# QUANTARION-AI: FIRST LIGHT TEST SCRIPT (v1.0-ALPHA)
# Hardware: 88-Node Phononic Core | Link: 2.402 GHz RF
import quantarion_rf as qrf
import time

def initiate_first_light():
    print("🚀 INITIALIZING PIEZO-RF DRIVE...")
    # 1. Lock Carrier Frequency to the Topological Peak
    carrier_freq = 2.402e9  # 2.402 GHz
    qrf.set_carrier(carrier_freq)
    
    # 2. Define "Hello World" SNN Spiking Sequence
    # Encoded as 4-bit TPSK Phase Shifts (pi/8 intervals)
    hello_world_spikes = [15, 7, 0, 7, 15] 
    
    print(f"📡 SENDING TOPOLOGICAL PULSE: {hello_world_spikes}")
    
    # 3. Execution: Injecting the Spikes into the 88-Node Lattice
    start_time = time.perf_counter_ns()
    response = qrf.inject_topological_pulse(hello_world_spikes, modulation='TPSK')
    end_time = time.perf_counter_ns()
    
    # 4. Verification: Check T2 Coherence and Bandgap Isolation
    coherence = qrf.measure_coherence_time() # Target > 520us
    rejection = qrf.get_out_of_band_rejection() # Target > 65dB
    
    return {
        "latency_ns": end_time - start_time,
        "coherence_us": coherence * 1e6,
        "rejection_db": rejection,
        "status": "PASS" if coherence > 520e-6 and rejection > 60 else "FAIL"
    }

# RUN THE TEST
results = initiate_first_light()
print(f"📊 TEST RESULTS: {results}")