switch( c )
        {
            case 'E':
                {
                    if ( get_expression( *( (int32_t *)p ), (int32_t *)p ) )
                    {
                        *error = KEY_VALUE_MAPPING_NOT_FOUND;
                        goto exit;
                    }
                } /* Intentional fall through */
            case 'I':
                {
                    *cur++ = (void *)p;
                    INCR_ASSERT( p, data, data_len, sizeof( int32_t ) );
                }
                break;
            case 'H': /* Intentional fall through */
            case 'S':
                {
                    uint32_t * sz = (uint32_t *)p;
                    INCR_ASSERT( p, data, data_len, sizeof( int32_t ) );
                    *cur++ = (void *)p;
                    if ( c == 'H' )
                        *cur++ = (void *)sz;
                    INCR_ASSERT( p, data, data_len, ( *sz ) );
                }
                break;
            default:
                    {
                        *error = DISPATCH_INVALID_TEST_DATA;
                        goto exit;
                    }
                break;
        }
    }

exit:
    if ( *error )
    {
        free( params );
        params = NULL;
    }

    return( params );
}

/**
 * \brief       Sends greentea key and int value pair to host.
 *
 * \param key   key string
 * \param value integer value
 *
 * \return      void
 */
void send_key_integer( char * key, int value )
{
    char str[50];
    snprintf( str, sizeof( str ), "%d", value );
    greentea_send_kv( key, str );
}

/**
 * \brief       Sends test setup failure to the host.
 *
 * \param failure   Test set failure
 *
 * \return      void
 */
void send_failure( int failure )
{
    send_key_integer( "F", failure );
}

/**
 * \brief       Sends test status to the host.
 *
 * \param status    Test status (PASS=0/FAIL=!0)
 *
 * \return      void
 */
void send_status( int status )
{
    send_key_integer( "R", status );
}


/**
 * \brief       Embedded implementation of execute_tests().
 *              Ignores command line and received test data
 *              on serial.
 *
 * \param argc  not used
 * \param argv  not used
 *
 * \return      Program exit status.
 */
int execute_tests( int args, const char ** argv )
{
    int ret = 0;
    uint32_t data_len = 0;
    uint8_t count = 0, function_id;
    void ** params = NULL;
    uint8_t * data = NULL, * p = NULL;

    GREENTEA_SETUP( 180, "mbedtls_test" );
    greentea_send_kv( "GO", " " );

    while ( 1 )
    {
        ret = 0;
        test_info.failed = 0;
        data_len = 0;

        data = receive_data( &data_len );
        if ( data == NULL )
            continue;
        p = data;

        do
        {
            /* Read dependency count */
            count = *p;
            TEST_HELPER_ASSERT( count < data_len );
            INCR_ASSERT( p, data, data_len, sizeof( uint8_t ) );
            ret = verify_dependencies( count, p );
            if ( ret != DEPENDENCY_SUPPORTED )
                break;

            if ( count )
                INCR_ASSERT( p, data, data_len, count );

            /* Read function id */
            function_id = *p;
            INCR_ASSERT( p, data, data_len, sizeof( uint8_t ) );
            if ( ( ret = check_test( function_id ) ) != DISPATCH_TEST_SUCCESS )
                break;

            /* Read number of parameters */
            count = *p;
            INCR_ASSERT( p, data, data_len, sizeof( uint8_t ) );

            /* Parse parameters if present */
            if ( count )
            {
                params = parse_parameters( count, p, data_len - ( p - data ), &ret );
                if ( ret )
                    break;
            }

            ret = dispatch_test( function_id, params );
        }
        while ( 0 );

        if ( data )
        {
            free( data );
            data = NULL;
        }

        if ( params )
        {
            free( params );
            params = NULL;
        }

        if ( ret )
            send_failure( ret );
        else
            send_status( test_info.failed );
    }
    return( 0 );
}