ABAP

Paradigms	Object-oriented, structured,imperative
Designed by	SAP AG
Appeared in	1983
Typing discipline	Static, strong, safe, nominative
Major implementations SAP R/2, SAP R/3
Influenced by	Objective-C,[citation needed]COBOL,[1][2] SQL[citation needed]
OS	Cross-platform

ABAP (Advanced Business Application Programming, originally Allgemeiner Berichts-Aufbereitungs-Prozessor, German for "general report creation processor"^[3]) is a high-level programming language created by the German software company SAP. It is currently positioned, alongside the more recently introduced Java, as the language for programming the SAP Application Server, part of its NetWeaver platform for building business applications. The syntax of ABAP is somewhat similar to COBOL.

Introduction

ABAP is one of the many application-specific fourth-generation languages (4GLs) first developed in the 1980s. It was originally the report language for SAP R/2, a platform that enabled large corporations to build mainframe business applications for materials management and financial and management accounting.

ABAP used to be an abbreviation of Allgemeiner BerichtsAufbereitungsProzessor, German for "generic report preparation processor", but was later renamed to the EnglishAdvanced Business Application Programming. ABAP was one of the first languages to include the concept of Logical Databases (LDBs), which provides a high level of abstraction from the basic database level(s).

The ABAP language was originally used by developers to develop the SAP R/3 platform. It was also intended to be used by SAP customers to enhance SAP applications – customers can develop custom reports and interfaces with ABAP programming. The language is fairly easy to learn^[opinion] for programmers but it is not a tool for direct use by non-programmers. Knowledge of relational database design and preferably also of object-oriented concepts is necessary to create ABAP programs.

ABAP remains as the language for creating programs for the client-server R/3 system, which SAP first released in 1992. As computer hardware evolved through the 1990s, more and more of SAP's applications and systems were written in ABAP. By 2001, all but the most basic functions were written in ABAP. In 1999, SAP released an object-oriented extension to ABAP called ABAP Objects, along with R/3 release 4.6.

SAP's current development platform NetWeaver supports both ABAP and Java.

ABAP runtime environment

All ABAP programs reside inside the SAP database. They are not stored in separate external files like Java or C++ programs. In the database all ABAP code exists in two forms: source code, which can be viewed and edited with the ABAP Workbench tools; and generated code, a binary representation somewhat comparable with Java bytecode. ABAP programs execute under the control of the runtime system, which is part of the SAP kernel. The runtime system is responsible for processing ABAP statements, controlling the flow logic of screens and responding to events (such as a user clicking on a screen button); in this respect it can be seen as a Virtual Machine comparable with the Java VM. A key component of the ABAP runtime system is the Database Interface, which turns database-independent ABAP statements ("Open SQL") into statements understood by the underlying DBMS ("Native SQL"). The database interface handles all the communication with the relational database on behalf of ABAP programs; It also contains extra features such as buffering of tables and frequently accessed data in the local memory of the application server.

SAP Basis

Abstraction between the business applications, the operating system and database. This ensures that applications do not depend directly upon a specific server or database platform and can easily be ported from one platform to another.

SAP Basis currently runs on UNIX (AIX, HP-UX, Solaris, Linux), Microsoft Windows, i5/OS on IBM System i (formerly iSeries, AS/400), and z/OS on IBM System z (formerly zSeries, S/390). Supported databases are IBM DB2, Informix, MaxDB, Oracle, and Microsoft SQL Server (support for Informix was discontinued in SAP Basis release 7.00).

SAP systems and landscapes

All SAP data exists and all SAP software runs in the context of a SAP system. A system consists of a central relational database and one or more application servers ("instances") accessing the data and programs in this database. A SAP system contains at least one instance but may contain more, mostly for reasons of sizing and performance. In a system with multiple instances, load balancing mechanisms ensure that the load is spread evenly over the available application servers.

Installations of the Web Application Server (landscapes) typically consist of three systems: one for development; one for testing and quality assurance; and one for production. The landscape may contain more systems (e.g., separate systems for unit testing and pre-production testing) or it may contain fewer (e.g., only development and production, without separate QA); nevertheless three is the most common configuration. ABAP programs are created and undergo first testing in the development system. Afterwards they are distributed to the other systems in the landscape. These actions take place under control of the Change and Transport System (CTS), which is responsible for concurrency control (e.g., preventing two developers from changing the same code at the same time), version management, and deployment of programs on the QA and production systems.

The Web Application Server consists of three layers: the database layer; the application layer; and the presentation layer. These layers may run on the same or on different physical machines. The database layer contains the relational database and the database software. The application layer knowledge contains the instance or instances of the system. All application processes, including the business transactions and the ABAP development, run on the application layer. The presentation layer handles the interaction with users of the system. Online access to ABAP application servers can go via a proprietary graphical interface, which is called "SAP GUI", or via a Web browser.

Transactions

A transaction in SAP terminology is the execution of a program. The normal way of executing ABAP code in the SAP system is by entering a transaction code (for instance, VA01 is the transaction code for "Create Sales Order"). Transactions can be called via system-defined or user-specific, role-based menus. They can also be started by entering the transaction code directly into a command field, which is present in every SAP screen. Transactions can also be invoked programmatically by means of the ABAP statements CALL TRANSACTION and LEAVE TO TRANSACTION.

The term "transaction" must not be misunderstood here; in the context just described, a transaction simply means calling and executing an ABAP program. In application programming, "transaction" often refers to an indivisible operation on data, which is either committed as a whole or undone (rolled back) as a whole. This concept exists in SAP and is called a LUW (Logical Unit of Work). In the course of one transaction (program execution), there can be different LUWs. Transaction for ABAP Workbench could be invoked using transaction code SE80 to work on all ABAP development related activities.^{[citation needed]}

Types of ABAP programs

As in other programming languages, an ABAP program is either an executable unit or a library, which provides reusable code to other programs and is not independently executable.

ABAP distinguishes two types of executable programs:

• Reports
• Module pools

Reports follow a relatively simple programming model whereby a user optionally enters a set of parameters (e.g., a selection over a subSET of data) and the program then uses the input parameters to produce a report in the form of an interactive list. The term "report" can be somewhat misleading in that reports can also be designed to modify data; the reason why these programs are called reports is the "list-oriented" nature of the output they produce.

Module pools define more complex patterns of user interaction using a collection of screens. The term “screen” refers to the actual, physical image that the user sees. Each screen also has a "flow logic", which refers to the ABAP code implicitly invoked by the screens, which is divided into a "PBO" (Process Before Output) and "PAI" (Process After Input) section. In SAP documentation the term “dynpro” (dynamic program) refers to the combination of the screen and its flow logic.

The non-executable program types are:

• INCLUDE modules
• Subroutine pools
• Function groups
• Object classes
• Interfaces
• Type pools

An INCLUDE module gets included at generation time into the calling unit; it is often used to subdivide very large programs. Subroutine pools contain ABAP subroutines (blocks of code enclosed by FORM/ENDFORM statements and invoked with PERFORM). Function groups are libraries of self-contained function modules (enclosed by FUNCTION/ENDFUNCTION and invoked with CALL FUNCTION). Object classes and interfaces are similar to Java classes and interfaces; the first define a set of methods and attributes, the second contain "empty" method definitions, for which any class implementing the interface must provide explicit code. Type pools define collections of data types and constants.

ABAP programs are composed of individual sentences (statements). The first word in a statement is called an ABAP keyword. Each statement ends with a period. Words must always be separated by at least one space. Statements can be indented as you wish. With keywords, additions and operands, the ABAP runtime system does not differentiate between upper and lowercase.

Statements can extend beyond one line. You can have several statements in a single line (though this is not recommended). Lines that begin with asterisk * in the first column are recognized as comment lines by the ABAP runtime system and are ignored. Double quotations marks (") indicate that the remainder of a line is a comment.

ABAP Workbench

The ABAP Workbench contains different tools for editing programs. The most important of these are (transaction codes are shown in parentheses):

• ABAP Editor for writing and editing reports, module pools, includes and subroutine pools (SE38)
• ABAP Dictionary for processing database table definitions and retrieving global types (SE11)
• Menu Painter for designing the user interface (menu bar, standard toolbar, application toolbar, function key assignment) (SE41)
• Screen Painter for designing screens and flow logic (SE51)
• Function Builder for function modules (SE37)
• Class Builder for ABAP Objects classes and interfaces (SE24)

The Object Navigator (transaction SE80) provides a single integrated interface into these various tools.

ABAP Coding Dictionary

The ABAP Dictionary contains all metadata about the data in the SAP system. It is closely linked with the ABAP Workbench in that any reference to data (e.g., a table, a view, or a data type) will be obtained from the dictionary. Developers use the ABAP Dictionary transactions (directly or through the SE80 Object Navigator inside the ABAP Workbench) to display and maintain this metadata.

When a dictionary object is changed, a program that references the changed object will automatically reference the new version the next time the program runs. Because ABAP is interpreted, it is not necessary to recompile programs that reference changed dictionary objects.

A brief description of the most important types of dictionary objects follows:

• Tables are data containers that exist in the underlying relational database. In the majority of cases there is a 1-to-1 relationship between the definition of a table in the ABAP Dictionary and the definition of that same table in the database (same name, same columns). These tables are known as "transparent". There are two types of non-transparent tables: "pooled" tables exist as independent entities in the ABAP Dictionary but they are grouped together in large physical tables ("pools") at the database level. Pooled tables are often small tables holding for example configuration data. "Clustered" tables are physically grouped in "clusters" based on their primary keys; for instance, assume that a clustered table H contains "header" data about sales invoices, whereas another clustered table D holds the invoice line items. Each row of H would then be physically grouped with the related rows from D inside a "cluster table" in the database. This type of clustering, which is designed to improve performance, also exists as native functionality in some, though not all, relational database systems.

• Indexes provide accelerated access to table data for often used selection conditions. Every SAP table has a "primary index", which is created implicitly along with the table and is used to enforce primary key uniqueness. Additional indexes (unique or non-unique) may be defined; these are called "secondary indexes".
• Views have the same purpose as in the underlying database: they define subsets of columns (and/or rows) from one or - using a join condition - several tables. View is actually a virtual table which does not contain data physically. Views take very short memory space in database because the views contain only the definition of data.
• Structures are complex data types consisting of multiple fields (comparable to struct in C/C++).
• Data elements provide the semantic content for a table or structure field. For example, dozens of tables and structures might contain a field giving the price (of a finished product, raw material, resource, ...). All these fields could have the same data element "PRICE".
• Domains define the structural characteristics of a data element. For example, the data element PRICE could have an assigned domain that defines the price as a numeric field with two decimals. Domains can also carry semantic content in providing a list of possible values. For example, a domain "BOOLEAN" could define a field of type "character" with length 1 and case-insensitive, but would also restrict the possible values to "T" (true) or "F" (false).
• Search helps (successors to the now obsolete "matchcodes") provide advanced search strategies when a user wants to see the possible values for a data field. The ABAP runtime provides implicit assistance (by listing all values for the field, e.g. all existing customer numbers) but search helps can be used to refine this functionality, e.g. by providing customer searches by geographical location, credit rating, etc.
• Lock objects implement application-level locking when changing data.

ABAP syntax

This brief description of the ABAP syntax begins inevitably with the ubiquitous "Hello world" program.

"Hello World"

REPORT TEST.
WRITE 'Hello World'.

This example contains two statements: REPORT and WRITE. The program displays a list on the screen. In this case, the list consists of the single line "Hello World". The REPORT statement indicates that this program is a report. An alternative statement, PROGRAM, would be used for a module pool arpit.

Chained statements

Consecutive statements with an identical first (leftmost) part can be combined into a "chained" statement using the chain operator ":" (colon). The common part of the statements is written to the left of the colon, the differing parts are written to the right of the colon and separated by commas. The colon operator is attached directly to the preceding token, without a space (the same applies to the commas in the token list on, as can be seen in the examples below).

Chaining is very often used in WRITE statements. WRITE accepts just one argument, so if for instance you wanted to display three fields from a structure called FLIGHTINFO, you would have to code:

WRITE FLIGHTINFO-CITYFROM.
WRITE FLIGHTINFO-CITYTO.
WRITE FLIGHTINFO-AIRPTO.

Chaining the statements results in a more readable and more intuitive form:

WRITE: FLIGHTINFO-CITYFROM, FLIGHTINFO-CITYTO, FLIGHTINFO-AIRPTO.

In a chain statement, the first part (before the colon) is not limited to the statement name alone. The entire common part of the consecutive statements can be placed before the colon. Example:

REPLACE 'A' WITH 'B' INTO LASTNAME.
REPLACE 'A' WITH 'B' INTO FIRSTNAME.
REPLACE 'A' WITH 'B' INTO CITYNAME.

could be rewritten in chained form as:

REPLACE 'A' WITH 'B' INTO: LASTNAME, FIRSTNAME, CITYNAME.

ABAP has 2 ways of defining text as a comment:

• An asterisk (*) in the leftmost column of a line makes the entire line a comment
• A double quotation mark (") anywhere on a line makes the rest of that line a comment

Example:

***************************************
** Program: BOOKINGS                 **
** Author: Joe Byte, 07-Jul-2007     **
***************************************
 
REPORT BOOKINGS.
 
* Read flight bookings from the database
SELECT * FROM FLIGHTINFO
  WHERE CLASS = 'Y'       "Y = economy
  OR    CLASS = 'C'.      "C = business
(...)

Data types and variables

ABAP provides a set of built-in data types. In addition, every structure, table, view or data element defined in the ABAP Dictionary can be used to type a variable. Also, object classes and interfaces can be used as types.

The built-in data types are:

Type	Description
I	Integer
P	Packed decimal
F	Floating point
N	Character numeric
C	Character
D	Date
T	Time
X	Hexadecimal (raw byte)
STRING	Variable-length string
XSTRING	Variable-length raw byte array

Date variables or constants (type D) contain the number of days since January 1, 1 AD. Time variables or constants (type T) contain the number of seconds since midnight. A special characteristic of both types is that they can be accessed both as integers and as character strings (with internal format "YYYYMMDD" for dates and "hhmmss" for times), which makes date/time handling very easy. For example, the code snippet below calculates the last day of the previous month (note: SY-DATUM is a system-defined variable containing the current date):

DATA LAST_EOM    TYPE D.  "last end-of-month date
 
* Start from today's date
  LAST_EOM = SY-DATUM.
* Set characters 6 and 7 (0-relative) of the YYYYMMDD string to "01",
* giving the first day of the current month
  LAST_EOM+6(2) = '01'.
* Subtract one day
  LAST_EOM = LAST_EOM - 1.
 
  WRITE: 'Last day of previous month was', LAST_EOM.

All ABAP variables must be explicitly declared in order to be used. Normally all declarations are placed at the top of the code module (program, subroutine, function) before the first executable statement; this placement is a convention and not an enforced syntax rule. The declaration consists of the name, type, length (where applicable), additional modifiers (e.g. the number of implied decimals for a packed decimal field) and optionally an initial value:

* Primitive types:
DATA: COUNTER      TYPE I,
      VALIDITY     TYPE I VALUE 60,
      TAXRATE(3)   TYPE P DECIMALS 1,
      LASTNAME(20) TYPE C,
      DESCRIPTION  TYPE STRING.
 
* Dictionary types:
DATA: ORIGIN       TYPE COUNTRY.
 
* Internal table:
DATA: T_FLIGHTS    TYPE TABLE OF FLIGHTINFO,
      T_LOOKUP     TYPE HASHED TABLE OF FLT_LOOKUP.
 
* Objects:
DATA: BOOKING      TYPE REF TO CL_FLT_BOOKING.

Notice the use of the colon to chain together consecutive DATA statements.

ABAP Objects

The ABAP language supports object-oriented programming, through a feature known as "ABAP Objects".^[4] This helps to simplify applications and make them more controllable.

ABAP Objects is fully compatible with the existing language, so one can use existing statements and modularization units in programs that use ABAP Objects, and can also use ABAP Objects in existing ABAP programs. Syntax checking is stronger in ABAP Objects programs, and some syntactical forms (usually older ones) of certain statements are not permitted.

ABAP statements – an overview

In contrast with languages like C/C++ or Java, which define a limited set of language-specific statements and provide most functionality via libraries, ABAP contains an extensive body of built-in statements. These statements often support many options, which explains why ABAP programs look "verbose", especially when compared with programs written in C, C++ or Java.

This section lists some of the most important statements in the language, subdivided by function. Both the statements listed here and the subdivision used are fairly arbitrary and by no means exhaustive.

Declarative statements

These statements define data types or declare data objects which are used by the other statements in a program or routine. The collected declarative statements in a program or routine make up its declaration part.

Examples of declarative statements:

TYPES, DATA, CONSTANTS, PARAMETERS, SELECT-OPTIONS, TABLES

Modularization statements

These statements define the processing blocks in an ABAP program.

The modularization statements can be further divided into event statements and defining statements:

Event statements

These are used to define the beginning of event processing blocks. There are no special statements to mark the end of such blocks - they end when the next processing block is introduced.

Examples of event keywords are:

LOAD OF PAGE,INITIALIZATION,AT SELECTION SCREEN OUTPUT,AT SELECTION SCREEN ON FIELD, AT SELECTION SCREEN ON BLOCK,
 AT SELECTION SCREEN, START-OF-SELECTION,END-OF-SELECTION, AT USER-COMMAND, AT LINE-SELECTION,GET,GET LATE,AT USER COMMAND,
AT LINE SELECTION

Defining statements

These statements delineate callable code units such as subroutines, function modules and methods. The statement marking the end of the unit has the name of the opening statement prefixed with "END".

Examples of defining keywords:

FORM ..... ENDFORM, FUNCTION ... ENDFUNCTION,
MODULE ... ENDMODULE, METHOD ... ENDMETHOD.

Control statements

These statements control the flow of the program within a processing block.

Statements controlling conditional execution are:

IF ... ELSEIF ... ELSE ... ENDIF
CASE ... WHEN ... ENDCASE
CHECK

The CHECK statement verifies a condition and exits the current processing block (e.g. loop or subroutine) if the condition is not satisfied.

Several statements exist to define a loop:

DO ... ENDDO
WHILE ... ENDWHILE
LOOP ... ENDLOOP

DO/ENDDO defines an unconditional loop. An exit condition (typically in the form "IF <condition>. EXIT. ENDIF.") must be provided inside the body of the loop. A variant (DO <n> TIMES) sets as exit condition the number of times the loop body is executed. WHILE/ENDWHILE defines a conditional loop. The condition is tested at the beginning of the loop. LOOP/ENDLOOP loops over the lines of an internal table. The loop ends after processing the last line of the internal table.

Call statements

These statements call processing blocks defined using the corresponding modularization statements. The blocks can either be in the same ABAP program or in a different program.

Examples of call keywords:

PERFORM, CALL METHOD, CALL TRANSACTION, CALL SCREEN, SUBMIT, LEAVE TO TRANSACTION, CALL FUNCTION

Operational statements

These statements retrieve or modify the contents of variables.

A first group of statements for numerical calculations:

ADD, SUBTRACT, MULTIPLY, DIVIDE

These statements, whose syntax originates in COBOL, can be written in a shorter form that uses operators rather than keywords:

ADD TAX TO PRICE.
* is equivalent to
PRICE = PRICE + TAX.

Examples of operational statements on character strings:

SEARCH, REPLACE, CONCATENATE, CONDENSE

Database access statements (Open SQL):

SELECT, INSERT, UPDATE, DELETE, MODIFY

Statements working on internal tables (notice that some "SQL" statements can also be used here):

READ TABLE, LOOP AT, INSERT, DELETE, MODIFY, SORT, DELETE ADJACENT DUPLICATES, APPEND, CLEAR, REFRESH, FREE

Formatting statements

You can use various formatting options with the WRITE statement.

Syntax

WRITE .... <f> <option>.

Formatting options for all data types

Option	Function
LEFT-JUSTIFIED	Output is left-justified.
CENTERED	Output is centered.
RIGHT-JUSTIFIED	Output is right-justified.
UNDER <g>	Output starts directly under field <g>.
NO-GAP	The blank after field <f> is omitted.
USING EDIT MASK <m>	Specifies format template <m>.
USING NO EDIT MASK	Deactivates a format template specified in the ABAP Dictionary.
NO-ZERO	If a field contains only zeros, these are replaced by blanks. For type C and N fields, leading zeros are replaced automatically.

Formatting options for numeric fields

Option	Function
NO-SIGN	The leading sign is not displayed on the screen.
DECIMALS <d>	<d> defines the number of digits after the decimal point.
EXPONENT <e>	In type F fields, the exponent is defined in <e>.
ROUND <r>	Type P fields are multiplied by 10**(-r) and then rounded.
CURRENCY <c>	Format according to currency <c> in table TCURX.
UNIT	The number of decimal places is fixed according to unit specified in table T006 for type P fields.

Formatting options for date fields

Option	Function
DD/MM/YY	Separators as defined in user’s master record.
MM/DD/YY	Separators as defined in user’s master record.
DD/MM/YYYY	Separators as defined in user’s master record.
MM/DD/YYYY	Separators as defined in user’s master record.
DDMMYY	No separators.
MMDDYY	No separators.
YYMMDD	No separators.

Internal tables in ABAP

Internal tables are an extremely important feature of the ABAP language. An internal table is defined as a vector of structs in C++ or a vector of objects in Java. The main difference with these languages is that ABAP provides a collection of statements to easily access and manipulate the contents of internal tables. Note that ABAP does not support arrays; the only way to define a multi-element data object is to use an internal table.^{[citation needed]}

Internal tables are a way to store variable datasets of a fixed structure in the working memory of ABAP, and provides the functionality of dynamic arrays. The data is stored on a row-by-row basis, where each row has the same structure.

Internal tables are preferably used to store and format the content of database tables from within a program. Furthermore, internal tables in connection with structures are the most important means of defining very complex data structures in an ABAP program.

Following example define an internal table with two fields with the format of database table VBRK.

Obsolete way:

* Define internal table with header line
DATA : BEGIN OF I_VBRK OCCURS 0,
         VBELN LIKE VBRK-VBELN,
         ZUONR LIKE VBRK-ZUONR,
       END OF I_VBRK.

Current way (from about version 4.6 and up):

* First define structured type
TYPES: BEGIN OF t_vbrk,
         VBELN TYPE VBRK-VBELN,
         ZUONR TYPE VBRK-ZUONR,
       END OF t_vbrk.
 
* Now define internal table of our defined type t_vbrk
DATA : gt_vbrk TYPE STANDARD TABLE OF t_vbrk,
       gt_vbrk_2 TYPE STANDARD TABLE OF t_vbrk.   "easy to define more tables
 
* If needed, define structure (line of internal table)
* Definition with type or with reference to internal table:
DATA : gs_vbrk TYPE t_vbrk,
       gs_vbrk2 LIKE LINE OF gt_vbrk2.
 
* You can also define table type if needed
TYPES tt_vbrk TYPE STANDARD TABLE OF t_vbrk.

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The Best Gemstone Countries on Earth

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by Bernie Gaboury

Filed Under: Australia

Where do our gemsones come from? We asked geologist and host of Gem Hunt, Bernie Gaboury, to give us a rundown of some of the world’s biggest producers of our favorite eye-catching stones. See where our sapphires, emeralds, opals, jade and rubies originate.

Colombia

Emeralds

Of all countries, Colombia mines the most emeralds, accounting for 70–90% of the world’s supply. Although indigenous people mined them in pre-colonial times, it was the Spanish conquistadores who first exploited Colombia’s emeralds commercially and internationally, forcing the conquered Indians to work in their mines. The geological forces that raised the Andes formed a particularly pure type of emerald, which is still mined today. Muzo is the most important of the 3 largest mines, which produce the finest emeralds.

Emeralds have also financed the on-going ”green war” in Colombia, involving left-wing guerrilla groups, right-wing paramilitary groups, Colombian drug cartels, and the Colombian government.

Lynn Gail / Getty

Madagascar

Sapphires

During the first few years of the 21st century, Madagascar produced about half the world’s sapphires. They were discovered in 1998, near the small town of Ilakaka, which has since boomed into a wild-west town with “sapphire fever” and a population of more than 30,000 people.

The surrounding countryside is pocked with pits, dug by small teams of poor fortune-seekers, who risk their lives to descend beneath the surface in search of sapphire-bearing soil. Ilakaka’s peak has passed: all the “easy” sapphires have been taken, and miners now have to dig further beneath the surface in hopes of finding their fortune. New sapphire deposits have been discovered in the Tamatave and Didy areas over the last 2 years.

In addition to Sapphire, Madagascar remains a treasure trove of other gems including aquamarine, morganite, emerald, tourmaline, spessartite, tsavorite, demantoid, and color-change garnets, to name a few.

Stephen J Boitano / Getty

Burma/Myanmar

Rubies

Rubies are the most expensive gem, by weight, in the world, and 90% of the world’s supply comes from Burma. The very finest are dug at Mogok, in Burma’s “Valley of Rubies.” The most productive pit at Mogok is the Safari mine, which produces 800 grams of gems per day: that’s 4,000 carats!

The gems are separated from gravel using high-pressure water cannons and sluices. Then the residue is painstakingly picked over by hand, for rubies and sapphires. Burma also produces significant gem spinel and Imperial jade. The jade of Burma can attain values to rival the best emerald or ruby.

Most gems from Burma are sold to buyers from Thailand, Malaysia, Singapore and other Asian countries. Until recently, many US and European jewelery companies refused to buy these gems, based on reports of terrible working conditions in the mines.

Sri Lanka

Various Gems

Since ancient times, the island of Sri Lanka has been known as the “Treasure Box of the Indian Ocean.” More than 50 varieties of gems are found here, including sapphires in every shade from yellow to cornflower blue.

The crown jewels of Russia, Great Britain and many other countries are studded with jewels from Sri Lankan mines. Ratnapura (“Gem Town”) is the center of the country’s mining industry. The gems are found in a clay deposit beneath the rice paddy fields in the surrounding countryside.

Using shovels and picks, miners dig pits as deep as 20 metres, and then tunnel sideways to excavate the clay. Once the clay has been brought to the surface, they sluice it in nearby rivers, using bamboo baskets, until the gems can be picked out.

Sri Lanka also produces a very coveted electric blue variety of Moonstone.

Auscape / UIG / Getty

Australia

Opal

A vast majority of the world’s supply of opal comes from Australia – around 97%. The best-known mines are found at Coober Pedy and Andamooka in South Australia and Lightning Ridge in New South Wales. Opals can show every color of the visible spectrum because of the way light diffracts through the stone’s molecules. This effect is enhanced by cutting a thin slice of opal, and attaching it to a backing of dark stone, such as basalt, to create a “doublet.”

Miners use bulldozers and mechanical diggers to find opal but once the precious stone is found, they stop the machines and extract it by hand. At Coober Pedy, the premier source of the world’s opals, old mines have been converted into underground houses.

Australia also produces blue sapphires from volcanic-related deposits. Up until the discovery of the sapphire fields in Ilakaka, Madagascar, Australia was the world’s leading producer of sapphire.

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