Since sections share property names eg. a length called L it is always necessary to specify which section is being discussed.
There are three methods of specifying which section a property refers to (with each being compact in some contexts and cumbersome in others). They are given below in order of precedence (highest first).
This takes precedence over the other methods and is described by the syntax sectionname.varname. Examples are
dendrite[2].L = dendrite[1].L + dendrite[0].L
axon.v = soma.v
print soma.gnabar
axon.nseg = 2*axon.nseg
This notation is necessary when one needs to refer to more than one section within a single statement.
The syntax is
sectionname {stmt}
and means that the currently selected section during the execution of stmt is sectionname. This method is the most useful for programming since the user has explicit control over the scope of the section and can set several range variables. Notice that after the stmt is executed the currently selected section reverts to the name (if any) it had before sectionname was seen. The programmer is allowed to nest these statements to any level. Avoid the error:
soma L=10 diam=10
which sets soma.L, then pops the section stack and sets diam for whatever section is then on the stack.
It is important that control flow reach the end of stmt in order to automatically pop the section stack. Therefore, one cannot use the continue, break, or return statements in stmt.
There is no explicit notion of a section variable in NEURON but the same effect can be obtained with the SectionRef class. The use of push_section() for this purpose is not recommended except as a last resort.
Looping over sets of sections is done most often with the forall and forsec commands.
The syntax
access sectionname
defines a default section name to be the currently selected section when the first two methods are not in effect. There is often a conceptually privileged section which gets most of the use and it is useful to declare that as the default section. e.g.
access soma
With this, one can, with a minimum of typing, get values of voltage, etc at the command line level.
In general, this statement should only be used once to give default access to a privileged section. It's bad programming practice to change the default access within anything other than an initialization procedure. The "sec { stmt }" form is almost always the right way to use the section stack.
access
- Syntax:
- access section
- Description:
Makes section the default currently accessed section. More precisely, it replaces the top of the section stack with the indicated section and so will be the permanent default section only if the section stack is empty or has only one section in it. This is lesser precedence than section stmt which is lesser precedence than section.var
Note:
The access statement should not be used within a procedure or function. In fact the best style is to execute it only once in a program to refer to a priviledged section such as "soma". It can be very confusing when a procedure has the side effect of permanently changing the default section.
Example:
create a, b, c, d access a print secname() b print secname() access c # not recommended. The "go_to" of sections. print secname() d print secname() print secname() # because the stack has more than one section, c is popped off print secname() # and the second "access" was not permanent!
forall
- Syntax:
- forall stmt
- Description:
Loops over all sections, successively making each section the currently accessed section.
Within an object, forall refers to all the sections declared in the object. This is generally the right thing to do when a template creates sections but is inconvenient when a template is constructed which needs to compute using sections external to it. In this case, one can pass a collection of sections into a template function as a SectionList object argument.
The forall is relatively slow, especially when used in conjunction with issection() and ismembrane() selectors. If you are often iterating over the same sets it is much faster to keep the sets in SectionList objects and use the much faster forsec command.
The iteration sequence order is undefined but will remain the same for a given sequence of create statements.
Example:
create soma, axon, dend[3] forall: print secname()prints the names of all the sections which have been created.
soma axon dend[0] dend[1] dend[2]See also
ifsec
- Syntax:
ifsec string stmt
ifsec sectionlist stmt
Description:
- ifsec string stmt
- Executes stmt if string is contained in the name of the currently accessed section. equivalent to if(issection(string)) stmt Note that the regular expression semantics is not the same as that used by issection. To get an exact match use ifsec ^string$
- ifsec sectionlist stmt
- Executes stmt if the currently accessed section is in the sectionlist.
See also
forsec string stmt
forsec sectionlist stmt
Description:
- forsec string stmt
- equivalent to forall ifsec string stmt but faster. Note that forsec string is equivalent to forall if (issection(string)) stmt
- forsec sectionlist
- equivalent to forall ifsec sectionlist stmt but very fast.
These provide a very efficient iteration over the list of sections.
Example:
create soma, dend[3], axon forsec "a" print secname()sl = h.SectionList() i = 2 while (i>= 0): i = i - 1 dend[i] sl.append() forsec sl print secname()
Example:
from neuron import h for i in range(5): soma[i] stim[i] = new IClamp(i/4) for i in range(5): x = stim[i].get_loc() print("location of %s is %s(%g)\n", stim[i], secname(), x) h.pop_section()
push_section(number)
push_section(section_name)
This function, along with pop_section() should only be used as a last resort. It will place a specified section on the top of the section stack, becoming the current section to which all operations apply. It is probably always better to use SectionRef or SectionList .
See also