I Ching divination

Plastromancy or the turtle-shell oracle is probably the earliest recorded form of fortune telling. The diviner would apply heat to a piece of a turtle shell (sometimes with a hot poker), and interpret the resulting cracks. The cracks were sometimes annotated with inscriptions, the oldest Chinese writings that have been discovered. This oracle predated the earliest versions of the Zhou Yi (dated from about 1100 BC) by hundreds of years.

A variant on this method was to use ox shoulder bones, a practice called scapulimancy. When thick material was to be cracked, the underside was thinned by carving with a knife.

A bunch of 50 yarrow (Achillea millefolium subsp. millefolium var. millefolium) stalks, used for I Ching divination.

Hexagrams may be generated by the manipulation of yarrow stalks. These are usually genuine Achillea millefolium stalks that have been cut and prepared for such purposes, or any form of wooden rod or sticks (the quality ranging from cheap hardwood to very expensive red sandalwood, etc.) which are plain, lacquered, or varnished. When genuine Achillea is used, varieties local to the diviner are considered the best, as they would contain qi closer to, and more in tune with, the diviner, or they may come from a particularly spiritual or relevant place, such as on the grounds of a Confucian temple. When not in use, they are kept in a cloth or silk bag/pouch or a wooden case/box.

Fifty yarrow stalks are used, though one stalk is set aside at the beginning and takes no further part in the process of consultation. The remaining forty-nine stalks are roughly sorted into two piles, and then for each pile one stalk is initially "remaindered"; then the pile is "cast off" in lots of four (i.e., groups of four stalks are removed). The remainders from each half are combined (traditionally placed between the fingers of one hand during the counting process) and set aside, with the process then repeated twice (i.e., for a total of three times). The total number of stalks in the remainder pile will necessarily (if the procedure has been followed correctly) be 9 or 5, in the first count, and 8 or 4, in the second. 9 or 8 is assigned a value of 2; 5 or 4, a value of 3. The total of the three passes will be one of just four values: 6 (2+2+2), 7 (2+2+3), 8 (2+3+3), or 9 (3+3+3)—that value is the number of the first line.[1] The forty-nine stalks are then gathered and the entire procedure repeated to generate each of the remaining five lines of the hexagram.

The yarrow-stalk method produces unequal probabilities[2][3] for obtaining each of the four totals, as shown in the table. Compared to the three-coin method discussed next, the probabilities of the lines produced by the yarrow-stalk method are significantly different.

Note that the Yarrow algorithm is a particular algorithm for generating random numbers; while it is named after the yarrow-stalk method of consulting the I Ching, its details are unrelated to it.

Yarrow Stalks prepared for regular usage

Two heads and one tail of the original I-Ching Divination Coins.

The three-coin method came into use over a thousand years after the yarrow-stalk method. The quickest, easiest, and most popular method by far, it has largely supplanted yarrow stalks, but produces outcomes with different likelihoods. Three coins are tossed at once; each coin is given a value of 2 or 3, depending upon whether it is tails or heads, respectively. Six such tosses make the hexagram. Some fortune-tellers use an empty tortoise shell to shake the coins in before throwing them on a dish or plate.

The three-coin method can be modified to have the same probabilities as the yarrow-stalk method by having one of the coins be of a second coin type, or in some way be marked as special (i.e., be distinguishable from the other coins). All three coins are tossed at once. The results are counted just as in the original three-coin method, with two exceptions: one to make yin less likely to move, and one to make yang more likely to move. (The probability for 6/8/9/7 in the coin method is 2/6/2/6, but in the yarrow-stalk method is 1/7/3/5; hence, 6 has to occur less often, and 9 has to occur more often.)

In the case where the special coin is tails and the other two are both tails—which would normally produce a 6—re-flip the marked coin: if it remains tails, then treat it as a 6 (moving yin); otherwise, it remains an 8 (static yin). As a 6 can become a 6 or an 8, it reduces the probability of the moving 6. In other words, it makes the old yin less likely to change (or move).

In the case where the special coin is heads and the other two are both tails—which would normally produce an 7—re-flip the marked coin: if it remains heads, then treat it as a 7 (static yang); otherwise, it remains an 9 (moving yang). As a 7 can become a 7 or an 9, it reduces the probability of the static 7. In other words, it makes the young yang less likely and hence more yangs change as a result.

This method retains the 50% chance of yin:yang, but changes the ratio of moving yang to static yang from 1:3 to 1:7; likewise, it changes the ratio of moving yin to static yin from 1:3 to 3:5, which is the same probabilities as the yarrow-stalk method.

Some purists contend that there is a problem with the three-coin method because its probabilities differ from the more ancient, yarrow-stalk, method. In fact, over the centuries there have even been other methods used for consulting the oracle.

The two-coin method involves tossing one pair of coins twice: on the first toss, two heads give a value of 2, and anything else is 3; on the second toss, each coin is valued separately, to give a sum from 6 to 9, as above. This results in the same distribution of probabilities as for the yarrow-stalk method.

With tails assigned the value 0 (zero) and heads the value 1, four coins tossed at once can be used to generate a four-bit binary number, the right-most coin indicating the first bit, the next coin (to the first's left) indicating the next bit, etc. The number 0000 is called old yin; the next three numbers—0001, 0010, and 0011 (the binary numbers whose decimal equivalents are 1, 2, and 3, respectively)—are called old yang, with a similar principle applied to the remaining twelve outcomes. This gives identical results to the yarrow-stalk method.

The two-coin method described above can be performed with four coins, simply by having one pair of coins be alike—of the same size or denomination—while the other two are of a different size or denomination; the larger coins can then be counted as the first toss, while the two smaller coins constitute the second toss (or vice versa).

Six coins—five identical coins and one different—can be thrown at once. The coin that lands closest to a line drawn on the table will make the first line of the hexagram, and so on: heads for yang, tails for yin. The distinct coin is a moving line. This method has the dual failings that (1) it forces every hexagram to be a changing hexagram, and (2) it only ever allows exactly one line to be changing.

Eight coins, one marked, are tossed at once. They are picked up in order and placed onto a Bagua diagram; the marked coin rests on the lower trigram. The eight process is repeated for the upper trigram. After a third toss, the first six coins are placed on the hexagram to mark a moving line. This has the deficiency or allowing at most one moving line, whereas all six lines could be moving in traditional methods.

Any dice with an even number of faces can also be used in the same fashion as the coin tosses, with even die rolls for heads and odd for tails. An eight-sided die (d8) can be used to simulate the chances of a line being an old moving line equivalent to the yarrow-stalk method. For example, because the chances of any yin line or any yang line are equal in the yarrow-stalk method, there is a one-in-eight chance of getting any basic trigram, the same chance held under the ba qian method, so the ba qian method can be used to determine the basic hexagram. The d8 can then be used by rolling it once for each line to determine moving lines. A result of 1 on a yin line, or 3 or less on a yang line, will make that line a moving line, preserving the yarrow-stalk method's outcomes.

Another dice method that produces the 1:7:3:5 ratio of the yarrow-stalk method is to add 1d4 + 1d8. All odd results are considered yin, with the result of 11 denoting an old yin. Any even results would be considered yang, with both 4 and 10 treated as old yang.

Two dice methods that not only produce the yarrow-stalk probabilities but maintain the traditional even–odd associations of yin and yang are the 3d4 and 2d8 methods. In the 3d4 method, one rolls three four-sided dice and adds their outcomes, treating all odd totals as yang and all even totals as yin, with totals of 4, 7, and 12 indicating a moving line. The 2d8 method works analogously for two eight-sided dice, but here, any total over 10 (with the exception of 12) is considered moving.

Sixteen marbles can be used in four different colours. For example:

• 1 marble of a colour (such as blue) representing old yin
• 5 marbles of a colour (such as white) representing young yang
• 7 marbles of a colour (such as black) representing young yin
• 3 marbles of a colour (such as red) representing old yang

The marbles are drawn with replacement six times to determine the six lines. The distribution of results is the same as for the yarrow-stalk method.

[4]

For this method, either rice grains or small seeds are used. Six small piles of rice grains are made by picking up rice between finger and thumb. The number of grains in a pile determines if it is yin or yang. The rice grain method doesn't mark any lines as moving, while the traditional yarrow method can mark any of the six lines as moving.

There is a tradition of Taoist thought which explores numerology, esoteric cosmology, astrology and feng shui in connection with the I Ching.

The Han period (206 BCE-220 CE)… saw the combination and correlation of the I Ching, particularly in its structural aspects of line, trigrams, and hexagrams, with the yin-yang and wu hsing (Five Element) theories of the cosmologists, with numerical patterns and speculations, with military theory, and, rather more nebulously, with the interests of the fang-shih or "Masters of Techniques," who ranged over many areas, from practical medicine, through alchemy and astrology, to the occult and beyond.

— Hacker, Moore and Patsco, I Ching: an annotated bibliography, "The I Ching in Time and Space", p. xiii

The eleventh-century Neo-Confucian philosopher Shao Yung contributed advanced methods of divination including the Plum Blossom Yi Numerology, a horary astrology[5] that takes into account the number of calligraphic brush strokes of one's query. Following the associations Carl Jung drew between astrology and I Ching with the introduction of his theory of synchronicity, the authors of modern Yi studies are much informed by the astrological paradigm.[6] Chu and Sherrill provide five astrological systems in An Anthology of I Ching[7] and in The Astrology of I Ching[8] develop a form of symbolic astrology that uses the eight trigrams in connection with the time of one's birth to generate an oracle from which further hexagrams and a daily line judgement are derived.[5] Another modern development incorporates the planetary positions of one's natal horoscope against the backdrop of Shao Yung's circular Fu Xi arrangement and the Western zodiac to provide multiple hexagrams corresponding to each of the planets.[5]

This method goes back to Jing Fang (78–37 BC). While a hexagram is derived with one of the common methods like coin or yarrow stalks, here the divination is not interpreted on the basis of the classic I Ching text. Instead, this system connects each of the six hexagram lines to one of the Twelve Earthly Branches, and then the picture can be analyzed with the use of 5 Elements (Wu Xing).[9]

By bringing in the Chinese calendar, this method not only tries to determine what will happen, but also when it will happen. As such, Wen Wang Gua makes a bridge between I Ching and the Four Pillars of Destiny.

The preceding ("concrete"/physical) methods can be simulated in ("abstract"/conceptual) software. This has the theoretical advantage of improving randomness aspects of consulting the I Ching ("not-doing" in the personal sense, enhancing the "universal" principle). For all methods, one must pre-focus/prepare the mind.

Here is a typical example for the "modified three-coin" method:

#!/usr/bin/env python3
#
# iChing_Modified_3_coins.py
#
#   see https://github.com/kwccoin/I-Ching-Modified-3-Coin-Method
#
#   Create (two) I Ching hexagrams: present > future (might be same).
#
# With both "3-coin method" and "modified 3-coin method" (see <nowiki>https://en.wikipedia.org/wiki/I_Ching_divination</nowiki>).
#
# 3-coins Probabilities:
#   old/changing/moving yin    "6 : == x ==" = 1/8
#   (young/stable/static) yang "7 : =======" = 3/8
#   (young/stable/static) yin  "8 : ==   ==" = 3/8
#   old/changing/moving yang   "9 : == o ==" = 1/8
#
# 3-coins Probabilities:
#   old/changing/moving yin    "6 : === x ===" = 1/8
#   (young/stable/static) yang "7 : =========" = 3/8
#   (young/stable/static) yin  "8 : ===   ===" = 3/8
#   old/changing/moving yang   "9 : ====o====" = 1/8
#
# Modified 3-coins Probabilities:
#   old/changing/moving yin    "6 : === x ===" = 1/8 * 1/2     = 1/16
#   (young/stable/static) yang "7 : =========" = 3/8 - 1/8*1/2 = 5/16
#   (young/stable/static) yin  "8 : ===   ===" = 3/8 - P[6]    = 7/16
#   old/changing/moving yang   "9 : ====o====" = 1/8 - p[7]    = 3/16

# see 
# https://aleadeum.com/2013/07/12/the-i-ching-random-numbers-and-why-you-are-doing-it-wrong/
# especially see the remark why 1st round are 1/4-3/4 whilst 2nd and 3rd round are 1/2-1/2

import random

def toss(method: str = "yarrow") -> int:
    "Toss."""
    rng = random.SystemRandom()  # Auto-seeded, with os.urandom()

    special_coin = 0
    val = 0

    for flip in range(3):        # Three simulated coin flips i.e. coin 0, 1, 2
        val += rng.randint(2,3)  # tail=2, head=3 for each coin
        if flip == 0:
           special_coin = val    # Coin 0 as the special coin 

    if method == "coin":         # Coin method note tth or 223 is 7 or young yang 
        return val               # Probability of 6/7/8/9 is 1/8 3/8 3/8 1/8
    
    elif method == "modified 3 coins":
        # method similar to "yarrow-stick" need to have prob. 
        # for 6/7/8/9 as 1/16  5/16  7/16  3/16
        
        # now coin method is
        # for 6/7/8/9 as 2/16  6/16  6/16  2/16
        
        # modified to change
        #               -1/16 -1/16 +1/16 + 1/16
        #                   6     7     8      9
        if ((val == 6) and (special_coin == 2)):
            special_coin = rng.randint(2,3)   
            if (special_coin  == 2): 
                val = 6 
            else:
                val = 8                          
        elif ((val == 7) and (special_coin == 3)): 
            special_coin = rng.randint(2,3)   
            if (special_coin  == 3): 
                val = 7 
            else:
                val = 9                              
                
        return val                               # probability of 6/7/8/9 is 1/16 5/16 7/16 3/16
    
    else: #yarrow-stick method as effectively default
          #start_sticks, sky-left, sky-reminder, human,  earth-right, earth-reminder, bin 
          #value->   49         0             0      0             0            0      0
          #index->    0         1             2      3             4            5      6
          # on table:
          #               heaven
          # heaven-left   human    earth-right
          #               earth
          #
          # sometimes use finger to hold above

        def printys(ys, remark):
            # String format example: f"Result: {value:{width}.{precision}}"
            width=3
            print(f'[{ys[0]}, \t{ys[1]}, \t{ys[2]}, \t{ys[3]}, \t{ys[4]}, \t{ys[5]}, \t{ys[6]}] \t{remark}')
            return
        
        def ys_round(ys, round, debug="no"):
            if debug=="yes": print("Round is", round)
            if debug=="yes": print("===============")
            if debug=="yes": print(f'[{"src"}, \t{"sky"}, \t{"left"}, \t{"human"}, \t{"earth"}, \t{"right"}, \t{"bin"}] \t{"remark"}')
            # Generate a number somewhere in between 1/3 to 2/3 as human do not trick 
            if debug=="yes": printys(ys, "Starting")
            ys[1] = rng.randint(ys[0]//3,ys[0]*2//3)
            ys[4] = ys[0] - ys[1]
            ys[0] = ys[0] - ys[1] - ys[4]
            if debug=="yes": printys(ys, "Separate into two")
            ys[3] = 1 
            ys[1] = ys[1] - ys[3] 
            if debug=="yes": printys(ys, "and with one as human")
            ys[2] = ys[1] % 4
            if ys[2] == 0:
                ys[2] = 4
            ys[1] = ys[1] - ys[2]
            if debug=="yes": printys(ys, "then 4 by 4 and sky behind ...")
            ys[5] = ys[4] % 4
            if ys[5] == 0:
                ys[5] = 4
            ys[4] = ys[4] - ys[5]
            if debug=="yes": printys(ys, "then 4 by 4 and earth behind ...")
            ys[6] += ys[2] + ys[3] + ys[5]
            ys[2] = 0
            ys[3] = 0
            ys[5] = 0
            ys[0] = ys[1] + ys[4] 
            ys[1] = 0
            ys[4] = 0
            if debug=="yes": printys(ys, "complete the cycle ...")
            return ys


        ys = [0, 0, 0, 0, 0, 0, 0]  # May be better use dictionary
        ys[0] = 55
        # printys(ys, "The number of heaven and earth is 55")
        ys[0] = 49
        # printys(ys, "only 49 is used")
            
        # Round 1 need to ensure mod 4 cannot return 0 and cannot have 0 
        # wiki said cannot have 1 as well not sure about that
        
        ys = ys_round(ys, 1, "no") # "yes")
        ys = ys_round(ys, 2, "no") # "yes")
        ys = ys_round(ys, 3, "no") # "yes")
        return (ys[0] // 4)


# We build in bottom to top

print("Method is yarrow by default\n")
toss_array = [0, 0, 0, 0, 0, 0]

for line in range(0,6,1):
     toss_array[line] = toss()
     print("Line is ", line+1, "; toss is ", toss_array[line], "\n")

# Hence we print in reverse

def print_lines_in_reverse(toss_array):
     for line in range(5, -1, -1):
         val = toss_array[line]  # The changing line/hexagram need another program
         if   val == 6: print('6  :  == x ==')# ||   ==   ==  >  -------')
         elif val == 7: print('7  :  -------')# ||   -------  >  -------')
         elif val == 8: print('8  :  ==   ==')# ||   ==   ==  >  ==   ==')
         elif val == 9: print('9  :  -- o --')# ||   -------  >  ==   ==')

print_lines_in_reverse(toss_array)

print("\n\n")

With a modified three-coin method as default, this may avoid the Sung dynasty issue, i.e., when you have an easily available and simple method, you use it—but with a wrong probability! (Also, the first number starts from the bottom like a hexagram.)

A JavaScript version of the Yarrow Stalk method, which generates slightly different probabilities, is available in open source form at GitHub.