diff options
Diffstat (limited to 'sc/inc/scfuncs.hrc')
| -rw-r--r-- | sc/inc/scfuncs.hrc | 4078 |
1 files changed, 4065 insertions, 13 deletions
diff --git a/sc/inc/scfuncs.hrc b/sc/inc/scfuncs.hrc index 5a4f016e6c7a..37e78ffc401e 100644 --- a/sc/inc/scfuncs.hrc +++ b/sc/inc/scfuncs.hrc @@ -16,18 +16,4070 @@ * except in compliance with the License. You may obtain a copy of * the License at http://www.apache.org/licenses/LICENSE-2.0 . */ -#include "scres.hrc" - -#define ID_FUNCTION_GRP_DATABASE 1 -#define ID_FUNCTION_GRP_DATETIME 2 -#define ID_FUNCTION_GRP_FINANZ 3 -#define ID_FUNCTION_GRP_INFO 4 -#define ID_FUNCTION_GRP_LOGIC 5 -#define ID_FUNCTION_GRP_MATH 6 -#define ID_FUNCTION_GRP_MATRIX 7 -#define ID_FUNCTION_GRP_STATISTIC 8 -#define ID_FUNCTION_GRP_TABLE 9 -#define ID_FUNCTION_GRP_TEXT 10 -#define ID_FUNCTION_GRP_ADDINS 11 +#ifndef INCLUDED_SC_INC_SCFUNCS_HRC +#define INCLUDED_SC_INC_SCFUNCS_HRC + +#define NC_(Context, String) (Context "\004" u8##String) + +/* Resource file for the function wizard / autopilot. + * + * For every function there is a StringArray with a resource id (offset by + * RID_SC_FUNC_DESCRIPTIONS_START) with the OpCode of the function + * + * In this stringarray, the description of the function is given as the first + * entry, followed by two entries for each parameter, first the type or name + * of the parameter, second a description of the parameter. + */ + +// -=*# Resource for function DCOUNT #*=- +const char* SC_OPCODE_DB_COUNT_ARY[] = +{ + NC_("SC_OPCODE_DB_COUNT", "Counts the cells of a data range whose contents match the search criteria."), + NC_("SC_OPCODE_DB_COUNT", "Database"), + NC_("SC_OPCODE_DB_COUNT", "The range of cells containing data."), + NC_("SC_OPCODE_DB_COUNT", "Database field"), + NC_("SC_OPCODE_DB_COUNT", "Indicates which database field (column) is to be used for the search criteria."), + NC_("SC_OPCODE_DB_COUNT", "Search criteria"), + NC_("SC_OPCODE_DB_COUNT", "Defines the cell range containing the search criteria.") +}; + +// -=*# Resource for function DCOUNTA #*=- +const char* SC_OPCODE_DB_COUNT_2_ARY[] = +{ + NC_("SC_OPCODE_DB_COUNT_2", "Counts all non-blank cells of a data range where the content corresponds to the search criteria."), + NC_("SC_OPCODE_DB_COUNT_2", "Database"), + NC_("SC_OPCODE_DB_COUNT_2", "The range of cells containing data."), + NC_("SC_OPCODE_DB_COUNT_2", "Database field"), + NC_("SC_OPCODE_DB_COUNT_2", "Indicates which database field (column) is to be used for the search criteria."), + NC_("SC_OPCODE_DB_COUNT_2", "Search criteria"), + NC_("SC_OPCODE_DB_COUNT_2", "Defines the cell range containing the search criteria.") +}; + +// -=*# Resource for function DAVERAGE #*=- +const char* SC_OPCODE_DB_AVERAGE_ARY[] = +{ + NC_("SC_OPCODE_DB_AVERAGE", "Returns the average value of all the cells of a data range whose contents match the search criteria."), + NC_("SC_OPCODE_DB_AVERAGE", "Database"), + NC_("SC_OPCODE_DB_AVERAGE", "The range of cells containing data."), + NC_("SC_OPCODE_DB_AVERAGE", "Database field"), + NC_("SC_OPCODE_DB_AVERAGE", "Indicates which database field (column) is to be used for the search criteria."), + NC_("SC_OPCODE_DB_AVERAGE", "Search criteria"), + NC_("SC_OPCODE_DB_AVERAGE", "Defines the cell range containing the search criteria.") +}; + +// -=*# Resource for function DGET #*=- +const char* SC_OPCODE_DB_GET_ARY[] = +{ + NC_("SC_OPCODE_DB_GET", "Defines the contents of the cell of a data range which matches the search criteria."), + NC_("SC_OPCODE_DB_GET", "Database"), + NC_("SC_OPCODE_DB_GET", "The range of cells containing data."), + NC_("SC_OPCODE_DB_GET", "Database field"), + NC_("SC_OPCODE_DB_GET", "Indicates which database field (column) is to be used for the search criteria."), + NC_("SC_OPCODE_DB_GET", "Search criteria"), + NC_("SC_OPCODE_DB_GET", "Defines the cell range containing the search criteria.") +}; + +// -=*# Resource for function DMAX #*=- +const char* SC_OPCODE_DB_MAX_ARY[] = +{ + NC_("SC_OPCODE_DB_MAX", "Returns the maximum value from all of the cells of a data range which correspond to the search criteria."), + NC_("SC_OPCODE_DB_MAX", "Database"), + NC_("SC_OPCODE_DB_MAX", "The range of cells containing data."), + NC_("SC_OPCODE_DB_MAX", "Database field"), + NC_("SC_OPCODE_DB_MAX", "Indicates which database field (column) is to be used for the search criteria."), + NC_("SC_OPCODE_DB_MAX", "Search criteria"), + NC_("SC_OPCODE_DB_MAX", "Defines the cell range containing the search criteria.") +}; + +// -=*# Resource for function DMIN #*=- +const char* SC_OPCODE_DB_MIN_ARY[] = +{ + NC_("SC_OPCODE_DB_MIN", "Returns the minimum of all cells of a data range where the contents correspond to the search criteria."), + NC_("SC_OPCODE_DB_MIN", "Database"), + NC_("SC_OPCODE_DB_MIN", "The range of cells containing data."), + NC_("SC_OPCODE_DB_MIN", "Database field"), + NC_("SC_OPCODE_DB_MIN", "Indicates which database field (column) is to be used for the search criteria."), + NC_("SC_OPCODE_DB_MIN", "Search criteria"), + NC_("SC_OPCODE_DB_MIN", "Defines the cell range containing the search criteria.") +}; + +// -=*# Resource for function DPRODUCT #*=- +const char* SC_OPCODE_DB_PRODUCT_ARY[] = +{ + NC_("SC_OPCODE_DB_PRODUCT", "Multiplies all cells of a data range where the contents match the search criteria."), + NC_("SC_OPCODE_DB_PRODUCT", "Database"), + NC_("SC_OPCODE_DB_PRODUCT", "The range of cells containing data."), + NC_("SC_OPCODE_DB_PRODUCT", "Database field"), + NC_("SC_OPCODE_DB_PRODUCT", "Indicates which database field (column) is to be used for the search criteria."), + NC_("SC_OPCODE_DB_PRODUCT", "Search criteria"), + NC_("SC_OPCODE_DB_PRODUCT", "Defines the cell range containing the search criteria.") +}; + +// -=*# Resource for function DSTDEV #*=- +const char* SC_OPCODE_DB_STD_DEV_ARY[] = +{ + NC_("SC_OPCODE_DB_STD_DEV", "Calculates the standard deviation of all cells in a data range whose contents match the search criteria."), + NC_("SC_OPCODE_DB_STD_DEV", "Database"), + NC_("SC_OPCODE_DB_STD_DEV", "The range of cells containing data."), + NC_("SC_OPCODE_DB_STD_DEV", "Database field"), + NC_("SC_OPCODE_DB_STD_DEV", "Indicates which database field (column) is to be used for the search criteria."), + NC_("SC_OPCODE_DB_STD_DEV", "Search criteria"), + NC_("SC_OPCODE_DB_STD_DEV", "Defines the cell range containing the search criteria.") +}; + +// -=*# Resource for function DSTDEVP #*=- +const char* SC_OPCODE_DB_STD_DEV_P_ARY[] = +{ + NC_("SC_OPCODE_DB_STD_DEV_P", "Returns the standard deviation with regards to the population of all cells of a data range matching the search criteria."), + NC_("SC_OPCODE_DB_STD_DEV_P", "Database"), + NC_("SC_OPCODE_DB_STD_DEV_P", "The range of cells containing data."), + NC_("SC_OPCODE_DB_STD_DEV_P", "Database field"), + NC_("SC_OPCODE_DB_STD_DEV_P", "Indicates which database field (column) is to be used for the search criteria."), + NC_("SC_OPCODE_DB_STD_DEV_P", "Search criteria"), + NC_("SC_OPCODE_DB_STD_DEV_P", "Defines the cell range containing the search criteria.") +}; + +// -=*# Resource for function DSUM #*=- +const char* SC_OPCODE_DB_SUM_ARY[] = +{ + NC_("SC_OPCODE_DB_SUM", "Adds all the cells of a data range where the contents match the search criteria."), + NC_("SC_OPCODE_DB_SUM", "Database"), + NC_("SC_OPCODE_DB_SUM", "The range of cells containing data."), + NC_("SC_OPCODE_DB_SUM", "Database field"), + NC_("SC_OPCODE_DB_SUM", "Indicates which database field (column) is to be used for the search criteria."), + NC_("SC_OPCODE_DB_SUM", "Search criteria"), + NC_("SC_OPCODE_DB_SUM", "Defines the cell range containing the search criteria.") +}; + +// -=*# Resource for function DVAR #*=- +const char* SC_OPCODE_DB_VAR_ARY[] = +{ + NC_("SC_OPCODE_DB_VAR", "Determines the variance of all the cells in a data range where the contents match the search criteria."), + NC_("SC_OPCODE_DB_VAR", "Database"), + NC_("SC_OPCODE_DB_VAR", "The range of cells containing data."), + NC_("SC_OPCODE_DB_VAR", "Database field"), + NC_("SC_OPCODE_DB_VAR", "Indicates which database field (column) is to be used for the search criteria."), + NC_("SC_OPCODE_DB_VAR", "Search criteria"), + NC_("SC_OPCODE_DB_VAR", "Defines the cell range containing the search criteria.") +}; + +// -=*# Resource for function DVARP #*=- +const char* SC_OPCODE_DB_VAR_P_ARY[] = +{ + NC_("SC_OPCODE_DB_VAR_P", "Determines variance of a population based on all cells in a data range where contents match the search criteria."), + NC_("SC_OPCODE_DB_VAR_P", "Database"), + NC_("SC_OPCODE_DB_VAR_P", "The range of cells containing data."), + NC_("SC_OPCODE_DB_VAR_P", "Database field"), + NC_("SC_OPCODE_DB_VAR_P", "Indicates which database field (column) is to be used for the search criteria."), + NC_("SC_OPCODE_DB_VAR_P", "Search criteria"), + NC_("SC_OPCODE_DB_VAR_P", "Defines the cell range containing the search criteria.") +}; + +// -=*# Resource for function DATE #*=- +const char* SC_OPCODE_GET_DATE_ARY[] = +{ + NC_("SC_OPCODE_GET_DATE", "Provides an internal number for the date given."), + NC_("SC_OPCODE_GET_DATE", "year"), + NC_("SC_OPCODE_GET_DATE", "An integer between 1583 and 9956 or 0 and 99 (19xx or 20xx depending on the defined option)."), + NC_("SC_OPCODE_GET_DATE", "month"), + NC_("SC_OPCODE_GET_DATE", "An integer between 1 and 12 representing the month."), + NC_("SC_OPCODE_GET_DATE", "day"), + NC_("SC_OPCODE_GET_DATE", "An integer between 1 and 31 representing the day of the month.") +}; + +// -=*# Resource for function DATE_VALUE #*=- +const char* SC_OPCODE_GET_DATE_VALUE_ARY[] = +{ + NC_("SC_OPCODE_GET_DATE_VALUE", "Returns an internal number for a text having a possible date format."), + NC_("SC_OPCODE_GET_DATE_VALUE", "text"), + NC_("SC_OPCODE_GET_DATE_VALUE", "A text enclosed in quotation marks which returns a date in a %PRODUCTNAME date format.") +}; + +// -=*# Resource for function DAY #*=- +const char* SC_OPCODE_GET_DAY_ARY[] = +{ + NC_("SC_OPCODE_GET_DAY", "Returns the sequential date of the month as an integer (1-31) in relation to the date value."), + NC_("SC_OPCODE_GET_DAY", "Number"), + NC_("SC_OPCODE_GET_DAY", "The internal number for the date.") +}; + +// -=*# Resource for function DAYS360 #*=- +const char* SC_OPCODE_GET_DIFF_DATE_360_ARY[] = +{ + NC_("SC_OPCODE_GET_DIFF_DATE_360", "Calculates the number of days between two dates based on a 360-day year."), + NC_("SC_OPCODE_GET_DIFF_DATE_360", "Date_1"), + NC_("SC_OPCODE_GET_DIFF_DATE_360", "The start date for calculating the difference in days."), + NC_("SC_OPCODE_GET_DIFF_DATE_360", "Date_2"), + NC_("SC_OPCODE_GET_DIFF_DATE_360", "The end date for calculating the difference in days."), + NC_("SC_OPCODE_GET_DIFF_DATE_360", "Type"), + NC_("SC_OPCODE_GET_DIFF_DATE_360", "Method used to form differences: Type = 0 denotes US method (NASD), Type = 1 denotes the European method.") +}; + +// -=*# Resource for function NETWORKDAYS #*=- +const char* SC_OPCODE_NETWORKDAYS_ARY[] = +{ + NC_("SC_OPCODE_NETWORKDAYS", "Returns the number of workdays between two dates using arguments to indicate weekenddays and holidays."), + NC_("SC_OPCODE_NETWORKDAYS", "Start Date"), + NC_("SC_OPCODE_NETWORKDAYS", "Start date for calculation."), + NC_("SC_OPCODE_NETWORKDAYS", "End Date"), + NC_("SC_OPCODE_NETWORKDAYS", "End date for calculation."), + NC_("SC_OPCODE_NETWORKDAYS", "list of dates"), + NC_("SC_OPCODE_NETWORKDAYS", "Optional set of one or more dates to be considered as holiday."), + NC_("SC_OPCODE_NETWORKDAYS", "array"), + NC_("SC_OPCODE_NETWORKDAYS", "Optional list of numbers to indicate working (0) and weekend (non-zero) days. When omitted, weekend is Saturday and Sunday.") +}; + +// -=*# Resource for function NETWORKDAYS.INTL #*=- +const char* SC_OPCODE_NETWORKDAYS_MS_ARY[] = +{ + NC_("SC_OPCODE_NETWORKDAYS_MS", "Returns the number of workdays between two dates using arguments to indicate weekend days and holidays."), + NC_("SC_OPCODE_NETWORKDAYS_MS", "Start Date"), + NC_("SC_OPCODE_NETWORKDAYS_MS", "Start date for calculation."), + NC_("SC_OPCODE_NETWORKDAYS_MS", "End Date"), + NC_("SC_OPCODE_NETWORKDAYS_MS", "End date for calculation."), + NC_("SC_OPCODE_NETWORKDAYS_MS", "number or string"), + NC_("SC_OPCODE_NETWORKDAYS_MS", "Optional number or string to indicate when weekends occur. When omitted, weekend is Saturday and Sunday."), + NC_("SC_OPCODE_NETWORKDAYS_MS", "array"), + NC_("SC_OPCODE_NETWORKDAYS_MS", "Optional set of one or more dates to be considered as holiday.") +}; + +// -=*# Resource for function WORKDAY.INTL #*=- +const char* SC_OPCODE_WORKDAY_MS_ARY[] = +{ + NC_("SC_OPCODE_WORKDAY_MS", "Returns the serial number of the date before or after a number of workdays using arguments to indicate weekend days and holidays."), + NC_("SC_OPCODE_WORKDAY_MS", "Start Date"), + NC_("SC_OPCODE_WORKDAY_MS", "Start date for calculation."), + NC_("SC_OPCODE_WORKDAY_MS", "Days"), + NC_("SC_OPCODE_WORKDAY_MS", "The number of workdays before or after start date."), + NC_("SC_OPCODE_WORKDAY_MS", "number or string"), + NC_("SC_OPCODE_WORKDAY_MS", "Optional number or string to indicate when weekends occur. When omitted, weekend is Saturday and Sunday."), + NC_("SC_OPCODE_WORKDAY_MS", "array"), + NC_("SC_OPCODE_WORKDAY_MS", "Optional set of one or more dates to be considered as holiday.") +}; + +// -=*# Resource for function HOUR #*=- +const char* SC_OPCODE_GET_HOUR_ARY[] = +{ + NC_("SC_OPCODE_GET_HOUR", "Determines the sequential number of the hour of the day (0-23) for the time value."), + NC_("SC_OPCODE_GET_HOUR", "Number"), + NC_("SC_OPCODE_GET_HOUR", "Internal time value") +}; + +// -=*# Resource for function MINUTE #*=- +const char* SC_OPCODE_GET_MIN_ARY[] = +{ + NC_("SC_OPCODE_GET_MIN", "Determines the sequential number for the minute of the hour (0-59) for the time value."), + NC_("SC_OPCODE_GET_MIN", "Number"), + NC_("SC_OPCODE_GET_MIN", "Internal time value.") +}; + +// -=*# Resource for function MONTH #*=- +const char* SC_OPCODE_GET_MONTH_ARY[] = +{ + NC_("SC_OPCODE_GET_MONTH", "Determines the sequential number of a month of the year (1-12) for the date value."), + NC_("SC_OPCODE_GET_MONTH", "Number"), + NC_("SC_OPCODE_GET_MONTH", "The internal number of the date.") +}; + +// -=*# Resource for function NOW #*=- +const char* SC_OPCODE_GET_ACT_TIME_ARY[] = +{ + NC_("SC_OPCODE_GET_ACT_TIME", "Determines the current time of the computer.") +}; + +// -=*# Resource for function SECOND #*=- +const char*SC_OPCODE_GET_SEC_ARY[] = +{ + NC_("SC_OPCODE_GET_SEC", "Determines the sequential number of the second of a minute (0-59) for the time value."), + NC_("SC_OPCODE_GET_SEC", "Number"), + NC_("SC_OPCODE_GET_SEC", "The internal time value.") +}; + +// -=*# Resource for function TIME #*=- +const char* SC_OPCODE_GET_TIME_ARY[] = +{ + NC_("SC_OPCODE_GET_TIME", "Determines a time value from the details for hour, minute and second."), + NC_("SC_OPCODE_GET_TIME", "hour"), + NC_("SC_OPCODE_GET_TIME", "The integer for the hour."), + NC_("SC_OPCODE_GET_TIME", "minute"), + NC_("SC_OPCODE_GET_TIME", "The integer for the minute."), + NC_("SC_OPCODE_GET_TIME", "second"), + NC_("SC_OPCODE_GET_TIME", "The integer for the second.") +}; + +// -=*# Resource for function TIMEVALUE #*=- +const char* SC_OPCODE_GET_TIME_VALUE_ARY[] = +{ + NC_("SC_OPCODE_GET_TIME_VALUE", "Returns a sequential number for a text shown in a possible time entry format."), + NC_("SC_OPCODE_GET_TIME_VALUE", "text"), + NC_("SC_OPCODE_GET_TIME_VALUE", "A text enclosed in quotation marks which returns a time in a %PRODUCTNAME time format.") +}; + +// -=*# Resource for function TODAY #*=- +const char* SC_OPCODE_GET_ACT_DATE_ARY[] = +{ + NC_("SC_OPCODE_GET_ACT_DATE", "Determines the current date of the computer.") +}; + +// -=*# Resource for function WEEKDAY #*=- +const char* SC_OPCODE_GET_DAY_OF_WEEK_ARY[] = +{ + NC_("SC_OPCODE_GET_DAY_OF_WEEK", "Returns the day of the week for the date value as an integer."), + NC_("SC_OPCODE_GET_DAY_OF_WEEK", "Number"), + NC_("SC_OPCODE_GET_DAY_OF_WEEK", "The internal number for the date."), + NC_("SC_OPCODE_GET_DAY_OF_WEEK", "Type"), + NC_("SC_OPCODE_GET_DAY_OF_WEEK", "Fixes the beginning of the week and the type of calculation to be used.") +}; + +// -=*# Resource for function YEAR #*=- +const char* SC_OPCODE_GET_YEAR_ARY[] = +{ + NC_("SC_OPCODE_GET_YEAR", "Returns the year of a date value as an integer."), + NC_("SC_OPCODE_GET_YEAR", "Number"), + NC_("SC_OPCODE_GET_YEAR", "Internal number of the date.") +}; + +// -=*# Resource for function DAYS #*=- +const char* SC_OPCODE_GET_DIFF_DATE_ARY[] = +{ + NC_("SC_OPCODE_GET_DIFF_DATE", "Calculates the number of days between two dates."), + NC_("SC_OPCODE_GET_DIFF_DATE", "Date_2"), + NC_("SC_OPCODE_GET_DIFF_DATE", "The end date for calculating the difference in days."), + NC_("SC_OPCODE_GET_DIFF_DATE", "Date_1"), + NC_("SC_OPCODE_GET_DIFF_DATE", "The start date for calculating the difference in days.") +}; + +// -=*# Resource for function DATEDIF #*=- +const char* SC_OPCODE_GET_DATEDIF_ARY[] = +{ + NC_("SC_OPCODE_GET_DATEDIF", "Returns the number of whole days, months or years between 'start date' and 'end date'."), + NC_("SC_OPCODE_GET_DATEDIF", "Start date"), + NC_("SC_OPCODE_GET_DATEDIF", "The start date."), + NC_("SC_OPCODE_GET_DATEDIF", "End date"), + NC_("SC_OPCODE_GET_DATEDIF", "The end date."), + NC_("SC_OPCODE_GET_DATEDIF", "Interval"), + NC_("SC_OPCODE_GET_DATEDIF", "Interval to be calculated. Can be \"d\", \"m\", \"y\", \"ym\", \"md\" or \"yd\".") +}; + +// -=*# Resource for function WEEKNUM #*=- +const char* SC_OPCODE_WEEK_ARY[] = +{ + NC_("SC_OPCODE_WEEK", "Calculates the calendar week corresponding to the given date."), + NC_("SC_OPCODE_WEEK", "Number"), + NC_("SC_OPCODE_WEEK", "The internal number of the date."), + NC_("SC_OPCODE_WEEK", "mode"), + NC_("SC_OPCODE_WEEK", "Indicates the first day of the week and when week 1 starts.") +}; + +// -=*# Resource for function ISOWEEKNUM #*=- +const char* SC_OPCODE_ISOWEEKNUM_ARY[] = +{ + NC_("SC_OPCODE_ISOWEEKNUM", "Calculates the ISO 8601 calendar week for the given date."), + NC_("SC_OPCODE_ISOWEEKNUM", "Number"), + NC_("SC_OPCODE_ISOWEEKNUM", "The internal number of the date.") +}; + +const char* SC_OPCODE_WEEKNUM_OOO_ARY[] = +{ + NC_("SC_OPCODE_WEEKNUM_OOO", "Calculates the calendar week corresponding to the given date.\nThis function only provides interoperability with %PRODUCTNAME 5.0 and earlier and OpenOffice.org."), + NC_("SC_OPCODE_WEEKNUM_OOO", "Number"), + NC_("SC_OPCODE_WEEKNUM_OOO", "The internal number of the date."), + NC_("SC_OPCODE_WEEKNUM_OOO", "mode"), + NC_("SC_OPCODE_WEEKNUM_OOO", "Indicates the first day of the week (1 = Sunday, other values = Monday).") +}; + +// -=*# Resource for function EASTERSUNDAY #*=- +const char* SC_OPCODE_EASTERSUNDAY_ARY[] = +{ + NC_("SC_OPCODE_EASTERSUNDAY", "Calculates the date of Easter Sunday in a given year."), + NC_("SC_OPCODE_EASTERSUNDAY", "year"), + NC_("SC_OPCODE_EASTERSUNDAY", "An integer between 1583 and 9956, or 0 and 99 (19xx or 20xx depending on the option set).") +}; + +// -=*# Resource for function PV #*=- +const char* SC_OPCODE_PV_ARY[] = +{ + NC_("SC_OPCODE_PV", "Present value. Calculates the present value of an investment."), + NC_("SC_OPCODE_PV", "Rate"), + NC_("SC_OPCODE_PV", "The rate of interest for the period given."), + NC_("SC_OPCODE_PV", "NPER"), + NC_("SC_OPCODE_PV", "The payment period. The total number of periods in which the annuity is paid."), + NC_("SC_OPCODE_PV", "PMT"), + NC_("SC_OPCODE_PV", "Regular payments. The constant amount of annuity that is paid in each period."), + NC_("SC_OPCODE_PV", "FV"), + NC_("SC_OPCODE_PV", "Future value. The value (final value) to be attained after the last payment."), + NC_("SC_OPCODE_PV", "Type"), + NC_("SC_OPCODE_PV", "Type = 1 denotes due at the beginning of the period, = 0 at the end.") +}; + +// -=*# Resource for function FV #*=- +const char* SC_OPCODE_FV_ARY[] = +{ + NC_("SC_OPCODE_FV", "Future value. Returns the future value of an investment based on regular payments and a constant interest rate."), + NC_("SC_OPCODE_FV", "Rate"), + NC_("SC_OPCODE_FV", "The rate of interest per period."), + NC_("SC_OPCODE_FV", "NPER"), + NC_("SC_OPCODE_FV", "Payment period. The total number of periods in which the annuity (pension) is paid."), + NC_("SC_OPCODE_FV", "PMT"), + NC_("SC_OPCODE_FV", "Regular payments. The constant annuity to be paid in each period."), + NC_("SC_OPCODE_FV", "PV"), + NC_("SC_OPCODE_FV", "Present value. The current value of a series of payments"), + NC_("SC_OPCODE_FV", "Type"), + NC_("SC_OPCODE_FV", "Type = 1 denotes due at the beginning of the period, = 0 at the end.") +}; + +// -=*# Resource for function NPER #*=- +const char* SC_OPCODE_NPER_ARY[] = +{ + NC_("SC_OPCODE_NPER", "Payment period. Calculates the number of payment periods for an investment based on regular payments and a constant interest rate."), + NC_("SC_OPCODE_NPER", "Rate"), + NC_("SC_OPCODE_NPER", "The rate of interest per period."), + NC_("SC_OPCODE_NPER", "PMT"), + NC_("SC_OPCODE_NPER", "Regular payments. The constant annuity to be paid in each period."), + NC_("SC_OPCODE_NPER", "PV"), + NC_("SC_OPCODE_NPER", "Present value. The current value of a series of payments"), + NC_("SC_OPCODE_NPER", "FV"), + NC_("SC_OPCODE_NPER", "Future value. The value (end value) to be attained after the final payment."), + NC_("SC_OPCODE_NPER", "Type"), + NC_("SC_OPCODE_NPER", "Type = 1 denotes due at the beginning of the period, = 0 at the end.") +}; + +// -=*# Resource for function PMT #*=- +const char* SC_OPCODE_PMT_ARY[] = +{ + NC_("SC_OPCODE_PMT", "Regular payments. Returns the periodic payment of an annuity, based on regular payments and a fixed periodic interest rate."), + NC_("SC_OPCODE_PMT", "Rate"), + NC_("SC_OPCODE_PMT", "The rate of interest per period."), + NC_("SC_OPCODE_PMT", "NPER"), + NC_("SC_OPCODE_PMT", "Payment period. The total number of periods in which the annuity (pension) is paid."), + NC_("SC_OPCODE_PMT", "PV"), + NC_("SC_OPCODE_PMT", "Present value. The current value of a series of payments"), + NC_("SC_OPCODE_PMT", "FV"), + NC_("SC_OPCODE_PMT", "Future value. The value (end value) to be attained after the final payment."), + NC_("SC_OPCODE_PMT", "Type"), + NC_("SC_OPCODE_PMT", "Type = 1 denotes due at the beginning of the period, = 0 at the end.") +}; + +// -=*# Resource for function RATE #*=- +const char* SC_OPCODE_RATE_ARY[] = +{ + NC_("SC_OPCODE_RATE", "Calculates the constant interest rate of an investment with regular payments."), + NC_("SC_OPCODE_RATE", "NPER"), + NC_("SC_OPCODE_RATE", "Payment period. The total number of periods in which the annuity (pension) is paid."), + NC_("SC_OPCODE_RATE", "PMT"), + NC_("SC_OPCODE_RATE", "Regular payments. The constant annuity to be paid in each period."), + NC_("SC_OPCODE_RATE", "PV"), + NC_("SC_OPCODE_RATE", "Present value. The current value of a series of payments"), + NC_("SC_OPCODE_RATE", "FV"), + NC_("SC_OPCODE_RATE", "Future value. The value (end value) to be attained after the final payment."), + NC_("SC_OPCODE_RATE", "Type"), + NC_("SC_OPCODE_RATE", "Type = 1 denotes due at the beginning of the period, = 0 at the end."), + NC_("SC_OPCODE_RATE", "Guess"), + NC_("SC_OPCODE_RATE", "Guess. The estimate of the interest rate for the iterative calculating method.") +}; + +// -=*# Resource for function IPMT #*=- +const char* SC_OPCODE_IPMT_ARY[] = +{ + NC_("SC_OPCODE_IPMT", "Compounded interest. Calculates the interest payment on the principal for an investment with regular payments and a constant interest rate for a given period."), + NC_("SC_OPCODE_IPMT", "Rate"), + NC_("SC_OPCODE_IPMT", "The rate of interest per period."), + NC_("SC_OPCODE_IPMT", "Period"), + NC_("SC_OPCODE_IPMT", "Periods. The periods for which the compounded interest is to be calculated. P = 1 denotes for the first period, P = NPER for the last one."), + NC_("SC_OPCODE_IPMT", "NPER"), + NC_("SC_OPCODE_IPMT", "Payment period. The total number of periods in which the annuity (pension) is paid."), + NC_("SC_OPCODE_IPMT", "pv"), + NC_("SC_OPCODE_IPMT", "Present value. The current value of a series of payments"), + NC_("SC_OPCODE_IPMT", "FV"), + NC_("SC_OPCODE_IPMT", "Future value. The value (end value) to be attained after the final payment."), + NC_("SC_OPCODE_IPMT", "Type"), + NC_("SC_OPCODE_IPMT", "Type = 1 denotes due at the beginning of the period, = 0 at the end.") +}; + +// -=*# Resource for function PPMT #*=- +const char* SC_OPCODE_PPMT_ARY[] = +{ + NC_("SC_OPCODE_PPMT", "Repayment. Calculates the repayment amount for a period for an investment whereby the payments are at regular intervals and the interest rate constant."), + NC_("SC_OPCODE_PPMT", "Rate"), + NC_("SC_OPCODE_PPMT", "The interest rate per period."), + NC_("SC_OPCODE_PPMT", "Period"), + NC_("SC_OPCODE_PPMT", "Period. The period for which the repayments are to be calculated. Per = 1 denotes for the first period, P = NPER for the last"), + NC_("SC_OPCODE_PPMT", "NPER"), + NC_("SC_OPCODE_PPMT", "The payment period. The total number of periods in which the annuity (pension) is paid."), + NC_("SC_OPCODE_PPMT", "PV"), + NC_("SC_OPCODE_PPMT", "The present value. The present value or the amount the annuity is currently worth."), + NC_("SC_OPCODE_PPMT", "FV"), + NC_("SC_OPCODE_PPMT", "Future value. The value (end value) attained after the last payment has been made."), + NC_("SC_OPCODE_PPMT", "Type"), + NC_("SC_OPCODE_PPMT", "Type = 1 denotes due at the beginning of the period, = 0 at the end.") +}; + +// -=*# Resource for function CUMPRINC #*=- +const char* SC_OPCODE_CUM_PRINC_ARY[] = +{ + NC_("SC_OPCODE_CUM_PRINC", "Cumulative Capital. Calculates the total amount of the repayment share in a period for an investment with constant interest rate."), + NC_("SC_OPCODE_CUM_PRINC", "Rate"), + NC_("SC_OPCODE_CUM_PRINC", "The rate of interest per period."), + NC_("SC_OPCODE_CUM_PRINC", "NPER"), + NC_("SC_OPCODE_CUM_PRINC", "Payment period. The total number of periods in which the annuity (pension) is paid."), + NC_("SC_OPCODE_CUM_PRINC", "PV"), + NC_("SC_OPCODE_CUM_PRINC", "The present value. The present value or the amount the annuity is currently worth."), + NC_("SC_OPCODE_CUM_PRINC", "S"), + NC_("SC_OPCODE_CUM_PRINC", "The start period. The first period to be taken into account. S = 1 denotes the very first period."), + NC_("SC_OPCODE_CUM_PRINC", "E"), + NC_("SC_OPCODE_CUM_PRINC", "End period. The last period to be taken into account."), + NC_("SC_OPCODE_CUM_PRINC", "Type"), + NC_("SC_OPCODE_CUM_PRINC", "Type = 1 denotes due at the beginning of the period, = 0 at the end.") +}; + +// -=*# Resource for function CUMIPMT #*=- +const char* SC_OPCODE_CUM_IPMT_ARY[] = +{ + NC_("SC_OPCODE_CUM_IPMT", "Cumulative compounded interest. Calculates the total amount of the interest share in a period for an investment with a constant interest rate."), + NC_("SC_OPCODE_CUM_IPMT", "Rate"), + NC_("SC_OPCODE_CUM_IPMT", "The rate of interest per period."), + NC_("SC_OPCODE_CUM_IPMT", "NPER"), + NC_("SC_OPCODE_CUM_IPMT", "Payment period. The total number of periods in which the annuity (pension) is paid."), + NC_("SC_OPCODE_CUM_IPMT", "pv"), + NC_("SC_OPCODE_CUM_IPMT", "The present value. The present value or the amount the annuity is currently worth."), + NC_("SC_OPCODE_CUM_IPMT", "S"), + NC_("SC_OPCODE_CUM_IPMT", "The start period. The first period to be taken into account. S = 1 denotes the very first period."), + NC_("SC_OPCODE_CUM_IPMT", "E"), + NC_("SC_OPCODE_CUM_IPMT", "The end period. The last period to be taken into account."), + NC_("SC_OPCODE_CUM_IPMT", "Type"), + NC_("SC_OPCODE_CUM_IPMT", "Type = 1 denotes due at the beginning of the period, = 0 at the end.") +}; + +// -=*# Resource for function SYD #*=- +const char* SC_OPCODE_SYD_ARY[] = +{ + NC_("SC_OPCODE_SYD", "Calculates the arithmetically declining value of an asset (depreciation) for a specified period."), + NC_("SC_OPCODE_SYD", "Cost"), + NC_("SC_OPCODE_SYD", "Acquisition costs. The initial cost of the asset."), + NC_("SC_OPCODE_SYD", "Salvage"), + NC_("SC_OPCODE_SYD", "Salvage: The remaining value of the asset at the end of its life."), + NC_("SC_OPCODE_SYD", "Life"), + NC_("SC_OPCODE_SYD", "Useful life. The number of periods in the useful life of the asset."), + NC_("SC_OPCODE_SYD", "Period"), + NC_("SC_OPCODE_SYD", "Period. The depreciation period which must have the same time unit as average useful life.") +}; + +// -=*# Resource for function SLN #*=- +const char* SC_OPCODE_SLN_ARY[] = +{ + NC_("SC_OPCODE_SLN", "Calculates the linear depreciation per period."), + NC_("SC_OPCODE_SLN", "Cost"), + NC_("SC_OPCODE_SLN", "Acquisition cost. The initial cost of an asset."), + NC_("SC_OPCODE_SLN", "Salvage"), + NC_("SC_OPCODE_SLN", "Salvage: The remaining value of the asset at the end of its life."), + NC_("SC_OPCODE_SLN", "Life"), + NC_("SC_OPCODE_SLN", "Useful life. The number of periods in the useful life of the asset.") +}; + +// -=*# Resource for function DDB #*=- +const char* SC_OPCODE_DDB_ARY[] = +{ + NC_("SC_OPCODE_DDB", "Calculates the depreciation of an asset for a specific period using the double-declining balance method or declining balance factor."), + NC_("SC_OPCODE_DDB", "Cost"), + NC_("SC_OPCODE_DDB", "Acquisition costs. The initial cost of the asset."), + NC_("SC_OPCODE_DDB", "Salvage"), + NC_("SC_OPCODE_DDB", "Salvage: The remaining value of the asset at the end of its life."), + NC_("SC_OPCODE_DDB", "Life"), + NC_("SC_OPCODE_DDB", "Useful life. The number of periods in the useful life of the asset."), + NC_("SC_OPCODE_DDB", "Period"), + NC_("SC_OPCODE_DDB", "Period. The depreciation period in the same time unit as the average useful life entry."), + NC_("SC_OPCODE_DDB", "Factor"), + NC_("SC_OPCODE_DDB", "Factor. The factor for balance decline. F = 2 means a double declining balance factor") +}; + +// -=*# Resource for function DB #*=- +const char* SC_OPCODE_DB_ARY[] = +{ + NC_("SC_OPCODE_DB", "Returns the real depreciation of an asset for a specified period using the fixed-declining balance method."), + NC_("SC_OPCODE_DB", "Cost"), + NC_("SC_OPCODE_DB", "Acquisition costs: The initial cost of the asset."), + NC_("SC_OPCODE_DB", "Salvage"), + NC_("SC_OPCODE_DB", "Salvage: The remaining value of the asset at the end of its life."), + NC_("SC_OPCODE_DB", "Life"), + NC_("SC_OPCODE_DB", "Useful life. The number of periods in the useful life of the asset."), + NC_("SC_OPCODE_DB", "Period"), + NC_("SC_OPCODE_DB", "Periods: The period for which the depreciation is calculated. The time unit used for period must be the same as that for the useful life."), + NC_("SC_OPCODE_DB", "month"), + NC_("SC_OPCODE_DB", "Months: The number of months in the first year of depreciation.") +}; + +// -=*# Resource for function VDB #*=- +const char* SC_OPCODE_VBD_ARY[] = +{ + NC_("SC_OPCODE_VBD", "Variable declining balance. Returns the declining balance depreciation for a particular period."), + NC_("SC_OPCODE_VBD", "Cost"), + NC_("SC_OPCODE_VBD", "Cost. The initial cost of the asset."), + NC_("SC_OPCODE_VBD", "Salvage"), + NC_("SC_OPCODE_VBD", "Salvage. The salvage value of an asset at the end of its useful life."), + NC_("SC_OPCODE_VBD", "Life"), + NC_("SC_OPCODE_VBD", "Useful life. The number of periods in the useful life of the asset."), + NC_("SC_OPCODE_VBD", "S"), + NC_("SC_OPCODE_VBD", "Start. The first period for depreciation in the same time unit as the useful life."), + NC_("SC_OPCODE_VBD", "end"), + NC_("SC_OPCODE_VBD", "End. The last period of the depreciation using the same time unit as for the useful life."), + NC_("SC_OPCODE_VBD", "Factor"), + NC_("SC_OPCODE_VBD", "Factor. The factor for the reduction of the depreciation. F = 2 denotes double rate depreciation."), + NC_("SC_OPCODE_VBD", "Type"), + NC_("SC_OPCODE_VBD", "Do not alter. Type = 1 denotes switch to linear depreciation, type = 0 do not switch.") +}; + +// -=*# Resource for function EFFECT #*=- +const char* SC_OPCODE_EFFECT_ARY[] = +{ + NC_("SC_OPCODE_EFFECT", "Calculates the annual net interest rate for a nominal interest rate."), + NC_("SC_OPCODE_EFFECT", "NOM"), + NC_("SC_OPCODE_EFFECT", "Nominal Interest"), + NC_("SC_OPCODE_EFFECT", "P"), + NC_("SC_OPCODE_EFFECT", "Periods. The number of interest payments per year.") +}; + +// -=*# Resource for function NOMINAL #*=- +const char* SC_OPCODE_NOMINAL_ARY[] = +{ + NC_("SC_OPCODE_NOMINAL", "Calculates the yearly nominal interest rate as an effective interest rate."), + NC_("SC_OPCODE_NOMINAL", "effect_rate"), + NC_("SC_OPCODE_NOMINAL", "The effective interest rate"), + NC_("SC_OPCODE_NOMINAL", "npery"), + NC_("SC_OPCODE_NOMINAL", "Periods. The number of interest payment per year.") +}; + +// -=*# Resource for function NPV #*=- +const char* SC_OPCODE_NPV_ARY[] = +{ + NC_("SC_OPCODE_NPV", "Net present value. Calculates the net present value of an investment based on a series of periodic payments and a discount rate."), + NC_("SC_OPCODE_NPV", "RATE"), + NC_("SC_OPCODE_NPV", "The rate of discount for one period."), + NC_("SC_OPCODE_NPV", "value "), + NC_("SC_OPCODE_NPV", "Value 1, value 2,... are arguments representing payments and income.") +}; + +// -=*# Resource for function IRR #*=- +const char* SC_OPCODE_IRR_ARY[] = +{ + NC_("SC_OPCODE_IRR", "Returns the actuarial rate of interest of an investment excluding costs or profits."), + NC_("SC_OPCODE_IRR", "Values"), + NC_("SC_OPCODE_IRR", "An array or reference to cells whose contents correspond to the payments."), + NC_("SC_OPCODE_IRR", "Guess"), + NC_("SC_OPCODE_IRR", "Guess. An estimated value of the rate of return to be used for the iteration calculation.") +}; + +// -=*# Resource for function MIRR #*=- +const char* SC_OPCODE_MIRR_ARY[] = +{ + NC_("SC_OPCODE_MIRR", "Returns the modified internal rate of return for a series of investments."), + NC_("SC_OPCODE_MIRR", "Values"), + NC_("SC_OPCODE_MIRR", "An array or reference to cells whose contents correspond to the payments."), + NC_("SC_OPCODE_MIRR", "investment"), + NC_("SC_OPCODE_MIRR", "Interest rate for investments (the negative values in the array)."), + NC_("SC_OPCODE_MIRR", "reinvest_rate"), + NC_("SC_OPCODE_MIRR", "interest rate for reinvestments (the positive values in the array).") +}; + +// -=*# Resource for function ISPMT #*=- +const char* SC_OPCODE_ISPMT_ARY[] = +{ + NC_("SC_OPCODE_ISPMT", "Returns the amount of interest for constant amortization rates."), + NC_("SC_OPCODE_ISPMT", "rate"), + NC_("SC_OPCODE_ISPMT", "Interest rate for a single amortization rate."), + NC_("SC_OPCODE_ISPMT", "Period"), + NC_("SC_OPCODE_ISPMT", "Number of amortization periods for the calculation of the interest."), + NC_("SC_OPCODE_ISPMT", "total_periods"), + NC_("SC_OPCODE_ISPMT", "Sum total of amortization periods."), + NC_("SC_OPCODE_ISPMT", "invest"), + NC_("SC_OPCODE_ISPMT", "Amount of the investment.") +}; + +// -=*# Resource for function PDURATION #*=- +const char* SC_OPCODE_PDURATION_ARY[] = +{ + NC_("SC_OPCODE_PDURATION", "Duration. Calculates the number of periods required by an investment to attain the desired value."), + NC_("SC_OPCODE_PDURATION", "RATE"), + NC_("SC_OPCODE_PDURATION", "The constant rate of interest."), + NC_("SC_OPCODE_PDURATION", "pv"), + NC_("SC_OPCODE_PDURATION", "The present value. The current value of the investment."), + NC_("SC_OPCODE_PDURATION", "FV"), + NC_("SC_OPCODE_PDURATION", "The future value of the investment.") +}; + +// -=*# Resource for function RRI #*=- +const char* SC_OPCODE_RRI_ARY[] = +{ + NC_("SC_OPCODE_RRI", "Interest. Calculates the interest rate which represents the rate of return from an investment."), + NC_("SC_OPCODE_RRI", "P"), + NC_("SC_OPCODE_RRI", "The number of periods used in the calculation."), + NC_("SC_OPCODE_RRI", "pv"), + NC_("SC_OPCODE_RRI", "Present value. The current value of the investment."), + NC_("SC_OPCODE_RRI", "FV"), + NC_("SC_OPCODE_RRI", "The future value of the investment.") +}; + +// -=*# Resource for function ISREF #*=- +const char* SC_OPCODE_IS_REF_ARY[] = +{ + NC_("SC_OPCODE_IS_REF", "Returns TRUE if value is a reference."), + NC_("SC_OPCODE_IS_REF", "value"), + NC_("SC_OPCODE_IS_REF", "The value to be tested.") +}; + +// -=*# Resource for function ISERR #*=- +const char* SC_OPCODE_IS_ERR_ARY[] = +{ + NC_("SC_OPCODE_IS_ERR", "Returns TRUE if the value is an error value not equal to #N/A."), + NC_("SC_OPCODE_IS_ERR", "value"), + NC_("SC_OPCODE_IS_ERR", "The value to be tested.") +}; + +// -=*# Resource for function ISERROR #*=- +const char* SC_OPCODE_IS_ERROR_ARY[] = +{ + NC_("SC_OPCODE_IS_ERROR", "Returns TRUE if the value is an error value."), + NC_("SC_OPCODE_IS_ERROR", "value"), + NC_("SC_OPCODE_IS_ERROR", "The value to be tested.") +}; + +// -=*# Resource for function ISBLANK #*=- +const char* SC_OPCODE_IS_EMPTY_ARY[] = +{ + NC_("SC_OPCODE_IS_EMPTY", "Returns TRUE if value refers to an empty cell."), + NC_("SC_OPCODE_IS_EMPTY", "value"), + NC_("SC_OPCODE_IS_EMPTY", "The value to be tested.") +}; + +// -=*# Resource for function ISLOGICAL #*=- +const char* SC_OPCODE_IS_LOGICAL_ARY[] = +{ + NC_("SC_OPCODE_IS_LOGICAL", "Returns TRUE if the value carries a logical number format."), + NC_("SC_OPCODE_IS_LOGICAL", "value"), + NC_("SC_OPCODE_IS_LOGICAL", "The value to be tested.") +}; + +// -=*# Resource for function ISNA #*=- +const char* SC_OPCODE_IS_NV_ARY[] = +{ + NC_("SC_OPCODE_IS_NV", "Returns TRUE if value equals #N/A."), + NC_("SC_OPCODE_IS_NV", "value"), + NC_("SC_OPCODE_IS_NV", "The value to be tested.") +}; + +// -=*# Resource for function ISNONTEXT #*=- +const char* SC_OPCODE_IS_NON_STRING_ARY[] = +{ + NC_("SC_OPCODE_IS_NON_STRING", "Returns TRUE if the value is not text."), + NC_("SC_OPCODE_IS_NON_STRING", "value"), + NC_("SC_OPCODE_IS_NON_STRING", "The value to be tested.") +}; + +// -=*# Resource for function ISTEXT #*=- +const char* SC_OPCODE_IS_STRING_ARY[] = +{ + NC_("SC_OPCODE_IS_STRING", "Returns TRUE if value is text."), + NC_("SC_OPCODE_IS_STRING", "value"), + NC_("SC_OPCODE_IS_STRING", "The value to be tested.") +}; + +// -=*# Resource for function ISNUMBER #*=- +const char* SC_OPCODE_IS_VALUE_ARY[] = +{ + NC_("SC_OPCODE_IS_VALUE", "Returns TRUE if value is a number."), + NC_("SC_OPCODE_IS_VALUE", "value"), + NC_("SC_OPCODE_IS_VALUE", "The value to be tested.") +}; + +// -=*# Resource for function ISFORMULA #*=- +const char* SC_OPCODE_IS_FORMULA_ARY[] = +{ + NC_("SC_OPCODE_IS_FORMULA", "Returns TRUE if the cell is a formula cell."), + NC_("SC_OPCODE_IS_FORMULA", "reference"), + NC_("SC_OPCODE_IS_FORMULA", "The cell to be checked.") +}; + +// -=*# Resource for function FORMULA #*=- +const char* SC_OPCODE_FORMULA_ARY[] = +{ + NC_("SC_OPCODE_FORMULA", "Returns the formula of a formula cell."), + NC_("SC_OPCODE_FORMULA", "Reference"), + NC_("SC_OPCODE_FORMULA", "The formula cell.") +}; + +// -=*# Resource for function N #*=- +const char* SC_OPCODE_N_ARY[] = +{ + NC_("SC_OPCODE_N", "Converts a value to a number."), + NC_("SC_OPCODE_N", "value"), + NC_("SC_OPCODE_N", "The value to be interpreted as a number.") +}; + +// -=*# Resource for function NA #*=- +const char* SC_OPCODE_NO_VALUE_ARY[] = +{ + NC_("SC_OPCODE_NO_VALUE", "Not available. Returns the error value #N/A.") +}; + +// -=*# Resource for function TYPE #*=- +const char* SC_OPCODE_TYPE_ARY[] = +{ + NC_("SC_OPCODE_TYPE", "Returns the data type of a value (1 = number, 2 = text, 4 = Boolean value, 8 = formula, 16 = error value, 64 = array)."), + NC_("SC_OPCODE_TYPE", "value"), + NC_("SC_OPCODE_TYPE", "The value for which the data type is to be determined.") +}; + +// -=*# Resource for function CELL #*=- +const char* SC_OPCODE_CELL_ARY[] = +{ + NC_("SC_OPCODE_CELL", "Determines information about address, formatting or contents of a cell."), + NC_("SC_OPCODE_CELL", "info_type"), + NC_("SC_OPCODE_CELL", "String that specifies the type of information."), + NC_("SC_OPCODE_CELL", "Reference"), + NC_("SC_OPCODE_CELL", "The position of the cell you want to examine.") +}; + +// -=*# Resource for function CURRENT #*=- +const char* SC_OPCODE_CURRENT_ARY[] = +{ + NC_("SC_OPCODE_CURRENT", "Calculates the current value of the formula at the present location.") +}; + +// -=*# Resource for function FALSE #*=- +const char* SC_OPCODE_FALSE_ARY[] = +{ + NC_("SC_OPCODE_FALSE", "Defines the logical value as FALSE.") +}; + +// -=*# Resource for function NOT #*=- +const char* SC_OPCODE_NOT_ARY[] = +{ + NC_("SC_OPCODE_NOT", "Reverses the value of the argument."), + NC_("SC_OPCODE_NOT", "Logical value"), + NC_("SC_OPCODE_NOT", "An expression that can be either TRUE or FALSE.") +}; + +// -=*# Resource for function TRUE #*=- +const char* SC_OPCODE_TRUE_ARY[] = +{ + NC_("SC_OPCODE_TRUE", "Returns the logical value TRUE.") +}; + +// -=*# Resource for function IF #*=- +const char* SC_OPCODE_IF_ARY[] = +{ + NC_("SC_OPCODE_IF", "Specifies a logical test to be performed."), + NC_("SC_OPCODE_IF", "Test"), + NC_("SC_OPCODE_IF", "Any value or expression which can be either TRUE or FALSE."), + NC_("SC_OPCODE_IF", "Then_value"), + NC_("SC_OPCODE_IF", "The result of the function if the logical test returns a TRUE."), + NC_("SC_OPCODE_IF", "Otherwise_value"), + NC_("SC_OPCODE_IF", "The result of the function if the logical test returns FALSE.") +}; + +// -=*# Resource for function IFERROR #*=- +const char* SC_OPCODE_IF_ERROR_ARY[] = +{ + NC_("SC_OPCODE_IF_ERROR", "Returns value if not an error value, else alternative."), + NC_("SC_OPCODE_IF_ERROR", "value"), + NC_("SC_OPCODE_IF_ERROR", "The value to be calculated."), + NC_("SC_OPCODE_IF_ERROR", "alternative value"), + NC_("SC_OPCODE_IF_ERROR", "The alternative to be returned, should value be an error value.") +}; + +// -=*# Resource for function IFNA #*=- +const char* SC_OPCODE_IF_NA_ARY[] = +{ + NC_("SC_OPCODE_IF_NA", "Returns value if not a #N/A error, else alternative."), + NC_("SC_OPCODE_IF_NA", "value"), + NC_("SC_OPCODE_IF_NA", "The value to be calculated."), + NC_("SC_OPCODE_IF_NA", "alternative value"), + NC_("SC_OPCODE_IF_NA", "The alternative to be returned, should value be a #N/A error.") +}; + +// -=*# Resource for function OR #*=- +const char* SC_OPCODE_OR_ARY[] = +{ + NC_("SC_OPCODE_OR", "Returns TRUE if an argument is TRUE."), + NC_("SC_OPCODE_OR", "Logical value "), + NC_("SC_OPCODE_OR", "Logical value 1, logical value 2,... are conditions to be tested and which return either TRUE or FALSE.") +}; + +// -=*# Resource for function XOR #*=- +const char* SC_OPCODE_XOR_ARY[] = +{ + NC_("SC_OPCODE_XOR", "Returns TRUE if an odd number of arguments evaluates to TRUE."), + NC_("SC_OPCODE_XOR", "Logical value "), + NC_("SC_OPCODE_XOR", "Logical value 1, logical value 2, ... are conditions to be tested and which return either TRUE or FALSE.") +}; + +// -=*# Resource for function AND #*=- +const char* SC_OPCODE_AND_ARY[] = +{ + NC_("SC_OPCODE_AND", "Returns TRUE if all arguments are TRUE."), + NC_("SC_OPCODE_AND", "Logical value "), + NC_("SC_OPCODE_AND", "Logical value 1, logical value 2;...are conditions to be tested and each returns either TRUE or FALSE.") +}; + +// -=*# Resource for function ABS #*=- +const char* SC_OPCODE_ABS_ARY[] = +{ + NC_("SC_OPCODE_ABS", "Absolute value of a number."), + NC_("SC_OPCODE_ABS", "Number"), + NC_("SC_OPCODE_ABS", "The number whose absolute value is to be returned.") +}; + +// -=*# Resource for function POWER #*=- +const char* SC_OPCODE_POWER_ARY[] = +{ + NC_("SC_OPCODE_POWER", "Returns a^b, base a raised to the power of exponent b."), + NC_("SC_OPCODE_POWER", "Base"), + NC_("SC_OPCODE_POWER", "The base a of the power a^b."), + NC_("SC_OPCODE_POWER", "Exponent"), + NC_("SC_OPCODE_POWER", "The exponent b of the power a^b.") +}; + +// -=*# Resource for function COUNTBLANK #*=- +const char* SC_OPCODE_COUNT_EMPTY_CELLS_ARY[] = +{ + NC_("SC_OPCODE_COUNT_EMPTY_CELLS", "Counts the blank cells in a specified range."), + NC_("SC_OPCODE_COUNT_EMPTY_CELLS", "range"), + NC_("SC_OPCODE_COUNT_EMPTY_CELLS", "The range in which empty cells are to be counted.") +}; + +// -=*# Resource for function PI #*=- +const char* SC_OPCODE_PI_ARY[] = +{ + NC_("SC_OPCODE_PI", "Returns the value of the number Pi.") +}; + +// -=*# Resource for function SUM #*=- +const char* SC_OPCODE_SUM_ARY[] = +{ + NC_("SC_OPCODE_SUM", "Returns the sum of all arguments."), + NC_("SC_OPCODE_SUM", "number "), + NC_("SC_OPCODE_SUM", "Number 1, number 2, ... are arguments whose total is to be calculated.") +}; + +// -=*# Resource for function SUMSQ #*=- +const char* SC_OPCODE_SUM_SQ_ARY[] = +{ + NC_("SC_OPCODE_SUM_SQ", "Returns the sum of the squares of the arguments."), + NC_("SC_OPCODE_SUM_SQ", "number "), + NC_("SC_OPCODE_SUM_SQ", "Number 1, number 2,... are arguments for which the sum of the squares is to be calculated.") +}; + +// -=*# Resource for function PRODUCT #*=- +const char* SC_OPCODE_PRODUCT_ARY[] = +{ + NC_("SC_OPCODE_PRODUCT", "Multiplies the arguments."), + NC_("SC_OPCODE_PRODUCT", "Number "), + NC_("SC_OPCODE_PRODUCT", "Number 1, number 2, ... are arguments to be multiplied and a result returned.") +}; + +// -=*# Resource for function SUMIF #*=- +const char* SC_OPCODE_SUM_IF_ARY[] = +{ + NC_("SC_OPCODE_SUM_IF", "Totals the arguments that meet the condition."), + NC_("SC_OPCODE_SUM_IF", "range"), + NC_("SC_OPCODE_SUM_IF", "The range to be evaluated by the criteria given."), + NC_("SC_OPCODE_SUM_IF", "criteria"), + NC_("SC_OPCODE_SUM_IF", "The criteria to be applied to the range."), + NC_("SC_OPCODE_SUM_IF", "sum_range"), + NC_("SC_OPCODE_SUM_IF", "The range from which the values are to be totalled.") +}; + +// -=*# Resource for function AVERAGEIF #*=- +const char* SC_OPCODE_AVERAGE_IF_ARY[] = +{ + NC_("SC_OPCODE_AVERAGE_IF", "Averages the arguments that meet the conditions."), + NC_("SC_OPCODE_AVERAGE_IF", "range"), + NC_("SC_OPCODE_AVERAGE_IF", "The range to be evaluated by the criteria given."), + NC_("SC_OPCODE_AVERAGE_IF", "criteria"), + NC_("SC_OPCODE_AVERAGE_IF", "The criteria to be applied to the range."), + NC_("SC_OPCODE_AVERAGE_IF", "average_range"), + NC_("SC_OPCODE_AVERAGE_IF", "The range from which the values are to be averaged.") +}; + +const char* SC_OPCODE_SUM_IFS_ARY[] = +{ + NC_("SC_OPCODE_SUM_IFS", "Totals the values of cells in a range that meet multiple criteria in multiple ranges."), + NC_("SC_OPCODE_SUM_IFS", "sum_range"), + NC_("SC_OPCODE_SUM_IFS", "The range from which the values are to be totalled."), + NC_("SC_OPCODE_SUM_IFS", "range "), + NC_("SC_OPCODE_SUM_IFS", "Range 1, range 2,... are the ranges to be evaluated by the criteria given."), + NC_("SC_OPCODE_SUM_IFS", "criteria "), + NC_("SC_OPCODE_SUM_IFS", "Criteria 1, criteria 2,... are the criteria to be applied to the ranges given.") +}; + +// -=*# Resource for function AVERAGEIFS #*=- +const char* SC_OPCODE_AVERAGE_IFS_ARY[] = +{ + NC_("SC_OPCODE_AVERAGE_IFS", "Averages the value of the cells that meet multiple criteria in multiple ranges."), + NC_("SC_OPCODE_AVERAGE_IFS", "average_range"), + NC_("SC_OPCODE_AVERAGE_IFS", "The range from which the values are to be averaged."), + NC_("SC_OPCODE_AVERAGE_IFS", "range "), + NC_("SC_OPCODE_AVERAGE_IFS", "Range 1, range 2,... are the ranges to be evaluated by the criteria given."), + NC_("SC_OPCODE_AVERAGE_IFS", "criteria "), + NC_("SC_OPCODE_AVERAGE_IFS", "Criteria 1, criteria 2,... are the criteria to be applied to the ranges given.") +}; + +// -=*# Resource for function COUNTIFS #*=- +const char* SC_OPCODE_COUNT_IFS_ARY[] = +{ + NC_("SC_OPCODE_COUNT_IFS", "Counts the cells that meet multiple criteria in multiple ranges."), + NC_("SC_OPCODE_COUNT_IFS", "range "), + NC_("SC_OPCODE_COUNT_IFS", "Range 1, range 2,... are the ranges to be evaluated by the criteria given."), + NC_("SC_OPCODE_COUNT_IFS", "criteria "), + NC_("SC_OPCODE_COUNT_IFS", "Criteria 1, criteria 2,... are the criteria to be applied to the ranges given.") +}; + +// -=*# Resource for function COUNTIF #*=- +const char* SC_OPCODE_COUNT_IF_ARY[] = +{ + NC_("SC_OPCODE_COUNT_IF", "Counts the arguments which meet the set conditions."), + NC_("SC_OPCODE_COUNT_IF", "range"), + NC_("SC_OPCODE_COUNT_IF", "The range of cells to be evaluated by the criteria given."), + NC_("SC_OPCODE_COUNT_IF", "criteria"), + NC_("SC_OPCODE_COUNT_IF", "The criteria to be applied to the range.") +}; + +// -=*# Resource for function SQRT #*=- +const char* SC_OPCODE_SQRT_ARY[] = +{ + NC_("SC_OPCODE_SQRT", "Returns the square root of a number."), + NC_("SC_OPCODE_SQRT", "number"), + NC_("SC_OPCODE_SQRT", "A positive value for which the square root is to be calculated.") +}; + +// -=*# Resource for function RAND #*=- +const char* SC_OPCODE_RANDOM_ARY[] = +{ + NC_("SC_OPCODE_RANDOM", "Returns a random number between 0 and 1.") +}; + +// -=*# Resource for function ISEVEN #*=- +const char* SC_OPCODE_IS_EVEN_ARY[] = +{ + NC_("SC_OPCODE_IS_EVEN", "Returns TRUE if value is an even integer."), + NC_("SC_OPCODE_IS_EVEN", "value"), + NC_("SC_OPCODE_IS_EVEN", "The value to be tested.") +}; + +// -=*# Resource for function ISODD #*=- +const char* SC_OPCODE_IS_ODD_ARY[] = +{ + NC_("SC_OPCODE_IS_ODD", "Returns TRUE if value is an odd integer."), + NC_("SC_OPCODE_IS_ODD", "value"), + NC_("SC_OPCODE_IS_ODD", "The value to be tested.") +}; + +// -=*# Resource for function COMBIN #*=- +const char* SC_OPCODE_COMBIN_ARY[] = +{ + NC_("SC_OPCODE_COMBIN", "Calculates the number of combinations for elements without repetition."), + NC_("SC_OPCODE_COMBIN", "number_1"), + NC_("SC_OPCODE_COMBIN", "The total number of elements."), + NC_("SC_OPCODE_COMBIN", "number_2"), + NC_("SC_OPCODE_COMBIN", "The number of elements selected.") +}; + +// -=*# Resource for function COMBINA #*=- +const char* SC_OPCODE_COMBIN_A_ARY[] = +{ + NC_("SC_OPCODE_COMBIN_A", "Calculates the number of combinations of elements including repetition."), + NC_("SC_OPCODE_COMBIN_A", "number_1"), + NC_("SC_OPCODE_COMBIN_A", "The total number of elements."), + NC_("SC_OPCODE_COMBIN_A", "number_2"), + NC_("SC_OPCODE_COMBIN_A", "The number of elements selected.") +}; + +// -=*# Resource for function ARCCOS #*=- +const char* SC_OPCODE_ARC_COS_ARY[] = +{ + NC_("SC_OPCODE_ARC_COS", "Returns the arccosine of a number."), + NC_("SC_OPCODE_ARC_COS", "Number"), + NC_("SC_OPCODE_ARC_COS", "A value between -1 and 1 for which the arccosine is to be returned.") +}; + +// -=*# Resource for function ARCSIN #*=- +const char* SC_OPCODE_ARC_SIN_ARY[] = +{ + NC_("SC_OPCODE_ARC_SIN", "Returns the arcsine of a number."), + NC_("SC_OPCODE_ARC_SIN", "Number"), + NC_("SC_OPCODE_ARC_SIN", "A value between -1 and 1 for which the arcsine is to be returned.") +}; + +// -=*# Resource for function ARCCOSHYP #*=- +const char* SC_OPCODE_ARC_COS_HYP_ARY[] = +{ + NC_("SC_OPCODE_ARC_COS_HYP", "Returns the inverse hyperbolic cosine of a number."), + NC_("SC_OPCODE_ARC_COS_HYP", "Number"), + NC_("SC_OPCODE_ARC_COS_HYP", "A value greater than or equal to 1 for which the inverse hyperbolic cosine is to be returned.") +}; + +// -=*# Resource for function ARCSINHYP #*=- +const char* SC_OPCODE_ARC_SIN_HYP_ARY[] = +{ + NC_("SC_OPCODE_ARC_SIN_HYP", "Returns the inverse hyperbolic sine of a number."), + NC_("SC_OPCODE_ARC_SIN_HYP", "Number"), + NC_("SC_OPCODE_ARC_SIN_HYP", "The value for which the inverse hyperbolic sine is to be returned.") +}; + +// -=*# Resource for function ARCCOT #*=- +const char* SC_OPCODE_ARC_COT_ARY[] = +{ + NC_("SC_OPCODE_ARC_COT", "Returns the inverse cotangent of a number."), + NC_("SC_OPCODE_ARC_COT", "Number"), + NC_("SC_OPCODE_ARC_COT", "The value for which the inverse cotangent is to be returned.") +}; + +// -=*# Resource for function ARCTAN #*=- +const char* SC_OPCODE_ARC_TAN_ARY[] = +{ + NC_("SC_OPCODE_ARC_TAN", "Returns the arctangent of a number."), + NC_("SC_OPCODE_ARC_TAN", "Number"), + NC_("SC_OPCODE_ARC_TAN", "The value for which the arctangent is to be returned.") +}; + +// -=*# Resource for function ARCCOTHYP #*=- +const char* SC_OPCODE_ARC_COT_HYP_ARY[] = +{ + NC_("SC_OPCODE_ARC_COT_HYP", "Returns the inverse hyperbolic cotangent of a number."), + NC_("SC_OPCODE_ARC_COT_HYP", "Number"), + NC_("SC_OPCODE_ARC_COT_HYP", "A value smaller than -1 or greater than 1 for which the inverse hyperbolic cotangent is to be returned.") +}; + +// -=*# Resource for function ARCTANHYP #*=- +const char* SC_OPCODE_ARC_TAN_HYP_ARY[] = +{ + NC_("SC_OPCODE_ARC_TAN_HYP", "Returns the inverse hyperbolic tangent of a number."), + NC_("SC_OPCODE_ARC_TAN_HYP", "Number"), + NC_("SC_OPCODE_ARC_TAN_HYP", "A value between -1 and 1 for which the inverse hyperbolic tangent is to be returned.") +}; + +// -=*# Resource for function COS #*=- +const char* SC_OPCODE_COS_ARY[] = +{ + NC_("SC_OPCODE_COS", "Returns the cosine of a number."), + NC_("SC_OPCODE_COS", "Number"), + NC_("SC_OPCODE_COS", "The angle in the radians for which the cosine is to be returned.") +}; + +// -=*# Resource for function SIN #*=- +const char* SC_OPCODE_SIN_ARY[] = +{ + NC_("SC_OPCODE_SIN", "Returns the sine of a number."), + NC_("SC_OPCODE_SIN", "number"), + NC_("SC_OPCODE_SIN", "The angle in radians for which the sine is to be calculated.") +}; + +// -=*# Resource for function COT #*=- +const char* SC_OPCODE_COT_ARY[] = +{ + NC_("SC_OPCODE_COT", "Returns the cotangent of a number."), + NC_("SC_OPCODE_COT", "Number"), + NC_("SC_OPCODE_COT", "The angle in radians whose cotangent value is to be returned.") +}; + +// -=*# Resource for function TAN #*=- +const char* SC_OPCODE_TAN_ARY[] = +{ + NC_("SC_OPCODE_TAN", "Returns the tangent of a number."), + NC_("SC_OPCODE_TAN", "number"), + NC_("SC_OPCODE_TAN", "The angle in radians for which the tangent is to be calculated.") +}; + +// -=*# Resource for function COSHYP #*=- +const char* SC_OPCODE_COS_HYP_ARY[] = +{ + NC_("SC_OPCODE_COS_HYP", "Returns the hyperbolic cosine of a number."), + NC_("SC_OPCODE_COS_HYP", "Number"), + NC_("SC_OPCODE_COS_HYP", "The value for which the hyperbolic cosine is to be returned.") +}; + +// -=*# Resource for function SINHYP #*=- +const char* SC_OPCODE_SIN_HYP_ARY[] = +{ + NC_("SC_OPCODE_SIN_HYP", "Returns the hyperbolic sine of a number."), + NC_("SC_OPCODE_SIN_HYP", "number"), + NC_("SC_OPCODE_SIN_HYP", "The value for which the hyperbolic sine is to be calculated.") +}; + +// -=*# Resource for function COTHYP #*=- +const char* SC_OPCODE_COT_HYP_ARY[] = +{ + NC_("SC_OPCODE_COT_HYP", "Returns the hyperbolic cotangent of a number."), + NC_("SC_OPCODE_COT_HYP", "Number"), + NC_("SC_OPCODE_COT_HYP", "A value not equal to 0 for which the hyperbolic cotangent is to be returned.") +}; + +// -=*# Resource for function TANHYP #*=- +const char* SC_OPCODE_TAN_HYP_ARY[] = +{ + NC_("SC_OPCODE_TAN_HYP", "Returns the hyperbolic tangent of a number."), + NC_("SC_OPCODE_TAN_HYP", "number"), + NC_("SC_OPCODE_TAN_HYP", "The value for which the hyperbolic tangent is to be calculated.") +}; + +// -=*# Resource for function ARCTAN2 #*=- +const char* SC_OPCODE_ARC_TAN_2_ARY[] = +{ + NC_("SC_OPCODE_ARC_TAN_2", "Returns the arctangent for the specified coordinates."), + NC_("SC_OPCODE_ARC_TAN_2", "number_x"), + NC_("SC_OPCODE_ARC_TAN_2", "The value for the x coordinate."), + NC_("SC_OPCODE_ARC_TAN_2", "number_y"), + NC_("SC_OPCODE_ARC_TAN_2", "The value for the y coordinate.") +}; + +// -=*# Resource for function CSC #*=- +const char* SC_OPCODE_COSECANT_ARY[] = +{ + NC_("SC_OPCODE_COSECANT", "Return the cosecant of an angle. CSC(x)=1/SIN(x)"), + NC_("SC_OPCODE_COSECANT", "Angle"), + NC_("SC_OPCODE_COSECANT", "The angle in radians for which the cosecant is to be calculated.") +}; + +// -=*# Resource for function SEC #*=- +const char* SC_OPCODE_SECANT_ARY[] = +{ + NC_("SC_OPCODE_SECANT", "Return the secant of an angle. SEC(x)=1/COS(x)"), + NC_("SC_OPCODE_SECANT", "Angle"), + NC_("SC_OPCODE_SECANT", "The angle in radians for which the secant is to be calculated.") +}; + +// -=*# Resource for function CSCH #*=- +const char* SC_OPCODE_COSECANT_HYP_ARY[] = +{ + NC_("SC_OPCODE_COSECANT_HYP", "Return the hyperbolic cosecant of a hyperbolic angle. CSCH(x)=1/SINH(x)"), + NC_("SC_OPCODE_COSECANT_HYP", "Angle"), + NC_("SC_OPCODE_COSECANT_HYP", "The hyperbolic angle in radians for which the hyperbolic cosecant is to be calculated.") +}; + +// -=*# Resource for function SECH #*=- +const char* SC_OPCODE_SECANT_HYP_ARY[] = +{ + NC_("SC_OPCODE_SECANT_HYP", "Return the hyperbolic secant of a hyperbolic angle. SECH(x)=1/COSH(x)"), + NC_("SC_OPCODE_SECANT_HYP", "Angle"), + NC_("SC_OPCODE_SECANT_HYP", "The hyperbolic angle in radians for which the hyperbolic secant is to be calculated.") +}; + +// -=*# Resource for function DEG #*=- +const char* SC_OPCODE_DEG_ARY[] = +{ + NC_("SC_OPCODE_DEG", "Converts a radian to degrees"), + NC_("SC_OPCODE_DEG", "Number"), + NC_("SC_OPCODE_DEG", "The angle in a radian") +}; + +// -=*# Resource for function RAD #*=- +const char* SC_OPCODE_RAD_ARY[] = +{ + NC_("SC_OPCODE_RAD", "Converts degrees to radians"), + NC_("SC_OPCODE_RAD", "Number"), + NC_("SC_OPCODE_RAD", "The angle in degrees.") +}; + +// -=*# Resource for function EXP #*=- +const char* SC_OPCODE_EXP_ARY[] = +{ + NC_("SC_OPCODE_EXP", "Calculates the exponent for basis e."), + NC_("SC_OPCODE_EXP", "Number"), + NC_("SC_OPCODE_EXP", "The exponent applied to base e.") +}; + +// -=*# Resource for function LOG #*=- +const char* SC_OPCODE_LOG_ARY[] = +{ + NC_("SC_OPCODE_LOG", "Calculates the logarithm to any specified base."), + NC_("SC_OPCODE_LOG", "Number"), + NC_("SC_OPCODE_LOG", "A value greater than 0 for which the logarithm is to be calculated."), + NC_("SC_OPCODE_LOG", "Base"), + NC_("SC_OPCODE_LOG", "The base of the logarithm. If omitted, the base is regarded as 10.") +}; + +// -=*# Resource for function LN #*=- +const char* SC_OPCODE_LN_ARY[] = +{ + NC_("SC_OPCODE_LN", "Calculates the natural logarithm of a number."), + NC_("SC_OPCODE_LN", "Number"), + NC_("SC_OPCODE_LN", "A value greater than 0 for which the natural logarithm is to be calculated.") +}; + +// -=*# Resource for function LOG10 #*=- +const char* SC_OPCODE_LOG10_ARY[] = +{ + NC_("SC_OPCODE_LOG10", "Calculates the base-10 logarithm of a number."), + NC_("SC_OPCODE_LOG10", "Number"), + NC_("SC_OPCODE_LOG10", "A value greater than 0 for which the logarithm is to be calculated.") +}; + +// -=*# Resource for function FACT #*=- +const char* SC_OPCODE_FACT_ARY[] = +{ + NC_("SC_OPCODE_FACT", "Calculates the factorial of a number."), + NC_("SC_OPCODE_FACT", "Number"), + NC_("SC_OPCODE_FACT", "The number for which the factorial is to be calculated.") +}; + +// -=*# Resource for function MOD #*=- +const char* SC_OPCODE_MOD_ARY[] = +{ + NC_("SC_OPCODE_MOD", "Calculates the remainder of a division."), + NC_("SC_OPCODE_MOD", "Dividend"), + NC_("SC_OPCODE_MOD", "The number to be divided."), + NC_("SC_OPCODE_MOD", "Divisor"), + NC_("SC_OPCODE_MOD", "The number by which the dividend is divided.") +}; + +// -=*# Resource for function SIGN #*=- +const char* SC_OPCODE_PLUS_MINUS_ARY[] = +{ + NC_("SC_OPCODE_PLUS_MINUS", "Returns the algebraic sign of a number."), + NC_("SC_OPCODE_PLUS_MINUS", "Number"), + NC_("SC_OPCODE_PLUS_MINUS", "The number for which the algebraic sign is to be determined.") +}; + +// -=*# Resource for function SUBTOTAL #*=- +const char* SC_OPCODE_SUB_TOTAL_ARY[] = +{ + NC_("SC_OPCODE_SUB_TOTAL", "Calculates subtotals in a spreadsheet."), + NC_("SC_OPCODE_SUB_TOTAL", "Function"), + NC_("SC_OPCODE_SUB_TOTAL", "Function index. Is an index of the possible functions Total, Max, ..."), + NC_("SC_OPCODE_SUB_TOTAL", "range"), + NC_("SC_OPCODE_SUB_TOTAL", "The cells of the range which are to be taken into account.") +}; + +// -=*# Resource for function AGGREGATE #*=- +const char* SC_OPCODE_AGGREGATE_ARY[] = +{ + NC_("SC_OPCODE_AGGREGATE", "Calculates an aggregate in a spreadsheet."), + NC_("SC_OPCODE_AGGREGATE", "Function"), + NC_("SC_OPCODE_AGGREGATE", "Function index. Is an index of the possible functions Total, Max, ..."), + NC_("SC_OPCODE_AGGREGATE", "Options"), + NC_("SC_OPCODE_AGGREGATE", "Option index. Is an index of the possible ignore options."), + NC_("SC_OPCODE_AGGREGATE", "Ref1 or array "), + NC_("SC_OPCODE_AGGREGATE", "The cell(s) of the range which are to be taken into account."), + NC_("SC_OPCODE_AGGREGATE", "Ref2..n or k "), + NC_("SC_OPCODE_AGGREGATE", "The cells of the range which are to be taken into account or mandatory 2nd argument for certain functions.") +}; + +// -=*# Resource for function INT #*=- +const char* SC_OPCODE_INT_ARY[] = +{ + NC_("SC_OPCODE_INT", "Rounds a number down to the nearest integer."), + NC_("SC_OPCODE_INT", "Number"), + NC_("SC_OPCODE_INT", "The number to be rounded down.") +}; + +// -=*# Resource for function TRUNC #*=- +const char* SC_OPCODE_TRUNC_ARY[] = +{ + NC_("SC_OPCODE_TRUNC", "Truncates the decimal places of a number."), + NC_("SC_OPCODE_TRUNC", "number"), + NC_("SC_OPCODE_TRUNC", "The number to be truncated."), + NC_("SC_OPCODE_TRUNC", "count"), + NC_("SC_OPCODE_TRUNC", "The number of places after the decimal point that are not to be truncated.") +}; + +// -=*# Resource for function ROUND #*=- +const char* SC_OPCODE_ROUND_ARY[] = +{ + NC_("SC_OPCODE_ROUND", "Rounds a number to a predefined accuracy."), + NC_("SC_OPCODE_ROUND", "number"), + NC_("SC_OPCODE_ROUND", "The number to be rounded."), + NC_("SC_OPCODE_ROUND", "count"), + NC_("SC_OPCODE_ROUND", "The number of places to which a number is to be rounded.") +}; + +// -=*# Resource for function ROUNDUP #*=- +const char* SC_OPCODE_ROUND_UP_ARY[] = +{ + NC_("SC_OPCODE_ROUND_UP", "Rounds a number up to the predefined accuracy."), + NC_("SC_OPCODE_ROUND_UP", "number"), + NC_("SC_OPCODE_ROUND_UP", "The number to be rounded up."), + NC_("SC_OPCODE_ROUND_UP", "count"), + NC_("SC_OPCODE_ROUND_UP", "The number of places to which a number is to be rounded.") +}; + +// -=*# Resource for function ROUNDDOWN #*=- +const char* SC_OPCODE_ROUND_DOWN_ARY[] = +{ + NC_("SC_OPCODE_ROUND_DOWN", "Rounds a number down to a predefined accuracy."), + NC_("SC_OPCODE_ROUND_DOWN", "number"), + NC_("SC_OPCODE_ROUND_DOWN", "The number to be rounded down."), + NC_("SC_OPCODE_ROUND_DOWN", "count"), + NC_("SC_OPCODE_ROUND_DOWN", "The number of places down to which a number is to be rounded.") +}; + +// -=*# Resource for function EVEN #*=- +const char* SC_OPCODE_EVEN_ARY[] = +{ + NC_("SC_OPCODE_EVEN", "Rounds a positive number up and negative number down to the nearest even integer."), + NC_("SC_OPCODE_EVEN", "Number"), + NC_("SC_OPCODE_EVEN", "The number to be rounded up.") +}; + +// -=*# Resource for function ODD #*=- +const char* SC_OPCODE_ODD_ARY[] = +{ + NC_("SC_OPCODE_ODD", "Rounds a positive number up and negative number down to the nearest odd integer."), + NC_("SC_OPCODE_ODD", "Number"), + NC_("SC_OPCODE_ODD", "The number to be rounded up.") +}; + +// -=*# Resource for function CEILING.XCL #*=- +const char* SC_OPCODE_CEIL_MS_ARY[] = +{ + NC_("SC_OPCODE_CEIL_MS", "Rounds a number away from zero to the nearest multiple of significance.\nThis function exists for interoperability with Microsoft Excel 2007 or older versions."), + NC_("SC_OPCODE_CEIL_MS", "Number"), + NC_("SC_OPCODE_CEIL_MS", "The number to be rounded up."), + NC_("SC_OPCODE_CEIL_MS", "Significance"), + NC_("SC_OPCODE_CEIL_MS", "The number to whose multiple the value is rounded.") +}; + +// -=*# Resource for function CEILING.PRECISE #*=- +const char* SC_OPCODE_CEIL_PRECISE_ARY[] = +{ + NC_("SC_OPCODE_CEIL_PRECISE", "Rounds a number up to the nearest multiple of significance, regardless of sign of significance."), + NC_("SC_OPCODE_CEIL_PRECISE", "Number"), + NC_("SC_OPCODE_CEIL_PRECISE", "The number to be rounded up."), + NC_("SC_OPCODE_CEIL_PRECISE", "Significance"), + NC_("SC_OPCODE_CEIL_PRECISE", "The number to whose multiple the value is rounded.") +}; + +// -=*# Resource for function ISO.CEILING #*=- +const char* SC_OPCODE_CEIL_ISO_ARY[] = +{ + NC_("SC_OPCODE_CEIL_ISO", "Rounds a number up to the nearest multiple of significance, regardless of sign of significance."), + NC_("SC_OPCODE_CEIL_ISO", "Number"), + NC_("SC_OPCODE_CEIL_ISO", "The number to be rounded up."), + NC_("SC_OPCODE_CEIL_ISO", "Significance"), + NC_("SC_OPCODE_CEIL_ISO", "The number to whose multiple the value is rounded.") +}; + +// -=*# Resource for function CEILING #*=- +const char* SC_OPCODE_CEIL_ARY[] = +{ + NC_("SC_OPCODE_CEIL", "Rounds a number up to the nearest multiple of significance."), + NC_("SC_OPCODE_CEIL", "Number"), + NC_("SC_OPCODE_CEIL", "The number to be rounded up."), + NC_("SC_OPCODE_CEIL", "Significance"), + NC_("SC_OPCODE_CEIL", "If given the number to whose multiple the value is rounded, else -1 or 1 depending on sign of Number."), + NC_("SC_OPCODE_CEIL", "Mode"), + NC_("SC_OPCODE_CEIL", "If given and not equal to zero then rounded up according to amount when a negative number and significance.") +}; + +// -=*# Resource for function CEILING.MATH #*=- +const char* SC_OPCODE_CEIL_MATH_ARY[] = +{ + NC_("SC_OPCODE_CEIL_MATH", "Rounds a number up to the nearest multiple of significance."), + NC_("SC_OPCODE_CEIL_MATH", "Number"), + NC_("SC_OPCODE_CEIL_MATH", "The number to be rounded up."), + NC_("SC_OPCODE_CEIL_MATH", "Significance"), + NC_("SC_OPCODE_CEIL_MATH", "If given the number to whose multiple the value is rounded, else 1."), + NC_("SC_OPCODE_CEIL_MATH", "Mode"), + NC_("SC_OPCODE_CEIL_MATH", "For negative numbers; if given and not equal to zero then rounds away from zero, else rounds towards zero.") +}; + +// -=*# Resource for function FLOOR #*=- +const char* SC_OPCODE_FLOOR_ARY[] = +{ + NC_("SC_OPCODE_FLOOR", "Rounds number down to the nearest multiple of significance."), + NC_("SC_OPCODE_FLOOR", "Number"), + NC_("SC_OPCODE_FLOOR", "The number to be rounded down."), + NC_("SC_OPCODE_FLOOR", "Significance"), + NC_("SC_OPCODE_FLOOR", "The number to whose multiple the value is to be rounded down."), + NC_("SC_OPCODE_FLOOR", "Mode"), + NC_("SC_OPCODE_FLOOR", "If given and not equal to zero then rounded towards zero with negative number and significance.") +}; + +// -=*# Resource for function FLOOR.XCL #*=- +const char* SC_OPCODE_FLOOR_MS_ARY[] = +{ + NC_("SC_OPCODE_FLOOR_MS", "Rounds number towards zero to the nearest multiple of absolute value of significance.\nThis function exists for interoperability with Microsoft Excel 2007 or older versions."), + NC_("SC_OPCODE_FLOOR_MS", "Number"), + NC_("SC_OPCODE_FLOOR_MS", "The number to be rounded down."), + NC_("SC_OPCODE_FLOOR_MS", "Significance"), + NC_("SC_OPCODE_FLOOR_MS", "The number to whose multiple the value is to be rounded down.") +}; + +// -=*# Resource for function FLOOR.MATH #*=- +const char* SC_OPCODE_FLOOR_MATH_ARY[] = +{ + NC_("SC_OPCODE_FLOOR_MATH", "Rounds number down to the nearest multiple of significance, regardless of sign of significance."), + NC_("SC_OPCODE_FLOOR_MATH", "Number"), + NC_("SC_OPCODE_FLOOR_MATH", "The number to be rounded down."), + NC_("SC_OPCODE_FLOOR_MATH", "Significance"), + NC_("SC_OPCODE_FLOOR_MATH", "The number to whose multiple the value is to be rounded down."), + NC_("SC_OPCODE_FLOOR_MATH", "Mode"), + NC_("SC_OPCODE_FLOOR_MATH", "For negative numbers; if given and not equal to or less than zero rounds towards zero.") +}; + +// -=*# Resource for function FLOOR.PRECISE #*=- +const char* SC_OPCODE_FLOOR_PRECISE_ARY[] = +{ + NC_("SC_OPCODE_FLOOR_PRECISE", "Rounds number down (towards -∞) to the nearest multiple of significance."), + NC_("SC_OPCODE_FLOOR_PRECISE", "Number"), + NC_("SC_OPCODE_FLOOR_PRECISE", "The number to be rounded down."), + NC_("SC_OPCODE_FLOOR_PRECISE", "Significance"), + NC_("SC_OPCODE_FLOOR_PRECISE", "The number to whose multiple the value is to be rounded down. Sign has no meaning.") +}; + +// -=*# Resource for function GCD #*=- +const char* SC_OPCODE_GCD_ARY[] = +{ + NC_("SC_OPCODE_GCD", "Greatest Common Divisor"), + NC_("SC_OPCODE_GCD", "Integer "), + NC_("SC_OPCODE_GCD", "Integer 1; integer 2,... are integers for which the greatest common divisor is to be calculated.") +}; + +// -=*# Resource for function LCM #*=- +const char* SC_OPCODE_LCM_ARY[] = +{ + NC_("SC_OPCODE_LCM", "Lowest common multiple"), + NC_("SC_OPCODE_LCM", "Integer "), + NC_("SC_OPCODE_LCM", "Integer 1; integer 2,... are integers whose smallest common multiple is to be calculated.") +}; + +// -=*# Resource for function TRANSPOSE #*=- +const char* SC_OPCODE_MAT_TRANS_ARY[] = +{ + NC_("SC_OPCODE_MAT_TRANS", "Array transposition. Exchanges the rows and columns of an array."), + NC_("SC_OPCODE_MAT_TRANS", "array"), + NC_("SC_OPCODE_MAT_TRANS", "The array in which the rows and columns have been transposed.") +}; + +// -=*# Resource for function MMULT #*=- +const char* SC_OPCODE_MAT_MULT_ARY[] = +{ + NC_("SC_OPCODE_MAT_MULT", "Array multiplication. Returns the product of two arrays."), + NC_("SC_OPCODE_MAT_MULT", "array_1"), + NC_("SC_OPCODE_MAT_MULT", "The first array for the array product."), + NC_("SC_OPCODE_MAT_MULT", "array_2"), + NC_("SC_OPCODE_MAT_MULT", "The second array having the same number of rows as the first array has columns.") +}; + +// -=*# Resource for function MDETERM #*=- +const char* SC_OPCODE_MAT_DET_ARY[] = +{ + NC_("SC_OPCODE_MAT_DET", "Returns the array determinant."), + NC_("SC_OPCODE_MAT_DET", "array"), + NC_("SC_OPCODE_MAT_DET", "The array for which the determinant is to be determined.") +}; + +// -=*# Resource for function MINVERSE #*=- +const char* SC_OPCODE_MAT_INV_ARY[] = +{ + NC_("SC_OPCODE_MAT_INV", "Returns the inverse of an array."), + NC_("SC_OPCODE_MAT_INV", "array"), + NC_("SC_OPCODE_MAT_INV", "The array to be inverted.") +}; + +// -=*# Resource for function MUNIT #*=- +const char* SC_OPCODE_MATRIX_UNIT_ARY[] = +{ + NC_("SC_OPCODE_MATRIX_UNIT", "Returns the unitary square array of a certain size."), + NC_("SC_OPCODE_MATRIX_UNIT", "Dimensions"), + NC_("SC_OPCODE_MATRIX_UNIT", "The size of the unitary array.") +}; + +// -=*# Resource for function SUMPRODUCT #*=- +const char* SC_OPCODE_SUM_PRODUCT_ARY[] = +{ + NC_("SC_OPCODE_SUM_PRODUCT", "(Inner products) Returns the sum of the products of array arguments."), + NC_("SC_OPCODE_SUM_PRODUCT", "Array "), + NC_("SC_OPCODE_SUM_PRODUCT", "Array 1, array 2, ... are arrays whose arguments are to be multiplied.") +}; + +// -=*# Resource for function SUMX2MY2 #*=- +const char* SC_OPCODE_SUM_X2MY2_ARY[] = +{ + NC_("SC_OPCODE_SUM_X2MY2", "Returns the sum of the difference of squares of two arrays."), + NC_("SC_OPCODE_SUM_X2MY2", "array_x"), + NC_("SC_OPCODE_SUM_X2MY2", "First array where the square of the arguments are totalled."), + NC_("SC_OPCODE_SUM_X2MY2", "array_y"), + NC_("SC_OPCODE_SUM_X2MY2", "Second array where the square of the arguments is to be subtracted.") +}; + +// -=*# Resource for function SUMX2PY2 #*=- +const char* SC_OPCODE_SUM_X2DY2_ARY[] = +{ + NC_("SC_OPCODE_SUM_X2DY2", "Returns the total of the square sum of two arrays."), + NC_("SC_OPCODE_SUM_X2DY2", "array_x"), + NC_("SC_OPCODE_SUM_X2DY2", "First array where the square of the arguments are totalled."), + NC_("SC_OPCODE_SUM_X2DY2", "array_y"), + NC_("SC_OPCODE_SUM_X2DY2", "Second array where the square of the arguments is to be totalled.") +}; + +// -=*# Resource for function SUMXMY2 #*=- +const char* SC_OPCODE_SUM_XMY2_ARY[] = +{ + NC_("SC_OPCODE_SUM_XMY2", "Returns the sum of squares of differences of two arrays."), + NC_("SC_OPCODE_SUM_XMY2", "array_x"), + NC_("SC_OPCODE_SUM_XMY2", "First array for forming argument differences."), + NC_("SC_OPCODE_SUM_XMY2", "array_y"), + NC_("SC_OPCODE_SUM_XMY2", "Second array for forming the argument differences.") +}; + +// -=*# Resource for function FREQUENCY #*=- +const char* SC_OPCODE_FREQUENCY_ARY[] = +{ + NC_("SC_OPCODE_FREQUENCY", "Returns a frequency distribution as a vertical array."), + NC_("SC_OPCODE_FREQUENCY", "data"), + NC_("SC_OPCODE_FREQUENCY", "The array of the data."), + NC_("SC_OPCODE_FREQUENCY", "classes"), + NC_("SC_OPCODE_FREQUENCY", "The array for forming classes.") +}; + +// -=*# Resource for function LINEST #*=- +const char* SC_OPCODE_LINEST_ARY[] = +{ + NC_("SC_OPCODE_LINEST", "Calculates parameters of the linear regression as an array."), + NC_("SC_OPCODE_LINEST", "data_Y"), + NC_("SC_OPCODE_LINEST", "The Y data array."), + NC_("SC_OPCODE_LINEST", "data_X"), + NC_("SC_OPCODE_LINEST", "The X data array."), + NC_("SC_OPCODE_LINEST", "Linear_type"), + NC_("SC_OPCODE_LINEST", "If type = 0 the linears will be calculated through the zero point, or else moved linears."), + NC_("SC_OPCODE_LINEST", "stats"), + NC_("SC_OPCODE_LINEST", "If parameter = 0 then only the regression coefficient will be calculated, otherwise other values as well.") +}; + +// -=*# Resource for function LOGEST #*=- +const char* SC_OPCODE_LOGEST_ARY[] = +{ + NC_("SC_OPCODE_LOGEST", "Calculates the parameters of the exponential regression curve as an array."), + NC_("SC_OPCODE_LOGEST", "data_Y"), + NC_("SC_OPCODE_LOGEST", "The Y data array."), + NC_("SC_OPCODE_LOGEST", "data_X"), + NC_("SC_OPCODE_LOGEST", "The X data array."), + NC_("SC_OPCODE_LOGEST", "Function_type"), + NC_("SC_OPCODE_LOGEST", "If type = 0 then the functions will be calculated in the form of y=m^x, or also functions y=b*m^x."), + NC_("SC_OPCODE_LOGEST", "stats"), + NC_("SC_OPCODE_LOGEST", "If parameter = 0 then only the regression coefficient will be calculated, otherwise other values as well.") +}; + +// -=*# Resource for function TREND #*=- +const char* SC_OPCODE_TREND_ARY[] = +{ + NC_("SC_OPCODE_TREND", "Calculates points along a regression line."), + NC_("SC_OPCODE_TREND", "data_Y"), + NC_("SC_OPCODE_TREND", "The Y data array."), + NC_("SC_OPCODE_TREND", "data_X"), + NC_("SC_OPCODE_TREND", "The X data array as the basis for the regression."), + NC_("SC_OPCODE_TREND", "new data_X"), + NC_("SC_OPCODE_TREND", "The array of X data for recalculating the values."), + NC_("SC_OPCODE_TREND", "Linear_type"), + NC_("SC_OPCODE_TREND", "If type = 0 the linears will be calculated through the zero point, or else moved linears.") +}; + +// -=*# Resource for function GROWTH #*=- +const char* SC_OPCODE_GROWTH_ARY[] = +{ + NC_("SC_OPCODE_GROWTH", "Calculates points on the exponential regression function."), + NC_("SC_OPCODE_GROWTH", "data_Y"), + NC_("SC_OPCODE_GROWTH", "The Y data array."), + NC_("SC_OPCODE_GROWTH", "data_X"), + NC_("SC_OPCODE_GROWTH", "The X data array as the basis for the regression."), + NC_("SC_OPCODE_GROWTH", "new_data_X"), + NC_("SC_OPCODE_GROWTH", "The array of X data for recalculating the values."), + NC_("SC_OPCODE_GROWTH", "Function_type"), + NC_("SC_OPCODE_GROWTH", "If type = 0 then the functions will be calculated in the form of y=m^x, or also functions y=b*m^x.") +}; + +// -=*# Resource for function COUNT #*=- +const char* SC_OPCODE_COUNT_ARY[] = +{ + NC_("SC_OPCODE_COUNT", "Counts how many numbers are in the list of arguments."), + NC_("SC_OPCODE_COUNT", "value "), + NC_("SC_OPCODE_COUNT", "Value 1, value 2, ... are arguments containing different data types but where only numbers are counted.") +}; + +// -=*# Resource for function COUNTA #*=- +const char* SC_OPCODE_COUNT_2_ARY[] = +{ + NC_("SC_OPCODE_COUNT_2", "Counts how many values are in the list of arguments."), + NC_("SC_OPCODE_COUNT_2", "value "), + NC_("SC_OPCODE_COUNT_2", "Value 1, value 2, ... are arguments representing the values to be counted.") +}; + +// -=*# Resource for function MAX #*=- +const char* SC_OPCODE_MAX_ARY[] = +{ + NC_("SC_OPCODE_MAX", "Returns the maximum value in a list of arguments."), + NC_("SC_OPCODE_MAX", "number "), + NC_("SC_OPCODE_MAX", "Number 1, number 2, ... are numerical arguments for which the largest number is to be determined.") +}; + +// -=*# Resource for function MAXA #*=- +const char* SC_OPCODE_MAX_A_ARY[] = +{ + NC_("SC_OPCODE_MAX_A", "Returns the maximum value in a list of arguments. Text is evaluated as Zero."), + NC_("SC_OPCODE_MAX_A", "value "), + NC_("SC_OPCODE_MAX_A", "Value 1, value 2, are arguments whose largest value is to be determined.") +}; + +// -=*# Resource for function MIN #*=- +const char* SC_OPCODE_MIN_ARY[] = +{ + NC_("SC_OPCODE_MIN", "Returns the minimum value in a list of arguments."), + NC_("SC_OPCODE_MIN", "number "), + NC_("SC_OPCODE_MIN", "Number 1, number 2, ... are numerical arguments for which the smallest number is to be determined.") +}; + +// -=*# Resource for function MINA #*=- +const char* SC_OPCODE_MIN_A_ARY[] = +{ + NC_("SC_OPCODE_MIN_A", "Returns the smallest value in a list of arguments. Text is evaluated as zero."), + NC_("SC_OPCODE_MIN_A", "value "), + NC_("SC_OPCODE_MIN_A", "Value 1; value 2;... are arguments whose smallest number is to be determined.") +}; + +// -=*# Resource for function VAR #*=- +const char* SC_OPCODE_VAR_ARY[] = +{ + NC_("SC_OPCODE_VAR", "Calculates the variance based on a sample."), + NC_("SC_OPCODE_VAR", "number "), + NC_("SC_OPCODE_VAR", "Number 1, number 2, ... are numerical arguments which portray a sample of a population.") +}; + +// -=*# Resource for function VAR.S #*=- +const char* SC_OPCODE_VAR_S_ARY[] = +{ + NC_("SC_OPCODE_VAR_S", "Calculates the variance based on a sample."), + NC_("SC_OPCODE_VAR_S", "number "), + NC_("SC_OPCODE_VAR_S", "Number 1, number 2, ... are numerical arguments which portray a sample of a population.") +}; + +// -=*# Resource for function VARA #*=- +const char* SC_OPCODE_VAR_A_ARY[] = +{ + NC_("SC_OPCODE_VAR_A", "Returns the variance based on a sample. Text is evaluated as zero."), + NC_("SC_OPCODE_VAR_A", "value "), + NC_("SC_OPCODE_VAR_A", "Value 1; value 2; ... are arguments representing a sample taken from a basic total population.") +}; + +// -=*# Resource for function VARP #*=- +const char* SC_OPCODE_VAR_P_ARY[] = +{ + NC_("SC_OPCODE_VAR_P", "Calculates variance based on the entire population."), + NC_("SC_OPCODE_VAR_P", "number "), + NC_("SC_OPCODE_VAR_P", "Number 1, number 2, ... are numerical arguments which represent a population.") +}; + +// -=*# Resource for function VAR.P #*=- +const char* SC_OPCODE_VAR_P_MS_ARY[] = +{ + NC_("SC_OPCODE_VAR_P_MS", "Calculates variance based on the entire population."), + NC_("SC_OPCODE_VAR_P_MS", "number "), + NC_("SC_OPCODE_VAR_P_MS", "Number 1, number 2, ... are numerical arguments which represent a population.") +}; + +// -=*# Resource for function VARPA #*=- +const char* SC_OPCODE_VAR_P_A_ARY[] = +{ + NC_("SC_OPCODE_VAR_P_A", "Returns the variance based on the entire population. Text is evaluated as zero."), + NC_("SC_OPCODE_VAR_P_A", "value "), + NC_("SC_OPCODE_VAR_P_A", "Value 1; value 2;... are arguments representing a population.") +}; + +// -=*# Resource for function STDEV #*=- +const char* SC_OPCODE_ST_DEV_ARY[] = +{ + NC_("SC_OPCODE_ST_DEV", "Calculates the standard deviation based on a sample."), + NC_("SC_OPCODE_ST_DEV", "number "), + NC_("SC_OPCODE_ST_DEV", "Number 1, number 2, ... are numerical arguments which portray a sample of a population.") +}; + +// -=*# Resource for function STDEV.S #*=- +const char* SC_OPCODE_ST_DEV_S_ARY[] = +{ + NC_("SC_OPCODE_ST_DEV_S", "Calculates the standard deviation based on a sample."), + NC_("SC_OPCODE_ST_DEV_S", "number "), + NC_("SC_OPCODE_ST_DEV_S", "Number 1, number 2, ... are numerical arguments which portray a sample of a population.") +}; + +// -=*# Resource for function STDEVA #*=- +const char* SC_OPCODE_ST_DEV_A_ARY[] = +{ + NC_("SC_OPCODE_ST_DEV_A", "Returns the standard deviation based on a sample. Text is evaluated as zero."), + NC_("SC_OPCODE_ST_DEV_A", "value "), + NC_("SC_OPCODE_ST_DEV_A", "Value 1; value 2; ... are arguments representing a sample taken from a basic total population.") +}; + +// -=*# Resource for function STDEVP #*=- +const char* SC_OPCODE_ST_DEV_P_ARY[] = +{ + NC_("SC_OPCODE_ST_DEV_P", "Calculates the standard deviation based on the entire population."), + NC_("SC_OPCODE_ST_DEV_P", "number "), + NC_("SC_OPCODE_ST_DEV_P", "Number 1, number 2, ... are numerical arguments which portray a population.") +}; + +// -=*# Resource for function STDEV.P #*=- +const char* SC_OPCODE_ST_DEV_P_MS_ARY[] = +{ + NC_("SC_OPCODE_ST_DEV_P_MS", "Calculates the standard deviation based on the entire population."), + NC_("SC_OPCODE_ST_DEV_P_MS", "number "), + NC_("SC_OPCODE_ST_DEV_P_MS", "Number 1, number 2, ... are numerical arguments which portray a population.") +}; + +// -=*# Resource for function STDEVPA #*=- +const char* SC_OPCODE_ST_DEV_P_A_ARY[] = +{ + NC_("SC_OPCODE_ST_DEV_P_A", "Returns the standard deviation based on the entire population. Text is evaluated as zero."), + NC_("SC_OPCODE_ST_DEV_P_A", "value "), + NC_("SC_OPCODE_ST_DEV_P_A", "Value 1; value 2;... are arguments corresponding to a population.") +}; + +// -=*# Resource for function AVERAGE #*=- +const char* SC_OPCODE_AVERAGE_ARY[] = +{ + NC_("SC_OPCODE_AVERAGE", "Returns the average of a sample."), + NC_("SC_OPCODE_AVERAGE", "number "), + NC_("SC_OPCODE_AVERAGE", "Number 1, number 2;...are numeric arguments representing a population sample.") +}; + +// -=*# Resource for function AVERAGEA #*=- +const char* SC_OPCODE_AVERAGE_A_ARY[] = +{ + NC_("SC_OPCODE_AVERAGE_A", "Returns the average value for a sample. Text is evaluated as zero."), + NC_("SC_OPCODE_AVERAGE_A", "value "), + NC_("SC_OPCODE_AVERAGE_A", "Value 1; value 2; ... are arguments representing a sample taken from a basic total population.") +}; + +// -=*# Resource for function DEVSQ #*=- +const char* SC_OPCODE_DEV_SQ_ARY[] = +{ + NC_("SC_OPCODE_DEV_SQ", "Returns the sum of squares of deviations from the sample mean value"), + NC_("SC_OPCODE_DEV_SQ", "number "), + NC_("SC_OPCODE_DEV_SQ", "Number 1, number 2, ... are numerical arguments which portray a sample.") +}; + +// -=*# Resource for function AVEDEV #*=- +const char* SC_OPCODE_AVE_DEV_ARY[] = +{ + NC_("SC_OPCODE_AVE_DEV", "Returns the average of the absolute deviations of a sample from the mean."), + NC_("SC_OPCODE_AVE_DEV", "number "), + NC_("SC_OPCODE_AVE_DEV", "Number 1, number 2;...are numerical arguments representing a sample.") +}; + +// -=*# Resource for function SKEW #*=- +const char* SC_OPCODE_SKEW_ARY[] = +{ + NC_("SC_OPCODE_SKEW", "Returns the skewness of a distribution."), + NC_("SC_OPCODE_SKEW", "number "), + NC_("SC_OPCODE_SKEW", "Number 1, number 2, ... are numerical arguments portraying a sample of the distribution.") +}; + +// -=*# Resource for function SKEWP #*=- +const char* SC_OPCODE_SKEWP_ARY[] = +{ + NC_("SC_OPCODE_SKEWP", "Returns the skewness of a distribution using the population of a random variable."), + NC_("SC_OPCODE_SKEWP", "number "), + NC_("SC_OPCODE_SKEWP", "Number 1, number 2, ... are numerical arguments portraying the population.") +}; + +// -=*# Resource for function KURT #*=- +const char* SC_OPCODE_KURT_ARY[] = +{ + NC_("SC_OPCODE_KURT", "Returns the kurtosis of a distribution."), + NC_("SC_OPCODE_KURT", "number "), + NC_("SC_OPCODE_KURT", "Number 1, number 2, ... are numerical arguments, representing a sample of the distribution.") +}; + +// -=*# Resource for function GEOMEAN #*=- +const char* SC_OPCODE_GEO_MEAN_ARY[] = +{ + NC_("SC_OPCODE_GEO_MEAN", "Returns the geometric mean of a sample."), + NC_("SC_OPCODE_GEO_MEAN", "number "), + NC_("SC_OPCODE_GEO_MEAN", "Number 1, number 2, ... are numerical arguments which portray a sample.") +}; + +// -=*# Resource for function HARMEAN #*=- +const char* SC_OPCODE_HAR_MEAN_ARY[] = +{ + NC_("SC_OPCODE_HAR_MEAN", "Returns the harmonic mean of a sample."), + NC_("SC_OPCODE_HAR_MEAN", "number "), + NC_("SC_OPCODE_HAR_MEAN", "Number 1, number 2, ... are numerical arguments which portray a sample.") +}; + +// -=*# Resource for function MODE #*=- +const char* SC_OPCODE_MODAL_VALUE_ARY[] = +{ + NC_("SC_OPCODE_MODAL_VALUE", "Returns the most common value in a sample."), + NC_("SC_OPCODE_MODAL_VALUE", "number "), + NC_("SC_OPCODE_MODAL_VALUE", "Number 1, number 2, ... are numerical arguments which portray a sample.") +}; + +// -=*# Resource for function MODE.SNGL #*=- +const char* SC_OPCODE_MODAL_VALUE_MS_ARY[] = +{ + NC_("SC_OPCODE_MODAL_VALUE_MS", "Returns the most common value in a sample."), + NC_("SC_OPCODE_MODAL_VALUE_MS", "number "), + NC_("SC_OPCODE_MODAL_VALUE_MS", "Number 1, number 2, ... are numerical arguments which portray a sample.") +}; + +// -=*# Resource for function MODE.MULT #*=- +const char* SC_OPCODE_MODAL_VALUE_MULTI_ARY[] = +{ + NC_("SC_OPCODE_MODAL_VALUE_MULTI", "Returns the most common value in a sample."), + NC_("SC_OPCODE_MODAL_VALUE_MULTI", "number "), + NC_("SC_OPCODE_MODAL_VALUE_MULTI", "Number 1, number 2, ... are 1 to 254 numerical arguments which portray a sample.") +}; + +// -=*# Resource for function MEDIAN #*=- +const char* SC_OPCODE_MEDIAN_ARY[] = +{ + NC_("SC_OPCODE_MEDIAN", "Returns the median of a given sample."), + NC_("SC_OPCODE_MEDIAN", "number "), + NC_("SC_OPCODE_MEDIAN", "Number 1, number 2, ... are numerical arguments which portray a sample.") +}; + +// -=*# Resource for function PERCENTILE #*=- +const char* SC_OPCODE_PERCENTILE_ARY[] = +{ + NC_("SC_OPCODE_PERCENTILE", "Returns the alpha quantile of a sample."), + NC_("SC_OPCODE_PERCENTILE", "data"), + NC_("SC_OPCODE_PERCENTILE", "The array of the data in the sample."), + NC_("SC_OPCODE_PERCENTILE", "Alpha"), + NC_("SC_OPCODE_PERCENTILE", "The percentage rate of the quantile between 0 and 1.") +}; + +// -=*# Resource for function PERCENTILE.EXC #*=- +const char* SC_OPCODE_PERCENTILE_EXC_ARY[] = +{ + NC_("SC_OPCODE_PERCENTILE_EXC", "Returns the alpha percentile of a sample."), + NC_("SC_OPCODE_PERCENTILE_EXC", "data"), + NC_("SC_OPCODE_PERCENTILE_EXC", "The array of the data in the sample."), + NC_("SC_OPCODE_PERCENTILE_EXC", "Alpha"), + NC_("SC_OPCODE_PERCENTILE_EXC", "The percentile value, range 0...1, exclusive.") +}; + +// -=*# Resource for function PERCENTILE.INC #*=- +const char* SC_OPCODE_PERCENTILE_INC_ARY[] = +{ + NC_("SC_OPCODE_PERCENTILE_INC", "Returns the alpha percentile of a sample."), + NC_("SC_OPCODE_PERCENTILE_INC", "data"), + NC_("SC_OPCODE_PERCENTILE_INC", "The array of the data in the sample."), + NC_("SC_OPCODE_PERCENTILE_INC", "Alpha"), + NC_("SC_OPCODE_PERCENTILE_INC", "The percentile value, range 0...1, inclusive.") +}; + +// -=*# Resource for function QUARTILE #*=- +const char* SC_OPCODE_QUARTILE_ARY[] = +{ + NC_("SC_OPCODE_QUARTILE", "Returns the quartile of a sample."), + NC_("SC_OPCODE_QUARTILE", "data"), + NC_("SC_OPCODE_QUARTILE", "The array of the data in the sample."), + NC_("SC_OPCODE_QUARTILE", "Type"), + NC_("SC_OPCODE_QUARTILE", "The type of the quartile (0 = MIN, 1 = 25%, 2 = 50%, 3 = 75%, 4 = MAX).") +}; + +// -=*# Resource for function QUARTILE.EXC #*=- +const char* SC_OPCODE_QUARTILE_EXC_ARY[] = +{ + NC_("SC_OPCODE_QUARTILE_EXC", "Returns the quartile of a sample."), + NC_("SC_OPCODE_QUARTILE_EXC", "data"), + NC_("SC_OPCODE_QUARTILE_EXC", "The array of the data in the sample."), + NC_("SC_OPCODE_QUARTILE_EXC", "Type"), + NC_("SC_OPCODE_QUARTILE_EXC", "The type of the quartile (1 = 25%, 2 = 50%, 3 = 75%).") +}; + +// -=*# Resource for function QUARTILE.INC #*=- +const char* SC_OPCODE_QUARTILE_INC_ARY[] = +{ + NC_("SC_OPCODE_QUARTILE_INC", "Returns the quartile of a sample."), + NC_("SC_OPCODE_QUARTILE_INC", "data"), + NC_("SC_OPCODE_QUARTILE_INC", "The array of the data in the sample."), + NC_("SC_OPCODE_QUARTILE_INC", "Type"), + NC_("SC_OPCODE_QUARTILE_INC", "The type of the quartile (0 = MIN, 1 = 25%, 2 = 50%, 3 = 75%, 4 = MAX).") +}; + +// -=*# Resource for function LARGE #*=- +const char* SC_OPCODE_LARGE_ARY[] = +{ + NC_("SC_OPCODE_LARGE", "Returns the k-th largest value of a sample."), + NC_("SC_OPCODE_LARGE", "data"), + NC_("SC_OPCODE_LARGE", "The array of the data in the sample."), + NC_("SC_OPCODE_LARGE", "Rank_c"), + NC_("SC_OPCODE_LARGE", "The ranking of the value.") +}; + +// -=*# Resource for function SMALL #*=- +const char* SC_OPCODE_SMALL_ARY[] = +{ + NC_("SC_OPCODE_SMALL", "Returns the k-th smallest value of a sample."), + NC_("SC_OPCODE_SMALL", "data"), + NC_("SC_OPCODE_SMALL", "The array of the data in the sample."), + NC_("SC_OPCODE_SMALL", "Rank_c"), + NC_("SC_OPCODE_SMALL", "The ranking of the value.") +}; + +// -=*# Resource for function PERCENTRANK #*=- +const char* SC_OPCODE_PERCENT_RANK_ARY[] = +{ + NC_("SC_OPCODE_PERCENT_RANK", "Returns the percentage rank of a value in a sample."), + NC_("SC_OPCODE_PERCENT_RANK", "data"), + NC_("SC_OPCODE_PERCENT_RANK", "The array of the data in the sample."), + NC_("SC_OPCODE_PERCENT_RANK", "value"), + NC_("SC_OPCODE_PERCENT_RANK", "The value for which percentage ranking is to be determined."), + NC_("SC_OPCODE_PERCENT_RANK", "significance"), + NC_("SC_OPCODE_PERCENT_RANK", "The number of significant digits for the returned percentage: if omitted, a value of 3 is used.") +}; + +// -=*# Resource for function PERCENTRANK.EXC #*=- +const char* SC_OPCODE_PERCENT_RANK_EXC_ARY[] = +{ + NC_("SC_OPCODE_PERCENT_RANK_EXC", "Returns the percentage rank (0..1, exclusive) of a value in a sample."), + NC_("SC_OPCODE_PERCENT_RANK_EXC", "data"), + NC_("SC_OPCODE_PERCENT_RANK_EXC", "The array of the data in the sample."), + NC_("SC_OPCODE_PERCENT_RANK_EXC", "value"), + NC_("SC_OPCODE_PERCENT_RANK_EXC", "The value for which percentage ranking is to be determined."), + NC_("SC_OPCODE_PERCENT_RANK_EXC", "significance"), + NC_("SC_OPCODE_PERCENT_RANK_EXC", "The number of significant digits for the returned percentage: if omitted, a value of 3 is used.") +}; + +// -=*# Resource for function PERCENTRANK.INC #*=- +const char* SC_OPCODE_PERCENT_RANK_INC_ARY[] = +{ + NC_("SC_OPCODE_PERCENT_RANK_INC", "Returns the percentage rank (0..1, inclusive) of a value in a sample."), + NC_("SC_OPCODE_PERCENT_RANK_INC", "data"), + NC_("SC_OPCODE_PERCENT_RANK_INC", "The array of the data in the sample."), + NC_("SC_OPCODE_PERCENT_RANK_INC", "value"), + NC_("SC_OPCODE_PERCENT_RANK_INC", "The value for which percentage ranking is to be determined."), + NC_("SC_OPCODE_PERCENT_RANK_INC", "significance"), + NC_("SC_OPCODE_PERCENT_RANK_INC", "The number of significant digits for the returned percentage: if omitted, a value of 3 is used.") +}; + +// -=*# Resource for function RANK #*=- +const char* SC_OPCODE_RANK_ARY[] = +{ + NC_("SC_OPCODE_RANK", "Returns the ranking of a value in a sample."), + NC_("SC_OPCODE_RANK", "value"), + NC_("SC_OPCODE_RANK", "The value for which the rank is to be determined."), + NC_("SC_OPCODE_RANK", "Data"), + NC_("SC_OPCODE_RANK", "The array of the data in the sample."), + NC_("SC_OPCODE_RANK", "Type"), + NC_("SC_OPCODE_RANK", "Sequence order: 0 or omitted means descending, any other value than 0 means ascending.") +}; + +// -=*# Resource for function RANK.EQ #*=- +const char* SC_OPCODE_RANK_EQ_ARY[] = +{ + NC_("SC_OPCODE_RANK_EQ", "Returns the ranking of a value in a sample; if more than one value has the same rank, the top rank of that set of values is returned."), + NC_("SC_OPCODE_RANK_EQ", "value"), + NC_("SC_OPCODE_RANK_EQ", "The value for which the rank is to be determined."), + NC_("SC_OPCODE_RANK_EQ", "Data"), + NC_("SC_OPCODE_RANK_EQ", "The array of the data in the sample."), + NC_("SC_OPCODE_RANK_EQ", "Type"), + NC_("SC_OPCODE_RANK_EQ", "Sequence order: 0 or omitted means descending, any other value than 0 means ascending.") +}; + +// -=*# Resource for function RANK.AVG #*=- +const char* SC_OPCODE_RANK_AVG_ARY[] = +{ + NC_("SC_OPCODE_RANK_AVG", "Returns the ranking of a value in a sample; if more than one value has the same rank, the average rank is returned."), + NC_("SC_OPCODE_RANK_AVG", "value"), + NC_("SC_OPCODE_RANK_AVG", "The value for which the rank is to be determined."), + NC_("SC_OPCODE_RANK_AVG", "Data"), + NC_("SC_OPCODE_RANK_AVG", "The array of the data in the sample."), + NC_("SC_OPCODE_RANK_AVG", "Type"), + NC_("SC_OPCODE_RANK_AVG", "Sequence order: 0 or omitted means descending, any other value than 0 means ascending.") +}; + +// -=*# Resource for function TRIMMEAN #*=- +const char* SC_OPCODE_TRIM_MEAN_ARY[] = +{ + NC_("SC_OPCODE_TRIM_MEAN", "Returns the mean of a sample without including the marginal values."), + NC_("SC_OPCODE_TRIM_MEAN", "data"), + NC_("SC_OPCODE_TRIM_MEAN", "The array of the data in the sample."), + NC_("SC_OPCODE_TRIM_MEAN", "Alpha"), + NC_("SC_OPCODE_TRIM_MEAN", "The percentage of marginal data that is not to be taken into account.") +}; + +// -=*# Resource for function PROB #*=- +const char* SC_OPCODE_PROB_ARY[] = +{ + NC_("SC_OPCODE_PROB", "Returns the discrete probability of an interval."), + NC_("SC_OPCODE_PROB", "data"), + NC_("SC_OPCODE_PROB", "The sample data array."), + NC_("SC_OPCODE_PROB", "probability"), + NC_("SC_OPCODE_PROB", "The array of the associated probabilities."), + NC_("SC_OPCODE_PROB", "Start"), + NC_("SC_OPCODE_PROB", "The start of the value interval whose probabilities is to be totalled."), + NC_("SC_OPCODE_PROB", "End"), + NC_("SC_OPCODE_PROB", "The end of the value interval where the probabilities are to be totalled.") +}; + +// -=*# Resource for function B #*=- +const char* SC_OPCODE_B_ARY[] = +{ + NC_("SC_OPCODE_B", "Returns the probability of a trial result using binomial distribution."), + NC_("SC_OPCODE_B", "trials"), + NC_("SC_OPCODE_B", "The number of trials."), + NC_("SC_OPCODE_B", "SP"), + NC_("SC_OPCODE_B", "The individual probability of a trial result."), + NC_("SC_OPCODE_B", "T_1"), + NC_("SC_OPCODE_B", "Lower limit for the number of trials."), + NC_("SC_OPCODE_B", "T_2"), + NC_("SC_OPCODE_B", "Upper limit for the number of trials.") +}; + +// -=*# Resource for function PHI #*=- +const char* SC_OPCODE_PHI_ARY[] = +{ + NC_("SC_OPCODE_PHI", "Values of the distribution function for a standard normal distribution."), + NC_("SC_OPCODE_PHI", "number"), + NC_("SC_OPCODE_PHI", "The value for which the standard normal distribution is to be calculated.") +}; + +// -=*# Resource for function GAUSS #*=- +const char* SC_OPCODE_GAUSS_ARY[] = +{ + NC_("SC_OPCODE_GAUSS", "Returns the integral values of the standard normal cumulative distribution."), + NC_("SC_OPCODE_GAUSS", "Number"), + NC_("SC_OPCODE_GAUSS", "The value for which the integral value of the standard normal distribution is to be calculated.") +}; + +// -=*# Resource for function FISHER #*=- +const char* SC_OPCODE_FISHER_ARY[] = +{ + NC_("SC_OPCODE_FISHER", "Returns the Fisher transformation."), + NC_("SC_OPCODE_FISHER", "Number"), + NC_("SC_OPCODE_FISHER", "The value to be transformed (-1 < VALUE < 1).") +}; + +// -=*# Resource for function FISHERINV #*=- +const char* SC_OPCODE_FISHER_INV_ARY[] = +{ + NC_("SC_OPCODE_FISHER_INV", "Returns the inverse of the Fisher transformation."), + NC_("SC_OPCODE_FISHER_INV", "Number"), + NC_("SC_OPCODE_FISHER_INV", "The value that is to be transformed back.") +}; + +// -=*# Resource for function BINOMDIST #*=- +const char* SC_OPCODE_BINOM_DIST_ARY[] = +{ + NC_("SC_OPCODE_BINOM_DIST", "Values of the binomial distribution."), + NC_("SC_OPCODE_BINOM_DIST", "X"), + NC_("SC_OPCODE_BINOM_DIST", "The number of successes in a series of trials."), + NC_("SC_OPCODE_BINOM_DIST", "trials"), + NC_("SC_OPCODE_BINOM_DIST", "The total number of trials."), + NC_("SC_OPCODE_BINOM_DIST", "SP"), + NC_("SC_OPCODE_BINOM_DIST", "The success probability of a trial."), + NC_("SC_OPCODE_BINOM_DIST", "C"), + NC_("SC_OPCODE_BINOM_DIST", "Cumulated. C=0 calculates the individual probability, C=1 the cumulated probability.") +}; + +// -=*# Resource for function BINOM.DIST #*=- +const char* SC_OPCODE_BINOM_DIST_MS_ARY[] = +{ + NC_("SC_OPCODE_BINOM_DIST_MS", "Values of the binomial distribution."), + NC_("SC_OPCODE_BINOM_DIST_MS", "X"), + NC_("SC_OPCODE_BINOM_DIST_MS", "The number of successes in a series of trials."), + NC_("SC_OPCODE_BINOM_DIST_MS", "trials"), + NC_("SC_OPCODE_BINOM_DIST_MS", "The total number of trials."), + NC_("SC_OPCODE_BINOM_DIST_MS", "SP"), + NC_("SC_OPCODE_BINOM_DIST_MS", "The success probability of a trial."), + NC_("SC_OPCODE_BINOM_DIST_MS", "C"), + NC_("SC_OPCODE_BINOM_DIST_MS", "Cumulated. C=0 calculates the individual probability, C=1 the cumulated probability.") +}; + +// -=*# Resource for function NEGBINOMDIST #*=- +const char* SC_OPCODE_NEG_BINOM_VERT_ARY[] = +{ + NC_("SC_OPCODE_NEG_BINOM_VERT", "Values of the negative binomial distribution."), + NC_("SC_OPCODE_NEG_BINOM_VERT", "X"), + NC_("SC_OPCODE_NEG_BINOM_VERT", "The number of failures in the trial range."), + NC_("SC_OPCODE_NEG_BINOM_VERT", "R"), + NC_("SC_OPCODE_NEG_BINOM_VERT", "The number of successes in the trial sequence."), + NC_("SC_OPCODE_NEG_BINOM_VERT", "SP"), + NC_("SC_OPCODE_NEG_BINOM_VERT", "The success probability of a trial.") +}; + +// -=*# Resource for function NEGBINOM.DIST #*=- +const char* SC_OPCODE_NEG_BINOM_DIST_MS_ARY[] = +{ + NC_("SC_OPCODE_NEG_BINOM_DIST_MS", "Values of the negative binomial distribution."), + NC_("SC_OPCODE_NEG_BINOM_DIST_MS", "X"), + NC_("SC_OPCODE_NEG_BINOM_DIST_MS", "The number of failures in the trial range."), + NC_("SC_OPCODE_NEG_BINOM_DIST_MS", "R"), + NC_("SC_OPCODE_NEG_BINOM_DIST_MS", "The number of successes in the trial sequence."), + NC_("SC_OPCODE_NEG_BINOM_DIST_MS", "SP"), + NC_("SC_OPCODE_NEG_BINOM_DIST_MS", "The success probability of a trial."), + NC_("SC_OPCODE_NEG_BINOM_DIST_MS", "Cumulative"), + NC_("SC_OPCODE_NEG_BINOM_DIST_MS", "0 or FALSE calculates the probability density function. Any other value or TRUE calculates the cumulative distribution function.") +}; + +// -=*# Resource for function CRITBINOM #*=- +const char* SC_OPCODE_CRIT_BINOM_ARY[] = +{ + NC_("SC_OPCODE_CRIT_BINOM", "Returns the smallest value for which the cumulative binomial distribution is greater than or equal to a criterion value."), + NC_("SC_OPCODE_CRIT_BINOM", "trials"), + NC_("SC_OPCODE_CRIT_BINOM", "The total number of trials."), + NC_("SC_OPCODE_CRIT_BINOM", "SP"), + NC_("SC_OPCODE_CRIT_BINOM", "The success probability of a trial."), + NC_("SC_OPCODE_CRIT_BINOM", "alpha"), + NC_("SC_OPCODE_CRIT_BINOM", "The border probability that is attained or exceeded.") +}; + +// -=*# Resource for function BINOM.INV #*=- +const char* SC_OPCODE_BINOM_INV_ARY[] = +{ + NC_("SC_OPCODE_BINOM_INV", "Returns the smallest value for which the cumulative binomial distribution is greater than or equal to a criterion value."), + NC_("SC_OPCODE_BINOM_INV", "trials"), + NC_("SC_OPCODE_BINOM_INV", "The total number of trials."), + NC_("SC_OPCODE_BINOM_INV", "SP"), + NC_("SC_OPCODE_BINOM_INV", "The success probability of a trial."), + NC_("SC_OPCODE_BINOM_INV", "alpha"), + NC_("SC_OPCODE_BINOM_INV", "The border probability that is attained or exceeded.") +}; + +// -=*# Resource for function POISSON #*=- +const char* SC_OPCODE_POISSON_DIST_ARY[] = +{ + NC_("SC_OPCODE_POISSON_DIST", "Returns the Poisson distribution."), + NC_("SC_OPCODE_POISSON_DIST", "Number"), + NC_("SC_OPCODE_POISSON_DIST", "The value for which the Poisson distribution is to be calculated."), + NC_("SC_OPCODE_POISSON_DIST", "mean"), + NC_("SC_OPCODE_POISSON_DIST", "Mean. The mean value of the Poisson distribution."), + NC_("SC_OPCODE_POISSON_DIST", "Cumulative"), + NC_("SC_OPCODE_POISSON_DIST", "0 or FALSE calculates the probability density function. Any other value or TRUE or omitted calculates the cumulative distribution function.") +}; + +// -=*# Resource for function POISSON.DIST #*=- +const char* SC_OPCODE_POISSON_DIST_MS_ARY[] = +{ + NC_("SC_OPCODE_POISSON_DIST_MS", "Returns the Poisson distribution."), + NC_("SC_OPCODE_POISSON_DIST_MS", "Number"), + NC_("SC_OPCODE_POISSON_DIST_MS", "The value for which the Poisson distribution is to be calculated."), + NC_("SC_OPCODE_POISSON_DIST_MS", "mean"), + NC_("SC_OPCODE_POISSON_DIST_MS", "Mean. The mean value of the Poisson distribution."), + NC_("SC_OPCODE_POISSON_DIST_MS", "Cumulative"), + NC_("SC_OPCODE_POISSON_DIST_MS", "0 or FALSE calculates the probability density function. Any other value or TRUE or omitted calculates the cumulative distribution function.") +}; + +// -=*# Resource for function NORMDIST #*=- +const char* SC_OPCODE_NORM_DIST_ARY[] = +{ + NC_("SC_OPCODE_NORM_DIST", "Values of the normal distribution."), + NC_("SC_OPCODE_NORM_DIST", "Number"), + NC_("SC_OPCODE_NORM_DIST", "The value for which the normal distribution is to be calculated."), + NC_("SC_OPCODE_NORM_DIST", "Mean"), + NC_("SC_OPCODE_NORM_DIST", "The mean value. The mean value of the normal distribution."), + NC_("SC_OPCODE_NORM_DIST", "STDEV"), + NC_("SC_OPCODE_NORM_DIST", "Standard deviation. The standard deviation of the normal distribution."), + NC_("SC_OPCODE_NORM_DIST", "C"), + NC_("SC_OPCODE_NORM_DIST", "0 or FALSE calculates the probability density function. Any other value or TRUE or omitted calculates the cumulative distribution function.") +}; + +// -=*# Resource for function NORM.DIST #*=- +const char* SC_OPCODE_NORM_DIST_MS_ARY[] = +{ + NC_("SC_OPCODE_NORM_DIST_MS", "Values of the normal distribution."), + NC_("SC_OPCODE_NORM_DIST_MS", "Number"), + NC_("SC_OPCODE_NORM_DIST_MS", "The value for which the normal distribution is to be calculated."), + NC_("SC_OPCODE_NORM_DIST_MS", "Mean"), + NC_("SC_OPCODE_NORM_DIST_MS", "The mean value. The mean value of the normal distribution."), + NC_("SC_OPCODE_NORM_DIST_MS", "STDEV"), + NC_("SC_OPCODE_NORM_DIST_MS", "Standard deviation. The standard deviation of the normal distribution."), + NC_("SC_OPCODE_NORM_DIST_MS", "C"), + NC_("SC_OPCODE_NORM_DIST_MS", "0 or FALSE calculates the probability density function. Any other value or TRUE calculates the cumulative distribution function.") +}; + +// -=*# Resource for function NORMINV #*=- +const char* SC_OPCODE_NORM_INV_ARY[] = +{ + NC_("SC_OPCODE_NORM_INV", "Values of the inverse normal distribution."), + NC_("SC_OPCODE_NORM_INV", "number"), + NC_("SC_OPCODE_NORM_INV", "The probability value for which the inverse normal distribution is to be calculated."), + NC_("SC_OPCODE_NORM_INV", "mean"), + NC_("SC_OPCODE_NORM_INV", "The mean value. The mean value of the normal distribution."), + NC_("SC_OPCODE_NORM_INV", "STDEV"), + NC_("SC_OPCODE_NORM_INV", "Standard deviation. The standard deviation of the normal distribution.") +}; + +// -=*# Resource for function NORM.INV #*=- +const char* SC_OPCODE_NORM_INV_MS_ARY[] = +{ + NC_("SC_OPCODE_NORM_INV_MS", "Values of the inverse normal distribution."), + NC_("SC_OPCODE_NORM_INV_MS", "number"), + NC_("SC_OPCODE_NORM_INV_MS", "The probability value for which the inverse normal distribution is to be calculated."), + NC_("SC_OPCODE_NORM_INV_MS", "mean"), + NC_("SC_OPCODE_NORM_INV_MS", "The mean value. The mean value of the normal distribution."), + NC_("SC_OPCODE_NORM_INV_MS", "STDEV"), + NC_("SC_OPCODE_NORM_INV_MS", "Standard deviation. The standard deviation of the normal distribution.") +}; + +// -=*# Resource for function NORMSDIST #*=- +const char* SC_OPCODE_STD_NORM_DIST_ARY[] = +{ + NC_("SC_OPCODE_STD_NORM_DIST", "The values of the standard normal cumulative distribution."), + NC_("SC_OPCODE_STD_NORM_DIST", "Number"), + NC_("SC_OPCODE_STD_NORM_DIST", "The value for which the standard normal distribution is to be calculated.") +}; + +// -=*# Resource for function NORM.S.DIST #*=- +const char* SC_OPCODE_STD_NORM_DIST_MS_ARY[] = +{ + NC_("SC_OPCODE_STD_NORM_DIST_MS", "The values of the standard normal distribution."), + NC_("SC_OPCODE_STD_NORM_DIST_MS", "Number"), + NC_("SC_OPCODE_STD_NORM_DIST_MS", "The value for which the standard normal distribution is to be calculated."), + NC_("SC_OPCODE_STD_NORM_DIST_MS", "Cumulative"), + NC_("SC_OPCODE_STD_NORM_DIST_MS", "0 or FALSE calculates the probability density function. Any other value or TRUE calculates the cumulative distribution function.") +}; + +// -=*# Resource for function NORMSINV #*=- +const char* SC_OPCODE_S_NORM_INV_ARY[] = +{ + NC_("SC_OPCODE_S_NORM_INV", "Values of the inverse standard normal distribution."), + NC_("SC_OPCODE_S_NORM_INV", "number"), + NC_("SC_OPCODE_S_NORM_INV", "The probability value for which the inverse standard normal distribution is to be calculated.") +}; + +// -=*# Resource for function NORM.S.INV #*=- +const char* SC_OPCODE_S_NORM_INV_MS_ARY[] = +{ + NC_("SC_OPCODE_S_NORM_INV_MS", "Values of the inverse standard normal distribution."), + NC_("SC_OPCODE_S_NORM_INV_MS", "number"), + NC_("SC_OPCODE_S_NORM_INV_MS", "The probability value for which the inverse standard normal distribution is to be calculated.") +}; + +// -=*# Resource for function LOGNORMDIST #*=- +const char* SC_OPCODE_LOG_NORM_DIST_ARY[] = +{ + NC_("SC_OPCODE_LOG_NORM_DIST", "Values of the log normal distribution."), + NC_("SC_OPCODE_LOG_NORM_DIST", "Number"), + NC_("SC_OPCODE_LOG_NORM_DIST", "The value for which the log normal distribution is to be calculated."), + NC_("SC_OPCODE_LOG_NORM_DIST", "mean"), + NC_("SC_OPCODE_LOG_NORM_DIST", "The mean value of the log normal distribution. It is set to 0 if omitted."), + NC_("SC_OPCODE_LOG_NORM_DIST", "STDEV"), + NC_("SC_OPCODE_LOG_NORM_DIST", "The standard deviation of the log normal distribution. It is set to 1 if omitted."), + NC_("SC_OPCODE_LOG_NORM_DIST", "Cumulative"), + NC_("SC_OPCODE_LOG_NORM_DIST", "0 or FALSE calculates the probability density function. Any other value or TRUE or omitted calculates the cumulative distribution function.") +}; + +// -=*# Resource for function LOGNORM.DIST #*=- +const char* SC_OPCODE_LOG_NORM_DIST_MS_ARY[] = +{ + NC_("SC_OPCODE_LOG_NORM_DIST_MS", "Values of the log normal distribution."), + NC_("SC_OPCODE_LOG_NORM_DIST_MS", "Number"), + NC_("SC_OPCODE_LOG_NORM_DIST_MS", "The value for which the log normal distribution is to be calculated."), + NC_("SC_OPCODE_LOG_NORM_DIST_MS", "mean"), + NC_("SC_OPCODE_LOG_NORM_DIST_MS", "The mean value of the log normal distribution."), + NC_("SC_OPCODE_LOG_NORM_DIST_MS", "STDEV"), + NC_("SC_OPCODE_LOG_NORM_DIST_MS", "The standard deviation of the log normal distribution."), + NC_("SC_OPCODE_LOG_NORM_DIST_MS", "Cumulative"), + NC_("SC_OPCODE_LOG_NORM_DIST_MS", "0 or FALSE calculates the probability density function. Any other value or TRUE calculates the cumulative distribution function.") +}; + +// -=*# Resource for function LOGINV #*=- +const char* SC_OPCODE_LOG_INV_ARY[] = +{ + NC_("SC_OPCODE_LOG_INV", "Values of the inverse of the lognormal distribution."), + NC_("SC_OPCODE_LOG_INV", "number"), + NC_("SC_OPCODE_LOG_INV", "The probability value for which the inverse log normal distribution is to be calculated."), + NC_("SC_OPCODE_LOG_INV", "mean"), + NC_("SC_OPCODE_LOG_INV", "Mean value. The mean value of the log normal distribution."), + NC_("SC_OPCODE_LOG_INV", "STDEV"), + NC_("SC_OPCODE_LOG_INV", "Standard deviation. The standard deviation of the log normal distribution.") +}; + +// -=*# Resource for function LOGNORM.INV #*=- +const char* SC_OPCODE_LOG_INV_MS_ARY[] = +{ + NC_("SC_OPCODE_LOG_INV_MS", "Values of the inverse of the lognormal distribution."), + NC_("SC_OPCODE_LOG_INV_MS", "number"), + NC_("SC_OPCODE_LOG_INV_MS", "The probability value for which the inverse log normal distribution is to be calculated."), + NC_("SC_OPCODE_LOG_INV_MS", "mean"), + NC_("SC_OPCODE_LOG_INV_MS", "Mean value. The mean value of the log normal distribution."), + NC_("SC_OPCODE_LOG_INV_MS", "STDEV"), + NC_("SC_OPCODE_LOG_INV_MS", "Standard deviation. The standard deviation of the log normal distribution.") +}; + +// -=*# Resource for function EXPONDIST #*=- +const char* SC_OPCODE_EXP_DIST_ARY[] = +{ + NC_("SC_OPCODE_EXP_DIST", "Values of the exponential distribution."), + NC_("SC_OPCODE_EXP_DIST", "Number"), + NC_("SC_OPCODE_EXP_DIST", "The value to which the exponential distribution is to be calculated."), + NC_("SC_OPCODE_EXP_DIST", "lambda"), + NC_("SC_OPCODE_EXP_DIST", "The parameters of the exponential distribution."), + NC_("SC_OPCODE_EXP_DIST", "C"), + NC_("SC_OPCODE_EXP_DIST", "Cumulated. C=0 calculates the density function, C=1 the distribution.") +}; + +// -=*# Resource for function EXPON.DIST #*=- +const char* SC_OPCODE_EXP_DIST_MS_ARY[] = +{ + NC_("SC_OPCODE_EXP_DIST_MS", "Values of the exponential distribution."), + NC_("SC_OPCODE_EXP_DIST_MS", "Number"), + NC_("SC_OPCODE_EXP_DIST_MS", "The value to which the exponential distribution is to be calculated."), + NC_("SC_OPCODE_EXP_DIST_MS", "lambda"), + NC_("SC_OPCODE_EXP_DIST_MS", "The parameters of the exponential distribution."), + NC_("SC_OPCODE_EXP_DIST_MS", "C"), + NC_("SC_OPCODE_EXP_DIST_MS", "Cumulated. C=0 calculates the density function, C=1 the distribution.") +}; + +// -=*# Resource for function GAMMADIST #*=- +const char* SC_OPCODE_GAMMA_DIST_ARY[] = +{ + NC_("SC_OPCODE_GAMMA_DIST", "Returns the value of the probability density function or the cumulative distribution function for the Gamma distribution."), + NC_("SC_OPCODE_GAMMA_DIST", "Number"), + NC_("SC_OPCODE_GAMMA_DIST", "The value for which the gamma distribution is to be calculated."), + NC_("SC_OPCODE_GAMMA_DIST", "alpha"), + NC_("SC_OPCODE_GAMMA_DIST", "The Alpha parameter of the Gamma distribution."), + NC_("SC_OPCODE_GAMMA_DIST", "beta"), + NC_("SC_OPCODE_GAMMA_DIST", "The Beta parameter of the Gamma distribution."), + NC_("SC_OPCODE_GAMMA_DIST", "Cumulative"), + NC_("SC_OPCODE_GAMMA_DIST", "0 or FALSE calculates the probability density function. Any other value or TRUE or omitted calculates the cumulative distribution function.") +}; + +// -=*# Resource for function GAMMA.DIST #*=- +const char* SC_OPCODE_GAMMA_DIST_MS_ARY[] = +{ + NC_("SC_OPCODE_GAMMA_DIST_MS", "Returns the value of the probability density function or the cumulative distribution function for the Gamma distribution."), + NC_("SC_OPCODE_GAMMA_DIST_MS", "Number"), + NC_("SC_OPCODE_GAMMA_DIST_MS", "The value for which the gamma distribution is to be calculated."), + NC_("SC_OPCODE_GAMMA_DIST_MS", "alpha"), + NC_("SC_OPCODE_GAMMA_DIST_MS", "The Alpha parameter of the Gamma distribution."), + NC_("SC_OPCODE_GAMMA_DIST_MS", "beta"), + NC_("SC_OPCODE_GAMMA_DIST_MS", "The Beta parameter of the Gamma distribution."), + NC_("SC_OPCODE_GAMMA_DIST_MS", "Cumulative"), + NC_("SC_OPCODE_GAMMA_DIST_MS", "0 or FALSE calculates the probability density function. Any other value or TRUE calculates the cumulative distribution function.") +}; + +// -=*# Resource for function GAMMAINV #*=- +const char* SC_OPCODE_GAMMA_INV_ARY[] = +{ + NC_("SC_OPCODE_GAMMA_INV", "Values of the inverse gamma distribution."), + NC_("SC_OPCODE_GAMMA_INV", "Number"), + NC_("SC_OPCODE_GAMMA_INV", "The probability value for which the inverse gamma distribution is to be calculated."), + NC_("SC_OPCODE_GAMMA_INV", "alpha"), + NC_("SC_OPCODE_GAMMA_INV", "The Alpha (shape) parameter of the Gamma distribution."), + NC_("SC_OPCODE_GAMMA_INV", "beta"), + NC_("SC_OPCODE_GAMMA_INV", "The Beta (scale) parameter of the Gamma distribution.") +}; + +// -=*# Resource for function GAMMA.INV #*=- +const char* SC_OPCODE_GAMMA_INV_MS_ARY[] = +{ + NC_("SC_OPCODE_GAMMA_INV_MS", "Values of the inverse gamma distribution."), + NC_("SC_OPCODE_GAMMA_INV_MS", "Number"), + NC_("SC_OPCODE_GAMMA_INV_MS", "The probability value for which the inverse gamma distribution is to be calculated."), + NC_("SC_OPCODE_GAMMA_INV_MS", "alpha"), + NC_("SC_OPCODE_GAMMA_INV_MS", "The Alpha (shape) parameter of the Gamma distribution."), + NC_("SC_OPCODE_GAMMA_INV_MS", "beta"), + NC_("SC_OPCODE_GAMMA_INV_MS", "The Beta (scale) parameter of the Gamma distribution.") +}; + +// -=*# Resource for function GAMMALN #*=- +const char* SC_OPCODE_GAMMA_LN_ARY[] = +{ + NC_("SC_OPCODE_GAMMA_LN", "Returns the natural logarithm of the gamma function."), + NC_("SC_OPCODE_GAMMA_LN", "Number"), + NC_("SC_OPCODE_GAMMA_LN", "The value for which the natural logarithm of the gamma function is to be calculated.") +}; + +// -=*# Resource for function GAMMALN.PRECISE #*=- +const char* SC_OPCODE_GAMMA_LN_MS_ARY[] = +{ + NC_("SC_OPCODE_GAMMA_LN_MS", "Returns the natural logarithm of the gamma function."), + NC_("SC_OPCODE_GAMMA_LN_MS", "Number"), + NC_("SC_OPCODE_GAMMA_LN_MS", "The value for which the natural logarithm of the gamma function is to be calculated.") +}; + + +// -=*# Resource for function GAMMA #*=- +const char* SC_OPCODE_GAMMA_ARY[] = +{ + NC_("SC_OPCODE_GAMMA", "Returns the value of the Gamma function."), + NC_("SC_OPCODE_GAMMA", "Number"), + NC_("SC_OPCODE_GAMMA", "The value for which the Gamma function is to be calculated.") +}; + + +// -=*# Resource for function BETADIST #*=- +const char* SC_OPCODE_BETA_DIST_ARY[] = +{ + NC_("SC_OPCODE_BETA_DIST", "Values of the beta distribution."), + NC_("SC_OPCODE_BETA_DIST", "number"), + NC_("SC_OPCODE_BETA_DIST", "The value for which the beta distribution is to be calculated."), + NC_("SC_OPCODE_BETA_DIST", "alpha"), + NC_("SC_OPCODE_BETA_DIST", "The Alpha parameter of the Beta distribution."), + NC_("SC_OPCODE_BETA_DIST", "beta"), + NC_("SC_OPCODE_BETA_DIST", "The Beta parameter of the Beta distribution."), + NC_("SC_OPCODE_BETA_DIST", "Start"), + NC_("SC_OPCODE_BETA_DIST", "The starting value for the value interval of the distribution."), + NC_("SC_OPCODE_BETA_DIST", "End"), + NC_("SC_OPCODE_BETA_DIST", "The final value for the value interval of the distribution."), + NC_("SC_OPCODE_BETA_DIST", "Cumulative"), + NC_("SC_OPCODE_BETA_DIST", "0 or FALSE for probability density function, any other value or TRUE or omitted for cumulative distribution function.") +}; + +// -=*# Resource for function BETAINV #*=- +const char* SC_OPCODE_BETA_INV_ARY[] = +{ + NC_("SC_OPCODE_BETA_INV", "Values of the inverse beta distribution."), + NC_("SC_OPCODE_BETA_INV", "number"), + NC_("SC_OPCODE_BETA_INV", "The probability value for which the inverse beta distribution is to be calculated."), + NC_("SC_OPCODE_BETA_INV", "alpha"), + NC_("SC_OPCODE_BETA_INV", "The Alpha parameter of the Beta distribution."), + NC_("SC_OPCODE_BETA_INV", "beta"), + NC_("SC_OPCODE_BETA_INV", "The Beta parameter of the Beta distribution."), + NC_("SC_OPCODE_BETA_INV", "Start"), + NC_("SC_OPCODE_BETA_INV", "The starting value for the value interval of the distribution."), + NC_("SC_OPCODE_BETA_INV", "End"), + NC_("SC_OPCODE_BETA_INV", "The final value for the value interval of the distribution.") +}; + +// -=*# Resource for function BETA.DIST #*=- +const char* SC_OPCODE_BETA_DIST_MS_ARY[] = +{ + NC_("SC_OPCODE_BETA_DIST_MS", "Values of the beta distribution."), + NC_("SC_OPCODE_BETA_DIST_MS", "number"), + NC_("SC_OPCODE_BETA_DIST_MS", "The value for which the beta distribution is to be calculated."), + NC_("SC_OPCODE_BETA_DIST_MS", "alpha"), + NC_("SC_OPCODE_BETA_DIST_MS", "The Alpha parameter of the Beta distribution."), + NC_("SC_OPCODE_BETA_DIST_MS", "beta"), + NC_("SC_OPCODE_BETA_DIST_MS", "The Beta parameter of the Beta distribution."), + NC_("SC_OPCODE_BETA_DIST_MS", "Cumulative"), + NC_("SC_OPCODE_BETA_DIST_MS", "0 or FALSE for probability density function, any other value or TRUE or omitted for cumulative distribution function."), + NC_("SC_OPCODE_BETA_DIST_MS", "Start"), + NC_("SC_OPCODE_BETA_DIST_MS", "The starting value for the value interval of the distribution."), + NC_("SC_OPCODE_BETA_DIST_MS", "End"), + NC_("SC_OPCODE_BETA_DIST_MS", "The final value for the value interval of the distribution.") +}; + +// -=*# Resource for function BETA.INV #*=- +const char* SC_OPCODE_BETA_INV_MS_ARY[] = +{ + NC_("SC_OPCODE_BETA_INV_MS", "Values of the inverse beta distribution."), + NC_("SC_OPCODE_BETA_INV_MS", "number"), + NC_("SC_OPCODE_BETA_INV_MS", "The probability value for which the inverse beta distribution is to be calculated."), + NC_("SC_OPCODE_BETA_INV_MS", "alpha"), + NC_("SC_OPCODE_BETA_INV_MS", "The Alpha parameter of the Beta distribution."), + NC_("SC_OPCODE_BETA_INV_MS", "beta"), + NC_("SC_OPCODE_BETA_INV_MS", "The Beta parameter of the Beta distribution."), + NC_("SC_OPCODE_BETA_INV_MS", "Start"), + NC_("SC_OPCODE_BETA_INV_MS", "The starting value for the value interval of the distribution."), + NC_("SC_OPCODE_BETA_INV_MS", "End"), + NC_("SC_OPCODE_BETA_INV_MS", "The final value for the value interval of the distribution.") +}; + +// -=*# Resource for function WEIBULL #*=- +const char* SC_OPCODE_WEIBULL_ARY[] = +{ + NC_("SC_OPCODE_WEIBULL", "Returns the values of the Weibull distribution."), + NC_("SC_OPCODE_WEIBULL", "Number"), + NC_("SC_OPCODE_WEIBULL", "The value for which the Weibull distribution is to be calculated."), + NC_("SC_OPCODE_WEIBULL", "Alpha"), + NC_("SC_OPCODE_WEIBULL", "The Alpha parameter of the Weibull distribution."), + NC_("SC_OPCODE_WEIBULL", "beta"), + NC_("SC_OPCODE_WEIBULL", "The Beta parameter of the Weibull distribution."), + NC_("SC_OPCODE_WEIBULL", "C"), + NC_("SC_OPCODE_WEIBULL", "Cumulated. C=0 calculates the density function, C=1 the distribution.") +}; + +// -=*# Resource for function WEIBULL.DIST #*=- +const char* SC_OPCODE_WEIBULL_MS_ARY[] = +{ + NC_("SC_OPCODE_WEIBULL_MS", "Returns the values of the Weibull distribution."), + NC_("SC_OPCODE_WEIBULL_MS", "Number"), + NC_("SC_OPCODE_WEIBULL_MS", "The value for which the Weibull distribution is to be calculated."), + NC_("SC_OPCODE_WEIBULL_MS", "Alpha"), + NC_("SC_OPCODE_WEIBULL_MS", "The Alpha parameter of the Weibull distribution."), + NC_("SC_OPCODE_WEIBULL_MS", "beta"), + NC_("SC_OPCODE_WEIBULL_MS", "The Beta parameter of the Weibull distribution."), + NC_("SC_OPCODE_WEIBULL_MS", "C"), + NC_("SC_OPCODE_WEIBULL_MS", "Cumulated. C=0 calculates the density function, C=1 the distribution.") +}; + +// -=*# Resource for function HYPGEOMDIST #*=- +const char* SC_OPCODE_HYP_GEOM_DIST_ARY[] = +{ + NC_("SC_OPCODE_HYP_GEOM_DIST", "Values of the hypergeometric distribution."), + NC_("SC_OPCODE_HYP_GEOM_DIST", "X"), + NC_("SC_OPCODE_HYP_GEOM_DIST", "The number of successes in the sample."), + NC_("SC_OPCODE_HYP_GEOM_DIST", "n_sample"), + NC_("SC_OPCODE_HYP_GEOM_DIST", "The size of the sample."), + NC_("SC_OPCODE_HYP_GEOM_DIST", "successes"), + NC_("SC_OPCODE_HYP_GEOM_DIST", "The number of successes in the population."), + NC_("SC_OPCODE_HYP_GEOM_DIST", "n_population"), + NC_("SC_OPCODE_HYP_GEOM_DIST", "The population size."), + NC_("SC_OPCODE_HYP_GEOM_DIST", "Cumulative"), + NC_("SC_OPCODE_HYP_GEOM_DIST", "Cumulated. TRUE calculates the cumulative distribution function, FALSE the probability mass function.") +}; + +// -=*# Resource for function HYPGEOM.DIST #*=- +const char* SC_OPCODE_HYP_GEOM_DIST_MS_ARY[] = +{ + NC_("SC_OPCODE_HYP_GEOM_DIST_MS", "Values of the hypergeometric distribution."), + NC_("SC_OPCODE_HYP_GEOM_DIST_MS", "X"), + NC_("SC_OPCODE_HYP_GEOM_DIST_MS", "The number of successes in the sample."), + NC_("SC_OPCODE_HYP_GEOM_DIST_MS", "n_sample"), + NC_("SC_OPCODE_HYP_GEOM_DIST_MS", "The size of the sample."), + NC_("SC_OPCODE_HYP_GEOM_DIST_MS", "successes"), + NC_("SC_OPCODE_HYP_GEOM_DIST_MS", "The number of successes in the population."), + NC_("SC_OPCODE_HYP_GEOM_DIST_MS", "n_population"), + NC_("SC_OPCODE_HYP_GEOM_DIST_MS", "The population size."), + NC_("SC_OPCODE_HYP_GEOM_DIST_MS", "Cumulative"), + NC_("SC_OPCODE_HYP_GEOM_DIST_MS", "Cumulated. TRUE calculates the cumulative distribution function, FALSE the probability mass function.") +}; + +// -=*# Resource for function TDIST #*=- +const char* SC_OPCODE_T_DIST_ARY[] = +{ + NC_("SC_OPCODE_T_DIST", "Returns the t-distribution."), + NC_("SC_OPCODE_T_DIST", "Number"), + NC_("SC_OPCODE_T_DIST", "The value for which the T distribution is to be calculated."), + NC_("SC_OPCODE_T_DIST", "degrees_freedom"), + NC_("SC_OPCODE_T_DIST", "The degrees of freedom of the T distribution."), + NC_("SC_OPCODE_T_DIST", "mode"), + NC_("SC_OPCODE_T_DIST", "Mode = 1 calculates the one-tailed test, 2 = two-tailed distribution.") +}; + +// -=*# Resource for function T.DIST.2T #*=- +const char* SC_OPCODE_T_DIST_2T_ARY[] = +{ + NC_("SC_OPCODE_T_DIST_2T", "Returns the two-tailed t-distribution."), + NC_("SC_OPCODE_T_DIST_2T", "Number"), + NC_("SC_OPCODE_T_DIST_2T", "The value for which the T distribution is to be calculated."), + NC_("SC_OPCODE_T_DIST_2T", "degrees_freedom"), + NC_("SC_OPCODE_T_DIST_2T", "The degrees of freedom of the T distribution.") +}; + +// -=*# Resource for function T.DIST #*=- +const char* SC_OPCODE_T_DIST_MS_ARY[] = +{ + NC_("SC_OPCODE_T_DIST_MS", "Returns the t-distribution."), + NC_("SC_OPCODE_T_DIST_MS", "Number"), + NC_("SC_OPCODE_T_DIST_MS", "The value for which the T distribution is to be calculated."), + NC_("SC_OPCODE_T_DIST_MS", "degrees_freedom"), + NC_("SC_OPCODE_T_DIST_MS", "The degrees of freedom of the T distribution."), + NC_("SC_OPCODE_T_DIST_MS", "cumulative"), + NC_("SC_OPCODE_T_DIST_MS", "True calculates the cumulative distribution function, false the probability density function.") +}; + +// -=*# Resource for function T.DIST.RT #*=- +const char* SC_OPCODE_T_DIST_RT_ARY[] = +{ + NC_("SC_OPCODE_T_DIST_RT", "Returns the right-tailed t-distribution."), + NC_("SC_OPCODE_T_DIST_RT", "Number"), + NC_("SC_OPCODE_T_DIST_RT", "The value for which the T distribution is to be calculated."), + NC_("SC_OPCODE_T_DIST_RT", "degrees_freedom"), + NC_("SC_OPCODE_T_DIST_RT", "The degrees of freedom of the T distribution.") +}; + +// -=*# Resource for function TINV #*=- +const char* SC_OPCODE_T_INV_ARY[] = +{ + NC_("SC_OPCODE_T_INV", "Values of the inverse t-distribution."), + NC_("SC_OPCODE_T_INV", "number"), + NC_("SC_OPCODE_T_INV", "The probability value for which the inverse T distribution is to be calculated."), + NC_("SC_OPCODE_T_INV", "degrees_freedom"), + NC_("SC_OPCODE_T_INV", "The degrees of freedom of the T distribution.") +}; + +// -=*# Resource for function T.INV #*=- +const char* SC_OPCODE_T_INV_MS_ARY[] = +{ + NC_("SC_OPCODE_T_INV_MS", "Values of the left-tailed inverse t-distribution."), + NC_("SC_OPCODE_T_INV_MS", "number"), + NC_("SC_OPCODE_T_INV_MS", "The probability value for which the inverse T distribution is to be calculated."), + NC_("SC_OPCODE_T_INV_MS", "degrees_freedom"), + NC_("SC_OPCODE_T_INV_MS", "The degrees of freedom of the T distribution.") +}; + +// -=*# Resource for function T.INV.2T #*=- +const char* SC_OPCODE_T_INV_2T_ARY[] = +{ + NC_("SC_OPCODE_T_INV_2T", "Values of the two-tailed inverse t-distribution."), + NC_("SC_OPCODE_T_INV_2T", "number"), + NC_("SC_OPCODE_T_INV_2T", "The probability value for which the inverse T distribution is to be calculated."), + NC_("SC_OPCODE_T_INV_2T", "degrees_freedom"), + NC_("SC_OPCODE_T_INV_2T", "The degrees of freedom of the T distribution.") +}; + +// -=*# Resource for function FDIST #*=- +const char* SC_OPCODE_F_DIST_ARY[] = +{ + NC_("SC_OPCODE_F_DIST", "Values of the F probability distribution."), + NC_("SC_OPCODE_F_DIST", "Number"), + NC_("SC_OPCODE_F_DIST", "The value for which the F distribution is to be calculated."), + NC_("SC_OPCODE_F_DIST", "degrees_freedom_1"), + NC_("SC_OPCODE_F_DIST", "The degrees of freedom in the numerator of the F distribution."), + NC_("SC_OPCODE_F_DIST", "degrees_freedom_2"), + NC_("SC_OPCODE_F_DIST", "The degrees of freedom in the denominator of the F distribution.") +}; + +// -=*# Resource for function F.DIST #*=- +const char* SC_OPCODE_F_DIST_LT_ARY[] = +{ + NC_("SC_OPCODE_F_DIST_LT", "Values of the left tail F probability distribution."), + NC_("SC_OPCODE_F_DIST_LT", "Number"), + NC_("SC_OPCODE_F_DIST_LT", "The value for which the F distribution is to be calculated."), + NC_("SC_OPCODE_F_DIST_LT", "degrees_freedom_1"), + NC_("SC_OPCODE_F_DIST_LT", "The degrees of freedom in the numerator of the F distribution."), + NC_("SC_OPCODE_F_DIST_LT", "degrees_freedom_2"), + NC_("SC_OPCODE_F_DIST_LT", "The degrees of freedom in the denominator of the F distribution."), + NC_("SC_OPCODE_F_DIST_LT", "cumulative"), + NC_("SC_OPCODE_F_DIST_LT", "Cumulative distribution function (TRUE) or probability density function (FALSE).") +}; + +// -=*# Resource for function F.DIST.RT #*=- +const char* SC_OPCODE_F_DIST_RT_ARY[] = +{ + NC_("SC_OPCODE_F_DIST_RT", "Values of the right tail F probability distribution."), + NC_("SC_OPCODE_F_DIST_RT", "Number"), + NC_("SC_OPCODE_F_DIST_RT", "The value for which the F distribution is to be calculated."), + NC_("SC_OPCODE_F_DIST_RT", "degrees_freedom_1"), + NC_("SC_OPCODE_F_DIST_RT", "The degrees of freedom in the numerator of the F distribution."), + NC_("SC_OPCODE_F_DIST_RT", "degrees_freedom_2"), + NC_("SC_OPCODE_F_DIST_RT", "The degrees of freedom in the denominator of the F distribution.") +}; + +// -=*# Resource for function FINV #*=- +const char* SC_OPCODE_F_INV_ARY[] = +{ + NC_("SC_OPCODE_F_INV", "Values of the inverse F distribution."), + NC_("SC_OPCODE_F_INV", "number"), + NC_("SC_OPCODE_F_INV", "The probability value for which the inverse F distribution is to be calculated."), + NC_("SC_OPCODE_F_INV", "degrees_freedom_1"), + NC_("SC_OPCODE_F_INV", "The degrees of freedom in the numerator of the F distribution."), + NC_("SC_OPCODE_F_INV", "degrees_freedom_2"), + NC_("SC_OPCODE_F_INV", "The degrees of freedom in the denominator of the F distribution.") +}; + +// -=*# Resource for function F.INV #*=- +const char* SC_OPCODE_F_INV_LT_ARY[] = +{ + NC_("SC_OPCODE_F_INV_LT", "Values of the inverse left tail F distribution."), + NC_("SC_OPCODE_F_INV_LT", "number"), + NC_("SC_OPCODE_F_INV_LT", "The probability value for which the inverse F distribution is to be calculated."), + NC_("SC_OPCODE_F_INV_LT", "degrees_freedom_1"), + NC_("SC_OPCODE_F_INV_LT", "The degrees of freedom in the numerator of the F distribution."), + NC_("SC_OPCODE_F_INV_LT", "degrees_freedom_2"), + NC_("SC_OPCODE_F_INV_LT", "The degrees of freedom in the denominator of the F distribution.") +}; + +// -=*# Resource for function F.INV.RT #*=- +const char* SC_OPCODE_F_INV_RT_ARY[] = +{ + NC_("SC_OPCODE_F_INV_RT", "Values of the inverse right tail F distribution."), + NC_("SC_OPCODE_F_INV_RT", "number"), + NC_("SC_OPCODE_F_INV_RT", "The probability value for which the inverse F distribution is to be calculated."), + NC_("SC_OPCODE_F_INV_RT", "degrees_freedom_1"), + NC_("SC_OPCODE_F_INV_RT", "The degrees of freedom in the numerator of the F distribution."), + NC_("SC_OPCODE_F_INV_RT", "degrees_freedom_2"), + NC_("SC_OPCODE_F_INV_RT", "The degrees of freedom in the denominator of the F distribution.") +}; + +// -=*# Resource for function CHIDIST #*=- +const char* SC_OPCODE_CHI_DIST_ARY[] = +{ + NC_("SC_OPCODE_CHI_DIST", "Returns the right-tail probability of the chi-square distribution."), + NC_("SC_OPCODE_CHI_DIST", "Number"), + NC_("SC_OPCODE_CHI_DIST", "The value for which the chi square distribution is to be calculated."), + NC_("SC_OPCODE_CHI_DIST", "degrees_freedom"), + NC_("SC_OPCODE_CHI_DIST", "The degrees of freedom of the chi square distribution.") +}; + +// -=*# Resource for function CHISQ.DIST.RT #*=- +const char* SC_OPCODE_CHI_DIST_MS_ARY[] = +{ + NC_("SC_OPCODE_CHI_DIST_MS", "Returns the right-tail probability of the chi-square distribution."), + NC_("SC_OPCODE_CHI_DIST_MS", "Number"), + NC_("SC_OPCODE_CHI_DIST_MS", "The value for which the chi square distribution is to be calculated."), + NC_("SC_OPCODE_CHI_DIST_MS", "degrees_freedom"), + NC_("SC_OPCODE_CHI_DIST_MS", "The degrees of freedom of the chi square distribution.") +}; + + +// -=*# Resource for function CHISQDIST #*=- +const char* SC_OPCODE_CHISQ_DIST_ARY[] = +{ + NC_("SC_OPCODE_CHISQ_DIST", "Returns left-tail probability of the cumulative distribution function or values of the probability density function of the chi-square distribution."), + NC_("SC_OPCODE_CHISQ_DIST", "Number"), + NC_("SC_OPCODE_CHISQ_DIST", "The value for which the probability density function or cumulative distribution function is to be calculated."), + NC_("SC_OPCODE_CHISQ_DIST", "Degrees of Freedom"), + NC_("SC_OPCODE_CHISQ_DIST", "The degrees of freedom of the chi-square distribution."), + NC_("SC_OPCODE_CHISQ_DIST", "Cumulative"), + NC_("SC_OPCODE_CHISQ_DIST", "0 or FALSE calculates the probability density function. Any other value or TRUE or omitted calculates the cumulative distribution function.") +}; + + +// -=*# Resource for function CHISQ.DIST #*=- +const char* SC_OPCODE_CHISQ_DIST_MS_ARY[] = +{ + NC_("SC_OPCODE_CHISQ_DIST_MS", "Returns left-tail probability of the cumulative distribution function or values of the probability density function of the chi-square distribution."), + NC_("SC_OPCODE_CHISQ_DIST_MS", "Number"), + NC_("SC_OPCODE_CHISQ_DIST_MS", "The value for which the probability density function or cumulative distribution function is to be calculated."), + NC_("SC_OPCODE_CHISQ_DIST_MS", "Degrees of Freedom"), + NC_("SC_OPCODE_CHISQ_DIST_MS", "The degrees of freedom of the chi-square distribution."), + NC_("SC_OPCODE_CHISQ_DIST_MS", "Cumulative"), + NC_("SC_OPCODE_CHISQ_DIST_MS", "0 or FALSE calculates the probability density function. Any other value or TRUE calculates the cumulative distribution function.") +}; + + +// -=*# Resource for function CHIINV #*=- +const char* SC_OPCODE_CHI_INV_ARY[] = +{ + NC_("SC_OPCODE_CHI_INV", "Values of the inverse of CHIDIST(x; DegreesOfFreedom)."), + NC_("SC_OPCODE_CHI_INV", "number"), + NC_("SC_OPCODE_CHI_INV", "The probability value for which the inverse chi square distribution is to be calculated."), + NC_("SC_OPCODE_CHI_INV", "degrees_freedom"), + NC_("SC_OPCODE_CHI_INV", "The degrees of freedom of the chi square distribution.") +}; + + +// -=*# Resource for function CHISQ.INV.RT #*=- +const char* SC_OPCODE_CHI_INV_MS_ARY[] = +{ + NC_("SC_OPCODE_CHI_INV_MS", "Values of the inverse of CHIDIST(x; DegreesOfFreedom)."), + NC_("SC_OPCODE_CHI_INV_MS", "number"), + NC_("SC_OPCODE_CHI_INV_MS", "The probability value for which the inverse chi square distribution is to be calculated."), + NC_("SC_OPCODE_CHI_INV_MS", "degrees_freedom"), + NC_("SC_OPCODE_CHI_INV_MS", "The degrees of freedom of the chi square distribution.") +}; + + +// -=*# Resource for function CHISQINV #*=- +const char* SC_OPCODE_CHISQ_INV_ARY[] = +{ + NC_("SC_OPCODE_CHISQ_INV", "Values of the inverse of CHISQDIST(x;DegreesOfFreedom;TRUE())."), + NC_("SC_OPCODE_CHISQ_INV", "Probability"), + NC_("SC_OPCODE_CHISQ_INV", "The probability value for which the inverse of the chi square distribution is to be calculated."), + NC_("SC_OPCODE_CHISQ_INV", "Degrees of Freedom"), + NC_("SC_OPCODE_CHISQ_INV", "The degrees of freedom of the chi square distribution.") +}; + + +// -=*# Resource for function CHISQ.INV #*=- +const char* SC_OPCODE_CHISQ_INV_MS_ARY[] = +{ + NC_("SC_OPCODE_CHISQ_INV_MS", "Values of the inverse of CHISQ.DIST(x;DegreesOfFreedom;TRUE())."), + NC_("SC_OPCODE_CHISQ_INV_MS", "Probability"), + NC_("SC_OPCODE_CHISQ_INV_MS", "The probability value for which the inverse of the chi square distribution is to be calculated."), + NC_("SC_OPCODE_CHISQ_INV_MS", "Degrees of Freedom"), + NC_("SC_OPCODE_CHISQ_INV_MS", "The degrees of freedom of the chi square distribution.") +}; + + +// -=*# Resource for function STANDARDIZE #*=- +const char* SC_OPCODE_STANDARD_ARY[] = +{ + NC_("SC_OPCODE_STANDARD", "Converts a random variable to a normalized value."), + NC_("SC_OPCODE_STANDARD", "Number"), + NC_("SC_OPCODE_STANDARD", "The value to be standardized."), + NC_("SC_OPCODE_STANDARD", "mean"), + NC_("SC_OPCODE_STANDARD", "The mean value used for moving."), + NC_("SC_OPCODE_STANDARD", "STDEV"), + NC_("SC_OPCODE_STANDARD", "The standard deviation used for scaling.") +}; + +// -=*# Resource for function PERMUT #*=- +const char* SC_OPCODE_PERMUT_ARY[] = +{ + NC_("SC_OPCODE_PERMUT", "Returns the number of permutations for a given number of elements without repetition."), + NC_("SC_OPCODE_PERMUT", "Count_1"), + NC_("SC_OPCODE_PERMUT", "The total number of elements."), + NC_("SC_OPCODE_PERMUT", "Count_2"), + NC_("SC_OPCODE_PERMUT", "The selection number taken from the elements.") +}; + +// -=*# Resource for function PERMUTATIONA #*=- +const char* SC_OPCODE_PERMUTATION_A_ARY[] = +{ + NC_("SC_OPCODE_PERMUTATION_A", "Returns the number of permutations for a given number of objects (repetition allowed)."), + NC_("SC_OPCODE_PERMUTATION_A", "Count_1"), + NC_("SC_OPCODE_PERMUTATION_A", "The total number of elements."), + NC_("SC_OPCODE_PERMUTATION_A", "Count_2"), + NC_("SC_OPCODE_PERMUTATION_A", "The selection number taken from the elements.") +}; + +// -=*# Resource for function CONFIDENCE #*=- +const char* SC_OPCODE_CONFIDENCE_ARY[] = +{ + NC_("SC_OPCODE_CONFIDENCE", "Returns a (1-alpha) confidence interval for a normal distribution."), + NC_("SC_OPCODE_CONFIDENCE", "alpha"), + NC_("SC_OPCODE_CONFIDENCE", "The level of the confidence interval."), + NC_("SC_OPCODE_CONFIDENCE", "STDEV"), + NC_("SC_OPCODE_CONFIDENCE", "The standard deviation of the population."), + NC_("SC_OPCODE_CONFIDENCE", "size"), + NC_("SC_OPCODE_CONFIDENCE", "The size of the population.") +}; + +// -=*# Resource for function CONFIDENCE.NORM #*=- +const char* SC_OPCODE_CONFIDENCE_N_ARY[] = +{ + NC_("SC_OPCODE_CONFIDENCE_N", "Returns a (1-alpha) confidence interval for a normal distribution."), + NC_("SC_OPCODE_CONFIDENCE_N", "alpha"), + NC_("SC_OPCODE_CONFIDENCE_N", "The level of the confidence interval."), + NC_("SC_OPCODE_CONFIDENCE_N", "STDEV"), + NC_("SC_OPCODE_CONFIDENCE_N", "The standard deviation of the population."), + NC_("SC_OPCODE_CONFIDENCE_N", "size"), + NC_("SC_OPCODE_CONFIDENCE_N", "The size of the population.") +}; + +// -=*# Resource for function CONFIDENCE.T #*=- +const char* SC_OPCODE_CONFIDENCE_T_ARY[] = +{ + NC_("SC_OPCODE_CONFIDENCE_T", "Returns a (1-alpha) confidence interval for a Student's t distribution."), + NC_("SC_OPCODE_CONFIDENCE_T", "alpha"), + NC_("SC_OPCODE_CONFIDENCE_T", "The level of the confidence interval."), + NC_("SC_OPCODE_CONFIDENCE_T", "STDEV"), + NC_("SC_OPCODE_CONFIDENCE_T", "The standard deviation of the population."), + NC_("SC_OPCODE_CONFIDENCE_T", "size"), + NC_("SC_OPCODE_CONFIDENCE_T", "The size of the population.") +}; + +// -=*# Resource for function ZTEST #*=- +const char* SC_OPCODE_Z_TEST_ARY[] = +{ + NC_("SC_OPCODE_Z_TEST", "Calculates the probability of observing a z-statistic greater than the one computed based on a sample."), + NC_("SC_OPCODE_Z_TEST", "data"), + NC_("SC_OPCODE_Z_TEST", "The given sample, drawn from a normally distributed population."), + NC_("SC_OPCODE_Z_TEST", "mu"), + NC_("SC_OPCODE_Z_TEST", "The known mean of the population."), + NC_("SC_OPCODE_Z_TEST", "sigma"), + NC_("SC_OPCODE_Z_TEST", "The known standard deviation of the population. If omitted, the standard deviation of the given sample is used.") +}; + +// -=*# Resource for function Z.TEST #*=- +const char* SC_OPCODE_Z_TEST_MS_ARY[] = +{ + NC_("SC_OPCODE_Z_TEST_MS", "Calculates the probability of observing a z-statistic greater than the one computed based on a sample."), + NC_("SC_OPCODE_Z_TEST_MS", "data"), + NC_("SC_OPCODE_Z_TEST_MS", "The given sample, drawn from a normally distributed population."), + NC_("SC_OPCODE_Z_TEST_MS", "mu"), + NC_("SC_OPCODE_Z_TEST_MS", "The known mean of the population."), + NC_("SC_OPCODE_Z_TEST_MS", "sigma"), + NC_("SC_OPCODE_Z_TEST_MS", "The known standard deviation of the population. If omitted, the standard deviation of the given sample is used.") +}; + +// -=*# Resource for function CHITEST #*=- +const char* SC_OPCODE_CHI_TEST_ARY[] = +{ + NC_("SC_OPCODE_CHI_TEST", "Returns the chi square independence test."), + NC_("SC_OPCODE_CHI_TEST", "Data_B"), + NC_("SC_OPCODE_CHI_TEST", "The observed data array."), + NC_("SC_OPCODE_CHI_TEST", "data_E"), + NC_("SC_OPCODE_CHI_TEST", "The expected data array.") +}; + +// -=*# Resource for function CHISQ.TEST #*=- +const char* SC_OPCODE_CHI_TEST_MS_ARY[] = +{ + NC_("SC_OPCODE_CHI_TEST_MS", "Returns the chi square independence test."), + NC_("SC_OPCODE_CHI_TEST_MS", "Data_B"), + NC_("SC_OPCODE_CHI_TEST_MS", "The observed data array."), + NC_("SC_OPCODE_CHI_TEST_MS", "data_E"), + NC_("SC_OPCODE_CHI_TEST_MS", "The expected data array.") +}; + +// -=*# Resource for function FTEST #*=- +const char* SC_OPCODE_F_TEST_ARY[] = +{ + NC_("SC_OPCODE_F_TEST", "Calculates the F test."), + NC_("SC_OPCODE_F_TEST", "data_1"), + NC_("SC_OPCODE_F_TEST", "The first record array."), + NC_("SC_OPCODE_F_TEST", "data_2"), + NC_("SC_OPCODE_F_TEST", "The second record array.") +}; + +// -=*# Resource for function F.TEST #*=- +const char* SC_OPCODE_F_TEST_MS_ARY[] = +{ + NC_("SC_OPCODE_F_TEST_MS", "Calculates the F test."), + NC_("SC_OPCODE_F_TEST_MS", "data_1"), + NC_("SC_OPCODE_F_TEST_MS", "The first record array."), + NC_("SC_OPCODE_F_TEST_MS", "data_2"), + NC_("SC_OPCODE_F_TEST_MS", "The second record array.") +}; + +// -=*# Resource for function TTEST #*=- +const char* SC_OPCODE_T_TEST_ARY[] = +{ + NC_("SC_OPCODE_T_TEST", "Calculates the T test."), + NC_("SC_OPCODE_T_TEST", "data_1"), + NC_("SC_OPCODE_T_TEST", "The first record array."), + NC_("SC_OPCODE_T_TEST", "data_2"), + NC_("SC_OPCODE_T_TEST", "The second record array."), + NC_("SC_OPCODE_T_TEST", "mode"), + NC_("SC_OPCODE_T_TEST", "Mode specifies the number of distribution tails to return. 1= one-tailed, 2 = two-tailed distribution"), + NC_("SC_OPCODE_T_TEST", "Type"), + NC_("SC_OPCODE_T_TEST", "The type of the T test.") +}; + +// -=*# Resource for function T.TEST #*=- +const char* SC_OPCODE_T_TEST_MS_ARY[] = +{ + NC_("SC_OPCODE_T_TEST_MS", "Calculates the T test."), + NC_("SC_OPCODE_T_TEST_MS", "data_1"), + NC_("SC_OPCODE_T_TEST_MS", "The first record array."), + NC_("SC_OPCODE_T_TEST_MS", "data_2"), + NC_("SC_OPCODE_T_TEST_MS", "The second record array."), + NC_("SC_OPCODE_T_TEST_MS", "mode"), + NC_("SC_OPCODE_T_TEST_MS", "Mode specifies the number of distribution tails to return. 1= one-tailed, 2 = two-tailed distribution"), + NC_("SC_OPCODE_T_TEST_MS", "Type"), + NC_("SC_OPCODE_T_TEST_MS", "The type of the T test.") +}; + +// -=*# Resource for function RSQ #*=- +const char* SC_OPCODE_RSQ_ARY[] = +{ + NC_("SC_OPCODE_RSQ", "Returns the square of the Pearson product moment correlation coefficient."), + NC_("SC_OPCODE_RSQ", "data_Y"), + NC_("SC_OPCODE_RSQ", "The Y data array."), + NC_("SC_OPCODE_RSQ", "data_X"), + NC_("SC_OPCODE_RSQ", "The X data array.") +}; + +// -=*# Resource for function INTERCEPT #*=- +const char* SC_OPCODE_INTERCEPT_ARY[] = +{ + NC_("SC_OPCODE_INTERCEPT", "Returns the intercept of the linear regression line and the Y axis."), + NC_("SC_OPCODE_INTERCEPT", "data_Y"), + NC_("SC_OPCODE_INTERCEPT", "The Y data array."), + NC_("SC_OPCODE_INTERCEPT", "data_X"), + NC_("SC_OPCODE_INTERCEPT", "The X data array.") +}; + +// -=*# Resource for function SLOPE #*=- +const char* SC_OPCODE_SLOPE_ARY[] = +{ + NC_("SC_OPCODE_SLOPE", "Returns the slope of the linear regression line."), + NC_("SC_OPCODE_SLOPE", "data_Y"), + NC_("SC_OPCODE_SLOPE", "The Y data array."), + NC_("SC_OPCODE_SLOPE", "data_X"), + NC_("SC_OPCODE_SLOPE", "The X data array.") +}; + +// -=*# Resource for function STEYX #*=- +const char* SC_OPCODE_STEYX_ARY[] = +{ + NC_("SC_OPCODE_STEYX", "Returns the standard error of the linear regression."), + NC_("SC_OPCODE_STEYX", "data_Y"), + NC_("SC_OPCODE_STEYX", "The Y data array."), + NC_("SC_OPCODE_STEYX", "data_X"), + NC_("SC_OPCODE_STEYX", "The X data array.") +}; + +// -=*# Resource for function PEARSON #*=- +const char* SC_OPCODE_PEARSON_ARY[] = +{ + NC_("SC_OPCODE_PEARSON", "Returns the Pearson product moment correlation coefficient."), + NC_("SC_OPCODE_PEARSON", "Data_1"), + NC_("SC_OPCODE_PEARSON", "The first record array."), + NC_("SC_OPCODE_PEARSON", "Data_2"), + NC_("SC_OPCODE_PEARSON", "The second record array.") +}; + +// -=*# Resource for function CORREL #*=- +const char* SC_OPCODE_CORREL_ARY[] = +{ + NC_("SC_OPCODE_CORREL", "Returns the correlation coefficient."), + NC_("SC_OPCODE_CORREL", "Data_1"), + NC_("SC_OPCODE_CORREL", "The first record array."), + NC_("SC_OPCODE_CORREL", "Data_2"), + NC_("SC_OPCODE_CORREL", "The second record array.") +}; + +// -=*# Resource for function COVAR #*=- +const char* SC_OPCODE_COVAR_ARY[] = +{ + NC_("SC_OPCODE_COVAR", "Calculates the population covariance."), + NC_("SC_OPCODE_COVAR", "Data_1"), + NC_("SC_OPCODE_COVAR", "The first record array."), + NC_("SC_OPCODE_COVAR", "Data_2"), + NC_("SC_OPCODE_COVAR", "The second record array.") +}; + +// -=*# Resource for function COVARIANCE.P #*=- +const char* SC_OPCODE_COVARIANCE_P_ARY[] = +{ + NC_("SC_OPCODE_COVARIANCE_P", "Calculates the population covariance."), + NC_("SC_OPCODE_COVARIANCE_P", "Data_1"), + NC_("SC_OPCODE_COVARIANCE_P", "The first record array."), + NC_("SC_OPCODE_COVARIANCE_P", "Data_2"), + NC_("SC_OPCODE_COVARIANCE_P", "The second record array.") +}; + +// -=*# Resource for function COVARIANCE.S #*=- +const char* SC_OPCODE_COVARIANCE_S_ARY[] = +{ + NC_("SC_OPCODE_COVARIANCE_S", "Calculates the sample covariance."), + NC_("SC_OPCODE_COVARIANCE_S", "Data_1"), + NC_("SC_OPCODE_COVARIANCE_S", "The first record array."), + NC_("SC_OPCODE_COVARIANCE_S", "Data_2"), + NC_("SC_OPCODE_COVARIANCE_S", "The second record array.") +}; + +// -=*# Resource for function FORECAST #*=- +const char* SC_OPCODE_FORECAST_ARY[] = +{ + NC_("SC_OPCODE_FORECAST", "Returns a value along a linear regression"), + NC_("SC_OPCODE_FORECAST", "value"), + NC_("SC_OPCODE_FORECAST", "The X value for which the Y value on the regression linear is to be calculated."), + NC_("SC_OPCODE_FORECAST", "data_Y"), + NC_("SC_OPCODE_FORECAST", "The Y data array."), + NC_("SC_OPCODE_FORECAST", "data_X"), + NC_("SC_OPCODE_FORECAST", "The X data array.") +}; + +// -=*# Resource for function FORECAST.ETS #*=- +const char* SC_OPCODE_FORECAST_ETS_ADD_ARY[] = +{ + NC_("SC_OPCODE_FORECAST_ETS_ADD", "Calculates future value(s) using additive Exponential Smoothing algorithm."), + NC_("SC_OPCODE_FORECAST_ETS_ADD", "target"), + NC_("SC_OPCODE_FORECAST_ETS_ADD", "The date (array) for which you want to predict a value."), + NC_("SC_OPCODE_FORECAST_ETS_ADD", "values"), + NC_("SC_OPCODE_FORECAST_ETS_ADD", "The data array from which you want to forecast."), + NC_("SC_OPCODE_FORECAST_ETS_ADD", "timeline"), + NC_("SC_OPCODE_FORECAST_ETS_ADD", "The date or numeric array; a consistent step between values is needed."), + NC_("SC_OPCODE_FORECAST_ETS_ADD", "period length"), + NC_("SC_OPCODE_FORECAST_ETS_ADD", "Number of Samples in Period (default 1); length of the seasonal pattern."), + NC_("SC_OPCODE_FORECAST_ETS_ADD", "data completion"), + NC_("SC_OPCODE_FORECAST_ETS_ADD", "Data completion (default 1); 0 treats missing points as zero, 1 interpolates."), + NC_("SC_OPCODE_FORECAST_ETS_ADD", "aggregation"), + NC_("SC_OPCODE_FORECAST_ETS_ADD", "Aggregation (default 1 = AVERAGE); method to be used to aggregate identical (time) values.") +}; + +// -=*# Resource for function FORECAST.ETS.MULT #*=- +const char* SC_OPCODE_FORECAST_ETS_MUL_ARY[] = +{ + NC_("SC_OPCODE_FORECAST_ETS_MUL", "Calculates future value(s) using multiplicative Exponential Smoothing algorithm."), + NC_("SC_OPCODE_FORECAST_ETS_MUL", "target"), + NC_("SC_OPCODE_FORECAST_ETS_MUL", "The date (array) for which you want to predict a value."), + NC_("SC_OPCODE_FORECAST_ETS_MUL", "values"), + NC_("SC_OPCODE_FORECAST_ETS_MUL", "The data array from which you want to forecast."), + NC_("SC_OPCODE_FORECAST_ETS_MUL", "timeline"), + NC_("SC_OPCODE_FORECAST_ETS_MUL", "The date or numeric array; a consistent step between values is needed."), + NC_("SC_OPCODE_FORECAST_ETS_MUL", "period length"), + NC_("SC_OPCODE_FORECAST_ETS_MUL", "Number of Samples in Period (default 1); length of the seasonal pattern."), + NC_("SC_OPCODE_FORECAST_ETS_MUL", "data completion"), + NC_("SC_OPCODE_FORECAST_ETS_MUL", "Data completion (default 1); 0 treats missing points as zero, 1 interpolates."), + NC_("SC_OPCODE_FORECAST_ETS_MUL", "aggregation"), + NC_("SC_OPCODE_FORECAST_ETS_MUL", "Aggregation (default 1 = AVERAGE); method to be used to aggregate identical (time) values.") +}; + +// -=*# Resource for function FORECAST.ETS.CONFINT #*=- +const char* SC_OPCODE_FORECAST_ETS_PIA_ARY[] = +{ + NC_("SC_OPCODE_FORECAST_ETS_PIA", "Returns a prediction interval at the specified target value(s) for additive Exponential Smoothing method"), + NC_("SC_OPCODE_FORECAST_ETS_PIA", "target"), + NC_("SC_OPCODE_FORECAST_ETS_PIA", "The date (array) for which you want to predict a value."), + NC_("SC_OPCODE_FORECAST_ETS_PIA", "values"), + NC_("SC_OPCODE_FORECAST_ETS_PIA", "The data array from which you want to forecast."), + NC_("SC_OPCODE_FORECAST_ETS_PIA", "timeline"), + NC_("SC_OPCODE_FORECAST_ETS_PIA", "The date or numeric array; a consistent step between values is needed."), + NC_("SC_OPCODE_FORECAST_ETS_PIA", "confidence level"), + NC_("SC_OPCODE_FORECAST_ETS_PIA", "Confidence level (default 0.95); value 0 to 1 (exclusive) for 0 to 100% calculated prediction interval."), + NC_("SC_OPCODE_FORECAST_ETS_PIA", "period length"), + NC_("SC_OPCODE_FORECAST_ETS_PIA", "Number of Samples in Period (default 1); length of the seasonal pattern."), + NC_("SC_OPCODE_FORECAST_ETS_PIA", "data completion"), + NC_("SC_OPCODE_FORECAST_ETS_PIA", "Data completion (default 1); 0 treats missing points as zero, 1 interpolates."), + NC_("SC_OPCODE_FORECAST_ETS_PIA", "aggregation"), + NC_("SC_OPCODE_FORECAST_ETS_PIA", "Aggregation (default 1 = AVERAGE); method to be used to aggregate identical (time) values.") +}; + +// -=*# Resource for function FORECAST.ETS.PI.MULT #*=- +const char* SC_OPCODE_FORECAST_ETS_PIM_ARY[] = +{ + NC_("SC_OPCODE_FORECAST_ETS_PIM", "Returns a prediction interval at the specified target value(s) for multiplicative Exponential Smoothing method"), + NC_("SC_OPCODE_FORECAST_ETS_PIM", "target"), + NC_("SC_OPCODE_FORECAST_ETS_PIM", "The date (array) for which you want to predict a value."), + NC_("SC_OPCODE_FORECAST_ETS_PIM", "values"), + NC_("SC_OPCODE_FORECAST_ETS_PIM", "The data array from which you want to forecast."), + NC_("SC_OPCODE_FORECAST_ETS_PIM", "timeline"), + NC_("SC_OPCODE_FORECAST_ETS_PIM", "The date or numeric array; a consistent step between values is needed."), + NC_("SC_OPCODE_FORECAST_ETS_PIM", "confidence level"), + NC_("SC_OPCODE_FORECAST_ETS_PIM", "Confidence level (default 0.95); value 0 to 1 (exclusive) for 0 to 100% calculated prediction interval."), + NC_("SC_OPCODE_FORECAST_ETS_PIM", "period length"), + NC_("SC_OPCODE_FORECAST_ETS_PIM", "Number of Samples in Period (default 1); length of the seasonal pattern."), + NC_("SC_OPCODE_FORECAST_ETS_PIM", "data completion"), + NC_("SC_OPCODE_FORECAST_ETS_PIM", "Data completion (default 1); 0 treats missing points as zero, 1 interpolates."), + NC_("SC_OPCODE_FORECAST_ETS_PIM", "aggregation"), + NC_("SC_OPCODE_FORECAST_ETS_PIM", "Aggregation (default 1 = AVERAGE); method to be used to aggregate identical (time) values.") +}; + +// -=*# Resource for function FORECAST.ETS.SEASONALITY #*=- +const char* SC_OPCODE_FORECAST_ETS_SEA_ARY[] = +{ + NC_("SC_OPCODE_FORECAST_ETS_SEA", "Calculates the number of samples in period (season) using additive Exponential Triple Smoothing algorithm."), + NC_("SC_OPCODE_FORECAST_ETS_SEA", "values"), + NC_("SC_OPCODE_FORECAST_ETS_SEA", "The data array from which you want to forecast."), + NC_("SC_OPCODE_FORECAST_ETS_SEA", "timeline"), + NC_("SC_OPCODE_FORECAST_ETS_SEA", "The date or numeric array; a consistent step between values is needed."), + NC_("SC_OPCODE_FORECAST_ETS_SEA", "data completion"), + NC_("SC_OPCODE_FORECAST_ETS_SEA", "Data completion (default 1); 0 treats missing points as zero, 1 interpolates."), + NC_("SC_OPCODE_FORECAST_ETS_SEA", "aggregation"), + NC_("SC_OPCODE_FORECAST_ETS_SEA", "Aggregation (default 1 = AVERAGE); method to be used to aggregate identical (time) values.") +}; + +// -=*# Resource for function FORECAST.ETS.STAT #*=- +const char* SC_OPCODE_FORECAST_ETS_STA_ARY[] = +{ + NC_("SC_OPCODE_FORECAST_ETS_STA", "Returns statistical value(s) using additive Exponential Smoothing algorithm."), + NC_("SC_OPCODE_FORECAST_ETS_STA", "values"), + NC_("SC_OPCODE_FORECAST_ETS_STA", "The data array from which you want to forecast."), + NC_("SC_OPCODE_FORECAST_ETS_STA", "timeline"), + NC_("SC_OPCODE_FORECAST_ETS_STA", "The date or numeric array; a consistent step between values is needed."), + NC_("SC_OPCODE_FORECAST_ETS_STA", "statistic type"), + NC_("SC_OPCODE_FORECAST_ETS_STA", "Value (1-9) or array of values, indicating which statistic will be returned for the calculated forecast"), + NC_("SC_OPCODE_FORECAST_ETS_STA", "period length"), + NC_("SC_OPCODE_FORECAST_ETS_STA", "Number of Samples in Period (default 1); length of the seasonal pattern."), + NC_("SC_OPCODE_FORECAST_ETS_STA", "data completion"), + NC_("SC_OPCODE_FORECAST_ETS_STA", "Data completion (default 1); 0 treats missing points as zero, 1 interpolates."), + NC_("SC_OPCODE_FORECAST_ETS_STA", "aggregation"), + NC_("SC_OPCODE_FORECAST_ETS_STA", "Aggregation (default 1 = AVERAGE); method to be used to aggregate identical (time) values.") +}; + +// -=*# Resource for function FORECAST.ETS.STAT.MULT #*=- +const char* SC_OPCODE_FORECAST_ETS_STM_ARY[] = +{ + NC_("SC_OPCODE_FORECAST_ETS_STM", "Returns statistical value(s) using multiplicative Exponential Smoothing algorithm."), + NC_("SC_OPCODE_FORECAST_ETS_STM", "values"), + NC_("SC_OPCODE_FORECAST_ETS_STM", "The data array from which you want to forecast."), + NC_("SC_OPCODE_FORECAST_ETS_STM", "timeline"), + NC_("SC_OPCODE_FORECAST_ETS_STM", "The date or numeric array; a consistent step between values is needed."), + NC_("SC_OPCODE_FORECAST_ETS_STM", "statistic type"), + NC_("SC_OPCODE_FORECAST_ETS_STM", "Value (1-9) or array of values, indicating which statistic will be returned for the calculated forecast"), + NC_("SC_OPCODE_FORECAST_ETS_STM", "period length"), + NC_("SC_OPCODE_FORECAST_ETS_STM", "Number Of Samples in Period (default 1); length of the seasonal pattern."), + NC_("SC_OPCODE_FORECAST_ETS_STM", "data completion"), + NC_("SC_OPCODE_FORECAST_ETS_STM", "Data completion (default 1); 0 treats missing points as zero, 1 interpolates."), + NC_("SC_OPCODE_FORECAST_ETS_STM", "aggregation"), + NC_("SC_OPCODE_FORECAST_ETS_STM", "Aggregation (default 1 = AVERAGE); method to be used to aggregate identical (time) values.") +}; + +// -=*# Resource for function FORECAST.LINEAR #*=- +const char* SC_OPCODE_FORECAST_LIN_ARY[] = +{ + NC_("SC_OPCODE_FORECAST_LIN", "Returns a value along a linear regression"), + NC_("SC_OPCODE_FORECAST_LIN", "value"), + NC_("SC_OPCODE_FORECAST_LIN", "The X value for which the Y value on the regression linear is to be calculated."), + NC_("SC_OPCODE_FORECAST_LIN", "data_Y"), + NC_("SC_OPCODE_FORECAST_LIN", "The Y data array."), + NC_("SC_OPCODE_FORECAST_LIN", "data_X"), + NC_("SC_OPCODE_FORECAST_LIN", "The X data array.") +}; + +// -=*# Resource for function ADDRESS #*=- +const char* SC_OPCODE_ADDRESS_ARY[] = +{ + NC_("SC_OPCODE_ADDRESS", "Returns the reference to a cell as text."), + NC_("SC_OPCODE_ADDRESS", "row"), + NC_("SC_OPCODE_ADDRESS", "The row number of the cell."), + NC_("SC_OPCODE_ADDRESS", "column"), + NC_("SC_OPCODE_ADDRESS", "The column number of the cell."), + NC_("SC_OPCODE_ADDRESS", "ABS"), + NC_("SC_OPCODE_ADDRESS", "Specifies whether absolute or relative referencing is to be used."), + NC_("SC_OPCODE_ADDRESS", "A1"), + NC_("SC_OPCODE_ADDRESS", "The reference style: 0 or FALSE means R1C1 style, any other value or omitted means A1 style."), + NC_("SC_OPCODE_ADDRESS", "sheet"), + NC_("SC_OPCODE_ADDRESS", "The spreadsheet name of the cell reference.") +}; + +// -=*# Resource for function AREAS #*=- +const char* SC_OPCODE_AREAS_ARY[] = +{ + NC_("SC_OPCODE_AREAS", "Returns the number of individual ranges that belong to a (multiple) range."), + NC_("SC_OPCODE_AREAS", "reference"), + NC_("SC_OPCODE_AREAS", "The reference to a (multiple) range.") +}; + +// -=*# Resource for function CHOOSE #*=- +const char* SC_OPCODE_CHOOSE_ARY[] = +{ + NC_("SC_OPCODE_CHOOSE", "Selects a value from a list of up to 30 value arguments."), + NC_("SC_OPCODE_CHOOSE", "Index"), + NC_("SC_OPCODE_CHOOSE", "The index of the value (1..30) selected."), + NC_("SC_OPCODE_CHOOSE", "value "), + NC_("SC_OPCODE_CHOOSE", "Value 1, value 2,... The list of arguments from which a value is chosen.") +}; + +// -=*# Resource for function COLUMNS #*=- +const char* SC_OPCODE_COLUMN_ARY[] = +{ + NC_("SC_OPCODE_COLUMN", "Returns the internal column number of a reference."), + NC_("SC_OPCODE_COLUMN", "reference"), + NC_("SC_OPCODE_COLUMN", "The reference to a cell or a range.") +}; + +// -=*# Resource for function ROW #*=- +const char* SC_OPCODE_ROW_ARY[] = +{ + NC_("SC_OPCODE_ROW", "Defines the internal row number of a reference."), + NC_("SC_OPCODE_ROW", "reference"), + NC_("SC_OPCODE_ROW", "The reference to a cell or a range.") +}; + +// -=*# Resource for function SHEET #*=- +const char* SC_OPCODE_SHEET_ARY[] = +{ + NC_("SC_OPCODE_SHEET", "Returns the internal sheet number of a reference or a string."), + NC_("SC_OPCODE_SHEET", "reference"), + NC_("SC_OPCODE_SHEET", "The reference to a cell or a range or the character string of a sheet name.") +}; + +// -=*# Resource for function COLUMNS #*=- +const char* SC_OPCODE_COLUMNS_ARY[] = +{ + NC_("SC_OPCODE_COLUMNS", "Returns the number of columns in an array or reference."), + NC_("SC_OPCODE_COLUMNS", "array"), + NC_("SC_OPCODE_COLUMNS", "The array (reference) for which the number of columns is to be determined.") +}; + +// -=*# Resource for function ROWS #*=- +const char* SC_OPCODE_ROWS_ARY[] = +{ + NC_("SC_OPCODE_ROWS", "Returns the number of rows in a reference or array."), + NC_("SC_OPCODE_ROWS", "array"), + NC_("SC_OPCODE_ROWS", "The array (reference) for which the number of rows is to be determined.") +}; + +// -=*# Resource for function SHEETS #*=- +const char* SC_OPCODE_SHEETS_ARY[] = +{ + NC_("SC_OPCODE_SHEETS", "Returns the number of sheets of a given reference. If no parameter has been entered, the total number of sheets in the document is returned."), + NC_("SC_OPCODE_SHEETS", "reference"), + NC_("SC_OPCODE_SHEETS", "The reference to a cell or a range.") +}; + +// -=*# Resource for function HLOOKUP #*=- +const char* SC_OPCODE_H_LOOKUP_ARY[] = +{ + NC_("SC_OPCODE_H_LOOKUP", "Horizontal search and reference to the cells located below."), + NC_("SC_OPCODE_H_LOOKUP", "search_criteria"), + NC_("SC_OPCODE_H_LOOKUP", "The value to be found in the first row."), + NC_("SC_OPCODE_H_LOOKUP", "array"), + NC_("SC_OPCODE_H_LOOKUP", "The array or the range for the reference."), + NC_("SC_OPCODE_H_LOOKUP", "Index"), + NC_("SC_OPCODE_H_LOOKUP", "The row index in the array."), + NC_("SC_OPCODE_H_LOOKUP", "sorted"), + NC_("SC_OPCODE_H_LOOKUP", "If the value is TRUE or not given, the search row of the array must be sorted in ascending order.") +}; + +// -=*# Resource for function VLOOKUP #*=- +const char* SC_OPCODE_V_LOOKUP_ARY[] = +{ + NC_("SC_OPCODE_V_LOOKUP", "Vertical search and reference to indicated cells."), + NC_("SC_OPCODE_V_LOOKUP", "Search criterion"), + NC_("SC_OPCODE_V_LOOKUP", "The value to be found in the first column."), + NC_("SC_OPCODE_V_LOOKUP", "array"), + NC_("SC_OPCODE_V_LOOKUP", "The array or range for referencing."), + NC_("SC_OPCODE_V_LOOKUP", "Index"), + NC_("SC_OPCODE_V_LOOKUP", "Column index number in the array."), + NC_("SC_OPCODE_V_LOOKUP", "sort order"), + NC_("SC_OPCODE_V_LOOKUP", "If the value is TRUE or not given, the search column of the array must be sorted in ascending order.") +}; + +// -=*# Resource for function INDEX #*=- +const char* SC_OPCODE_INDEX_ARY[] = +{ + NC_("SC_OPCODE_INDEX", "Returns a reference to a cell from a defined range."), + NC_("SC_OPCODE_INDEX", "reference"), + NC_("SC_OPCODE_INDEX", "The reference to a (multiple) range."), + NC_("SC_OPCODE_INDEX", "row"), + NC_("SC_OPCODE_INDEX", "The row in the range."), + NC_("SC_OPCODE_INDEX", "column"), + NC_("SC_OPCODE_INDEX", "The column in the range."), + NC_("SC_OPCODE_INDEX", "range"), + NC_("SC_OPCODE_INDEX", "The index of the subrange if referring to a multiple range.") +}; + +// -=*# Resource for function INDIRECT #*=- +const char* SC_OPCODE_INDIRECT_ARY[] = +{ + NC_("SC_OPCODE_INDIRECT", "Returns the contents of a cell that is referenced in text form."), + NC_("SC_OPCODE_INDIRECT", "ref"), + NC_("SC_OPCODE_INDIRECT", "The cell whose contents are to be evaluated is to be referenced in text form (e.g. \"A1\")."), + NC_("SC_OPCODE_INDIRECT", "A1"), + NC_("SC_OPCODE_INDIRECT", "The reference style: 0 or FALSE means R1C1 style, any other value or omitted means A1 style.") +}; + +// -=*# Resource for function LOOKUP #*=- +const char* SC_OPCODE_LOOKUP_ARY[] = +{ + NC_("SC_OPCODE_LOOKUP", "Determines a value in a vector by comparison to values in another vector."), + NC_("SC_OPCODE_LOOKUP", "Search criterion"), + NC_("SC_OPCODE_LOOKUP", "The value to be used for comparison."), + NC_("SC_OPCODE_LOOKUP", "Search vector"), + NC_("SC_OPCODE_LOOKUP", "The vector (row or column) in which to search."), + NC_("SC_OPCODE_LOOKUP", "result_vector"), + NC_("SC_OPCODE_LOOKUP", "The vector (row or range) from which the value is to be determined.") +}; + +// -=*# Resource for function MATCH #*=- +const char* SC_OPCODE_MATCH_ARY[] = +{ + NC_("SC_OPCODE_MATCH", "Defines a position in a array after comparing values."), + NC_("SC_OPCODE_MATCH", "Search criterion"), + NC_("SC_OPCODE_MATCH", "The value to be used for comparison."), + NC_("SC_OPCODE_MATCH", "lookup_array"), + NC_("SC_OPCODE_MATCH", "The array (range) in which the search is made."), + NC_("SC_OPCODE_MATCH", "Type"), + NC_("SC_OPCODE_MATCH", "Type can take the value 1, 0 or -1 and determines the criteria are to be used for comparison purposes.") +}; + +// -=*# Resource for function OFFSET #*=- +const char* SC_OPCODE_OFFSET_ARY[] = +{ + NC_("SC_OPCODE_OFFSET", "Returns a reference which has been moved in relation to the starting point."), + NC_("SC_OPCODE_OFFSET", "reference"), + NC_("SC_OPCODE_OFFSET", "The reference (cell) from which to base the movement."), + NC_("SC_OPCODE_OFFSET", "rows"), + NC_("SC_OPCODE_OFFSET", "The number of rows to be moved either up or down."), + NC_("SC_OPCODE_OFFSET", "columns"), + NC_("SC_OPCODE_OFFSET", "The number of columns that are to be moved to the left or to the right."), + NC_("SC_OPCODE_OFFSET", "height"), + NC_("SC_OPCODE_OFFSET", "The number of rows of the moved reference."), + NC_("SC_OPCODE_OFFSET", "width"), + NC_("SC_OPCODE_OFFSET", "The number of columns in the moved reference.") +}; + +// -=*# Resource for function ERRORTYPE #*=- +const char* SC_OPCODE_ERROR_TYPE_ARY[] = +{ + NC_("SC_OPCODE_ERROR_TYPE", "Returns a number corresponding to an error type"), + NC_("SC_OPCODE_ERROR_TYPE", "reference"), + NC_("SC_OPCODE_ERROR_TYPE", "The reference (cell) in which the error occurred.") +}; + +// -=*# Resource for function ERROR.TYPE #*=- +const char* SC_OPCODE_ERROR_TYPE_ODF_ARY[] = +{ + NC_("SC_OPCODE_ERROR_TYPE_ODF", "Returns a number corresponding to one of the error values or #N/A if no error exists"), + NC_("SC_OPCODE_ERROR_TYPE_ODF", "expression"), + NC_("SC_OPCODE_ERROR_TYPE_ODF", "The error value whose identifying number you want to find. Can be the actual error value or a reference to a cell that you want to test.") +}; + +// -=*# Resource for function STYLE #*=- +const char* SC_OPCODE_STYLE_ARY[] = +{ + NC_("SC_OPCODE_STYLE", "Applies a Style to the formula cell."), + NC_("SC_OPCODE_STYLE", "Style"), + NC_("SC_OPCODE_STYLE", "The name of the Style to be applied."), + NC_("SC_OPCODE_STYLE", "Time"), + NC_("SC_OPCODE_STYLE", "The time (in seconds) that the Style is to remain valid."), + NC_("SC_OPCODE_STYLE", "Style2"), + NC_("SC_OPCODE_STYLE", "The Style to be applied after time expires.") +}; + +// -=*# Resource for function DDE #*=- +const char* SC_OPCODE_DDE_ARY[] = +{ + NC_("SC_OPCODE_DDE", "Result of a DDE link."), + NC_("SC_OPCODE_DDE", "server"), + NC_("SC_OPCODE_DDE", "The name of the server application."), + NC_("SC_OPCODE_DDE", "File"), + NC_("SC_OPCODE_DDE", "The name of the file."), + NC_("SC_OPCODE_DDE", "range"), + NC_("SC_OPCODE_DDE", "The range from which data is to be taken."), + NC_("SC_OPCODE_DDE", "mode"), + NC_("SC_OPCODE_DDE", "Defines how data is to be converted to numbers.") +}; + +// -=*# Resource for function HYPERLINK #*=- +const char* SC_OPCODE_HYPERLINK_ARY[] = +{ + NC_("SC_OPCODE_HYPERLINK", "Hyperlink."), + NC_("SC_OPCODE_HYPERLINK", "URL"), + NC_("SC_OPCODE_HYPERLINK", "URL"), + NC_("SC_OPCODE_HYPERLINK", "CellText"), + NC_("SC_OPCODE_HYPERLINK", "Cell Text") +}; + +// -=*# Resource for function GETPIVOTDATA #*=- +const char* SC_OPCODE_GET_PIVOT_DATA_ARY[] = +{ + NC_("SC_OPCODE_GET_PIVOT_DATA", "Extracts value(s) from a pivot table."), + NC_("SC_OPCODE_GET_PIVOT_DATA", "Data Field"), + NC_("SC_OPCODE_GET_PIVOT_DATA", "The name of the pivot table field to extract."), + NC_("SC_OPCODE_GET_PIVOT_DATA", "Pivot Table"), + NC_("SC_OPCODE_GET_PIVOT_DATA", "A reference to a cell or range in the pivot table."), + NC_("SC_OPCODE_GET_PIVOT_DATA", "Field Name / Item"), + NC_("SC_OPCODE_GET_PIVOT_DATA", "Field name/value pair to filter the target data.") +}; + +// -=*# Resource for function BAHTTEXT #*=- +const char* SC_OPCODE_BAHTTEXT_ARY[] = +{ + NC_("SC_OPCODE_BAHTTEXT", "Converts a number to text (Baht)."), + NC_("SC_OPCODE_BAHTTEXT", "Number"), + NC_("SC_OPCODE_BAHTTEXT", "The number to convert.") +}; + +// -=*# Resource for function JIS #*=- +const char* SC_OPCODE_JIS_ARY[] = +{ + NC_("SC_OPCODE_JIS", "Converts half-width ASCII and katakana characters to full-width."), + NC_("SC_OPCODE_JIS", "text"), + NC_("SC_OPCODE_JIS", "The text to convert.") +}; + +// -=*# Resource for function ASC #*=- +const char* SC_OPCODE_ASC_ARY[] = +{ + NC_("SC_OPCODE_ASC", "Converts full-width ASCII and katakana characters to half-width."), + NC_("SC_OPCODE_ASC", "text"), + NC_("SC_OPCODE_ASC", "The text to convert.") +}; + +// -=*# Resource for function CODE #*=- +const char* SC_OPCODE_CODE_ARY[] = +{ + NC_("SC_OPCODE_CODE", "Returns a numeric code for the first character in a text string."), + NC_("SC_OPCODE_CODE", "text"), + NC_("SC_OPCODE_CODE", "This is the text for which the code of the first character is to be found.") +}; + +// -=*# Resource for function DOLLAR #*=- +const char* SC_OPCODE_CURRENCY_ARY[] = +{ + NC_("SC_OPCODE_CURRENCY", "Converts a number to text in currency format."), + NC_("SC_OPCODE_CURRENCY", "value"), + NC_("SC_OPCODE_CURRENCY", "Value is a number, a reference to a cell containing a number or a formula that results in a number."), + NC_("SC_OPCODE_CURRENCY", "decimals"), + NC_("SC_OPCODE_CURRENCY", "Decimal places. Denotes the number of digits to the right of the decimal point.") +}; + +// -=*# Resource for function CHAR #*=- +const char* SC_OPCODE_CHAR_ARY[] = +{ + NC_("SC_OPCODE_CHAR", "Converts a code number into a character or letter."), + NC_("SC_OPCODE_CHAR", "number"), + NC_("SC_OPCODE_CHAR", "The code value for the character.") +}; + +// -=*# Resource for function CLEAN #*=- +const char* SC_OPCODE_CLEAN_ARY[] = +{ + NC_("SC_OPCODE_CLEAN", "Removes all nonprintable characters from text."), + NC_("SC_OPCODE_CLEAN", "text"), + NC_("SC_OPCODE_CLEAN", "The text from which nonprintable characters are to be removed.") +}; + +// -=*# Resource for function CONCATENATE #*=- +const char* SC_OPCODE_CONCAT_ARY[] = +{ + NC_("SC_OPCODE_CONCAT", "Combines several text items into one."), + NC_("SC_OPCODE_CONCAT", "text"), + NC_("SC_OPCODE_CONCAT", "Text for the concatenation.") +}; + +// -=*# Resource for function CONCAT #*=- +const char* SC_OPCODE_CONCAT_MS_ARY[] = +{ + NC_("SC_OPCODE_CONCAT_MS", "Combines several text items into one, accepts cell ranges as arguments."), + NC_("SC_OPCODE_CONCAT_MS", "text"), + NC_("SC_OPCODE_CONCAT_MS", "Text and/or cell ranges for the concatenation.") +}; + +// -=*# Resource for function TEXTJOIN #*=- +const char* SC_OPCODE_TEXTJOIN_MS_ARY[] = +{ + NC_("SC_OPCODE_TEXTJOIN_MS", "Combines several text items into one, accepts cell ranges as arguments. Uses delimiter between items."), + NC_("SC_OPCODE_TEXTJOIN_MS", "delimiter"), + NC_("SC_OPCODE_TEXTJOIN_MS", "Text string to be used as delimiter."), + NC_("SC_OPCODE_TEXTJOIN_MS", "skip empty cells"), + NC_("SC_OPCODE_TEXTJOIN_MS", "If TRUE, empty cells will be ignored."), + NC_("SC_OPCODE_TEXTJOIN_MS", "text"), + NC_("SC_OPCODE_TEXTJOIN_MS", "Text and/or cell ranges for the concatenation.") +}; + +// -=*# Resource for function IFS #*=- +const char* SC_OPCODE_IFS_MS_ARY[] = +{ + NC_("SC_OPCODE_IFS_MS", "Checks 1 or more conditions and returns a value corresponding to the first true condition."), + NC_("SC_OPCODE_IFS_MS", "test"), + NC_("SC_OPCODE_IFS_MS", "Any value or expression which can be either TRUE or FALSE."), + NC_("SC_OPCODE_IFS_MS", "result"), + NC_("SC_OPCODE_IFS_MS", "The result of the function if test is TRUE.") +}; + +// -=*# Resource for function SWITCH #*=- +const char* SC_OPCODE_SWITCH_MS_ARY[] = +{ + NC_("SC_OPCODE_SWITCH_MS", "Checks 1 or more values and returns a result corresponding to the first value equal to the given expression."), + NC_("SC_OPCODE_SWITCH_MS", "expression"), + NC_("SC_OPCODE_SWITCH_MS", "Value that will be compared against value1-valueN."), + NC_("SC_OPCODE_SWITCH_MS", "value"), + NC_("SC_OPCODE_SWITCH_MS", "Value that will be compared against expression."), + NC_("SC_OPCODE_SWITCH_MS", "result"), + NC_("SC_OPCODE_SWITCH_MS", "Value to return when corresponding value argument matches expression.") +}; + +const char* SC_OPCODE_MINIFS_MS_ARY[] = +{ + NC_("SC_OPCODE_MINIFS_MS", "Returns the minimum value in a range that meet multiple criteria in multiple ranges."), + NC_("SC_OPCODE_MINIFS_MS", "min_range"), + NC_("SC_OPCODE_MINIFS_MS", "The range from which the minimum will be determined."), + NC_("SC_OPCODE_MINIFS_MS", "range"), + NC_("SC_OPCODE_MINIFS_MS", "Range 1, range 2,... are the ranges to be evaluated by the criteria given."), + NC_("SC_OPCODE_MINIFS_MS", "criteria"), + NC_("SC_OPCODE_MINIFS_MS", "Criteria 1, criteria 2,... are the criteria to be applied to the ranges given.") +}; + +const char* SC_OPCODE_MAXIFS_MS_ARY[] = +{ + NC_("SC_OPCODE_MAXIFS_MS", "Returns the maximum value in a range that meet multiple criteria in multiple ranges."), + NC_("SC_OPCODE_MAXIFS_MS", "max_range"), + NC_("SC_OPCODE_MAXIFS_MS", "The range from which the maximum will be determined."), + NC_("SC_OPCODE_MAXIFS_MS", "range"), + NC_("SC_OPCODE_MAXIFS_MS", "Range 1, range 2,... are the ranges to be evaluated by the criteria given."), + NC_("SC_OPCODE_MAXIFS_MS", "criteria"), + NC_("SC_OPCODE_MAXIFS_MS", "Criteria 1, criteria 2,... are the criteria to be applied to the ranges given.") +}; + +// -=*# Resource for function EXACT #*=- +const char* SC_OPCODE_EXACT_ARY[] = +{ + NC_("SC_OPCODE_EXACT", "Specifies whether two texts are identical."), + NC_("SC_OPCODE_EXACT", "text_1"), + NC_("SC_OPCODE_EXACT", "The first text to be used for comparing texts."), + NC_("SC_OPCODE_EXACT", "text_2"), + NC_("SC_OPCODE_EXACT", "The second text for comparing texts.") +}; + +// -=*# Resource for function FIND #*=- +const char* SC_OPCODE_FIND_ARY[] = +{ + NC_("SC_OPCODE_FIND", "Looks for a string of text within another (case sensitive)"), + NC_("SC_OPCODE_FIND", "find_text"), + NC_("SC_OPCODE_FIND", "The text to be found."), + NC_("SC_OPCODE_FIND", "text"), + NC_("SC_OPCODE_FIND", "The text in which a search is to be made."), + NC_("SC_OPCODE_FIND", "position"), + NC_("SC_OPCODE_FIND", "The position in the text from which the search starts.") +}; + +// -=*# Resource for function SEARCH #*=- +const char* SC_OPCODE_SEARCH_ARY[] = +{ + NC_("SC_OPCODE_SEARCH", "Looks for one text value within another (not case-sensitive)."), + NC_("SC_OPCODE_SEARCH", "find_text"), + NC_("SC_OPCODE_SEARCH", "The text to be found."), + NC_("SC_OPCODE_SEARCH", "text"), + NC_("SC_OPCODE_SEARCH", "The text in which a search is to be made."), + NC_("SC_OPCODE_SEARCH", "position"), + NC_("SC_OPCODE_SEARCH", "The position in the text where the search is started.") +}; + +// -=*# Resource for function TRIM #*=- +const char* SC_OPCODE_TRIM_ARY[] = +{ + NC_("SC_OPCODE_TRIM", "Removes extra spaces from text."), + NC_("SC_OPCODE_TRIM", "text"), + NC_("SC_OPCODE_TRIM", "The text in which extra spaces between words are to be deleted.") +}; + +// -=*# Resource for function PROPER #*=- +const char* SC_OPCODE_PROPER_ARY[] = +{ + NC_("SC_OPCODE_PROPER", "Capitalizes the first letter in all words."), + NC_("SC_OPCODE_PROPER", "text"), + NC_("SC_OPCODE_PROPER", "The text in which the beginning of words are to be replaced by capital letters.") +}; + +// -=*# Resource for function UPPER #*=- +const char* SC_OPCODE_UPPER_ARY[] = +{ + NC_("SC_OPCODE_UPPER", "Converts text to uppercase."), + NC_("SC_OPCODE_UPPER", "text"), + NC_("SC_OPCODE_UPPER", "The text in which lower case letters are to be converted to capitals.") +}; + +// -=*# Resource for function LOWER #*=- +const char* SC_OPCODE_LOWER_ARY[] = +{ + NC_("SC_OPCODE_LOWER", "Converts text to lowercase."), + NC_("SC_OPCODE_LOWER", "text"), + NC_("SC_OPCODE_LOWER", "The text in which capitals are converted to lower case letters.") +}; + +// -=*# Resource for function VALUE #*=- +const char* SC_OPCODE_VALUE_ARY[] = +{ + NC_("SC_OPCODE_VALUE", "Converts text to a number."), + NC_("SC_OPCODE_VALUE", "text"), + NC_("SC_OPCODE_VALUE", "The text to be converted to a number.") +}; + +// -=*# Resource for function TEXT #*=- +const char* SC_OPCODE_TEXT_ARY[] = +{ + NC_("SC_OPCODE_TEXT", "Converts a number to text according to a given format."), + NC_("SC_OPCODE_TEXT", "number"), + NC_("SC_OPCODE_TEXT", "The numeric value to be converted."), + NC_("SC_OPCODE_TEXT", "Format"), + NC_("SC_OPCODE_TEXT", "The text that describes the format.") +}; + +// -=*# Resource for function T #*=- +const char* SC_OPCODE_T_ARY[] = +{ + NC_("SC_OPCODE_T", "Returns a value if it is text, otherwise an empty string."), + NC_("SC_OPCODE_T", "value"), + NC_("SC_OPCODE_T", "The value to be checked and returned if it is text.") +}; + +// -=*# Resource for function REPLACE #*=- +const char* SC_OPCODE_REPLACE_ARY[] = +{ + NC_("SC_OPCODE_REPLACE", "Replaces characters within a text string with a different text string."), + NC_("SC_OPCODE_REPLACE", "Text"), + NC_("SC_OPCODE_REPLACE", "The text in which some characters are to be replaced."), + NC_("SC_OPCODE_REPLACE", "position"), + NC_("SC_OPCODE_REPLACE", "The character position from which text is to be replaced."), + NC_("SC_OPCODE_REPLACE", "length"), + NC_("SC_OPCODE_REPLACE", "The number of characters to be replaced."), + NC_("SC_OPCODE_REPLACE", "new text"), + NC_("SC_OPCODE_REPLACE", "The text to be inserted.") +}; + +// -=*# Resource for function FIXED #*=- +const char* SC_OPCODE_FIXED_ARY[] = +{ + NC_("SC_OPCODE_FIXED", "Formats a number with a fixed number of places after the decimal point and thousands separator."), + NC_("SC_OPCODE_FIXED", "number"), + NC_("SC_OPCODE_FIXED", "The number to be formatted."), + NC_("SC_OPCODE_FIXED", "Decimals"), + NC_("SC_OPCODE_FIXED", "Decimal places. The number of fixed decimal places that are to be displayed."), + NC_("SC_OPCODE_FIXED", "No thousands separators"), + NC_("SC_OPCODE_FIXED", "Thousands separator. If 0 or omitted the locale group separator is used else the separator is suppressed.") +}; + +// -=*# Resource for function LEN #*=- +const char* SC_OPCODE_LEN_ARY[] = +{ + NC_("SC_OPCODE_LEN", "Calculates length of a text string."), + NC_("SC_OPCODE_LEN", "text"), + NC_("SC_OPCODE_LEN", "The text in which the length is to be determined.") +}; + +// -=*# Resource for function LEFT #*=- +const char* SC_OPCODE_LEFT_ARY[] = +{ + NC_("SC_OPCODE_LEFT", "Returns the first character or characters of a text."), + NC_("SC_OPCODE_LEFT", "text"), + NC_("SC_OPCODE_LEFT", "The text where the initial partial words are to be determined."), + NC_("SC_OPCODE_LEFT", "number"), + NC_("SC_OPCODE_LEFT", "The number of characters for the start text.") +}; + +// -=*# Resource for function RIGHT #*=- +const char* SC_OPCODE_RIGHT_ARY[] = +{ + NC_("SC_OPCODE_RIGHT", "Returns the last character or characters of a text."), + NC_("SC_OPCODE_RIGHT", "text"), + NC_("SC_OPCODE_RIGHT", "The text in which the end partial words are to be determined."), + NC_("SC_OPCODE_RIGHT", "number"), + NC_("SC_OPCODE_RIGHT", "The number of characters for the end text.") +}; + +// -=*# Resource for function MID #*=- +const char* SC_OPCODE_MID_ARY[] = +{ + NC_("SC_OPCODE_MID", "Returns a partial text string of a text."), + NC_("SC_OPCODE_MID", "text"), + NC_("SC_OPCODE_MID", "The text in which partial words are to be determined."), + NC_("SC_OPCODE_MID", "start"), + NC_("SC_OPCODE_MID", "The position from which the part word is to be determined."), + NC_("SC_OPCODE_MID", "number"), + NC_("SC_OPCODE_MID", "The number of characters for the text.") +}; + +// -=*# Resource for function REPT #*=- +const char* SC_OPCODE_REPT_ARY[] = +{ + NC_("SC_OPCODE_REPT", "Repeats text a given number of times."), + NC_("SC_OPCODE_REPT", "text"), + NC_("SC_OPCODE_REPT", "The text to be repeated."), + NC_("SC_OPCODE_REPT", "number"), + NC_("SC_OPCODE_REPT", "The number of times the text is to be repeated.") +}; + +// -=*# Resource for function SUBSTITUTE #*=- +const char* SC_OPCODE_SUBSTITUTE_ARY[] = +{ + NC_("SC_OPCODE_SUBSTITUTE", "Substitutes new text for old text in a string."), + NC_("SC_OPCODE_SUBSTITUTE", "text"), + NC_("SC_OPCODE_SUBSTITUTE", "The text in which partial words are to be replaced."), + NC_("SC_OPCODE_SUBSTITUTE", "search_text"), + NC_("SC_OPCODE_SUBSTITUTE", "The partial string to be (repeatedly) replaced."), + NC_("SC_OPCODE_SUBSTITUTE", "new text"), + NC_("SC_OPCODE_SUBSTITUTE", "The text which is to replace the text string."), + NC_("SC_OPCODE_SUBSTITUTE", "occurrence"), + NC_("SC_OPCODE_SUBSTITUTE", "Which occurrence of the old text is to be replaced.") +}; + +// -=*# Resource for function BASE #*=- +const char* SC_OPCODE_BASE_ARY[] = +{ + NC_("SC_OPCODE_BASE", "Converts a positive integer to text from a number system to the base defined."), + NC_("SC_OPCODE_BASE", "number"), + NC_("SC_OPCODE_BASE", "The number to be converted."), + NC_("SC_OPCODE_BASE", "radix"), + NC_("SC_OPCODE_BASE", "The base number for conversion must be in the range 2 - 36."), + NC_("SC_OPCODE_BASE", "Minimum length"), + NC_("SC_OPCODE_BASE", "If the text is shorter than the specified length, zeros are added to the left of the string.") +}; + +// -=*# Resource for function DECIMAL #*=- +const char* SC_OPCODE_DECIMAL_ARY[] = +{ + NC_("SC_OPCODE_DECIMAL", "Converts a text of a specified number system to a positive integer in the base given."), + NC_("SC_OPCODE_DECIMAL", "text"), + NC_("SC_OPCODE_DECIMAL", "The text to be converted."), + NC_("SC_OPCODE_DECIMAL", "radix"), + NC_("SC_OPCODE_DECIMAL", "The base number for conversion must be in the range 2 - 36.") +}; + +// -=*# Resource for function CONVERT_OOO #*=- +const char* SC_OPCODE_CONVERT_OOO_ARY[] = +{ + NC_("SC_OPCODE_CONVERT_OOO", "Converts a value according to a conversion table in the configuration (main.xcd)."), + NC_("SC_OPCODE_CONVERT_OOO", "value"), + NC_("SC_OPCODE_CONVERT_OOO", "The value to be converted."), + NC_("SC_OPCODE_CONVERT_OOO", "text"), + NC_("SC_OPCODE_CONVERT_OOO", "Unit from which something is converted, case-sensitive."), + NC_("SC_OPCODE_CONVERT_OOO", "text"), + NC_("SC_OPCODE_CONVERT_OOO", "Unit into which something is converted, case-sensitive.") +}; + +// -=*# Resource for function ROMAN #*=- +const char* SC_OPCODE_ROMAN_ARY[] = +{ + NC_("SC_OPCODE_ROMAN", "Converts a number to a Roman numeral."), + NC_("SC_OPCODE_ROMAN", "Number"), + NC_("SC_OPCODE_ROMAN", "The number to be converted to a Roman numeral must be in the 0 - 3999 range."), + NC_("SC_OPCODE_ROMAN", "Mode"), + NC_("SC_OPCODE_ROMAN", "The more this value increases, the more the Roman numeral is simplified. The value must be in the 0 - 4 range.") +}; + +// -=*# Resource for function ARABIC #*=- +const char* SC_OPCODE_ARABIC_ARY[] = +{ + NC_("SC_OPCODE_ARABIC", "Calculates the value of a Roman numeral."), + NC_("SC_OPCODE_ARABIC", "Text"), + NC_("SC_OPCODE_ARABIC", "The text that represents a Roman numeral.") +}; + +const char* SC_OPCODE_INFO_ARY[] = +{ + NC_("SC_OPCODE_INFO", "Returns information about the environment."), + NC_("SC_OPCODE_INFO", "Text"), + NC_("SC_OPCODE_INFO", "Can be \"osversion\", \"system\", \"release\", \"numfile\", and \"recalc\".") +}; + +const char* SC_OPCODE_UNICODE_ARY[] = +{ + NC_("SC_OPCODE_UNICODE", "Returns the numeric code for the first Unicode character in a text string."), + NC_("SC_OPCODE_UNICODE", "text"), + NC_("SC_OPCODE_UNICODE", "This is the text for which the code of the first character is to be found.") +}; + +const char* SC_OPCODE_UNICHAR_ARY[] = +{ + NC_("SC_OPCODE_UNICHAR", "Converts a code number into a Unicode character or letter."), + NC_("SC_OPCODE_UNICHAR", "number"), + NC_("SC_OPCODE_UNICHAR", "The code value for the character.") +}; + +const char* SC_OPCODE_EUROCONVERT_ARY[] = +{ + NC_("SC_OPCODE_EUROCONVERT", "Converts a value from one to another Euro currency."), + NC_("SC_OPCODE_EUROCONVERT", "value"), + NC_("SC_OPCODE_EUROCONVERT", "The value to be converted."), + NC_("SC_OPCODE_EUROCONVERT", "from_currency"), + NC_("SC_OPCODE_EUROCONVERT", "ISO 4217 code of the currency from which is converted, case-sensitive."), + NC_("SC_OPCODE_EUROCONVERT", "to_currency"), + NC_("SC_OPCODE_EUROCONVERT", "ISO 4217 code of the currency into which is converted, case-sensitive."), + NC_("SC_OPCODE_EUROCONVERT", "full_precision"), + NC_("SC_OPCODE_EUROCONVERT", "If omitted or 0 or FALSE, the result is rounded to the decimals of to_currency. Else the result is not rounded."), + NC_("SC_OPCODE_EUROCONVERT", "triangulation_precision"), + /* This description uses almost all available space in the dialog, make sure translations fit in size */ + NC_("SC_OPCODE_EUROCONVERT", "If given and >=3, the intermediate result of a triangular conversion is rounded to that precision. If omitted, the result is not rounded.") +}; + +const char* SC_OPCODE_NUMBERVALUE_ARY[] = +{ + NC_("SC_OPCODE_NUMBERVALUE", "Converts text to a number, in a locale-independent way."), + NC_("SC_OPCODE_NUMBERVALUE", "text"), + NC_("SC_OPCODE_NUMBERVALUE", "The text to be converted to a number."), + NC_("SC_OPCODE_NUMBERVALUE", "decimal_separator"), + NC_("SC_OPCODE_NUMBERVALUE", "Defines the character used as the decimal separator."), + NC_("SC_OPCODE_NUMBERVALUE", "group_separator"), + NC_("SC_OPCODE_NUMBERVALUE", "Defines the character(s) used as the group separator.") +}; + + +const char* SC_OPCODE_BITAND_ARY[] = +{ + NC_("SC_OPCODE_BITAND", "Bitwise \"AND\" of two integers."), + NC_("SC_OPCODE_BITAND", "Number1"), + NC_("SC_OPCODE_BITAND", "Positive integer less than 2^48."), + NC_("SC_OPCODE_BITAND", "Number2"), + NC_("SC_OPCODE_BITAND", "Positive integer less than 2^48.") +}; + +const char* SC_OPCODE_BITOR_ARY[] = +{ + NC_("SC_OPCODE_BITOR", "Bitwise \"OR\" of two integers."), + NC_("SC_OPCODE_BITOR", "Number1"), + NC_("SC_OPCODE_BITOR", "Positive integer less than 2^48."), + NC_("SC_OPCODE_BITOR", "Number2"), + NC_("SC_OPCODE_BITOR", "Positive integer less than 2^48.") +}; + +const char* SC_OPCODE_BITXOR_ARY[] = +{ + NC_("SC_OPCODE_BITXOR", "Bitwise \"exclusive OR\" of two integers."), + NC_("SC_OPCODE_BITXOR", "Number1"), + NC_("SC_OPCODE_BITXOR", "Positive integer less than 2^48."), + NC_("SC_OPCODE_BITXOR", "Number2"), + NC_("SC_OPCODE_BITXOR", "Positive integer less than 2^48.") +}; + +const char* SC_OPCODE_BITRSHIFT_ARY[] = +{ + NC_("SC_OPCODE_BITRSHIFT", "Bitwise right shift of an integer value."), + NC_("SC_OPCODE_BITRSHIFT", "Number"), + NC_("SC_OPCODE_BITRSHIFT", "The value to be shifted. Positive integer less than 2^48."), + NC_("SC_OPCODE_BITRSHIFT", "Shift"), + NC_("SC_OPCODE_BITRSHIFT", "The integer number of bits the value is to be shifted.") +}; + +const char* SC_OPCODE_BITLSHIFT_ARY[] = +{ + NC_("SC_OPCODE_BITLSHIFT", "Bitwise left shift of an integer value."), + NC_("SC_OPCODE_BITLSHIFT", "Number"), + NC_("SC_OPCODE_BITLSHIFT", "The value to be shifted. Positive integer less than 2^48."), + NC_("SC_OPCODE_BITLSHIFT", "Shift"), + NC_("SC_OPCODE_BITLSHIFT", "The integer number of bits the value is to be shifted.") +}; + +const char* SC_OPCODE_LENB_ARY[] = +{ + NC_("SC_OPCODE_LENB", "Calculates length of a text string, with DBCS"), + NC_("SC_OPCODE_LENB", "text"), + NC_("SC_OPCODE_LENB", "The text in which the length is to be determined.") +}; + +const char* SC_OPCODE_RIGHTB_ARY[] = +{ + NC_("SC_OPCODE_RIGHTB", "Returns the last character or characters of a text,with DBCS"), + NC_("SC_OPCODE_RIGHTB", "text"), + NC_("SC_OPCODE_RIGHTB", "The text in which the end partial words are to be determined."), + NC_("SC_OPCODE_RIGHTB", "number"), + NC_("SC_OPCODE_RIGHTB", "The number of characters for the end text.") +}; + +const char* SC_OPCODE_LEFTB_ARY[] = +{ + NC_("SC_OPCODE_LEFTB", "Returns the first character or characters of a text,with DBCS"), + NC_("SC_OPCODE_LEFTB", "text"), + NC_("SC_OPCODE_LEFTB", "The text where the initial partial words are to be determined."), + NC_("SC_OPCODE_LEFTB", "number"), + NC_("SC_OPCODE_LEFTB", "The number of characters for the start text.") +}; + +const char* SC_OPCODE_MIDB_ARY[] = +{ + NC_("SC_OPCODE_MIDB", "Returns a partial text string of a text, with DBCS"), + NC_("SC_OPCODE_MIDB", "text"), + NC_("SC_OPCODE_MIDB", "The text in which partial words are to be determined."), + NC_("SC_OPCODE_MIDB", "start"), + NC_("SC_OPCODE_MIDB", "The position from which the part word is to be determined."), + NC_("SC_OPCODE_MIDB", "number"), + NC_("SC_OPCODE_MIDB", "The number of characters for the text.") +}; + +const char* SC_OPCODE_FILTERXML_ARY[] = +{ + NC_("SC_OPCODE_FILTERXML", "Apply an XPath expression to an XML document"), + NC_("SC_OPCODE_FILTERXML", "XML Document"), + NC_("SC_OPCODE_FILTERXML", "String containing a valid XML stream"), + NC_("SC_OPCODE_FILTERXML", "XPath expression"), + NC_("SC_OPCODE_FILTERXML", "String containing a valid XPath expression") +}; + +const char* SC_OPCODE_COLOR_ARY[] = +{ + NC_("SC_OPCODE_COLOR", "Returns an implementation defined value representing a RGBA color"), + NC_("SC_OPCODE_COLOR", "Red"), + NC_("SC_OPCODE_COLOR", "Value of red"), + NC_("SC_OPCODE_COLOR", "Green"), + NC_("SC_OPCODE_COLOR", "Value of green"), + NC_("SC_OPCODE_COLOR", "Blue"), + NC_("SC_OPCODE_COLOR", "Value of blue"), + NC_("SC_OPCODE_COLOR", "Alpha"), + NC_("SC_OPCODE_COLOR", "Value of alpha") +}; + +const char* SC_OPCODE_WEBSERVICE_ARY[] = +{ + NC_("SC_OPCODE_WEBSERVICE", "Get some webcontent from an URI."), + NC_("SC_OPCODE_WEBSERVICE", "URI"), + NC_("SC_OPCODE_WEBSERVICE", "URI of the webservice") +}; + +const char* SC_OPCODE_ENCODEURL_ARY[] = +{ + NC_("SC_OPCODE_ENCODEURL", "Return a URL-encoded string."), + NC_("SC_OPCODE_ENCODEURL", "Text"), + NC_("SC_OPCODE_ENCODEURL", "A string to be URL-encoded") +}; + +const char* SC_OPCODE_ERF_MS_ARY[] = +{ + NC_("SC_OPCODE_ERF_MS", "Returns the error function."), + NC_("SC_OPCODE_ERF_MS", "Lower Limit"), + NC_("SC_OPCODE_ERF_MS", "The lower limit for integration") +}; + +const char* SC_OPCODE_ERFC_MS_ARY[] = +{ + NC_("SC_OPCODE_ERFC_MS", "Returns the complementary error function."), + NC_("SC_OPCODE_ERFC_MS", "Lower Limit"), + NC_("SC_OPCODE_ERFC_MS", "The lower limit for integration") +}; + +const char* SC_OPCODE_RAWSUBTRACT_ARY[] = +{ + NC_("SC_OPCODE_RAWSUBTRACT", "Returns the subtraction of numbers. Like a-b-c but without eliminating small roundoff errors."), + NC_("SC_OPCODE_RAWSUBTRACT", "minuend"), + NC_("SC_OPCODE_RAWSUBTRACT", "Number from which following arguments are subtracted."), + NC_("SC_OPCODE_RAWSUBTRACT", "subtrahend "), + NC_("SC_OPCODE_RAWSUBTRACT", "Subtrahend 1, subtrahend 2, ... are numerical arguments subtracted from the minuend.") +}; + +// -=*# Resource for function ROUNDSIG #*=- +const char* SC_OPCODE_ROUNDSIG_ARY[] = +{ + NC_("SC_OPCODE_ROUNDSIG", "Rounds a number to predefined significant digits."), + NC_("SC_OPCODE_ROUNDSIG", "value"), + NC_("SC_OPCODE_ROUNDSIG", "The number to be rounded."), + NC_("SC_OPCODE_ROUNDSIG", "digits"), + NC_("SC_OPCODE_ROUNDSIG", "The number of significant digits to which value is to be rounded.") +}; + +const char* SC_OPCODE_REPLACEB_ARY[] = +{ + NC_("SC_OPCODE_REPLACEB", "Replaces characters within a text string with a different text string, with DBCS."), + NC_("SC_OPCODE_REPLACEB", "Text"), + NC_("SC_OPCODE_REPLACEB", "The text in which some characters are to be replaced."), + NC_("SC_OPCODE_REPLACEB", "position"), + NC_("SC_OPCODE_REPLACEB", "The character position from which text is to be replaced."), + NC_("SC_OPCODE_REPLACEB", "length"), + NC_("SC_OPCODE_REPLACEB", "The number of characters to be replaced."), + NC_("SC_OPCODE_REPLACEB", "new text"), + NC_("SC_OPCODE_REPLACEB", "The text to be inserted.") +}; + +#endif /* vim:set shiftwidth=4 softtabstop=4 expandtab: */ |