def sections(self): sections = [] ''' Trade Section ''' if self.attr.id == "xxwld": export_tmap = Build("tree_map", "hs92", "export", self.attr, "all", "show", self.year) this_yo = self.models.Yo.query.filter_by(year = self.year).all() export_val = sum([o.export_val for o in this_yo]) export_subtitle = _(u"The total world trade in %(year)s was %(export_val)s. ", year=self.year, export_val=num_format(export_val, "export_val")) past_yr = self.year - 5 past_yo = self.models.Yo.query.filter_by(year = past_yr).all() growth_val = median([o.export_val_growth_pct_5 for o in this_yo]) chg = "increased" if growth_val >= 0 else "decreased" export_subtitle += _(u"During the last five years exports have %(increased_decreased)s at a median annualized rate of %(change_rate)s%%, from $%(past_export_val)s in %(past_year)s to $%(current_export_val)s in %(current_year)s. ", increased_decreased=chg, change_rate=num_format(growth_val*100), \ past_export_val=num_format(sum([o.export_val for o in past_yo])), past_year=past_yr, current_export_val=num_format(export_val), current_year=self.year) top_exports = self.models.Yp.query.filter_by(year = self.year, hs92_id_len=6).order_by(desc("export_val")).limit(2).all() export_subtitle += _(u"The most recent exports are led by %(top_export)s which represent %(top_export_pct)s%% of the total products exported, followed by %(second_export)s, which account for %(second_export_pct)s%%. ", top_export=top_exports[0].product.get_profile_link(), top_export_pct=num_format((top_exports[0].export_val/export_val)*100), \ second_export=top_exports[1].product.get_profile_link(), second_export_pct=num_format((top_exports[1].export_val/export_val)*100)) origins_tmap = Build("tree_map", "hs92", "import", self.attr, "show", "all", self.year) yo_exp = self.models.Yo.query.filter_by(year = self.year).order_by(desc("export_val")).limit(5).all() origin_list = self.stringify_items(yo_exp, "export_val", "country") origin_subtitle = _(u"The top exporters globally are %(origins)s.", origins=origin_list) trade_section = { "builds": [ {"title": _(u"Exports"), "build": export_tmap, "subtitle": export_subtitle, "tour":"This is just a test", "seq":5}, {"title": _(u"Origins"), "build": origins_tmap, "subtitle": origin_subtitle}, ] } else: export_subtitle, import_subtitle, dest_subtitle, origin_subtitle = [None]*4 export_tmap = Build("tree_map", "hs92", "export", self.attr, "all", "show", self.year) import_tmap = Build("tree_map", "hs92", "import", self.attr, "all", "show", self.year) yop_base = self.models.Yop.query.filter_by(year = self.year, origin = self.attr, hs92_id_len=6) # get growth past_yr = self.year - 5 past_yo = self.models.Yo.query.filter_by(year = past_yr, country = self.attr).first() this_yo = self.models.Yo.query.filter_by(year = self.year, country = self.attr).first() exp_val_stat = filter(lambda s: s["key"] == "export_val", self.stats()) if exp_val_stat: exp_val_stat = exp_val_stat.pop() export_subtitle = "" if self.attr.id != "xxwld": exp_rank = num_format(exp_val_stat["rank"], "ordinal") if exp_val_stat["rank"] > 1 else "" export_subtitle += _(u"In %(year)s %(country)s exported $%(export_val)s, making it the %(export_rank)s largest exporter in the world. ", year=self.year, country=self.attr.get_name(article=True), export_val=num_format(exp_val_stat["val"]), export_rank=exp_rank) if past_yo: chg = "increased" if this_yo.export_val_growth_pct_5 >= 0 else "decreased" export_subtitle += _(u"During the last five years the exports %(of_country)s have %(increased_decreased)s at an annualized rate of %(change_rate)s%%, from $%(past_export_val)s in %(past_year)s to $%(current_export_val)s in %(current_year)s. ", of_country=self.attr.get_name(article="of"), increased_decreased=chg, change_rate=num_format(this_yo.export_val_growth_pct_5*100), \ past_export_val=num_format(past_yo.export_val), past_year=past_yr, current_export_val=num_format(this_yo.export_val), current_year=self.year) top_exports = yop_base.order_by(desc("export_val")).limit(2).all() if top_exports: # raise Exception(top_exports[0].product.get_profile_link(), num_format((top_exports[0].export_val/exp_val_stat["val"])*100), self.attr.get_name(article="of"), top_exports[1].product.get_profile_link(), num_format((top_exports[1].export_val/exp_val_stat["val"])*100)) export_subtitle += _(u"The most recent exports are led by %(top_export)s which represent %(top_export_pct)s%% of the total exports %(of_country)s, followed by %(second_export)s, which account for %(second_export_pct)s%%.", top_export=top_exports[0].product.get_profile_link(), top_export_pct=num_format((top_exports[0].export_val/exp_val_stat["val"])*100), \ of_country=self.attr.get_name(article="of"), second_export=top_exports[1].product.get_profile_link(), second_export_pct=num_format((top_exports[1].export_val/exp_val_stat["val"])*100)) imp_val_stat = filter(lambda s: s["key"] == "import_val", self.stats()) if imp_val_stat: imp_val_stat = imp_val_stat.pop() import_subtitle = "" if self.attr.id != "xxwld": imp_rank = num_format(imp_val_stat["rank"], "ordinal") if imp_val_stat["rank"] > 1 else "" import_subtitle += _(u"In %(year)s %(country)s imported $%(import_val)s, making it the %(import_rank)s largest importer in the world. ", year=self.year, country=self.attr.get_name(article=True), import_val=num_format(imp_val_stat["val"]), import_rank=imp_rank) if past_yo: chg = "increased" if this_yo.import_val_growth_pct_5 >= 0 else "decreased" import_subtitle += _(u"During the last five years the imports %(of_country)s have %(increased_decreased)s at an annualized rate of %(change_rate)s%%, from $%(past_import_val)s in %(past_year)s to $%(current_import_val)s in %(current_year)s. ", of_country=self.attr.get_name(article="of"), increased_decreased=chg, change_rate=num_format(this_yo.import_val_growth_pct_5*100), \ past_import_val=num_format(past_yo.import_val), past_year=past_yr, current_import_val=num_format(this_yo.import_val), current_year=self.year) top_imports = yop_base.order_by(desc("import_val")).limit(2).all() if top_imports: import_subtitle += _(u"The most recent imports are led by %(top_import)s which represent %(top_import_pct)s%% of the total imports %(of_country)s, followed by %(second_import)s, which account for %(second_import_pct)s%%.", top_import=top_imports[0].product.get_profile_link(), top_import_pct=num_format((top_imports[0].import_val/imp_val_stat["val"])*100), \ of_country=self.attr.get_name(article="of"), second_import=top_imports[1].product.get_profile_link(), second_import_pct=num_format((top_imports[1].import_val/imp_val_stat["val"])*100)) dests_tmap = Build("tree_map", "hs92", "export", self.attr, "show", "all", self.year) yod_exp = self.models.Yod.query.filter_by(year = self.year, origin = self.attr).order_by(desc("export_val")).limit(5).all() if yod_exp: dest_list = self.stringify_items(yod_exp, "export_val", "dest") dest_subtitle = _(u"The top export destinations %(of_country)s are %(destinations)s.", of_country=self.attr.get_name(article="of"), destinations=dest_list) origins_tmap = Build("tree_map", "hs92", "import", self.attr, "show", "all", self.year) yod_imp = self.models.Yod.query.filter_by(year = self.year, dest = self.attr).order_by(desc("export_val")).limit(5).all() if yod_imp: origin_list = self.stringify_items(yod_imp, "export_val", "origin") origin_subtitle = _(u"The top import origins %(of_country)s are %(origins)s.", of_country=self.attr.get_name(article="of"), origins=origin_list) # trade balance viz -- first_yo = self.models.Yo.query.filter_by(year = available_years["hs92"][-1], country = self.attr).first() tb_subtitle = "" tb_build = Build("line", "hs92", "show", self.attr, "all", "all", available_years["hs92"]) if first_yo: net_trade = this_yo.export_val - this_yo.import_val trade_balance = _("positive") if net_trade >= 0 else _("negative") trade_direction = _("exports") if net_trade >= 0 else _("imports") tb_subtitle = _(u"As of %(year)s %(country)s had a %(positive_negative)s trade balance of $%(net_trade)s in net %(exports_imports)s.", year=self.year, country=self.attr.get_name(article=True), positive_negative=trade_balance, net_trade=num_format(abs(net_trade)), exports_imports=trade_direction) old_yo = self.models.Yo.query.filter_by(year = available_years["hs92"][0], country = self.attr).first() if old_yo: old_net_trade = old_yo.export_val - old_yo.import_val old_trade_balance = _("positive") if old_net_trade >= 0 else _("negative") old_trade_direction = _("exports") if old_net_trade >= 0 else _("imports") is_diff = True if old_trade_balance != trade_balance else False still_or_not = _("still") if old_trade_balance == trade_balance else "" tb_subtitle += _(u" As compared to their trade balance in %(year)s when they %(still)s had a %(positive_negative)s trade balance of $%(net_trade)s in net %(exports_imports)s.", year=available_years["hs92"][0], still=still_or_not, positive_negative=old_trade_balance, net_trade=num_format(abs(old_net_trade)), exports_imports=old_trade_direction) trade_section = { "builds": [ {"title": _(u"Exports"), "build": export_tmap, "subtitle": export_subtitle, "tour":"This is just a test", "seq":5}, {"title": _(u"Imports"), "build": import_tmap, "subtitle": import_subtitle}, {"title": _(u"Trade Balance"), "build": tb_build, "subtitle": tb_subtitle}, {"title": _(u"Destinations"), "build": dests_tmap, "subtitle": dest_subtitle}, {"title": _(u"Origins"), "build": origins_tmap, "subtitle": origin_subtitle}, ] } sections.append(trade_section) ''' Product Space Section ''' subtitle = False if self.attr.id != "xxwld": num_exports_w_rca = db.session.query(func.count(self.models.Yop.hs92_id)) \ .filter_by(year = self.year, origin = self.attr) \ .filter(self.models.Yop.export_rca >= 1) \ .filter(func.char_length(self.models.Yop.hs92_id)==6) \ .scalar() this_attr_yo = attrs.Yo.query.filter_by(year = self.year, country = self.attr).first() if this_attr_yo: eci = this_attr_yo.eci eci_rank = this_attr_yo.eci_rank if eci_rank: subtitle = _(u"The economy %(of_country)s has an Economic Complexity Index (ECI) of %(eci)s making it the %(eci_rank)s most complex country. ", of_country=self.attr.get_name(article="of"), eci=num_format(eci), eci_rank=num_format(eci_rank, "ordinal")) else: subtitle = "" subtitle += _(u"%(country)s exports %(num_of_exports)s products with revealed comparative advantage " \ u"(meaning that its share of global exports is larger than what " \ u"would be expected from the size of its export economy " \ u"and from the size of a product’s global market).", country=self.attr.get_name(article=True), num_of_exports=num_exports_w_rca) product_space = Build("network", "hs92", "export", self.attr, "all", "show", self.year) ps_text = _(u"The product space is a network connecting products that are likely to be co-exported and can be used to predict the evolution of a country’s export structure.") if subtitle: ps_text = u"{}</p><p>{}".format(ps_text, subtitle) ps_section = { "title": _(u"Economic Complexity %(of_country)s", of_country=self.attr.get_name(article="of")), "builds": [ {"title": _(u"Product Space"), "build": product_space, "subtitle": ps_text, "tour":"The product space...", "seq":6} ] } ''' ECI Ranking Section ''' if self.attr.id == "xxwld": line_rankings = Build("line", "sitc", "eci", "show", "all", "all", [y for y in available_years["sitc"] if y >= 1964]) start_year = 1980 start_year = max(1964, start_year) if start_year != 1980 else 1964 year_range = self.year - start_year subtitle = _("""The Economic Complexities of each country visualized over the past %(year_range)s years.""", year_range=year_range) ps_section["builds"].append({"title": _(u"Economic Complexity Ranking"), "build": line_rankings, "subtitle": subtitle}) elif this_attr_yo and this_attr_yo.eci != None: line_rankings = Build("line", "sitc", "eci", "show", self.attr, "all", [y for y in available_years["sitc"] if y >= 1964]) start_year = earliest_data.get(self.attr.id, 1980) start_year = max(1964, start_year) if start_year != 1980 else 1964 year_range = self.year - start_year attr_yo_historic = attrs.Yo.query.filter_by(country=self.attr).filter(attrs.Yo.year == start_year).first() if attr_yo_historic.eci_rank: eci_delta = this_attr_yo.eci_rank - attr_yo_historic.eci_rank inc_dec = _('increased') if eci_delta < 0 else _('decreased') subtitle = _("""The Economic Complexity ranking %(of_country)s has %(increased_or_decreased)s by %(rank_delta)s places over the past %(year_range)s years from %(old_eci)s in %(old_year)s to %(current_eci)s in %(current_year)s.""", of_country=self.attr.get_name(article="of"), increased_or_decreased=inc_dec, rank_delta=abs(eci_delta), year_range=year_range, old_eci=num_format(attr_yo_historic.eci_rank, "ordinal"), old_year=start_year, current_eci=num_format(this_attr_yo.eci_rank, "ordinal"), current_year=self.year) ps_section["builds"].append({"title": _(u"Economic Complexity Ranking"), "build": line_rankings, "subtitle": subtitle}) sections.append(ps_section) sections.append({ "title": _(u"More on %(country)s from our sister sites", country=self.attr.get_name(article=True)), "source": "sisters" }) ''' DataViva ''' if self.attr.id == "xxwld": dv_munic_dest_iframe = "http://dataviva.info/apps/embed/tree_map/secex/all/all/all/bra/?size=import_val&controls=false" dv_munic_dest_subtitle = _(u""" This treemap shows the municipalities in Brazil that imported products internationally.<br /><br /> DataViva is a visualization tool that provides official data on trade, industries, and education throughout Brazil. If you would like more info or to create a similar site get in touch with us at <a href='mailto:[email protected]'>[email protected]</a>. </p><p><a target='_blank' href='http://dataviva.info/apps/builder/tree_map/secex/all/all/all/bra/?size=import_val&controls=false'>Explore on DataViva <i class='fa fa-external-link'></i></a> """, country=self.attr.get_name(article=True)) dv_section = { "title": u"<a href='http://dataviva.info/' target='_blank'><img src='http://en.dataviva.info/static/img/nav/DataViva.png' /></a>", "source": "dataviva", "builds": [ {"title": _(u"Imports of Brazil by Municipality"), "iframe": dv_munic_dest_iframe, "subtitle": dv_munic_dest_subtitle, "tour":"Profile pages also contain visualizations from other websites created by member of the OEC team. The following are 2 embeded visualization from DataViva, a similar visualization platorm centered around Brazilian data.", "seq":7} ] } elif self.attr.id == "sabra": dv_geo_map = "http://en.dataviva.info/apps/embed/geo_map/secex/all/all/all/bra/?color=export_val&controls=false&year=2013" dv_wages = "http://en.dataviva.info/apps/embed/bar/rais/all/all/all/bra/?controls=false&year=2013" dv_geo_map_subtitle = _(u""" This map shows the exports of Brazil by state.<br /><br /> DataViva is a visualization tool that provides official data on trade, industries, and education throughout Brazil. If you would like more info or to create a similar site get in touch with us at <a href='mailto:[email protected]'>[email protected]</a>. </p><p><a target='_blank' href='http://en.dataviva.info/apps/builder/geo_map/secex/all/all/all/bra/?color=export_val&controls=false&year=2013'>Explore on DataViva <i class='fa fa-external-link'></i></a> """) dv_wages_subtitle = _(u""" This bar chart shows the wage distribution for the working population in Brazil. </p><p><a target='_blank' href='http://en.dataviva.info/apps/builder/bar/rais/all/all/all/bra/?controls=false&year=2013'>Explore on DataViva <i class='fa fa-external-link'></i></a> """) dv_section = { "title": u"<a href='http://dataviva.info/' target='_blank'><img src='http://en.dataviva.info/static/img/nav/DataViva.png' /></a>", "source": "dataviva", "builds": [ {"title": _(u"State Exports"), "iframe": dv_geo_map, "subtitle": dv_geo_map_subtitle, "tour":"Profile pages also contain visualizations from other websites created by member of the OEC team. The following are 2 embeded visualization from DataViva, a similar visualization platorm centered around Brazilian data.", "seq":7}, {"title": _(u"Wage Distribution"), "iframe": dv_wages, "subtitle": dv_wages_subtitle}, ] } else: dv_country_id = "asrus" if self.attr.id == "eurus" else self.attr.id dv_munic_dest_iframe = "http://dataviva.info/apps/embed/tree_map/secex/all/all/{}/bra/?size=import_val&controls=false".format(dv_country_id) dv_munic_origin_iframe = "http://dataviva.info/apps/embed/tree_map/secex/all/all/{}/bra/?size=export_val&controls=false".format(dv_country_id) dv_munic_dest_subtitle = _(u""" This treemap shows the municipalities in Brazil that imported products from %(country)s.<br /><br /> DataViva is a visualization tool that provides official data on trade, industries, and education throughout Brazil. If you would like more info or to create a similar site get in touch with us at <a href='mailto:[email protected]'>[email protected]</a>. </p><p><a target='_blank' href='http://dataviva.info/apps/builder/tree_map/secex/all/all/%(dv_country_id)s/bra/?size=import_val&controls=false'>Explore on DataViva <i class='fa fa-external-link'></i></a> """, country=self.attr.get_name(article=True), dv_country_id=dv_country_id) dv_munic_origin_subtitle = _(u""" This treemap shows the municipalities in Brazil that exported products to %(country)s. </p><p><a target='_blank' href='http://dataviva.info/apps/builder/tree_map/secex/all/all/%(dv_country_id)s/bra/?size=export_val&controls=false'>Explore on DataViva <i class='fa fa-external-link'></i></a> """, country=self.attr.get_name(article=True), dv_country_id=dv_country_id) dv_section = { "title": u"<a href='http://dataviva.info/' target='_blank'><img src='http://en.dataviva.info/static/img/nav/DataViva.png' /></a>", "source": "dataviva", "builds": [ {"title": _(u"Brazilian Municipalities that import from %(country)s", country=self.attr.get_name(article=True)), "iframe": dv_munic_dest_iframe, "subtitle": dv_munic_dest_subtitle, "tour":"Profile pages also contain visualizations from other websites created by member of the OEC team. The following are 2 embeded visualization from DataViva, a similar visualization platorm centered around Brazilian data.", "seq":7}, {"title": _(u"Brazilian Municipalities that export to %(country)s", country=self.attr.get_name(article=True)), "iframe": dv_munic_origin_iframe, "subtitle": dv_munic_origin_subtitle}, ] } sections.append(dv_section) ''' Pantheon ''' pantheon_id = "all" if self.attr.id == "xxwld" else self.attr.id_2char if pantheon_id: if self.attr.id != "xxwld": pantheon_id = pantheon_id.upper() pantheon_iframe_fields = "http://pantheon.media.mit.edu/treemap/country_exports/{}/all/-4000/2010/H15/pantheon/embed".format(pantheon_id) pantheon_link_fields = "<a target='_blank' href='http://pantheon.media.mit.edu/treemap/country_exports/{}/all/-4000/2010/H15/pantheon/'>Explore on Pantheon <i class='fa fa-external-link'></i></a>".format(pantheon_id) pantheon_iframe_cities = "http://pantheon.media.mit.edu/treemap/country_by_city/all/{}/-4000/2010/H15/pantheon/embed".format(pantheon_id) pantheon_link_cities = "<a target='_blank' href='http://pantheon.media.mit.edu/treemap/country_by_city/{}/all/-4000/2010/H15/pantheon/'>Explore on Pantheon <i class='fa fa-external-link'></i></a>".format(pantheon_id) pantheon_section = { "title": "<a target='_blank' href='http://pantheon.media.mit.edu'><img src='http://pantheon.media.mit.edu/pantheon_logo.png' />", "source": "pantheon", "builds": [ {"title": _(u"Globally Famous People %(of_country)s", of_country=self.attr.get_name(article="of")), "iframe": pantheon_iframe_fields, "subtitle": _(u"This treemap shows the cultural exports %(of_country)s, as proxied by the production of globally famous historical characters.</p><p>%(pantheon_link)s", of_country=self.attr.get_name(article="of"), pantheon_link=pantheon_link_fields), "tour":"Pantheon...", "seq":8 }, {"title": _(u"Globally Famous People %(of_country)s by City", of_country=self.attr.get_name(article="of")), "iframe": pantheon_iframe_cities, "subtitle": _(u"This treemap shows the cultural exports %(of_country)s by city, as proxied by the production of globally famous historical characters.</p><p>%(pantheon_link)s", of_country=self.attr.get_name(article="of"), pantheon_link=pantheon_link_cities) }, ] } sections.append(pantheon_section) return sections
def sections(self): sections = [] ''' Trade Section ''' if self.attr.id == "xxwld": export_tmap = Build("tree_map", "hs92", "export", self.attr, "all", "show", self.year) this_yo = self.models.Yo.query.filter_by(year=self.year).all() export_val = sum([o.export_val for o in this_yo]) export_subtitle = _( u"The total world trade in %(year)s was %(export_val)s.", year=self.year, export_val=num_format(export_val, "export_val")) export_subtitle += u" " past_yr = self.year - 5 past_yo = self.models.Yo.query.filter_by(year=past_yr).all() growth_val = median([o.export_val_growth_pct_5 for o in this_yo]) chg = "increased" if growth_val >= 0 else "decreased" export_subtitle += _(u"During the last five years exports have %(increased_decreased)s at a median annualized rate of %(change_rate)s%%, from $%(past_export_val)s in %(past_year)s to $%(current_export_val)s in %(current_year)s.", increased_decreased=chg, change_rate=num_format(growth_val*100), \ past_export_val=num_format(sum([o.export_val for o in past_yo])), past_year=past_yr, current_export_val=num_format(export_val), current_year=self.year) export_subtitle += u" " top_exports = self.models.Yp.query.filter_by( year=self.year, hs92_id_len=6).order_by(desc("export_val")).limit(2).all() export_subtitle += _(u"The most recent exports are led by %(top_export)s which represent %(top_export_pct)s%% of the total products exported, followed by %(second_export)s, which account for %(second_export_pct)s%%.", top_export=top_exports[0].product.get_profile_link(), top_export_pct=num_format((top_exports[0].export_val/export_val)*100), \ second_export=top_exports[1].product.get_profile_link(), second_export_pct=num_format((top_exports[1].export_val/export_val)*100)) origins_tmap = Build("tree_map", "hs92", "import", self.attr, "show", "all", self.year) yo_exp = self.models.Yo.query.filter_by(year=self.year).order_by( desc("export_val")).limit(5).all() origin_list = self.stringify_items(yo_exp, "export_val", "country") origin_subtitle = _(u"The top exporters globally are %(origins)s.", origins=origin_list) trade_section = { "builds": [ { "title": _(u"Exports"), "build": export_tmap, "subtitle": export_subtitle }, { "title": _(u"Origins"), "build": origins_tmap, "subtitle": origin_subtitle }, ] } else: export_subtitle, import_subtitle, dest_subtitle, origin_subtitle = [ None ] * 4 export_tmap = Build("tree_map", "hs92", "export", self.attr, "all", "show", self.year) import_tmap = Build("tree_map", "hs92", "import", self.attr, "all", "show", self.year) yop_base = self.models.Yop.query.filter_by(year=self.year, origin=self.attr, hs92_id_len=6) # get growth past_yr = self.year - 5 past_yo = self.models.Yo.query.filter_by( year=past_yr, country=self.attr).first() this_yo = self.models.Yo.query.filter_by( year=self.year, country=self.attr).first() exp_val_stat = filter(lambda s: s["key"] == "export_val", self.stats()) if exp_val_stat and this_yo: exp_val_stat = exp_val_stat.pop() export_subtitle = "" if self.attr.id != "xxwld": exp_rank = num_format( exp_val_stat["rank"], "ordinal") if exp_val_stat["rank"] > 1 else "" export_subtitle += _( u"In %(year)s %(country)s exported $%(export_val)s, making it the %(export_rank)s largest exporter in the world.", year=self.year, country=self.attr.get_name(article=True), export_val=num_format(exp_val_stat["val"]), export_rank=exp_rank) export_subtitle += u" " if past_yo and this_yo.export_val_growth_pct_5: chg = "increased" if this_yo.export_val_growth_pct_5 >= 0 else "decreased" export_subtitle += _(u"During the last five years the exports %(of_country)s have %(increased_decreased)s at an annualized rate of %(change_rate)s%%, from $%(past_export_val)s in %(past_year)s to $%(current_export_val)s in %(current_year)s.", of_country=self.attr.get_name(article="of"), increased_decreased=chg, change_rate=num_format(this_yo.export_val_growth_pct_5*100), \ past_export_val=num_format(past_yo.export_val), past_year=past_yr, current_export_val=num_format(this_yo.export_val), current_year=self.year) export_subtitle += u" " top_exports = yop_base.order_by( desc("export_val")).limit(2).all() if top_exports: # raise Exception(top_exports[0].product.get_profile_link(), num_format((top_exports[0].export_val/exp_val_stat["val"])*100), self.attr.get_name(article="of"), top_exports[1].product.get_profile_link(), num_format((top_exports[1].export_val/exp_val_stat["val"])*100)) export_subtitle += _(u"The most recent exports are led by %(top_export)s which represent %(top_export_pct)s%% of the total exports %(of_country)s, followed by %(second_export)s, which account for %(second_export_pct)s%%.", top_export=top_exports[0].product.get_profile_link(), top_export_pct=num_format((top_exports[0].export_val/exp_val_stat["val"])*100), \ of_country=self.attr.get_name(article="of"), second_export=top_exports[1].product.get_profile_link(), second_export_pct=num_format((top_exports[1].export_val/exp_val_stat["val"])*100)) imp_val_stat = filter(lambda s: s["key"] == "import_val", self.stats()) if imp_val_stat and this_yo: imp_val_stat = imp_val_stat.pop() import_subtitle = "" if self.attr.id != "xxwld": imp_rank = num_format( imp_val_stat["rank"], "ordinal") if imp_val_stat["rank"] > 1 else "" import_subtitle += _( u"In %(year)s %(country)s imported $%(import_val)s, making it the %(import_rank)s largest importer in the world.", year=self.year, country=self.attr.get_name(article=True), import_val=num_format(imp_val_stat["val"]), import_rank=imp_rank) import_subtitle += u" " if past_yo and this_yo.import_val_growth_pct_5: chg = "increased" if this_yo.import_val_growth_pct_5 >= 0 else "decreased" import_subtitle += _(u"During the last five years the imports %(of_country)s have %(increased_decreased)s at an annualized rate of %(change_rate)s%%, from $%(past_import_val)s in %(past_year)s to $%(current_import_val)s in %(current_year)s.", of_country=self.attr.get_name(article="of"), increased_decreased=chg, change_rate=num_format(this_yo.import_val_growth_pct_5*100), \ past_import_val=num_format(past_yo.import_val), past_year=past_yr, current_import_val=num_format(this_yo.import_val), current_year=self.year) import_subtitle += u" " top_imports = yop_base.order_by( desc("import_val")).limit(2).all() if top_imports: import_subtitle += _(u"The most recent imports are led by %(top_import)s which represent %(top_import_pct)s%% of the total imports %(of_country)s, followed by %(second_import)s, which account for %(second_import_pct)s%%.", top_import=top_imports[0].product.get_profile_link(), top_import_pct=num_format((top_imports[0].import_val/imp_val_stat["val"])*100), \ of_country=self.attr.get_name(article="of"), second_import=top_imports[1].product.get_profile_link(), second_import_pct=num_format((top_imports[1].import_val/imp_val_stat["val"])*100)) dests_tmap = Build("tree_map", "hs92", "export", self.attr, "show", "all", self.year) yod_exp = self.models.Yod.query.filter_by( year=self.year, origin=self.attr).order_by(desc("export_val")).limit(5).all() if yod_exp: dest_list = self.stringify_items(yod_exp, "export_val", "dest") dest_subtitle = _( u"The top export destinations %(of_country)s are %(destinations)s.", of_country=self.attr.get_name(article="of"), destinations=dest_list) origins_tmap = Build("tree_map", "hs92", "import", self.attr, "show", "all", self.year) yod_imp = self.models.Yod.query.filter_by( year=self.year, dest=self.attr).order_by(desc("export_val")).limit(5).all() if yod_imp: origin_list = self.stringify_items(yod_imp, "export_val", "origin") origin_subtitle = _( u"The top import origins %(of_country)s are %(origins)s.", of_country=self.attr.get_name(article="of"), origins=origin_list) # trade balance viz -- first_yo = self.models.Yo.query.filter_by( year=available_years["hs92"][-1], country=self.attr).first() tb_subtitle = "" tb_build = Build("line", "hs92", "show", self.attr, "all", "all", available_years["hs92"]) if first_yo: net_trade = this_yo.export_val - this_yo.import_val trade_balance = _("positive") if net_trade >= 0 else _( "negative") trade_direction = _("exports") if net_trade >= 0 else _( "imports") tb_subtitle = _( u"As of %(year)s %(country)s had a %(positive_negative)s trade balance of $%(net_trade)s in net %(exports_imports)s.", year=self.year, country=self.attr.get_name(article=True), positive_negative=trade_balance, net_trade=num_format(abs(net_trade)), exports_imports=trade_direction) old_yo = self.models.Yo.query.filter_by( year=available_years["hs92"][0], country=self.attr).first() if old_yo: old_net_trade = old_yo.export_val - old_yo.import_val old_trade_balance = _( "positive") if old_net_trade >= 0 else _("negative") old_trade_direction = _( "exports") if old_net_trade >= 0 else _("imports") is_diff = True if old_trade_balance != trade_balance else False still_or_not = _( "still") if old_trade_balance == trade_balance else "" tb_subtitle += u" " tb_subtitle += _( u"As compared to their trade balance in %(year)s when they %(still)s had a %(positive_negative)s trade balance of $%(net_trade)s in net %(exports_imports)s.", year=available_years["hs92"][0], still=still_or_not, positive_negative=old_trade_balance, net_trade=num_format(abs(old_net_trade)), exports_imports=old_trade_direction) trade_section = { "builds": [ { "title": _(u"Exports"), "build": export_tmap, "subtitle": export_subtitle, "tour": "This is just a test", "seq": 5 }, { "title": _(u"Imports"), "build": import_tmap, "subtitle": import_subtitle }, { "title": _(u"Trade Balance"), "build": tb_build, "subtitle": tb_subtitle }, { "title": _(u"Destinations"), "build": dests_tmap, "subtitle": dest_subtitle }, { "title": _(u"Origins"), "build": origins_tmap, "subtitle": origin_subtitle }, ] } sections.append(trade_section) ''' Product Space Section ''' subtitle = False if self.attr.id != "xxwld": num_exports_w_rca = db.session.query(func.count(self.models.Yop.hs92_id)) \ .filter_by(year = self.year, origin = self.attr) \ .filter(self.models.Yop.export_rca >= 1) \ .filter(func.char_length(self.models.Yop.hs92_id)==6) \ .scalar() this_attr_yo = attrs.Yo.query.filter_by(year=self.year, country=self.attr).first() if this_attr_yo: eci = this_attr_yo.eci eci_rank = this_attr_yo.eci_rank if eci_rank: subtitle = _( u"The economy %(of_country)s has an Economic Complexity Index (ECI) of %(eci)s making it the %(eci_rank)s most complex country.", of_country=self.attr.get_name(article="of"), eci=num_format(eci), eci_rank=num_format(eci_rank, "ordinal")) subtitle += u" " else: subtitle = "" subtitle += _(u"%(country)s exports %(num_of_exports)s products with revealed comparative advantage " \ u"(meaning that its share of global exports is larger than what " \ u"would be expected from the size of its export economy " \ u"and from the size of a product’s global market).", country=self.attr.get_name(article=True), num_of_exports=num_exports_w_rca) product_space = Build("network", "hs92", "export", self.attr, "all", "show", self.year) ps_text = _( u"The product space is a network connecting products that are likely to be co-exported and can be used to predict the evolution of a country’s export structure." ) if subtitle: ps_text = u"{}</p><p>{}".format(ps_text, subtitle) ps_section = { "title": _(u"Economic Complexity %(of_country)s", of_country=self.attr.get_name(article="of")), "builds": [{ "title": _(u"Product Space"), "build": product_space, "subtitle": ps_text, "tour": "The product space...", "seq": 6 }] } ''' PGI Section ''' if self.attr.id != "xxwld": pgi_product_space = Build("network", "sitc", "pgi", self.attr, "all", "show", available_years["sitc"][-1]) subtitle = _( "In this version of the product space products are colored according to their Product Gini Index, or PGI. The PGI of a product is the level of income inequality that we expect for the countries that export a product. For more information see: %(paper1)s and %(paper2)s.", country=self.attr.get_name(article=True), paper1= "<a target='_blank' href='https://arxiv.org/abs/1505.07907'>Linking Economic Complexity, Institutions and Income Inequality</a>", paper2= "<a target='_blank' href='https://arxiv.org/abs/1701.03770'>The structural constraints of income inequality in Latin America</a>" ) ps_section["builds"].append({ "title": _(u"Complexity and Income Inequality"), "build": pgi_product_space, "subtitle": subtitle }) ''' ECI Ranking Section ''' if self.attr.id == "xxwld": line_rankings = Build( "line", "sitc", "eci", "show", "all", "all", [y for y in available_years["sitc"] if y >= 1964]) start_year = 1980 start_year = max(1964, start_year) if start_year != 1980 else 1964 year_range = self.year - start_year subtitle = _( "The Economic Complexity of each country visualized over the past %(year_range)s years.", year_range=year_range) ps_section["builds"].append({ "title": _(u"Economic Complexity Ranking"), "build": line_rankings, "subtitle": subtitle }) elif this_attr_yo and this_attr_yo.eci != None: line_rankings = Build( "line", "sitc", "eci", "show", self.attr, "all", [y for y in available_years["sitc"] if y >= 1964]) start_year = earliest_data.get(self.attr.id, 1980) start_year = max(1964, start_year) if start_year != 1980 else 1964 year_range = self.year - start_year attr_yo_historic = attrs.Yo.query.filter_by( country=self.attr).filter(attrs.Yo.year == start_year).first() if attr_yo_historic and attr_yo_historic.eci_rank != None and this_attr_yo.eci_rank != None: eci_delta = this_attr_yo.eci_rank - attr_yo_historic.eci_rank inc_dec = _('increased') if eci_delta < 0 else _('decreased') subtitle = _( "The Economic Complexity ranking %(of_country)s has %(increased_or_decreased)s by %(rank_delta)s places over the past %(year_range)s years from %(old_eci)s in %(old_year)s to %(current_eci)s in %(current_year)s.", of_country=self.attr.get_name(article="of"), increased_or_decreased=inc_dec, rank_delta=abs(eci_delta), year_range=year_range, old_eci=num_format(attr_yo_historic.eci_rank, "ordinal"), old_year=start_year, current_eci=num_format(this_attr_yo.eci_rank, "ordinal"), current_year=self.year) ps_section["builds"].append({ "title": _(u"Economic Complexity Ranking"), "build": line_rankings, "subtitle": subtitle }) sections.append(ps_section) sections.append({ "title": _(u"More on %(country)s from our other sites", country=self.attr.get_name(article=True)), "source": "sisters" }) ''' DataViva ''' # dv_section = make_dv_section(self) # sections.append(dv_section) ''' Data USA ''' if self.attr.id == "nausa": us_section = make_us_section() sections.append(us_section) ''' Data Africa ''' if any(country[0] == self.attr.id for country in data_africa_countries): da_country = filter(lambda x: x[0] == self.attr.id, data_africa_countries) africa_section = make_africa_section(self, da_country[0]) sections.append(africa_section) # raise Exception("found dataafrican country: {}".format(da_country[0])) ''' Pantheon ''' pantheon_id = "all" if self.attr.id == "xxwld" else self.attr.id_2char if pantheon_id: if self.attr.id != "xxwld": pantheon_id = pantheon_id.upper() pantheon_section = make_pantheon_section(pantheon_id, self.attr) sections.append(pantheon_section) return sections
def sections(self): sections = [] ''' Trade Section ''' if self.attr.id == "xxwld": export_tmap = Build("tree_map", "hs92", "export", self.attr, "all", "show", self.year) this_yo = self.models.Yo.query.filter_by(year = self.year).all() export_val = sum([o.export_val for o in this_yo]) export_subtitle = _(u"The total world trade in %(year)s was %(export_val)s.", year=self.year, export_val=num_format(export_val, "export_val")) export_subtitle += u" " past_yr = self.year - 5 past_yo = self.models.Yo.query.filter_by(year = past_yr).filter(self.models.Yo.export_val.isnot(None)).all() growth_val = median([o.export_val_growth_pct_5 for o in this_yo]) chg = "increased" if growth_val >= 0 else "decreased" export_subtitle += _(u"During the last five years exports have %(increased_decreased)s at a median annualized rate of %(change_rate)s%%, from $%(past_export_val)s in %(past_year)s to $%(current_export_val)s in %(current_year)s.", increased_decreased=chg, change_rate=num_format(growth_val*100), \ past_export_val=num_format(sum([o.export_val for o in past_yo])), past_year=past_yr, current_export_val=num_format(export_val), current_year=self.year) export_subtitle += u" " top_exports = self.models.Yp.query.filter_by(year = self.year, hs92_id_len=6).order_by(desc("export_val")).limit(2).all() export_subtitle += _(u"The most recent exports are led by %(top_export)s which represent %(top_export_pct)s%% of the total products exported, followed by %(second_export)s, which account for %(second_export_pct)s%%.", top_export=top_exports[0].product.get_profile_link(), top_export_pct=num_format((top_exports[0].export_val/export_val)*100), \ second_export=top_exports[1].product.get_profile_link(), second_export_pct=num_format((top_exports[1].export_val/export_val)*100)) origins_tmap = Build("tree_map", "hs92", "import", self.attr, "show", "all", self.year) yo_exp = self.models.Yo.query.filter_by(year = self.year).order_by(desc("export_val")).limit(5).all() origin_list = self.stringify_items(yo_exp, "export_val", "country") origin_subtitle = _(u"The top exporters globally are %(origins)s.", origins=origin_list) trade_section = { "builds": [ {"title": _(u"Exports"), "build": export_tmap, "subtitle": export_subtitle}, {"title": _(u"Origins"), "build": origins_tmap, "subtitle": origin_subtitle}, ] } else: export_subtitle, import_subtitle, dest_subtitle, origin_subtitle = [None]*4 export_tmap = Build("tree_map", "hs92", "export", self.attr, "all", "show", self.year) import_tmap = Build("tree_map", "hs92", "import", self.attr, "all", "show", self.year) yop_base = self.models.Yop.query.filter_by(year = self.year, origin = self.attr, hs92_id_len=6) # get growth past_yr = self.year - 5 past_yo = self.models.Yo.query.filter_by(year = past_yr, country = self.attr).first() this_yo = self.models.Yo.query.filter_by(year = self.year, country = self.attr).first() exp_val_stat = filter(lambda s: s["key"] == "export_val", self.stats()) if exp_val_stat and this_yo: exp_val_stat = exp_val_stat.pop() export_subtitle = "" if self.attr.id != "xxwld": exp_rank = num_format(exp_val_stat["rank"], "ordinal") if exp_val_stat["rank"] > 1 else "" export_subtitle += _(u"In %(year)s %(country)s exported $%(export_val)s, making it the %(export_rank)s largest exporter in the world.", year=self.year, country=self.attr.get_name(article=True), export_val=num_format(exp_val_stat["val"]), export_rank=exp_rank) export_subtitle += u" " if past_yo and this_yo.export_val_growth_pct_5: chg = "increased" if this_yo.export_val_growth_pct_5 >= 0 else "decreased" export_subtitle += _(u"During the last five years the exports %(of_country)s have %(increased_decreased)s at an annualized rate of %(change_rate)s%%, from $%(past_export_val)s in %(past_year)s to $%(current_export_val)s in %(current_year)s.", of_country=self.attr.get_name(article="of"), increased_decreased=chg, change_rate=num_format(this_yo.export_val_growth_pct_5*100), \ past_export_val=num_format(past_yo.export_val), past_year=past_yr, current_export_val=num_format(this_yo.export_val), current_year=self.year) export_subtitle += u" " top_exports = yop_base.order_by(desc("export_val")).limit(2).all() if top_exports: # raise Exception(top_exports[0].product.get_profile_link(), num_format((top_exports[0].export_val/exp_val_stat["val"])*100), self.attr.get_name(article="of"), top_exports[1].product.get_profile_link(), num_format((top_exports[1].export_val/exp_val_stat["val"])*100)) export_subtitle += _(u"The most recent exports are led by %(top_export)s which represent %(top_export_pct)s%% of the total exports %(of_country)s, followed by %(second_export)s, which account for %(second_export_pct)s%%.", top_export=top_exports[0].product.get_profile_link(), top_export_pct=num_format((top_exports[0].export_val/exp_val_stat["val"])*100), \ of_country=self.attr.get_name(article="of"), second_export=top_exports[1].product.get_profile_link(), second_export_pct=num_format((top_exports[1].export_val/exp_val_stat["val"])*100)) imp_val_stat = filter(lambda s: s["key"] == "import_val", self.stats()) if imp_val_stat and this_yo: imp_val_stat = imp_val_stat.pop() import_subtitle = "" if self.attr.id != "xxwld": imp_rank = num_format(imp_val_stat["rank"], "ordinal") if imp_val_stat["rank"] > 1 else "" import_subtitle += _(u"In %(year)s %(country)s imported $%(import_val)s, making it the %(import_rank)s largest importer in the world.", year=self.year, country=self.attr.get_name(article=True), import_val=num_format(imp_val_stat["val"]), import_rank=imp_rank) import_subtitle += u" " if past_yo and this_yo.import_val_growth_pct_5: chg = "increased" if this_yo.import_val_growth_pct_5 >= 0 else "decreased" import_subtitle += _(u"During the last five years the imports %(of_country)s have %(increased_decreased)s at an annualized rate of %(change_rate)s%%, from $%(past_import_val)s in %(past_year)s to $%(current_import_val)s in %(current_year)s.", of_country=self.attr.get_name(article="of"), increased_decreased=chg, change_rate=num_format(this_yo.import_val_growth_pct_5*100), \ past_import_val=num_format(past_yo.import_val), past_year=past_yr, current_import_val=num_format(this_yo.import_val), current_year=self.year) import_subtitle += u" " top_imports = yop_base.order_by(desc("import_val")).limit(2).all() if top_imports: import_subtitle += _(u"The most recent imports are led by %(top_import)s which represent %(top_import_pct)s%% of the total imports %(of_country)s, followed by %(second_import)s, which account for %(second_import_pct)s%%.", top_import=top_imports[0].product.get_profile_link(), top_import_pct=num_format((top_imports[0].import_val/imp_val_stat["val"])*100), \ of_country=self.attr.get_name(article="of"), second_import=top_imports[1].product.get_profile_link(), second_import_pct=num_format((top_imports[1].import_val/imp_val_stat["val"])*100)) dests_tmap = Build("tree_map", "hs92", "export", self.attr, "show", "all", self.year) yod_exp = self.models.Yod.query.filter_by(year = self.year, origin = self.attr).order_by(desc("export_val")).limit(5).all() if yod_exp: dest_list = self.stringify_items(yod_exp, "export_val", "dest") dest_subtitle = _(u"The top export destinations %(of_country)s are %(destinations)s.", of_country=self.attr.get_name(article="of"), destinations=dest_list) origins_tmap = Build("tree_map", "hs92", "import", self.attr, "show", "all", self.year) yod_imp = self.models.Yod.query.filter_by(year = self.year, dest = self.attr).order_by(desc("export_val")).limit(5).all() if yod_imp: origin_list = self.stringify_items(yod_imp, "export_val", "origin") origin_subtitle = _(u"The top import origins %(of_country)s are %(origins)s.", of_country=self.attr.get_name(article="of"), origins=origin_list) # trade balance viz -- first_yo = self.models.Yo.query.filter_by(year = available_years["hs92"][-1], country = self.attr).first() tb_subtitle = "" tb_build = Build("line", "hs92", "show", self.attr, "all", "all", available_years["hs92"]) if first_yo: net_trade = this_yo.export_val - this_yo.import_val trade_balance = _("positive") if net_trade >= 0 else _("negative") trade_direction = _("exports") if net_trade >= 0 else _("imports") tb_subtitle = _(u"As of %(year)s %(country)s had a %(positive_negative)s trade balance of $%(net_trade)s in net %(exports_imports)s.", year=self.year, country=self.attr.get_name(article=True), positive_negative=trade_balance, net_trade=num_format(abs(net_trade)), exports_imports=trade_direction) old_yo = self.models.Yo.query.filter_by(year = available_years["hs92"][0], country = self.attr).first() if old_yo: old_net_trade = old_yo.export_val - old_yo.import_val old_trade_balance = _("positive") if old_net_trade >= 0 else _("negative") old_trade_direction = _("exports") if old_net_trade >= 0 else _("imports") is_diff = True if old_trade_balance != trade_balance else False still_or_not = _("still") if old_trade_balance == trade_balance else "" tb_subtitle += u" " tb_subtitle += _(u"As compared to their trade balance in %(year)s when they %(still)s had a %(positive_negative)s trade balance of $%(net_trade)s in net %(exports_imports)s.", year=available_years["hs92"][0], still=still_or_not, positive_negative=old_trade_balance, net_trade=num_format(abs(old_net_trade)), exports_imports=old_trade_direction) trade_section = { "builds": [ {"title": _(u"Exports"), "build": export_tmap, "subtitle": export_subtitle, "tour":"This is just a test", "seq":5}, {"title": _(u"Imports"), "build": import_tmap, "subtitle": import_subtitle}, {"title": _(u"Trade Balance"), "build": tb_build, "subtitle": tb_subtitle}, {"title": _(u"Destinations"), "build": dests_tmap, "subtitle": dest_subtitle}, {"title": _(u"Origins"), "build": origins_tmap, "subtitle": origin_subtitle}, ] } sections.append(trade_section) ''' Product Space Section ''' subtitle = False if self.attr.id != "xxwld": num_exports_w_rca = db.session.query(func.count(self.models.Yop.hs92_id)) \ .filter_by(year = self.year, origin = self.attr) \ .filter(self.models.Yop.export_rca >= 1) \ .filter(func.char_length(self.models.Yop.hs92_id)==6) \ .scalar() this_attr_yo = attrs.Yo.query.filter_by(year = self.year, country = self.attr).first() if this_attr_yo: eci = this_attr_yo.eci eci_rank = this_attr_yo.eci_rank if eci_rank: subtitle = _(u"The economy %(of_country)s has an Economic Complexity Index (ECI) of %(eci)s making it the %(eci_rank)s most complex country.", of_country=self.attr.get_name(article="of"), eci=num_format(eci), eci_rank=num_format(eci_rank, "ordinal")) subtitle += u" " else: subtitle = "" subtitle += _(u"%(country)s exports %(num_of_exports)s products with revealed comparative advantage " \ u"(meaning that its share of global exports is larger than what " \ u"would be expected from the size of its export economy " \ u"and from the size of a product’s global market).", country=self.attr.get_name(article=True), num_of_exports=num_exports_w_rca) product_space = Build("network", "hs92", "export", self.attr, "all", "show", self.year) ps_text = _(u"The product space is a network connecting products that are likely to be co-exported and can be used to predict the evolution of a country’s export structure.") if subtitle: ps_text = u"{}</p><p>{}".format(ps_text, subtitle) ps_section = { "title": _(u"Economic Complexity %(of_country)s", of_country=self.attr.get_name(article="of")), "builds": [ {"title": _(u"Product Space"), "build": product_space, "subtitle": ps_text, "tour":"The product space...", "seq":6} ] } ''' PGI Section ''' if self.attr.id != "xxwld": pgi_product_space = Build("network", "sitc", "pgi", self.attr, "all", "show", available_years["sitc"][-1]) subtitle = _("In this version of the product space products are colored according to their Product Gini Index, or PGI. The PGI of a product is the level of income inequality that we expect for the countries that export a product. For more information see: %(paper1)s and %(paper2)s.", country=self.attr.get_name(article=True), paper1="<a target='_blank' href='https://arxiv.org/abs/1505.07907'>Linking Economic Complexity, Institutions and Income Inequality</a>", paper2="<a target='_blank' href='https://arxiv.org/abs/1701.03770'>The structural constraints of income inequality in Latin America</a>") ps_section["builds"].append({"title": _(u"Complexity and Income Inequality"), "build": pgi_product_space, "subtitle": subtitle}) ''' ECI Ranking Section ''' if self.attr.id == "xxwld": line_rankings = Build("line", "sitc", "eci", "show", "all", "all", [y for y in available_years["sitc"] if y >= 1964]) start_year = 1980 start_year = max(1964, start_year) if start_year != 1980 else 1964 year_range = self.year - start_year subtitle = _("The Economic Complexity of each country visualized over the past %(year_range)s years.", year_range=year_range) ps_section["builds"].append({"title": _(u"Economic Complexity Ranking"), "build": line_rankings, "subtitle": subtitle}) elif this_attr_yo and this_attr_yo.eci != None: line_rankings = Build("line", "sitc", "eci", "show", self.attr, "all", [y for y in available_years["sitc"] if y >= 1964]) start_year = earliest_data.get(self.attr.id, 1980) start_year = max(1964, start_year) if start_year != 1980 else 1964 year_range = self.year - start_year attr_yo_historic = attrs.Yo.query.filter_by(country=self.attr).filter(attrs.Yo.year == start_year).first() if attr_yo_historic and attr_yo_historic.eci_rank != None and this_attr_yo.eci_rank != None: eci_delta = this_attr_yo.eci_rank - attr_yo_historic.eci_rank inc_dec = _('increased') if eci_delta < 0 else _('decreased') subtitle = _("The Economic Complexity ranking %(of_country)s has %(increased_or_decreased)s by %(rank_delta)s places over the past %(year_range)s years from %(old_eci)s in %(old_year)s to %(current_eci)s in %(current_year)s.", of_country=self.attr.get_name(article="of"), increased_or_decreased=inc_dec, rank_delta=abs(eci_delta), year_range=year_range, old_eci=num_format(attr_yo_historic.eci_rank, "ordinal"), old_year=start_year, current_eci=num_format(this_attr_yo.eci_rank, "ordinal"), current_year=self.year) ps_section["builds"].append({"title": _(u"Economic Complexity Ranking"), "build": line_rankings, "subtitle": subtitle}) sections.append(ps_section) sections.append({ "title": _(u"More on %(country)s from our other sites", country=self.attr.get_name(article=True)), "source": "sisters" }) ''' DataViva ''' # dv_section = make_dv_section(self) # sections.append(dv_section) ''' Data USA ''' if self.attr.id == "nausa": us_section = make_us_section() sections.append(us_section) ''' Data Africa ''' if any(country[0] == self.attr.id for country in data_africa_countries): da_country = filter(lambda x:x[0]==self.attr.id, data_africa_countries) africa_section = make_africa_section(self, da_country[0]) sections.append(africa_section) # raise Exception("found dataafrican country: {}".format(da_country[0])) ''' Pantheon ''' pantheon_id = "all" if self.attr.id == "xxwld" else self.attr.id_2char if pantheon_id: if self.attr.id != "xxwld": pantheon_id = pantheon_id.upper() pantheon_section = make_pantheon_section(pantheon_id, self.attr) sections.append(pantheon_section) return sections