Model/backend/tests/test_integration.py

# import ast
# import json
from copy import deepcopy
# from dataclasses import replace
# from datetime import datetime

import random
from tqdm import tqdm
# import pandas as pd
import numpy as np
from etl.epc.Record import EPCRecord
# from backend.SearchEpc import SearchEpc
# from sqlalchemy.exc import IntegrityError, OperationalError
# from sqlalchemy.orm import sessionmaker
# from starlette.responses import Response

# from backend.app.config import get_settings, get_prediction_buckets
# from backend.app.db.connection import db_engine
# from backend.app.db.functions.materials_functions import get_materials
# from backend.app.db.functions.portfolio_functions import aggregate_portfolio_recommendations
# from backend.app.db.functions.property_functions import (
#     create_property, create_property_details_epc, create_property_targets, update_property_data,
#     update_or_create_property_spatial_details
# )
# from backend.app.db.functions.recommendations_functions import (
#     create_plan, upload_recommendations, create_scenario
# )
# from backend.app.db.functions.funding_functions import upload_funding
# from backend.app.db.functions.energy_assessment_functions import get_latest_assessment_by_uprn
# from backend.app.db.models.portfolio import rating_lookup
from backend.app.plan.schemas import PlanTriggerRequest, WALL_INSULATION_MEASURES, ROOF_INSULATION_MEASURES
# from backend.app.plan.utils import get_cleaned
# from backend.app.utils import sap_to_epc
import backend.app.assumptions as assumptions

from backend.ml_models.api import ModelApi
from backend.Property import Property
from backend.apis.GoogleSolarApi import GoogleSolarApi

from recommendations.optimiser.CostOptimiser import CostOptimiser
from recommendations.optimiser.GainOptimiser import GainOptimiser
import recommendations.optimiser.optimiser_functions as optimiser_functions
from recommendations.Recommendations import Recommendations
# from utils.logger import setup_logger
# from utils.s3 import read_dataframe_from_s3_parquet, read_csv_from_s3, read_excel_from_s3
# from backend.ml_models.Valuation import PropertyValuation
#
# from etl.bill_savings.KwhData import KwhData
# from etl.spatial.OpenUprnClient import OpenUprnClient
# from etl.find_my_epc.RetrieveFindMyEpc import RetrieveFindMyEpc

from backend.Funding import Funding
from recommendations.optimiser.funding_optimiser import optimise_with_funding_paths
from recommendations.recommendation_utils import convert_thickness_to_numeric, get_wall_u_value

# Input data (temp)
import pickle

import pandas as pd

with open("local_data_for_deletion.pkl", 'rb') as f:
    local_data = pickle.load(f)

cleaning_data = local_data["cleaning_data"]
materials = local_data["materials"]
cleaned = local_data["cleaned"]
project_scores_matrix = local_data["project_scores_matrix"]
partial_project_scores_matrix = local_data["partial_project_scores_matrix"]
whlg_eligible_postcodes = local_data["whlg_eligible_postcodes"]

with open("kwh_client_for_deletion.pkl", "rb") as f:
    kwh_client = pickle.load(f)

epc_data = pd.read_csv(
    "/Users/khalimconn-kowlessar/Downloads/domestic-E06000002-Middlesbrough/certificates.csv",
    low_memory=False
)

# TODO: Store this for cleaning
costs_by_floor_area = epc_data[
    pd.to_datetime(epc_data["LODGEMENT_DATE"]) >= "2024-01-01"
    ][["TOTAL_FLOOR_AREA", "CURRENT_ENERGY_EFFICIENCY", "LIGHTING_COST_CURRENT", "HEATING_COST_CURRENT",
       "HOT_WATER_COST_CURRENT"]].copy()

costs_by_floor_area.columns = [c.lower().replace("_", "-") for c in costs_by_floor_area.columns]
for c in ["lighting-cost-current", "heating-cost-current", "hot-water-cost-current"]:
    costs_by_floor_area[c + "_scaled"] = costs_by_floor_area[c] / costs_by_floor_area["total-floor-area"]

costs_by_floor_area = costs_by_floor_area.groupby("current-energy-efficiency")[
    ["lighting-cost-current_scaled", "heating-cost-current_scaled", "hot-water-cost-current_scaled"]
].mean().reset_index()

sample_epc_data = epc_data[pd.to_datetime(epc_data["LODGEMENT_DATE"]) >= "2015-01-01"].drop_duplicates("UPRN").sample(
    3000).reset_index(drop=True)

# TODO: In Property find_energy_sources, sort out biomass community heating - what fuel type
# TODO: We might be able to remove find_energy_sources entirely and remove estimate_electrical_consumption. It's used
#       in the google solar api but is it really needed? I don't think it's super accurate. It might be better to
#       just use an average energy consumption by floor area for UK households?
# Load the input properties
input_properties = []
for row_id, config in tqdm(sample_epc_data.iterrows(), total=len(sample_epc_data)):
    epc = {
        k.lower().replace("_", "-"): v if not pd.isnull(v) else None for k, v in config.items()
    }
    # Avoid the data load inside of EPCRecord - something we should pull out
    for x in ["number-habitable-rooms", "floor-height", "number-heated-rooms"]:
        if pd.isnull(epc[x]):
            if x == "floor-height":
                epc[x] = 2.4
            if x == "number-habitable-rooms":
                epc[x] = 3
            if x == "number-heated-rooms":
                epc[x] = 3

    epc_records = {'original_epc': epc, 'full_sap_epc': {}, 'old_data': []}

    prepared_epc = EPCRecord(
        epc_records=epc_records,
        run_mode="newdata",
        cleaning_data=cleaning_data,
    )

    input_properties.append(
        Property(
            id=row_id,
            is_new=True,
            address=epc["address"],
            postcode=epc["postcode"],
            epc_record=prepared_epc,
            already_installed={},
            property_valuation={},
            non_invasive_recommendations=[],
            energy_assessment=None,
            **Property.extract_kwargs(config),  # TODO: Depraecate this
        )
    )

# For each property, insert the default solar configuration
for p in tqdm(input_properties):
    solar_api = GoogleSolarApi(
        api_key=None, solar_materials=[m for m in materials if m["type"] == "solar_pv"], max_retries=5
    )
    panel_performance = solar_api.default_panel_performance(property_instance=p)
    p.set_solar_panel_configuration(
        solar_panel_configuration={
            "insights_data": None, "panel_performance": panel_performance, "unit_share_of_energy": 1
        },
    )

# We mock kwh preds
mocked_kwh_predictions = {"heating_kwh_predictions": [], "hotwater_kwh_predictions": []}
for p in tqdm(input_properties):
    mocked_kwh_predictions["heating_kwh_predictions"].append({
        "id": p.uprn, "predictions": random.sample(range(100, 3000), 1)[0]
    })
    mocked_kwh_predictions["hotwater_kwh_predictions"].append({
        "id": p.uprn, "predictions": random.sample(range(100, 3000), 1)[0]
    })
mocked_kwh_predictions["heating_kwh_predictions"] = pd.DataFrame(mocked_kwh_predictions["heating_kwh_predictions"])
mocked_kwh_predictions["hotwater_kwh_predictions"] = pd.DataFrame(mocked_kwh_predictions["hotwater_kwh_predictions"])

# TODO: We might want to implement this generally, via an ETL process
for p in input_properties:
    for col in ["lighting-cost-current", "heating-cost-current", "hot-water-cost-current"]:
        if pd.isnull(p.data[col]):
            min_diff = abs(
                (costs_by_floor_area["current-energy-efficiency"] - p.data["current-energy-efficiency"])
            ).min()
            df = costs_by_floor_area[
                abs((costs_by_floor_area["current-energy-efficiency"] - p.data[
                    "current-energy-efficiency"])) == min_diff
                ]
            if df.shape[0] > 1:
                df = df.head(1)
            p.data[col] = (df[col + "_scaled"] * p.data["total-floor-area"]).values[0]

[
    p.set_features(cleaned=cleaned, kwh_client=kwh_client, kwh_predictions=mocked_kwh_predictions) for p in
    input_properties
]
# for p in input_properties:
#     p.set_features(cleaned=cleaned, kwh_client=kwh_client, kwh_predictions=mocked_kwh_predictions)

# Run the recommendations
recommendations = {}
recommendations_scoring_data = []
representative_recommendations = {}
for p in tqdm(input_properties):
    if p.data["property-type"] == "House" and pd.isnull(p.data["built-form"]):
        p.data["built-form"] = "Semi-Detached"
    recommender = Recommendations(
        property_instance=p,
        materials=materials,
        exclusions=[],
        inclusions=[],
        default_u_values=True
    )
    property_recommendations, property_representative_recommendations = recommender.recommend()

    if not property_recommendations:
        continue

    recommendations[p.id] = property_recommendations
    representative_recommendations[p.id] = property_representative_recommendations

    p.create_base_difference_epc_record(cleaned_lookup=cleaned)
    p.adjust_difference_record_with_recommendations(
        property_recommendations, property_representative_recommendations
    )

    recommendations_scoring_data.extend(p.recommendations_scoring_data)

recommendations_scoring_data = pd.DataFrame(recommendations_scoring_data)
recommendations_scoring_data = recommendations_scoring_data.drop(
    columns=[
        "rdsap_change", "heat_demand_change", "carbon_change", "sap_ending", "heat_demand_ending",
        "carbon_ending"
    ]
)

model_predictions_mocked = {
    "sap_change_predictions": None,
    "heat_demand_predictions": None,
    "carbon_change_predictions": None,
    "heating_kwh_predictions": None,
    "hotwater_kwh_predictions": None,
}

for k in model_predictions_mocked.keys():
    model_predictions_mocked[k] = recommendations_scoring_data[["id"]].copy()
    model_predictions_mocked[k][['property_id', 'recommendation_id']] = (
        model_predictions_mocked[k]['id'].str.split('+', expand=True)
    )
    model_predictions_mocked[k]['phase'] = model_predictions_mocked[k]['recommendation_id'].apply(
        ModelApi.extract_phase)

    if k in ["heating_kwh_predictions", "hotwater_kwh_predictions"]:
        model_predictions_mocked[k]["predictions"] = random.choices(range(100, 3000),
                                                                    k=len(recommendations_scoring_data))
        continue

    model_predictions_mocked[k] = model_predictions_mocked[k].sort_values(["property_id", "phase"], ascending=True)
    preds = []
    for p_id in model_predictions_mocked[k]["property_id"].unique():
        # We add some amount each time
        p = [p for p in input_properties if str(p.id) == p_id][0]
        if k == "sap_change_predictions":
            start = p.data["current-energy-efficiency"]
        elif k == "heat_demand_predictions":
            start = p.data["energy-consumption-current"]
        else:
            start = p.data["co2-emissions-current"]
        df = model_predictions_mocked[k][model_predictions_mocked[k]["property_id"] == p_id].copy()
        # Add some amount each time
        to_add = random.choices(range(0, 15), k=len(df))
        to_add = np.cumsum(to_add)
        df["predictions"] = start + to_add
        preds.append(df)
    preds = pd.concat(preds)
    model_predictions_mocked[k] = preds

for property_id in tqdm(recommendations.keys(), total=len(recommendations)):
    property_instance = [p for p in input_properties if p.id == property_id][0]

    recommendations_with_impact, impact_summary = (
        Recommendations.calculate_recommendation_impact(
            property_instance=property_instance,
            all_predictions=model_predictions_mocked,
            recommendations=recommendations,
            representative_recommendations=representative_recommendations
        )
    )

    # We use the impact_summary to update the simulation_epcs with the new SAP, heat demand, carbon, cost etc
    # at each phase
    property_instance.update_simulation_epcs(impact_summary)
    recommendations[property_id] = recommendations_with_impact

for property_id in tqdm([p.id for p in input_properties]):
    property_recommendations = recommendations.get(property_id, [])
    property_instance = [p for p in input_properties if p.id == property_id][0]

    property_current_energy_bill = (
        Recommendations.calculate_recommendation_tenant_savings(
            property_instance=property_instance,
            kwh_simulation_predictions=model_predictions_mocked,
            property_recommendations=property_recommendations,
            ashp_cop=2.8
        )
    )
    property_instance.current_energy_bill = property_current_energy_bill

body = PlanTriggerRequest(
    **{'budget': None, 'goal': 'Increasing EPC', 'housing_type': 'Social', 'goal_value': 'B', 'portfolio_id': 0,
       'trigger_file_path': '', 'already_installed_file_path': '',
       'patches_file_path': None, 'non_invasive_recommendations_file_path': None,
       'valuation_file_path': '',
       'required_measures': [], 'scenario_name': 'EPC B', 'scenario_id': None,
       'multi_plan': True, 'optimise': True, 'default_u_values': True, 'ashp_cop': 2.8,
       'event_type': 'remote_assessment', 'simulate_sap_10': False, 'file_type': None, 'file_format': None,
       'sheet_name': None, 'sheet_count': None, 'index_start': None, 'index_end': None}
)

for p in tqdm(input_properties):
    if not recommendations.get(p.id):
        continue

    # we need to double unlist because we have a list of lists
    property_measure_types = {rec["type"] for recs in recommendations[p.id] for rec in recs}
    property_required_measures = [m for m in recommendations[p.id] if m[0]["type"] in body.required_measures]
    measures_to_optimise = [m for m in recommendations[p.id] if m[0]["type"] not in body.required_measures]

    # If a measure requiring ventilation is selected, and the property does not have ventilation, we enfore
    # its inclusion
    needs_ventilation = any(
        x in property_measure_types for x in assumptions.measures_needing_ventilation
    ) and not p.has_ventilation

    if not measures_to_optimise:
        # Nothing to do, we just reshape the recommendations
        recommendations[p.id] = optimiser_functions.flatten_recommendations_with_defaults(
            p.id, recommendations, set()
        )
        continue

    fixed_gain = optimiser_functions.calculate_fixed_gain(
        property_required_measures, recommendations, p, needs_ventilation
    )
    gain = optimiser_functions.calculate_gain(body=body, p=p, fixed_gain=fixed_gain)

    funding = Funding(
        tenure="Social",
        project_scores_matrix=project_scores_matrix,
        partial_project_scores_matrix=partial_project_scores_matrix,
        whlg_eligible_postcodes=whlg_eligible_postcodes,
        eco4_social_cavity_abs_rate=12.5,
        eco4_social_solid_abs_rate=17,
        eco4_private_cavity_abs_rate=12.5,
        eco4_private_solid_abs_rate=17,
        gbis_social_cavity_abs_rate=21,
        gbis_social_solid_abs_rate=25,
        gbis_private_cavity_abs_rate=21,
        gbis_private_solid_abs_rate=28,
    )

    li_thickness = convert_thickness_to_numeric(
        p.roof["insulation_thickness"], p.roof["is_pitched"], p.roof["is_flat"]
    )
    current_wall_u_value = p.walls["thermal_transmittance"]
    if current_wall_u_value is None:
        current_wall_u_value = get_wall_u_value(
            clean_description=p.walls["clean_description"],
            age_band=p.age_band,
            is_granite_or_whinstone=p.walls["is_granite_or_whinstone"],
            is_sandstone_or_limestone=p.walls["is_sandstone_or_limestone"],
        )

    # We insert the innovation uplift
    measures_to_optimise_with_uplift = deepcopy(measures_to_optimise)

    # TODO: Turn this into a function and store the innovaiton uplift
    for group in measures_to_optimise_with_uplift:
        for r in group:

            if r["type"] in ["mechanical_ventilation", "low_energy_lighting", "secondary_heating",
                             "extension_cavity_wall_insulation", "draught_proofing", "sealing_open_fireplace"]:
                (
                    r["partial_project_score"],
                    r["partial_project_funding"],
                    r["innovation_uplift"],
                    r["uplift_project_score"],
                ) = (
                    0, 0, 0, 0
                )
                continue

            (
                r["partial_project_score"], r["partial_project_funding"], r["innovation_uplift"],
                r["uplift_project_score"]
            ) = funding.get_innovation_uplift(
                measure=r,
                starting_sap=p.data["current-energy-efficiency"],
                floor_area=p.floor_area,
                is_cavity=p.walls["is_cavity_wall"],
                current_wall_uvalue=current_wall_u_value,
                is_partial="partial" in p.walls["clean_description"].lower(),
                existing_li_thickness=li_thickness,
                mainheating=p.main_heating,
                main_fuel=p.main_fuel,
                mainheat_energy_eff=p.data["mainheat-energy-eff"],
            )

    input_measures = optimiser_functions.prepare_input_measures(
        measures_to_optimise_with_uplift, body.goal, needs_ventilation, funding=True
    )

    # When the goal is Increasing EPC, we can run the funding optimiser
    if body.goal == "Increasing EPC":

        solutions = optimise_with_funding_paths(
            p=p,
            input_measures=input_measures,
            housing_type=body.housing_type,
            budget=body.budget,
            target_gain=gain,
            funding=funding
        )

        # Given the solutions we select the optimal one
        solutions["cost_less_full_project_funding"] = np.where(
            solutions["scheme"] == "eco4",
            solutions["total_cost"] - solutions["full_project_funding"] - solutions["total_uplift"],
            solutions["total_cost"] - solutions["partial_project_funding"] - solutions["total_uplift"]
        )

        solutions["cost_less_full_project_funding"] = (
            solutions["total_cost"] - solutions["full_project_funding"] - solutions["total_uplift"]
        )
        solutions = solutions.sort_values("cost_less_full_project_funding", ascending=True)

        if solutions["meets_upgrade_target"].any():
            # If we have a solution that meets the upgrade target, we select that one
            optimal_solution = solutions[solutions["meets_upgrade_target"]].iloc[0]
        else:
            # Pick the cheapest
            optimal_solution = solutions.iloc[0]

        # This is the list of measures that we will recommend
        scheme = optimal_solution["scheme"]
        funded_measures = optimal_solution["items"] if scheme != "none" else []
        solution = optimal_solution["items"] + optimal_solution["unfunded_items"]
        # This is the total amount of funding that the project will produce (including uplifts) (£)
        project_funding = optimal_solution["full_project_funding"] if scheme == "eco4" else \
            optimal_solution["partial_project_funding"]
        # This is the total amount of funding associated to the uplift (£)
        total_uplift = optimal_solution["total_uplift"]
        # This is the funding scheme selected
        # This is the full project ABS
        full_project_score = optimal_solution["project_score"]
        # This is the partial project ABS
        partial_project_score = optimal_solution["partial_project_score"]
        # This is the uplift score ABS
        uplift_project_score = optimal_solution["total_uplift_score"]
    else:
        # We optimise and then we determine eligibility for funding, based on the measures selected
        optimiser = (
            GainOptimiser(
                input_measures, max_cost=body.budget, max_gain=gain, allow_slack=False
            ) if body.budget else CostOptimiser(input_measures, min_gain=gain)
        )
        optimiser.setup()
        optimiser.solve()
        solution = optimiser.solution

        recommendation_types = []
        for measures in input_measures:
            for measure in measures:
                recommendation_types.append(measure["type"])
        recommendation_types = set(recommendation_types)

        has_wall_insulation_recommendation = any(
            (m in recommendation_types or "+".join([m, "mechanical_ventilation"])) for m in
            WALL_INSULATION_MEASURES
        )
        has_roof_insulation_recommendation = any(
            (m in recommendation_types or "+".join([m, "mechanical_ventilation"])) for m in
            ROOF_INSULATION_MEASURES
        )

        funding.check_funding(
            measures=solution,
            starting_sap=p.data["current-energy-efficiency"],
            ending_sap=p.data["current-energy-efficiency"] + sum([x["gain"] for x in solution]),
            floor_area=p.floor_area,
            mainheat_description=p.main_heating["clean_description"],
            heating_control_description=p.main_heating_controls["clean_description"],
            is_cavity=p.walls["is_cavity_wall"],
            current_wall_uvalue=current_wall_u_value,
            is_partial="partial" in p.walls["clean_description"].lower(),
            existing_li_thickness=li_thickness,
            mainheating=p.main_heating,
            main_fuel=p.main_fuel,
            mainheat_energy_eff=p.data["mainheat-energy-eff"],
            has_wall_insulation_recommendation=has_wall_insulation_recommendation,
            has_roof_insulation_recommendation=has_roof_insulation_recommendation,
        )

        # Determine the scheme
        scheme = "none"
        if funding.eco4_eligible:
            scheme = "eco4"
        if scheme == "none" and funding.gbis_eligible:
            scheme = "gbis"

        funded_measures = solution if scheme in ["gbis", "eco4"] else []
        project_funding = 0 if funding.full_project_abs is not None else funding.full_project_abs
        total_uplift = funding.eco4_uplift
        full_project_score = 0 if funding.full_project_abs is not None else funding.full_project_abs
        partial_project_score = funding.partial_project_abs
        uplift_project_score = funding.eco4_uplift if scheme == "eco4" else funding.gbis_uplift

    selected = {r["id"] for r in solution}

    if property_required_measures:
        solution = optimiser_functions.add_required_measures(
            property_id=p.id, property_required_measures=property_required_measures,
            recommendations=recommendations, selected=selected,
        )

    # Add best practice measures (ventilation/trickle vents)
    selected = optimiser_functions.add_best_practice_measures(p.id, solution, recommendations, selected)
    # Final flattening - Don't do this!
    # recommendations[p.id] = optimiser_functions.flatten_recommendations_with_defaults(
    #     p.id, recommendations, selected
    # )

    # TODO: functionise
    for measure in funded_measures:
        if "+mechanical_ventilation" in measure["type"]:
            measure["type"] = measure["type"].split("+mechanical_ventilation")[0]

    p.insert_funding(
        scheme=scheme,
        funded_measures=funded_measures,
        project_funding=project_funding,
        total_uplift=total_uplift,
        full_project_score=full_project_score,
        partial_project_score=partial_project_score,
        uplift_project_score=uplift_project_score
    )