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#ifndef _FORMAT_H
#define _FORMAT_H
#include "ledger.h"
#include "valexpr.h"
namespace ledger {
std::string truncated(const std::string& str, unsigned int width);
std::string partial_account_name(const account_t * account,
const unsigned int start_depth);
struct element_t
{
enum kind_t {
STRING,
VALUE_EXPR,
DATE_STRING,
CLEARED,
CODE,
PAYEE,
ACCOUNT_NAME,
ACCOUNT_FULLNAME,
OPT_AMOUNT,
VALUE,
TOTAL,
SPACER
};
bool align_left;
unsigned int min_width;
unsigned int max_width;
kind_t type;
std::string chars;
node_t * val_expr;
struct element_t * next;
element_t() : align_left(false), min_width(0), max_width(0),
type(STRING), val_expr(NULL), next(NULL) {}
~element_t() {
if (val_expr) delete val_expr;
if (next) delete next; // recursive, but not too deep
}
};
struct format_t
{
element_t * elements;
static std::auto_ptr<node_t> value_expr;
static std::auto_ptr<node_t> total_expr;
format_t(const std::string& _format) : elements(NULL) {
reset(_format);
}
~format_t() {
if (elements) delete elements;
}
void reset(const std::string& _format) {
if (elements)
delete elements;
elements = parse_elements(_format);
}
static element_t * parse_elements(const std::string& fmt);
void format_elements(std::ostream& out, const details_t& details) const;
static void compute_value(balance_t& result, const details_t& details) {
if (value_expr.get())
value_expr->compute(result, details);
}
static void compute_total(balance_t& result, const details_t& details) {
if (total_expr.get())
total_expr->compute(result, details);
}
};
class format_transaction
{
std::ostream& output_stream;
const format_t& first_line_format;
const format_t& next_lines_format;
const bool collapsed;
const bool inverted;
item_predicate<transaction_t> disp_pred_functor;
typedef bool (*intercept_t)(transaction_t * xact);
intercept_t intercept;
mutable balance_pair_t subtotal;
mutable unsigned int count;
mutable entry_t * last_entry;
mutable transaction_t * last_xact;
public:
format_transaction(std::ostream& _output_stream,
const format_t& _first_line_format,
const format_t& _next_lines_format,
const node_t * display_predicate,
const bool _collapsed = false,
const bool _inverted = false,
intercept_t _intercept = NULL)
: output_stream(_output_stream),
first_line_format(_first_line_format),
next_lines_format(_next_lines_format),
collapsed(_collapsed), inverted(_inverted),
disp_pred_functor(display_predicate),
intercept(_intercept), count(0),
last_entry(NULL), last_xact(NULL) {}
void start() const {}
void finish() const {
if (subtotal)
report_cumulative_subtotal();
}
void report_cumulative_subtotal() const;
void operator()(transaction_t * xact) const;
};
// An intercept that can be used to report changes in commodity value
bool report_changed_values(transaction_t * xact);
class format_account
{
std::ostream& output_stream;
const format_t& format;
item_predicate<account_t> disp_pred_functor;
mutable const account_t * last_account;
public:
format_account(std::ostream& _output_stream,
const format_t& _format,
const node_t * display_predicate = NULL)
: output_stream(_output_stream), format(_format),
disp_pred_functor(display_predicate), last_account(NULL) {}
void start() const {}
void finish() const {}
void operator()(const account_t * account,
const unsigned int max_depth = 1,
const bool report_top = false) const;
};
} // namespace ledger
#endif // _REPORT_H
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